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-Project Gutenberg's The Standard Electrical Dictionary, by T. O'Conor Slone
-
-This eBook is for the use of anyone anywhere at no cost and with
-almost no restrictions whatsoever.  You may copy it, give it away or
-re-use it under the terms of the Project Gutenberg License included
-with this eBook or online at www.gutenberg.org
-
-
-Title: The Standard Electrical Dictionary
-       A Popular Dictionary of Words and Terms Used in the Practice
-       of Electrical Engineering
-
-Author: T. O'Conor Slone
-
-Release Date: September 5, 2008 [EBook #26535]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK THE STANDARD ELECTRICAL DICTIONARY ***
-
-
-
-
-Produced by Don Kostuch
-
-
-
-
-[Transcriber's Notes]
-
-Obvious spelling errors have been corrected. I have not reconciled the
-variety of spellings of names and other words. Obvious factual errors,
-typographical errors, discoveries made after 1892, and contemporary
-(2008) theories and use of words are noted in the text within square
-brackets. I have not researched and checked every assertion by the
-author.
-
-This book was published 5 years before discovery of the electron. See
-the labored and completely inaccurate explanations of aurora and
-"energy, atomic". The author and his contemporaries were like fifteenth
-century sailors. They had a good idea of their latitude and direction
-(Ampere, Kirkoff, Maxwell, Gauss, Faraday, Edison, �), but only the
-vaguest notion of their longitude (nuclear structure, electrons, ions).
-Altitude (special relativity, quantum theory) was not even imagined.
-
-Some relevant dates:
-Franklin's Kite--1752
-Faraday's Law of Induction--1831
-Maxwell's Equations--1861
-Edison's Phonograph--1877
-Edison's light bulb--1879
-Edison's first DC power station--1882
-Michelson-Morley experiment disproving ether--1887
-Hertz demonstrates radio waves--1888
-Westinghouse first AC power station--1891
-This book--1892
-Discovery of the electron--1897
-Marconi radio signals cross the English Channel--1897
-First Vacuum Tube--1904
-Special Relativity, photo-electric effect explained with photons--1905
-General Relativity: space-time dilation and curvature--1915
-Confirmation of general relativity's prediction of the deflection
-  of starlight by the Sun--1919
-Discovery of the proton--1920
-Quantum theory--1926
-Discovery of neutron--1932
-First transistor--1947
-Soviet satellite Luna measures solar wind--1959
-Edward M. Purcell explains magnetism with special relativity--1963
-
-Purcell's explanation of magnetism as a result of Lorentz contraction of
-space along the direction of a current is a welcome relief from the
-convoluted descriptions in this book.
-
-Mathematical notation is rendered using "programming" notation.
-^     Power--Exponential; A^3 means "A cubed"
-*     Multiply
-/     Divide
-+     Add
--     Subtract
-( )   Precedence--Perform before enclosing expression
-2E6   Scientific Notation (2,000,000)
-
-
-        A
----------------------
-4.452 X 10^12 X t
-
-is rendered as
-
-A / ( 4.452E12 *  t  )
-
-
-Where the rendering of a mathematical expression is in doubt, an image
-of the original text is included.
-
-
-Here are some definitions absent from the text.
-
-Foucault currents.
-  Eddy currents.
-
-inspissate
-  To thicken, as by evaporation.
-
-riband
-  Ribbon.
-
-sapotaceous
-  Order Sapotace[ae] of trees and shrubs, including the star apple, the
-  Lucuma, or natural marmalade tree, the gutta-percha tree (Isonandra),
-  and the India mahwa, as well as the sapodilla, or sapota, after which
-  the order is named.
-
-
-Don Kostuch, MS, Electrical Engineering.
-[End Transcriber's notes.]
-
-
-
-WORKS OF
-T. O'CONOR SLOANE, A.M., E.M., Ph.D.
-
-
-ARITHMETIC OF ELECTRICITY
-A MANUAL OF ELECTRICAL CALCULATIONS
-BY ARITHMETICAL METHODS.
-Third Edition. Illustrated. $1.00.
-It is very useful to that class of readers to whom Algebra is a
-comparatively unknown quantity, and will meet its wants
-admirably.--Electrical World.
-
-
-
-ELECTRICITY SIMPLIFIED.
-A POPULAR TREATMENT OF THE SUBJECT.
-Illustrated. $1. 00.
-We especially recommend it to those who would like to acquire a popular
-idea of the subject.--Electric Age.
-
-
-
-ELECTRIC TOY MAKING.
-FOR AMATEURS.
-INCLUDING BATTERIES, MAGNETS, MOTORS, MISCELLANEOUS TOYS,
-AND DYNAMO CONSTRUCTION.
-Fully Illustrated. $1.00.
-
-THE STANDARD ELECTRICAL DICTIONARY.
-
-A POPULAR DICTIONARY OF WORDS AND TERMS
-USED IN THE PRACTICE OF ELECTRICAL ENGINEERING.
-
-
-BY
-T. O'CONOR SLOANE, A.M., E.M., Ph.D.
-
-
-NEW YORK
-GEORGE D. HURST
-PUBLISHER
-
-
-
-Copyright 1892
-by
-NORMAN W. HENLEY & CO.
-
-
-
-PREFACE
-
-The purpose of this work is to present the public with a concise and
-practical book of reference, which it is believed will be appreciated in
-this age of electricity. The science has expanded so much that the
-limits of what may be termed strictly a dictionary of the present day
-would a few years ago have sufficed for an encyclopedia. It follows that
-an encyclopedia of electricity would be a work of great size. Yet a
-dictionary with adequate definitions, and kept within the closest limits
-by the statement of synonyms, and by the consigning of all the
-innumerable cross-references to a concise index will be far more than a
-mere dictionary in the ordinary sense of the term.
-
-Duplication of matter is to be avoided. This makes many definitions
-appear short. Yet, by the assistance of the reader's own general
-knowledge, and by referring to the very complete index, almost any
-subject can be found treated in all its aspects. There are exceptions to
-this statement. So much has been done in the way of mechanical detail,
-so many inventions in telegraphy and other branches have sprung into
-prominence only to disappear again, or to be modified out of
-recognition, that to embody descriptions of many ingenious and
-complicated apparatus has been absolutely impossible for want of space.
-
-A word as to the use of the book and the system of its construction may
-be given here. Each title or subject is defined once in the text. Where
-a title is synonymous with one or more others the definition is only
-given under one title, and the others appear at the foot of the article
-as synonyms. It may be that the reader is seeking the definition of one
-of these synonyms. If so a reference to the index shows him at once what
-page contains the information sought for. The use of an index in a work,
-necessarily of an encyclopedic form, will be appreciated by all users of
-this book.
-
-
-vi   PREFACE.
-
-
-Where a title embraces several words, all orders of the words will be
-cited in the index. To make the operation of finding references easy
-this rule has been carried out very fully.
-
-It is customary to regard electricity as a growing science. It is
-unquestionably such, but the multiplication of terms and words is now
-not nearly so rapid as it has been, and the time for the compiling of a
-work of this character seems most propitious. It is hoped that the
-public will indulgently appreciate the labor it has entailed on all
-concerned in its production.
-
-
-SYMBOLS AND ABBREVIATIONS.
-
-adj.   Adjective.
-v.   Verb.
-q.v.   "Which see.'
-/   A mark of division, as A/B, meaning "A divided by B."
-./.  The same as above.
-        [Transcriber's note: / will be substituted for this divide symbol.]
-=  A mark of equality, meaning "is equal to."
-X   A mark of multiplication, meaning "multiplied by."
-        [Transcriber's note: * will be substituted for this divide symbol.]
-
-Fractional exponents indicate the roots expressed by their denominators
-and the powers expressed by their numerators. Thus, A^1/2 means the
-"square root of A;" A^1/3 means the "cube root of A;" B^3/2 means the
-"square root of the cube or third power of B."
-
-The use of powers of ten, as 10^10, 10^11, as multipliers, will be found
-explained at length in the definition "Ten, Powers of."
-
-vii  STANDARD ELECTRICAL DICTIONARY
-
-A.
-Abbreviation for anode, employed in text relating to
-electro-therapeutics. It is sometimes written An.
-
-
-Abscissa.
-In a system of plane co-ordinates (see Co-ordinates) the
-distance of any point from the axis of ordinates measured parallel to
-the axis of abscissas.
-
-In the cut the abscissa of the point a is the line or distance a c.
-
-
-Fig. 1. AXES OF CO-ORDINATES.
-
-
-Absolute. adj.
-In quantities it may be defined as referring to fixed units of quantity,
-and it is opposed to "relative," which merely refers to the relation of
-several things to each other. Thus the relative resistance of one wire
-may be n times that of another; its absolute resistance might be 5 ohms,
-when the absolute resistance of the second wire would be 5/n ohms. A
-galvanometer gives absolute readings if it is graduated to read directly
-amperes or volts; if not so graduated, it may by "calibration" q. v. be
-made to do practically the same thing.
-
-
-8   STANDARD ELECTRICAL DICTIONARY.
-
-
-Absolute Measurement.
-Measurement based upon the centimeter, gram, and second. (See
-Centimeter-Gram-Second System.)
-
-
-Absolute Temperature.
-Temperature reckoned from absolute zero (see "Zero, Absolute"). It is
-obtained by adding for the centigrade scale 273, and for the Fahrenheit
-scale 459, to the degree readings of the regular scale.
-
-
-Absorption, Electric.
-A property of the static charge. When a Leyden jar is being charged it
-dilates a little and the capacity increases, so that it can take a
-little more charge for a given potential difference existing between its
-two coatings. This phenomenon occurs with other static condensers,
-varying in degree with the dielectric. With shellac, paraffin, sulphur
-and resin, for instance, the absorption is very slight; with
-gutta-percha, stearine, and glass, the absorption is relatively great.
-The term is due to Faraday. Iceland spar seems almost or quite destitute
-of electric absorption.
-
-
-A. C. C.
-Symbol of or abbreviation for "anodic closure contraction" q. v.
-
-
-Acceleration.
-The rate of change of velocity. If of increase of velocity it is
-positive; if of decrease, it is negative. It can only be brought about
-by the exercise of force and is used as the measure of or as determining
-the unit of force. It is equal to velocity (L/T) imparted, divided by
-time (T); its dimensions therefore are L/(T^2). The c. g. s. unit of
-acceleration is one centimeter in one second.
-
-[Transcriber's note: The unit of acceleration is "centimeters per second
-per second."]
-
-
-Accumulator.
-(a) A term sometimes applied to the secondary or storage battery. (See
-Battery, Secondary.)
-(b) See Accumulator, Electrostatic
-(c) See Accumulator, Water Dropping.
-(d) See Wheel, Barlow's
-
-
-Accumulator, Electrostatic.
-Two conducting surfaces oppositely placed, and separated by a
-dielectric and arranged for the opposite charging of the two surfaces,
-constitute an accumulator, sometimes termed a condenser. As this
-arrangement introduces the element of a bound and of a binding charge,
-the electrostatic capacity of such is greater than that of either or of
-both of its component surfaces. The thinner the dielectric which
-separates the conducting surfaces, and the larger the surfaces the
-greater is the capacity; or the less will be the potential difference
-which a given charge will establish between its two coatings. The nature
-of the dielectric also determines its capacity. (See Capacity, Specific
-Inductive.)
-
-
-9  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 2. SIR WILLIAM THOMSON'S WATER-DROPPING ACCUMULATOR.
-
-
-Accumulator, Water Dropping.
-This is also known as Sir William Thomson's Water-Gravity Electric
-Machine. It is an apparatus for converting the potential energy of
-falling water drops, due to gravity, into electric energy. Referring to
-the illustration, G represents a bifurcated water pipe whose two faucets
-are adjusted to permit a series of drops to fall from each. C and F are
-two metallic tubes connected by a conductor; E and D are the same. Two
-Leyden jars, A and B, have their inner coatings represented by strong
-sulphuric acid, connected each to its own pair of cylinders, B to D and
-E, and A to F and C. The outer coatings are connected to earth, as is
-also the water supply. One of the jars, say A, is charged interiorily
-with positive electricity. This charge, C and F, share with it, being in
-electric contact therewith. Just before the drops break off from the jet
-leading into C, they are inductively charged with negative electricity,
-the positive going to earth. Thus a series of negatively excited drops
-fall into the metal tube D, with its interior funnel or drop arrester,
-charging it, the Leyden jar B, and the tube E with negative electricity.
-This excitation causes the other stream of drops to work in the converse
-way, raising the positive potential of F and C and A, thus causing the
-left-hand drops to acquire a higher potential. This again raises the
-potential of the right-hand drops, so that a constant accumulating
-action is kept up. The outer coatings of the Leyden jars are connected
-to earth to make it possible to raise the potential of their inner
-coatings. In each case the drops are drawn by gravity into contact with
-objects similarly excited in opposition to the electric repulsion. This
-overcoming of the electric repulsion is the work done by gravity, and
-which results in the development of electric energy.
-
-
-10   STANDARD ELECTRICAL DICTIONARY.
-
-
-Acidometer.
-A hydrometer or areometer used to determine the specific gravity of
-acid. They are employed in running storage batteries, to determine when
-the charging is completed. (See Areometer.)
-
-
-Aclinic Line.
-A terrestrial element; the locus on the earth's surface of no
-inclination of the magnetic needle; the magnetic equator. (See Magnetic
-Elements.)
-
-
-Acoustic Telegraphy.
-The system of sound-reading in telegraphy, universally used in the Morse
-system. The direct stroke of the armature of the electro-magnet and its
-"back stroke" disclose to the ear the long and short strokes, dots and
-lines, and long and short spaces as produced by the dispatcher of the
-message. In the Morse system a special magnet and armature is used to
-produce the sound called the "sounder;" in other systems, e. g.,
-Steinheil's and Bright's apparatus, bells are used. (See Alphabets,
-Telegraphic.)
-
-
-Acoutemeter.
-A Hughes audiometer or sonometer applied to determining the quality of a
-person's hearing (See Hughes' Induction Balance,--Audiometer). The
-central coil by means of a tuning fork and microphone with battery
-receives a rapidly varying current tending to induce currents in the
-other two coils. Telephones are put in circuit with the latter and pick
-up sound from them. The telephones are applied to the ears of the person
-whose hearing is to be tested. By sliding the outer coils back and forth
-the intensity of induction and consequent loudness of the sounds in the
-telephones is varied. The position when the sounds grow so faint as to
-be no longer audible, gives the degree of delicacy of the person's
-hearing. By using a single telephone the same apparatus affords a means
-of testing the relative capacity of the right and left ears.
-
-
-11  STANDARD ELECTRICAL DICTIONARY.
-
-
-Actinic Rays.
-The rays of light at the violet end of the spectrum; also the invisible
-rays beyond such end, or the ether waves of short periods which most
-strongly induce chemical change.
-
-
-Actinism.
-The power possessed by ether waves of inducing chemical change, either
-of decomposition or of combination. The violet and ultra-violet end of
-the spectrum of white light, generally speaking, represent the most
-highly actinic rays.
-
-
-Actinometer, Electric.
-Properly an apparatus for measuring the intensity of light by its action
-upon the resistance of selenium. A current produced by fixed
-electro-motive force passing through the selenium affects a galvanometer
-more or less according to the intensity of the light. It is more
-properly an electric photometer. The term has also been applied to a
-combination of a thermo-electric pile and galvanometer, the light
-falling on the pile affecting the motions of the galvanometer.
-
-
-Action, Local.
-(a) The wasteful oxydation of the zinc in a galvanic battery due to
-local impurities and variations in the composition of the zinc. These
-act to constitute local galvanic couples which cause the zinc to
-dissolve or oxydize, without any useful result. Amalgamation of the zinc
-prevents local action. Chemically pure zinc is also exempt from local
-action, and can be used in an acid battery without amalgamation. (See
-Amalgamation.)
-
-(b) The same term has been employed to indicate the eddy or foucault
-currents in dynamo electric machines. (Sec Current, Foucault.)
-
-
-Activity.
-The rate of doing work; the work done per second by any expenditure of
-energy. The activity of a horse-power is 550 foot lbs. per second, or
-746 volt-coulombs per second. The practical electric unit is the
-volt-ampere, often called the watt. (Sec Energy, Electric.)
-
-
-Adapter.
-A screw coupling to engage with a different sized screw on each end; one
-of the uses is to connect incandescent lamps to gas-fixtures.
-
-
-A. D. C.
-Abbreviation for Anodic Duration Contraction, q. v.; a term in
-electro-therapeutics.
-
-
-Adherence, Electro-magnetic.
-The adherence between surfaces of iron due to elcctro-magnetic
-attraction. It has been applied to the driving-wheels of an engine and
-rail, whose grip is increased by such action. In one method a deep
-groove was cut around the wheel which was wound with a magnetizing coil.
-Thus one rim becomes a north and the other a south pole, and the rail
-completing the circuit acts as the armature. Such an arrangement
-prevents a wheel from sliding. Electro-magnetic adherence has also been
-employed to drive friction gear wheels. In one arrangement the two
-wheels are surrounded by a magnetizing coil, under whose induction each
-attracts the other, developing high adherence between their peripheries.
-
-
-12  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 3. ELECTRO-MAGNETIC CAR WHEEL.
-
-
-Fig. 4. ELECTRO-MAGNETIC FRICTION GEAR.
-
-
-Admiralty Rule of Heating.
-The British Admiralty specifications for the permissible heating of
-dynamos. It holds that at the end of a run of six hours no part of the
-dynamo under trial shall show a rise of temperature greater than 11� C.
-(20� F.) above the temperature of the air surrounding it. This is
-thought to be a very stringent and unnecessarily high requirement.
-
-
-Aerial Conductor.
-An electric conductor carried from housetops, poles, or otherwise so as
-to be suspended in the air, as distinguished from an underground or
-submarine conductor.
-
-
-Affinity.
-The attraction of atoms and in some cases perhaps of molecules for each
-other by the force of chemical attraction. When the affinity is allowed
-to act or is carried out, a chemical change, as distinguished from a
-physical or mechanical change, ensues. Thus if sulphur and iron are each
-finely powdered and are mixed the change and mixture are mechanical. If
-slightly heated the sulphur will melt, which is a physical change. If
-heated to redness the iron will combine with the sulphur forming a new
-substance, ferric sulphide, of new properties, and especially
-characterized by unvarying and invariable ratios of sulphur to iron.
-Such change is a chemical one, is due to chemical affinity, is due to a
-combination of the atoms, and the product is a chemical compound.
-
-
-13  STANDARD ELECTRICAL DICTIONARY.
-
-
-Agir Motor.
-The Anderson and Girdlestone motor. The term "agir" is made up from the
-first portions of each name.
-
-
-Agonic Line.
-The locus of points on the earth's surface where the magnetic needle
-points to the true north; an imaginary line determined by connecting
-points on the earth's surface where the needle lies in the true
-geographical meridian. Such a line at present, starting from the north
-pole goes through the west of Hudson's Bay, leaves the east coast of
-America near Philadelphia, passes along the eastern West Indies, cuts
-off the eastern projection of Brazil and goes through the South Atlantic
-to the south pole. Thence it passes through the west of Australia, the
-Indian Ocean, Arabia, the Caspian sea, Russia and the White sea to the
-North Pole. It crosses the equator at 70� W. and 55� E. approximately.
-(See Magnetic Elements.)
-
-Synonym--Agone.
-
-[Transcriber's note: The file Earth_Declination_1590_1990.gif provided
-by the U.S. Geological Survey (http://www.usgs.gov) is an animation of
-the declination of the entire earth.]
-
-
-Air.
-Air is a dielectric whose specific inductive capacity at atmosphere
-pressure is taken as 1. It is practically of exactly the same
-composition in all places and hence can be taken as a standard. When dry
-it has high resistance, between that of caoutchouc and dry paper.
-Dampness increases its conductivity.
-
-It is a mixture of oxygen and nitrogen, with a little carbonic acid gas
-and other impurities. Its essential composition is:
-
-Oxygen:   (by weight)   23.14   (by volume)   21
-Nitrogen:               76.86                 79
-
-The specific inductive capacity varies for different pressures thus:
-
-Approximate vacuum (.001 mm., .0004 inch)   0.94 (Ayrton)
-    "          "   ( 5 mm.  , .2 inches )   0.9985 (Ayrton)
-                                            0.99941 (Boltzman.)
-
-The specific gravity of air under standard conditions 15.5� C (60� F.)
-and 760 mm. barometric pressure (30 inches) is taken as unity as a
-standard for gases.
-
-[Transcriber's note: Argon accounts for 0.9340%. It was discovered in
-1894, two years after this book.]
-
-
-Air-Blast.
-(a) In the Thomson-Houston dynamo an air-blast is used to blow away the
-arc-producing spark liable to form between the brushes and commutator.
-It is the invention of Prof. Elihu Thomson. The air is supplied by a
-positive action rotary blower connected to the main shaft, and driven
-thereby. The wearing of the commutator by destructive sparking is thus
-prevented.
-
-A drum H H is rotated, being mounted on the axis X of the dynamo. As it
-rotates the three vanes are thrown out against the irregular shaped
-periphery of the outer case T T. The arrow shows the direction of
-rotation. The air is thus sent out by the apertures a a. O is the
-oil-cup.
-
-(b) The air-blast has also been used by Prof. Thomson in experiments
-with high frequency currents of high potential. By directing a blast of
-air against a spark discharge between ball terminals of an alternating
-current, the nature of the current was changed and it became capable of
-producing most extraordinary effects by induction.
-
-
-14   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 5. AIR BLOWER FOR THOMSON'S DYNAMO.
-
-
-Air Condenser.
-A static condenser whose dielectric is air. The capacity of an air
-condenser in farads is equal to
-  A / ( 4.452E12 * t )
-in which A is the area of one sheet or sum of the areas of one set of
-connected sheets in square inches and t is the thickness of the layer of
-air separating them.
-
-A convenient construction given by Ayrton consists in a pile of glass
-plates P separated by little bits of glass F of known thickness, three
-for each piece. Tin-foil T is pasted on both sides of each piece of
-glass and the two coatings are connected. The tin-foil on each second
-plate is smaller in area than that on the others. The plates are
-connected in two sets, each set comprising every second plate. For A in
-the formula the area of the set of smaller sheets of tin-foil is taken.
-By this construction it will be seen that the glass does not act as the
-dielectric, but only as a plane surface for attachment of the tin-foil.
-Posts E E keep all in position. One set of sheets connects with the
-binding post A, the other with B.
-
-The capacity of any condenser with a dielectric of specific inductive
-capacity i is given by the formula:
-     ( i *A^1 ) / ( 4.452E12 * t1 )
-
-The air condenser is used for determining the value of i for different
-dielectrics.
-
-
-Fig. 6. AIR CONDENSER.
-
-
-15  STANDARD ELECTRICAL DICTIONARY.
-
-
-Air Gaps.
-In a dynamo or motor the space intervening between the poles of the
-field magnet and the armature. They should be of as small thickness, and
-of as extended area as possible. Their effect is to increase the
-magnetic reluctance of the circuit, thereby exacting the expenditure of
-more energy upon the field. They also, by crowding back the potential
-difference of the two limbs, increase the leakage of lines of force from
-limb to limb of the magnet.
-
-
-Air Line Wire.
-In telegraphy the portion of the line wire which is strung on poles and
-carried through the air.
-
-
-Air Pump, Heated.
-It has been proposed to heat portions of a mercurial air pump to secure
-more perfect vacua, or to hasten the action. Heating expands the air and
-thus produces the above effects.
-
-
-16   STANDARD ELECTRICAL DICTIONARY.
-
-
-Air Pump, Mercurial.
-An air pump operated by mercury. The mercury acts virtually as the
-piston, and the actuating force is the weight of the column of mercury,
-which must exceed thirty inches in height. There are many types.
-Mercurial air pumps are largely used for exhausting incandescent lamp
-chambers. (See Geissler Air Pump,--Sprengel Air Pump.)
-
-
-Air Pumps, Short Fall.
-A mercurial air pump in which the fall of mercury or the height of the
-active column is comparatively small. It is effected by using several
-columns, one acting after the other. A height of ten inches for each
-column suffices in some forms. Enough columns must be used in succession
-to make up an aggregate height exceeding 30 inches.
-
-
-Fig. 7. BURGLAR ALARM SWITCH OR CIRCUIT BREAKER.
-
-
-Fig. 8. BURGLAR ALARM SWITCH OR CIRCUIT BREAKER.
-
-
-Alarm, Burglar.
-A system of circuits with alarm bell extending over a house or
-apartments designed to give notice of the opening of a window or door.
-As adjuncts to the system the treads of the stairs are sometimes
-arranged to ring the bell, by completing a circuit when trod on. Door
-mats are also arranged to close circuits in like manner.
-
-
-17  STANDARD ELECTRICAL DICTIONARY.
-
-
-For doors and windows switches are provided which are open as long as
-the door or window is closed, but which, on being released by opening
-the door or windows, automatically close the circuit. The circuit
-includes an alarm bell and battery, and the latter begins to ring and
-continues until stopped, either by the closing of the door or by a
-switch being turned. The connections are sometimes so contrived that the
-reclosing of the door or window will not stop the bell from ringing.
-
-The cuts show various switches for attachment to doors and windows. It
-will be seen that they normally keep the circuit closed, and that it is
-only open when pressure, as from a closed door, is brought upon them. In
-the case of a door a usual place for them is upon the jamb on the hinge
-side, where they are set into the wood, with the striking pin
-projecting, so that as the door is closed the pin is pressed in, thus
-breaking the circuit.
-
-Sometimes the connections are arranged so as to switch on the electric
-lights if the house is entered. Special annunciators showing where the
-house has been entered are a part of the system. A clock which turns the
-alarm on and off at predetermined hours is also sometimes used.
-
-The circuits may be carried to a central station or police station. One
-form of burglar alarm device is the Yale lock switch. This is a contact
-attached to a Yale lock which will be closed if the wrong key is used,
-completing a circuit and ringing a bell.
-
-
-Fig. 9. BURGLAR ALARM SWITCH OR CIRCUIT BREAKER.
-
-
-Alarm, Electric.
-An appliance for calling attention, generally by
-ringing a bell. It is used to notify of water-level in boilers or tanks,
-of entrance of a house, or of other things as desired. It is evident
-that any number of alarms could be contrived.
-
-
-18   STANDARD ELECTRICAL DICTIONARY.
-
-
-Alarm, Fire and Heat.
-An alarm for giving notice of the existence of a conflagration. Such are
-sometimes operated by a compound bar thermostat (see Thermostat), which
-on a given elevation of temperature closes a circuit and rings an
-electric bell. Sometimes the expansion of a column of mercury when
-heated is used. This, by coming in contact with one or two platinum
-points, completes a circuit, and rings the bell.
-
-The identical apparatus may be used in living rooms, greenhouses.
-factories and elsewhere, to give an alarm when the temperature rises or
-falls beyond predetermined limits.
-
-
-Alarm, Overflow.
-An alarm to indicate an overflow of water has been suggested on the
-lines of a contact completed by water, or of the elements of a battery
-which would be made active by water. Thus two sheets of metal might be
-separated by bibulous paper charged with salt. If these sheets were
-terminals of a circuit including a bell and battery, when water reached
-them the circuit would be closed and the bell would ring. It was also
-proposed to use one copper and one zinc sheet so as to constitute a
-battery in itself, to be thrown into action by moisture. These contacts
-or inactive batteries could be distributed where water from an overflow
-would be most likely to reach them.
-
-
-Alarm, Water Level.
-An alarm operated by a change of water level in a tank or boiler. By a
-float a contact is made as it rises with the water. Another float may be
-arranged to fall and close a contact as the level falls. The closing of
-the contacts rings an electric bell to notify the attendant in charge.
-
-
-Alcohol, Electrical Rectification of.
-A current of electricity passed through impure alcohol between zinc
-electrodes is found to improve its quality. This it does by decomposing
-the water present. The nascent hydrogen combines with the aldehydes,
-converting them into alcohols while the oxygen combines with the zinc
-electrode.
-
-
-Alignment.
-The placing in or occupying of the same straight line. The bearings of a
-shaft in dynamos, engines, and other machinery have to be in accurate
-alignment.
-
-
-Allotropy.
-The power of existing in several modifications possessed by some
-substances, notably by chemical elements. Instances of the allotropic
-state are found in carbon which exists as charcoal, as graphite
-(plumbago or black lead), and as the diamond. All three are the same
-elemental substance, although differing in every physical and electrical
-property.
-
-
-19   STANDARD ELECTRICAL DICTIONARY.
-
-
-Alloy.
-A mixture, produced almost universally by fusion, of two or more metals.
-Sometimes alloys seem to be chemical compounds, as shown by their having
-generally a melting point lower than the average of those of their
-constituents. An alloy of a metal with mercury is termed an amalgam. An
-important application in electricity is the use of fusible alloys for
-fire alarms or for safety fuses. German silver is also of importance for
-resistance coils, and palladium alloys are used for unmagnetizable
-watches. An alloy of wrought iron with manganese is almost
-unmagnetizable, and has been proposed for use in ship building to avoid
-errors of the compass.
-
-Alloys or what are practically such can be deposited by electrolysis in
-the electro- plater's bath. We give the composition of some alloys
-interesting to the electrician.
-
-  Solder:   Lead   1 part   Tin   2 parts
-              "      "       "    1  "
-              "      "       "    2  "
-
-German Silver: Copper, 2 parts; Nickel, 1 part;
-               Zinc, 1 part (used for resistances).
-
-Platinum, Silver Alloys: Platinum, 1 part;
-                         silver, 2 parts (used for resistances.)
-
-Palladium alloys for watch springs. (See Palladium.)
-
-
-Alphabet, Telegraphic.
-The combinations of sounds, of dots and dashes marked on paper, of
-right-hand and left-hand deflections of a needle, of bells of different
-notes, or of other symbols by which a fixed combination is expressed for
-each character of the alphabet, for numerals, and for punctuation. While
-the code is designed for telegraphic uses it can be used not only for
-the conveyance of signals and messages by the electrical telegraphs, but
-also by any semaphoric or visual system, as by flashes of light,
-movements of a flag or even of the arms of the person signalling.
-
-In the English and continental needle telegraphy in which the message is
-transmitted by the movements of an index normally vertical, but
-oscillating to one side or the other under the influence of the current,
-the latter being controlled by the transmitter of the message, the left
-hand swings of the needle are interpreted as dots, the right hand as
-dashes.
-
-This system enables one alphabet to be translated into the other, or
-virtually one alphabet answers for both Morse and needle transmitters.
-
-There are two principal telegraphic alphabets, the American Morse and
-the International codes. They are very similar, their essential
-distinction being that spaces are used in the American code, while they
-are excluded from the International code.
-
-In the American Morse system the message is now universally received by
-sound. (See Sounder--Sound Reading.)
-
-
-20   STANDARD ELECTRICAL DICTIONARY.
-
-
-The two codes or telegraphic alphabets are given here.
-
-THE INTERNATIONAL ALPHABET.
-  Parenthesis,             - . - - . -
-  Understand,              ... - .
-  I don't understand,      ..-- ....--..
-  Wait,                    .-. . .
-  Erase,                   ...   ...   ...
-  Call signal,             -.-.-.-
-  End of message,          .-.-.-.
-  Cleared out all right,   .-..-..-.
-  A  .-    L  .-..  W  .--
-  B  -...  M  --    X  -..-
-  C  -.-.  N  -.    Y  -.--
-  D  -..   O  ---   Z  --..
-  E  .     P  .--.
-  F  ..-.  Q  --.-  Ch ----
-  G  --.   R  .-.   �  .-.-
-  H  ....  S  ...   �  ---.
-  I  ..    T  -     �  ..--
-  J  .---  U  ..-   �  ..-..
-  K  -.-   V  ...-  �  --.--
-
-NUMERALS
-  1  .----  4  ....-  8  ---..
-  2  ..---  5  .....  9  ----.
-  3  ...--  6  -....  0  -----
-            7  --...
-
-
-[Transcriber's note: The original image of the dot/dash pattern is somewhat
-ambiguous. Since there may be differences from contemporary specifications,
-the original image is included.]
-
-[Image of page 20: THE INTERNATIONAL ALPHABET.]
-
-
-21  STANDARD ELECTRICAL DICTIONARY.
-
-PUNCTUATION, ETC.,
-
-  Period (.)         ...   ...
-  Comma (,)          .-.-.-
-  Query(?)           ..--..
-  Exclamation (!)    --..--
-  Apostrophe (')     .----.
-  Hyphen (-)         -....-
-  Fresh paragraph,   .-.-..
-  Inverted commas,   -..-.
-
-THE AMERICAN ALPHABET.
-  A  .-       L  ----(Continuous)  W  .--
-  B  -...     M  --                X  .-..
-  C  ..s.     N  -.                Y  ..s..
-  D  -..      O  .s.               Z  �.
-  E  .        P  .....
-  F  .-.      Q  ..-.              Ch ----
-  G  --.      R  .s..              �  .-.-
-  H  ....     S  ...               �  ---.
-  I  ..       T  -                 �  ..--
-  J  - . - .  U  ..-               �  ..-..
-  K  -.-      V  ...-              �  --.--
-
-NUMERALS
-  1  .--.    4  ....-     8  -....
-  2  ..-..   5  ---       9  -..-
-  3  ...-.   6  ... ...   0  -----(Continuous)
-             7  --..
-
-[Transcriber's Note: The "s" in the American Code indicates a "space". I
-leave the following to the reader's imagination. See the original
-image.]
-
-Comma (,)
-Semicolon (;)
-Colon (:)
-Colon Dash (:~)
-Period (.)
-Interrogation (?)
-Exclamation (!)
-Dash (-)
-Hyphen (-)
-Pound Sterling (�)
-Shilling Mark ( )
-
-
-[Image of page 21: THE AMERICAN ALPHABET.]
-
-
-22   STANDARD ELECTRICAL DICTIONARY.
-
-
-[Transcriber's Note: I leave these to the reader's imagination. See the
-following original image.]
-
-Dollars ($)
-Decimal Point (.)
-Cents (c)
-Paragraph ()
-Pence (d.)
-Fractional Mark (--)
-Capitalized Letter
-Italics or Underline
-Colon followed by Quotation :"
-Parenthesis (   )
-Brackets [   ]
-Quotation Marks " "
-Quotation within a Quotation " ' ' "
-
-[Image of page 22: THE AMERICAN ALPHABET.]
-
-The principal differences in the two codes are the use of spaces in the
-American code, such being excluded from the International code. This
-affects the letters C, R, Y, & Z.
-
-The following diagram, due to Commandant Perian, enables the letter
-corresponding to an International code sign to be rapidly found with the
-exception of R.
-
-             <- dot       start         dash   ->
-               /                           \
-              E                             T
-         /          \                /             \
-       I              A             N                M
-    /    \          /    \        /    \         /      \
-   S      U        R      W       D      K       G       O
- /  \    / \     / \    /  \    /  \     /  \    /  \    /  \
-H   V   F   U   L   A   P   J   B   X   C   Y   Z   Q   �   CH
-
-Fig. 10. Diagram for translating the Morse Alphabet.
-
-
-In order to find what letter corresponds to a given sign, starting from
-the top of the diagram, each line is traced down to a bifurcation,
-taking the right hand line of each bifurcation for a dash, and the left
-hand line for a dot, and stopping when the dots and dashes are used up.
-Thus, for example,
-
-the signal -.- -   leads us to the letter d,
-
-the signal - - - - to the letter j and so on.
-
-
-23  STANDARD ELECTRICAL DICTIONARY.
-
-
-Alternating. adj.
-Term descriptive of a current changing periodically in
-direction. (See Current, Alternating.)
-
-Synonyms--Oscillatory--periodic--undulatory--harmonic.
-
-
-Alternating Current Arc.
-The arc produced by the alternating current. It presents several
-peculiarities. With an insufficient number of alternations per second it
-goes out. As the carbons wear away equally it is adopted for such lamps
-as the Jablochkoff candle, (see Candle, Jablochkoff). As no crater is
-formed the light is disseminated equally both up and down. For this
-reason to get full downward illumination a reflector is recommended.
-
-
-Alternating Current System.
-A system of electric distribution employing the alternating current. For
-transmission in the open air or in conduits a high potential circuit is
-used, from 1,000 to 10,000 volts being maintained at the central
-station. Two leads unconnected at the end lead from the station. Where
-current is desired a converter or transformer (see Converter) is placed,
-whose primary is connected to the two leads bridging the interval
-between them. From the secondary the house leads are taken with an
-initial potential in some cases of 50 volts. The converters are thus all
-placed in parallel. By law or insurance rules the converters are
-generally kept outside of buildings. Where no secondary current is taken
-from the converters very little primary current passes them on account
-of their counter-electromotive force. As more secondary current is taken
-the primary increases and this accommodation of one to the other is one
-of the interesting and valuable features. Street lamps are sometimes
-connected in series. Each lamp in such case is in parallel with a small
-coil with iron core. While the lamp is intact little current passes
-through the coil. If the lamp is broken, then the converter impedes the
-current by its spurious resistance, q. v., just enough to represent and
-replace the resistance of the extinguished and broken lamp filament.
-(See Meter, Alternating Current; Motor, Alternating Current.)
-
-
-Alternation.
-The change in direction of a current. The number of such changes is
-expressed as number of alternations; thus a current may have a frequency
-of 500 or 20,000 alternations per second.
-
-[Transcriber's note: One alternation per second is now called one hertz.]
-
-
-Alternation, Complete.
-A double alternation; a change from one direction
-to the other and back again to the original phase. A symbol derived from
-its graphic representation by a sine curve is used to indicate it. The
-symbol is  ~
-
-
-24   STANDARD ELECTRICAL DICTIONARY.
-
-
-Alternative Path.
-A second path for a current appearing as a disruptive
-discharge. Where two paths are offered the discharge, as it is of
-alternating or oscillatory type, selects the path of least
-self-induction. Thus a thick bar of copper, with no air gap, may be
-abandoned by the current in favor of a small iron wire with an air gap,
-but which has less self-induction.
-
-The lightning arresters, q. v., for the protection of telegraph offices
-are sometimes based on these principles. A path of very high resistance
-but of small self-induction is offered between the line and the earth.
-This the lightning discharge selects in preference to the instruments
-with their iron cores, as the latter are of very high self-induction.
-
-
-Alternator.
-A dynamo electric generator supplying an alternating current. (See
-Dynamo, Alternating Current.)
-
-Synonym--Alternating current generator or dynamo.
-
-
-Alternator, Constant Current.
-An alternating current dynamo supplying a current of unvarying virtual
-amperage. Alternators of this type are constructed with an armature of
-high self-induction. Sometimes fine winding contained in deep peripheral
-notches in the core-discs is employed to magnify the self-induction.
-Such generators are employed for series lighting, especially
-arc-lighting.
-
-
-Aluminum.
-A metal; one of the elements; symbol: Al.
-Atomic weight: 27.4. Equivalent: 9.13. Valency: 3.
-Specific gravity: 2.6. It is a conductor of electricity.
-Relative resistance annealed, (Silver = 1)  1.935
-Specific resistance at 0�C (32�F.)    2.912 microhms
-
-Resistance of a wire at 0�C  (32�F.)
-a) 1 foot long, weighing 1 grain,     0.1074 ohms.
-b) 1 foot long, 1/1000 inch thick,   17.53     "
-c) 1 meter long, weighing 1 gram,     0.0749   "
-d) 1 meter long, 1 millimeter thick   0.03710  "
-Resistance of a 1-inch cube at 0�C (32�F.) 1.147 microhms
-Electro-chemical equivalent.    .0958 (hydrogen == .0105)
-
-
-25  STANDARD ELECTRICAL DICTIONARY.
-
-
-Amalgam.
-(a) A combination or alloy in which one of the constituents is mercury.
-Usually the term is applied to an alloy of a single metal with mercury.
-Some metals readily form amalgams; such metals are: Gold, zinc, silver,
-lead and others; some, such as platinum and iron, form amalgams only
-under exceptional circumstances.
-
-(b) The word is also applied to compositions for application to the
-cushions of frictional electric machine in which cases it is often a
-misnomer. True amalgams used for this purpose are made as follows:
-
-(a) Tin, 1 part;  Zinc, 1 part;  Mercury, 2 parts (Kienmayer).
-(b) Tin, 2 parts; Zinc, 3 parts.
-(c) Tin, 3 parts; Zinc, 5 parts; Mercury, 4 parts.
-(d) Zinc, 1 part: Mercury, 4 parts; Mercury, 9 parts.  [sic]
-
-The tin, if such is used, (formula a, b and c) is first melted, the zinc
-is added in successive portions. The mercury, which must be heated, is
-slowly poured into the melted alloy after removal of the latter from the
-fire, and the mixture, while making, is constantly stirred. It is kept
-stirred or rubbed in a mortar until cold. Sometimes it is poured into
-water and kept in constant agitation until cold. It is thus obtained in
-a granular condition, and is pounded in a mortar until reduced to
-powder. It must be dried and kept in tightly stopped bottles and is
-applied to the cushions after they have been greased. It is to be
-noticed that it is said that alloy (d) requires no pulverization beyond
-constant rubbing in a mortar as it cools. Sometimes the amalgam is
-shaken about in a wooden tray with chalk while cooling. The action of
-amalgams is not very clearly understood. Some claim that there is a
-chemical action, others that they simply act as conductors, others that
-they are more highly negative to the glass than the leather of the
-cushions.
-
-Graphite or sulphide of tin (mosaic gold) are sometimes used to coat the
-cushions; it is these that are sometimes incorrectly called amalgams.
-
-
-Amalgamation.
-The application of mercury to a metal with which it forms an amalgam, or
-with which it amalgamates. Battery zincs are amalgamated in two ways. In
-the immersion method, the plate is dipped into an acid solution of
-mercuric chloride or nitrate. The latter is best. In the direct
-application method the plate is first wet all over with dilute acid and
-a little mercury is dropped upon it and is rubbed over the surface with
-a rag or, what is better, with a piece of galvanized iron. A very little
-mercury answers the purpose. The whole surface of the plate should be
-left as bright as silver. (See Action, Local.)
-
-
-Amber.
-Amber is a fossil resin, supposed to be a product of the extinct Pinites
-Succinifer and other coniferous trees. Most of it is gathered on the
-shores of the Baltic between Koenigsberg and Memel. It is also found in
-small pieces at Gay Head, Mass., and in New Jersey green sand. It is
-found among the prehistoric remains of the Swiss Lake dwellers. When
-rubbed with a cloth it becomes excited with negative electricity. The
-Greek word for it is electron, which gave the name electricity to the
-modern science. Thales of Miletus, 600 B. C., and Theophrastus, about
-300 B. C., both mention its electric properties or power of attracting
-small objects when rubbed.
-
-
-26   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ammeter.
-The commercial name for an ampere-meter, an instrument designed
-to show by direct reading the number of amperes of current which are
-passing through a circuit.
-
-A great variety of ammeters have been invented, based on different
-principles. The definitions following this one give some idea of the
-lines of construction followed.
-
-Synonym--Ampere meter.
-
-
-Ammeter, Ayrton's.
-A direct reading instrument for measuring current intensity.
-
-A solenoid receives the current. In the axis of the solenoid an iron
-tube is suspended by a long spiral spring that passes down within it,
-and the upper end of which spring is fastened to the glass top of the
-instrument. The tube is provided with proper guides so as to maintain a
-vertical position, and is free to rotate. Its upper end carries an
-index.
-
-The whole operates as a magnifying device. A slight longitudinal
-displacement of the tube causes it to rotate through a considerable
-angle by the action of the spring. By properly proportioning the parts,
-the angle of displacement of the index is directly proportional to the
-current between 15� and 270� angular displacement.
-
-The same instrument is wound for use as a volt-meter.
-
-Its principal fault is its restricted range.
-
-
-Ammeter, Commutator.
-A commutator ammeter is one whose windings consist of separate strands,
-each of any desired number of turns, and provided with a commutating
-attachment for throwing them into series or into parallel as desired.
-The essential condition is that all the wires shall be of equal
-resistance and of equal number of turns. Such an instrument can be used
-for heavy or light currents. Two sets of graduations are marked on its
-scale if it is a calibrated instrument. (See Calibration.) Commutator
-volt-meters are constructed on the same principle.
-
-
-Ammeter, Cunynghame's.
-A modification of the Siemens' electro-dynamometer. (See
-Electro-dynamometer, Siemens'.) An electro-magnet with very massive core
-is excited by the current. As the core is of small reluctance the
-strength of the magnet is nearly proportional to the current strength.
-Between the poles of the magnet a soft iron armature or induced magnet
-is pivoted. It carries a pointer so adjusted that when the axis of the
-soft iron magnet is at an angle of about 30� with the line joining the
-poles of the electro-magnet the pointer will indicate zero.
-
-The soft iron armature is so massive that the magnetism induced in it is
-proportional to the strength of the electro-magnet. Hence the couple
-exerted by the electro-magnet on the pivoted armature will be
-proportional to the square of the current.
-
-The armature is retained in place by a spiral spring lying in line with
-its axis of rotation. The instrument is operated as a zero reading
-instrument. The current is passed through it. The needle is deflected;
-it is brought back to zero by turning a milled head which twists the
-spring. The current will be proportional to the square root of the angle
-of displacement of the milled head. A scale with index is provided,
-giving directly the square roots of the angle over which the pointer is
-moved.
-
-The same instrument is wound for use as a volt-meter.
-
-
-27  STANDARD ELECTRICAL DICTIONARY.
-
-
-Ammeter, Eccentric Iron Disc.
-This ammeter comprises a cylindrical electro-magnet excited by the
-current to be measured. A disc of iron free to rotate is suspended on
-pivots below it. A piece is cut off the disc at one part of its
-periphery so as to give more metal to one side than to the other. In its
-zero position this portion of the disc swings towards the magnet. As the
-latter is more and more excited the other or more projecting portion of
-the disc turns towards it, being attracted like an armature, and moves
-against the force of gravity, the disc rotating. An index attached to
-the disc swings over the face of a graduated scale. The disc is so
-counterpoised that in its natural position the index points to zero.
-
-
-Ammeter, Electro-magnetic.
-An ammeter depending for its working upon the action of an
-electro-magnet, which is excited by the current to be measured.
-
-
-Ammeter, Gravity.
-An ammeter whose hand or index is drawn into the zero position by
-gravity, and whose displacement therefrom is produced by the action of
-the current to be measured.
-
-
-Fig. 11. GRAVITY SOLENOID AMMETER.
-
-
-Ammeter, Magnetic Vane.
-A fixed plate of soft iron is placed within a coil. Facing it is a
-second disc free to move or swing on an axis. When the field is excited
-the two repel each other because like polarity is induced in each, and
-the motion of the movable disc indicates the strength of the current.
-The same instrument is wound for high resistance and constitutes a
-Magnetic Vane Voltmeter.
-
-
-28   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ammeter, Magnifying Spring.
-A solenoid ammeter in which a spiral spring is used to convert the
-longitudinal motion of the armature or movable core into a rotary motion
-(see Ammeter, Ayrton's) and magnify the apparent range of motion.
-
-
-Ammeter, Permanent Magnet.
-An ammeter with a magnetic field produced by a permanent magnet.
-
-
-Ammeter, Solenoid.
-An ammeter in which the attraction, when a current is passing through
-it, exerted by a hollow coil of wire upon an iron bar or tube in line
-with its axis, is utilized to indicate the strength of current. The bar
-is drawn into the coil to different extents proportional to the
-attraction. As an example see Ammeter, Ayrton's, and cut of Gravity
-Ammeter.
-
-
-Ammeter, Spring.
-An ammeter in which the part moved by the current is controlled or
-brought to the zero position by a spring.
-
-
-Ammeter, Steel Yard.
-A solenoid ammeter in which the solenoid core is suspended vertically
-from the short end of a steel yard fitted with a sliding weight. The
-current passes through the solenoid coil and attracts or draws downwards
-the coil. A sliding weight is moved in and out on the long steel-yard
-arm which is graduated for amperes. In use the weight is slid out until
-the arm is in equipose; the divisions give the amperes.
-
-
-Fig. 12. STEEL YARD AMMETER.
-
-
-29  STANDARD ELECTRICAL DICTIONARY.
-
-
-Ammunition Hoist, Electric.
-An apparatus for use on ships for hoisting ammunition to the guns by an
-electric elevator. The characteristic feature of it is that a constant
-motion of the switch or handle is required to keep it in action. If the
-operator is shot so as to be incapacitated from taking charge of the
-switch, the hoist stops until another is assigned to it.
-
-
-Amperage.
-Current intensity expressed in amperes, as an amperage of ten amperes.
-
-
-Ampere.
-The practical unit of electric current strength. It is the measure of
-the current produced by an electro-motive force of one volt through a
-resistance of one ohm. In electric quantity it is the rate of one
-coulomb per second. It is one-tenth the absolute C. G. S. unit of
-current strength. Its best analogy is derived from water. Assuming the
-electric current to be represented by a current of water, the pressure,
-head, or descent producing such current would be the electro-motive
-force. The current might be measured in gallons (or other unit) passed
-per second. In the analogy these gallons would be coulombs. But it might
-be measured by reference to a standard stream, as for instance, the
-stream which would pass through a hole an inch square under a given
-head, say six inches of water. This unit is the miner's inch, and is the
-exact analogy of the ampere. A current of water may flow at the rate of
-so many miner's inches, just as a current of electricity may flow at the
-rate of so many amperes. In neither case it will be noted is there any
-reference to time. "An ampere per second" is a redundant expression, and
-means no more than "an ampere"; an "ampere-second," on the other hand,
-is a coulomb. The number of coulombs passed per second gives the amperes
-of current.
-
-For value of ampere, see Coulomb.
-
-[Transcriber's note: The SI definition of an ampere: A current in two
-straight parallel conductors of infinite length and negligible
-cross-section, 1 metre apart in vacuum, would produce a force equal to
-2E-7 newton per metre of length.]
-
-
-
-Fig. 13. THE MINER'S INCH AS AN ANALOGY FOR THE AMPERE.
-
-
-30   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ampere, Arc.
-A conductor bent into the arc of a circle, and employed in measuring the
-electric current by the electric balance.
-
-
-Ampere-currents.
-The currents assumed to be the cause of magnetism. (See Magnetism,
-Ampere's Theory of.)
-
-
-Ampere-feet.
-The product of amperes of current by the length, in feet, of a conductor
-passing such current. It may be in empiric calculations of dynamo or
-motor construction, but is little used. One ampere-foot is a current of
-one ampere passing through one foot length of a conductor, or one-tenth
-ampere through ten feet, and so on.
-
-
-Ampere-hour.
-The quantity of electricity passed by a current of one ampere in one
-hour. It is used by electric power and lighting companies as the unit of
-energy supplied by them, because they maintain a constant potential
-difference in their leads, so that only the amperes and hours need
-measuring or recording to give the energy, viz. : volt-ampere-hours.
-The same unit is applied to batteries to indicate their potential
-energy, because they also are assumed to be of constant voltage or
-electro-motive force.
-
-
-Ampere-meters.
-The product of amperes of current by the length, in meters, of a
-conductor carrying such current. One ampere-meter is a current of one
-ampere passing through one meter of a conductor.
-
-The term must not be confused with the identically spelled Ampere-meter,
-a synonym for Ammeter.
-
-
-Ampere-minute.
-The quantity of electricity passed by a current of one ampere in one
-minute; sixty coulombs.
-
-
-Ampere Ring.
-A conductor forming a ring or circle used in electric balances for
-measuring currents. (See Balance, Ampere.)
-
-
-Ampere-second.
-The quantity of electricity passed by a current of one ampere in one
-second; the coulomb, q. v.
-
-
-Amperes, Lost.
-In a shunt or compound-wound dynamo, part of the total amperes of
-current produced in the armature coils go through the shunt, and hence,
-do not appear in the outer circuit. S. P. Thompson has proposed the term
-"lost amperes" for this portion of the current.
-
-
-Ampere's Memoria Technica.
-An expression of the effect of a current on a magnetic needle. If we
-imagine the observer in the line of the current and facing the magnetic
-needle, the current entering by his feet and leaving by his head, the
-north pole is deflected to his left.
-
-
-31  STANDARD ELECTRICAL DICTIONARY.
-
-
-Ampere-turns.
-The amperes of current supplied to a magnet coil multiplied by the
-number of turns the current makes in the coil. If the coil is wound two
-or three in parallel, the virtual turns by which the amperes are
-multiplied are one-half or one-third the actual turns of wire.
-
-Synonym--Ampere Windings.
-
-
-Ampere-turns, Primary.
-The ampere-turns in the primary coil of an induction coil or
-transformer.
-
-
-Ampere-turns, Secondary.
-The ampere-turns in the secondary coil of an induction coil or
-transformer.
-
-
-Amplitude of Waves.
-Waves are distinguished by length and amplitude. The latter, in the case
-of transverse waves, such as those of water and of the ether, correspond
-with and measure the height from lowest to highest point, or from valley
-to summit of the waves in question. In the case of longitudinal waves,
-such as those of the air, due to sounding bodies, the ratio of degree of
-rarefaction to degree of condensation existing in the system is the
-amplitude. The latter can be graphically represented by a sinuous line,
-such as would represent the section of a transverse wave. Ether waves
-are produced by heated bodies and by electro-magnetic impulses, as in
-the discharge of the Leyden jar.
-
-The amplitude of a wave, other things being equal, is the measure of its
-intensity. Thus, the louder a sound the greater is the amplitude of the
-system of waves to which it is due. The same applies to ether waves,
-whether they are perceived in the electro-magnetic, light, or
-heat-giving modification. As the amplitude of ether waves cannot be
-accurately known, amplitude is a relative term and is not stated
-generally in any absolute unit.
-
-
-Analogous Pole.
-One of the elements of a pyro-electric crystalline substance, such as
-tourmaline. When heated, such bodies acquire electrical properties. If
-of such crystalline form that they are differently modified at the ends
-of their crystalline axis, by hemihedral modifications, the ends may be
-differently affected. One end may show positive electricity when the
-temperature is rising, and negative when falling. Such end is then
-called the analogous pole. The opposite end presents, in such cases, the
-opposite phenomena; becoming negative when the temperature is rising,
-and becoming positive when it is falling; such end is called the
-antilogous pole.
-
-
-Analysis.
-The determination of the elements of a case. It may be chemical, and
-consist in finding what a substance consists of; it may be mathematical,
-and consist in determining the unknown quantities in a problem; or it
-may belong to other branches of science. The term has a very extended
-application. Where the constituents are only determined in kind it is
-called qualitative analysis; where their quantity or percentage is
-ascertained it is called quantitative analysis.
-
-
-32   STANDARD ELECTRICAL DICTIONARY.
-
-
-Analysis, Electric.
-Chemical analysis by electrolytic methods. (See Electrolytic  Analysis.)
-
-
-Analyzer, Electric.
-An apparatus used in investigations on electric ether waves. It consists
-of a series of parallel metallic wires. When the electric waves have
-been polarized, the analyzer will only permit them to go through it
-intact, when the plane of vibration of the waves is parallel to its
-wires.
-
-
-Anelectrics.
-(a) Bodies which do not become electrified by friction; a term
-introduced by Gilbert, now little used, as all bodies develop
-electricity under proper conditions by contact action; the reverse of
-idioelectrtics.
-
-(b) Also a conductor of electricity, the reverse of a dielectric, q. v.
-(See Conductor.)
-
-It will be seen that Gilbert's anelectrics were, after all, the same as
-the modern anelectrics, i.e., conductors.
-
-
-Anelectrotonus.
-A term used in medical electricity or electro-therapeutics to indicate
-the deceased functional activity induced in a nerve by the proximity of
-the anode of an active electric circuit completed through the nerve. The
-converse of Kathelectrotonus.
-
-
-Angle of Declination.
-The angle of error of the magnetic needle or compass, measuring the
-extent of its deviation from the meridian in any locality. It is the
-angle between the plane of the magnetic axis of a magnetic needle free
-to take its natural position, and the geographical meridian, the needle
-being counterpoised if necessary, so as to hold an absolutely horizontal
-position. The deviation is expressed as being east or west, referring
-always to the north pole. (See Magnetic Elements.)
-
-Synonym--Variation of the Compass.
-
-[Transcriber's note:  See Agonic Line.]
-
-
-Angle of the Polar Span.
-In a dynamo or motor the angle subtended by the portion of a pole piece
-facing the armature, such angle being referred to the centre of the
-cross-section of the armature as its centre.
-
-
-STANDARD ELECTRICAL DICTIONARY.   33
-
-
-Angular Velocity.
-The velocity of a body moving in a circular path, measured with
-reference to the angle it passes over in one second multiplied by the
-radius and divided by the time. A unit angle is taken (57�.29578 =
-57� 17' 44".8 nearly) such that it is subtended by a portion of the
-circumference equal in length to the radius. Hence, the circumference,
-which is 360�, is equal to 2*PI*unit angle, PI being equal to 3.1416--.
-"Unit angular velocity" is such as would in a circle of radius = 1
-represent a path = 1, traversed in unit time = 1 second. If the radius
-is r and the angle passed over is theta, the distance is proportional to
-r*theta; if this distance is traversed in t seconds the angular velocity
-is theta / t. The angular velocity, if it is multiplied by r, theta
-expressing a distance, will give the linear velocity. The dimensions of
-angular velocity are an angle (= arc / radius) / a Time = (L/L)/T =
-(T^-1).
-
-The velocity expressed by the rate of an arc of a circle of unit radius,
-which arc subtends an angle of 57� 17' 44".8, such arc being traversed
-in unit time, is unit angular velocity.
-
-
-Animal Electricity.
-Electricity, notably of high tension, generated in the animal system, in
-the Torpedo, Gymnotus and Silurus. The shocks given by these fish are
-sometimes very severe. The gymnotus, or electric eel, was elaborately
-investigated by Faraday. It has the power of voluntarily effecting this
-discharge. There is undoubtedly some electricity in all animals. The
-contact of the spinal column of a recently killed frog with the lumbar
-muscles produces contraction, showing electric excitement. Currents can
-be obtained from nerve and muscle, or from muscle sides and muscle cut
-transversely, in each case one thing representing positive and the other
-negative elements of a couple.
-
-
-Angle of Inclination or Dip.
-The angle which the magnetic axis of a magnet, which magnet is free to
-move in the vertical plane of the magnetic meridian, makes with a
-horizontal line intersecting such axis. To observe it a special
-instrument, the dipping compass, inclination compass, dipping needle, or
-dipping circle, as it is called, is used. (See Elements, Magnetic,
---Dipping Needle,--Compass, Inclination.)
-
-
-Angle of Lag.
-The angle expressing the displacement of the magnetic axis of the
-armature core of a dynamo in the direction of its rotation. (See Lag.)
-Lag is due to the motion of the armature core.
-
-
-Angle of Lead.
-The angle expressing the displacement in the direction of rotation of
-the armature of a dynamo which has to be given the brushes to compensate
-for the lag. (See Lag.) This is positive lead. In a motor the brushes
-are set the other way, giving a negative angle of lead or angle of
-negative lead.
-
-
-Anion.
-The electro-negative element or radical of a molecule, such as oxygen,
-chlorine or the radical sulphion. (See Ions.) It is the portion which
-goes to the anode, q.v., in electrolytic decomposition.
-
-
-34   STANDARD ELECTRICAL DICTIONARY.
-
-
-Anisotropic. (adj.)
-Unequal in physical properties, as in conduction and specific inductive
-capacity, along various axes or directions. An anisotropic conductor is
-one whose conductivity varies according to the direction of the current,
-each axis of crystallization in a crystalline body marking a direction
-of different conductivity. An anisotropic medium is one varying in like
-manner with regard to its specific inductive capacity. In magnetism an
-anisotropic substance is one having different susceptibilities to
-magnetism in different directions. The term is applicable to other than
-electric or magnetic subjects.
-
-Synonym--AEolotropic.
-
-
-Annealing, Electric.
-Annealing by the heat produced by the passage of the electric current
-through the body to be annealed. The object is clamped or otherwise
-brought into a circuit, and a current strong enough to heat it to
-redness, or to the desired temperature is passed through it.
-
-
-Annunciator.
-An apparatus for announcing a call from any place to another, as from a
-living-room to an office in a hotel, or for announcing the entering of
-any given room or window in a building protected by a burglar alarm.
-
-A usual system comprises for each annunciator an electro-magnet. Its
-armature is normally held away from its poles by a spring, and when in
-that position a latch connected to the armature holds a little shutter.
-When by a push-button or other device a current is sent through a
-circuit which includes the electro-magnet the armature is attracted,
-this releases the latch and the shutter drops. In dropping it displays a
-number, letter or inscription which indicates the locality of the
-push-button or other circuit-closing device. Often annunciators are
-connected in circuit with a bell.
-
-
-Fig. 14. ANNUNCIATOR.
-
-
-35  STANDARD ELECTRICAL DICTIONARY.
-
-
-Annunciator Clock.
-A clock operating an annunciator by making contact at determined times.
-
-Annunciator Drop.
-The little shutter which is dropped by some forms of annunciators, and
-whose fall discloses a number, character or inscription, indicating
-whence the call was sent.
-
-
-Fig. 15. DROP ANNUNCIATOR.
-
-
-Fig. 16. ANNUNCIATOR DETACHING MECHANISM.
-
-
-Annunciator, Gravity Drop.
-An annunciator whose operations release shutters which fall by gravity.
-
-
-Annunciator, Needle.
-A needle annunciator is one whose indications are given by the movements
-of needles, of which there is usually a separate one for each place of
-calling.
-
-
-Annunciator, Swinging or Pendulum.
-An annunciator which gives its indications by displacing from its
-vertical position a pendulum or vertically suspended arm.
-
-
-36   STANDARD ELECTRICAL DICTIONARY.
-
-
-Anodal Diffusion.
-A term in electro-therapeutics; the introduction of a medicine into the
-animal system by using a sponge-anode saturated with the solution of the
-drug in question. On passing a current the desired result is secured by
-cataphoresis, q. v.
-
-
-Anode.
-The positive terminal in a broken metallic or true conducting circuit;
-the terminal connected to the carbon plate of a galvanic battery or to
-its equivalent in case of any other generator. In general practice it is
-restricted to the positive terminal in a decomposition or electrolytic
-cell, such as the nickel anode in a nickel-plating bath or the anode of
-platinum in a gas voltameter. It is the terminal out of or from which
-the current is supposed to flow through the decomposition cell. In
-electro-therapeutics the term is used simply to indicate the positive
-terminal. In an electrolytic cell the electro-negative substance or
-anion goes to the anode. Hence, it is the one dissolved, if either are
-attacked. The nickel, copper or silver anodes of the electroplater
-dissolve in use and keep up the strength of the bath. The platinum anode
-in a gas voltameter is unattacked because the anion cannot act upon it
-chemically.
-
-
-Anodic Closure Contraction.
-A physiological change in a living subject produced by the closing of
-the electric current; the muscular contraction which takes place beneath
-the anode applied to the surface of the body when the circuit is closed,
-the kathode being applied elsewhere; it is due, presumably, to direct
-action on the motor nerve. It is a term in electro-therapeutics. It is
-the converse of anodic opening contraction, q. v. An abbreviation A. C.
-C. is often used to designate it.
-
-
-Anodic Duration Contraction.
-A term in electro-therapeutics. On the opening or closing of an electric
-circuit, the anode of which is placed over a muscle, a contraction is
-observed (see Anodic Closure Contraction--Anodic Opening Contraction).
-The above term is used to designate the duration of such contraction. An
-abbreviation A. D. C. is often used to designate it.
-
-
-Anodic Opening Contraction.
-The converse of Anodic Closure Contraction, q. v.; it is the contraction
-of living muscle beneath or near the anode where the circuit, including
-such anode and the body in its course, is closed; a physiological
-phenomenon observed in electro-therapeutics to which branch of science
-the term belongs. An abbreviation A. O. C. is often used to designate
-it.
-
-
-Anodic Reactions.
-A term in electro-therapeutics; the diagnosis of disease by the actions
-of the tissue near the anode of a circuit.
-
-
-Anti-Induction Conductor.
-A conductor constructed to avoid induction effects in the conducting
-element. Many kinds have been made. A tubular metal shield or envelope
-which may be grounded will protect an enclosed conductor to some extent.
-Or the conductor may be a double wire twisted around itself, one branch
-being used for the regular and the other for the return circuit, thus
-constituting a closed metallic circuit. The inductive effects are due to
-interrupted or varying currents in neighboring wires and circuits. Many
-anti-induction conductors have been invented and patented.
-
-
-37  STANDARD ELECTRICAL DICTIONARY.
-
-
-Anti-magnetic Shield.
-In general terms a hollow screen of soft iron designed to protect any
-mass of steel behind or enclosed by it from magnetization by any magnet
-near it, such as a dynamo field magnet. This it does by concentrating
-the lines of force within its own mass, so that the space within it or
-enclosed by it is comparatively free from lines of force. It is often
-applied to watches, and is virtually an iron case in which they are
-enclosed.
-
-Antimony.
-A metal, one of the elements, atomic weight, 122:
-equivalent, 40.6 and 24.4; valency, 3 and 5;
-specific gravity, 6.8.
-It is a conductor of electricity.
-Relative resistance, compressed (silver = 1),   23.60
-Specific resistance,   35.50 microhms.
-Resistance of a wire,
-(a) 1 foot long, weighing 1 grain,       3.418 ohms.
-(b) 1 foot long, 1/1000 inch thick,    213.6     "
-(c) 1 meter long, weighing 1 gram,       2.384   "
-(d) 1 meter long. 1 millimeter thick,    0.4521  "
-
-Resistance of a 1-inch cube,   13.98 microhms.
-
-Approximate percentage resistance per degree C.
-(1.8� F. at 20� C. 88� F.)   0.389 per cent.
-
-Elcctro-chemical equivalent (hydrogen = .0105)  .2560
-(See Thermo-Electric Series.)
-
-
-Anvil.
-An intermittent contact, or "make and break" of the current is sometimes
-produced by directly pressing a key down upon a metallic surface, the
-two being terminals of the circuit. The surface or stud on which such
-pressure is produced is called the anvil. The ordinary telegraph key,
-which makes a contact by the pressure of the operator's fingers does it
-by making a contact between a contact piece upon the front end of the
-key and the anvil. In the induction coil the anvil is also found. Thus
-in the cut representing the end of an induction coil and its circuit
-breaker in which O and O' and P and P' represent the secondary circuit
-terminal connections A is the core of soft iron wires, h is the anvil;
-the hammer when resting upon it so as to be in contact closes the
-circuit. When the current coming from the primary to the post i, passes
-through the hammer and anvil h, and emerges by m, it magnetizes the
-core; this attracts the hammer, which is made of or is armed with a mass
-of iron. This breaks the circuit. The hammer falls at once on the anvil,
-again making the circuit, and the action is repeated with great
-rapidity. Hammer and anvil or key and anvil connections should be made
-of platinum.
-
-
-Fig. 17. INDUCTION COIL CIRCUIT BREAKER.
-
-
-38   STANDARD ELECTRICAL DICTIONARY.
-
-
-A. O. C.
-Abbreviation for Anodic Opening Contraction, q. v.
-
-
-Aperiodic. adj.
-In an oscillating apparatus, or in the oscillating member of apparatus,
-the fact of having no reference to time of vibration; dead-beat.
-
-Synonym. Dead-beat.
-
-
-39  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 18. ARAGO'S DISC.
-
-
-Arago's Disc.
-An apparatus consisting of a disc of copper mounted horizontally, or on
-a vertical spindle, and so arranged as to be susceptible of rapid
-rotation. Immediately over it, and best with a pane of glass
-intervening, a magnetic needle is mounted on a pivot directly over the
-axis of the disc. If the disc is rotated the lines of force of the
-magnet are cut by it, and consequently currents are produced in the
-copper. These currents act upon the needle and cause it to rotate,
-although quite disconnected. It is advisable for the needle to be strong
-and close to the disc, which should rotate rapidly.
-
-
-Arc v.
-To form a voltaic arc.
-
-
-Arc, Compound.
-A voltaic arc springing across between more than two electrodes.
-
-
-Arc, Metallic.
-The voltaic arc produced between terminals or electrodes of metal. The
-characteristics of such arc as contrasted with the more usual arc
-between carbon electrodes are its greater length for the same
-expenditure of energy, its flaming character and characteristic colors
-due to the metals employed. It is sometimes, for the latter reason, used
-in spectroscopic investigations.
-
-
-Arc Micrometer.
-A micrometer for measuring the distance between the electrodes of a
-voltaic arc.
-
-
-Arc, Simple.
-A voltaic arc produced, as usual, between only two electrodes.
-
-
-40   STANDARD ELECTRICAL DICTIONARY.
-
-
-Arc, Voltaic.
-The voltaic arc is the arc between two carbon electrodes slightly
-separated, which is produced by a current of sufficient strength and
-involving sufficient potential difference. The pencils of carbon are
-made terminals in a circuit. They are first placed in contact and after
-the current is established they are separated a little. The current now
-seems to jump across the interval in what sometimes appears an arch of
-light. At the same time the carbon ends become incandescent. As regards
-the distance of separation with a strong current and high electro-motive
-force, the arc may be several inches long.
-
-The voltaic arc is the source of the most intense heat and brightest
-light producible by man. The light is due principally to the
-incandescence of the ends of the carbon pencils. These are differently
-affected. The positive carbon wears away and becomes roughly cupped or
-hollowed; the negative also wears away, but in some cases seems to have
-additions made to it by carbon from the positive pole. All this is best
-seen when the rods are slender compared to the length of the arc.
-
-It is undoubtedly the transferred carbon dust which has much to do with
-its formation. The conductivity of the intervening air is due partly,
-perhaps, to this, but undoubtedly in great measure to the intense
-heating to which it is subject. But the coefficient of resistance of the
-intervening air is so much higher than that of any other part of the
-circuit that an intense localization of resistance occurs with
-corresponding localization of heating effect. This is the cause of the
-intense light. Thus if the carbons are but 1/32 of an inch apart as in a
-commercial lamp the resistance may be 1.5 ohms. The poor thermal
-conductivity of the carbon favors the concentration of heat also. The
-apparent resistance is too great to be accounted for by the ohmic
-resistance of the interposed air. A kind of thermoelectric effect is
-produced. The positive carbon has a temperature of about 4,000� C.
-(7,232� F.), the negative from 3,000� C. (5,432� F.) to 3,500� C.
-(6,322� F.). This difference of temperature produces a
-counter-electro-motive force which acts to virtually increase the
-resistance of the arc. The carbon ends of an arc can be projected with
-the lantern. Globules are seen upon them due to melted silica from the
-arc of the carbon.
-
-
-Fig. 19. EXPERIMENTAL APPARATUS FOR PRODUCING THE VOLTAIC ARC.
-
-
-41  STANDARD ELECTRICAL DICTIONARY.
-
-
-Areometer.
-An instrument for determining the specific gravity of a fluid. It
-consists of an elongated body ballasted so as to float vertically and
-provided with a mark or a scale. It floats deeper in a light than in a
-heavy liquid. If it carries but one mark weights are added until that
-mark is reached, when the weights required give the specific gravity. Or
-the scale may give the reading directly based upon the depth to which it
-sinks. Areometers are often made of glass, ballasted with shot or
-mercury enclosed in their bottom bulb as shown. They are used in
-regulating battery solutions, and in watching the charging and
-discharging of storage batteries.
-
-
-Fig. 20. AREOMETER
-
-
-Fig. 21. BEAD AREOMETER
-
-
-Areometer, Bead.
-A tube of glass containing beads of different specific gravities. It has
-apertures at top and bottom. When immersed in a liquid, the same fills
-it, and the specific gravity within certain limits, depending on the
-factors of the beads, is shown by the beads which float and those which
-sink. It is used for storage batteries and other purposes where acids
-and solutions have to be tested.
-
-
-Argyrometry.
-The method of ascertaining the weight and inferentially the thickness of
-an electroplater's deposit of silver. It is done by weighing the article
-before and after plating.
-
-
-Arm.
-The four members of a Wheatstone bridge, q. v., are termed its arms.
-Referring to the diagram of a bridge, P, Q, R, S, are the arms.
-
-
-Fig. 22. DIAGRAM OF WHEATSTONE'S BRIDGE.
-
-
-Armature.
-(a.) A mass or piece of iron or steel, or a collection of pieces of iron
-designed to be acted on by a magnet. While nickel or cobalt might be
-used, they rarely or never are except in experimental apparatus. The
-armature of a permanent horse shoe magnet is simply a little bar of soft
-iron. When the magnet is not in use it is kept in contact with the poles
-with the idea of retaining its magnetism. It is then said to be used as
-a keeper. A bar magnet does not generally have an armature. The armature
-is also used to exhibit the attraction of the magnet.
-
-Sometimes an armature is made of steel and is permanently magnetized.
-Such an armature, termed a polarized armature, is repelled when its like
-poles are opposed to like poles of the magnet and otherwise is attracted
-with force due to the sums of the magnetism. If the magnet is
-sufficiently powerful depolarization of the armature may ensue when like
-poles are opposed to like poles. Polarized armatures are used in various
-appliances, magneto generators, telegraphic instruments and others.
-
-(b) In a dynamo or Motor the mass of laminated iron or of wire which
-carries the coils of insulated wires which are caused to rotate in the
-field of force of the field magnets in order to establish and maintain
-potential difference with its accompanying current, or which rotates
-under the effects of a current in a motor. (See Dynamo Electric
-Generator.)
-
-The work of the armature core is twofold. It acts as a portion of the
-magnetic circuit, conducting the lines of force, and by virtue of its
-high permeability or multiplying power concentrating a number of the
-lines of force through its own substance. To enable it to act with
-efficiency in this direction it should be made of iron of the highest
-permeability, and should approach as closely as possible to the armature
-cores consistent with leaving space for the wire winding. It next acts
-as a support for the wires which are to be swept through the field of
-force. Thus it acts both to establish a strong field and then acts as a
-carrier for the wires which are to be cut by the wires in question. In
-connection with this subject the different definitions under Armature,
-Dynamo, Commutator, Induction and similar topics may be consulted.
-
-(c) See Armature of Influence Machine.
-
-(d) See Armature of Leyden Jar or Static Condenser.
-
-
-42   STANDARD ELECTRICAL DICTIONARY.
-
-
-Armature, Bar.
-An armature in a dynamo or motor whose winding is made up of conductors
-in the form of bars, round, rectangular and of other sections. This type
-of armature conductor is objectionable as Foucault currents are produced
-in it. It is found best to laminate or subdivide low resistance armature
-windings.
-
-[Transcriber's Note: Foucault currents are also called eddy currents.]
-
-
-Armature, Bipolar.
-An armature in which two poles are induced by the field. A bipolar field
-magnet produces a bipolar armature.
-
-
-Armature Bore.
-The cylindrical space defined by the pole pieces of a dynamo or motor
-within which the armature rotates.
-
-Synonym--Armature Chamber.
-
-
-43  STANDARD ELECTRICAL DICTIONARY.
-
-
-Armature, Closed Coil.
-An armature for a motor or dynamo, the ends of all of whose coils are
-united, so as to be in one closed circuit all the way around.
-
-
-Fig. 23. CLOSED COIL GRAMME RING ARMATURE.
-
-
-Armature Coil, or Coils.
-The insulated wire wound around the core of the armature of an electric
-current generator or motor.
-
-
-Armature Core.
-The central mass of iron on which the insulated wire, to be rotated in
-the field of an electric current generator or motor, is wound. (See
-Dynamo-electric Machine and Motor, Electric.)
-
-
-Armature, Cylinder.
-An armature of the Gramme ring type, but longer in the axial direction,
-so that its core resembles a long hollow cylinder, the wire being wound
-inside and outside as in the Gramme ring. (See Gramme Ring.)
-
-
-Armature, Disc.
-(a) An armature of a dynamo electric machine or motor in which the coils
-are wound so as to be flat and are carried on the face of a disc forming
-the core or part of the core of the armature. S. P. Thompson treats it
-as a modified drum armature extended radially, the outer periphery
-corresponding to the back end of the drum. The poles of the field are
-generally placed to face the side or sides of the disc.
-
-(b) Another type of disc armature has its wire wound on bobbins arranged
-around the periphery of a disc.
-
-In disc armatures there is often no iron core, their thinness enabling
-this to be dispensed with.
-
-
-44   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 24. DISC ARMATURE OF FRITSCHE MACHINE.
-
-
-Fig. 25. PLAN OF WINDING PACINOTTI'S DISC ARMATURE.
-
-
-Armature, Discoidal Ring.
-In a dynamo an armature of the shape of a ring of considerable radial
-depth of section as compared to its axial depth. It is generally made of
-iron ribbon or thin band wound to the proper size.
-
-Synonym--Flat Ring Armature.
-
-
-45 STANDARD ELECTRICAL DICTIONARY.
-
-
-Armature, Drum.
-An armature for a dynamo or motor, consisting of a cylinder of iron
-preferably made up of discs insulated from each other by thin shellacked
-paper, or simply by their oxidized surfaces, and wound with wire
-parallel to the axis where it lies on the cylindrical periphery and
-crossing the heads approximately parallel to the diameter. It operates
-practically on the same principle as a Gramme Ring Armature. (See Gramme
-Ring.)
-
-Synonym--Cylindrical Armature.
-
-
-Armature Factor.
-The number of conductors on an armature, counted or enumerated all
-around its external periphery.
-
-
-Armature, Hinged.
-An armature pivoted to the end of one of the legs of an electro-magnet
-so as to be free to swing and bring its other end down upon the other
-pole.
-
-
-Fig. 26. HINGED ARMATURES OF CLUB-FOOT ELECTRO MAGNETS.
-
-
-Armature, Hole.
-An armature whose core is perforated to secure cooling.
-
-Synonym--perforated Armature.
-
-
-Armature, Intensity.
-An armature wound for high electro-motive force. A term little used at
-the present time.
-
-
-Armature Interference.
-A limit to the ampere turns permissible on a given armature is found in
-the increase of cross magnetizing effect, q. v., the increased lead
-necessitated, and the growth of the demagnetizing power. All such
-perturbing effects are sometimes expressed as armature interference.
-
-
-46   STANDARD ELECTRICAL DICTIONARY.
-
-
-Armature, Load of.
-The circumflux, q. v., of the armature, or the ampere turns of the same.
-The maximum load which can be carried by an armature without sparking is
-directly proportional to the radial depth of core and to the length of
-the gap, and inversely proportional to the breadth of the polar span.
-
-
-Armature, Multipolar.
-An armature in which a number of poles greater than two is determined by
-the field. A multipolar field is employed for its production.
-
-
-Armature, Neutral.
-An armature of a magnet or telegraph relay which is not polarized or
-magnetized.
-
-Synonym--Non-polarized Armature--Neutral Relay Armature.
-
-
-Armature of Influence Machine.
-Pieces of paper pasted on the stationary plate of an electric machine of
-the Holtz type.
-
-
-Armature of Leyden Jar or Static Condenser.
-The inner and outer tin-foil coatings of a Leyden jar or other
-condenser.
-
-
-Armature, Open Coil.
-An armature of a dynamo or motor on which the coils are not joined in
-one closed circuit, but have their ends or some of them separated, and
-connected each to its own commutator bar or each set to their own bar.
-
-
-Fig. 27. OPEN COIL RING ARMATURE.
-
-
-47  STANDARD ELECTRICAL DICTIONARY.
-
-
-Armature, Pivoted.
-An armature for an electro-magnet mounted on a pivot, which is at right
-angles to the yoke or parallel with the legs of the magnet, so as to be
-free to rotate. When the magnet is excited the armature is drawn into
-line or approximately so with its base or yoke. The system is used in
-some telegraph apparatus.
-
-
-Armature Pockets.
-Spaces or recesses in armatures provided for the reception of the coils.
-
-
-Armature, Polarized.
-An armature made of steel or having a steel core to which permanent
-magnetism has been imparted. Such are used in some forms of magneto
-current generators, and in telegraphic instruments. (See Relay,
-Polarized.)
-
-
-Armature, Pole.
-An armature having coils wound on separate poles projecting radially all
-around the periphery of its central hub or disc, or projecting
-internally from a ring-like frame, their ends facing the field magnet.
-
-Synonym--Radial Armature.
-
-
-Armature, Quantity.
-An armature of a dynamo or motor wound for current of large quantity.
-The term is now but little used.
-
-
-Armature-Reactions.
-When an armature is running in an active dynamo a series of
-reactions is established, the more important of which are:
-I. A tendency to cross-magnetize the armature.
-II. A tendency to spark at the brushes.
-III. A tendency for the armature current to demagnetize on account of
-the lead which has to be given to the brushes.
-IV. Variations in the neutral points as more or less current is taken
-from the machine.
-V. Heating of armature, both core and conductors, and of pole pieces,
-which heating is due to Foucault currents.
-
-
-Armature, Revolving, Page's.
-An early form of motor. The field is produced by a permanent magnet.
-Above its poles is a soft iron armature wound with a coil of insulated
-wire. A two-part commutator with contact springs conveys the current to
-the coil. The whole is so arranged that the polarity of the armature, as
-induced by the coil, through which a current is passed, is reversed as
-its ends sweep by the poles of the magnet. Then it is repelled from the
-poles and swings through 180� to have its polarity reversed and to go
-through the next 180�, and so on. Thus it rotates at a very high rate of
-speed.
-
-In the cut showing the elevation A, B, is the armature;  f, g, the
-springs or brushes; h, the commutator with its sections o, i. In the
-section of the commutator W, W, designate the springs or brushes, A, the
-vertical spindle carrying the armature and commutator, and S, S, the
-commutator sections.
-
-
-48   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 28. PAGE'S REVOLVING ARMATURE.
-
-
-Fig. 29. SECTION OF COMMUTATOR OF PAGE'S REVOLVING ARMATURE.
-W, W, Brushes; A, Spindle; S, S, Armature Segments.
-
-
-Armature, Ring.
-An armature whose core is in the shape of a ring, as the Gramme Ring
-Armature. (See Figs. 23 & 27.)
-
-
-49  STANDARD ELECTRICAL DICTIONARY.
-
-
-Armature, Rolling.
-(a) An armature for a permanent horseshoe magnet consisting of a
-straight cylinder of soft iron on which a heavy wheel is mounted. When
-the legs of the magnet are inclined downward and the bar is laid across
-them it rolls down to the poles, across their ends, and back up the
-under side. It is merely a magnetic toy or illustrative experiment.
-
-Synonym--Wheel Armature.
-
-(b) Another form consists of little bars of iron with brass discs
-attached to the ends. On placing two of these together and bringing the
-poles of a magnet near them, as shown, they become magnetized with like
-polarity by induction and repel each other, rolling away in opposite
-directions.
-
-
-Fig. 30. ROLLING OR WHEEL ARMATURE.
-
-
-Fig. 31. ROLLING ARMATURES.
-
-
-Armature, Shuttle.
-The original Siemens' armature, now discarded. The core was long and
-narrow, and its cross section was nearly of the section of an H. The
-grooves were wound full of wire, so that the whole formed almost a
-perfect cylinder, long and narrow comparatively. (See Winding Shuttle.)
-
-Synonym--Siemens' Old Armature--Girder Armature--H Armature.
-
-
-Fig. 32. SHUTTLE OR H ARMATURE.
-
-
-Armature, Spherical.
-An armature of a dynamo which is wound on a spherical core, so as to be
-almost a sphere. It is employed in the Thomson-Houston dynamo, being
-enclosed in a cavity nearly fitting it, formed by the pole pieces.
-
-
-Armature, Stranded Conductor.
-A substitute for bar-armatures in which stranded copper wire conductors
-are substituted for the solid bar conductors, to avoid Foucault
-currents. (See Armature, Bar.)
-
-
-50   STANDARD ELECTRICAL DICTIONARY.
-
-
-Armature, Unipolar.
-An armature of a unipolar dynamo. (See Dynamo Unipolar.)
-
-
-Armor of Cable.
-The metal covering, often of heavy wire, surrounding a telegraph or
-electric cable subjected to severe usage, as in submarine cables.
-
-Synonym--Armature of Cable.
-
-
-Arm, Rocker.
-An arm extending from a rocker of a dynamo or motor, to which arm one of
-the brushes is attached. (See Rocker.) Ordinarily there are two arms,
-one for each brush.
-
-
-Articulate Speech.
-Speech involving the sounds of words. It is a definition which has
-acquired importance in the Bell telephone litigations, one contention,
-concerning the Bell telephone patent, holding that the patentee did not
-intend his telephone to transmit articulations, but only sound and
-music.
-
-
-Astatic. adj.
-Having no magnetic directive tendency due to the earth's magnetism.
-Examples are given under Astatic Needle; Circuit, Astatic; and
-Galvanometer Astatic.
-
-
-Fig. 33. NOBILI'S PAIR.
-
-
-FIG. 34. VERTICAL PAIR ASTATIC COMBINATION.
-
-
-Astatic Needle.
-A combination of two magnetic needles so adjusted as to
-have as slight directive tendency as possible. Such a pair of needles
-when poised or suspended will hardly tend to turn more to one point of
-the compass than another. The combination is generally made up of two
-needles arranged one above the other, with their poles in opposite
-directions. This combination is usually called Nobili's pair. If of
-equal strength and with parallel magnetic axes of equal length they
-would be astatic. In practice this is very rarely the case. A resultant
-axis is generally to be found which may even be at right angles to the
-long axis of the magnets, causing them to point east and west. Such a
-compound needle requires very little force to turn it one way or the
-other. If one of the needles is placed within a coil of insulated wire a
-feeble current will act almost as strongly to deflect the system as if
-the other was absent, and the deflection will only be resisted by the
-slight directive tendency of the pair of needles. This is the basis of
-construction of the astatic galvanometer. Sometimes coils wound in
-opposite directions and connected in series, or one following the other,
-surround both needles, thus producing a still greater effect of
-deflection.
-
-Other astatic needles are shown in the cuts below. [Figures 33 to 35.]
-
-
-51  STANDARD ELECTRICAL DICTIONARY.
-
-
-FIG. 35. SIMPLE ASTATIC NEEDLE.
-
-
-Asymptote.
-A line continuously approached by a curve, but which the curve, owing to
-its construction or nature of curvature, can never touch, be tangent to,
-or intersect.
-
-
-Atmosphere.
-(a) A term applied to the atmospheric pressure as a practical unit of
-pressure equal to 15 lbs. to the square inch as generally taken. It is
-really about 14.7 lbs. per square inch, or 1,033 grams per square
-centimeter.
-
-(b) Air, q. v.
-
-
-Atmosphere Residual.
-The atmosphere left in a vessel after exhaustion. The term may be
-applied to any gas. In an incandescent lamp after flashing the residual
-atmosphere consists of hydro-carbons.
-
-
-Atmospheric Electricity.
-The electricity of the atmosphere, rarely absent, but often changing in
-amount and sign. Benjamin Franklin, in a memoir published in 1749,
-indicated the method of drawing electricity from the clouds by pointed
-conductors. In June, 1752, he flew a kite and by its moistened cord drew
-an electric spark from the clouds, confirming his hypothesis that
-lightning was identical with the disruptive discharge of electricity. To
-observe electricity in fine weather a gold-leaf or other electroscope
-may be connected to the end of a long pointed insulated conductor. The
-electricity during thunderstorms can be shown by a similar arrangement,
-or burning alcohol or tinder gives an ascending current of warm air that
-acts as a conductor. Quite elaborate apparatus for observing and
-recording it have been devised. Atmospheric electricity is usually
-positive, but occasionally negative. When the sky is cloudless it is
-always positive, increasing with the elevation and isolation of the
-place. In houses, streets, and under trees no positive electricity can
-be found. In the Isle of Arran, Scotland, a rise of 24 to 48 volts per
-foot of increase in elevation was found by Sir William Thomson. At
-sunrise the electrification of the air is feeble, it increases towards
-noon and decreases again to reach a second maximum a few hours after
-sunset. It increases with the barometric pressure generally. In cloudy
-weather it is sometimes negative and the sign often changes several
-times in the same day. In a thunderstorm the changes in sign and
-potential are very rapid. The cause of atmospheric electricity is far
-from clear. Tait attributes it to a contact effect between air and water
-vapor, Solmeke to friction of water vesicles against ice particles in
-the upper atmosphere, he first showing that the two may coexist. The
-cause of the enormous increase of potential producing lightning is
-attributed to the decreased capacity due to the change of water from
-cloud vesicles to drops, thus diminishing the electrostatic capacity of
-the water in question. (See Lightning.)
-
-
-52   STANDARD ELECTRICAL DICTIONARY.
-
-
-Atom.
-The ultimate particle or division of an elementary substance; the
-smallest part that can exist in combination, and one which cannot exist
-alone. An elementary substance is composed of molecules just as truly as
-a compound one, but the atoms in the molecule of an elementary substance
-are all precisely alike. Hence atoms are the units of chemistry, they
-have to do with combinations, but the physical unit, the smallest
-particle of matter that can have an independent existence, is the
-molecule. The two are often confounded, especially by writers of a few
-years ago, so that by "atom" the molecule is often meant. There is
-nothing to be said of their size or mass. All such calculations refer to
-the molecule, q. v., often spoken of and called the atom.
-
-[Transcriber's note: Yet to be discovered: electron--1897 (5 years),
-proton--1920 (28 years), neutron--1932 (30 years), quark--1961 (69 years).]
-
-
-Atomic Attraction.
-The attraction of atoms for each other, in virtue of which they combine
-into molecules; chemical affinity, q. v., treats principally of this,
-although molecular attraction also plays a part in it.
-
-
-Atomic Heat.
-The product of the atomic weight of a substance by its specific heat.
-This product is approximately the same, 6.4; this approximation is so
-close that it is of use in determining the valency and atomic weights of
-substances. The atomic weight of a substance therefore represents the
-approximate number of gram-calories required to raise one gram-atom, q.
-v., of such substance through 1� C. (1.8� F.)
-
-
-Atomicity.
-The quantivalence or valency of the atoms; the number of combination
-bonds, or bonds of affinity, possessed by the atoms of any substance.
-Thus two atoms of hydrogen combine with one atom of oxygen, and three of
-oxygen with one of sulphur, forming saturated compounds. Therefore,
-taking hydrogen as of single atomicity or a monad, oxygen is of double
-atomicity or a dyad, and sulphur is of six-fold atomicity, or a hexad.
-The elements are thus classified into seven orders of atomicities, thus:
-
-  1, Monads or Univalent elements,   Hydrogen, etc.
-  2, Dyads or Bivalent        "      Oxygen, etc.
-  3, Triads or Trivalent      "      Nitrogen, etc.
-  4, Tetrads or Quadrivalent  "      Lead, etc.
-  5, Pentads or Quinquivalent "      Phosphorous, etc.
-  6, Hexads or Sexivalent     "      Chromium, etc.
-  7, Heptads or Septivalent   "      Chromium, etc.
-
-The same element often possesses several atomicities. Barium is
-generally a dyad, sometimes a tetrad; nitrogen acts as a monad, dyad,
-triad, tetrad and pentad. The familiar electrolysis of water, giving two
-volumes of hydrogen to one of oxygen, is one of the illustrations of the
-theory indicating that two atoms of hydrogen are combined with one of
-oxygen.
-
-
-53  STANDARD ELECTRICAL DICTIONARY.
-
-
-Atomic Weight.
-The number expressing the relative weight of the atom of any substance,
-that of hydrogen being generally taken as unity. This is the universal
-system, although any other element might be taken as the basis of the
-system. The whole theory of atomic weights is based on the
-indivisibility of the atom and on the theory of atomicity, q. v. (See
-Equivalents.)
-
-[Transcriber's note: The standard is now the isotope carbon-12 as
-exactly 12.]
-
-
-Attraction.
-The tendency to approach and adhere or cohere, shown by all forms of
-matter. It includes gravitation, cohesion, adhesion, chemical affinity
-and other forms, and is opposed by repulsion, and is sometimes overcome
-by it, although it may be assumed to be always present. See the
-different kinds of attractions under their titles: Atomic Attraction,
-Electro-magnetic Attraction and Repulsion, Electro Static Attraction and
-Repulsion, Electro-dynamic Attraction and Repulsion; Magnetic Attraction
-and Repulsion; Molar Attraction.
-
-
-Audiometer.
-An apparatus for obtaining a balance of induction from two coils acting
-upon a third. The third is placed between the other two and is free to
-move towards either. A scale is provided to show the extent of its
-movement. A varying or interrupted current being passed through the two
-outer coils, the preponderating current will produce the most induction
-if the central coil is equidistant. It can always be moved to such a
-point that there will be no inductive effect, one counteracting the
-other. Thus its position measures the relative induction. A telephone is
-in circuit with the intermediate coil and is used to determine when its
-position is such that no current is induced in it. It is sometimes used
-as a direct test of hearing. (See Hughes' Induction Balance.)
-
-Synonym--Acoutemeter.
-
-
-Aura, Electrical.
-The blast of air produced at highly electrified points.
-
-
-Aurora.
-A luminous display seen in the northern heavens in the northern
-hemisphere, where it is the Aurora Borealis, and seen in the southern
-heavens in the southern hemisphere, where it is called Aurora Australis,
-or indifferently for either, the Aurora Polaris. It takes the form of
-pale luminous bands, rays and curtains varying in color. Near the poles
-they are very numerous. A French commission observed 150 auroras in 200
-days. Their height is variously estimated at from 90 to 460 miles; they
-are most frequent at the equinoxes and least so at the solstices. There
-is a secular variation also, they attain a maximum of occurrence every
-11 years together with sun spots, with a minimum 5 or 6 years after the
-maximum. There is also a period of 60 years, coincident with
-disturbances in the earth's magnetism. Various attempts have been made
-to account for them. They have a constant direction of arc with
-reference to the magnetic meridian (q. v.) and act upon the magnetic
-needle; in high latitudes they affect telegraph circuits violently.
-There is a strong probability that they represent electric currents or
-discharges. De la Rive considers them due to electric discharges between
-the earth and atmosphere, which electricities are separated by the
-action of the sun in equatorial regions. According to Balfour Stewart,
-auroras and earth currents.(q. v.) may be regarded as secondary currents
-due to small but rapid changes in the earth's magnetism. The subject is
-very obscure. Stewart treats the earth as representing the magnetic core
-of an induction coil, the lower air is the dielectric, and the upper
-rarefied and therefore conducting atmosphere is the secondary coil. This
-makes the aurora a phenomenon of induced currents. Then the sun may be
-regarded as the instigator of the primary changes in the earth's lines
-of force representing the primary of an induction coil.
-
-[Transcriber's note: Solar wind, streams of electrons and protons,
-interacting with the earth's magnetic field causes aurora. Neither
-electrons (1897) nor protons (1920) were known in 1892. The Soviet
-satellite Luna first measured the solar wind in 1959. Even today
-increased understanding of solar and auroral phenomenon continues.]
-
-
-54   STANDARD ELECTRICAL DICTIONARY.
-
-
-Austral Pole.
-The north pole of the magnet is thus called sometimes in France; the
-austral pole of a magnet is the one which points towards the north polar
-regions As unlike magnetic poles attract each other, it is but rational
-to call the north-seeking pole of the magnet the south or Austral Pole.
-In the same nomenclature the south pole of a magnet, or the
-south-seeking pole, is called the Boreal Pole.
-
-
-A. W. G.
-Abbreviation for American Wire Gauge, q. v.
-
-
-Axis, Electric.
-The electric axis of a pyroelectric crystal, such as a tourmaline
-crystal; the line connecting the points of greatest pyroelectric
-excitability.
-
-
-Axis of Abscissa.
-In a system of rectilinear, or right angle co-ordinates, the horizontal
-axis. (See Co-ordinates.)
-
-Synonym--Axis of X.
-
-
-Axis of Ordinates.
-In a system of rectilinear right angle co-ordinates, the vertical axis.
-(See Co-ordinates.)
-
-Synonym--Axis of Y.
-
-
-Azimuth.
-The angle between the plane of the meridian and the plane of an azimuth
-circle, q. v.
-
-
-Azimuth Circle.
-A great circle, whose plane passes through the zenith or point of the
-heavens directly overhead; any great circle in whose plane the vertical
-at the point of observation is included.
-
-Each celestial body has or determines an azimuth circle.
-
-
-55  STANDARD ELECTRICAL DICTIONARY.
-
-
-B.
-(a) Abbreviation for Baum�, a hydrometer scale. (See Baum�.) Thus 10� B.
-means "ten degrees Baum�."
-
-(b) Symbol for the coefficient of induced magnetization, or the number
-of lines per square centimeter induced in a magnetic circuit or in any
-specified part of it.
-
-
-B. A.
-Abbreviation for British Association. It is prefixed to standards fixed
-by the committee of the British Association for the Advancement of
-Science. Thus the B. A. ohm means the British Association ohm, a measure
-of resistance which is equal to the resistance of a column of mercury
-104.9 centimeters long and one square millimeter area of cross-section.
-(See Ohm.)
-
-
-Back Induction.
-A demagnetizing force produced in a dynamo armature when a lead is given
-the brushes. The windings by such setting of the brushes are virtually
-divided into two sets, one a direct magnetizing set, the other a cross
-magnetizing set. The latter have a component due to the obliqueness of
-the neutral line, which component is demagnetizing in its action.
-
-
-Back Shock or Stroke of Lightning.
-A lightning stroke received after the main discharge of the lightning,
-and caused by a charge induced in neighboring surfaces by the main
-discharge. The discharge affects the evenness of distribution of
-surrounding surfaces so that a species of secondary discharge is
-required to make even the distribution, or to supply charge where needed
-to bind an opposite one. The effects are much lese severe as a rule than
-those of the main charge, although the back stroke has caused death. The
-back stroke is sometimes felt a considerable distance from the place of
-the original lightning stroke.
-
-Synonym--Return Stroke.
-
-
-Back Stroke.
-(a) In telegraphy the return stroke of the lever in a telegraph sounder,
-striking the end of the regulating screw with a sound distinct from that
-which it produces on the forward stroke as it approaches the magnet
-poles. It is an important factor in receiving by ear or sound reading.
-
-(b) See Back Shock or Stroke of Lightning.
-
-
-Balance.
-(a) Wheatstone's Bridge, q. v., is sometimes termed the Electric
-Balance.
-
-(b) A suspension or torsion balance is one which includes a filament or
-pair of filaments to whose lower end or ends are attached a horizontal
-indicator often called a needle, or a magnetic needle. (See Torsion
-Balance.)
-
-(c) See Induction Balance, Hughes'.
-
-(d) For Thermic Balance, see Bolometer.
-
-(e) See Balance, Ampere.
-
-
-56   STANDARD ELECTRICAL DICTIONARY.
-
-
-Balance, Ampere.
-A class of electrical measuring instruments due to Sir William Thomson
-may be grouped under this head.
-
-The instrument is a true balance or scales such as used for weighing. It
-is supported by a torsional wire support in place of knife edges. At
-each end it carries a circle of wire through which the current to be
-tested is passed. The torsional wire support enables the current to be
-carried to these wire rings. Above and below each of these rings are two
-similar rings, also connected so as to receive the current. They are so
-connected that the current shall go through them in opposite senses.
-When a current passes, therefore, one of these rings repels and one
-attracts the balanced ring.
-
-The extent of this action measures the intensity of the current. A
-sliding weight moving along a graduated scale on the balance is used to
-bring the balance beam into equilibrium when the current is passing. The
-degree of displacement of this weight gives the strength of the current
-in amperes.
-
-These balances are made for different currents. Thus there is a
-centi-ampere balance, deka-ampere balance and others, as well as an
-ampere balance.
-
-
-Balata.
-A gum used as an insulating material. It is the inspissated juice of a
-sapotaceous tree, the bullet tree, Mimusops globosa, of tropical
-America, from the Antilles to Guiana. It is intermediate in character
-between caoutchouc and gutta percha. It is superior to gutta percha in
-some respects, being very slightly acted on by light.
-
-Synonym--Chicle.
-
-
-B. & S.. W. G.
-Abbreviation for Brown & Sharpe Wire Gauge; the regular American Wire
-Gauge. (See Wire Gauge, American.)
-
-
-Barad.
-An absolute or fundamental unit of pressure, equal to one dyne per
-square centimeter.
-
-
-Barometer.
-An apparatus for measuring the pressure exerted by the atmosphere. It
-consists, in the mercurial form, of a glass tube, over 31 inches long,
-closed at one end, filled with mercury and inverted, with its open end
-immersed in a cistern of mercury. The column falls to a height
-proportional to the pressure of the atmosphere from 30 to 31 inches at
-the sea level. The "standard barometer" is a height of the mercury or of
-the "barometric column" of 30 inches or 760 centimeters, measured from
-the surface of the mercury in the cistern.
-
-The column of mercury is termed the barometric column. Above it in the
-tube is the Torricellian vacuum.
-
-[Transcriber's note: More accurately, 29.92 inches of mercury or 14.696
-PSI.]
-
-
-Bars of Commutators.
-The metal segments of a commutator of a dynamo or motor. They are made
-of bars of copper, brass or bronze insulated from one another. (See
-Commutator.)
-
-Synonyms--Segments, Commutator Segments, Commutator Bars.
-
-
-57 STANDARD ELECTRICAL DICTIONARY.
-
-
-Bath.
-(a) In electro-plating the solution used for depositing metal as
-contained in a vat or tank; as a silver, copper, or nickel bath used for
-plating articles with silver, copper, or nickel respectively.
-
-(b) In electro-therapeutics a bath with suitable arrangements,
-electrodes and connections for treating patients with electricity. It is
-termed an electric bath or electro-therapeutic bath.
-
-
-Bath, Bipolar Electric.
-In electro-therapeutics a bath in which the electrodes are both immersed
-in the water. The patient placed between them receives part of the
-discharge. The electrodes are large copper plates, termed shovel
-electrodes.
-
-
-Bath, Electric Shower.
-An electro-medical shower bath. The patient is placed on a metallic
-stove or support connected to one of the electric terminals. Water
-slightly alkaline is showered upon him. The other electrode is in
-connection with the water. The rain of drops and streamlets is the
-conductor of the current or discharge.
-
-
-Bath, Multipolar Electric.
-An electro-medical bath with a number of electrodes instead of two.
-
-
-Bath, Stripping.
-In electro-plating a solution used for dissolving and thus removing the
-plating from any object. The stripping bath is of the same general type
-as the plating bath for the same metal as the one to be dissolved. The
-object to be "stripped" is made the anode of a plating circuit, and as
-the current acts the old plating is attacked and dissolves, leaving the
-body of the article bare. It is simply the operation of plating
-reversed. The same term is applied to baths acting by simple solution.
-Stripping baths are described under the different metals as Silver Bath,
-Stripping--Gold Bath, Stripping.
-
-
-Bath, Unipolar Electric.
-An electro-medical bath, in which only one electrode connects with the
-water of the bath. The second electrode is supported above the bath. The
-patient touches this while in the water whenever electric action is
-desired.
-
-
-FIG. 36. THREE WIRE MOULDING OR BATTEN.
-
-
-FIG. 37. TWO WIRE MOULDING OR BATTEN.
-
-
-58   STANDARD ELECTRICAL DICTIONARY.
-
-
-Batten.
-A strip of wood grooved longitudinally for holding wires in wiring
-apartments for electric light or power. In use they are fastened to the
-wall, grooves inward, or else grooves outward, with the wires lying in
-the grooves and covered with the covering strip. For two wire work each
-batten contains two grooves; for the three wire system it contains three
-grooves.
-
-Synonym--Moulding.
-
-
-Battery.
-A combination of parts or elements for the production of electrical
-action. The term is principally applied to voltaic batteries, but there
-are also magnetic batteries, batteries of Leyden jars, and other
-combinations, described in their places, which come under this category.
-
-[Transcriber's note: A group of similar items such as questions,
-machines, parts, guns, or electric cells.]
-
-
-Battery, Acetic Acid.
-A battery whose active solution or excitant is acetic acid or vinegar.
-This acid has been used by Pulvermacher in his medical battery, as being
-a substance found in every household in the form of vinegar. It is now
-but little used.
-
-
-Battery, Alum.
-A battery using as excitant a solution of alum. This battery has had
-some application for electric clocks, but only to a limited extent.
-
-
-Fig. 38. BALLOON OR FLASK BATTERY.
-
-
-Battery, Aluminum.
-A battery in which aluminum is the negative plate and aluminum sulphate
-the excitant. It is mounted like the gravity battery. Its electro-motive
-force is 0.2 volt.
-
-
-59  STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Bagration.
-A battery with zinc and carbon electrodes immersed in earth sprinkled
-with sal ammoniac (ammonium chloride). The copper is preferably first
-immersed in sal ammoniac solution and dried, until a green layer is
-formed on its surface.
-
-The battery is highly praised for its constancy by De la Rive, but may
-be regarded as obsolete.
-
-
-Battery, Balloon.
-A form of gravity battery into whose centre a globular flask, B, is
-inverted, which is filled before inversion with copper sulphate, of
-which 2 lbs. are used, and water, so as to remain full. This acts as a
-reservoir of copper sulphate, which it constantly supplies. The glass
-jar is closed with a perforated wooden cover.
-
-
-Battery, Banked.
-(a) A battery arranged to feed a number of separate circuits.
-
-(b) A battery connected in parallel or in multiple arc.
-
-
-Battery, Bichromate.
-A battery with amalgamated zinc and carbon plates, with an exciting
-fluid composed of sulphuric acid, water, and potassium bichromate. For
-formula of such solutions see Electropoion Fluid--Kookogey's
-Solution--Poggendorff's Solution--Trouv�'s Solution--Delaurier's
-Solution, and others. (See Index.)
-
-
-Battery, Bunsen.
-A two fluid porous cell battery. The negative plate is carbon, the
-positive plate, amalgamated zinc. The depolarizer is nitric acid or
-electropoion fluid, q.v., in which the carbon is immersed. The last
-named depolarizer or some equivalent chromic acid depolarizing mixture
-is now universally used.  The excitant is a dilute solution of sulphuric
-acid. Originally the carbon was made cylindrical in shape and surrounded
-the porous cups, in which the zinc was placed. This disposition is now
-generally reversed. The electro-motive force is 1.9 volts. The
-depolarizing solution is placed in the compartment with the carbon. The
-excitant surrounds the zinc.
-
-
-Fig. 39. BUNSEN'S BATTERY.
-
-
-60   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Cadmium.
-A battery in which cadmium is the negative plate, sulphate of cadmium
-solution the excitant and depolarizer, and zinc the positive plate.
-Electro-motive force, .31 volt or about one third of a Daniell cell. It
-is mounted like a gravity battery.
-
-
-Battery, Callan.
-A modification of Grove's battery. Platinized lead is used for the
-negative plate, and as a depolarizer a mixture of 4 parts concentrated
-sulphuric acid, 2 parts of nitric acid, and 2 parts of a saturated
-solution of potassium nitrate. (See Battery, Grove's.)
-
-
-Battery, Camacho's.
-A battery with carbon negative and amalgamated zinc positive electrodes.
-The carbon is contained in a porous cup, packed with loose carbon.
-Electropoion or other fluid of that type serves as excitant and
-depolarizer, and is delivered as shown from cell to cell by syphons.
-
-
-Fig. 40. CAMACHO'S BATTERY.
-
-
-Battery, Carr�'s.
-A Daniell battery for whose porous cup a vessel or species of sack made
-of parchment paper is substituted. The battery has been used for
-electric light, and has been run for 200 successive hours, by replacing
-every 24 hours part of the zinc sulphate solution by water.
-
-
-61  STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Cautery.
-A battery used for heating a platinum wire or other conductor used for
-cauterization in electro-therapeutics. The term is descriptive, not
-generic.
-
-
-Battery, Chloric Acid.
-A battery of the Bunsen type in which an acidulated solution of
-potassium chlorate is used as depolarizer.
-
-
-Battery, Chloride of Lime.
-A battery in which bleaching powder is the excitant. The zinc electrode
-is immersed in a strong solution of salt, the carbon in a porous vessel
-is surrounded with fragments of carbon and is packed with chloride of
-lime (bleaching powder). There is no action on open circuit. It has to
-be hermetically sealed on account of the odor. Its electro-motive force
-is--initial, 1.65 volts; regular, 1.5 volts.
-
-Synonym--Niaudet's Battery.
-
-
-Battery, Chromic Acid.
-Properly a battery in which chromic acid is used as a depolarizer. It
-includes the bichromate battery. (See Battery, Bichromate.)
-
-
-Battery, Closed Circuit.
-A battery adapted by its construction to maintain a current on a closed
-circuit for a long time without sensible polarization. The term is
-merely one of degree, for any battery becomes exhausted sooner or later.
-As examples the Grove, Bunsen or Daniell batteries may be cited.
-
-
-62   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 41. COLUMN BATTERY.
-
-
-Battery, Column.
-The original Volta's pile. It consists of a series of compound circular
-plates, the upper or lower half, A, copper; the other, Z, of zinc.
-Between each pair of plates some flannel or cloth, u, u, is laid, which
-is saturated with dilute acid. As shown in the cut, the parts are laid
-up in two piles, connected at the top with a bar, c, c, and with vessels
-of acidulated water, b, b, as electrodes. The great point in setting it
-up is to be sure that no acid runs from one disc of flannel to the next
-over the outside of the plates, as this would create a short circuit.
-The plates are best compound, being made up of a zinc and a copper plate
-soldered together. They may, however, be separate, and merely laid one
-on the other. In such case great care must be taken to admit no acid
-between them.
-
-Volta's pile is no longer used, except occasionally. Trouv�'s blotting
-paper battery (see Battery, Trouv�'s) is a relic of it, and the same is
-to be said for Zamboni's dry pile.
-
-It rapidly polarizes, the flannel retains but little acid, so that it is
-soon spent, and it is very troublesome to set up. Great care must be
-taken to have the cloth discs thoroughly saturated, and wrung out to
-avoid short circuiting by squeezing out of the acid.
-
-
-Battery, D'Arsonval's.
-A battery of the Bunsen type, differing therefrom in the solutions. As
-excitant in which the zinc electrode is immersed, the following solution
-is used:
-
-Water, 20 volumes;
-Sulphuric Acid (purified by shaking with a little olive or similar oil),
-1 volume;
-hydrochloric acid, 1 volume.
-
-As polarizer in which the carbon is immersed the following is used:
-
-Nitric acid, 1 volume;
-hydrochloric acid, 1 volume;
-water acidulated with 1/20th sulphuric acid, 2 volumes.
-
-
-Battery, de la Rue.
-A battery with zinc positive and silver negative electrode; the
-depolarizer is silver chloride; the excitant common salt or ammonium
-chloride. The cut shows one of its forms of construction.
-
-The right hand portion of the cut, Fig. 42, shows the zinc perforated at
-C for the connection from the next silver plate. The next to it is the
-negative electrode of silver around which a mass of silver chloride is
-cast in cylindrical form. A is a parchment paper cylinder with two holes
-near its top, through which the silver wire of the negative electrode is
-threaded, as shown in B. A solution of 23 parts ammonium chloride in
-1,000 parts of water is the approved excitant. Its electro-motive force
-is 1.03 volts.
-
-The jars are closed with paraffin.
-
-
-Fig. 42. DE LA RUE'S BATTERY.
-
-
-63   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Dry.
-(a) A form of open circuit battery in which the solutions by a mass of
-zinc oxychloride, gypsum, or by a gelatinous mass such as gelatinous
-silica, or glue jelly, are made practically solid. Numbers of such have
-been patented, and have met with considerable success.
-
-(b) Zamboni's dry pile, q. v., is sometimes termed a dry battery.
-
-
-Battery, Element of.
-A term applied sometimes to a single plate, sometimes to the pair of
-plates, positive and negative, of the single couple.
-
-
-Battery, Faradic.
-A term applied, not very correctly however, to apparatus for producing
-medical faradic currents. It may be an induction coil with battery, or a
-magneto-generator worked by hand.
-
-
-Battery, Ferric Chloride.
-A battery of the Bunsen type, in which a solution of perchloride of iron
-(ferric chloride) is used for the depolarizing agent. A little bromine
-is added with advantage. The depolarizing agent recuperates on standing,
-by oxidation from the oxygen of the air.
-
-
-Battery, Fuller's.
-A battery of the Bunsen type. The zinc plate is short and conical, and
-rests in the porous jar into which some mercury is poured. An insulated
-copper wire connects with the zinc. A plate of carbon is in the outer
-jar. The solutions are used as in the Bunsen battery.
-
-Synonym--Mercury Bichromate Battery.
-
-
-Battery, Gas.
-(a) A battery whose action depends on the oxidation of hydrogen as its
-generating factor. It was invented by Grove. Plates of platinum are
-immersed in cups of dilute acid, arranged as if they were plates of zinc
-and carbon, in an ordinary battery. Each plate is surrounded by a glass
-tube sealed at the top. The plates are filled with acid to the tops.
-Through the top the connection is made. A current from another battery
-is then passed through it, decomposing the water and surrounding the
-upper part of one set of plates with an atmosphere of oxygen and of the
-other with hydrogen. Considerable quantities of these gasses are also
-occluded by the plates. On now connecting the terminals of the battery,
-it gives a current in the reverse direction of that of the charging
-current.
-
-This battery, which is experimental only, is interesting as being the
-first of the storage batteries.
-
-(b) Upward's Chlorine Battery and any battery of that type (see Battery,
-Upward's,) is sometimes termed a gas battery.
-
-
-64   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery Gauge.
-A pocket or portable galvanometer for use in testing batteries and
-connections.
-
-
-Battery, Gravity.
-A battery of the Daniell type, in which the porous cup is suppressed and
-the separation of the fluids is secured by their difference in specific
-gravity. A great many forms have been devised, varying only in details.
-The copper plate, which is sometimes disc shaped, but in any case of
-inconsiderable height, rests at the bottom of the jar. Near the top the
-zinc plate, also flat or of slight depth, is supported. As exciting
-liquid a strong solution of copper sulphate lies at the bottom of the
-jar. This is overlaid by a solution of zinc sulphate, or sodium
-sulphate, which must be of considerably less specific gravity than that
-of the copper sulphate solution. In charging the jar one-tenth of a
-saturated solution of zinc sulphate mixed with water is sometimes used
-as the upper fluid. This may be first added so as to half fill the jar.
-The strong solution of copper sulphate may then be added with a syphon
-or syringe underneath the other so as to raise it up. From time to time
-copper sulphate in crystals are dropped into the jar. They sink to the
-bottom and maintain the copper sulphate solution in a state of
-saturation.
-
-
-Fig. 43. GRAVITY BATTERY OF THE TROUV�-CALLAUD TYPE.
-
-
-If the battery is left on open circuit the liquids diffuse, and metallic
-copper precipitates upon the zincs. This impairs its efficiency and
-creates local action. As long as the battery is kept at work on closed
-circuit work but little deposition, comparatively speaking, occurs.
-
-From time to time, in any case, the zinc plates are removed and scraped,
-so as to remove the copper which inevitably forms on their surface. Care
-must be taken that the zinc sulphate solution, which is constantly
-increasing in strength, does not get so strong as to become of as high
-specific gravity as the copper sulphate solution. From time to time some
-of the upper solution is therefore removed with a syphon or syringe and
-replaced with water. An areometer is useful in running this battery.
-
-
-65  STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Grenet.
-A plunge battery with zinc positive and carbon negative electrodes.
-Electropoion or other chromic acid or bichromate solution is used as
-depolarizer and excitant. The zinc plate alone is plunged into and
-withdrawn from the solution.
-
-
-Fig. 44. GRENET'S BATTERY.
-
-
-Fig. 45. GROVE'S BATTERY.
-
-
-Battery, Grove's.
-A two fluid galvanic battery. A porous cup has within it a riband of
-platinum, which is the negative plate; amalgamated zinc in the outer jar
-is the positive plate. Dilute sulphuric acid (10 per cent. solution) is
-placed in the outer jar, and strong nitric acid (40� B.) as a
-depolarizer in the porous cups. Its E. M. F. is 1.96 volts.
-
-It is objectionable, as it gives off corrosive nitrous fumes. These are
-produced by the oxidation of the nascent hydrogen by the nitric acid, by
-the following reaction:
-
-3 H + H N O3 = 2 H2 O + N O. There are other reactions, one of which
-results in the formation of ammonia by the reduction of the nitric acid
-radical by the hydrogen. Ammonium can be detected in the spent liquids.
-
-
-66   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Hydrochloric Acid.
-A battery in which hydrochloric acid is used as the excitant. Many
-attempts have been made to use this acid in batteries, but the volatile
-nature of the acid causes the production of so much odor with corrosive
-fumes that it has never come into use.
-
-
-Battery, Lead Chloride.
-A battery of the lead sulphate type in which lead chloride is the
-depolarizer. It has had no extended use.
-
-
-Battery, Lead Sulphate.
-A battery similar to Mari� Davy's battery or the gravity battery, but
-using lead sulphate as depolarizer and excitant. Lead, copper or tin is
-the material of the negative plate. Becquerel used the lead sulphate as
-a solid cylindrical mass surrounding a lead rod 1/5 to 1/4 inch in
-diameter. One part of common salt may be mixed with 5 parts of the lead
-sulphate. The electro-motive force is about 0.5 volt. The resistance is
-very high.
-
-
-Battery, Leclanch�.
-An open circuit battery with porous cup. In the outer jar is a zinc rod;
-a carbon plate is placed in the porous cup. The latter is packed with a
-mixture of clean powdered manganese binoxide as depolarizer, and
-graphite in equal volumes. A strong solution of ammonium chloride (sal
-ammoniac) is placed in the outer jar. It is only used on open circuit
-work. Its electromotive force is 1.48 volts, when not polarized.
-
-The reaction is supposed to be about the following:
-
-2 N H4 Cl + 2 Mn O2 + Zn = Zn Cl2 + 2 N H3 + H2 0 + M2 O3
-
-The battery rapidly weakens on open circuit, but quickly recuperates.
-There is another form of this battery, termed the agglomerate battery.
-(See Battery, Leclanch� Agglomerate.)
-
-
-Fig. 46. LECLANCH� BATTERY.
-
-
-Battery, Leclanch� Agglomerate.
-A form of the Leclanch� in which the porous jar is suppressed. Cakes
-made of a mixture of carbon, 52 parts; manganese binoxide, 40 parts; gum
-lac, 5 parts; potassium bisulphate, 3 parts, compressed at 300
-atmospheres, at a temperature of 100� C. (212� F.), are fastened by
-India rubber bands or otherwise against the carbon plate. These
-constitute the depolarizer. Various shapes are given the carbon and
-depolarizing agglomerates.
-
-
-Battery, Local.
-A battery supplying a local circuit (see Circuit. Local). The current is
-governed by the relay situated on the main line and operated by its
-current.
-
-
-Battery, Main.
-The battery used in operating the main line. It is usually applied to
-telegraphy. Its function is then to supply current for working relays,
-which in turn actuate the local circuits.
-
-Main and local circuits and batteries are also used in the automatic
-block system of railroad signalling.
-
-
-67  STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Mari� Davy's.
-A two fluid porous cup battery with carbon negative plate, zinc positive
-plate, and mercury sulphate, a nearly insoluble salt, as depolarizer and
-excitant. Mercurous or mercuric sulphates have been used in it. Its
-electromotive force is 1.5 volts. The local action and waste, owing to
-the slight solubility of the mercury compounds, is very slight. If used
-on close circuit it becomes polarized. It is also subject under extreme
-circumstances to reversal of polarity, zinc becoming deposited upon the
-carbon, and there forming a positive electrode.
-
-In using the cells in series the level of liquid in all must be the
-same, otherwise the cell in which it is lowest will become polarized and
-exhausted.
-
-Modifications of this battery on the lines of the gravity battery have
-been constructed.
-
-Synonym--Sulphate of Mercury Battery.
-
-
-Battery, Maynooth's.
-A battery of the Bunsen type, with cast iron negative plate. The iron
-takes the passive form and is not attacked.
-
-
-Battery, Medical.
-A term applied very indiscriminately to medical current generators, and
-to medical induction coils, or to any source of electricity, static or
-current, for medical application.
-
-
-68   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Meidinger's.
-A variety of Daniell cell of the gravity type. The plates are
-cylindrical. The zinc plate lies against the upper walls of the vessel.
-The copper plate of smaller diameter rests on the bottom. A large tube,
-with an aperture in its bottom, is supported in the centre and is
-charged with copper sulphate crystals. The cup is filled with a dilute
-solution of Epsom salts (magnesium sulphate) or with dilute sulphuric
-acid.
-
-
-Battery Mud.
-A deposit of mud-like character which forms in gravity batteries and
-which consists of metallic copper precipitated by the zinc. It indicates
-wasteful action.
-
-
-Battery, Multiple-connected.
-A battery connected in parallel, all the positive plates being connected
-to one electrode, and all the negative to another.
-
-
-Battery, Nitric Acid.
-A battery in which nitric acid is used as the excitant. Owing to its
-cost and volatility this acid has been but little used in batteries,
-other than as a depolarizer. In Grove's battery (see Battery, Grove's)
-it has been thus used.
-
-
-Battery of Dynamos.
-A number of dynamos may be arranged to supply the same circuit. They are
-then sometimes termed as above, a Dynamo Battery. They may be arranged
-in series or in parallel or otherwise combined.
-
-
-Battery of Leyden Jars.
-To produce the quantity effect of a single large Leyden jar with a
-number of small ones they are often connected in parallel and termed a
-battery. In such case the inner coatings are all connected by regular
-bar conductors, and the outside coatings are also all in connection.
-They are conveniently placed in a box or deep tray whose inner surface
-is lined with tinfoil, with an outside connection for grounding, etc.
-The cascade, q. v., arrangement is not so generally termed a battery.
-
-
-Battery, Open Circuit.
-A battery adapted for use in open circuit work. Its main requirement is
-that it shall not run down, or exhaust itself when left on open circuit.
-The Leclanch� battery is very extensively used for this work. Its action
-is typical of that of most open circuit batteries. It is without any
-action on open circuit. It is very quickly exhausted on closed circuit,
-but recuperates or depolarizes quite soon when on open circuit. It is
-always in condition for a momentary connection, but useless for steady
-work.
-
-
-Battery, Oxide of Copper.
-A battery with zinc positive and iron negative electrodes. The excitant
-is a 30 or 40 per cent. solution of sodium or potassium hydrate (caustic
-soda or caustic potash). The depolarizer is copper oxide. In action the
-copper is gradually reduced to the metallic state. The iron element is
-often the containing vessel. The battery is practically inactive on open
-circuit.
-
-Its electro-motive force varies from .75 to .90 volt. To prevent the
-formation of sodium or potassium carbonate the cell should be closed, or
-else the liquid should be covered with mineral oil.
-
-Synonyms--Lalande & Chaperon Battery--Lalande-Edison Battery.
-
-
-69  STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Peroxide of Lead.
-A battery in which peroxide of lead (lead binoxide) is the depolarizer.
-It is a sort of predecessor of the present secondary battery.
-
-
-Battery, Platinized Carbon.
-A modification of Smee's battery, in which platinized carbon is used for
-the negative plates. Before polarization the E. M. F. is equal to that
-of Smee's battery. Polarization reduces its electro-motive force
-one-half.
-
-
-Battery, Plunge.
-A battery whose plates are mounted so as to be immersed in the battery
-cups or cells, when the battery is to be used, and withdrawn and
-supported out of the cups when not in use. The object is to prevent
-wasting of the plates by standing in the solution. It is a construction
-generally used with sulphuric acid--chromic acid solution and
-amalgamated zinc and carbon plates.
-
-
-Battery, Pneumatic.
-A battery arranged to have air blown through the solution to assist
-diffusion and depolarization. It is a construction applied to chromic
-acid or bichromate batteries.
-
-
-Battery, Primary.
-A battery in which the current is supplied by the solution of one of the
-plates by the solution. The term distinguishes it from a secondary or
-storage battery.
-
-
-Battery, Pulvermacher's Electro-Medical.
-In this battery, the electrodes were zinc and copper wires wound upon
-small pieces of wood. Dilute vinegar was used as the excitant, because
-it could be found in every household. Formerly the battery had great
-success. It is now little used.
-
-
-Battery, Sal Ammoniac.
-Batteries in which a solution of ammonium chloride is the excitant; they
-are very extensively used on open circuit work. (See Battery,
-Leclanch�.)
-
-The crystals formed in these batteries have been analyzed and found to
-consist of ammonium zinc chloride, 3 Zn Cl2, 8 N H3, 4 H20.
-
-
-Battery, Salt, or Sea Salt.
-Batteries in which a solution of sodium chloride or common salt is the
-excitant, have been largely used, especially for telegraphic purposes.
-The Swiss telegraphs use a carbon-zinc combination with salt and water
-as the excitant. The batteries are sometimes mounted as plunge
-batteries. They are exhausted by short circuiting after some hours, but
-recuperate on standing. The zinc is not amalgamated.
-
-
-70   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Sand.
-A battery whose cells are charged with sand saturated with dilute acid.
-It prevents spilling of acid. It is now practically obsolete.
-
-
-Fig. 47. SECONDARY BATTERY.
-
-
-Battery, Secondary.
-A voltaic battery whose positive and negative electrodes are formed or
-deposited by a current from a separate source of electricity by
-electrolysis. On disconnection the battery is ready to yield a current,
-in the reverse direction of that of the charging current. The usual type
-has lead plates on one of which lead binoxide and on the other of which
-spongy lead is formed. The lead binoxide seems to be the negative
-element, and it also acts as the depolarizer. The spongy lead is the
-positive electrode. The solution is dilute sulphuric acid of specific
-gravity 1.17. The action consists first in the oxidation of the spongy
-lead. The hydrogen set free by the reaction, and which by electrolytic
-transfer goes to the other plate, reduces the lead binoxide to
-protoxide. The sulphuric acid then attacks the oxides and converts the
-oxides into sulphates.
-
-The charging process consists in sending a current in the reverse
-direction through the battery. If there are several cells they are
-arranged in series, so that each one receives the same intensity of
-current. An electrolytic decomposition takes place, the lead sulphate on
-one plate is reduced to metallic lead, and that on the other plate is
-oxidized to lead binoxide. It is then ready for use.
-
-
-71  STANDARD ELECTRICAL DICTIONARY.
-
-
-The plates in a lead plate battery are of very large area per cell, and
-are placed close together. Sometimes, as in Plant�'s battery, large flat
-plates are laid together with a separating insulator between them, and
-are then rolled into a spiral. Sometimes, the most usual arrangement,
-the plates are in sets, the positive and negative ones alternating, and
-each cell containing a number of plates.
-
-To secure a good quantity of active material, the plates are sometimes
-perforated, and the perforations are filled with oxide of lead. This
-gives a good depth of material for the charging current to act on, and
-avoids the necessity for a tedious "forming," q. v.
-
-The electro-motive force of such a battery per cell is 2 volts. Its
-resistance may only be one or two-hundredths of an ohm. An intense
-current of many amperes can be supplied by it, but to avoid injuring the
-cell a current far less than the maximum is taken from it.
-
-To charge it, a slightly greater electro-motive force, the excess being
-termed spurious voltage, is required.
-
-
-Fig. 48. SIEMENS' AND HALSKE'S PAPER PULP BATTERY.
-
-
-72   STANDARD ELECTRICAL DICTIONARY.
-
-Battery, Secondary, Plante's.
-Plante's secondary battery is one of the earlier forms of storage
-battery, but has had much success. Two lead plates, large in area and
-close together but not touching, are "formed," by exposure to an
-electrolyzing current of electricity in one direction, while they are
-immersed in dilute sulphuric acid. This converts the surface of one
-plate into binoxide. The cell is then allowed to discharge itself almost
-completely, when the charging current is again turned on. This process
-is repeated over and over again, until the surfaces of the plates are
-considerably attacked, one plate, however, being maintained in a state
-of oxidation. After a few days of this operation a period of rest is
-allowed between the reversals, which sets up a local action on the
-oxidized plate, between the metallic lead of the plate, and its coating
-of binoxide. This causes the lead to be attacked, under the influence of
-the local couple, and sulphate of lead is formed, which, ultimately, by
-the charging current is converted into peroxide. These operations
-produce an exceedingly good battery. The process described is termed
-forming.
-
-The plates separated by strips of insulating material are generally
-wound into a double spiral.
-
-
-Battery, Siemens' and Halske's.
-A Daniell battery of peculiar shape. The copper, C, is at the bottom of
-the glass jar, A. The inner jar, K, has the form of a bell, and supports
-a mass of paper pulp, which is dampened with sulphuric acid. The zinc,
-Z, rests on top of the mass of pulp. The battery is very durable, but of
-high resistance.
-
-
-Battery, Sir William Thomson's.
-A form of Daniell battery, of the gravity type. The receptacles are
-shallow wooden trays lined with lead. A thin plate of copper rests on
-the bottom. The zinc plate is of gridiron shape, and rests on wooden
-blocks which support it in a horizontal position above the copper. One
-tray is placed on top of the other, the upper tray resting on the
-corners of the zinc plate which rise above the level of the top of the
-flat vessel. Thus connection is assured without wires or binding posts.
-It is charged like a gravity battery. The density of the zinc sulphate
-solution should be between 1.10 and 1.30. The circuit must be kept
-closed to prevent deposition of metallic copper on the zinc. The entire
-disposition of the battery is designed to reduce resistance.
-
-
-Battery, Skrivanow.
-A pocket battery of the De la Rue type, with a solution of 75 parts
-caustic potash in 100 parts of water as the excitant. The silver
-chloride is contained in a parchment paper receptacle. Its
-electro-motive force is 1.45 to 1.5 volts.
-
-
-Battery, Smee's.
-A single fluid combination, with zinc positive plate, and a plate of
-silver, coated with platinum black, for the negative plate. The finely
-divided platinum affords a surface from which the hydrogen bubbles
-instantly detach themselves, thus preventing polarization. The liquid is
-a mixture of one part sulphuric acid to seven parts of water. For the
-negative plate silver-plated copper, coated with platinum black, is
-used. Electromotive force, .47 volt.
-
-
-Fig. 49. SMEE'S BATTERY.
-
-
-73  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 50. SPIRAL BATTERY, OR HARE'S DEFLAGRATOR.
-
-
-Battery, Spiral.
-A battery whose plates of thin zinc and copper are wound into a spiral
-so as to be very close, but not touching. Dilute sulphuric acid is the
-excitant. It is now practically obsolete.
-
-Synonyms--Calorimeter--Hare's Deflagrator.
-
-
-Battery, Split.
-A battery of a number of voltaic cells, connected in series, with their
-central portion grounded or connected to earth. This gives the ends of
-opposite potentials from the earth, and of difference therefrom equal to
-the product of one-half of the number of cells employed, multiplied by
-their individual voltage.
-
-
-Battery Solutions, Chromic Acid.
-A number of formulae have been proposed for these solutions. (See
-Electropoion Fluid--Kookogey's Solution--Poggendorff's Solution--
-Trouv�'s Solution--Delaurier's Solution--Chutaux's Solution--Dronier's
-Salt--Tissandier's Solution.)
-
-
-Battery, Trough.
-A battery whose elements are contained in a trough, which is divided by
-cross-partitions so as to represent cups. A favorite wood for the trough
-is teak, which is divided by glass or slate partitions. Marine glue or
-other form of cement is used to make the joints tight. For porous cup
-divisions plates of porous porcelain or pottery are placed across,
-alternating with the impervious slate partitions.
-
-
-Battery, Trouv�'s Blotting Paper.
-A battery of the Daniell type in which the solutions are retained by
-blotting paper. A considerable thickness of blotting paper lies between
-the two plates. The upper half of the thickness of the blotting paper is
-saturated with a solution of zinc sulphate, on which the zinc plate
-rests.
-
-The lower half of the paper is saturated with copper sulphate solution,
-and this rests upon the copper plate.
-
-
-Fig. 51. TROUV�'S BLOTTING PAPER BATTERY.
-
-
-74   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Tyer's.
-A modification, as regards the positive element, of Smee's battery, q.
-v. The bottom of the battery jar contains a quantity of mercury in which
-pieces of zinc are thrown, and this constitutes the positive element.
-
-A ball of zinc at the end of an insulated copper wire affords the
-connection with the zinc and mercury. Its great advantage is that the
-smallest scraps of zinc can be used in it, by being dropped into the
-mercury. The negative plate is platinized silver; the exciting liquid,
-dilute sulphuric acid.
-
-
-Fig. 52. TYER'S BATTERY.
-
-
-75  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 53. SECTION OF UPWARD'S BATTERY.
-
-
-Fig. 54. ELEVATION OF UPWARD'S BATTERY.
-
-
-Battery, Upward's.
-A primary voltaic cell, the invention of A. Ren�e Upward. Referring to
-the cuts, the positive plate. Z, is of cast zinc; it is immersed in
-water, in a porous cup, B. Outside of the porous cup and contained in
-the battery jar are two carbon plates, C, C, connected together. The
-rest of the space between the porous cup and battery jar is packed with
-crushed carbon, and the top is cemented. Chlorine gas is led by a pipe,
-D, into the outer cell. It diffuses through the fine carbon, dissolves
-in the water, and so finds its way to the zinc, which it attacks,
-directly combining therewith, and forming zinc chloride (Zn + 2 Cl = Zn
-Cl 2). Such of the chlorine as is not absorbed finds its way by an outlet
-tube, E, to the next cell. Arrangements are provided for generating
-chlorine gas as required. The high specific gravity of the gas is
-utilized in regulating its distribution through the cells. The
-electro-motive force of the cell is 2.1 volts. A cell 11.5 by 5.5 inches
-and 12.5 inches deep has a resistance of 0.2 ohm.
-
-An overflow pipe, F, with faucet, T, is supplied to withdraw the
-solution of zinc chloride as it accumulates.
-
-
-76   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Varley's.
-A Daniell battery of the Siemens' and Halske's type (see Battery,
-Siemens' and Halske's), in which zinc oxide is substituted for the paper
-pulp of the other battery. It has been very little used.
-
-
-Battery, Volta's.
-The original acid battery. It has a negative electrode of copper, a
-positive electrode of zinc; the excitant is sulphuric acid diluted with
-sixteen times its volume of water. It rapidly polarizes, and is very
-little used.
-
-
-Battery, Voltaic or Galvanic.
-An apparatus for converting chemical energy directly into electric
-energy. This is as broad a definition as can well be given. The general
-conception of a battery includes the action of electrolysis, a solution
-in the battery acting upon one of two conducting electrodes immersed in
-such fluid, which dissolves one of them only, or one more than the
-other. The best way to obtain a fundamental idea of a battery is to
-start with the simplest. Dilute sulphuric acid dissolves neither pure
-zinc nor copper. But it has a far stronger affinity for the first named
-metal. If now we immerse in dilute acid two plates, one of pure zinc,
-and one of copper, no action will be discernible. But if the plates are
-brought in contact with each other a stream of bubbles of hydrogen gas
-will escape from the surface of the copper and the zinc will dissolve.
-By applying proper tests and deductions it will be found that the copper
-and zinc are being constantly charged with opposite electricities, and
-that these are constantly recombining. This recombination produces what
-is known as an electric current.
-
-To constitute a battery the zinc and copper plates must be connected
-outside of the solution. This connection need not be immediate. Any
-conductor which touches both plates will bring about the action, and the
-current will pass through it.
-
-The easiest way to picture the action of a battery is to accept the
-doctrine of contact action. In the battery the molecules of water are
-pulled apart. The hydrogen molecules go to the copper, the oxygen
-molecules go to the zinc, each one, leaving its contact with the other,
-comes off charged with opposite electricity. This charges the plates,
-and the continuous supply of charge and its continuous discharge
-establishes the current.
-
-The accumulation of hydrogen acts to stop the action by polarization.
-Its own affinity for oxygen acts against or in opposition to the
-affinity of the zinc for the same element, and so cuts down the action.
-A depolarizer of some kind is used in acid batteries for this reason. As
-such depolarizer has only to act upon one plate, in most batteries it is
-usual to surround such plate only, as far as it is possible, with the
-depolarizer. The solution which dissolves the zinc is termed the
-excitant or exciting solution.
-
-To this concrete notion of a voltaic battery the different modifications
-described here may be referred. Zinc, it will be seen, forms the almost
-universally used dissolved plate; carbon or copper forms the most usual
-undissolved plate; sulphuric acid in one form or another is the most
-usual excitant.
-
-The solution in a voltaic battery is electrolyzed (see Electrolysis).
-Hence the solutions must be electrolytes. The sulphuric acid and other
-ingredients play a secondary role as imparting to the battery fluids
-this characteristic.
-
-It is not necessary to have electrodes of different substances, the same
-metal maybe used for both if they are immersed in different solutions
-which act differentially upon them, or which act with more energy on one
-than on the other. Such are only of theoretical interest.
-
-
-77  STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Water.
-A voltaic battery, whose exciting fluid is water. They are used for
-charging quadrant electrometer needles and similar purposes. They
-polarize very quickly and are of high resistance. Hence very small
-plates in large number can be used without impairing their advantage.
-
-Rowland's water battery dispenses with cups and uses capillarity
-instead. The zinc and platinum or copper plates of a couple are placed
-very close together, while the couples are more distant. On dipping into
-water each couple picks up and retains by capillarity a little water
-between its plates, which forms the exciting fluid. Many hundred couples
-can be mounted on a board, and the whole is charged by dipping into
-water and at once removing therefrom. It then develops its full
-potential difference.
-
-
-Fig. 55. SECTION OF WOLLASTON BATTERY.
-
-
-Fig. 56. PLATES OF WOLLASTON'S BATTERY.
-
-
-78   STANDARD ELECTRICAL DICTIONARY.
-
-
-Battery, Wollaston.
-The original plunge battery is attributed to Wollaston. He also invented
-the battery known by his name, having the disposition shown in the cut,
-of zinc Z, surrounded by a thin sheet of copper C; o, o', o", are the
-terminals and B, B, the battery jars. Dilute sulphuric acid is used for
-exciting fluid.
-
-
-B. A. U.
-Abbreviation for British Association unit, referring generally to the B.
-A. unit of resistance.
-
-
-B. A. Unit of Resistance.
-The original ohm used under that name previous to 1884. The Paris
-committee of that year recommended as a practical unit what is known as
-the legal ohm. (See Ohm, Legal.)
-  1  Legal Ohm                 =  1.0112      B. A. Units of Resistance.
-  1  B. A. Unit of Resistance  =   .9889      Legal Ohms.
-  1  B. A. Unit of Resistance  =   .98651E9   C. G. S. units.
-
-
-B. E. adj.
-British Engineering, a qualification of a set of units, the B. E. units,
-having for base the foot and pound. The term is but little used.
-
-
-Beaum� Hydrometer.
-A hydrometer graduated on the following principle:
-
-The zero point corresponds to the specific gravity of water for liquids
-heavier than water. A solution of 15 parts of salt in 85 parts of water
-corresponds in specific gravity to 15� B., and between that and zero
-fifteen equal degrees are laid out. The degrees are carried down below
-this point.
-
-The zero points for liquids lighter than water correspond to the
-specific gravity of a solution of 10 parts of salt in 90 parts of water.
-The specific gravity of water is taken as 10� B. This gives ten degrees
-which are continued up the scale.
-
-
-Becquerel's Laws of Thermoelectricity.
-These are stated under the heads, Law of Intermediate Metals and Law of
-Successive Temperatures, q. v.
-
-
-Bed Piece.
-In a dynamo or motor the frame carrying it, including often the
-standards in which the armature shaft is journaled, and often the yoke
-or even entire field magnet core.
-
-
-Bell, Automatic Electric.
-A bell which rings as long as the circuit is closed, having a circuit
-breaker operated by its own motion. (See Bell, Electric.)
-
-Synonyms--Trembling Bell--Vibrating Bell.
-
-
-Bell, Call.
-A bell operated by electricity, designed to call attention, as to a
-telephone or telegraphic receiver. (See Bell, Electric.)
-
-
-79  STANDARD ELECTRICAL DICTIONARY.
-
-
-Bell Call.
-A calling device for attracting the attention of any one, consisting of
-some type of electric bell.
-
-
-Bell, Circular.
-A gong-shaped bell, whose clapper and general mechanism is within its
-cavity or behind it.
-
-
-Bell, Differentially Wound.
-An electric bell, whose magnet is wound differentially so as to prevent
-sparking.
-
-
-Fig 57. AUTOMATIC ELECTRIC BELL.
-
-
-Bell, Electric.
-A bell rung by electricity. Generally it is worked by a current exciting
-an electro-magnet, attracting or releasing an armature which is attached
-to the vibrating or pivoted tongue of the bell. It may be worked by a
-distant switch or press-button, q. v., ringing once for each movement of
-the distant switch, etc., or it may be of the vibrating bell type as
-shown in the cut. When the current is turned on in this case it attracts
-the armature. As this moves towards the poles of the magnet it breaks
-the circuit by drawing the contact spring, q. v., away from the contact
-point, q. v. This opens the circuit, to whose continuity the contact of
-these two parts is essential. The hammer, however, by its momentum
-strikes the bell and at once springs back. This again makes the contact
-and the hammer is reattracted. This action continues as long as the
-circuit is closed at any distant point to which it may be carried. The
-ordinary vibrating bell is a typical automatic circuit breaker, q. v.,
-this type keeping up the ringing as long as the circuit is closed. Other
-bells have no electric contact and simply ring once every time the
-circuit is closed. Others worked by an alternating current ring once for
-each change of direction of current.
-
-
-80   STANDARD ELECTRICAL DICTIONARY.
-
-
-Bell, Electro-mechanical.
-A bell which has its striking train operated by a spring or descending
-weight, and which train is thrown into action by the release of a detent
-or equivalent action by the closing of an electric circuit. It rings for
-any given time after being started.
-
-
-Bell, Indicating.
-A bell which by drop-shutter or other indicator connected in circuit
-with it, indicates its number or other designation of its call.
-
-
-Bell, Magneto.
-An electric bell operated by the alternating current from a magneto
-generator. It has a polarized armature and no circuit breaker. The
-armature is attracted first in one direction and then in the other, as
-the current alternates and reverses the polarity of the electro-magnet.
-
-
-Bell, Relay.
-A bell operated by a relay circuit.
-
-
-Bias.
-In polarized relay the adjustment of the tongue to lie normally against
-one or the other contact. (See Relay, Polarized.)
-
-
-81   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 58. RESISTANCE COILS SHOWING BIFILAR WINDING.
-
-
-Bifilar Winding.
-The method followed in winding resistance coils to prevent them from
-creating fields of force. The wire is doubled, and the doubled wire
-starting with the bend or bight is wound into a coil. The current going
-in opposite senses in the two lays of the winding produces no field of
-force.
-
-
-Binary Compound.
-A chemical compound whose molecule contains only two elements, such as
-water (H2 0), lead oxide (Pb 0), and many others.
-
-
-Binding.
-In a dynamo or motor armature the wire wound around the coils to secure
-them in place and prevent their disturbance by centrifugal action.
-
-
-Fig. 59. DOUBLE BINDING POST.
-
-
-Fig. 60. BINDING POST, ENGLISH PATTERN.
-
-
-FIG. 61. WOOD SCREW BINDING POST.
-
-
-Binding Posts or Screws.
-Arrangements for receiving the loose end of a wire of an electric
-circuit, and securing such end by a screw. Several constructions are
-used, as shown here. Sometimes the wire is passed through a hole, and a
-screw tapped in at right angles to the hole is screwed down upon the
-wire. Sometimes the wire is clamped between two shoulders, one on the
-screw, the other on the post. The screw is often a flat-headed thumb
-screw or has a milled edge. Sometimes the screw has a slot and is turned
-by a screw-driver.
-
-Several openings are often provided in the same post for different
-wires.
-
-
-Binnacle.
-The case containing a mariner's compass on shipboard. It is enclosed
-completely; it has a glass side or window through which the compass can
-be seen, and is provided with one or two lamps arranged to light the
-card, while showing as little light as possible outside.
-
-
-82   STANDARD ELECTRICAL DICTIONARY.
-
-
-Bioscopy, Electric.
-The diagnosis of life and death by the action of the animal system when
-subjected to an electric current or electrification.
-
-
-Bismuth.
-A metal, one of the elements, atomic weight, 210 ; equivalent, 70;
-valency, 3; specific gravity, 9.9. It is a conductor of electricity.
-Relative Resistance, compressed, (silver = 1)   87.23
-Specific Resistance,   131.2 microhms
-Resistance of a wire
-  (a) 1 foot long,  weighing 1 grain,     18.44   ohms
-  (b) 1 foot long,  1/1000 inch thick,   789.3  "
-  (c) 1 meter long, weighing 1 gram,      12.88   "
-  (d) 1 meter long, 1 millimeter thick,    1.670   "
-Resistance of a 1-inch cube   51.65   microhms
-Electro chemical equivalent,   .7350
-(Hydrogen = .0105)
-(See Thermo-electric Series.)
-
-
-FIGS. 62, 63. INCANDESCENT WIRE FUSE.  ABEL'S PATENT.
-
-
-FIG 64.  VON EBNER'S FRICTIONAL ELECTRIC MACHINE FOR
-EXPLODING ELECTRIC FUSES OR DETONATORS.
-
-
-Bi-telephone.
-A pair of telephones arranged with a curved connecting arm or spring, so
-that they can be simultaneously applied to both ears. They are
-self-retaining, staying in position without the use of the hands.
-
-
-83  STANDARD ELECTRICAL DICTIONARY.
-
-
-Blasting, Electric.
-The ignition of blasting charges of powder or high explosives by the
-electric spark, or by the ignition to incandescence (red or white heat)
-of a thin wire immersed in or surrounded by powder. Special influence or
-frictional electric machines or induction coils are used to produce
-sparks, if that method of ignition is employed. For the incandescent
-wire a hand magneto is very generally employed. (See Fuse, Electric.)
-
-The cuts, Figs. 62 and 63, show one form of incandescent wire fuse. The
-large wires are secured to the capsule, so that no strand can come upon
-the small wire within the cavity.
-
-The cut, Fig. 64, shows a frictional electric machine for igniting spark
-fuses.
-
-
-Bleaching, Electric.
-Bleaching by agents produced or made available by the direct action of
-electricity. Thus if a current under proper conditions is sent through a
-solution of common salt (sodium chloride), the electrodes being close
-together, the salt is decomposed, chlorine going to one pole and sodium
-hydrate to the other. The two substances react upon each other and
-combine, forming sodium hypochlorite, which bleaches the tissue immersed
-in its solution.
-
-
-Block System.
-A system of signalling on railroads. The essence of the system consists
-in having signal posts or stations all along the road at distances
-depending on the traffic. The space between each two signal posts is
-termed a block. From the signal posts the trains in day time are
-signalled by wooden arms termed semaphores, and at night by lanterns.
-The arms may be moved by hand or by automatic mechanism depending in
-part on electricity for carrying out its functions. Thus in the
-Westinghouse system the semaphores are moved by pneumatic cylinders and
-pistons, whose air valves are opened and shut by the action of solenoid
-magnets, q. v. The current of these magnets is short circuited by
-passing trains, so as to let the valves close as the train passes the
-signal post. The block system causes the semaphore to be set at "danger"
-or "caution," as the train enters the next block. Then the following
-train is not allowed to enter the block until the safety signal is
-shown. The Westinghouse system provides for two semaphores on a post,
-one indicating "danger" as long as the train is on the next block; the
-other indicating "caution" as long as the train is on the next two
-blocks. The rails form part of the circuit, their joints being bridged
-by copper wire throughout the block, and being insulated where the
-blocks meet.
-
-
-Block Wire.
-In the block system a wire connecting adjacent block-signal towers or
-semaphore poles.
-
-
-Blow-pipe.
-A name sometimes given to an electric experiment illustrating the
-repulsion of electrified air particles from a point held at high
-relative potential. A metallic point, placed on the prime conductor of
-an electric friction or influence machine, becomes highly electrified,
-and the air becoming excited is repelled and acts upon the candle flame.
-If the candle is placed on the conductor and a point held towards it the
-repulsion is still away from the point.
-
-
-84   STANDARD ELECTRICAL DICTIONARY.
-
-
-Blow-pipe, Electric Arc.
-A name sometimes given to devices for using the voltaic arc to produce
-local heating effects. The directive action of the magnet may be used to
-force out the arc like a blow-pipe flame, or a blast of air may be
-directly applied for the same purpose.
-
-
-Blue-stone.
-A trade name for crystallized copper sulphate, used in Daniell's and
-gravity batteries.
-
-
-Boat, Electric.
-A boat propelled by electricity. The electricity drives a motor which
-actuates a screw propeller. The current is generally supplied by a
-storage battery. When used on rivers charging stations are established
-at proper places. When the boat is used as a tender or launch for a
-steam ship, such as a war-vessel, the battery is charged by a plant on
-board the ship. From their noiselessness electric boats are peculiarly
-available for nocturnal torpedo operations, and the universal equipment
-of modern war-ships with electric lightning and power plants makes their
-use possible at all points. This type is often termed an electric
-launch, and most or all electric boats fall under this category.
-
-
-Bobbins.
-A spool of wood or other material wound with insulated wire. In a
-tangent galvanometer the bobbin becomes a ring, with a channel to
-receive the winding. As the ring is not infinitely large compared to the
-needle the tangent law is not absolutely fulfilled. It is most
-accurately fulfilled (S. P. Thomson) when the depth of the groove or
-channel in the radial direction bears to the breadth in the axial
-direction the ratio of square root of 3 to the square root of 2 or
-approximately 11 : 9
-
-
-Body Protector.
-A metallic short circuit connected with the wrists and lower legs of the
-human body, so that if by accident an active circuit is grounded by the
-hands and body of the workman wearing it, most of the current will pass
-through the wire conductors, thus avoiding the vital organs of the body.
-
-
-Boiler Feed, Electric.
-An apparatus by which an electric current acting on an electro-magnet,
-or other equivalent device, opens the water supply when the water level
-in a boiler sinks too low, and cuts off the water supply as the water
-level rises.
-
-
-Boiling.
-In secondary batteries the escape of hydrogen and oxygen gas when the
-battery is charged. The bubbling of the escaping gases produces the
-effect of boiling.
-
-
-85  STANDARD ELECTRICAL DICTIONARY.
-
-
-Boll.
-An absolute, or c. g. s., unit of momentum; a gram moving at the rate of
-one centimeter per second; a gram-kine (see Kine); a unit proposed by
-the British Association.
-
-
-Bolometer.
-An apparatus for detecting small amounts of radiant energy (radiant
-heat, so called). A coil suspended by a fine wire or filament so as to
-be free to rotate under the effect of force is made up of two parallel
-and equal wires, insulated from each other, but connected so that
-parallel currents sent through them go in opposite direction through
-each. This coil is hung in a strong electro-magnetic field produced by a
-large coil surrounding it. When a current passes through the suspended
-coil no effect will follow, because the oppositely wound portions
-counteract each other exactly. In the circuit with one half of the
-suspended coil is an exceedingly thin strip of platinum wire. The other
-half of the coil has no strips. Both halves unite after leaving the
-coil. If now the strip of platinum is heated its conductivity is
-affected and its half of the coil receives less current than the other
-half. This disturbs the balance and the coil swings through a small arc.
-This apparatus may be made very sensitive, so that an increase of
-temperature of 1/1400� F., 9/70000�C. (1/14000� F.) will be perceptible.
-Another construction takes the form of a Wheatstone Bridge, q. v., in
-whose arms are introduced resistances consisting of bands of iron, .5
-Millimeter wide (.02 inches), .004 millimeter (.00016 inch) thick, and
-folded on themselves 14 times so as to make a rectangular grating, 17 x
-12 millimeters (.68 x .48 inch). The least difference of heat applied to
-the grating affects the galvanometer.
-
-Synonym-Thermic Balance.
-
-
-Boreal Pole.
-The south pointing pole of the magnet. (See Austral Pole.)
-
-
-Bot.
-A colloquial expression for the English Board of Trade unit of
-Electrical Supply. It is formed of the initials of the words "Board of
-Trade." (See Unit, Board of Trade.)
-
-
-Box Bridge.
-A constriction of Wheatstone's Bridge in which the necessary resistance
-coils are contained in a single box with plugs for throwing the coils in
-and out of circuit, and connections to bring the coils into the
-different arms of the system. The cut shows a box bridge. Connections
-for the galvanometer, battery wires, and terminals of the unknown
-resistance are provided, by which its resistances and the connections
-are brought into the exact relations indicated in the conventional
-diagram of Wheatstone's bridge. (See Wheatstone's Bridge.)
-
-Referring to the cut, the battery wire, say from the zinc plate,
-connects at A1, thereby reaching A, its true connecting point. To B1 one
-end of the galvanometer circuit or lead is attached, thereby reaching B,
-its true connecting point. To C are connected the other end from the
-galvanometer and one end of the unknown resistance. The other end of the
-unknown resistance, and the other end of the battery wire, in this case
-from the carbon plate, connect to D. At G is an infinity plug, as it is
-called. When out it breaks the circuit.
-
-In use after the connections are made the key is depressed and the
-galvanometer observed. The resistance is changed until no action of the
-galvanometer is produced by closing the circuit when the ratio of the
-resistances of the arms gives the proportion for calculating the unknown
-resistances.
-
-Synonym--Commercial Wheatstone Bridge, or commercial form of same.
-
-
-Fig. 65. TOP OF BOX BRIDGE.
-
-
-86   STANDARD ELECTRICAL DICTIONARY.
-
-
-Boxing the Compass.
-Naming the thirty-two points of the compass in order, and in sequence to
-any point called out at random. There are many exercises in the relative
-sailing points and bearings that come under the same head. Thus the
-direction of two given points being given by names of the compass
-points, it may be required to state the number of points intervening.
-
-
-Brake, Electro-magnetic.
-A brake to stop a wheel from rotating. It comprises a shoe, or sometimes
-a ring, which by electro-magnetic attraction is drawn against the
-rotating wheel, thus preventing it from turning, or tending to bring it
-to rest. (See Electro-magnet, Annular.)
-
-
-Fig. 66. ELECTRIC BRAKE.
-
-
-87  STANDARD ELECTRICAL DICTIONARY.
-
-
-Branch.
-A conductor branching from a main line. Sometimes the term is restricted
-to a principal conductor, from which current is distributed.
-
-
-Branch Block.
-In electric wiring of buildings, a block of porcelain or other material
-with grooves, holes and screws for the connection of branch wires to a
-main wire. Its functions are not only to afford a basis for connecting
-the wires, but also to contain safety fuses. As when a branch wire is
-taken off, fuses have to be put in its line, the branch block carries
-these also. One end of each fuse connects with a main wire, the other
-end connects with one of the wires of the branch leader or wire.
-
-Porcelain is a favorite material for them, as the fusing or "blowing
-out" of the safety fuses cannot set it on fire.
-
-
-Branch Conductor.
-A parallel or shunt conductor.
-
-
-Brazing, Electric.
-Brazing in which the spelter is melted by means of electricity; either
-current incandescence or the voltaic arc may be used. It is identical in
-general with electric welding. (See Welding, Electric.)
-
-
-Branding, Electric.
-A system of branding in which the heat of electrically ignited or
-incandescent conductors is used to produce or burn in the marks upon the
-surface. For the alternating current a small transformer is connected to
-or forms part of the tool.
-
-
-88   STANDARD ELECTRICAL DICTIONARY.
-
-
-Brassing.
-The deposition of a coating of brass by electrolysis. The plating bath
-contains both copper and zinc. As anode a plate of brass is used. The
-operation must be constantly watched. The deposition of both metals goes
-on simultaneously, so  that a virtual alloy is deposited. By changing
-the depth of immersion of the anode the color of the deposit is varied.
-
-As a formula for a brassing bath the following are typical. They are
-expressed in parts by weight.
-
-(a) For iron and steel.
-I.
-  Sodium Bisulphate,                 200
-  Potassium Cyanide, 70 per cent.,   500
-  Sodium Carbonate,                1,000
-  Water,                           8,000
-II.
-  Copper Acetate,                    125
-  Zinc Chloride,                     100
-  Water,                           2,000
-Add the second solution to the first.
-
-(b) For zinc.
-I.
-  Sodium Bisulphate,                 700
-  Potassium Cyanide, 70 per cent., 1,000
-  Water,                          20,000
-II.
-  Copper Acetate,                    350
-  Zinc Chloride,                     350
-  Aqua Ammoniae,                     400
-  Water,                           5,000
-Add the second solution to the first.
-
-Use a brass anode; add more zinc to produce a greenish color; more
-copper for a red color. A weak current gives a red color; a strong
-current lightens the color. The battery power can be altered, a larger
-or smaller anode can be used, or a copper or zinc anode can be used to
-change the color of the deposit. The bath may vary from 1.036 to 1.100
-sp. gr., without harm.
-
-
-Break.
-A point where an electric conductor is cut, broken, or opened by a
-switch or other device, or simply by discontinuity of the wires.
-
-
-Break-down Switch.
-A switch used in the three-wire system to provide for the discontinuance
-of the running of one of the dynamos.
-
-By connecting the positive and negative bus wires to one terminal of the
-active dynamo, and the neutral bus wire to the other terminal, one
-dynamo will supply the current and the system operates like a two-wire
-system, but can only be used for half its normal capacity.
-
-
-Breaking Weight.
-The weight which, applied in tension, will break a prism or cylinder, as
-an electric current conductor.
-
-
-89  STANDARD ELECTRICAL DICTIONARY.
-
-
-Breath Figures, Electric.
-If a conductor is electrified and placed upon a piece of glass, it will
-electrify the glass in contact with it by conduction or discharge. On
-removing the conductor the glass remains electrified. The localized
-electrification is shown by breathing gently on the glass, when a
-species of image of the conductor is produced by the condensed moisture.
-A coin is often used for conductor.
-
-
-Breeze, Electric.
-A term in medical electricity, used to designate the silent or brush
-discharge of high tension electricity. As an instance of its employment,
-the electric head bath (see Bath, Electric Head,) may be cited. The
-patient forming one electrode, being insulated and connected to one of
-the conductors, the other conductor, on being brought near his person,
-discharges into his body.
-
-
-Bridge.
-(a) A special bar of copper connecting the dynamos to the bus wire, q. v.,
-in electric lighting or power stations.
-
-(b) Wheatstone's bridge, q. v., and its many modifications, all of which
-may be consulted throughout these pages.
-
-
-British Association Bridge.
-The type of Wheatstone bridge used by the committee of the association
-in determining the B. A. ohm; the meter bridge, q. v.
-
-
-Broadside Method.
-A method of determining the magnetic moment of a magnet. The magnet, n,
-s, under examination is fixed so that it is at right angles to the
-magnetic meridian, M, R, which passes through its own center and that of
-a compass needle. From the deflection of the latter the moment is
-calculated.
-
-
-FIG 67. BROADSIDE METHOD.
-
-
-Bronzing.
-In electro-plating the deposition of a mixture or virtual alloy of
-copper and tin. In general manipulation it resembles the operation of
-depositing gold and silver alloy, or of brassing.
-
-For bronzing the following bath is recommended:
-
-Prepare each by itself (a) a solution of copper phosphate and (b) a
-solution of stannous chloride in a solution of sodium pyrophosphate. For
-a, dissolve recently precipitated copper phosphate in concentrated
-solution of sodium pyrophosphate. For b, add to a saturated solution of
-sodium pyrophosphate solution of stannous chloride as long as the
-precipitate which is formed dissolves. Of these two solutions add to a
-solution of sodium pyrophosphate which contains about 1.75 oz. of the
-salt to the quart, until the precipitate appears quickly and of the
-desired color. For anodes use cast bronze plates. Sodium phosphate must
-be added from time to time; if the deposit is too light add copper
-solution, if too dark add tin solution. (W. T. Brannt.)
-
-
-90   STANDARD ELECTRICAL DICTIONARY.
-
-
-Brush.
-In electric current generators and motors, the pieces of copper or other
-material that bear against the cylindrical surface of the commutator are
-thus termed. Many different constructions have been employed. Some have
-employed little wheels or discs bearing against and rotating on the
-surface of the commutator. A bundle of copper strips is often employed,
-placed flatwise. Sometimes the same are used, but are placed edgewise.
-Wire in bundles, soldered together at their distant ends have been
-employed. Carbon brushes, which are simply rods or slabs of carbon, are
-used with much success.
-
-Synonym--Collecting Brush.
-
-
-Brush, Carbon.
-A brush for a dynamo or motor, which consists of a plate or rod of
-carbon, held in a brush holder and pressed against the commutator
-surface.
-
-
-Brushes, Adjustment of.
-In electric current generators and motors, the brushes which bear upon
-the commutator when the machine is in action need occasional adjustment.
-This is effected by shifting them until sparking between them and the
-commutator is nearly or quite suppressed.
-
-
-Fig. 68. BRUSH HOLDER.
-
-
-Brushes, Lead of.
-In a dynamo electric generator, the lead or displacement in advance of
-or beyond the position at right angles to the line connecting the poles
-of the field magnet, which is given the brushes. In a motor the brushes
-are set back of the right angle position, or are given a negative lead.
-(See Lag.)
-
-
-91  STANDARD ELECTRICAL DICTIONARY.
-
-
-Brush Holders.
-The adjustable (generally) clutch or clamps for holding the commutator
-brushes of a dynamo, which keep them in contact with the commutator, and
-admit of adjustment by shifting backward and forward of the brushes to
-compensate for wear. They are connected to and form part of the rocker,
-q. v. By rotating the latter the brush-holders and brushes are carried
-in one direction or other around the commutator, so as to vary the lead
-as required.
-
-
-Brush, Pilot.
-A third brush, used for application to different parts of a revolving
-armature commutator to determine the distribution of potential
-difference between its different members. (See Curve of Distribution of
-Potential in Armature.) One terminal of a volt-meter is connected to one
-of the regular brushes, A, of a dynamo; the other to a third brush, p,
-which is pressed against different portions of the commutator of the
-dynamo. The readings of the volt-meter are plotted in a curve of
-distribution of potential.
-
-
-Fig. 69. PILOT BRUSH.
-
-
-Brush, Rotating.
-Brushes for taking off the current from dynamo commutators, or giving
-current connection to motors, whose ends are in the form of rollers
-which rotate like little wheels, and press against the commutator
-surface.
-
-
-Brush, Third.
-A third brush is sometimes provided in a dynamo for regulating purposes.
-Applied to a series machine it adjoins one of the regular brushes and
-delivers its current to a resistance, to whose further end the regular
-circuit is connected. By a sliding connection the resistance is divided
-between the third brush circuit and the regular circuit, and by varying
-the position of this contact regulation is obtained.
-
-It is to be distinguished from the pilot brush used for determining the
-characteristic of the commutator, although based on the same general
-principles.
-
-
-Fig. 70. THIRD BRUSH REGULATION.
-
-
-92   STANDARD ELECTRICAL DICTIONARY.
-
-
-Brush, Wire Gauze.
-A collecting or commutator brush for a dynamo or motor, which brush is
-made of wire gauze rolled up and compressed into shape.
-
-
-Buckling.
-The bending up and distortion of secondary battery plates. It is largely
-due to over-exhausting the batteries. Where the E. M. F. is never
-allowed to fall below 1.90 volt it is far less liable to occur.
-
-
-Bug.
-Any fault or trouble in the connections or working of electric
-apparatus.
-
-
-Bug Trap.
-A connection or arrangement for overcoming a "bug." It is said that the
-terms "bug" and "bug trap" originated in quadruplex telegraphy.
-
-
-Bunsen Disc.
-In photometry, the Bunsen Disc is a piece of paper upon whose centre a
-spot is saturated with melted paraffin, or a ring of paraffined surface
-surrounds an untouched central spot. If placed in such a position that
-it receives an equal illumination on each side, the spot almost
-disappears. It is used on the bar photometer. (See Photometer, Bar.)
-
-Synonym--Grease Spot.
-
-
-93  STANDARD ELECTRICAL DICTIONARY.
-
-
-Buoy, Electric.
-A buoy for use to indicate channels or dangers in harbors and elsewhere,
-which carries an electric light, whose current is supplied by cable from
-shore. It has been proposed to use glass tubes exhausted of air and
-containing mercury, which, as moved by the waves, would produce a
-luminous effect. A fifty-candle power incandescent lamp is an approved
-source of light.
-
-
-Burner, Electric Gas.
-A gas burner arranged for the flame to be lighted by electricity. It
-takes a great variety of forms. In some cases a pair of terminals are
-arranged near the flame or a single terminal is placed near the metal
-tip, the latter forming one of the terminals. The spark is generally
-produced by an induction coil, or a spark coil. The gas may first be
-turned on and the spark then passed. Sometimes the turning of the gas
-cock of an individual burner makes and breaks a contact as it turns, and
-thereby produces simultaneously with the turning on of the gas a spark
-which lights it.
-
-Another form is wholly automatic. A pair of electro-magnets are attached
-below the base of the burner, one of which, when excited, turns on the
-gas, and the other one when it is excited turns it off. At the same time
-a spark is produced with the turning on of the gas so that it is
-lighted. Thus, by use of a automatic burner, a distant gas burner can be
-lighted by turning an electric switch. An out-door lamp may be lighted
-from within a house.
-
-The increasing use of electric incandescent lamps, lighted by the
-turning of a switch, tends to displace electric gas burners. The latter
-have been classified into a number of types depending on their
-construction.
-
-Burners are sometimes connected in series with leads from an induction
-coil. Then the gas is turned on all at once, and a succession of sparks
-passed until the gas is all lighted. The ignition is practically
-instantaneous.
-
-
-Button, Push.
-A species of switch which is actuated by the pressure of a button. In
-its normal position the button is pressed outwards by a spring, and the
-circuit is open. When pressed inwards, it closes the circuit. When
-released it springs backward and opens the circuit again.
-
-They are principally used for ringing bells. If the latter are of the
-automatic type, they ring as long as the button is pressed.
-
-For door-bells and room-bells, the button often occupies the center of a
-rosette of wood or bronze or other ornamental piece. Sometimes, as shown
-in the cut, they are constructed for use on floors to be pressed by the
-foot. The general principle of their construction is shown, although the
-method of making the contact varies.
-
-Synonym--Press Button.
-
-
-Fig. 71. FLOOR PUSH BUTTON.
-
-
-94   STANDARD ELECTRICAL DICTIONARY.
-
-
-Burning.
-(a) In a dynamo, the production of shifting and temporary arcs between
-the commutator and brushes, which arcs produce heat enough to injure the
-parts in question.
-
-(b) In electro-plating, a defect due to too strong a current in
-proportion to the strength of solution and area of electrodes. This
-gives a black or badly-colored deposit.
-
-
-Bus Rod.
-A copper conductor used in electric lighting or power stations, to
-receive the current from all the dynamos. The distributing leads are
-connected to the bus wires.
-
-In the three-wire system there are three; in the two-wire system there
-are two bus wires.
-
-The name is undoubtedly derived from "omnibus."
-
-The bus wires may be divided into positive, negative, and, in the
-three-wire system, neutral bus wires.
-
-Synonyms--Omnibus Rod, Wire, or Bar--Bus Bar, or Wire.
-
-
-Buzzer.
-An electric alarm or call produced by a rapid vibration of electric make
-and break mechanism, which is often magnified by enclosure in a
-resonating chamber, resembling a bell, but which is not struck or
-touched by the vibrating parts. Sometimes a square wooden box is used as
-resonator.
-
-
-Fig. 72. BUZZER.
-
-
-95  STANDARD ELECTRICAL DICTIONARY.
-
-
-B. W. G.
-Abbreviation for Birmingham Wire Gauge. (See Wire Gauge, Birmingham.)
-
-
-C.
-(a) Abbreviation for Centigrade, as 100 C., meaning 100 Centigrade. (See
-Centigrade Scale.)
-
-(b) A symbol of current or of current strength. Thus in the expression
-of Ohm's law C = E/R. C indicates current strength or intensity, not in
-any fixed unit, but only in a unit of the same order in which E and R
-are expressed; E Indicating electro-motive force and R resistance.
-
-
-Cable.
-(a) Abbreviation for Cablegram, q. v.
-
-(b) v. It is also used as a verb, meaning to transmit a message by
-submarine cable.
-
-(c). An insulated electric conductor, of large diameter. It often is
-protected by armor or metallic sheathing and may be designed for use as
-an aerial, submarine, subterranean or conduit cable. A cable often
-contains a large number of separately insulated conductors, so as to
-supply a large number of circuits.
-
-
-Cable, Aerial.
-A cable usually containing a large number of separately insulated wires,
-and itself insulated. It is suspended in the air. As its weight is
-sometimes so great that it could not well sustain it, a suspending wire
-is in such cases carried along with it, to which it is suspended by
-cable hangers, q. v.
-
-
-Cable Box.
-A box for receiving underground cable ends and connecting the separate
-wires of the cable to air-line wires. It is often mounted on a pole,
-which forms the starting point of the air-line portion of the system.
-
-
-Cable, Bunched.
-A cable containing a number of separate and individual conductors. In
-some forms it consists virtually of two or more small cables laid
-tangent to each other and there secured. Thus each in section represents
-two or more tangent circles with the interstice solidly filled with the
-metal sheathing.
-
-
-Cable, Capacity of.
-The electrostatic capacity of a cable. A cable represents a Leyden jar
-or static condenser. The outer sheathing or armor, or even the more or
-less moist coating, if it is unarmored, represents one coating. The wire
-conductors represent the other coating, and the insulator is the
-dielectric.
-
-The capacity of a cable interferes with its efficiency as a conductor of
-broken or interrupted currents, such as are used in telegraphy or
-telephoning. As each impulse or momentary current is sent into the line,
-it has to charge the cable to at least a certain extent before the
-effects of the current are perceptible at the other end. Then the cable
-has to discharge itself. All this creates a drag or retardation.
-
-The capacity of a cable is used to determine the locality of breaks in
-the continuity of the conductors. The capacity per unit of length being
-accurately known, it is obvious that, if the conductor breaks without
-disturbance of the insulator, the distance of the break from the end can
-be ascertained by determining the capacity of the cable from one end.
-This capacity will be in proportion to the capacity of a mile, a knot or
-any fixed unit, as the distance to the break is to the length used as
-standard.
-
-
-96   STANDARD ELECTRICAL DICTIONARY.
-
-
-Cable Core.
-The conductors of a cable. They are generally copper wire. In a
-telephone cable they may be very numerous and insulated from each other.
-In ocean cables they may be a group of bare wires twisted or laid
-together. Sometimes the conductors are arranged for metallic circuits,
-each pair being distinguished by special colored windings.
-
-
-Cable, Duplex.
-A cable containing two wires, each with separate insulation, so as to be
-virtually two cables, laid and secured parallel and side by side.
-
-
-Cable, Flat.
-A cable, flat in shape, so as to lie closely against a wall or ceiling.
-
-
-Cablegram.
-A message which has been transmitted or is to be transmitted by a
-submarine cable. It is sometimes called a cable.
-
-
-Cable Grip.
-A grip for holding the end of a cable, when the cable is to be drawn
-into a conduit in a subway. It is an attachment to provide the cable
-with an eye or loop. Its end is a split socket and embraces the end of
-the cable, and is secured thereto by bolts driven through the cable end.
-In drawing a cable into a conduit a capstan and rope are often used, and
-the rope is secured to the cable end by the grip.
-
-
-Fig. 73. CABLE HANGER, CABLE, AND SUSPENDING WIRE.
-
-
-Fig. 74. CABLE HANGER, OPEN.
-
-
-Cable Hanger.
-When a heavy electric cable is suspended from poles it often would be
-unsafe to trust to its longitudinal strength to support or sustain its
-own weight unless the poles were very near together. In such case an
-auxiliary or sustaining wire is run along with it, and by clips or
-hangers the cable is connected thereto at as frequent intervals as seem
-desirable. The contrivance may take the form of a strip of metal
-surrounding the cable and carrying a hook or eye through which the
-supporting wire passes.
-
-Synonym--Cable Clip.
-
-
-97  STANDARD ELECTRICAL DICTIONARY
-
-
-Cable Hanger Tongs.
-Tongs for attaching cable hangers, q.v. They have long handles so as to
-be worked from the ground at the middle of a span.
-
-
-Cable, Suspending Wire of.
-A wire by which an aerial cable is in part or entirely suspended. The
-cable, being incapable of sustaining its own weight, is secured by clips
-or hangers to a wire, strong from pole to pole immediately above it.
-(See Cable Hanger.)
-
-
-Cable Tank.
-A tank in which a submarine cable is coiled away on board a cable-laying
-ship, or in the factory on shore for the purpose of testing or
-watching its insulation. Sometimes, in order to test it under pressures
-approximating to those it will be subjected to in practice, the tank is
-closed and the portion of cable within it is subjected to hydraulic
-pressure. This represents the pressure it will be exposed to in deep
-water.
-
-
-Calamine.
-A mineral; zinc silicate; formula Zn2 Si 03, crystalline system,
-Orthorhombic; specific gravity, 3.16-3.9.
-
-The crystals often show strong pyroelectric properties.
-
-
-Calibration.
-The determination by experiment or calculation of the value of the
-readings of an instrument, such as a galvanometer or eudiometer. Thus if
-a tangent galvanometer has its circle graduated in degrees, a table of
-the value of tangents corresponding to every reading occurring in
-practice would represent a calibration by calculation. A determination
-of the current required to produce each deflection would be a
-calibration in the more usual sense. Calibration is generally absolute,
-as referring to some fixed unit, but it may be relative, as between two
-things both of unknown absolute value.
-
-
-Calibration, Absolute.
-The determination of the absolute value of currents producing given
-deflections in a galvanometer, or in other instruments the determination
-of corresponding values, as the instrument may be a magnetometer,
-quadrant electrometer, or other apparatus.
-
-
-Calibration, Invariable.
-Calibration applicable to specially constructed galvanometers, which is
-unaffected by the proximity of masses of iron or field magnets. Such
-galvanometers must have a constant controlling field. Such is given by a
-powerful permanent magnet, whose field is practically unaffected by the
-causes named. Or else, in place of a controlling field, a spring maybe
-used to which the needle is attached, and which tends to hold it in one
-position.
-
-
-98   STANDARD ELECTRICAL DICTIONARY.
-
-
-Calibration, Relative.
-The determination of the law connecting the various indications of an
-instrument, such as the deflections of the needle of a galvanometer,
-with the relative causes; in the case of a galvanometer, the strength of
-the currents or the electro-motive forces producing them directly or
-indirectly.
-
-
-Call Bell.
-A bell rung by pressing a button or otherwise to call the attention of a
-person in a distant place. They can be classified into a great variety
-of types according to their uses or construction.
-
-
-Call Button.
-A push button used for ringing a call bell, sounding a buzzer, working
-an annunciator and for similar purposes. (See Push Button.)
-
-Synonym--Push Button.
-
-
-Calling Drop.
-In a telephone exchange or telegraph office a drop shutter annunciator,
-which falls to call the attention of the operator, notifying him that
-the line connected to such drop is to be connected to some other
-circuit.
-
-
-Calorie or Calory.
-A practical unit of heat. There are two calories, respectively called
-the great and the small calorie, or the kilogram and the gram calorie.
-The first is the quantity of heat required to raise the temperature of
-one kilogram of water one degree centigrade. The second is the quantity
-of heat required to raise the temperature of one gram of water one
-degree centigrade.
-
-
-Calorimeter.
-An apparatus for measuring the quantity of heat evolved or produced by
-or under different conditions. Dulong's water calorimeter consists of a
-water jacket, and by the increase of temperature of the water and
-enclosing vessels the amount of heat produced by anything in the inner
-vessels is determined. The amount of ice a heated body will melt is
-sometimes made the basis of a calorimeter. The expansion of a fluid, as
-water, may be used. In the calorimeter shown in the cut the heat
-produced in a conductor by the passage of an electric current is caused
-to heat water whose temperature is shown by a thermometer immersed
-therein. The increase of temperature and the weight of the water give
-the basis for a determination of the heat produced by the current.
-Knowing the resistance of the conductor immersed, the watts can be
-calculated. This gives the bases for the determination of the
-heat-equivalent of electric energy. This is but an imperfect
-calorimeter, as it constantly would lose heat by the surrounding
-atmosphere, and would cease to operate as a calorimeter when the water
-was as hot as the wire normally would be, for then it would not absorb
-all the heat.
-
-
-Fig. 75. CALORIMETER.
-
-
-99 STANDARD ELECTRICAL DICTIONARY.
-
-
-Candle.
-The generally accepted unit of illuminating power; there are
-three kinds in use as standards. (See Candle, Decimal--Candle, German
-Standard--Candle, Standard.)
-
-
-Candle, Concentric.
-An electric candle of the Jablochkoff type, having a small solid carbon
-inside of an outside tubular carbon, the space between being filled with
-refractory material corresponding to the colombin, q. v., of the
-ordinary type. The arc springs across from one carbon to the other.
-
-
-Candle, Debrun.
-An arc lamp with approximately parallel carbons. A transverse priming
-connects their bases, and the arc starting there at once flies out to
-the end.
-
-
-Candle, Decimal.
-A standard of illuminating power, proposed to the Congress of
-Electricians of 1889 by Picou. It is one-twentieth of a Viole, or almost
-exactly one standard candle. (See Viole's Standard of Illuminating
-Power.)
-
-Candle, Electric.
-An arc lamp regulated by simple gravity, or without any feed of the
-carbons or special feeding apparatus, generally for the production of an
-arc light of low intensity. This definition may be considered too
-elastic, and the word may be restricted to parallel carbon lamps in
-which the arc springs across from carbon to carbon. For the latter class
-an alternating current is used to keep the carbons of equal length. They
-are but little used now. Various kinds have been invented, some of which
-are given here.
-
-
-Candle, German Standard.
-A standard of illuminating power used in Germany. It is a paraffin
-candle, 6 to the pound, 20 millimeters diameter; flame, 56 millimeters
-high; rate of consumption, 7.7 grams per hour. Its value is about two
-per cent. lower than the English standard candle.
-
-
-100   STANDARD ELECTRICAL DICTIONARY.
-
-
-Candle Holder.
-A clamp for holding electric candles of the Jablochkoff type. The ones
-shown in the cut designed for Jablochkoff  candles comprise a pair of
-metallic clamps, each member insulated from the other, and connected as
-terminals of the circuit. When the candle is placed in position the
-metal pieces press against the carbons of the candle and thus convey the
-current. Below each member of the clamps is a binding screw for the line
-wire terminals.
-
-
-Fig. 76. JABLOCHKOFF CANDLE HOLDERS.
-
-
-Fig. 77. JABLOCHKOFF CANDLE.
-
-
-Candle, Jablochkoff.
-An arc lamp without regulating mechanism, producing an arc between the
-ends of parallel carbons. It consists of two parallel rods of carbon,
-between which is an insulating layer of non-combustible material called
-the colombin. Kaolin was originally employed for this part; later, as
-the fusion of this material was found to short- circuit the arc, a
-mixture of two parts of calcium sulphate and one of barium sulphate was
-used. The carbons are 4 millimeters (.16 inch) thick, and the colombin
-is 3 millimeters (.12 inch) wide and two-thirds as thick. A little slip
-of carbon is placed across the top, touching both carbons to start the
-arc. Once started the candle burns to the end, and cannot be restarted
-after ignition, except by placing a short conductor across the ends, as
-at first. The Jablochkoff candle may now be considered as virtually
-extinct in this country. In France at one time a great number were in
-use.
-
-To keep the carbons of equal length an alternating current must always
-be used with them. Special alternating combinations were employed in
-some cases where a direct current had to be drawn upon.
-
-
-Candle, Jamin.
-An arc lamp with approximately parallel carbons, one of which oscillates
-and is controlled by an electro-magnet and armature. A coil of wire is
-carried around the carbons to keep the arc steady and in place. The
-frame and wire coils have been found unsatisfactory, as causing a
-shadow.
-
-
-Candle Power.
-The amount of light given by the standard candle. The legal English and
-standard American candle is a sperm candle burning two grains a minute.
-It should have burned some ten minutes before use, and the wick should
-be bent over and have a red tip. Otherwise its readings or indications
-are useless. A sixteen candle power lamp means a lamp giving the light
-of sixteen candles. The candle power is a universal unit of illuminating
-power.
-
-
-101  STANDARD ELECTRICAL DICTIONARY.
-
-
-Candle Power, Rated.
-The candle power of arc lamps is always stated in excess of the truth,
-and this may be termed as above. A 2000 candle power lamp really gives
-about 800 candles illumination.
-
-Synonym--Nominal Candle Power.
-
-
-Candle Power, Spherical.
-The average candle power of a source of light in all directions. An arc
-lamp and an incandescent lamp vary greatly in the intensity of light
-emitted by them in different directions. The average of a number of
-determinations at various angles, the lamp being moved about into
-different positions, is taken for the spherical candle power.
-
-
-Candle, Standard.
-A standard of illuminating power. Unless otherwise expressed the English
-standard sperm candle is indicated by this term. (See Candle Power.)
-
-
-Candle, Wilde.
-An arc lamp with approximately parallel carbons. One of the carbons can
-rotate through a small arc being pivoted at its base. This oscillation
-is regulated by an electro-magnet at its base, and the carbons touch
-when no current is passing. They separate a little when the current
-passes, establishing an arc. The regulation is comparable to that of a
-regular arc lamp.
-
-
-Fig. 78. WILDE CANDLE.
-
-
-Caoutchouc.
-India rubber; a substance existing in an emulsion or solution in the
-juice of certain trees and vines of the tropics, whence it is obtained
-by coagulation and drying. The name "rubber" is due to the fact that one
-of its earliest uses was for erasing pencil marks by rubbing. It has a
-very high value as an insulator. The unworked crude rubber is called
-virgin gum; after working over by kneading, it is termed masticated or
-pure gum rubber; after mixture with sulphur and heating, it is termed
-vulcanized rubber. If enough sulphur is added it becomes hard, and if
-black, is termed ebonite; if vermilion or other pigment is also added to
-produce a reddish color, it is termed vulcanite. The masticated gum
-dissolves more or less completely in naphtha (sp. gr., .850) benzole,
-turpentine, chloroform, ether and other similar liquids.. The resistance
-per centimeter cube of "Hooper's" vulcanized India rubber, such as is
-used in submarine cables is 1.5E16 ohms. The specific inductive capacity
-of pure India rubber is 2.34--of vulcanized 2.94 (Schiller).
-
-Synonyms--India Rubber--Rubber.
-
-
-102   STANDARD ELECTRICAL DICTIONARY.
-
-
-Capacity, Dielectric.
-The capacity of a dielectric in retaining an electrostatic charge; the
-same as Specific Inductive Capacity. 'The number expressing it is
-sometimes called the dielectric constant. (See Capacity, Specific
-Inductive.)
-
-
-Capacity, Electric, or Electrostatic.
-The relative capacity of a conductor or system to retain a charge of
-electricity with the production of a given difference of potential. The
-greater the charge for a given change of potential, or the less the
-change of potential for a given charge the greater the capacity. The
-measure of its capacity is the amount of electricity required to raise
-the potential to a stated amount. The unit of capacity is the farad, q.
-v. Electric capacity is comparable to the capacity of a bottle for air.
-A given amount of air will raise the pressure more or less, and the
-amount required to raise its pressure a stated amount might be taken as
-the measure of capacity, and would be strictly comparable to
-electrostatic charge and potential change. The capacity, K, is obviously
-proportional to the quantity, Q, of the charge at a given potential, E,
-and inversely proportional to the potential, E, for a given quantity, Q,
-or,
-  (1) K == Q/E
-  and
-  (2) Q = K * E,
-or, the quantity required to raise a conductor by a given potential is
-equal to the capacity of the conductor or system multiplied by the rise
-of potential. The capacity of a conductor depends upon its environments,
-such as the nature of the dielectric surrounding it, the proximity of
-oppositely charged bodies and other similar factors. (See
-Dielectric-Condenser-Leyden jar.)
-
-The dimensions of capacity are found by dividing a quantity of
-electricity by the potential produced in the conductor by such
-quantity.
-
-Quantity ( ((M^.5)*(L^1.5)) / T ) / potential ( ((M^.5)*(L^.5)) / T ) = L.
-
-
-Capacity, Instantaneous.
-The capacity of a condenser when connected only for an instant to a
-source of electricity. This is in contrast to electric absorption (see
-Absorption, Electric), and is capacity without such absorption taking
-part in the action.
-
-
-103  STANDARD ELECTRICAL DICTIONARY.
-
-
-Capacity of a Telegraph Conductor.
-The electric capacity of a telegraphic conductor is identical in quality
-with that of any other conductor. It varies in quantity, not only for
-different wires, but for the same wire under different environments, as
-the wire reacting through the surrounding air or other dielectric upon
-the earth, represents one element of a condenser, the earth, in general,
-representing the other. Hence, a wire placed near the earth has greater
-capacity than one strung upon high poles, although the wires may be
-identical in length, material and diameter. The effect of high capacity
-is to retard the transmission of intermitting signals. Thus, when--as in
-the Morse system--a key is depressed, closing a long telegraph current
-and sending a signal into a line, it is at least very probable that a
-portion of the electricity travels to the end of the wire with the
-velocity of light. But as the wire has to be charged, enough current to
-move the relay may not reach the end for some seconds.
-
-
-Capacity of Polarization of a Voltaic Cell.
-The relative resistance to polarization of a voltaic cell, measured by
-the quantity of electricity it can supply before polarization. A
-counter-electromotive force may be developed, or the acid or other
-solution may become exhausted. The quantity of electricity delivered
-before this happens depends on the size and type of cell and other
-factors.
-
-
-Capacity, Residual.
-When two insulated conductors are separated by a dielectric, and are
-discharged disruptively by being connected or nearly connected
-electrically, on removing the discharger it is found that a slight
-charge is present after a short interval. This is the residual charge.
-(See Charge, Residual.) Shaking or jarring the dielectric facilitates
-the complete discharge. This retaining of a charge is a phenomenon of
-the dielectric, and as such, is termed residual capacity. It varies
-greatly in different substances. In quartz it is one-ninth what it is in
-air. Iceland spar (crystalline calcite) seems to have no residual
-capacity. The action of shaking and jarring in facilitating a discharge
-indicates a mechanical stress into which the electrostatic polarization
-of the conductor has thrown the intervening dielectric.
-
-
-Capacity, Specific Inductive.
-The ratio of the capacity of a condenser when its plates are separated
-by any substance to the capacity of the same condenser when its plates
-are separated by air.
-
-A static accumulator consists of two conducting surfaces separated by an
-insulator. It is found that the capacity of an accumulator for an
-electric charge, which varies with or may be rated by the potential
-difference to which its conductors will be brought by the given charge,
-varies with the nature of the interposed dielectric, and is proportional
-to a constant special to each substance. This constant is the specific
-inductive capacity of the dielectric.
-
-The same condenser will have a higher capacity as the dielectric is
-thinner, other things being equal. But different dielectrics having
-different specific inductive capacities, the constant may be determined
-by ascertaining the relative thicknesses of layers having the same total
-inductive capacity. The thicker the layer, the higher is its specific
-inductive capacity.
-
-Thus it is found that 3.2 units thickness of sulphur have the same total
-inductive capacity as 1 unit thickness of air. In other words, if
-sulphur is interposed between two conducting plates, they may be
-separated to over three times the distance that would be requisite to
-retain the same capacity in air. Hence, sulphur is the better
-dielectric, and air being taken as unity, the specific inductive
-capacity of sulphur is 3.2.
-
-
-104   STANDARD ELECTRICAL DICTIONARY.
-
-
-The specific inductive capacity of a dielectric varies with the time and
-temperature. That of glass rises 2.5 per cent. between 12� C. (53.6� F.)
-and 83� C. (181.4� F.). If a condenser is discharged disruptively, it
-retains a small residual charge which it can part with later. If a
-metallic connection is made between the plates, the discharge is not
-instantaneous. Vibration shaking and jarring facilitate the complete
-discharge. All this shows that the charge is a phase of the dielectric
-itself, and indicates a strained state into which it is brought.
-
-The following table gives the specific inductive capacity of various
-substances:
-
-                         Specific Inductive Capacity.
-Substance                                         Specific
-                                                  Inductive   Authority
-                                                  Capacity.
-Vacuum, air at about 0.001 millimeters pressure   0.94 about  Ayrton
-Vacuum, air at about 5 millimeters                0.9985      Ayrton
-                                                  0.99941     Boltzmann
-Hydrogen at about 760 millimeters pressure        0.9997      Boltzmann
-                                                  0.9998      Ayrton
-Air at about 760 millimeters pressure             1.0         Taken as the
-                                                              standard
-Carbon Dioxide at about 760 millimeters pressure  1.000356    Boltzmann
-                                                  1.0008      Ayrton
-Olefiant Gas at about 760 millimeters pressure    1.000722    Boltzmann
-Sulphur Dioxide at about 760 millimeters pressure 1.0037      Ayrton
-Paraffin Wax, Clear                               1.92        Schiller
-                                                  1.96        W�llner
-                                                  1.977   Gibson and Barclay
-                                                  2.32        Boltzmann
-Paraffin Wax, Milky                               2.47        Schiller
-India Rubber, Pure                                2.34        Schiller
-India Rubber, Vulcanized                          2.94        Schiller
-Resin                                             2.55        Boltzmann
-Ebonite                                           2.56        W�llner
-                                                  2.76        Schiller
-                                                  3.15        Boltzmann
-Sulphur                                           2.88 to 3.21  W�llner
-                                                  3.84        Boltzmann
-Shellac                                           2.95 to 3.73  W�llner
-Gutta percha                                      4.2
-Mica                                              5
-Flint Glass, Very light                           6.57        J. Hopkinson
-Flint Glass, Light                                6.85        J. Hopkinson
-Flint Glass, Dense                                7.4         J. Hopkinson
-Flint Glass, Double extra dense                  10.1         J. Hopkinson
-
-
-105  STANDARD ELECTRICAL DICTIONARY.
-
-
-Capacity, Unit of.
-The unit of capacity is the capacity of a surface which a unit quantity
-will raise to a unit potential. The practical unit is the surface which
-a coulomb will raise to one volt, and is called the farad, q. v.
-
-
-Capacity, Storage.
-In secondary batteries the quantity of electrical current which they can
-supply when charged, without undue exhaustion. It is expressed in
-ampere-hours. The potential varies so little during the discharge that
-it is assumed to be constant.
-
-
-Capillarity.
-The reaction between liquid surfaces of different kinds or between
-liquid and solid surfaces due to surface tension. Its phenomena are
-greatly modified by electric charging, which alters the surface tension.
-Capillarity is the cause of solutions "creeping," as it is termed. Thus
-in gravity batteries a crust of zinc sulphate often formed over the edge
-of the jar due to the solution creeping and evaporating. As a liquid
-withdraws from a surface which it does not wet, creeping as above is
-prevented by coating the edge with paraffin wax, something which water
-does not moisten. It also causes the liquids of a battery cell to reach
-the connections and injure them by oxidation. The solutions creep up in
-the pores of the carbons of a battery and oxidize the clamps. To give
-good connections a disc of platinum or of lead is used for the contact
-as not being attacked. Another way is to dip the upper ends of the dry
-and warm carbons into melted paraffin wax, or to apply the wax to the
-hot carbons at the top, and melt it in with a hot iron.
-
-
-106   STANDARD ELECTRICAL DICTIONARY.
-
-
-Carbon.
-(a) One of the elements; atomic weight, 12. It exists in three
-allotropic modifications, charcoal, graphite and diamond. In the
-graphitic form it is used as an electric current conductor, as in
-batteries and for arc lamp, electrodes and incandescent lamp filaments.
-It is the only substance which conducts electricity and which cannot be
-melted with comparative ease by increase of current. (See Resistance.)
-
-(b) The carbon plate of a battery or rod of an arc lamp. To secure
-greater conductivity in lamp carbons, they are sometimes plated with
-nickel or with copper.
-
-(c) v. To place carbons in arc lamps. This has generally to be done once
-in twenty-four hours, unless the period of burning is very short.
-
-
-Carbon, Artificial.
-For lamps, carbons and battery plates carbons are made by igniting,
-while protected from the action of the air, a mixture of carbon dust and
-a cementing and carbonizable substance. Lamp black may be added also.
-Powdered coke or gas carbon is mixed with molasses, coal tar, syrup, or
-some similar carbonaceous liquid. It is moulded into shape. For lamp
-carbons the mixture is forced from a vessel through a round aperture or
-die, by heavy pressure, and is cut into suitable lengths. For battery
-plates it may be simply pressed into moulds. The carbons are ignited in
-covered vessels and also covered with charcoal dust, lamp black or its
-equivalent. They are heated to full redness for some hours. After
-removal and cooling they are sometimes dipped again into the liquid used
-for cementing and reignited. Great care in securing pure carbon is
-sometimes necessary, especially for lamps. Fine bituminous coal is
-sometimes used, originally by Robert Bunsen, in 1838 or 1840;
-purification by different processes has since been applied; carbon from
-destructive distillation of coal tar has been used. The famous Carr�
-carbons are made, it is said, from 15 parts very pure coke dust, five
-parts calcined lamp-black, and seven or eight parts sugar--syrup mixed
-with a little gum. Five hours heating, with subsequent treatment with
-boiling caramel and reignition are applied. The latter treatment is
-termed "nourishing." Napoli used three parts of coke to one of tar.
-Sometimes a core of different carbon than the surrounding tube is
-employed.
-
-
-107  STANDARD ELECTRICAL DICTIONARY.
-
-
-The following are the resistances of Carr�'s carbons per meter (39.37
-inches):
-
-Diameter in     Diameter in  Resistance in Ohms.
-Millimeters.    Inches.      @ 20� C. (98� F.)
-    1           .039           50.000
-    2           .078           12.5
-    3           .117            5.55
-    4           .156            3.125
-    5           .195            2.000
-    6           .234            1.390
-    8           .312             .781
-   10           .390             .5
-   12           .468             .348
-   15           .585             .222
-   18           .702             .154
-   20           .780             .125
-
-At high temperatures the resistance is about one-third these amounts. A
-layer of copper may increase the conductivity one hundred times and
-prolong the duration 14 per cent. Thus a layer of copper 1/695
-millimeter (1/17300 inch) thick increases the conductivity 4.5 times; a
-coating 1/60 millimeter (1/1500 inch) thick increases the conductivity
-one hundred and eleven times.
-
-
-Carbon, Cored.
-A carbon for arc lamps with a central core of softer carbon than the
-exterior zone. It fixes the position of the arc, and is supposed to give
-a steadier light.
-
-Synonym--Concentric Carbon.
-
-
-Carbon Holders.
-In arc lamps, the fixed clamps for holding the ends of the carbons.
-
-
-Carbonization.
-The igniting in a closed vessel, protected from air, of an organic
-substance so as to expel from it all the constituents except part of
-the carbon; destructive distillation. (See Carbonized Cloth.)
-
-
-Carbonized Cloth.
-Cloth cut in discs and heated in vessels protected from the air, until
-reduced to carbon. The heating is sometimes conducted in vacuo. They are
-placed in a pile in a glass or other insulating tube, and offer a
-resistance which can be varied by pressure. The greater the pressure the
-less will be the resistance, and vice versa.
-
-Carbon Dioxide.
-A compound gas, CO2. It is composed of
-  Carbon, 12 parts by weight.
-  Oxygen. 32  "
-  Specific gravity, 1.524 (Dulong and Berzelins).
-  Molecular weight, 44.
-
-It is a dielectric of about the resistance of air. Its specific
-inductive capacity at atmospheric pressures is
-  1.000356 (Boltzmann).
-  1.0008 (Ayrton).
-
-Synonyms--Carbonic Acid--Carbonic Acid Gas.
-
-
-108   STANDARD ELECTRICAL DICTIONARY
-
-
-Carbon, Volatilization of.
-In arc lamps the heat is so intense that it is believed that part of the
-carbon is volatilized as vapor before being burned or oxidized by the
-oxygen of the air. The same volatilization may take place in
-incandescent lamps which are overheated.
-
-
-Carcel.
-The standard of artificial illumination used in France. It is the light
-yielded by a standard lamp burning 42 grams (648 grains) of colza oil
-per hour, with a flame 40 millimeters (1.57 inch) in height. One carcel
-is equal to 9.5 to 9.6 candles.
-
-
-Carcel Lamp.
-The lamp giving the standard of illuminating power. The wick is
-cylindrical, giving an Argand or central draft flame. It is woven with
-75 strands, and weighs 3.6 grams (55.5 grains) per decimeter (3.9
-inches) of length. The chimney is 29 centimeters (11.3 inches) high, 47
-millimeters (1.88 inch) in diameter at the bottom, contracting just
-above the wick to 34 millimeters (1.36 inch).
-
-
-Carcel Gas Jet.
-A standard Argand gas burner, made with proper rating to give the light
-of a definite number of carcels illuminating power. Cognizance must be
-taken of the quality of the gas as well as of the burner used.
-
-
-Carrying Capacity.
-In a current conductor, its capacity for carrying a current without
-becoming unduly heated. It is expressed in amperes. (See Wire Gauge,
-American.)
-
-
-Cascade.
-The arrangement of Leyden jars in series on insulating supports, as
-described below.
-
-
-Cascade, Charging and Discharging Leyden Jars In.
-An arrangement of Leyden jars in series for the purpose of charging and
-discharging. They are placed on insulating supports, the inner coating
-of one connected with the outer coating of the next one all through the
-series. The actual charge received by such a series, the outer coating
-of one end jar being grounded, and the inner coating of the other being
-connected to a source of high potential, or else the same being
-connected to electrodes of opposite potentials is no greater than that
-of a single jar, but a much higher potential difference can be developed
-without risk of perforating the glass of a jar. The difference of
-potential in each jar of the series is equal to the total potential
-difference divided by the number of jars. The energy of discharge is
-equal to the same fraction of the energy of a single jar charged with
-the same quantity.
-
-[Transcriber's note: The equal distribution of potential assumes all the
-jars have the same capacity. The charge on all jars is the same since
-they are in series.]
-
-
-109  STANDARD ELECTRICAL DICTIONARY.
-
-
-Case-hardening, Electric.
-The conversion of the surface of iron into steel by applying a proper
-carbonaceous material to it while it is heated by an electric current.
-It is a superficial cementation process.
-
-
-Cataphoresis.
-Electric osmore; the transfer of substances in solution through porous
-membranes under the influence probably of electrolysis, but without
-themselves being decomposed.
-
-
-Cautery, Electric.
-An electro-surgical appliance for removing diseased parts, or arresting
-hemorrhages, taking the place of the knife or other cutting instrument.
-The cautery is a platinum wire heated to whiteness by an electric
-current, and when in that condition used to cut off tumors, stop the
-flow of blood and parallel operations. The application is painful, but
-by the use of anaesthetics pain is avoided, and the healing after the
-operation is greatly accelerated.
-
-The heated wire of the cautery can be used for cutting operations in
-many cases where excision by a knife would be almost impracticable.
-
-Synonyms--Galvano-cautery--Galvano-caustry--Galvano-electric,
-do.--Galvano-thermal, do.
-
-
-C. C.
-A contraction of cubic centimeter. It is often written in small letters,
-as 100 c.c., meaning 100 cubic centimeters.
-
-
-Cell, Constant.
-A cell which yields a constant and uniform current under unvarying
-conditions. This implies that neither the electro-motive force or the
-resistance of the cell shall vary, or else that as the electro-motive
-forces run down the resistance shall diminish in proper proportion to
-maintain a constant current. There is really no constant cell. The
-constancy is greatest when the external resistance is high in proportion
-to the internal resistance.
-
-
-Cell, Electrolytic.
-A vessel containing the electrolyte, a liquid decomposable by the
-current, and electrodes, arranged for the passage of a decomposing
-current. The voltameter, q. v., is an example.
-
-
-Cell, Standard Voltaic.
-A cell designed to be a standard of electro-motive force; one in which
-the same elements shall always be present under the same conditions, so
-as to develop the same electro-motive force. In use the circuit is
-closed only for a very short time, so that it shall not become altered
-by polarization or exhaustion.
-
-
-Cell, Standard Voltaic, Daniell's.
-A zinc-copper-copper sulphate couple. Many forms are used. Sometimes a
-number of pieces of blotting paper are interposed between two plates,
-one of copper--the other of zinc. The paper next the copper is soaked in
-copper sulphate solution, and those next the zinc in zinc sulphate
-solution, of course before being put together. Sometimes the ordinary
-porous cup combination is employed. The cut shows a modification due to
-Dr. Fleming (Phil. Mag. S. 5, vol. xx, p. 126), which explains itself.
-The U tube is 3/4-inch diameter, and 8 inches long. Starting with it
-empty the tap A is opened, and the whole U tube filled with zinc
-sulphate solution, and the tap A is closed. The zinc rod usually kept in
-the tube L is put in place, tightly corking up its end of the U tube.
-The cock C is opened, which lowers the level of the solution in the
-right-hand limb of the U tube only. The tap B is opened and the copper
-sulphate solution is run in, preserving the line of separation of the
-two solutions. The copper rod is taken out of its tube M, and is put in
-place. India rubber corks are used for both rods. As the liquids begin
-to mix the mixture can be drawn off at C and the sharp line of
-demarcation re-established. In Dr. Sloane's standard cell two test tubes
-are employed for the solutions and a syphon is used to connect them.
-
-Oxidation of the zinc lowers the E. M. F.; oxidation of the copper
-raises it. With solutions of equal sp. gr. the E. M. F. is 1.104 volts.
-If the copper sulphate solution is 1.100 sp. gr. and the zinc sulphate
-solution 1.400 sp. gr., both at 15� C. (59�F.), the E. M. F. will be
-1.074 volt. Clean pure zinc and freshly electrolyzed copper should be
-used.
-
-
-Fig. 79 STANDARD DANIELL CELL--FLEMING'S FORM.
-
-
-110   STANDARD ELECTRICAL DICTIONARY.
-
-
-Cell, Standard Voltaic, Latimer Clark's.
-A mercury and zinc electrode couple with mercurous sulphate as excitant
-and depolarizer. The positive element is an amalgam of zinc, the
-negative is pure mercury. Each element, in a representative form, the H
-form, is contained in a separate vessel which communicate by a tube.
-Over the pure mercury some mercurous sulphate is placed. Both vessels
-are filled to above the level of the connecting tube with zinc sulphate
-solution, and kept saturated. It is tightly closed or corked. The E. M.
-F. at 15� C (59� F.) is 1.438.
-Temperature correction
-
-(1 -  (.00077 *(t - 15� C) ) )
-
-t being expressed in degrees centigrade (Rayleigh). A diminution in
-specific gravity of the zinc solution increases the E. M. F. The cell
-polarizes rapidly and the temperature coefficient is considered too
-high.
-
-
-Fig. 80. LATIMER CLARK'S STANDARD CELL.
-
-
-111   STANDARD ELECTRICAL DICTIONARY.
-
-
-Cements, Electrical.
-A few cements find their use in electrical work. Marine glue,
-Chatterton's compound, and sealing wax may be cited.
-
-
-Centi-.
-Employed as a prefix to indicate one-hundredth, as centimeter, the
-one-hundredth of a meter; centi-ampere, the one-hundredth of an ampere.
-
-
-Centigrade-scale.
-A thermometer scale in use by scientists of all countries and in general
-use in many. The temperature of melting ice is 0�; the temperature of
-condensing steam is 100� ; the degrees are all of equal length. To
-reduce to Fahrenheit degrees multiply by 9 and divide by 5, and add 32
-algebraically, treating all readings below 0� as minus quantities. For
-its relations to the Reamur scale, see Reamur Scale. Its abbreviation is
-C., as 10� C., meaning ten degrees centigrade.
-
-
-Centimeter.
-A metric system unit of length; one-hundredth of a meter; 0.3937 inch.
-The absolute or c. g. s. unit of length.
-
-
-Centimeter-gram-second System.
-The accepted fundamental or absolute system of units, called the C. G.
-S. system. It embraces units of size, weight, time, in mechanics,
-physics, electricity and other branches. It is also called the absolute
-system of units. It admits of the formation of new units as required by
-increased scope or classification. The following are basic units of the
-system :
-
-Of length, centimeter;
-of mass, gram;
-of time, second:
-of force, dyne:
-of work or energy, erg.
-
-See Dyne, Erg., and other units in general.
-
-
-112   STANDARD ELECTRICAL DICTIONARY.
-
-
-Central Station Distribution or Supply.
-The system of supplying electric energy in current form from a main
-generating plant to a district of a number of houses, factories, etc. It
-is in contrast with the isolated plant system in which each house or
-factory has its own separate generating installment, batteries or
-dynamos.
-
-
-Centre of Gravity.
-A point so situated with respect to any particular body, that the
-resultant of the parallel attracting forces between the earth and the
-several molecules of the body always passes through it. These are
-resultants of the relative moments of the molecules. If a body is
-suspended, as by a string, the centre of gravity always lies vertically
-under its point of suspension. By two trials the point of intersection
-of plumb lines from the point of suspension being determined the centre
-of gravity is known. The vertical from the point of support coincides
-with the line of direction.
-
-
-Centre of Gyration.
-The centre of gyration with respect to the axis of a rotating body is a
-point at which if the entire mass of the body were concentrated its
-moment of inertia would remain unchanged. The distance of this point
-from the axis is the radius of gyration.
-
-
-Centre of Oscillation.
-The point referred to in a body, suspended or mounted to swing like a
-pendulum, at which if all the mass were concentrated, 1t would complete
-its oscillations in the same time. The distance from the axis of support
-to this point gives the virtual length of the pendulum which the body
-represents.
-
-
-Centre of Percussion.
-The point in a suspended body, one free to swing like a pendulum, at
-which an impulse may be applied, perpendicular to the plane through the
-axis of the body and through the axis of support without shock to the
-axis. It is identical with the centre of oscillation, q. v., when such
-lies within the body.
-
-
-Centrifugal Force.
-The force which draws a body constrained to move in a curved path away
-from the centre of rotation. It is really due to a tangential impulse
-and by some physicists is called the centrifugal component of tangential
-velocity. It has to be provided against in generator and motor
-armatures, by winding them with wire or bands to prevent the coils of
-wire from spreading or leaving their bed upon the core.
-
-
-113  STANDARD ELECTRICAL DICTIONARY.
-
-
-Centrifugal Governor.
-The usual type of steam-engine governor. The motion of the engine
-rotates a system of weights, which are forced outward by centrifugal
-force, and are drawn inwards by gravity or by springs. Moving outwards
-they shut off steam, and moving inwards they admit it, thus keeping the
-engine at approximately a constant speed. The connections between them
-and the steam supply and the general construction vary widely in
-different governors.
-
-
-C. G. S.
-Abbreviation or symbol for Centimeter-gram-second, as the C. G. S.
-system. (See Centimeter-gram-second System.) It is sometimes expressed
-in capitals, as above, and sometimes in small letters, as the c. g. s.
-unit of resistance.
-
-
-Chamber of Incandescent Lamp.
-The interior of the bulb of an incandescent lamp. (See Lamp,
-Incandescent.)
-
-
-Fig. 81. CHARACTERISTIC CURVE OF A DYNAMO.
-
-
-FIG. 82. DROOPING CHARACTERISTIC.
-
-
-Characteristic Curve.
-A curve indicating the variations in electro-motive force developed
-during the rotations of the armature of a dynamo or other generator of
-E. M. F. The term as used in the electrical sense is thus applied,
-although the indicator diagram of a steam engine may be termed its
-characteristic curve, and so in many other cases. As the amperes taken
-from a series generator are increased in number, the E. M. F. rises, it
-may be very rapidly up to a certain point, and thereafter more slowly.
-To construct the curve coordinates, q. v., are employed. The resistance
-of the dynamo and of the outer circuit being known, the current
-intensity is measured. To obtain variations in electro-motive force the
-external resistance is changed. Thus a number of ampere readings with
-varying known resistance are obtained, and for each one an
-electro-motive force is calculated by Ohm's law. From these data a curve
-is plotted, usually with volts laid off on the ordinate and amperes on
-the abscissa.
-
-By other methods other characteristic curves may be obtained, for which
-the titles under Curve may be consulted.
-
-
-114   STANDARD ELECTRICAL DICTIONARY.
-
-
-Characteristic, Drooping.
-A characteristic curve of a dynamo which indicates a fall in voltage
-when an excessive current is taken from the dynamo in question. It is
-shown strongly in some Brush machines, and is partly due to the
-arrangements for cutting out two of the coils as they approach the
-neutral line. It is an advantage, as it protects from overheating on
-short circuit.
-
-
-Characteristic, External.
-In a dynamo the characteristic curve in which the relations of volts
-between terminals to amperes in the outer circuit are plotted. (See
-Curve, External Characteristic.)
-
-
-Characteristic, Internal.
-A characteristic curve of a shunt dynamo, in which the relations of
-volts to amperes in the shunt circuit is plotted.
-
-
-Characteristics of Sound.
-Of interest, electrically, as affecting the telephone, they comprise:
-
-(1) Pitch, due to frequency of vibrations.
-
-(2) Intensity or loudness, due to amplitude of waves of sound.
-
-(3) Quality or timbre, the distinguishing characteristics of any
-specific sound due to overtones, discords, etc., by which the sound is
-recognizable from others. The telephone is held by the U. S. courts to
-be capable of reproducing the voice by means of the undulatory current.
-(See Current, Undulatory.)
-
-
-Charge.
-The quantity of electricity that is present on the surface of a body or
-conductor. If no electricity is supplied, and the conductor is connected
-to the earth, it is quickly discharged. A charge is measured by the
-units of quantity, such as the coulomb. The charge that a conductor can
-retain at a given rise of potential gives its capacity, expressible in
-units of capacity, such as the farad. A charge implies the stretching or
-straining between the surface of the charged body, and some
-complimentary charged surface or surfaces, near or far, of large or
-small area, of even or uneven distribution.
-
-
-Charge. v.
-(a) To introduce an electrostatic charge, as to charge a condenser.
-
-(b) To decompose the elements of a secondary battery, q. v., so as to
-render it capable of producing a current. Thus, a spent battery is
-charged or recharged to enable it to do more work.
-
-Synonyms--Renovate--Revivify--Recharge.
-
-
-115  STANDARD ELECTRICAL DICTIONARY.
-
-
-Charge, Bound.
-A charge of electricity borne by the surface of a body so situated with
-reference to another oppositely charged body, that the charge is
-imperceptible to ordinary test, will not affect an electroscope nor
-leave the surface if the latter is connected to the earth. To discharge
-such a body it must be connected to its complimentarily charged body.
-The bound charge was formerly called dissimulated or latent electricity.
-(See Charge, Free.)
-
-The charge or portion of a charge of a surface which is neutralized
-inductively by a neighboring charge of opposite kind. The degree of
-neutralization or of binding will depend on the distance of the two
-charged surfaces from one another and on the electro-static nature of
-the medium intervening, which must of necessity be a dielectric. A
-charge not so held or neutralized is termed a free charge. Thus a
-surface may be charged and by the approach of a surface less highly
-charged may have part of its charge bound. Then if connected to earth.
-it will part with its unbound or free charge, but will retain the other
-until the binding surface is removed, or until the electricity of such
-surface is itself bound, or discharged, or until connection is made
-between the two surfaces. Thus a body may have both a bound and a free
-charge at the same time.
-
-
-Charge, Density of.
-The relative quantity of electricity upon a given surface. Thus a
-charged surface may have an evenly distributed charge or one of even
-density, or an unevenly distributed charge or one of uneven density. In
-a thunderstorm the earth has a denser charge under the clouds than
-elsewhere.
-
-Synonym--Electrical Density.
-
-
-Charge, Dissipation of.
-As every body known conducts electricity, it is impossible so to
-insulate a surface that it will not lose its charge by leakage. An
-absolute vacuum might answer, and Crookes in a high vacuum has retained
-a charge against dissipation for years. The gradual loss is termed as
-above.
-
-
-Charge, Distribution of.
-The relation of densities of charge on different parts of a charged
-body. On a spherical conductor the charge is normally of even
-distribution; on other conductors it is unevenly distributed, being of
-greatest density at points, edges, and parts of smallest radius of
-curvature. Even distribution can also be disturbed by local induction,
-due to the presence of oppositely charged bodies.
-
-
-116   STANDARD ELECTRICAL DICTIONARY.
-
-
-Charge, Free.
-The charge borne by an insulated body, independent of surrounding
-objects. Theoretically it is an impossibility. A charge always has its
-compliment somewhere in surrounding objects. As a matter of convenience
-and convention, where the complimentary charge is so distributed that
-its influence is not perceptible the charge is called a free charge. If
-connected to earth the free charge will leave the body. If the body is
-connected with an electroscope the free charge will affect the same.
-(See Charge, Bound.)
-
-
-Charge, Residual.
-When a Leyden jar or other condenser is discharged by the ordinary
-method, after a few minutes standing a second discharge of less amount
-can be obtained from it. This is due to what is known as the residual
-charge. It seems to be connected in some way with the mechanical or
-molecular distortion of the dielectric. The jarring of the dielectric
-after discharge favors the rapidity of the action, diminishing the time
-required for the appearance of the residual charge. The phenomenon, it
-will be seen, is analogous to residual magnetism. This charge is the
-reciprocal of electric absorption and depends for its amount upon the
-nature of the dielectric. (See Absorption, Electric, and Capacity,
-Residual.)
-
-Synonym--Electric Residue.
-
-
-Chatterton's Compound.
-A cement used for cementing together layers or sheets of gutta percha,
-and for similar purposes in splicing telegraph cables. Its formula is:
-  Stockholm Tar,   1 part.
-  Resin,           1 part.
-  Gutta Percha,    3 parts.
-All parts by weight.
-
-
-Chemical Change.
-When bodies unite in the ratio of their chemical equivalents, so as to
-represent the satisfying of affinity or the setting free of thermal or
-other energy, which uniting is generally accompanied by sensible heat
-and often by light, as in the ignition of a match, burning of a candle,
-and, when the new compound exhibits new properties distinct from those
-of its components, a chemical combination is indicated. More definitely
-it is a change of relation of the atoms. Another form of chemical change
-is decomposition, the reverse of combination, and requiring or absorbing
-energy and producing several bodies of properties distinct from those of
-the original compound. Thus in a voltaic battery chemical combination
-and decomposition take place, with evolution of electric instead of
-thermal energy.
-
-
-Chemical Equivalent.
-The quotient obtained by dividing the atomic weight, q. v., of an
-element by its valency, q. v. Thus the atomic weight of oxygen is 16,
-its valency is 2. its chemical equivalent is 8. It is the weight of the
-element corresponding to a unit weight of hydrogen, either as replacing
-it, or combining with it. In electro-chemical calculations the chemical
-equivalent is often conveniently used to avoid the necessity of dividing
-by the valency when atomic weights are used. The latter is really the
-better practice. The atomic weights in the old system of chemical
-nomenclature were chemical equivalents.
-
-
-117  STANDARD ELECTRICAL DICTIONARY.
-
-
-Chemical Recorder.
-A form of telegraphic recorder in which the characters, often of the
-Morse alphabet or some similar one, are inscribed on chemically prepared
-paper by decomposition affecting the compound with which the paper is
-charged. In the original chemical recorder of Bain, the instrument was
-somewhat similar to the Morse recorder, except that the motionless
-stylus, S, always pressing against the paper was incapable of making any
-mark, but being of iron, and the paper strip being impregnated with
-potassium ferrocyanide, on the passage of a current a stain of Prussian
-blue was produced where the stylus touched the paper. The current passes
-from the line by way of the iron stylus, through the paper, and by way
-of a brass surface, M, against which the paper is held and is pressed by
-the stylus, to the earth. This recorder is extremely simple and has no
-part to be moved by the current. The solution in which the paper is
-dipped contains a mixture of potassium ferrocyanide and ammonium
-nitrate. The object of the latter is to keep the paper moist. In recent
-recorders a solution of potassium iodide has been used, which gives a
-brown stain of free iodine, when the current passes. This stain
-disappears in a few days.
-
-
-Fig. 83. BAIN'S TELEGRAPH EMPLOYING CHEMICAL RECORDER.
-
-
-In the cut, R is the roll of paper, B is a tank of solution with roll,
-W1, for moistening the paper; M is the brass surface against which the
-stylus, S, presses the paper, P P; W, W are feed rollers; T is the
-transmitting key, and zk the battery; Pl, Pl are earth plates. The
-apparatus is shown duplicated for each end.
-
-
-118   STANDARD ELECTRICAL DICTIONARY.
-
-
-Chemistry.
-The science treating of atomic and molecular relations of the elements
-and of chemical compounds of the same.
-
-
-Chimes, Electric.
-An apparatus employed to illustrate the principles of the electrostatic
-charge, involving the ringing of bells by electrostatic attraction and
-repulsion. It is used in connection with a frictional, or influence
-electric machine. Two bells are employed with a button or clapper
-suspended between them. One bell is connected to one of the prime
-conductors, q. v., of the machine. The other insulated therefrom is
-connected to earth, or if an influence machine is used, to the other
-prime conductor. The clappers are hung by a silk thread, so as to be
-entirely insulated. On working the machine the bells become oppositely
-excited. A clapper is attracted to one, then when charged is repelled
-and attracted to the other, it gives up its charge and becoming charged
-with similar electricity to that of the bell it touches, is repelled and
-attracted to the other, and this action is kept up as long as the
-excitement continues, the bells ringing continuously.
-
-
-Fig. 84. ELECTRIC CHIMES.
-
-
-Chronograph, Electric.
-An apparatus for indicating electrically, and thereby measuring, the
-lapse of time. The periods measured may be exceedingly short, such as
-the time a photographic shutter takes to close, the time required by a
-projectile to go a certain distance, and similar periods.
-
-A drum rotated with even and known velocity may be marked by a stylus
-pressed upon it by the action of an electro-magnet when a key is
-touched, or other disturbance. Then the space between two marks would
-give the period elapsing between the two disturbances of the circuit. As
-it is practically impossible to secure even rotation of a drum, it is
-necessary to constantly measure its rate of rotation. This is effected
-by causing a tuning-fork of known rate of vibration to be maintained in
-vibration electrically. A fine point or bristle attached to one of its
-arms, marks a sinuous line upon the smoked surface of the cylinder. This
-gives the basis for most accurately determining the smallest intervals.
-Each wave drawn by the fork corresponds to a known fraction of a second.
-
-For projectiles, the cutting of a wire opens a circuit, and the opening
-is recorded instead of the closing. By firing so as to cut two wires at
-a known distance apart the rate is obtained by the chronograph.
-
-Synonym--Chronoscope.
-
-
-119  STANDARD ELECTRICAL DICTIONARY.
-
-
-Chutaux's Solution.
-A solution for bichromate batteries. It is composed as follows:
-  Water,                1,500 parts
-  Potassium bichromate,   100 parts
-  mercury bisulphate,     100 parts
-  66� sulphuric acid,      50 parts.
-
-Circle, Galvanic or Voltaic.
-A term for the voltaic circuit; obsolete.
-
-
-Fig. 85. MAGIC CIRCLE.
-
-
-Circle, Magic.
-A form of electro-magnet. It is a thick circle of round iron and is used
-in connection with a magnetizing coil, as shown, to illustrate
-electro-magnetic attraction.
-
-
-120   STANDARD ELECTRICAL DICTIONARY.
-
-
-Circuit.
-A conducting path for electric currents properly forming a complete path
-with ends joined and including generally a generating device of some
-kind. Part of the conduction may be true and part electrolytic. (See
-Electrolytic Conduction.) The term has become extended, so that the term
-is often applied to any portion of a circuit conveniently considered by
-itself. The simplest example of a complete circuit would be a circular
-conductor. If rotated in the earth's field so as to cut its lines of
-force a current would go through it, and it would be an electric
-circuit. Another example is a galvanic battery with its ends connected
-by a wire. Here the battery generates the current which, by electrolytic
-conduction, goes through the battery and by true conduction through the
-wire. For an example of a portion of a circuit spoken of as "a circuit"
-see Circuit, Astatic.
-
-
-Circuit, Astatic.
-A circuit so wound with reference to the direction of the currents
-passing through it that the terrestrial or other lines of force have no
-directive effect upon it, one member counteracting the other. It may be
-produced by making the wire lie in two closed curves, A and B, each
-enclosing an equal area, one of identical shape and disposition with the
-other, and with the current circulating in opposite directions in each
-one. Thus each circuit represents a magnetizing turn of opposite
-polarity and counteracting each other's directive tendency exhibited in
-a field of force with reference to an axis a c. Another form of astatic
-circuit is shown in Fig. 86. The portions C, D, lying on opposite sides
-of the axis of rotation a c, are oppositely acted on by the earth's
-directive force as regards the direction of their rotation.
-
-
-Figs. 86 and 87. ASTATIC CIRCUITS.
-
-
-Circuit, Branch.
-A circuit dividing into two or more parts in parallel with each other.
-
-
-121  STANDARD ELECTRICAL DICTIONARY.
-
-
-Circuit Breaker.
-Any apparatus for opening and closing a circuit is thus termed, but it
-is generally applied to automatic apparatus. A typical circuit breaker
-is the hammer and anvil of the induction coil. (See Induction Coil;
-Anvil.) Again a pendulum connected to one terminal of a circuit may
-swing so as to carry a point on its lower end through a globule of
-mercury as it swings, which globule is connected to the other terminal.
-A great many arrangements of this character have been devised.
-
-Synonym.--Contact Breaker.
-
-
-Circuit Breaker, Automatic.
-A circuit breaker worked by the apparatus to which it is attached, or
-otherwise automatically. (See Induction Coil; Anvil; Bell, Electric.)
-
-
-Circuit Breaker, File.
-A coarsely cut file, forms one terminal of an electric circuit, with a
-straight piece of copper or steel for the other terminal. The latter
-terminal drawn along the teeth makes and breaks the contact once for
-every tooth. The movable piece should have an insulated handle.
-
-
-Circuit Breaker, Mercury.
-A circuit breaker which may be identical in principle, with the
-automatic circuit breaker of an induction coil, but in which in place of
-the anvil, q. v., a mercury cup is used, into which the end of a wire
-dips and emerges as it is actuated by the impulses of the current. Each
-dip makes the contact, which is broken as the wire springs back. The
-mercury should be covered with alcohol to protect it from oxidation.
-
-
-Circuit Breaker, Pendulum.
-A circuit breaker in which a pendulum in its swing makes and breaks a
-contact. It may be kept in motion by clockwork, or by an electro-magnet,
-attracting intermittently an armature attached to its rod, the
-magnet circuit being opened and closed by the pendulum or circuit
-breaker itself. A mercury contact may be used with it.
-
-
-Fig. 88. PENDULUM CIRCUIT BREAKER.
-
-
-122   STANDARD ELECTRICAL DICTIONARY.
-
-
-Circuit Breaker, Tuning Fork.
-A circuit breaker in which a tuning fork makes and breaks the circuit.
-Each vibration of one of the prongs in one direction makes a contact,
-and the reverse vibration breaks a contact. The adjustment is
-necessarily delicate, owing to the limited amplitude of the motion of
-the fork. The fork is kept in vibration sometimes by an electro-magnet,
-which is excited as the circuit is closed by the fork. One leg of the
-fork acts as the armature of the magnet, and is attracted according to
-its own natural period.
-
-
-Circuit Breaker, Wheel.
-A toothed wheel with a spring bearing against its teeth. One terminal of
-a circuit connects with the wheel through its axle, the other connects
-with the spring. When the wheel is turned the circuit is opened and
-closed once for each tooth. The interstices between teeth on such a
-wheel may be filled with insulating material, giving a cylindrical
-surface for the contact spring to rub on.
-
-
-Fig. 89--TOOTHED WHEEL CIRCUIT BREAKER.
-
-
-Circuit, Closed.
-A circuit whose electric continuity is complete; to make an open circuit
-complete by closing a switch or otherwise is to close, complete, or make
-a circuit.
-
-Synonyms--Completed Circuit--Made Circuit.
-
-
-Circuit, Compound.
-A circuit characterized by compounding of generating or receiving
-devices, as including several separate batteries, or several motors, or
-other receiving devices. It is sometimes used to indicate a circuit
-having its battery arranged in series. It should be restricted to the
-first definition.
-
-
-123  STANDARD ELECTRICAL DICTIONARY.
-
-
-Circuit, Derived.
-A partial circuit connected to two points of another circuit, so as to
-be in parallel with the portion thereof between such two points; a shunt
-circuit.
-
-Synonyms--Shunt Circuit--Derivative Circuit--Parallel Circuit.
-
-
-Circuit, Electric, Active.
-A circuit through which a current passes. The circuit itself need only
-be a conducting ring, or endless wire. Generally it includes, as part of
-the circuit, a generator of electro-motive force, and through which
-generator by conduction, ordinary or electrolytic, the same current goes
-that passes through the rest of the circuit. One and the same current
-passes through all parts of a series circuit when such current is
-constant.
-
-A current being produced by electro-motive force, and electromotive
-force disappearing in its production in an active circuit, there must be
-some source of energy which will maintain electromotive force against
-the drain made upon it by the current.
-
-The simplest conception of an active electric circuit is a ring or
-endless conductor swept through a field of force so as to cut lines of
-force. A simple ring dropped over a magnet pole represents the
-simplification of this process. In such a ring a current, exceedingly
-slight, of course, will be produced. In this case there is no generator
-in the circuit. An earth coil (see Coil, Earth,) represents such a
-circuit, with the addition, when experimented with, of a galvanometer in
-the circuit.
-
-In practice, a circuit includes a generator such as a battery or dynamo,
-and by conductors is led through a continuous path. Electric lamps,
-electrolytic cells, motors and the like may be included in it.
-
-The term "circuit" is also applied to portions of a true circuit, as the
-internal circuit, or external circuit. A certain amount of elasticity is
-allowed in its use. It by no means necessarily indicates a complete
-through circuit.
-
-
-Circuit, Electrostatic.
-(a) A circuit through which an electrostatic or high tension discharge
-takes place. It is virtually an electric circuit.
-
-(b) The term is applied also to the closed paths of electrostatic lines
-of force.
-
-
-Circuit, External.
-The portion of a circuit not included within the generator.
-
-
-Circuit, Grounded.
-A circuit, one of whose members, the return circuit, is represented by
-the earth, so that the earth completes the circuit. In telegraphy each
-end of the line is grounded or connected to an earth-plate, q. v., or to
-the water or gas-pipes, and the current is assumed to go through the
-earth on its return. It really amounts to a discharging at one end, and
-charging at the other end of the line. The resistance of the earth is
-zero, but the resistance of the grounding or connection with the earth
-may be considerable.
-
-Synonyms--Ground Circuit--Earth Circuit--Single Wire Circuit.
-
-[Transcriber's note: The resistance of the earth is high enough that
-large power system return currents may produce dangerous voltage
-gradients when a power line is shorted to the ground. Don't walk near
-downed lines!]
-
-
-124   STANDARD ELECTRICAL DICTIONARY.
-
-
-Circuit Indicator.
-A pocket compass, decomposition apparatus, galvanometer or other device
-for indicating the condition of a wire, whether carrying a current or
-not, and, if carrying one, its direction, and sometimes roughly
-indicating its strength.
-
-
-Circuit, Internal.
-The portion of an electric circuit included within the generator.
-
-
-Circuit, Line.
-The portion of a circuit embracing the main line or conductor, as in a
-telegraph circuit the line carried on the poles; distinguished from the
-local circuit (see Circuit, Local,) in telegraphy.
-
-
-Circuit, Local.
-In telegraphy, a short circuit with local generator or battery included,
-contained within the limits of the office or station and operated by a
-relay, q. v. This was the original local circuit; the term is applicable
-to any similar arrangement in other systems. Referring to the cut, the
-main line circuit includes the main battery, E, Key, P, Relay, R, ground
-plates, G, G1. The relay magnet opens and closes the local circuit with
-its local battery, L, and sounder magnet, H, with its armature, B. The
-minor parts, such as switches, are omitted.
-
-
-Fig. 90. LOCAL CIRCUIT OF TELEGRAPH SYSTEM.
-
-
-Circuit, Local Battery.
-A local circuit worked by and including a local battery in its course.
-
-
-125   STANDARD ELECTRICAL DICTIONARY.
-
-
-Circuit, Loop.
-A minor circuit introduced in series into another circuit by a cut-out,
-or other device, so as to become a portion of the main circuit.
-
-
-Circuit Loop Break.
-A supporter or bracket with two arms for carrying insulators. Its use is
-to enable a loop connection to be introduced into a line which is cut,
-so as to enable the connection of the ends of the loop to be made, one
-to each end of the through wire, which ends are attached, one to each of
-the two insulators.
-
-
-Circuit, Main.
-The circuit including the main line and apparatus supplied by the main
-battery, as distinguished from the local circuit. (See Circuit, Local.)
-
-
-Circuit, Main Battery.
-The main circuit, including the main or principal battery in its course.
-
-
-Circuit, Metallic.
-A circuit in which the current outside the generator, or similar parts,
-is carried on a metallic conductor; a circuit without any ground
-circuit. The including of a galvanic battery or electro plating bath
-would not prevent the application of the term; its essential meaning is
-the omission of the earth as the return circuit.
-
-
-Circuit, Negative Side of.
-The side of a circuit opposite to the positive side. (See Circuit,
-Positive Side of) It is defined as the half of a circuit leading to the
-positive terminal of the generator.
-
-
-Circuit, Open.
-A circuit with its continuity broken, as by disconnecting a wire from
-the battery, or opening a switch; a broken circuit is its synonym. To
-open a switch or disconnect or cut the wire is termed opening or
-breaking the circuit.
-
-Synonyms--Incomplete Circuit--Broken Circuit.
-
-
-Circuit, Positive Side of.
-This side is such that an observer standing girdled by the current with
-his head in the positive side or region, would see the current pass
-around him from his right toward his left hand. It is also defined as
-the half of the circuit leading to the negative terminal of the
-generator.
-
-
-Circuit, Recoil.
-The portion of a parallel circuit presenting an alternative path, q. v.,
-for a disruptive discharge.
-
-
-Circuit, Return.
-(a) The part of a circuit extending from the generator to the extreme
-point in general, upon which no apparatus is placed. In telegraph
-systems the ground generally forms the return circuit. The distinction
-of return and working circuit cannot always be made.
-
-(b) It may also be defined as the portion of a circuit leading to the
-negative terminal of the generator.
-
-
-126   STANDARD ELECTRICAL DICTIONARY
-
-
-Circuits, Forked.
-Circuits starting in different paths or directions from one and the same
-point.
-
-
-Circuit, Simple.
-A circuit containing a single generator, and single receiver of any
-kind, such as a motor or sounder, with a single connecting conductor. It
-is also used to indicate arrangement in multiple arc, but not generally,
-or with approval.
-
-
-Circuits, Parallel.
-Two or more conductors starting from a common point and ending at
-another common point are termed, parallel circuits, although really but
-parts of circuits. If of equal resistance their joint resistance is
-obtained by dividing the resistance of one by the number of parallel
-circuits. If of unequal resistance r, r', r" , etc., the formula for
-joint resistance, R, of two is
-
-R = ( r * r' ) / ( r + r' )
-
-This resistance may then be combined with a third one by the same
-formula, and thus any number may be calculated.
-
-Synonym--Shunt Circuit.
-
-
-Circuit, Voltaic.
-Properly a circuit including a conductor and voltaic couple.
-
-It is also applied to the electric circuit, q. v., or to any circuit
-considered as a bearer of current electricity.
-
-
-Circular Units.
-Units of area, usually applied to cross sectional area of conductors, by
-whose use area is expressed in terms of  circle of unit diameter,
-usually a circular mil, which is the area of a circle of one-thousandth
-of an inch diameter, or a circular millimeter, which is the area of a
-circle of one millimeter diameter. Thus a wire one-quarter of an inch
-in diameter has an area of 250 circular mils; a bar one centimeter in
-diameter has an area of ten circular millimeters.
-
-[Transcriber's Note: Area is the diameter squared. A 1/4 inch wire has
-62500 circular mils of area. A one centimeter (10 millimeter) wire has
-100 circular millimeters of area. Actual area = circular mils * (PI/4).]
-
-
-Circumflux.
-The product of the total number of conductor turns on the armature of a
-dynamo or motor, into the current carried thereby. For two pole machines
-it is equal to twice the armature ampere-turns; for four pole machines
-to four times such quantity, and so on.
-
-
-Clamp.
-The appliance for grasping and retaining the end of the rod that holds a
-carbon in the arc lamp.
-
-Clark's Compound.
-A cement used for the outside of the sheath of telegraph cables.
-Its formula is:
-  Mineral Pitch,   65 parts.
-  Silica,          30 parts.
-  Tar,              5 parts.
-All parts by weight.
-
-
-127  STANDARD ELECTRICAL DICTIONARY.
-
-
-Cleats.
-A support; a short block of wood, grooved transversely, for holding
-electric wires against a wall. For the three wire system three grooves
-are used. The entire wiring of apartments is sometimes done by the
-"cleat system," using cleats instead of battens, q. v., or mouldings.
-The cleats are secured against the wall with the grooves facing it, and
-the wires are introduced therein.
-
-
-Fig. 91. TWO WIRE CLEAT.
-
-
-Fig. 92. THREE WIRE CLEAT.
-
-
-Cleat, Crossing.
-A cleat with grooves or apertures to support wires which cross each
-other. Two or three grooves are transverse, and on the under side, as
-above; one groove is longitudinal and on the upper side.
-
-
-Cleavage, Electrification by.
-If a mass of mica is rapidly split in the dark a slight flash is
-perceived. Becquerel found that in such separation the two pieces came
-away oppositely charged with electricity. The splitting of mica is its
-cleavage.
-
-
-Clock, Controlled.
-In a system of electric clocks, the clocks whose movements are
-controlled by the current, regulated by the master or controlling clock.
-
-Synonym--Secondary Clock.
-
-
-Clock, Controlling.
-In a system of electric clocks the master clock which controls the
-movements of the others, by regulating the current.
-
-Synonym--Master Clock.
-
-
-Clock, Electric Annunciator.
-A clock operating any form of electric annunciator, as dropping
-shutters, ringing bells, and the like. It operates by the machinery
-closing circuits as required at any desired hour or intervals.
-
-
-128   STANDARD ELECTRICAL DICTIONARY.
-
-
-Clock, Electrolytic.
-A clock worked by the electrolytic deposition and resolution of a
-deposit of metal upon a disc. It is the invention of Nikola Tesla. A
-metallic disc is mounted on a transverse axis, so as to readily rotate.
-It is immersed in a vessel of copper sulphate. A current is passed
-through the bath, the terminals or electrodes being near to and facing
-the opposite edges of the disc, so that the line connecting the
-electrodes lies in the plane of the disc. If a current is passed through
-the solution by the electrodes, copper is deposited on one side of the
-disc, and as it rotates under the influence of the weight thus
-accumulated on one side, the same metal as it is brought to the other
-side of the disc is redissolved. Thus a continuous rotation is
-maintained. The cause of the deposition and solution is the position of
-the disc; one-half becomes negative and the other positive in their
-mutual relations.
-
-
-Clock, Self-winding Electric.
-A clock which is wound periodically by an electric motor and battery.
-
-
-Clockwork, Feed.
-In arc-lamps the system of feeding the carbon or carbons by clockwork
-whose movements are controlled by the resistance of the arc. This system
-is employed in the Serrin, and in the Gramme regulators, among others.
-The carbons, if they approach, move clockwork. The movement of this is
-stopped or freed by an electro-magnet placed in shunt around the arc
-and carbons.
-
-
-Cloisons.
-Partitions or divisions; applied to the winding of electro-magnets and
-coils where the winding is put on to the full depth, over single
-sections of the core, one section at a time, until the whole core is
-filled up.
-
-
-Closure.
-The closing or completion of a circuit by depressing a key or moving a
-switch.
-
-
-Clutch.
-In arc lamps a device for the feed of the upper carbons. In its simplest
-form it is simply a plate or bar pierced with a hole through which the
-carbon passes loosely. The action of the mechanism raises or lowers one
-end of the plate or bar. As it rises it binds and clutches the carbon,
-and if the action continues it lifts it a little. When the same end is
-lowered the carbon and clutch descend together until the opposite end of
-the clutch being prevented from further descent, the clutch approaches
-the horizontal position and the rod drops bodily through the aperture.
-The cut shows the clutches of the Brush double carbon lamp. In practice
-the lifting and releasing as regulated by an electro-magnet are so very
-slight that practically an almost absolutely steady feed is secured. A
-similar clutch is used in the Weston lamp.
-
-
-129  STANDARD ELECTRICAL DICTIONARY.
-
-
-Clutch, Electro-magnetic.
-A clutch or appliance for connecting a shaft to a source of rotary
-motion while the latter is in action. In one form a disc, in whose face
-a groove has been formed, which groove is filled with a coil of wire, is
-attached to the loose wheel, while the shaft carries a flat plate to act
-as armature. On turning on the current the flat plate is attached,
-adheres, and causes its wheel to partake of the motion of the shaft.
-Contact is made by brushes and collecting rings.
-
-In the cut, A A is the attracted disc; the brushes, B B, take current to
-the collecting rings, C. The magnetizing coil is embedded in the body of
-the pulley, as shown.
-
-
-Fig. 93. CLUTCH OF BRUSH LAMP.
-
-
-Fig. 94. ELECTRO-MAGNETIC CLUTCH.
-
-
-130   STANDARD ELECTRICAL DICTIONARY.
-
-
-Coatings of a Condenser or Prime Conductor.
-The thin conducting coatings of tinfoil, gold leaf or other conducting
-substance, enabling the surface to receive and part with the electric
-charge readily. Without such a coating the charge and discharge would be
-very slow, and would operate by degrees only, as one part of a
-non-conducting surface might be densely charged and another part be
-quite devoid of sensible charge.
-
-
-Code, Cipher.
-A code of arbitrary words to designate prearranged or predetermined
-words, figures or sentences. The systems used in commerce have single
-words to represent whole sentences or a number of words of a sentence.
-This not only imparts a degree of secrecy, but makes the messages much
-shorter. Codes are used a great deal in cable transmission.
-
-
-Code, Telegraphic.
-A telegraphic alphabet. (See Alphabets, Telegraphic.)
-
-
-Coefficient.
-In algebra, the numerical multiplier of a symbol, as in the expression
-"5x," 5 is the coefficient. In physics, generally a number expressing
-the ratio or relation between quantities, one of which is often unity,
-as a standard or base of the set of coefficients. Thus the coefficient
-of expansion by heat of any substance is obtained by dividing its volume
-for a given degree of temperature by its volume at the standard
-temperature as 0� C., or 32� F. This gives a fraction by which if any
-volume of a substance, taken at 0� C., or at whatever may be taken as
-the basic temperature, is multiplied, the expanded volume for the given
-change of temperature will be obtained as the product. A coefficient
-always in some form implies the idea of a multiplier. Thus the
-coefficient of an inch referred to a foot would be 1/12 or .833+,
-because any number of inches multiplied by that fraction would give the
-corresponding number of feet.
-
-[Transcriber's note: 1/12 is 0.0833+]
-
-
-Coefficient, Economic.
-In machinery, electric generators, prime motors and similar structures,
-the number expressing the ratio between energy absorbed by the device,
-and useful, not necessarily available, work obtained from it. It is
-equal to work obtained divided by energy absorbed, and is necessarily a
-fraction. If it exceeded unity the doctrine of the conservation of
-energy would not be true. The economic coefficient expresses the
-efficiency, q. v., of any machine, and of efficiencies there are several
-kinds, to express any one of which the economic coefficient may be used.
-Thus, let W--energy absorbed, and w = work produced ; then w/W is the
-economic coefficient, and for each case would be expressed numerically.
-(See Efficiency, Commercial--Efficiency, Electrical--Efficiency of
-Conversion.)
-
-The distinction between useful and available work in a dynamo is as
-follows: The useful work would include the work expended by the field,
-and the work taken from the armature by the belt or other mechanical
-connection. Only the latter would be the available work.
-
-
-131  STANDARD ELECTRICAL DICTIONARY.
-
-
-Coercive or Coercitive Force.
-The property of steel or hard iron, in virtue of which it slowly takes
-up or parts with magnetic force, is thus termed ("traditionally";
-Daniell). It seems to have to do with the positions of the molecules, as
-jarring a bar of steel facilitates its magnetization or accelerates its
-parting, when not in a magnetic field, with its permanent or residual
-magnetism. For this reason a permanent magnet should never be jarred,
-and permitting the armature to be suddenly attracted and to strike
-against it with a jar injures its attracting power.
-
-Coercive force is defined also as the amount of negative magnetizing
-force required to reduce remnant magnetism to zero.
-
-By some authorities the term is entirely rejected, as the phenomenon
-does not seem directly a manifestation of force.
-
-
-Coil and Coil Plunger.
-A device resembling the coil and plunge, q. v., except that for the
-plunger of iron there is substituted a coil of wire of such diameter as
-to enter the axial aperture of the other, and wound or excited in the
-same or in the opposite sense, according to whether attraction or
-repulsion is desired.
-
-
-Coil and Plunger.
-A coil provided with a core which is free to enter or leave the central
-aperture. When the coil is excited, the core is drawn into it. Various
-forms of this device have been used in arc lamp regulators.
-
-Synonym--Sucking coil.
-
-
-Fig. 95. COIL AND COIL PLUNGER OF MENGIES ARC LAMP.
-
-
-Fig. 96. COIL AND PLUNGER EXPERIMENT.
-
-
-132   STANDARD ELECTRICAL DICTIONARY.
-
-
-Coil and Plunger, Differential.
-An arrangement of coil and plunger in which two plungers or one plunger
-are acted on by two coils, wound so as to act oppositely or
-differentially on the plunger or plungers. Thus one coil may be in
-parallel with the other, and the action on the plunger will then depend
-on the relative currents passing through the coils.
-
-
-Coil, Choking.
-A coil of high self-induction, used to resist the intensity of or
-"choke" alternating currents. Any coil of insulated wire wound around
-upon a laminated or divided iron core forms a choking coil. The iron
-coil is usually so shaped as to afford a closed magnetic circuit.
-
-A converter or transformer acts as a choking coil as long as its
-secondary is left open. In alternating current work special choking
-coils are used. Thus for theatrical work, a choking coil with a movable
-iron core is used to change the intensity of the lights. It is in
-circuit with the lamp leads. By thrusting in the core the self-induction
-is increased and the current diminishes, lowering the lamps; by
-withdrawing it the self-induction diminishes, and the current increases.
-Thus the lamps can be made to gradually vary in illuminating power like
-gas lights, when turned up or down.
-
-Synonyms--Kicking Coil--Reaction Coil.
-
-
-Fig. 97. DIFFERENTIAL COILS AND PLUNGERS.
-
-
-Fig. 98. BISECTED COILS.
-
-
-133    STANDARD ELECTRICAL DICTIONARY.
-
-
-Coils, Bisected.
-Resistance coils with connections at their centers, as shown in the
-diagram. They are used for comparing the resistances of two conductors.
-The connections are arranged as shown in the coil, each coil being
-bisected. For the wires, movable knife-edge contacts are employed. The
-principle of the Wheatstone bridge is used in the method and
-calculations.
-
-
-Coil, Earth.
-A coil of wire mounted with commutator to be rotated so as to cut the
-lines of force of the earth's magnetic field, thereby generating
-potential difference. The axis of rotation may be horizontal, when the
-potential will be due to the vertical component of the earth's field, or
-the axis may be horizontal, when the potential will be due to the
-vertical component, or it may be set at an intermediate angle.
-
-Synonym--Delezenne's Circle.
-
-
-Fig. 99. DELEZENNE'S CIRCLE OR EARTH COIL.
-
-
-Coil, Electric.
-A coil of wire used to establish a magnetic field by passing a current
-through it. The wire is either insulated, or so spaced that its
-convolutions do not touch.
-
-
-Coil, Flat.
-A coil whose windings all lie in one plane, making a sort of disc, or an
-incomplete or perforated disc.
-
-
-Coil, Induction.
-A coil in which by mutual induction the electromotive force of a portion
-of a circuit is made to produce higher or lower electro-motive force, in
-an adjoining circuit, or in a circuit, part of which adjoins the
-original circuit, or adjoins part of it.
-
-An induction coil comprises three principal parts, the core, the primary
-coil and the secondary coil. If it is to be operated by a steady
-current, means must be provided for varying it or opening and closing
-the primary circuit. A typical coil will be described.
-
-
-134   STANDARD ELECTRICAL DICTIONARY.
-
-
-The core is a mass of soft iron preferably divided to prevent extensive
-Foucault currents. A cylindrical bundle of soft iron wires is generally
-used. Upon this the primary coil of reasonably heavy wire, and of one or
-two layers in depth, is wrapped, all being carefully insulated with
-shellac and paper where necessary. The secondary coil is wrapped upon or
-over the primary. It consists of very fine wire; No. 30 to 36 is about
-the ordinary range. A great many turns of this are made. In general
-terms the electro-motive force developed by the secondary stands to that
-of the primary terminals in the ratio of the windings. This is only
-approximate.
-
-The greatest care is required in the insulating. The secondary is
-sometimes wound in sections so as to keep those parts differing greatly
-in potential far from each other. This prevents sparking, which would
-destroy the insulation.
-
-A make and break, often of the hammer and anvil type, is operated by the
-coil. (See Circuit Breaker, Automatic.) As the current passes through
-the primary it magnetizes the core. This attracts a little hammer which
-normally resting on an anvil completes the circuit. The hammer as
-attracted is lifted from the anvil and breaks the circuit. The soft iron
-core at once parts with its magnetism and the hammer falls upon the
-anvil again completing the circuit. This operation goes on rapidly, the
-circuit being opened and closed in quick succession.
-
-Every closing of the primary circuit tends to produce a reverse current
-in the secondary, and every opening of the primary circuit tends to
-produce a direct current in the secondary. Both are of extremely short
-duration, and the potential difference of the two terminals of the
-secondary may be very high if there are many times more turns in the
-secondary than in the primary.
-
-The extra currents interfere with the action of an induction coil. To
-avoid their interference a condenser is used. This consists of two
-series of sheets of tin foil. Leaves of paper alternate with the sheets
-of tin-foil, the whole being built up into a little book. Each sheet of
-tin-foil connects electrically with the sheet next but one to it. Thus
-each leaf of a set is in connection with all others of the same set, but
-is insulated from the others. One set of leaves of tin-foil connects
-with the hammer, the other with the anvil. In large coils there may be
-75 square feet of tin-foil in the condenser.
-
-The action of the condenser is to dispose of the direct extra current.
-When the primary circuit is opened this current passes into the
-condenser, which at once discharges itself in the other direction
-through the coil. This demagnetizes the core, and the action intensifies
-and shortens the induced current. The condenser prevents sparking, and
-in general improves the action of the coil.
-
-Many details enter into the construction of coils, and many variations
-in their construction obtain. Thus a mercury cup into which a plunger
-dips often replaces the anvil and hammer.
-
-
-135   STANDARD ELECTRICAL DICTIONARY.
-
-
-The induction coil produces a rapid succession of sparks, which may
-spring across an interval of forty inches. The secondary generally ends
-in special terminals or electrodes between which the sparking takes
-place. A plate of glass, two inches in thickness, can be pierced by
-them. In the great Spottiswoode coil there are 280 miles of wire in the
-secondary, and the wire is about No. 36 A.W.G.
-
-
-Fig. 100. VERTICAL SECTION OF INDUCTION COIL.
-
-
-Fig. l01. PLAN OF INDUCTION COIL CONNECTIONS.
-
-
-Induction coils have quite extended use in electrical work. They are
-used in telephone transmitters, their primary being in circuit with the
-microphone, and their secondary with the line and receiving telephone.
-In electric welding, and in the alternating current system they have
-extended application. In all these cases they have no automatic circuit
-breaker, the actuating current being of intermittent or alternating
-type.
-
-
-136   STANDARD ELECTRICAL DICTIONARY.
-
-
-In the cuts the general construction of an induction coil is shown. In
-the sectional elevation, Fig. 100, A, is the iron core; B is the primary
-of coarse wire; C is a separating tube, which may be of pasteboard; D is
-the secondary of fine wire; E, E are the binding posts connected to the
-secondary; H, H are the heads or standards; K, K are the terminals of
-the primary; F is the vibrating contact spring; G, a standard carrying
-the contact screw; J is the condenser with wires, L, M, leading to it.
-
-Referring to the plan, Fig. 101, H represents the primary coil; B and A
-are two of the separate sheets of the condenser, each sheet with
-projecting ears; G, G are the heads of the coil; the dark lines are
-connections to the condenser. One set of sheets connects with the
-primary coil at C, and also with the vibrating spring shown in plan and
-in the elevation at F. The other set of sheets connects with the post,
-carrying the contact screw. The other terminal of the primary runs to a
-binding post E. F, in the plan is a binding post in connection with the
-standard and contact screw.
-
-
-Coil, Induction, Inverted.
-An induction coil arranged to have a lower electro-motive force in the
-secondary than in the primary. This is effected by having more
-convolutions in the primary wire than in the secondary. Such coils in
-practice are used with the alternating current and then do not include a
-circuit breaker or condenser. They are employed in alternating current
-system and in electric welding. (See Welding, Electric--Converter.)
-
-In the cut an inverted coil, as constructed for electric welding is
-shown. In it the primary coil is marked P; the secondary, merely a bar
-of metal, is marked E, with terminals S, S; the heavy coils, I, of iron
-wire are the core; K is a screw for regulating the clamps; J, Z is a
-second one for the same purpose, while between D and D' the heat is
-produced for welding the bars, B, B', held in the clamps, C, C'. It will
-be seen how great may be the difference in turns between the single
-circle of heavy copper rod or bar which is the secondary of the coil,
-and the long coil of wire forming the primary.
-
-
-Fig. 102. INVERTED INDUCTION COIL FOR ELECTRIC WELDING.
-
-
-137   STANDARD ELECTRICAL DICTIONARY.
-
-
-Coil, Induction, Telephone.
-An induction coil used in telephone circuits. It is placed in the box or
-case near the transmitter. The primary is in circuit with the
-microphone. The secondary is in circuit with the line and receiving
-telephone. In the Bell telephone apparatus the primary of the induction
-coil is wound with No. 18 to 24 A. W. G. wire to a resistance of 1/2
-ohm; the secondary, with No. 36 wire to a resistance of 80 ohms. The
-Edison telephone induction coil was wound with similar wires to a
-resistance of 3 to 4 ohms and of 250 ohms respectively.
-
-
-Coil, Magnetizing.
-A coil of insulated wire for making magnets; and for experimental uses;
-it has a short axis and central aperture of as small size as consistent
-with the diameter of the bar to be magnetized, which has to pass through
-it readily. The wire may be quite heavy, 2 or 3 millimeters (.08--.12
-inch) thick, and is cemented together with carpenter's glue, or with
-shellac or ethereal solution of gum copal. In use it is passed over the
-bar a few times while a heavy current is going through it. It is used
-for magic circles also. (See Circle, Magic.)
-
-
-Fig. 103. MAGNETIZING COIL.
-
-
-Coil, Resistance.
-A coil constructed for the purpose of offering a certain resistance to a
-steady current. This resistance may be for the purpose of carrying out
-quantitative tests, as in Wheatstone bridge work (see Wheatstone's
-Bridge), or simply to reduce the intensity of a current. For the first
-class of work the coils are wound so as to prevent the creation of a
-magnetic field. This is effected by first doubling the wire without
-breaking it, and then starting at the bend the doubled wire, which is
-insulated, is wound on a bobbin or otherwise until a proper resistance
-is shown by actual measurement. The coils are generally contained or set
-in closed boxes with ebonite tops. Blocks of brass are placed on the
-top, and one end from one coil and one end from the next connect with
-the same block. By inserting a plug, P, so as to connect any two blocks,
-which have grooves reamed out for the purpose, the coil beneath will be
-short circuited. German silver, platinoid or other alloy, q. v., is
-generally the material of the wire. A great object is to have a wire
-whose resistance will be unaffected by heat.
-
-
-138   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 104. RESISTANCE COILS AND CONNECTIONS, SHOWING PLUG.
-
-
-Coil, Rhumkorff.
-The ordinary induction coil with circuit breaker, for use with original
-direct and constant current, is thus termed. (See Coil, Induction.)
-
-Synonym--Inductorium.
-
-
-Coil, Ribbon.
-A coil made of copper ribbon wound flatwise, often into a disc-like
-shape, and insulated by tape or strips of other material intervening
-between the successive turns.
-
-
-Coils, Compensating.
-Extra coils on the field magnets of dynamos or motors, which coils are
-in series with the armature windings for the purpose of keeping the
-voltage constant. In compound wound machines the regular series-wound
-coil is thus termed. In a separately excited dynamo a coil of the same
-kind in circuit with the armature may be used as a compensator.
-
-
-Coils, Henry's.
-An apparatus used in repeating a classic experiment in electro-magnetic
-induction, due to Prof. Henry. It consists in a number of coils, the
-first and last ones single, the intermediate ones connected in pairs,
-and one of one pair placed on the top of one of the next pair. On
-opening or closing the circuit of an end coil the induced effect goes
-through the series and is felt in the circuit of the other end coil.
-Prof. Henry extended the series so as to include seven successive
-inductions, sometimes called inductions of the first, second, third and
-other orders. Frequently ribbon coils (see Coil, Ribbon,) are used in
-these experiments.
-
-
-Coils, Sectioned.
-A device for prolonging the range of magnetic attraction. It consists of
-a series of magnetizing coils traversed by an iron plunger. As it passes
-through them, the current is turned off the one in the rear or passing
-to the rear and turned into the next one in advance. The principle was
-utilized in one of Page's electric motors about 1850, and later by
-others. The port-electric railroad, q. v., utilizes the same principle.
-
-
-139  STANDARD ELECTRICAL DICTIONARY.
-
-
-Collecting Ring.
-In some kinds of generators instead of the commutator a pair of
-collecting rings of metal, insulated from the machine and from each
-other, are carried on the armature shaft. A brush, q. v., presses on
-each, and the circuit terminals connect to these two brushes. Such rings
-are employed often on alternating current generators, where the current
-does not have to be changed or commuted. Collecting rings with their
-brushes are used also where a current has to be communicated to a
-revolving coil or circuit as in the magnetic car wheel, the cut of which
-is repeated here. The coil of wire surrounding the wheel and rotating
-with it has to receive current. This it receives through the two
-stationary brushes which press upon two insulated metallic rings,
-surrounding the shaft. The terminals of the coil connect one to each
-ring. Thus while the coil rotates it constantly receives current, the
-brushes being connected to the actuating circuit.
-
-
-Fig. 105. MAGNETIC CAR WHEEL SHOWING COLLECTING RINGS AND BRUSHES.
-
-
-Collector.
-(a) A name for the brush, q. v., in mechanical electric generators, such
-as dynamos, a pair of which collectors or brushes press on the
-commutator or collecting rings, and take off the current.
-
-(b) The pointed connections leading to the prime conductor on a static
-machine for collecting the electricity; often called combs. The points
-of the combs or collectors face the statically charged rotating glass
-plate or cylinder of the machine.
-
-
-Colombin.
-The insulating material between the carbons in a Jablochkoff candle or
-other candle of that type. Kaolin was originally used. Later a mixture
-of two parts calcium sulphate (plaster of Paris) and one part barium
-sulphate (barytes) was substituted.
-
-The colombin was three millimeters (.12 inch) wide, and two millimeters
-(.08 inch) thick. (See Candle, Jablochkoff.)
-
-
-Column, Electric.
-An old name for the voltaic pile, made up of a pile of discs of copper
-and zinc, with flannel discs, wet with salt solution or dilute acid,
-between each pair of plates.
-
-
-140   STANDARD ELECTRICAL DICTIONARY.
-
-
-Comb.
-A bar from which a number of teeth project, like the teeth of a comb. It
-is used as a collector of electricity from the plate of a frictional or
-influence electric machine; it is also used in a lightning arrester to
-define a path of very high resistance but of low self-induction, for the
-lightning to follow to earth.
-
-
-Communicator.
-The instrument by which telegraph signals are transmitted is sometimes
-thus termed.
-
-
-Commutator.
-In general an apparatus for changing. It is used on electric current
-generators, and motors, and on induction coils, and elsewhere, for
-changing the direction of currents, and is of a great variety of types.
-
-Synonym--Commuter (but little used).
-
-
-Fig. 106. DYNAMO OR MOTOR COMMUTATOR.
-
-
-Commutator Bars.
-The metallic segments of a dynamo or motor commutator.
-
-
-Commutator, Flats in.
-A wearing away or lowering in level of one or more metallic segments of
-a commutator. They are probably due in many cases to sparking, set up by
-periodic springing in the armature mounting, or by defective commutator
-connections.
-
-
-Commutator of Current Generators and Motors.
-In general a cylinder, formed of alternate sections of conducting and
-non-conducting material, running longitudinally or parallel with the
-axis. Its place is on the shaft of the machine, so that it rotates
-therewith. Two brushes, q. v., or pieces of conducting material, press
-upon its surface.
-
-
-141  STANDARD ELECTRICAL DICTIONARY.
-
-
-As a part of electric motors and generators, its function is to collect
-the currents produced by the cutting of lines of force so as to cause
-them all to concur to a desired result. The cut shows the simplest form
-of commutator, one with but two divisions. Its object may be to enable a
-current of constant direction to be taken from a rotating armature, in
-which the currents alternate or change direction once in each rotation.
-It is carried by the shaft A of the armature and rotates with it. It
-consists of two leaves, S S, to which the terminals of the armature are
-connected. Two springs, W W, the terminals of the outer circuit, press
-against the leaves. The springs which do this take off the current. It
-is so placed, with reference to the springs and armature, that just as
-the current changes in direction, each leaf changes from one spring to
-the other. Thus the springs receive constant direction currents. The
-changing action of this commutator appears in its changing the character
-of the current from alternating to constant. Were two insulated
-collecting rings used instead of a commutator, the current in the outer
-circuit would be an alternating one. On some dynamos the commutator has
-a very large number of leaves.
-
-Taking the Gramme ring armature, there must be as many divisions of the
-commutator as there are connections to the coils. In this case the
-function of the commutator is simply to lessen friction, for the brushes
-could be made to take current from the coils directly outside of the
-periphery of the ring.
-
-
-Commutator, Split Ring.
-A two-division commutator for a motor; it consists of two segments of
-brass or copper plate, bent to arcs of a circle, and attached to an
-insulating cylinder. They are mounted on the revolving spindle, which
-carries the armature, and acts as a two part commutator. For an example
-of its application, see Armature, Revolving, Page's. (See also Fig.
-107.)
-
-
-Fig. 107. SECTION OF SPLIT RING COMMUTATOR, WITH BRUSHES.
-
-
-Compass.
-An apparatus for utilizing the directive force of the earth upon the
-magnetic needle. It consists of a circular case, within which is poised
-a magnetized bar of steel. This points approximately to the north, and
-is used on ships and elsewhere to constantly show the direction of the
-magnetic meridian. Two general types are used. In one the needle is
-mounted above a fixed "card" or dial, on which degrees or points of the
-compass, q. v., are inscribed. In the other the card is attached to the
-needle and rotates with it. The latter represents especially the type
-known as the mariner's compass. (See Compass, Mariner's--Compass,
-Spirit, and other titles under compass, also Magnetic Axis--Magnetic
-Elements.) The needle in good compasses carries for a bearing at its
-centre, a little agate cup, and a sharp brass pin is the point of
-support.
-
-
-Compass, Azimuth.
-A compass with sights on one of its diameters; used in determining the
-magnetic bearing of objects.
-
-
-142   STANDARD ELECTRICAL DICTIONARY.
-
-
-Compass Card.
-The card in a compass; it is circular in shape, and its centre coincides
-with the axis of rotation of the magnetic needle; on it are marked the
-points of the compass, at the ends generally of star points. (See
-Compass, Points of the.) It may be fixed, and the needle may be poised
-above it, or it may be attached to the needle and rotate with it.
-
-
-Compass, Declination.
-An instrument by which the magnetic declination of any place may be
-determined. It is virtually a transit instrument and compass combined,
-the telescope surmounting the latter. In the instrument shown in the
-cut, L is a telescope mounted by its axis, X, in raised journals with
-vernier, K, and arc x, for reading its vertical angle, with level n. The
-azimuth circle, Q, R, is fixed. A vernier, V is carried by the box, A,
-E, and both turn with the telescope. A very light lozenge-shaped
-magnetic needle, a, b, is pivoted in the exact centre of the graduated
-circles, Q R, and M. The true meridian is determined by any convenient
-astronomical method, and the telescope is used for the purpose. The
-variation of the needle from the meridian thus determined gives the
-magnetic declination.
-
-
-FIG. 108. DECLINATION COMPASS.
-
-
-Compass, Inclination.
-A magnetic needle mounted on a horizontal axis at its centre of gravity,
-so as to be free to assume the dip, or magnetic inclination, when placed
-in the magnetic meridian. It moves over the face of a vertical graduated
-circle, and the frame also carries a spirit level and graduated
-horizontal circle. In use the frame is turned until the needle is
-vertical. Then the axis of suspension of the needle is in the magnetic
-meridian. The vertical circle is then turned through 90� of the horizon,
-which brings the plane of rotation of the needle into the magnetic
-meridian, when it assumes the inclination of the place.
-
-
-143  STANDARD ELECTRICAL DICTIONARY.
-
-
-Compass, Mariner's.
-A compass distinguished by the card being attached to and rotating with
-the needle. A mark, the "lubber's mark" of the sailors is made upon the
-case. This is placed so that the line connecting it, and the axis of
-rotation of the card is exactly in a plane, passing through the keel of
-the ship. Thus however the ship may be going, the point of the card
-under or in line with the "lubber's mark," shows how the ship is
-pointing. The case of the mariner's compass is often bowl-shaped and
-mounted in gimbals, a species of universal joint, so as to bc always
-horizontal. (See Compass, Spirit-Gimbals.)
-
-
-FIG. 109. MARINER'S COMPASS.
-
-
-Compass, Points of the.
-The circle of the horizon may bc and is best referred to angular
-degrees. It has also been divided into thirty-two equiangular and named
-points. A point is 11.25�. The names of the points are as follows:
-North, North by East, North North-east, North-east by North, North-east,
-North-east by East, East North-east, East by North, East, East by South,
-East South-east, South-east by East, South-east, South-east by South,
-South South-east, South by East, South, South by West, South South-west,
-South-west by South, South-west, South-west by West, West South-west,
-West by South, West, West by North, West North-west, North-west by West,
-North-west, North West by North, North North-west, North by West. They
-are indicated by their initials as N. N. W., North North-west, N. by W.,
-North by West.
-
-
-Compass, Spirit.
-A form of mariner's compass. The bowl or case is hermetically sealed and
-filled with alcohol or other nonfreezing liquid. The compass card is
-made with hollow compartments so as nearly to float. In this way the
-friction of the pivot or point of support is greatly diminished, and the
-compass is far more sensitive.
-
-
-Compass, Surveyor's.
-A species of theodolite; a telescope with collimation lines, mounted
-above a compass, so as to be applicable for magnetic surveys. Its use is
-to be discouraged on account of the inaccuracy and changes in
-declination of the magnetic needle.
-
-
-144   STANDARD ELECTRICAL DICTIONARY.
-
-
-Compensating Resistances.
-In using a galvanometer shunt the total resistance of the circuit is
-diminished so that in some cases too much current flows through it; in
-such case additional resistance, termed as above, is sometimes
-introduced in series. The shunt in parallel with the galvanometer is
-thus compensated for, and the experimental or trial circuit does not
-take too much current.
-
-
-Complementary Distribution.
-Every distribution of electricity has somewhere a corresponding
-distribution, exactly equal to it of opposite electricity; the latter is
-the complimentary distribution to the first, and the first distribution
-is also complimentary to it.
-
-
-Component.
-A force may always be represented diagrammatically by a straight line,
-terminating in an arrow-head to indicate the direction, and of length to
-represent the intensity of the force. The line may always be assumed to
-represent the diagonal of a parallelogram, two of whose sides are
-represented by lines starting from the base of the arrow, and of length
-fixed by the condition that the original force shall be the diagonal of
-the parallelogram of which they are two contiguous sides; such lines are
-called components, and actually represent forces into which the original
-force may always be resolved. The components can have any direction.
-Thus the vertical component of a horizontal force is zero; its
-horizontal component is equal to itself. Its 450 component is equal to
-the square root of one-half of its square.
-
-
-Condenser.
-An appliance for storing up electrostatic charges: it is also called a
-static accumulator. The telegraphic condenser consists of a box packed
-full of sheets of tinfoil. Between every two sheets is a sheet of
-paraffined paper, or of mica. The alternate sheets of tinfoil are
-connected together, and each set has its own binding post. (See
-Accumulator, Electrostatic.)
-
-
-Condenser, Sliding.
-An apparatus representing a Leyden jar whose coatings can be slid past
-each other. This diminishes or increases the facing area, and
-consequently in almost exactly similar ratio diminishes or increases the
-capacity of the condenser.
-
-
-Conductance.
-The conducting power of a given mass of specified material of specified
-shape and connections. Conductance varies in cylindrical or prismatic
-conductors, inversely as the length, directly as the cross-section, and
-with the conductivity of the material. Conductance is an attribute of
-any specified conductor, and refers to its shape, length and other
-factors. Conductivity is an attribute of any specified material without
-direct reference to its shape, or other factors.
-
-
-Conduction.
-The process or act of conducting a current.
-
-
-145  STANDARD ELECTRICAL DICTIONARY.
-
-
-Conductivity.
-The relative power of conducting the electric current possessed by
-different substances. A path for the current through the ether is opened
-by the presence of a body of proper quality, and this quality, probably
-correlated to opacity, is termed conductivity. There is no perfect
-conductor, all offer some resistance, q. v., and there is hardly any
-perfect non-conductor. It is the reverse and reciprocal of resistance.
-
-
-Conductivity, Specific.
-The reciprocal of specific resistance. (See Resistance--Specific.)
-
-
-Conductivity, Unit of.
-The reciprocal of the ohm; it is a more logical unit, but has never been
-generally adopted; as a name the title mho (or ohm written backwards)
-has been suggested by Sir William Thomson, and provisionally adopted.
-
-
-Conductivity, Variable.
-The conductivity for electric currents of conductors varies with their
-temperature, with varying magnetization, tension, torsion and
-compression.
-
-
-Conductor.
-In electricity, anything that permits the passage of an electric
-current. Any disturbance in the ether takes the form of waves because
-the ether has restitutive force or elasticity. In a conductor, on the
-other hand, this force is wanting; it opens a path through the ether and
-a disturbance advances through it from end to end with a wave front, but
-with no succession of waves. This advance is the beginning of what is
-termed a current. It is, by some theorists, attributed to impulses given
-at all points along the conductor through the surrounding ether, so that
-a current is not merely due to an end thrust. If ether waves preclude a
-current on account of their restitutive force, ether waves cannot be
-maintained in a conductor, hence conductors should be opaque to light,
-for the latter is due to ether waves. This is one of the more practical
-every day facts brought out in Clerk Maxwell's electromagnetic theory of
-light. The term conductor is a relative one, as except a vacuum there is
-probably no substance that has not some conducting power. For relative
-conducting power, tables of conductivity, q. v., should be consulted.
-The metals beginning with silver are the best conductors, glass is one
-of the worst.
-
-[Transcriber's note: See "ether" for contemporary comments on this now
-discarded concept.]
-
-
-Conductor, Anti-Induction.
-A current conductor arranged to avoid induction from other lines. Many
-kinds have been invented and made the subject of patents. A fair
-approximation may be attained by using a through metallic circuit and
-twisting the wires composing it around each other. Sometimes concentric
-conductors, one a wire and the other a tube, are used, insulated, one
-acting as return circuit for the other.
-
-
-Conductor, Conical.
-A prime conductor of approximately conical shape, but rounded on all
-points and angles. Its potential is highest at the point.
-
-
-146   STANDARD ELECTRICAL DICTIONARY.
-
-
-Conductor, Imbricated.
-A conductor used in dynamo armatures for avoiding eddy currents, made by
-twisting together two or more strips of copper.
-
-
-Conductor, Prime.
-A body often cylindrical or spherical in shape, in any case with no
-points or angles, but rounded everywhere, whose surface, if the
-conductor itself is not metallic, is made conducting by tinfoil or gold
-leaf pasted over it. It is supported on an insulating stand and is used
-to collect or receive and retain static charges of electricity.
-
-
-Conductors, Equivalent.
-Conductors of identical resistance. The quotient of the length divided
-by the product of the conductivity and cross-section must be the same in
-each, if each is of uniform diameter.
-
-
-Conjugate. adj.
-Conjugate coils or conductors are coils placed in such relation that the
-lines of force established by one do not pass through the coils of the
-other. Hence variations of current in one produce no induced currents in
-the other.
-
-
-Connect. v.
-To bring two ends of a conductor together, or to bring one end of a
-conductor in connection with another, or in any way to bring about an
-electrical connection.
-
-
-Connector.
-A sleeve with screws or other equivalent device for securing the ends of
-wires in electrical contact. A binding-post, q. v., is an example.
-Sometimes wire spring-catches are used, the general idea being a device
-that enables wires to be connected or released at will without breaking
-off or marring their ends. The latter troubles result from twisting
-wires together.
-
-
-Consequent Poles.
-A bar magnet is often purposely or accidentally magnetized so as to have
-both ends of the same polarity, and the center of opposite polarity. The
-center is said to comprise two consequent poles. (See Magnet,
-Anomalous.)
-
-
-Conservation of Electricity.
-As every charge of electricity has its equal and opposite charge
-somewhere, near or far, more or less distributed, the sum of negative is
-equal always to the sum of positive electrical charges. For this
-doctrine the above title was proposed by Lippman.
-
-
-Contact Breaker.
-Any contrivance for closing a circuit, and generally for opening and
-closing in quick succession. An old and primitive form consisted of a
-very coarsely cut file. This was connected to one terminal, and the
-other terminal was drawn over its face, making and breaking contact as
-it jumped from tooth to tooth. (See Circuit Breaker--do. Automatic,
-etc.--do. Wheel-do. Pendulum.)
-
-
-147   STANDARD ELECTRICAL DICTIONARY.
-
-
-Contact, Electric.
-A contact between two conductors, such that a current can flow through
-it. It may be brought about by simple touch or impact between the ends
-or terminals of a circuit, sometimes called a dotting contact, or by a
-sliding or rubbing of one terminal on another, or by a wheel rolling on
-a surface, the wheel and surface representing the two terminals.
-
-There are various descriptions of contact, whose names are
-self-explanatory. The term is applied to telegraph line faults also, and
-under this, includes different descriptions of contact with neighboring
-lines, or with the earth.
-
-
-Contact Electricity.
-When two dissimilar substances are touched they assume different
-electric potentials. If conductors, their entire surfaces are affected;
-if dielectrics, only the surfaces which touch each other. (See Contact
-Theory.)
-
-
-Contact Faults.
-A class of faults often called contacts, due to contact of the conductor
-of a circuit with another conductor. A full or metallic contact is where
-practically perfect contact is established; a partial contact and
-intermittent contact are self-explanatory.
-
-
-Contact Point.
-A point, pin or stud, often of platinum, arranged to come in contact
-with a contact spring, q. v., or another contact point or surface, under
-any determined conditions.
-
-
-Contact Potential Difference.
-The potential difference established by the contact of two dissimilar
-substances according to the contact theory, q. v.
-
-
-Contact Series.
-An arrangement or tabulation of substances in pairs, each intermediate
-substance appearing in two pairs, as the last member of the first, and
-first member of the succeeding pair, with the statement of the potential
-difference due to their contact, the positively electrified substance
-coming first. The following table of some contact potentials is due to
-Ayrton and Perry:
-CONTACT SERIES.
-Difference of Potential in Volts.
-Zinc--Lead        .210
-Lead--Tin         .069
-Tin--Iron         .313
-Iron--Copper      .146
-Copper--Platinum  .238
-Platinum-Carbon   .113
-
-The sum of these differences is 1.089, which is the contact potential
-between zinc and carbon.
-
-Volta's Law refers to this and states that--
-  The difference of potential produced by the contact of any two
-  substances is equal to the sum of the differences of potentials
-  between the intervening substances in the contact series.
-
-It is to be remarked that the law should no longer be restricted to or
-stated only for metals.
-
-
-148   STANDARD ELECTRICAL DICTIONARY.
-
-
-Contact-spring.
-A spring connected to one lead of an electric circuit, arranged to press
-against another spring, or contact point, q. v., under any conditions
-determined by the construction of the apparatus. (See Bell,
-Electric--Coil, Induction.)
-
-
-Contact Theory.
-A theory devised to explain electrification, the charging of bodies by
-friction, or rubbing, and the production of current by the voltaic
-battery. It holds that two bodies, by mere contact become oppositely
-electrified. If such contact is increased in extent by rubbing together,
-the intensity of their electrification is increased. This
-electrification is accounted for by the assumption of different kinetic
-energy, or energy of molecular motion, possessed by the two bodies;
-there being a loss and gain of energy, on the two sides respectively,
-the opposite electrifications are the result. Then when separated, the
-two bodies come apart oppositely electrified.
-
-The above accounts for the frictional production of electricity. In the
-voltaic battery, a separation of the atoms of hydrogen and oxygen, and
-their consolidation into molecules occurs, and to such separation and
-the opposite electrification of the electrodes by the oxygen and
-hydrogen, the current is attributed, because the hydrogen goes to one
-electrode, and the oxygen to the other, each giving up or sharing its
-own charge with the electrodes to which it goes. If zinc is touched to
-copper, the zinc is positively and the copper negatively electrified. In
-the separation of hydrogen and oxygen, the hydrogen is positively and
-the oxygen negatively electrified. In the battery, the current is due to
-the higher contact difference of oxygen and hydrogen compared to that
-between zinc and copper. It will be seen that the two contact actions in
-a battery work against each other, and that the current is due to a
-differential contact action. The zinc in a battery is electrified
-negatively because the negative electrification of the oxygen is greater
-in amount than its own positive electrification due to contact with the
-copper.
-
-
-Contractures.
-A muscular spasm or tetanus due to the passage of a current of
-electricity; a term in electro-therapeutics.
-
-
-Controlling Field.
-The magnetic or electro-magnetic field, which is used in galvanometers
-to control the magnetic needle, tending to restore it to a definite
-position whenever it is turned therefrom. It may be the earth's field or
-one artificially produced.
-
-
-Controlling Force.
-In galvanometers and similar instruments, the force used to bring the
-needle or indicator back to zero. (See Controlling
-Field--Electro-Magnetic Control--Gravity Control--Magnetic
-Control--Spring Control.)
-
-
-149   STANDARD ELECTRICAL DICTIONARY.
-
-
-Convection, Electric.
-The production of blasts or currents of air (convection streams) from
-points connected to statically charged conductors. The term is sometimes
-applied to electric convection of heat. (See Convection of Heat,
-Electric.)
-
-
-Convection, Electrolytic.
-The resistance of acidulated water as a true conductor is known to be
-very, almost immeasurably, high. As an electrolytic, its resistance is
-very much lower. Hence the current produced between immersed electrodes
-is theoretically almost null, unless the difference of potential between
-them is high enough to decompose the liquid. Yet a feeble current too
-great for a true conduction current is sometimes observed when two
-electrodes with potential difference too low to cause decomposition are
-immersed in it. Such a current is termed an electrolytic convection
-current. It is supposed to be due to various causes. Some attribute it
-to the presence of free oxygen from the air, dissolved in the water with
-which the hydrogen combines. Others attribute it to the diffusion of the
-gases of decomposition in the solution; others assume a partial
-polarization of the molecules without decomposition. Other theories are
-given, all of which are unsatisfactory. The term is due to Helmholtz.
-
-
-Convection of Heat, Electric.
-The effect of a current upon the distribution of heat in an unevenly
-heated conductor. In some, such as copper, the current tends to equalize
-the varying temperatures; the convection is then said to be positive, as
-comparable to that of water flowing through an unequally heated tube. In
-others, such as platinum or iron, it is negative, making the heated
-parts hotter, and the cooler parts relatively cooler.
-
-The effect of the electric current in affecting the distribution of heat
-in unequally heated metal (Thomson's effect. q. v.), is sometimes so
-termed. If a current passes through unequally heated iron it tends to
-increase the difference of temperature, and the convection is negative;
-in copper it tends to equalize the temperature, and the convection is
-positive.
-
-
-Converter.
-An induction coil used with the alternating current for changing
-potential difference and inversely therewith the available current. They
-generally lower the potential, and increase the current, and are placed
-between the primary high potential system that connects the houses with
-the central station, and the secondary low potential system within the
-houses. A converter consists of a core of thin iron sheets, wound with a
-fine primary coil of many convolutions, and a coarse secondary coil of
-few convolutions. The ratio of convolutions gives the ratio of maximum
-potential differences of their terminals between the primary and
-secondary coils. The coil may be jacketed with iron to increase the
-permeance. (See Alternating Current System.)
-
-
-Fig. 110. FERRANTI'S CONVERTER OR TRANSFORMER.
-
-
-Fig. 111.   SWINBURNE'S HEDGEHOG TRANSFORMER.
-
-
-150   STANDARD ELECTRICAL DICTIONARY.
-
-
-Co-ordinates, System of.
-A system for indicating the position of points in space by reference to
-fixed lines, intersecting at a determined and arbitrary point 0, termed
-the origin of co-ordinates. In plane rectangular co-ordinates two lines
-are drawn through the origin, one horizontal, termed the axis of
-abscissas, or axis of X. All distances measured parallel to it, if
-unknown, are indicated by x, and are termed abscissas. The other axis is
-vertical, and is termed the axis of ordinates, or axis of Y. All
-distances measured parallel to it, if unknown, are indicated by y and
-are termed ordinates. Thus by naming its abscissa and ordinate a point
-has its position with reference to the axes determined, and by
-indicating the relation between a point, line or curve, and a system of
-abscissas and ordinates, the properties of a line or curve can be
-expressed algebraically. Co-ordinates may also be inclined to each other
-at any other angles, forming oblique co-ordinates; relations may be
-expressed partly in angles referred to the origin as a centre, giving
-polar co-ordinates. For solid geometry or calculations in three
-dimensions, a third axis, or axis of Z, is used, distances parallel to
-which if unknown are indicated by z.
-
-
-Fig. 112. AXES OF CO-ORDINATES.
-
-
-151   STANDARD ELECTRICAL DICTIONARY.
-
-
-Cooling Box.
-In a hydroelectric machine, q. v., a conduit or chest through which the
-steam passes on its way to the nozzles. Its object is to partially
-condense the steam so as to charge it with water vesicles whose friction
-against the sides of the nozzles produces the electrification .
-
-
-152   STANDARD ELECTRICAL DICTIONARY.
-
-
-Copper.
-A metal; one of the elements. Symbol, Cu; atomic weight, 63.5;
-equivalent, 63.5 and 31.75; valency, 1 and 2; specific gravity, 8.96.
-It is a conductor of electricity, whose conductivity is liable to
-vary greatly on account of impurities.
-
-                                     Annealed.   Hard drawn.
-Relative resistance (Silver = 1),     1.063      1.086
-Specific resistance,                  1.598      1.634 microhms.
-
-Resistance of a wire at 0� C. (32� F.),
-                                     Annealed.     Hard Drawn.
-(a) 1 foot long, weighing 1 grain,     .2041  ohms   .2083  ohms.
-(b) 1 foot long, 1/1000 inch thick,   9.612   "     9.831    "
-(c) 1 meter long, weighing 1 gram,     .1424  "      .1453   "
-(d) 1 meter long, 1 millimeter thick,  .02034 "      .02081  "
-
-                                            microhm.   microhm.
-Resistance of 1 inch cube at 0�C. (32� F.)   .6292     .6433
-
-Percentage of resistance change,
-per 1� C. (1.8� F.) at about 20� C. (68� F.) = 0.388 per cent.
-
-Electro-chemical Equivalent (Hydrogen = .0105)   Cuprous  .6667
-                                                 Cupric   .3334
-
-In electricity it has been very extensively used as the negative plate
-of voltaic batteries. It has its most extensive application as
-conductors for all classes of electrical leads.
-
-
-Copper Bath.
-A solution of copper used for depositing the metal in the electroplating
-process. For some metals, such as zinc or iron, which decompose copper
-sulphate solution, special baths have to be used.
-
-The regular bath for copper plating is the following:
-
-To water acidulated with 8 to 10 percent. of sulphuric acid as much
-copper sulphate is added as it will take up at the ordinary temperature.
-The saturated bath should have a density of 1.21. It is used cold and is
-kept in condition by the use of copper anodes, or fresh crystals may be
-added from time to time.
-
-For deposition on zinc, iron, tin and other metals more electropositive
-than copper, the following baths may be used, expressed in parts by
-weight:
-
-                          Tin
-                     Iron and Steel.   Cast Iron
-                     Cold     Hot.     and Zinc.   Zinc.
-Sodium Bisulphate,    500     200         300      100
-Potassium Cyanide,    500     700         500      700
-Sodium Carbonate,    1000     500         ---      ---
-Copper Acetate,       475     500         350      450
-Aqua Ammoniae,        350     300         200      150
-Water,               2500    2500        2500     2500
-
-These are due to Roseleur.
-
-
-153  STANDARD ELECTRICAL DICTIONARY.
-
-
-Copper Stripping Bath.
-There is generally no object in stripping copper from objects. It can be
-done with any of the regular copper baths using the objects to be
-stripped as anode. The danger of dissolving the base itself and thereby
-injuring the article and spoiling the bath is obvious.
-
-
-Cord Adjuster.
-A device for shortening or lengthening the flexible cord, or flexible
-wire supplying the current, and by which an incandescent lamp is
-suspended. It often is merely a little block of wood perforated with two
-holes through which the wires pass, and in which they are retained in
-any desired position by friction and their own stiffness.
-
-
-Fig. 113. FLEXIBLE CORD ADJUSTER.
-
-
-Cord, Flexible.
-A pair of flexible wire conductors, insulated lightly, twisted together
-and forming apparently a cord. They are used for minor services, such as
-single lamps and the like, and are designated according to the service
-they perform, such as battery cords, dental cords (for supplying dental
-apparatus) and other titles.
-
-
-Core.
-(a) The conductor or conductors of an electric cable. (See Cable Core.)
-
-(b) The iron mass, generally central in an electro-magnet or armature,
-around which the wire is coiled. It acts by its high permeance to
-concentrate or multiply the lines of force, thus maintaining a more
-intense field. (See Armature--Magnet, Electro--Magnet, Field--Core,
-Laminated). In converters or transformers (See Converter) it often
-surrounds the wire coils.
-
-
-Core-discs.
-Discs of thin wire, for building up armature cores. (See Laminated
-Core.) The usual form of core is a cylinder. A number of thin discs of
-iron are strung upon the central shaft and pressed firmly together by
-end nuts or keys. This arrangement, it will be seen, gives a cylinder as
-basis for winding the wire on.
-
-
-Core-discs, Pierced.
-Core-discs for an armature of dynamo or motor, which are pierced around
-the periphery. Tubes of insulating material pass through the peripheral
-holes, and through these the conductors or windings are carried. The
-conductors are thus embedded in a mass of iron and are protected from
-eddy currents, and they act to reduce the reluctance of the air gaps.
-From a mechanical point of view they are very good. For voltages over
-100 they are not advised.
-
-Synonym--Perforated Core-discs.
-
-
-154   STANDARD ELECTRICAL DICTIONARY.
-
-
-Core-discs, Segmental.
-Core-discs made in segments, which are bolted together to form a
-complete disc or section of the core. The plan is adopted principally on
-large cores. The discs thus made up are placed together to form the core
-exactly as in the case of ordinary one piece discs.
-
-
-Fig. 114. PIERCED OR PERFORATED CORE-DISC.
-
-
-Core-discs, Toothed.
-Core-discs of an armature of a dynamo or motor, which discs are cut into
-notches on the periphery. These are put together to form the armature
-core, with the notches corresponding so as to form a series of grooves
-in which the wire winding is laid. This construction reduces the actual
-air-gaps, and keeps the wires evenly spaced. Distance-pieces of
-box-wood, m, m, are sometimes used to lead the wires at the ends of the
-armature.
-
-
-Fig. 115. TOOTHED CORE-DISC.
-
-
-Core, Laminated.
-A core of an armature, induction coil or converter or other similar
-construction, which is made up of plates insulated more or less
-perfectly from each other. The object of lamination is to prevent the
-formation of Foucault currents. (See Currents, Foucault.) As insulation,
-thin shellacked paper may be used, or sometimes the superficial
-oxidation of the plates alone is relied on. The plates, in general, are
-laid perpendicular to the principal convolutions of the wire, or
-parallel to the lines of force. The object is to break up currents, and
-such currents are induced by the variation in intensity of the field of
-force, and their direction is perpendicular to the lines of force, or
-parallel to the inducing conductors.
-
-A core built up of core discs is sometimes termed a tangentially
-laminated core. Made up of ribbon or wire wound coil fashion, it is
-termed a radially laminated core.
-
-
-155  STANDARD ELECTRICAL DICTIONARY.
-
-
-Core Ratio.
-In a telegraph cable the ratio existing between the diameter of the
-conducting core and the insulator. To get a ratio approximately accurate
-in practical calculations, the diameter of the core is taken at 5 per
-cent. less than its actual diameter. The calculations are those
-referring to the electric constants of the cable, such as its static
-capacity and insulation resistance.
-
-
-Core, Ribbon.
-For discoidal ring-shaped cores of armatures, iron ribbon is often used
-to secure lamination and prevent Foucault currents.
-
-Synonym--Tangentially Laminated Core.
-
-
-Core, Ring.
-A core for a dynamo or motor armature, which core forms a complete ring.
-
-
-Core, Stranded.
-In an electric light cable, a conducting core made up of a group of
-wires laid or twisted together.
-
-
-Core, Tubular.
-Tubes used as cores for electro-magnets. For very small magnetizing
-power, tubular cores are nearly as efficient as solid ones in straight
-magnets, because the principal reluctance is due to the air-path. On
-increasing the magnetization the tubular core becomes less efficient
-than the solid core, as the reluctance of the air-path becomes
-proportionately of less importance in the circuit.
-
-
-Corpusants.
-The sailors' name for St. Elmo's Fire, q. v.
-
-
-Coulomb.
-The practical unit of quantity of electricity. It is the quantity passed
-by a current of one ampere intensity in one second. It is equal to 1/10
-the C. G. S. electro-magnetic unit of quantity, and to 3,000,000,000 C.
-G. S. electrostatic units of quantity. It corresponds to the
-decomposition of .0935 milligrams of water, or to the deposition of
-1.11815 milligrams of silver.
-
-[Transcriber's note: A coulomb is approximately 6.241E18 electrons. Two
-point charges of one coulomb each, one meter apart, exerts a force of
-900,000 metric tons.]
-
-
-Coulomb's Laws of Electrostatic Attraction and Repulsion.
-1. The repulsions or attractions between two electrified bodies are in
-the inverse ratio of the squares of their distance.
-
-2. The distance remaining the same, the force of attraction or repulsion
-between two electrified bodies is directly as the product of the
-quantities of electricity with which they are charged.
-
-
-156   STANDARD ELECTRICAL DICTIONARY.
-
-
-Counter, Electric.
-A device for registering electrically, or by electro-magnetic machinery,
-the revolutions of shafts, or any other data or factors.
-
-
-Counter-electro-motive Force.
-A potential difference in a circuit opposed to the main potential
-difference, and hence, resisting the operation of the latter, and
-diminishing the current which would be produced without it. It appears
-in electric motors, which, to a certain extent, operate as dynamos and
-reduce the effective electro-motive force that operates them. It
-appears in the primary coils of induction coils, and when the secondary
-circuit is open, is almost equal to the main electro-motive force, so
-that hardly any current can go through them under such conditions. It
-appears in galvanic batteries, when hydrogen accumulates on the copper
-plate, and in other chemical reactions. A secondary battery is charged
-by a current in the reverse direction to that which it would normally
-produce. Its own potential difference then appears as a
-counter-electro-motive force.
-
-Synonym--Back Electro-motive Force.
-
-
-Counter-electro-motive Force of Polarization.
-To decompose a solution by electrolysis, enough electro-motive force is
-required to overcome the energy of composition of the molecule
-decomposed. A part of this takes the form of a counter-electromotive
-force, one which, for a greater or less time would maintain a current in
-the opposite direction if the original source of current were removed.
-Thus in the decomposition of water, the electrodes become covered, one
-with bubbles of oxygen, the others with bubbles of hydrogen; this
-creates a counter E. M. F. of polarization. In a secondary battery, the
-working current may be defined as due to this cause.
-
-Synonym--Back Electro-motive Force of Polarization.
-
-
-Couple.
-Two forces applied to different points of a straight line, when opposed
-in direction or unequal in amount, tend to cause rotation about a point
-intermediate between their points of application and lying on the
-straight line. Such a pair constitute a couple.
-
-
-Couple, Voltaic or Galvanic.
-The combination of two electrodes, and a liquid or liquids, the
-electrodes being immersed therein, and being acted on differentially by
-the liquid or liquids. The combination constitutes a source of
-electro-motive force and consequently of current. It is the galvanic or
-voltaic cell or battery. (See Battery, Voltaic--Contact
-Theory--Electro-motive Force--Electro-motive Series.)
-
-
-Coupling.
-The joining of cells of a galvanic battery, of dynamos or of other
-devices, so as to produce different effects as desired.
-
-
-157  STANDARD ELECTRICAL DICTIONARY
-
-
-Couple, Astatic.
-An astatic couple is a term sometimes applied to astatic needles, q.v.
-
-
-C. P.
-(a) An abbreviation of or symbol for candle power, q. v.
-
-(b) An abbreviation of chemically pure. It is used to indicate a high
-degree of purity of chemicals. Thus, in a standard Daniell battery, the
-use of C. P. chemicals may be prescribed or advised.
-
-
-Crater.
-The depression that forms in the positive carbon of a voltaic arc. (See
-Arc, Voltaic.)
-
-
-Creeping.
-A phenomenon of capillarity, often annoying in battery jars. The
-solution, by capillarity, rises a little distance up the sides,
-evaporates, and as it dries more creeps up through it, and to a point a
-little above it. This action is repeated until a layer of the salts may
-form over the top of the vessel. To avoid it, paraffine is often applied
-to the edges of the cup, or a layer of oil, often linseed oil, is poured
-on the battery solution,
-
-
-Crith.
-The weight of a litre of hydrogen at 0� C. (32� F.), and 760 mm. (30
-inches) barometric pressure. It is .0896 grams. The molecular weight of
-any gas divided by 2 and multiplied by the value of the crith, gives the
-weight of a litre of the gas in question. Thus a litre of electrolytic
-gas, a mixture of two molecules of hydrogen for one of oxygen, with a
-mean molecular weight of 12, weighs (12/2) * .0896 or .5376 gram.
-
-
-Critical Speed.
-(a) The speed of rotation at which a series dynamo begins to excite its
-own field.
-
-(b) In a compound wound dynamo, the speed at which the same potential is
-generated with the full load being taken from the machine, as would be
-generated on open circuit, in which case the shunt coil is the only
-exciter. The speed at which the dynamo is self-regulating.
-
-(c) In a dynamo the rate of speed when a small change in the speed of
-rotation produces a comparatively great change in the electro-motive
-force. It corresponds to the same current (the critical current) in any
-given series dynamo.
-
-
-Cross.
-(a) A contact between two electric conductors; qualified to express
-conditions as a weather cross, due to rain, a swinging cross when a wire
-swings against another, etc.
-
-(b) vb. To make such contact.
-
-
-Cross-Connecting Board.
-A special switch board used in telephone exchanges and central telegraph
-offices. Its function is, by plugs and wires, to connect the line wires
-with any desired section of the main switchboard. The terminals of the
-lines as they enter the building are connected directly to the
-cross-connecting board.
-
-
-158   STANDARD ELECTRICAL DICTIONARY.
-
-
-Cross Connection.
-A method of disposing of the effects of induction from neighboring
-circuits by alternately crossing the two wires of a metallic telephone
-circuit, so that for equal intervals they lie to right and left, or one
-above, and one below.
-
-[Transcriber's note: Also used to cancel the effect of variations in the
-ambient magnetic field, such as solar activity.]
-
-
-Crossing Wires.
-The cutting out of a defective section in a telegraph line, by carrying
-two wires from each side of the defective section across to a
-neighboring conductor, pressing it for the time into service and cutting
-the other wire if necessary.
-
-
-Cross-magnetizing Effect.
-A phase of armature interference. The current in an armature of a dynamo
-or motor is such as to develop lines of force approximately at right
-angles to those of the field. The net cross-magnetizing effect is such
-component of these lines, as is at right angles to the lines produced by
-the field alone.
-
-
-Cross-over Block.
-A piece of porcelain or other material shaped to receive two wires which
-are to cross each other, and hold them so that they cannot come in
-contact. It is used in wiring buildings, and similar purposes. (See
-Cleat, Crossing.)
-
-Cross Talk.
-On telephone circuits by induction or by contact with other wires sound
-effects of talking are sometimes received from other circuits; such
-effects are termed cross talk.
-
-
-Crucible, Electric.
-A crucible for melting difficultly fusible substances, or for reducing
-ores, etc., by the electric arc produced within it. Sometimes the
-heating is due more to current incandescence than to the action of an
-arc.
-
-
-Fig. 116. ELECTRIC FURNACE OR CRUCIBLE.
-
-
-Crystallization, Electric.
-Many substances under proper conditions take a crystalline form. The
-great condition is the passage from the fluid into the solid state. When
-such is brought about by electricity in any way, the term electric
-crystallization may be applied to the phenomenon. A solution of silver
-nitrate for instance, decomposed by a current, may give crystals of
-metallic silver.
-
-
-159    STANDARD ELECTRICAL DICTIONARY.
-
-
-Cup, Porous.
-A cup used in two-fluid voltaic batteries to keep the solutions separate
-to some extent. It forms a diaphragm through which diffusion inevitably
-takes place, but which is considerably retarded, while electrolysis and
-electrolytic convection take place freely through its walls. As
-material, unglazed pottery is very generally used.
-
-In some batteries the cup is merely a receptacle for the solid
-depolarizer. Thus, in the Leclanch� battery, the cup contains the
-manganese dioxide and graphite in which the carbon electrode is
-embedded, but does not separate two solutions, as the battery only uses
-one. Nevertheless, the composition of the solution outside and inside
-may vary, but such variation is incidental only, and not an essential of
-the operation.
-
-
-Current.
-The adjustment, or effects of a continuous attempt at readjustment of
-potential difference by a conductor, q. v., connecting two points of
-different potential. A charged particle or body placed in a field of
-force tends to move toward the oppositely charged end or portion of the
-field. If a series of conducting particles or a conducting body are held
-so as to be unable to move, then the charge of the field tends, as it
-were, to move through it, and a current results. It is really a
-redistribution of the field and as long as such redistribution continues
-a current exists. A current is assumed to flow from a positive to a
-negative terminal; as in the case of a battery, the current in the outer
-circuit is assumed to flow from the carbon to the zinc plate, and in the
-solution to continue from zinc to carbon. As a memoria technica the zinc
-may be thought of as generating the current delivering it through the
-solution to the carbon, whence it flows through the wire connecting
-them. (See Ohm's Law--Maxwell's Theory of Light--Conductor-Intensity.)
-
-[Transcriber's note: Supposing electric current to be the motion of
-positive charge causes no practical difficulty, but the current is
-actually the (slight) motion of negative electrons.]
-
-
-Current, After.
-A current produced by the animal tissue after it has been subjected to a
-current in the opposite direction for some time. The tissue acts like a
-secondary battery. The term is used in electro-therapeutics.
-
-
-Current, Alternating.
-Usually defined and spoken of as a current flowing alternately in
-opposite directions. It may be considered as a succession of currents,
-each of short duration and of direction opposite to that of its
-predecessor. It is graphically represented by such a curve as shown in
-the cut. The horizontal line may denote a zero current, that is no
-current at all, or may be taken to indicate zero electro-motive force.
-The curve represents the current, or the corresponding electro-motive
-forces. The further from the horizontal line the greater is either, and
-if above the line the direction is opposite to that corresponding to the
-positions below the line. Thus the current is alternately in opposite
-directions, has periods of maximum intensity, first in one and then in
-the opposite sense, and between these, passing from one direction to the
-other, is of zero intensity. It is obvious that the current may rise
-quickly in intensity and fall slowly, or the reverse, or may rise and
-fall irregularly. All such phases may be shown by the curve, and a curve
-drawn to correctly represent these variations is called the
-characteristic curve of such current. It is immaterial whether the
-ordinates of the curve be taken as representing current strength or
-electromotive force. If interpreted as representing electro-motive
-force, the usual interpretation and best, the ordinates above the line
-are taken as positive and those below as negative.
-
-Synonyms--Reversed Current--Periodic Currents.
-
-
-Fig. 117. CHARACTERISTIC CURVE OF ALTERNATING CURRENT.
-
-
-160   STANDARD ELECTRICAL DICTIONARY.
-
-
-Current, Atomic.
-A unit of current strength used in Germany; the strength of a current
-which will liberate in 24 hours (86,400 seconds) one gram of hydrogen
-gas, in a water voltameter. The atomic current is equal to 1.111
-amperes. In telegraphic work the milliatom is used as a unit, comparable
-to the milliampere. The latter is now displacing it.
-
-
-Current, Charge.
-If the external coatings of a charged and uncharged jar are placed in
-connection, and if the inner coatings are now connected, after
-separating them they are both found to be charged in the same manner. In
-this process a current has been produced between the outside coatings
-and one between the inner ones, to which Dove has given the name Charge
-Current, and which has all the properties of the ordinary discharge
-current. (Ganot.)
-
-
-Current, Circular.
-A current passing through a circular conductor; a current whose path is
-in the shape of a circle.
-
-
-Current, Commuted.
-A current changed, as regards direction or directions, by a commutator,
-q. v., or its equivalent.
-
-
-Current, Constant.
-An unvarying current. A constant current system is one maintaining such
-a current. In electric series, incandescent lighting, a constant current
-is employed, and the system is termed as above. In arc lighting systems,
-the constant current series arrangement is almost universal.
-
-
-161  STANDARD ELECTRICAL DICTIONARY.
-
-
-Current, Continuous.
-A current of one direction only; the reverse of an alternating current.
-(See Current, Alternating.)
-
-
-Current, Critical.
-The current produced by a dynamo at its critical speed; at that speed
-when a slight difference in speed produces a great difference in
-electro-motive force. On the characteristic curve it corresponds to the
-point where the curve bends sharply, and where the electro-motive force
-is about two-thirds its maximum.
-
-
-Current, Daniell/U.S. , Daniell/Siemens' Unit.
-A unit of current strength used in Germany. It is the strength of a
-current produced by one Daniell cell in a circuit of the resistance of
-one Siemens' unit. The current deposits 1.38 grams of copper per hour.
-It is equal to 1.16 amperes.
-
-
-Current, Demarcation.
-In electro-therapeutics, a current which can be taken from an injured
-muscle, the injured portion acting electro-negatively toward the
-uninjured portion.
-
-
-Current Density.
-The current intensity per unit of cross-sectional area of the conductor.
-The expression is more generally used for electrolytic conduction, where
-the current-density is referred to the mean facing areas of the
-electrodes, or else to the facing area of the cathode only.
-
-The quality of the deposited metal is intimately related to the current
-density. (See Burning.)
-
-              Proper Current Density for Electroplating
-           Amperes Per Square Foot of Cathode.--(Urquhart.)
-Copper, Acid Bath.                               5.0  to 10.0
-"       Cyanide Bath,                            3.0  "   5.0
-Silver, Double Cyanide,                          2.0  "   5.0
-Gold, Chloride dissolved in Potassium Cyanide,   1.0  "   2.0
-Nickel, Double Sulphate,                         6.6  "   8.0
-Brass, Cyanide,                                  2.0  "   3.0
-
-
-Current, Diacritical.
-A current, which, passing through a helix surrounding an iron core,
-brings it to one-half its magnetic saturation, q. v.
-
-
-Current, Diaphragm.
-If a liquid is forced through a diaphragm, a potential difference
-between the liquid on opposite sides of the diaphragm is maintained.
-Electrodes or terminals of platinum may be immersed in the liquid, and a
-continuous current, termed a diaphragm current, may be taken as long as
-the liquid is forced through the diaphragm. The potential difference is
-proportional to the pressure, and also depends on the nature of the
-diaphragm and on the liquid.
-
-
-162   STANDARD ELECTRICAL DICTIONARY.
-
-
-Current, Direct.
-A current of unvarying direction, as distinguished from an alternating
-current. It may be pulsatory or intermittent in character, but must be
-of constant direction.
-
-
-Current, Direct Induced.
-On breaking a circuit, if it is susceptible of exercising
-self-induction, q. v., an extra current, in the direction of the
-original is induced, which is called "direct" because in the same
-direction as the original. The same is produced by a current in one
-circuit upon a parallel one altogether separated from it. (See
-Induction, Electro-Magnetic-Current, Extra.)
-
-Synonym--Break Induced Current.
-
-
-Current, Direction of.
-The assumed direction of a current is from positively charged electrode
-to negatively charged one; in a galvanic battery from the carbon or
-copper plate through the outer circuit to the zinc plate and back
-through the electrolyte to the carbon or copper plate. (See Current.)
-
-[Transcriber's note: Current is caused by the motion of negative
-electrons, from the negative pole to the positive. The electron was
-discovered five years after this publication.]
-
-
-Current, Displacement.
-The movement or current of electricity taking place in a dielectric
-during displacement. It is theoretical only and can only be assumed to
-be of infinitely short duration. (See Displacement, Electric.)
-
-
-Currents, Eddy Displacement.
-The analogues of Foucault currents, hypothetically produced in the mass
-of a dielectric by the separation of the electricity or by its
-electrification. (See Displacement.)
-
-
-Current, Extra.
-When a circuit is suddenly opened or closed a current of very brief
-duration, in the first case in the same direction, in the other case in
-the opposite direction, is produced, which exceeds the ordinary current
-in intensity. A high potential difference is produced for an instant
-only. These are called extra currents. As they are produced by
-electro-magnetic induction, anything which strengthens the field of
-force increases the potential difference to which they are due. Thus the
-wire may be wound in a coil around an iron core, in which case the extra
-currents may be very strong. (See Induction, Self-Coil, Spark.)
-
-
-Current, Faradic.
-A term in medical electricity for the induced or secondary alternating
-current, produced by comparatively high electro-motive force, such as
-given by an induction coil or magneto-generator, as distinguished from
-the regular battery current.
-
-
-163   STANDARD ELECTRICAL DICTIONARY.
-
-
-Current, Foucault.
-A current produced in solid conductors, and which is converted into heat
-(Ganot). These currents are produced by moving the conductors through a
-field, or by altering the strength of a field in which they are
-contained. They are the source of much loss of energy and other
-derangement in dynamos and motors, and to avoid them the armature cores
-are laminated, the plane of the laminations being parallel to the lines
-of force. (See Core, Laminated.)
-
-The presence of Foucault currents, if of long duration, is shown by the
-heating of the metal in which they are produced. In dynamo armatures
-they are produced sometimes in the metal of the windings, especially if
-the latter are of large diameter.
-
-Synonyms--Eddy Currents--Local Currents--Parasitical Currents.
-
-
-Current, Franklinic.
-In electro-therapeutics the current produced by a frictional electric
-machine.
-
-
-Current, Induced.
-The current produced in a conductor by varying the conditions of a field
-of force in which it is placed; a current produced by induction.
-
-
-Current Induction.
-Induction by one current on another or by a portion of a current on
-another portion of itself. (See Induction.)
-
-
-Current Intensity.
-Current strength, dependent on or defined by the quantity of electricity
-passed by such current in a given time. The practical unit of current
-intensity is the ampere, equal to one coulomb of quantity per second of
-time.
-
-
-Current, Inverse Induced.
-The current induced in a conductor, when in a parallel conductor or in
-one having a parallel component a current is started, or is increased in
-strength. It is opposite in direction to the inducing current and hence
-is termed inverse. (See Induction, Electro-magnetic.) The parallel
-conductors may be in one circuit or in two separate circuits.
-
-Synonyms--Make-induced Current--Reverse-induced Current.
-
-
-Current, Jacobi's Unit of.
-A current which will liberate one cubic centimeter of mixed gases
-(hydrogen and oxygen) in a water voltameter per minute, the gases being
-measured at 0� C. (32� F.) and 760 mm. (29.92 inches) barometric
-pressure. It is equal to .0961 ampere.
-
-
-Current, Joint.
-The current given by several sources acting together. Properly, it
-should be restricted to sources connected in series, thus if two battery
-cells are connected in series the current they maintain is their joint
-current.
-
-
-Current, Linear.
-A current passing through a straight conductor; a current whose path
-follows a straight line.
-
-
-164   STANDARD ELECTRICAL DICTIONARY.
-
-
-Current, Make and Break.
-A succession of currents of short duration, separated by absolute
-cessation of current. Such current is produced by a telegraph key, or by
-a microphone badly adjusted, so that the circuit is broken at intervals.
-The U. S. Courts have virtually decided that the telephone operates by
-the undulatory currents, and not by a make and break current. Many
-attempts have been made to produce a telephone operating by a
-demonstrable make and break current, on account of the above
-distinction, in hopes of producing a telephone outside of the scope of
-the Bell telephone patent.
-
-[Transcriber's note: Contemporary long distance telephone service is
-digital, as this item describes.]
-
-
-Current-meter.
-An apparatus for indicating the strength of current. (See Ammeter.)
-
-
-Current, Negative.
-In the single needle telegraph system the current which deflects the
-needle to the left.
-
-
-Current, Nerve and Muscle.
-A current of electricity yielded by nerves or muscles. Under proper
-conditions feeble currents can be taken from nerves, as the same can be
-taken from muscles.
-
-
-Current, Opposed.
-The current given by two or more sources connected in opposition to each
-other. Thus a two volt and a one volt battery may be connected in
-opposition, giving a net voltage of only one volt, and a current due to
-such net voltage.
-
-
-Current, Partial.
-A divided or branch current. A current which goes through a single
-conductor to a point where one or more other conductors join it in
-parallel, and then divides itself between the several conductors, which
-must join further on, produces partial currents. It produces as many
-partial currents as the conductors among which it divides. The point of
-division is termed the point of derivation.
-
-Synonym--Derived Current.
-
-
-Current, Polarizing.
-In electro-therapeutics, a constant current.
-
-
-Current, Positive.
-In the single needle telegraph system the current which deflects the
-needle to the right.
-
-
-Current, Pulsatory.
-A current of constant direction, but whose strength is constantly
-varying, so that it is a series of pulsations of current instead of a
-steady flow.
-
-Current, Rectified.
-A typical alternating current is represented by a sine curve, whose
-undulations extend above and below the zero line. If by a simple two
-member commutator the currents are caused to go in one direction, in
-place of the sine curve a series of short convex curves following one
-another and all the same side of the zero line results. The currents all
-in the same direction, become what is known as a pulsating current.
-
-Synonym--Redressed Current.
-
-
-165  STANDARD ELECTRICAL DICTIONARY.
-
-
-Current, Rectilinear.
-A current flowing through a rectilinear conductor. The action of
-currents depending on their distance from the points where they act,
-their contour is a controlling factor. This contour is determined by the
-conductors through which they flow.
-
-
-Current Reverser.
-A switch or other contrivance for reversing the direction of a
-current in a conductor.
-
-
-Currents, Amp�rian.
-The currents of electricity assumed by Ampere's theory to circulate
-around a magnet. As they represent the maintenance of a current or of
-currents without the expenditure of energy they are often assumed to be
-of molecular dimensions. As they all go in the same sense of rotation
-and are parallel to each other the result is the same as if a single set
-of currents circulated around the body of the magnet. More will be found
-on this subject under Magnetism. The Amp�rian currents are purely
-hypothetical and are predicated on the existence of a field of force
-about a permanent magnet. (See Magnetism, Amp�re's Theory of.)
-
-If the observer faces the north pole of a magnet the Amp�rian currents
-are assumed to go in the direction opposite to that of a watch, and the
-reverse for the south pole.
-
-
-Figs. 118-119 DIRECTION OF AMP�RIAN CURRENTS.
-
-
-Currents, Angular.
-Currents passing through conductors which form an angle with each other.
-
-
-Currents, Angular, Laws of.
-1. Two rectilinear currents, the directions of which form an angle with
-each other, attract one another when both approach to or recede from the
-apex of the angle.
-
-2. They repel one another, if one approaches and the other recedes from
-the apex of the angle.
-
-
-166   STANDARD ELECTRICAL DICTIONARY
-
-
-Currents, Earth.
-In long telegraph lines having terminal grounds or connected to earth
-only at their ends, potential differences are sometimes observed that
-are sufficient to interfere with their working and which, of course, can
-produce currents. These are termed earth-currents. It will be noted that
-they exist in the wire, not in the earth. They may be of 40 milliamperes
-strength, quite enough to work a telegraph line without any battery.
-Lines running N. E. and S. W. are most affected; those running N.W. and
-S. E. very much less so. These currents only exist in lines grounded at
-both ends, and appear in underground wires. Hence they are not
-attributable to atmospheric electricity. According to Wilde they are the
-primary cause of magnetic storms, q. v., but not of the periodical
-changes in the magnetic elements. (See Magnetic Elements.)
-
-Synonym--Natural Currents.
-
-
-Current, Secondary.
-(a) A current induced in one conductor by a variation in the current in
-a neighboring one; the current produced in the secondary circuit of an
-induction coil or alternating current converter.
-
-(b) The current given by a secondary battery. This terminology is not to
-be recommended.
-
-
-Current, Secretion.
-In electro-therapeutics, a current due to stimulation of the secretory
-nerves.
-
-
-Current Sheet.
-(a) If two terminals of an active circuit are connected to two points of
-a thin metallic plate the current spreads over or occupies practically a
-considerable area of such plate, and this portion of the current is a
-current sheet.
-
-The general contour of the current sheet can be laid out in lines of
-flux. Such lines resemble lines of force. Like the latter, they are
-purely an assumption, as the current is not in any sense composed  of
-lines.
-
-(b) A condition of current theoretically brought about by the Amp�rian
-currents in a magnet. Each molecule having its own current, the
-contiguous portions of the molecules counteract each other and give a
-resultant zero current. All that remains is the outer sheet of electric
-current that surrounds the whole.
-
-
-Current, Sinuous.
-A current passing through a sinuous conductor.
-
-
-Currents, Multiphase.
-A term applied to groups of currents of alternating type which
-constantly differ from each other by a constant proportion of periods of
-alternation. They are produced on a single dynamo, the winding being so
-contrived that two, three or more currents differing a constant amount
-in phase are collected from corresponding contact rings. There are
-virtually as many windings on the armature as there are currents to be
-produced. Separate conductors for the currents must be used throughout.
-
-Synonyms--Polyphase Currents--Rotatory Currents.
-
-
-167  STANDARD ELECTRICAL DICTIONARY.
-
-
-Currents of Motion.
-In electro-therapeutics, the currents produced in living muscle or
-nerves after sudden contraction or relaxation.
-
-
-Currents of Rest.
-In electro-therapeutics, the currents traversing muscular or nervous
-tissue when at rest. Their existence is disputed.
-
-
-Currents, Orders of.
-An intermittent current passing through a conductor will induce
-secondary alternating currents in a closed circuit near it. This
-secondary current will induce a tertiary current in a third closed
-circuit near it, and so on. The induced currents are termed as of the
-first, second, third and other orders. The experiment is carried out by
-Henry's coils. (See Coils, Henry's.)
-
-
-Currents, Thermo-electric.
-These currents, as produced from existing thermo-electric batteries,
-are generated by low potential, and are of great constancy. The opposite
-junctions of the plates can be kept at constant temperatures, as by
-melting ice and condensing steam, so that an identical current can be
-reproduced at will from a thermopile.
-
-Thermo-electric currents were used by Ohm in establishing his law. (See
-Ohm's Law.)
-
-
-Current, Swelling.
-In electro-therapeutics, a current gradually increasing in strength.
-
-
-Current, Undulatory.
-A current varying in strength without any abrupt transition from action
-to inaction, as in the make and break current. The current may be
-continually changing in direction (see Current, Alternating), and hence,
-of necessity, may pass through stages of zero intensity, but such
-transition must be by a graduation, not by an abrupt transition. Such
-current may be represented by a curve, such as the curve of sines. It is
-evident that the current may pass through the zero point as it crosses
-the line or changes direction without being a make and break current.
-When such a current does alternate in direction it is sometimes called a
-"shuttle current." The ordinary commercial telephone current and the
-alternating current is of this type. (See Current, Make and Break.)
-
-
-Current, Unit.
-Unit current is one which in a wire of unit length, bent so as to form
-an arc of a circle of unit length of radius, would act upon a unit pole
-(see Magnetic Pole, Unit,) at the center of the circle with unit force.
-Unit length is the centimeter; unit force is the dyne.
-
-[Transcriber's note: The SI definition of an ampere: A current in two
-straight parallel conductors of infinite length and negligible
-cross-section, 1 metre apart in vacuum, would produce a force equal to
-2E-7 newton per metre of length.]
-
-
-168   STANDARD ELECTRICAL DICTIONARY.
-
-
-Current, Wattless.
-Whenever there is a great difference in phase in an alternating current
-dynamo between volts and current, the true watts are much less than the
-product of the virtual volts and amperes, because the the watts are
-obtained by multiplying the product of the virtual volts and amperes by
-the cosine of the angle of lag (or lead). Any alternating current may be
-resolved into two components in quadrature with each other, one in phase
-with the volts, the other in quadrature therewith, the former is termed
-by S. P. Thompson the Working Current, the latter the Wattless Current.
-The greater the angle of lag the greater will be the wattless current.
-
-
-Curve, Arrival.
-A curve representing the rate of rise of intensity of current at the end
-of a long conductor when the circuit has been closed at the other end.
-In the Atlantic cable, for instance, it would require about 108 seconds
-for the current at the distant end to attain 9/10 of its full value. The
-curve is drawn with its abscissa representing time and its ordinates
-current strength.
-
-
-Curve, Characteristic.
-A curve indicating, graphically, the relations between any two factors,
-which are interdependent, or which vary simultaneously. Thus in a
-dynamo, the voltage increases with the speed of rotation, and a
-characteristic curve may be based on the relations between the speed of
-rotation and voltage developed. The current produced by a dynamo varies
-with the electro-motive force, and a curve can express the relations
-between the electro-motive force and the current produced.
-
-A characteristic curve is usually laid out by rectangular co-ordinates
-(see Co-ordinates). Two lines are drawn at right angles to each other,
-one vertical, and the other horizontal. One set of data are marked off
-on the horizontal line, say one ampere, two amperes, and so on, in the
-case of a dynamo's characteristic curve.
-
-For each amperage of current there is a corresponding voltage in the
-circuit. Therefore on each ampere mark a vertical is erected, and on
-that the voltage corresponding to such amperage is laid off. This gives
-a series of points, and these points may be connected by a curve. Such
-curve will be a characteristic curve.
-
-The more usual way of laying out a curve is to work directly upon the
-two axes. On one is laid off the series of values of one set of data; on
-the other the corresponding series of values of the other dependent
-data. Vertical lines or ordinates, q. v., are erected on the horizontal
-line or axis of abscissas at the points laid off; horizontal lines or
-abscissas, q. v., are drawn from the points laid off on the vertical
-line or axis of ordinates. The characteristic curve is determined by the
-intersections of each corresponding pair of abscissa and ordinate.
-
-
-169  STANDARD ELECTRICAL DICTIONARY.
-
-
-Variations exist in characteristic curve methods. Thus to get the
-characteristic of a commutator, radial lines may be drawn from a circle
-representing its perimeter. Such lines may be of length proportional to
-the voltage developed on the commutator at the points whence the lines
-start. A cut giving an example of such a curve is given in Fig. 125.
-(See Curve of Distribution of Potential in Armature.)
-
-There is nothing absolute in the use of ordinates or abscissas. They may
-be interchanged. Ordinarily voltages are laid off as ordinates, but the
-practise may be reversed. The same liberty holds good for all
-characteristic curves. Custom, however, should be followed.
-
-Synonym--Characteristic.
-
-
-Fig. 120. CHARACTERISTIC CURVE OF A DYNAMO WITH HORSE POWER CURVES.
-
-
-Curve, Characteristic, of Converter.
-The characteristic curve of the secondary circuit of an alternating
-current converter. It gives by the usual methods (see Curve,
-Characteristic,) the relations between the electro-motive force and the
-current in the secondary circuit at a fixed resistance. If connected in
-parallel a constant electro-motive force is maintained, and the curve is
-virtually a straight line. If connected in series an elliptical curve is
-produced.
-
-
-170   STANDARD ELECTRICAL DICTIONARY.
-
-
-Curve, Charging.
-In secondary battery manipulation, a curve indicating the increase of
-voltage as the charging is prolonged. The rise in voltage with the
-duration of the charging current is not uniform. In one case, shown in
-the cut, there was a brief rapid rise of about 0.1 volt; then a long
-slow rise for 0.15 volt; then a more rapid rise for nearly 0.40 volt,
-and then the curve became a horizontal line indicating a cessation of
-increase of voltage. The charging rate should be constant.
-
-The horizontal line is laid off in hours, the vertical in volts, so that
-the time is represented by abscissas and the voltage by ordinates of the
-curve.
-
-
-Fig. 121. CHARGING CURVE OF A SECONDARY BATTERY.
-
-
-Curve, Discharging.
-A characteristic curve of a storage battery, indicating the fall in
-voltage with hours of discharge. The volts may be laid off on the axis
-of ordinates, and the hours of discharging on the axis of abscissas. To
-give it meaning the rate of discharge must be constant.
-
-
-Curve, Electro-motive Force.
-A characteristic curve of a dynamo. It expresses the relation between
-its entire electromotive force, as calculated by Ohm's Law, and the
-current intensities corresponding thereto. To obtain the data the dynamo
-is driven with different resistances in the external circuit and the
-current is measured for each resistance. This gives the amperes. The
-total resistance of the circuit, including that of the dynamo, is known.
-By Ohm's Law the electro-motive force in volts is obtained for each case
-by multiplying the total resistance of the circuit in ohms by the
-amperes of current forced through such resistance. Taking the voltages
-thus calculated for ordinates and the corresponding amperages for
-abscissas the curve is plotted. An example is shown in the cut.
-
-
-171  STANDARD ELECTRICAL DICTIONARY.
-
-
-Curve, External Characteristic.
-A characteristic curve of a dynamo, corresponding to the electro-motive
-force curve, except that the ordinates represent the voltages of the
-external circuit, the voltages as taken directly from the terminals of
-the machine, instead of the total electro-motive force of the circuit.
-The dynamo is run at constant speed. The resistance of the external
-circuit is varied. The voltages at the terminals of the machine and the
-amperages of current corresponding thereto are determined. Using the
-voltages thus determined as ordinates and the corresponding amperages as
-abscissas the external characteristic curve is plotted.
-
-This curve can be mechanically produced. A pencil may be moved against a
-constant force by two electro-magnets pulling at right angles to each
-other. One must be excited by the main current of the machine, the other
-by a shunt current from the terminals of the machine. The point of the
-pencil will describe the curve.
-
-
-Fig. 122. CHARACTERISTIC CURVE OF A DYNAMO.
-
-
-Curve, Horse Power.
-Curves indicating electric horse power. They are laid out with
-co-ordinates, volts being laid off on the axis of ordinates, and amperes
-on the axis of abscissas generally. The curves are drawn through points
-where the product of amperes by volts equals 746. On the same diagram 1,
-2, 3 .... and any other horse powers can be plotted if within the
-limits. See Fig. 120.
-
-
-Curve, Isochasmen.
-A line drawn on the map of the earth's surface indicating the locus of
-equal frequency of auroras.
-
-
-172   STANDARD ELECTRICAL DICTIONARY.
-
-
-Curve, Life.
-A characteristic curve showing the relations between the durability and
-conditions affecting the same in any appliance. It is used most for
-incandescent lamps. The hours of burning before failure give ordinates,
-and the rates of burning, expressed indirectly in volts or in
-candle-power, give abscissas. For each voltage or for each candle-power
-an average duration is deducible from experience, so that two dependent
-sets of data are obtained for the construction of the curve.
-
-
-Curve, Load.
-A characteristic curve of a dynamo, expressing the relation between its
-voltage and the amount of excitation under a definite condition of
-ampere load, at a constant speed. The ordinates represent voltage, the
-abscissas ampere turns in the field, and the curves may be constructed
-for a flow of 0, 50, 100, or .. , or any other number of amperes.
-
-
-Fig. 123. LOAD CURVES.
-
-
-Curve, Magnetization.
-A characteristic curve of an electromagnet, indicating the relation of
-magnetization to exciting current. Laying off on the axis of ordinates
-the quantities of magnetism evoked, and the corresponding strengths of
-the exciting current on the axis of abscissas, the curve can be plotted.
-It first rises rapidly, indicating a rapid increase of magnetization,
-but grows nearly horizontal as the iron becomes more saturated. The
-effect due to the coils alone, or the effect produced in the absence of
-iron is a straight line, because air does not change in permeability.
-
-
-Curve of Distribution of Potential in Armature.
-A characteristic curve indicating the distribution of potential
-difference between adjoining sections of the commutator of an armature
-in different positions all around it. The potential differences are
-taken by a volt-meter or potential galvanometer, connection with the
-armature being made by two small metal brushes, held at a distance apart
-equal to the distance from centre to centre of two adjoining commutator
-bars. The curve is laid out as if by polar co-ordinates extending around
-the cross-section of the commutator, with the distances from the
-commutator surface to the curve proportional to the potential
-differences as determined by shifting the pair of brushes all around the
-commutator.
-
-The above is S. P. Thompson's method. Another method of W. M. Mordey
-involves the use of a pilot brush. (See Brush, Pilot.) Otherwise the
-method is in general terms identical with the above.
-
-
-173  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 124. MAGNETIZATION CURVE.
-
-
-Fig. 125. ARMATURE: CURVE.
-
-
-Fig. 126. DEVELOPMENT OF ARMATURE CURVE.
-
-
-Curve of Dynamo.
-The characteristic curve of a dynamo. (See Curve, Characteristic.)
-
-
-Curve of Sines.
-An undulating curve representing wave motion. It is produced by
-compounding a simple harmonic motion, or a two and fro motion like that
-of an infinitely long pendulum with a rectilinear motion. Along a
-horizontal line points may be laid off to represent equal periods of
-time. Then on each point a perpendicular must be erected. The length of
-each must be equal to the length of path traversed by the point up to
-the expiration of each one of the given intervals of time. The abscissas
-are proportional to the times and the ordinates to the sines of angles
-proportional to the times. Thus if a circle be drawn upon the line and
-divided into thirty-two parts of equal angular value, the sines of these
-angles may be taken as the ordinates and the absolute distance or length
-of arc of the angle will give the abscissas.
-
-Synonyms--Sine Curve--Sinusoidal Curve--Harmonic Curve.
-
-
-Fig. 127. CURVE OF SINES.
-
-
-174   STANDARD ELECTRICAL DICTIONARY.
-
-
-Curve of Saturation of the Magnetic Circuit.
-A characteristic curve whose ordinates may represent the number of
-magnetic lines of force induced in a magnetic circuit, and whose
-abscissas may represent the ampere turns of excitation or other
-representative of the inducing force.
-
-Curve of Torque.
-A characteristic curve showing the relations between torque, q. v., and
-current in a dynamo or motor.
-
-
-Curve, Permeability Temperature.
-A characteristic curve expressing the changes in permeability of a
-paramagnetic substance as the temperature changes. The degrees of
-temperature may be abscissas, and the permeabilities corresponding
-thereto ordinates of the curve.
-
-
-Cut In. v.
-To connect any electric appliance, mechanism or conductor, into a
-circuit.
-
-
-Cut Out. v.
-The reverse of to cut in; to remove from a circuit any conducting
-device, and sometimes so arranged as to leave the circuit completed in
-some other way.
-
-
-Cut Out.
-An appliance for removing any apparatus from an electric circuit, so
-that no more current shall pass through such apparatus, and sometimes
-providing means for closing the circuit so as to leave it complete after
-the removal of the apparatus.
-
-
-175    STANDARD ELECTRICAL DICTIONARY.
-
-
-Cut Out, Automatic.
-(a) A mechanism for automatically shunting an arc or other lamp when it
-ceases to work properly. It is generally worked by an electro-magnet of
-high resistance placed in parallel with the arc. If the arc grows too
-long the magnet attracts its armature, thereby completing a shunt of
-approximately the resistance of the arc, and which replaces it until the
-carbons approach again to within a proper distance. Sometimes a strip or
-wire of fusible metal is arranged in shunt with the arc. When the arc
-lengthens the current through the wire increases, melts it and a spring
-is released which acts to complete or close a shunt circuit of
-approximately arc-resistance.
-
-(b) See Safety Device--Safety Fuse.
-
-(c) See below.
-
-
-Cut-out, Magnetic.
-A magnetic cut-out is essentially a coil of wire with attracted core or
-armature. When the coil is not excited the core, by pressing down a
-strip of metal or by some analogous arrangement, completes the circuit.
-When the current exceeds a certain strength the core rises as it is
-attracted and the circuit is opened.
-
-
-Cut-out, Safety.
-A block of porcelain or other base carrying a safety fuse, which melts
-and breaks the circuit before the wire connected to it is dangerously
-heated.
-
-Synonyms--Fuse Block--Safety Catch--Safety Fuse.
-
-
-Cut Out, Wedge.
-A cut out operated by a wedge. The line terminals consist of a spring
-bearing against a plate, the circuit being completed through their point
-of contact. A plug or wedge composed of two metallic faces insulated
-from each other is adapted to wedge the contact open. Terminals of a
-loop circuit are connected to the faces of the wedge. Thus on sliding it
-into place, the loop circuit is brought into series in the main circuit.
-
-Synonym--Plug Cut Out--Spring Jack.
-
-
-Cutting of Lines of Force.
-A field of force is pictured as made up of lines of force; a conductor
-swept through the field is pictured as cutting these lines. By so doing
-it produces potential difference or electro-motive force in itself with
-a current, if the conductor is part of a closed circuit.
-
-
-Cycle of Alternation.
-A full period of alternation of an alternating current. It begins
-properly at the zero line, goes to a maximum value in one sense and
-returns to zero, goes to maximum in the other sense and returns to zero.
-
-
-Cystoscopy.
-Examination of the human bladder by the introduction of a special
-incandescent electric lamp. The method is due to Hitze.
-
-
-176   STANDARD ELECTRICAL DICTIONARY.
-
-
-Damper.
-(a) A copper frame on which the wire in a galvanometer is sometimes
-coiled, which acts to damp the oscillations of the needle.
-
-(b) A tube of brass or copper placed between the primary and secondary
-coils of an induction coil. It cuts off induction and diminishes the
-current and potential of the secondary circuit. On pulling it out, the
-latter increases. It is used on medical coils to adjust their strength
-of action.
-
-
-Damping.
-Preventing the indicator of an instrument from oscillating in virtue of
-its own inertia or elasticity. In a galvanometer it is defined as
-resistance to quick vibrations of the needle, in consequence of which it
-is rapidly brought to rest when deflected (Ayrton). In dead-beat
-galvanometers (see Galvanometer, Dead-Beat,) damping is desirable in
-order to bring the needle to rest quickly; in ballistic galvanometers
-(see Galvanometer, Ballistic,) damping is avoided in order to maintain
-the principle of the instrument. Damping may be mechanical, the
-frictional resistance of air to an air-vane, or of a liquid to an
-immersed diaphragm or loosely fitting piston, being employed. A
-dash-pot, q. v., is an example of the latter. It may be
-electro-magnetic. A mass of metal near a swinging magnetic needle tends
-by induced currents to arrest the oscillations thereof, and is used for
-this purpose in dead-beat galvanometers. This is termed, sometimes,
-magnetic friction. The essence of damping is to develop resistance to
-movement in some ratio proportional to velocity, so that no resistance
-is offered to the indicator slowly taking its true position. (See
-Galvanometer, Dead-Beat.)
-
-
-Dash-Pot.
-A cylinder and piston, the latter loosely fitting or perforated, or some
-equivalent means being provided to permit movement. The cylinder may
-contain a liquid such as glycerine, or air only. Thus the piston is
-perfectly free to move, but any oscillations are damped (see Damping).
-In some arc lamps the carbon holder is connected to a dash-pot to check
-too sudden movements of the carbon. The attachment may be either to the
-piston or to the cylinder. In the Brush lamp the top of the carbon
-holder forms a cylinder containing glycerine, and in it a loosely
-fitting piston works. This acts as a dash-pot.
-
-
-Dead Beat. adj.
-Reaching its reading quickly; applied to instruments having a moving
-indicator, which normally would oscillate back and forth a number of
-times before reaching its reading were it not prevented by damping. (See
-Galvanometer, Aperiodic--Damping.)
-
-
-Dead Earth.
-A fault in a telegraph line which consists in the wire being thoroughly
-grounded or connected to the earth.
-
-
-177  STANDARD ELECTRICAL DICTIONARY.
-
-
-Dead Point of an Alternator.
-A two-phase alternator of the ordinary type connected as a motor to
-another alternator cannot start itself, as it has dead points where the
-relations and polarity of field and armature are such that there is no
-torque or turning power.
-
-
-Dead-Turns.
-In the winding of an armature, a given percentage of the turns, it may
-be 80 per cent., more or less, is assumed to be active; the other 20 per
-cent. or thereabouts, is called dead-turns. This portion represents the
-wire on such portions of the armature as comes virtually outside of the
-magnetic field. They are termed dead, as not concurring to the
-production of electro-motive force.
-
-
-Dead Wire.
-(a) The percentage or portion of wire on a dynamo or motor armature that
-does not concur in the production of electromotive force. The
-dead-turns, q. v., of a drum armature or the inside wire in a Gramme
-ring armature are dead wire.
-
-(b) A disused and abandoned electric conductor, such as a telegraph
-wire.
-
-(c) A wire in use, but through which, at the time of speaking, no
-current is passing.
-
-
-Death, Electrical.
-Death resulting from electricity discharged through the animal system.
-The exact conditions requisite for fatal results have not been
-determined. High electro-motive force is absolutely essential; a
-changing current, pulsatory or alternating, is most fatal, possibly
-because of the high electro-motive force of a portion of each period.
-Amperage probably has something to do with it, although the total
-quantity in coulombs may be very small. As applied to the execution of
-criminals, the victim is seated in a chair and strapped thereto. One
-electrode with wet padded surface is placed against his head or some
-adjacent part. Another electrode is placed against some of the lower
-parts, and a current from an alternating dynamo passed for 15 seconds or
-more. The potential difference of the electrodes is given at 1,500 to
-2,000 volts, but of course the maximum may be two or three times the
-measured amount, owing to the character of the current.
-
-
-Decalescence.
-The converse of recalescence, q. v. When a mass of steel is being heated
-as it reaches the temperature of recalescence it suddenly absorbs a
-large amount of heat, apparently growing cooler.
-
-
-Deci.
-Prefix originally used in the metric system to signify one-tenth of, now
-extended to general scientific units. Thus decimeter means one-tenth of
-a meter; decigram, one-tenth of a gram.
-
-
-Declination, Angle of.
-The angle intercepted between the true meridian and the axis of a
-magnetic needle at any place. The angle is measured to east or west,
-starting from the true meridian as zero.
-
-
-178   STANDARD ELECTRICAL DICTIONARY.
-
-
-Declination of the Magnetic Needle.
-The deviation of the magnetic needle from the plane of the earth's
-meridian. It is also called the variation of the compass. (See Magnetic
-Elements.)
-
-
-Decomposition.
-The reduction of a compound substance into its constituents, as in
-chemical analysis. The constituents may themselves be compounds or
-proximate constituents, or may be elemental or ultimate constituents.
-
-
-Decomposition, Electrolytic.
-The decomposition or separation of a compound liquid into its
-constituents by electrolysis. The liquid must be an electrolyte, q. v.,
-and the decomposition proceeds subject to the laws of electrolysis, q.
-v. See also Electrolytic Analysis.
-
-
-Decrement.
-When a suspension needle which has been disturbed is oscillating the
-swings gradually decrease in amplitude if there is any damping, as there
-always is. The decrement is the ratio of the amplitude of one
-oscillation to the succeeding one. This ratio is the same for any
-successive swings.
-
-
-De-energize.
-To cut off its supply of electric energy from an electric motor, or any
-device absorbing and worked by electric energy.
-
-
-Deflagration.
-The explosive or violent volatilizing and dissipating of a substance by
-heat, violent oxidation and similar means. It may be applied among other
-things to the destroying of a conductor by an intense current, or the
-volatilization of any material by the electric arc.
-
-
-Deflecting Field.
-The field produced in a galvanometer by the current which is being
-tested, and which field deflects the needle, such deflection being the
-measure of the current strength.
-
-
-Deflection.
-In magnetism the movement out of the plane of the magnetic meridian of a
-magnetic needle, due to disturbance by or attraction towards a mass of
-iron or another magnet.
-
-
-Deflection Method.
-The method of electrical measurements in which the deflection of the
-index of the measuring instrument is used as the measure of the current
-or other element under examination. It is the opposite of and is to be
-distinguished from the zero or null method, q. v. In the latter
-conditions are established which make the index point to zero and from
-the conditions necessary for this the measurement is deduced. The
-Wheatstone Bridge, q. v., illustrates a zero method, the sine or the
-tangent compass, illustrates a deflection method. The use of deflection
-methods involves calibration, q. v., and the commercial measuring
-instruments, such as ammeters and volt meters, which are frequently
-calibrated galvanometers, are also examples of deflection instruments.
-
-
-179  STANDARD ELECTRICAL DICTIONARY.
-
-
-Degeneration, Reaction of.
-The diminished sensibility to electro-therapeutic treatment exhibited by
-the human system with continuance of the treatment in question. The
-general lines of variation are stated in works on the subject.
-
-
-Deka.
-Prefix originally used in the metric system to signify multiplying by
-ten, as dekameter, ten meters, dekagram, ten grams; now extended to many
-scientific terms.
-
-
-De la Rive's Floating Battery.
-A small galvanic couple, immersed in a little floating cell and
-connected through a coil of wire immediately above them. When the
-exciting battery solution is placed in the cell the whole, as it floats
-in a larger vessel, turns until the coil lies at right angles to the
-magnetic needle. Sometimes the two plates are thrust through a cork and
-floated thus in a vessel of dilute sulphuric acid.
-
-A magnet acts to attract or repel the coil in obedience to Amp�re's
-Theory, (See Magnetism, Ampere's Theory of.)
-
-
-Delaurier's Solution.
-A solution for batteries of the Bunsen and Grenet type. It is of the
-following composition:
-  Water,                2,000 parts;
-  potassium bichromate,   184 parts;
-  sulphuric acid,         428 parts.
-
-
-Demagnetization.
-Removal of magnetism from a paramagnetic substance. It is principally
-used for watches which have become magnetized by exposure to the
-magnetic field surrounding dynamos or motors.
-
-The general principles of most methods are to rotate the object, as a
-watch, in a strong field, and while it is rotating to gradually remove
-it from the field, or to gradually reduce the intensity of the field
-itself to zero. A conical coil of wire within which the field is
-produced in which the watch is placed is sometimes used, the idea being
-that the field within such a coil is strongest at its base. Such a coil
-supplied by an alternating current is found effectual (J. J. Wright).
-
-If a magnetized watch is made to turn rapidly at the end of a twisted
-string and is gradually brought near to and withdrawn from the poles of
-a powerful dynamo it may be considerably improved.
-
-A hollow coil of wire connected with a pole changer and dip-battery has
-been used. The battery creates a strong field within the coil. The watch
-is placed there and the pole changer is worked so as to reverse the
-polarity of the field very frequently. By the same action of the pole
-changer the plates of the battery are gradually withdrawn from the
-solution so as to gradually reduce the magnetic field to zero while
-constantly reversing its polarity. (G. M. Hopkins.)
-
-Steel may be demagnetized by jarring when held out of the magnetic
-meridian, or by heating to redness.
-
-
-180   STANDARD ELECTRICAL DICTIONARY.
-
-
-Density, Electric Superficial.
-The relative quantity of electricity residing as an electric charge upon
-a unit area of surface. It may be positive or negative.
-
-Synonyms--Density of Charge--Surface Density.
-
-
-Dental Mallet, Electric.
-A dentist's instrument for hammering the fillings as inserted into
-teeth. It is a little hammer held in a suitable handle, and which is
-made to strike a rapid succession of blows by electro-magnetic motor
-mechanism.
-
-
-Depolarization.
-(a) The removal of permanent magnetism. (See Demagnetization.)
-
-(b) The prevention of the polarization of a galvanic cell. It is
-effected in the Grove battery by the reduction of nitric acid; in the
-Bunsen, by the reduction of chromic acid; in the Smee battery,
-mechanically, by the platinum coated or rather platinized negative
-plate. Other examples will be found under the description of various
-cells and batteries. A fluid which depolarizes is termed a depolarizer
-or depolarizing fluid or solution. (See Electropoion Fluid.)
-
-
-Deposit, Electrolytic.
-The metal or other substance precipitated by the action of a battery or
-other current generator.
-
-
-Derivation, Point of.
-A point where a circuit branches or divides into two or more leads. The
-separate branches then receive derived or partial currents.
-
-
-Desk Push.
-A press or push button, with small flush rim, for setting into the
-woodwork of a desk.
-
-
-Detector.
-A portable galvanometer, often of simple construction, used for rough or
-approximate work.
-
-
-Detector, Lineman's.
-A portable galvanometer with a high and a low resistance actuating coil,
-constructed for the use of linemen and telegraph constructors when in
-the field, and actually putting up, repairing or testing lines.
-
-
-Deviation, Quadrantal.
-Deviation of the compass in iron or steel ships due to the magnetization
-of horizontal beams by the earth's induction. The effect of this
-deviation disappears when the ship is in the plane of the electric
-meridian, or at right angles thereto; its name is taken from the fact
-that a swing of the ship through a quadrant brings the needle from zero
-deviation to a maximum and back to zero.
-
-
-181  STANDARD ELECTRICAL DICTIONARY.
-
-
-Deviation, Semicircular.
-Deviation of the compass in iron or steel ships due to vertical
-induction. (See Induction, Vertical.) The effect of this induction
-disappears when the ship is in the electric meridian. Its name is
-derived from the fact that a swing of the ship through half the circle
-brings the needle from zero deviation to a maximum and back to zero.
-
-
-Dextrotorsal. adj.
-Wound in the direction or sense of a right-handed screw; the reverse of
-sinistrotorsal, q. v.
-
-
-Fig. 128. DEXTROTORSAL HELIX.
-
-
-Diacritical. adj.
-(a) The number of ampere turns, q. v., required to bring an iron core to
-one half its magnetic saturation, q. v., is termed the diacritical
-number.
-
-(b) The diacritical point of magnetic saturation is proposed by Sylvanus
-P. Thompson as a term for the coefficient of magnetic saturation which
-gives a magnet core one-half its maximum magnetization.
-
-
-Diagnosis, Electro.
-A medical diagnosis of a patient's condition based on the action of
-different parts of the body under electric excitement.
-
-
-Diamagnetic. adj.
-Possessing a negative coefficient of magnetic susceptibility; having
-permeability inferior to that of air. Such substances placed between the
-poles of a magnet are repelled; if in the form of bars, they tend to
-turn so as to have their long axis at right angles to the line joining
-the poles. The reason is that the lines of force always seek the easiest
-path, and these bodies having higher reluctance than air, impede the
-lines of force, and hence are as far as possible pushed out of the way.
-The above is the simplest explanation of a not well understood set of
-phenomena. According to Tyndall, "the diamagnetic force is a polar
-force, the polarity of diamagnetic bodies being opposed to that of
-paramagnetic ones under the same conditions of excitement." Bismuth is
-the most strongly diamagnetic body known; phosphorus, antimony, zinc,
-and many others are diamagnetic. (See Paramagnetic.)
-
-
-182   STANDARD ELECTRICAL DICTIONARY.
-
-
-Diagometer.
-An apparatus for use in chemical analysis for testing the purity of
-substances by the time required for a charged surface to be discharged
-through them to earth. It is the invention of Rousseau.
-
-An electrometer is charged with a dry pile. One of its terminals is
-connected with one surface of the solution or substance to be tested,
-and the other with the other surface. The time of discharge gives the
-index of the purity of the substance.
-
-
-Diamagnetic Polarity.
-Treating diamagnetism as due to a polar force, the polarity of a
-diamagnetic body is the reverse of the polarity of iron or other
-paramagnetic bodies. A bar-shaped diamagnetic body in a field of force
-tends to place itself at right angles to the lines of force.
-
-
-Diamagnetism.
-(a) The science or study of diamagnetic substances and phenomena.
-
-(b) The magnetic property of a diamagnetic substance.
-
-
-Diameter of Commutation.
-The points on the commutator of a closed circuit ring--or
-drum--armature, which the brushes touch, and whence they take the
-current, mark the extremities of the diameter of commutation. Were it
-not for the lag this would be the diameter at right angles to the line
-connecting the centers of the opposite faces of the field. It is always
-a little to one side of this position, being displaced in the direction
-of rotation. In open circuit armatures the brushes are placed on the
-diameter at right angles to this one, and sometimes the term diameter of
-commutation is applied to it. All that has been said is on the
-supposition that the armature divisions correspond not only in
-connection but in position with those of the armature coils. Of course,
-the commutator could be twisted so as to bring the diameter of
-commutation into any position desired.
-
-
-Diapason, Electric.
-A tuning-fork or diapason kept in vibration by electricity. In general
-principle the ends of the fork act as armatures for an electro-magnet,
-and in their motion by a mercury cup or other form of contact they make
-and break the circuit as they vibrate. Thus the magnet alternately
-attracts and releases the leg, in exact harmony with its natural period
-of vibration.
-
-
-Diaphragm.
-(a) In telephones and microphones a disc of iron thrown into motion by
-sound waves or by electric impulses, according to whether it acts as the
-diaphragm of a transmitter or receiver. It is generally a plate of
-japanned iron such as used in making ferrotype photographs. (See
-Telephone and Microphone.)
-
-(b) A porous diaphragm is often used in electric decomposition cells and
-in batteries. The porous cup represents the latter use.
-
-[Transcriber's note: Japanned--covered with heavy black lacquer, like
-enamel paint.]
-
-
-183  STANDARD ELECTRICAL DICTIONARY.
-
-
-Dielectric.
-A non-conductor; a substance, the different parts of which may, after an
-electric disturbance, remain, without any process of readjustment, and
-for an indefinite period of time, at potentials differing to any extent
-(Daniell). There is no perfect dielectric. The term dielectric is
-generally only used when an insulator acts to permit induction to take
-place through it, like the glass of a Leyden jar.
-
-
-Dielectric Constant.
-The number or coefficient expressing the relative dielectric capacity of
-a medium or substance. (See Capacity, Specific Inductive.)
-
-
-Dielectric, Energy of.
-In a condenser, the conducting coatings are merely to conduct the
-current all over the surface they cover; the keeping the electricities
-separated is the work of the dielectric, and represents potential energy
-which appears in the discharge. The amount of energy is proportional to
-the charge, and to the potential difference. As any electrified body
-implies an opposite electrification somewhere, and a separating
-dielectric, the existence of a condenser is always implied.
-
-[Transcriber's note: The energy stored in a capacitor (condenser) is
-(Q*Q)/2C = (Q*V)/2 = (C*V*V)/2
-The energy is proportional to the voltage SQUARED or the charge SQUARED.]
-
-
-Dielectric Polarization.
-A term due to Faraday. It expresses what he conceived to be the
-condition of a dielectric when its opposite faces are oppositely
-electrified. The molecules are supposed to be arranged by the
-electrification in a series of polar chains, possibly being originally
-in themselves seats of opposite polarities, or having such imparted to
-them by the electricities. The action is analogous to that of a magnet
-pole on a mass of soft iron, or on a pile of iron filings.
-
-
-Dielectric Strain.
-The strain a solid dielectric is subjected to, when its opposite
-surfaces are electrified. A Leyden jar dilates under the strain, and
-when discharged gives a dull sound. The original condition is not
-immediately recovered. Jarring, shaking, etc., assist the recovery from
-strain. The cause of the strain is termed Electric Stress. (See Stress,
-Electric.) This is identical with the phenomenon of residual charge.
-(See Charge, Residual.) Each loss of charge is accompanied with a
-proportional return of the dielectric towards its normal condition.
-
-
-Dielectric Resistance.
-The mechanical resistance a body offers to perforation or destruction by
-the electric discharge.
-
-
-Dielectric Strength.
-The resistance to the disruptive discharge and depending on its
-mechanical resistance largely or entirely. It is expressible in volts
-per centimeter thickness. Dry air requires 40,000 volts per centimeter
-for a discharge.
-
-
-184   STANDARD ELECTRICAL DICTIONARY.
-
-
-Differential Winding Working.
-A method of working an electro-magnet intermittently, so as to avoid
-sparking. The magnet is wound with two coils. One is connected straight
-into the circuit, the other is connected in parallel therewith with a
-switch inserted. The coils are so connected that when the switch is
-closed the two are in opposition, the current going through them in
-opposite senses. Thus one overcomes the effect of the other and the
-magnet core shows no magnetism, provided the two coils are of equal
-resistance and equal number of convolutions or turns.
-
-
-Fig. 129. DIFFERENTIAL WINDING WORKING OF ELECTRO-MAGNETIC APPARATUS.
-
-
-Diffusion.
-A term properly applied to the varying current density found in
-conductors of unequal cross sectional area. In electro-therapeutics it
-is applied to the distribution of current as it passes through the human
-body. Its density per cross-sectional area varies with the area and
-with the other factors.
-
-
-Diffusion Creep.
-When electrodes of an active circuit are immersed in a solution of an
-electrolyte, a current passes electrolytically if there is a sufficient
-potential difference. The current passes through all parts of the
-solution, spreading out of the direct prism connecting or defined by the
-electrodes. To this portion of the current the above term is applied. If
-the electrodes are small enough in proportion to the distance between
-them the current transmission or creep outside of the line becomes the
-principal conveyor of the current so that the resistance remains the
-same for all distances.
-
-
-Dimensions and Theory of Dimensions.
-The expression of the unitary value of a physical quantity in one or
-more of the units of length (L), time (T) and mass (M) is termed the
-dimensions of such quantity. Thus the dimension or dimensions of a
-distance is simply L; of an angle, expressible by dividing the arc by
-the radius is L/L; of a velocity, expressible by distance divided by
-time--L/T; of acceleration, which is velocity acquired in a unit of
-time, and is therefore expressible by velocity divided by time--L/T/T or
-L/T2; of momentum, which is the product of mass into velocity--M*L/T; of
-kinetic energy taken as the product of mass into the square of
-velocity--M*(L2/T2); of potential energy taken as the product of mass
-into acceleration into space-M*(L/T2)*L reducing to M*(L2/T2). The
-theory is based on three fundamental units and embraces all electric
-quantities. The simple units generally taken are the gram, centimeter
-and second and the dimensions of the fundamental compound units are
-expressed in terms of these three, forming the centimeter-gram-second or
-C. G. S. system of units. Unless otherwise expressed or implied the
-letters L, M and T, may be taken to indicate centimeter, gram and second
-respectively. It is obvious that very complicated expressions of
-dimensions may be built up, and that a mathematical expression of
-unnamed quantities may be arrived at. Dimensions in their application by
-these symbols are subject to the laws of algebra. They were invented by
-Fourier and were brought into prominence by J. Clerk Maxwell. Another
-excellent definition reads as follows: "By the dimensions of a physical
-quantity we mean the quantities and powers of quantities, involved in
-the measurement of it." (W. T. A. Emtage.)
-
-
-185  STANDARD ELECTRICAL DICTIONARY.
-
-
-Dimmer.
-An adjustable choking coil used for regulating the intensity of electric
-incandescent lights. Some operate by the introduction and withdrawal of
-an iron core as described for the choking coil (see Coil, Choking),
-others by a damper of copper, often a copper ring surrounding the coil
-and which by moving on or off the coil changes the potential of the
-secondary circuit.
-
-
-Dip of Magnetic Needle.
-The inclination of the magnetic needle. (See Elements, Magnetic.)
-
-
-Dipping.
-(a) Acid or other cleaning processes applied by dipping metals in
-cleaning or pickling solutions before plating in the electroplater's
-bath.
-
-(b) Plating by dipping applies to electroplating without a battery by
-simple immersion. Copper is deposited on iron from a solution of copper
-sulphate in this way.
-
-Synonym--Simple Immersion.
-
-
-Dipping Needle.
-A magnet mounted in horizontal bearings at its centre of gravity. Placed
-in the magnetic meridian it takes the direction of the magnetic lines of
-force of the earth at that point. It is acted on by the vertical
-component of the earth's magnetism, as it has no freedom of horizontal
-movement. (See Magnetic Elements, and Compass, Inclination.)
-
-Directing Magnet.
-In a reflecting galvanometer the magnet used for controlling the
-magnetic needle by establishing a field. It is mounted on the spindle of
-the instrument above the coil and needle.
-
-Synonym--Controlling Magnet.
-
-
-186   STANDARD ELECTRICAL DICTIONARY.
-
-
-Direction.
-(a) The direction of an electric current is assumed to be from a
-positively charged electrode or terminal to a negatively charged one in
-the outer circuit. (See Current.)
-
-(b) The direction of magnetic and electro-magnetic lines of force is
-assumed to be from north to south pole of a magnet in the outer circuit.
-It is sometimes called the positive direction. Their general course is
-shown in the cuts diagrammatically. The circles indicate a compass used
-in tracing their course. The magnetic needle tends to place itself in
-the direction of or tangential to the lines of force passing nearest it.
-
-(c) The direction of electrostatic lines of force is assumed to be out
-of a positively charged and to a negatively charged surface.
-
-
-Fig. 130. DIRECTION OF LINES OF FORCE OF A PERMANENT MAGNET.
-
-
-Fig. 131, DIRECTION OF LINES OF FORCE OF AN ELECTRO-MAGNET.
-
-
-187   STANDARD ELECTRICAL DICTIONARY.
-
-
-Directive Power.
-In magnetism the power of maintaining itself in the plane of the
-magnetic meridian, possessed by the magnetic needle.
-
-
-Discharge, Brush.
-The static discharge of electricity into or through the air may be of
-the brush or spark form. The brush indicates the escape of electricity
-in continuous flow; the spark indicates discontinuity. The conditions
-necessary to the production of one or the other refer to the nature of
-the conductor, and of other conductors in its vicinity and to the
-electro-motive force or potential difference; small alterations may
-transform one into the other. The brush resembles a luminous core whose
-apex touches the conductor. It is accompanied by a slight hissing noise.
-Its luminosity is very feeble. The negative conductor gives a smaller
-brush than that of the positive conductor and discharges it more
-readily. When electricity issues from a conductor, remote from an
-oppositely excited one, it gives an absolutely silent discharge, showing
-at the point of escape a pale blue luminosity called electric glow, or
-if it escapes from points it shows a star-like centre of light. It can
-be seen in the dark by placing a point on the excited conductor of a
-static-electric machine.
-
-Synonyms--Silent Discharge--Glow Discharge.
-
-
-Discharge, Conductive.
-A discharge of a static charge by conduction through a conductor.
-
-
-Discharge, Convective.
-The discharge of static electricity from an excited conductor through
-air or rarefied gas; it is also called the quiet or silent discharge.
-The luminous effect in air or gas at atmospheric pressures takes the
-form of a little brush from a small positive electrode; the negative
-shows a star. The phenomena of Gassiot's cascade, the philosopher's egg
-and Geissler tubes, all of which may be referred to, are instances of
-convective discharge.
-
-
-Discharge, Dead Beat.
-A discharge that is not oscillatory in character.
-
-
-Discharge, Disruptive.
-A discharge of a static charge through a dielectric. It involves
-mechanical perforation of the dielectric, and hence the mere mechanical
-strength of the latter has much to do with preventing it. A disruptive
-discharge is often oscillatory in character; this is always the case
-with the discharge of a Leyden jar.
-
-
-188   STANDARD ELECTRICAL DICTIONARY.
-
-
-Discharge, Duration of.
-The problem of determining this factor has been attacked by various
-observers. Wheatstone with his revolving mirror found it to be 1/24000
-second. Fedderson, by interposing resistance, prolonged it to 14/10000
-and again to 138/10000 second. Lucas & Cazin made it from 26 to 47
-millionths of a second. All these experiments were performed with Leyden
-jars.
-
-
-Discharge, Impulsive.
-A disruptive discharge produced between conductors by suddenly produced
-potential differences. The self-induction of the conductor plays an
-especially important part in discharges thus produced.
-
-
-Discharge, Lateral.
-(a) A lightning discharge, which sometimes takes place between a
-lightning rod and the building on which it is.
-
-(b) In the discharge of a Leyden jar or condenser the discharge which
-takes the alternative path, q. v.
-
-
-Discharge, Oscillatory.
-The sudden or disruptive discharge of a static condenser, such as a
-Leyden jar, or of many other charged conductors, is oscillatory in
-character. The direction of the currents rapidly changes, so that the
-discharge is really an alternating current of excessively short total
-duration. The discharge sends electro-magnetic waves through the ether,
-which are exactly analogous to those of light but of too long period to
-affect the eye.
-
-Synonym--Surging Discharge.
-
-[Transcriber's note: Marconi's transmission across the English channel
-occurs in 1897, five years after the publication of this book.]
-
-
-Fig. 132. DISCHARGER.
-
-
-Discharger.
-An apparatus for discharging Leyden jars. It consists of a conductor
-terminating in balls, and either jointed like a tongs or bent with a
-spring-action, so that the balls can be set at distances adapted to
-different sized jars. It has an insulating handle or a pair of such. In
-use one ball is brought near to the coating and the other to the spindle
-ball of the jar. When nearly or quite in contact the jar discharges.
-
-Synonyms--Discharging Rod--Discharging Tongs.
-
-
-189  STANDARD ELECTRICAL DICTIONARY.
-
-
-Discharger, Universal.
-An apparatus for exposing substances to the static discharge spark. It
-consists of a base with three insulating posts. The central post carries
-an ivory table to support the object. The two side posts carry
-conducting rods, terminating in metal balls, and mounted with universal
-joints. A violent shock can be given to any object placed on the table.
-
-Synonym--Henley's Universal Discharger.
-
-
-Discharge, Silent.
-This term is sometimes applied to the glow or brush discharge and
-sometimes to the condition of electric effluvium. (See Discharge,
-Brush--Effluvium, Electric.)
-
-
-Discharge, Spark.
-The discontinuous discharge of high tension electricity through a
-dielectric or into the air produces electric sparks. These are quite
-strongly luminous, of branching sinuous shape, and in long sparks the
-luminosity varies in different parts of the same spark. A sharp noise
-accompanies each spark. High density of charge is requisite for the
-formation of long sparks.
-
-
-Disconnection.
-The separation of two parts of, or opening a circuit, as by turning a
-switch, unscrewing a binding screw, or the like. The term is sometimes
-used to indicate a class of faults in telegraph circuits. Disconnections
-may be total, partial or intermittent, and due to many causes, such as
-open or partially replaced switches, oxidized or dirty contact points,
-or loose joints.
-
-
-Displacement, Electric.
-A conception of the action of charging a dielectric. The charge is all
-on the surface. This fact being granted, the theory of displacement
-holds that charging a body is the displacing of electricity, forcing it
-from the interior on to the surface, or vice versa, producing a positive
-or negative charge by displacement of electricity. While displacement is
-taking place in a dielectric there is assumed to be a movement or
-current of electricity called a displacement current.
-
-
-Disruptive Tension.
-When the surface of a body is electrified, it tends to expand, all
-portions of the surface repelling each other. The film of air
-surrounding such a body is electrified too, and is subjected to a
-disruptive tension, varying in intensity with the square of the density.
-
-
-Dissimulated Electricity.
-The electricity of a bound charge. (See Charge, Bound.)
-
-
-Dissociation.
-The separation of a chemical compound into its elements by a
-sufficiently high degree of heat. All compounds are susceptible of
-dissociation, so that it follows that combustion is impossible at high
-temperatures.
-
-
-190   STANDARD ELECTRICAL DICTIONARY.
-
-
-Distance, Critical, of Alternative Path.
-The length of air gap in an alternative path whose resistance joined to
-the impedance of the rest of the conductors of the path just balances
-the impedance of the other path.
-
-
-Distance, Sparking.
-The distance between electrodes, which a spark from a given Leyden jar
-or other source will pass across.
-
-Synonym--Explosive Distance.
-
-
-Distillation.
-The evaporation of a liquid by heat, and sometimes in a vacuum, followed
-by condensation of the vapors, which distil or drop from the end of the
-condenser. It is claimed that the process is accelerated by the liquid
-being electrified.
-
-
-Distributing Box.
-In an electric conduit system, a small iron box provided for giving
-access to the cable for the purpose of making house and minor
-connections.
-
-Synonym--Hand Hole.
-
-
-Distributing Switches.
-Switch systems for enabling different dynamos to supply different lines
-of a system as required. Spring jacks, q. v., are used for the lines,
-and plug switches for the dynamo leads. Thus, dynamos can be thrown in
-or out as desired, without putting out the lights.
-
-
-Distribution of Electric Energy, Systems of.
-The systems of electric current distribution from central stations or
-from private generating plants, mechanical or battery, the latter
-primary or secondary. They include in general the alternating current
-system and direct current systems. Again, these may be subdivided into
-series and multiple arc, multiple-series and series-multiple
-distribution, and the three, four, or five wire system may be applied to
-multiple arc or multiple series systems. (See Alternating
-Current--Current System--Multiple Arc--Multiple Series--Series
-Multiple--Three Wire System.)
-
-
-Door Opener, Electric.
-An apparatus for opening a door by pushing back the latch. A spring then
-draws the door open, and it is closed against the force of the spring by
-the person entering. Electro-magnetic mechanism actuates the latch, and
-is operated by a switch or press-button. Thus a person on the upper
-floor can open the hall door without descending.
-
-
-Dosage, Galvanic.
-In electro-therapeutics the amount of electric current or discharge, and
-duration of treatment given to patients.
-
-
-Double Carbon Arc Lamp.
-An arc lamp designed to burn all night, usually constructed with two
-parallel sets of carbons, one set replacing the other automatically, the
-current being switched from the burnt out pair to the other by the
-action of the mechanism of the lamp.
-
-
-191  STANDARD ELECTRICAL DICTIONARY.
-
-
-Double Fluid Theory.
-A theory of electricity. Electricity is conveniently treated as a fluid
-or fluids. According to the double fluid hypothesis negative electricity
-is due to a preponderance of negative fluid and vice versa. Like fluid
-repels like, and unlike attracts unlike; either fluid is attracted by
-matter; the presence in a body of one or the other induces
-electrification; united in equal proportions they neutralize each other,
-and friction, chemical decomposition and other causes effect their
-separation. The hypothesis, while convenient, is overshadowed by the
-certainty that electricity is not really a fluid at all. (See Single
-Fluid Theory--Fluid, Electric.)
-
-Synonym--Symmer's Theory.
-
-[Transcriber's note: Current is the motion of negative electrons in a
-conductor or plasma. Unequal distribution of electrons is static
-electricity. The relatively immobile nuclei of atoms are positive when
-one or more of its electrons is absent and accounts for part of the
-current in electrolysis and plasmas.]
-
-
-Double Fluid Voltaic Cell.
-A cell in which two fluids are used, one generally as depolarizer
-surrounding the negative plate, the other as excitant surrounding the
-positive plate. A porous diaphragm or difference in specific gravities
-is used to keep the solutions separate and yet permit the essential
-electrolytic diffusion. Grove's Cell, Bunsen's Cell, and Daniell's Cell,
-all of which may be referred to, are of this type, as are many others.
-
-
-Double Wedge.
-A plug for use with a spring-jack. It has connection strips at its end
-and another pair a little distance back therefrom, so that it can make
-two loop connections at once.
-
-Synonym--Double Plug.
-
-
-Doubler.
-A continuously acting electrophorous, q.v.; an early predecessor of the
-modern electric machines. It is now no longer used.
-
-
-D. P.
-Abbreviation for Potential Difference.
-
-
-Drag.
-The pull exercised by a magnetic field upon a conductor moving through
-it or upon the motion of an armature in it.
-
-
-Dreh-strom. (German)
-Rotatory currents; a system of currents alternating in periodic
-succession of phases and producing a rotatory field. (See Field,
-Rotatory--Multiphase Currents.)
-
-
-Drill Electric.
-A drill for metals or rock worked by an electro-magnetic motor. For
-metals a rotary motion, for rocks a reciprocating or percussion action
-is imparted. It is used by shipbuilders for drilling holes in plates
-which are in place in ships, as its flexible conductors enable it to be
-placed anywhere. For rock-drilling a solenoid type of construction is
-adopted, producing rapid percussion.
-
-
-192   STANDARD ELECTRICAL DICTIONARY.
-
-
-Drip Loop.
-A looping downward of wires entering a building, so that rain water, as
-it runs along the wire, will drip from the lowest part of the loop
-instead of following the wire into or against the side of the building.
-
-
-Driving Horns.
-Projections on the periphery of an armature of a dynamo for holding the
-winding in place and preventing its displacement. Various arrangements
-have been adopted. They are sometimes wedges or pins and are sometimes
-driven into spaces left in the drum core. The toothed disc armature
-cores make up an armature in which the ridges formed by the teeth form
-practically driving horns.
-
-
-Dronier's Salt.
-A substance for solution for use in bichromate batteries. It is a
-mixture of one-third potassium bichromate and two-thirds potassium
-bisulphate. It is dissolved in water to make the exciting fluid.
-
-
-Drop, Automatic.
-A switch or circuit breaker, operating to close a circuit by dropping
-under the influence of gravity. It is held up by a latch, the circuit
-remaining open, until the latch is released by a current passing through
-an electro-magnet. This attracting an armature lets the drop fall. As it
-falls it closes a local or second circuit, and thus may keep a bell
-ringing until it is replaced by hand. It is used in burglar alarms, its
-function being to keep a bell ringing even though the windows or door by
-which entrance was made is reclosed.
-
-
-193   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 133. THE MAGIC DRUM.
-
-
-Drum, Electric.
-A drum with a mechanism within for striking the head with a hammer or
-some equivalent method so as to be used as a piece of magical apparatus.
-In the one shown in the cut a sort of telephone action is used to
-produce the sound, the electro-magnet D and armature being quite
-screened from observation through the hole. (See Fig. 133) A ring, C,
-shown in Fig. 133, with two terminals, the latter shown by the unshaded
-portions a a, and a suspending hook E, also with two terminals, and two
-suspending conductors A, B, carry the current to the magnet. A sudden
-opening or closing of the circuit produces a sound.
-
-
-Dub's Laws.
-1. The magnetism excited at any transverse section of a magnet is
-proportional to the square root of the distance between the given
-section and the end.
-
-2. The free magnetism at any given transverse section of a magnet is
-proportional to the difference between the square root of half the
-length of the magnet and the square root of the distance between the
-given section and the nearest end.
-
-
-Duct.
-The tube or compartment in an electric subway for the reception of a
-cable. (See Conduit, Electric Subway.)
-
-
-Dyad.
-A chemical term; an element which in combination replaces two monovalent
-elements; one which has two bonds or is bivalent.
-
-
-Dyeing, Electric.
-The producing mordanting or other dyeing effects on goods in dyeing by
-the passage of an electric current.
-
-
-Dynamic Electricity.
-Electricity of relatively low potential and large quantity; current
-electricity as distinguished from static electricity; electricity in
-motion.
-
-
-194   STANDARD ELECTRICAL DICTIONARY.
-
-
-Dynamo, Alternating Current.
-A dynamo-electric machine for producing an alternating current; an
-alternator. They are classified by S. P. Thompson into three classes--I.
-Those with stationary field-magnet and rotating armature. II. Those with
-rotating field magnet and stationary armature. III. Those with both
-field magnet part and armature part stationary, the amount of magnetic
-induction from the latter through the former being caused to vary or
-alternate in direction by the revolution of appropriate pieces of iron,
-called inductors. Another division rests on whether they give one simple
-alternating current, a two phase current, or whether they give multi
-phase currents. (See Current, Alternating--Currents, Multiphase.)
-
-A great many kinds of alternators have been constructed. Only an outline
-of the general theory can be given here. They are generally multipolar,
-with north and south poles alternating around the field. The armature
-coils, equal in number in simple current machines, to the poles, are
-wound in opposite senses, so that the current shall be in one direction,
-though in opposite senses, in all of them at anyone time. As the
-armature rotates the coils are all approaching their poles at one time
-and a current in one sense is induced in every second coil, and one in
-the other sense in the other coils. They are all in continuous circuit
-with two open terminals, each connected to its own insulated connecting
-ring on the shaft. As the coils pass the poles and begin to recede from
-them the direction changes, and the current goes in the other direction
-until the next poles are reached and passed. Thus there are as many
-changes of direction of current per rotation as there are coils in the
-armature or poles in the field.
-
-
-Fig. 134. ALTERNATING CURRENT DYNAMO WITH
-SEPARATE EXCITER MOUNTED ON MAIN SHAFT.
-
-
-195  STANDARD ELECTRICAL DICTIONARY.
-
-
-The field-magnets whose windings may be in series are often excited by a
-separate direct current generation. Some are self-exciting, one or more
-of the armature coils being separated from the rest, and connected to a
-special commutator, which rectifies its current.
-
-By properly spacing the coils with respect to the poles of the field,
-and connecting each set of coils by itself to separate connecting rings,
-several currents can be taken from the same machine, which currents
-shall have a constant difference in phase. It would seem at first sight
-that the same result could be attained by using as many separate
-alternators as there were currents to be produced. But it would be
-almost impossible to preserve the exact relation of currents and current
-phase where each was produced by its own machine. The currents would
-overrun each other or would lag behind. In a single machine with
-separate sets of coils the relation is fixed and invariable.
-
-
-Fig. I35. DIAGRAM OF ARRANGEMENT OF ARMATURE COILS AND
-COLLECTING RINGS IN AN ALTERNATING CURRENT DYNAMO.
-
-
-Dynamo, Alternating Current, Regulation of.
-Transformers, converters, or induction coils are used to regulate
-alternating current dynamos, somewhat as compound winding is applied in
-the case of direct-current dynamos. The arrangement consists in
-connecting the primary of an induction coil or transformer into the
-external circuit with its secondary connected to the field circuit. Thus
-the transformer conveys current to the field picked up from the main
-circuit, and represents to some extent the shunt of a direct-current
-machine.
-
-Dynamo, Commercial Efficiency of.
-The coefficient, q. v., obtained by dividing the mechanically useful or
-available work of a dynamo by the mechanical energy absorbed by it. This
-only includes the energy available in the outer circuit, for doing
-useful work.
-
-
-196   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 136. COMPOUND WOUND DYNAMO.
-
-
-Dynamo. Compound.
-A compound wound dynamo; one which has two coils on its field magnet;
-one winding is in series with the external circuit and armature; the
-other winding is in parallel with the armature winding, or else with the
-armature winding and field winding, both in series. (See Winding, Long
-Shunt--Winding, Short Shunt.)
-
-Such a dynamo is, to a certain extent, self-regulating, the two coils
-counteracting each other, and bringing about a more regular action for
-varying currents than that of the ordinary shunt or series dynamo.
-
-The extent of the regulation of such a machine depends on the
-proportions given its different parts. However good the self-regulating
-may be in a compound wound machine, it can only be perfect at one
-particular speed.
-
-To illustrate the principle on which the approximate regulation is
-obtained the characteristic curve diagram may be consulted.
-
-
-Fig. 137. CURVES OF SERIES AND SHUNT WINDINGS SUPERIMPOSED.
-
-
-One curve is the curve of a series winding, the other that of a shunt
-winding, and shows the variation of voltage in each with resistance in
-the external or working circuit. The variation is opposite in each case.
-It is evident that the two windings could be so proportioned on a
-compound machine that the resultant of the two curves would be a
-straight line. This regulation would then be perfect and automatic, but
-only for the one speed.
-
-
-197  STANDARD ELECTRICAL DICTIONARY.
-
-
-Dynamo, Direct Current.
-A dynamo giving a current of unvarying direction, as distinguished from
-an alternator or alternating current dynamo.
-
-
-Dynamo, Disc.
-A dynamo with a disc armature, such as Pacinotti's disc, q. v. (See also
-Disc, Armature.) The field magnets are disposed so that the disc rotates
-close to their poles, and the poles face or are opposite to the side or
-sides of the disc. The active leads of wire are those situated on the
-face or faces of the disc.
-
-
-Fig. 138. POLECHKO'S DISC DYNAMO.
-
-
-Dynamo-electric Machine.
-A machine driven by power, generally steam power, and converting the
-mechanical energy expended on driving it into electrical energy of the
-current form. The parts of the ordinary dynamo may be summarized as
-follows: First, A circuit as complete as possible of iron. Such circuit
-is composed partly of the cores of an electro-magnet or of several
-electro-magnets, and partly of the cylindrical or ring-shaped core of an
-armature which fits as closely as practicable between the magnet ends or
-poles which are shaped so as to partly embrace it. Second, of coils of
-insulated wire wound upon the field-magnet cores. When these coils are
-excited the field-magnets develop polarity and the circuit just spoken
-of becomes a magnetic circuit, interrupted only by the air gaps between
-the poles and armatures. Thirdly, of coils of insulated wire upon the
-armature core. These coils when rotated in the magnetic field cut
-magnetic lines of force and develop electro-motive force.
-
-
-198   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fourthly, of collecting mechanism, the commutator in direct current
-dynamos, attached to the armature shaft and rotating with it. This
-consists of insulated rings, or segments of rings to which the wire
-coils of the armature are connected, and on which two springs of copper
-or plates of carbon or some other conductor presses. The electro-motive
-force developed by the cutting of lines of force, by the wires of the
-armature, shows itself as potential difference between the two springs.
-If the ends of a conductor are attached, one to each of these brushes,
-the potential difference will establish a current through the wire. By
-using properly divided and connected segments on the commutator the
-potential difference and consequent direction of the current may be kept
-always in the same sense or direction. It is now clear that the external
-wire may be connected with the windings of the field-magnet. In such
-case the excitement of the field-magnets is derived from the armature
-and the machine is self-excited and entirely self-contained.
-
-The above is a general description of a dynamo. Sometimes the coils of
-the field-magnets are not connected with the armature, but derive their
-current from an outside source. Such are termed separately excited
-dynamos.
-
-Some general features of dynamo generators may be seen in the
-definitions under this head and elsewhere. The general conception is to
-cut lines of force with a conductor and thus generate electromotive
-force, or in some way to change the number of lines of force within a
-loop or circuit with the same effect.
-
-
-Dynamo, Electroplating.
-A dynamo designed for low potential and high current intensity. They are
-wound for low resistance, frequently several wires being used in
-parallel, or ribbon, bar or rectangular conductors being employed. They
-are of the direct current type. They should be shunt wound or they are
-liable to reverse. They are sometimes provided with resistance in the
-shunt, which is changed as desired to alter the electro-motive force.
-
-
-Dynamo, Equalizing.
-A combination for three and five-wire systems. A number of armatures or
-of windings on the same shaft are connected across the leads. If the
-potential drops at any pair of mains, the armature will begin to be
-driven by the other mains, acting to an extent as an element of a motor,
-and will raise the potential in the first pair.
-
-
-Dynamo, Far Leading.
-A motor dynamo, used to compensate the drop of potential in long mains.
-Into the mains at a distant point a series motor is connected, driving a
-dynamo placed in shunt across the mains. The dynamo thus driven raises
-the potential difference between the two mains.
-
-
-199  STANDARD ELECTRICAL DICTIONARY.
-
-
-Dynamograph.
-A printing telegraph in which the message is printed at both
-transmitting and receiving ends.
-
-
-Dynamo, Inductor.
-A generator in which the armature or current-generating windings are all
-comprised upon the poles of the field magnets. Masses of iron, which
-should be laminated and are the inductors, are carried past the field
-magnet poles concentrating in their passage the lines of force, thus
-inducing currents in the coils. In one construction shown in the cut the
-field magnets a, a .. are U shaped and are arranged in a circle, their
-poles pointing inwards. A single exciting coil c, c ... is wound around
-the circle in the bend of the V-shaped segments. The poles carry the
-armature coils e, e ... The laminated inductors i, i ... are mounted on
-a shaft S, by spiders h, to be rotated inside the circle of magnets,
-thus generating an alternating current.
-
-Synonym--Inductor Generator.
-
-
-Fig. 139. INDUCTOR DYNAMO.
-
-
-Dynamo, Interior Pole.
-A dynamo with a ring armature, with field magnet pole pieces which
-extend within the ring.
-
-
-200   STANDARD ELECTRICAL DICTIONARY.
-
-
-Dynamo, Iron Clad.
-A dynamo in which the iron of the field magnet is of such shape as to
-enclose the field magnet coils as well as the armature.
-
-
-Dynamometer.
-A device or apparatus for measuring force applied, or rate of
-expenditure of energy by, or work done in a given time by a machine. A
-common spring balance can be used as a force dynamometer, viz: to
-determine how hard a man is pulling and the like. The steam engine
-indicator represents an energy-dynamometer of the graphic type, the
-instrument marking an area whence, with the aid of the fixed factors of
-the engine, the work done may be determined. Prony's Brake, q. v., is a
-type of the friction dynamometer, also of the energy type. In the latter
-type during the experiment the whole power must be turned on or be
-expended on the dynamometer.
-
-
-Dynamo, Motor.
-A motor dynamo is a machine for (a) converting a continuous current at
-any voltage to a continuous current of different strength at a different
-voltage or for (b) transforming a continuous current into an alternating
-one, and vice versa.
-
-For the first type see Transformer, Continuous Current; for the second
-type see Transformer, Alternating Current.
-
-
-Dynamo, Multipolar.
-A dynamo having a number of field magnet poles, not merely a single
-north and a single south pole. The field magnet is sometimes of a
-generally circular shape with the poles arranged radially within it, the
-armature revolving between the ends.
-
-
-Dynamo, Non-polar.
-A name given by Prof. George Forbes to a dynamo invented by him. In it a
-cylinder of iron rotates within a perfectly self-contained iron-clad
-field magnet. The current is taken off by brushes bearing near the
-periphery, at two extremities of a diameter. A machine with a disc 18
-inches in diameter was said to give 3,117 amperes, with 5.8 volts E. M.
-F. running at 1,500 revolutions per second. The E. M. F. of such
-machines varies with the square of the diameter of the disc or cylinder.
-
-
-Dynamo, Open Coil.
-A dynamo the windings of whose armatures may be grouped in coils, which
-are not connected in series, but which have independent terminals. These
-terminals are separate divisions of the commutator and so spaced that
-the collecting brushes touch each pair belonging to the same coil
-simultaneously. As the brushes come in contact with the sections forming
-the terminals they take current from the coil in question. This coil is
-next succeeded by another one, and so on according to the number of
-coils employed.
-
-
-Dynamo, Ring.
-A dynamo the base of whose field magnets is a ring in general shape, or
-perhaps an octagon, and with poles projecting inwardly therefrom.
-
-
-201   STANDARD ELECTRICAL DICTIONARY.
-
-
-Dynamo, Coupling of.
-Dynamos can be coupled exactly like batteries and with about the same
-general results. An instance of series coupling would be given by the
-dynamos in the three wire system when no current is passing through the
-neutral wire, and when the lamps on each side of it are lighted in equal
-number.
-
-
-Dynamo, Self-exciting.
-A dynamo which excites its own field. The majority of dynamos are of
-this construction. Others, especially alternating current machines, are
-separately excited, the field magnets being supplied with current from a
-separate dynamo or current generator.
-
-
-Dynamo, Separate Circuit.
-A dynamo in which the field magnet coils are entirely disconnected from
-the main circuit, and in which current for the field is supplied by
-special coils carried for the purpose by the same armature, or by a
-special one, in either case a special commutator being provided to
-collect the current.
-
-
-Dynamo, Separately Excited.
-A dynamo whose field magnets are excited by a separate current
-generator, such as a dynamo or even a battery. Alternating current
-dynamos are often of this construction. Direct current dynamos are not
-generally so. The term is the opposite of self-exciting.
-
-
-Fig. 140. SERIES DYNAMO.
-
-
-Dynamo, Series.
-A dynamo whose armature, field winding, and external circuit are all in
-series.
-
-In such a dynamo short circuiting or lowering the resistance of the
-external circuit strengthens the field, increases the electro-motive
-force and current strength and may injure the winding by heating the
-wire, and melting the insulation.
-
-
-202   STANDARD ELECTRICAL DICTIONARY.
-
-
-Dynamo, Shunt.
-A dynamo whose field is wound in shunt with the external circuit. Two
-leads are taken from the brushes; one goes around the field magnets to
-excite them; the other is the external circuit.
-
-In such a dynamo the lowering of resistance on the outer circuit takes
-current from the field and lowers the electro-motive force of the
-machine. Short circuiting has no heating effect.
-
-
-Fig. 141.   SHUNT DYNAMO.
-
-
-Dynamo, Single Coil.
-A dynamo whose field magnet is excited by a single coil. Several such
-have been constructed, with different shapes of field magnet cores, in
-order to obtain a proper distribution of poles.
-
-
-Dynamo, Tuning Fork.
-A dynamo in which the inductive or armature coils were carried at the
-ends of the prongs of a gigantic tuning fork, and were there maintained
-in vibration opposite the field magnets. It was invented by T. A.
-Edison, but never was used.
-
-
-Dynamo, Uni-polar.
-A dynamo in which the rotation of a conductor effects a continuous
-increase in the number of lines cut, by the device of arranging one part
-of the conductor to slide on or around the magnet. (S. P. Thomson.)
-Faraday's disc is the earliest machine of this type.
-
-
-203  STANDARD ELECTRICAL DICTIONARY.
-
-
-Dyne.
-The C. G. S. or fundamental unit of force. It is the force which can
-impart an acceleration of one centimeter per second to a mass of one
-gram in one second. It is equal to about 1/981 the weight of a gram,
-this weight varying with the latitude.
-
-
-Earth.
-(a) The earth is arbitrarily taken as of zero electrostatic potential.
-Surfaces in such condition that their potential is unchanged when
-connected to the earth are said to be of zero potential. All other
-surfaces are discharged when connected to the earth, whose potential,
-for the purposes of man at least, never changes.
-
-(b) As a magnetic field of force the intensity of the earth's field is
-about one-half a line of force per square centimeter.
-
-(c) The accidental grounding of a telegraph line is termed an earth, as
-a dead, total, partial, or intermittent earth, describing the extent and
-character of the trouble.
-
-[Transcriber's note: Fallen power lines can produce voltage gradients on
-the earth's surface that make walking in the area dangerous, as in
-hundreds of volts per foot. Lightning may be associated with substantial
-changes in the static ground potential.]
-
-
-Earth, Dead.
-A fault, when a telegraph or other conductor is fully connected to earth
-or grounded at some intermediate point.
-
-Synonyms--Solid Earth--Total Earth.
-
-
-Earth, Partial.
-A fault, when a telegraph or other conductor is imperfectly connected to
-earth or grounded at some intermediate point.
-
-
-Earth Plate.
-A plate buried in the earth to receive the ends of telegraph lines or
-other circuits to give a ground, q. v. A copper plate is often used. A
-connection to a water or gas main gives an excellent ground, far better
-than any plate. When the plate oxidizes it is apt to introduce
-resistance.
-
-
-Earth Return.
-The grounding of a wire of a circuit at both ends gives the circuit an
-earth return.
-
-
-Earth, Swinging.
-A fault, when a telegraph or other conductor makes intermittent
-connection with the earth. It is generally attributable to wind action
-swinging the wire, whence the name.
-
-
-Ebonite.
-Hard vulcanized India rubber, black in color. Specific resistance in
-ohms per cubic centimeter at 46� C. (115� F.): 34E15 (Ayrton); specific
-inductive capacity, (air = 1): 2.56 (W�llner); 2.76 (Schiller); 3.15
-(Boltzmann). It is used in electrical apparatus for supporting members
-such as pillars, and is an excellent material for frictional generation
-of potential. Its black color gives it its name, and is sometimes made a
-point of distinction from Vulcanite, q. v.
-
-
-204   STANDARD ELECTRICAL DICTIONARY.
-
-
-Economic Coefficient.
-The coefficient of electric efficiency. (See Efficiency, Electric.)
-
-
-Edison Effect.
-A continuous discharge resulting in a true current which takes place
-between a terminal of an incandescent lamp filament and a plate placed
-near it. The lamp must be run at a definitely high voltage to obtain it.
-
-
-Ediswan.
-An abbreviation for Edison-Swan; the trade name of the incandescent lamp
-used in Great Britain, and of other incandescent system apparatus.
-
-
-Fig. 142. GYMNOTUS ELECTRICUS.
-
-
-Eel, Electric (Gymnotus Electricus).
-An eel capable of effecting the discharge of very high potential
-electricity, giving painful or dangerous shocks. Its habitat is the
-fresh water, in South America. Faraday investigated it and estimated its
-shock as equal to that from fifteen Leyden jars, each of 1.66 square
-feet of coating. (See Animal Electricity and Ray, Electric.)
-
-
-Effect, Counter-inductive.
-A counter-electro-motive force due to induction, and opposing a current.
-
-
-Efficiency.
-The relation of work done to energy absorbed. A theoretically perfect
-machine would have the maximum efficiency in which the two qualities
-named would be equal to each other. Expressed by a coefficient, q. v.,
-the efficiency in such case would be equal to 1. If a machine produced
-but half the work represented by the energy it absorbed, the rest
-disappearing in wasteful expenditure, in heating the bearings, in
-overcoming the resistance of the air and in other ways, its efficiency
-would be expressed by the coefficient 1/2 or .5, or if one hundred was
-the basis, by fifty per centum. There are a number of kinds of
-efficiencies of an electric generator which are given below.
-
-
-Efficiency, Commercial.
-Practical efficiency of a machine, obtained by dividing the available
-output of work or energy of a machine by the energy absorbed by the same
-machine. Thus in a dynamo part of the energy is usefully expended in
-exciting the field magnet, but this energy is not available for use in
-the outer circuit, is not a part of the output, and is not part of the
-dividend.
-
-If M represents the energy absorbed, and W the useful or available
-energy, the coefficient of commercial efficiency is equal to W/M. M is
-made up of available, unavailable and wasted (by Foucault currents,
-etc.,) energy. Calling available energy W, unavailable but utilized
-energy w, and wasted energy m, the expression for the coefficient of
-commercial efficiency becomes
-
-  W / ( W + w + m )
-  when M = W + w + m
-
-Synonym--Net efficiency.
-
-
-205   STANDARD ELECTRICAL DICTIONARY.
-
-
-Efficiency, Electrical.
-In a dynamo or generator the relation of total electric energy produced,
-both wasted and useful or available to the useful or available
-electrical energy. If we call W the useful electric and w the wasted
-electric energy, the coefficient of electrical efficiency is equal to
-
-  W / ( W + w )
-
-Synonyms--Intrinsic Efficiency--Economic Coefficient--Coefficient of
-Electrical Efficiency.
-
-
-Efficiency of Conversion.
-In a dynamo or generator the relation of energy absorbed to total
-electric energy produced. Part of the electric energy is expended in
-producing the field and in other ways. Thus a generator with high
-efficiency of conversion may be a very poor one, owing to the
-unavailable electric energy which it produces. The coefficient of
-Efficiency of Conversion is obtained by dividing the total electric
-energy produced by the energy absorbed in working the dynamo. If M
-represents the energy absorbed, or work done in driving the dynamo or
-generator, W the useful electric, and w the wasted electrical energy,
-then the coefficient of efficiency of conversion is equal to
-
-(W + w ) / M
-
-In the quantity M are included besides available (W) and unavailable (w)
-electric energy, the totally wasted energy due to Foucault currents,
-etc., calling the latter m, the above formula may be given
-
-( W+ w ) / (W + w + m )
-
-This coefficient may refer to the action of a converter, q. v., in the
-alternating system. Synonym--Gross Efficiency.
-
-
-Efficiency of Secondary Battery, Quantity.
-The coefficient obtained by dividing the ampere-hours obtainable from a
-secondary battery by the ampere hours required to charge it.
-
-
-Efficiency of Secondary Battery, Real.
-The coefficient obtained by dividing the energy obtainable from a
-secondary battery by the energy absorbed in charging it. The energy is
-conveniently taken in watt-hours and includes the consideration of the
-spurious voltage. (See Battery, Secondary.)
-
-
-206   STANDARD ELECTRICAL DICTIONARY.
-
-
-Efflorescence.
-The appearance of a dry salt upon the walls of a vessel containing a
-solution above the normal water-line from evaporation of a liquid. It
-appears in battery jars and in battery carbons, in the latter
-interfering with the electrical connections, and oxidizing or rusting
-them. (See Creeping.)
-
-
-Effluvium, Electric.
-When a gas is made to occupy the position of dielectric between two
-oppositely electrified surfaces a peculiar strain or condition of the
-dielectric is produced, which promotes chemical change. The condition is
-termed electrical effluvium or the silent discharge. By an apparatus
-specially constructed to utilize the condition large amounts of ozone
-are produced.
-
-Synonym--Silent Discharge.
-
-
-Elastic Curve.
-A crude expression for a curve without projections or sudden
-sinuosities; such a curve as can be obtained by bending an elastic strip
-of wood.
-
-
-Electrepeter.
-An obsolete name for a key, switch or pole changer of any kind.
-
-
-Elasticity, Electric.
-The phenomenon of the dielectric is described under this term. When a
-potential difference is established between two parts of the dielectric,
-a flow of electricity displacement current starts through the
-dielectric, which current is due to the electric stress, but is
-instantly arrested by what has been termed the electric elasticity of
-the dielectric. This is expressed by
-  ( electric stress ) / ( electric strain )
-and in any substance is inversely proportional to the specific inductive
-capacity.
-
-
-Electricity.
-It is impossible in the existing state of human knowledge to give a
-satisfactory definition of electricity. The views of various authorities
-are given here to afford a basis for arriving at the general consensus
-of electricians.
-
-We have as yet no conception of electricity apart from the electrified
-body; we have no experience of its independent existence. (J. E. H.
-Gordon.)
-
-What is Electricity? We do not know, and for practical purposes it is
-not necessary that we should know. (Sydney F. Walker.)
-
-Electricity � is one of those hidden and mysterious powers of nature
-which has thus become known to us through the medium of effects.
-(Weale's Dictionary of Terms.)
-
-This word Electricity is used to express more particularly the cause,
-which even today remains unknown, of the phenomena that we are about to
-explain. (Am�d�e Guillemin.)
-
-
-207  STANDARD ELECTRICAL DICTIONARY.
-
-
-Electricity is a powerful physical agent which manifests itself mainly
-by attractions and repulsions, but also by luminous and heating effects,
-by violent commotions, by chemical decompositions, and many other
-phenomena. Unlike gravity, it is not inherent in bodies, but it is
-evoked in them by a variety of causes � (Ganot's Physics.)
-
-Electricity and magnetism are not forms of energy; neither are they
-forms of matter. They may, perhaps, be provisionally defined as
-properties or conditions of matter; but whether this matter be the
-ordinary matter, or whether it be, on the other hand, that
-all-pervading ether by which ordinary matter is surrounded, is a question
-which has been under discussion, and which now may be fairly held to be
-settled in favor of the latter view. (Daniell's Physics.)
-
-The name used in connection with an extensive and important class of
-phenomena, and usually denoting the unknown cause of the phenomena or
-the science that treats of them. (Imperial Dictionary.)
-
-Electricity. . . is the imponderable physical agent, cause, force or the
-molecular movement, by which, under certain conditions, certain
-phenomena, chiefly those of attraction and repulsion, . . . are
-produced. (John Angell.)
-
-It has been suggested that if anything can rightly be called
-"electricity," this must be the ether itself; and that all electrical
-and magnetic phenomena are simply due to changes, strains and motions in
-the ether. Perhaps negative electrification. . .means an excess of
-ether, and positive electrification a defect of ether, as compared with
-the normal density. (W. Larden.)
-
-Electricity is the name given to the supposed agent producing the
-described condition (i. e. electrification) of bodies. (Fleeming
-Jenkin.)
-
-There are certain bodies which, when warm and dry, acquire by friction,
-the property of attracting feathers, filaments of silk or indeed any
-light body towards them. This property is called Electricity, and bodies
-which possess it are said to be electrified. (Linnaeus Cumming.)
-
-What electricity is it is impossible to say, but for the present it is
-convenient to look upon it as a kind of invisible something which
-pervades all bodies. (W. Perren Maycock.)
-
-What is electricity? No one knows. It seems to be one manifestation of
-the energy which fills the universe and which appears in a variety of
-other forms, such as heat, light, magnetism, chemical affinity,
-mechanical motion, etc. (Park Benjamin.)
-
-
-208   STANDARD ELECTRICAL DICTIONARY.
-
-
-The theory of electricity adopted throughout these lessons is, that
-electricity, whatever its true nature, is one, not two; that this
-Electricity, whatever it may prove to be, is not matter, and is not
-energy; that it resembles both matter and energy in one respect,
-however, in that it can neither be created nor destroyed. (Sylvanus P.
-Thomson.)
-
-In Physics a name denoting the cause of an important class of phenomena
-of attraction and repulsion, chemical decomposition, etc., or,
-collectively, these phenomena themselves. (Century Dictionary.)
-
-A power in nature, often styled the electric fluid, exhibiting itself,
-when in disturbed equilibrium or in activity, by a circuit movement, the
-fact of direction in which involves polarity, or opposition of
-properties in opposite directions; also, by attraction for many
-substances, by a law involving attraction between substances of unlike
-polarity, and repulsion between those of like; by exhibiting accumulated
-polar tension when the circuit is broken; and by producing heat, light,
-concussion, and often chemical changes when the circuit passes between
-the poles, or through any imperfectly conducting substance or space. It
-is evolved in any disturbance of molecular equilibrium, whether from a
-chemical, physical, or mechanical cause. (Webster's Dictionary.)
-
-In point of fact electricity is not a fluid at all, and only in a few of
-its attributes is it at all comparable to a fluid. Let us rather
-consider electricity to be a condition into which material substances
-are thrown. . .(Slingo & Brooker.)
-
-[Transcriber's note: 2008 Dictionary: Phenomena arising from the
-behavior of electrons and protons caused by the attraction of particles
-with opposite charges and the repulsion of particles with the same
-charge.]
-
-
-Electricity, Cal.
-The electricity produced in the secondary of a transformer by changes of
-temperature in the core. This is in addition to the regularly induced
-current.
-
-Synonym--Acheson Effect.
-
-
-Electrics.
-Substances developing electrification by rubbing or friction; as
-Gilbert, the originator of the term, applied it, it would indicate
-dielectrics. He did not know that, if insulated, any substance was one
-of his "electrics." A piece of copper held by a glass handle becomes
-electrified by friction.
-
-
-Electrification.
-The receiving or imparting an electric charge to a surface; a term
-usually applied to electrostatic phenomena.
-
-
-Electrization.
-A term in electro-therapeutics; the subjection of the human system to
-electric treatment for curative, tonic or diagnostic purposes.
-
-
-Electro-biology.
-The science of electricity in its relation to the living organism,
-whether as electricity is developed by the organism, or as it affects
-the same when applied from an external source.
-
-
-209  STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-capillarity.
-The relations between surface tension, the potential difference and the
-electrostatic capacity of fluids in contact. Although nominally in
-contact such surfaces are separated by about one-twenty-millionth of a
-centimeter (1/50000000 inch) ; thus a globule of mercury and water in
-which it is immersed constitute an electrostatic accumulator of definite
-electrostatic capacity. Again the mercury and water being in electric
-connection differ in potential by contact (see Contact Theory). A
-definite surface tension is also established. Any change in one of these
-factors changes the other also. A current passed through the contact
-surfaces will change the surface tension and hence the shape of the
-mercury globule. Shaking the globule will change its shape and capacity
-and produce a current. Heating will do the same. (See Electrometer,
-Capillary; and Telephone, Capillary.) Mercury and water are named as
-liquids in which the phenomena are most conveniently observed. They are
-observable in other parallel cases.
-
-
-Electro-chemical Equivalent.
-The quantity of an element or compound liberated from or brought into
-combination, electrolytically, by one coulomb of electricity. The
-electro-chemical equivalent of hydrogen is found by experiment to be
-.0000105 gram. That of any other substance is found by multiplying this
-weight by its chemical equivalent referred to hydrogen, which is its
-atomic or molecular weight divided by its valency. Thus the atomic
-weight of oxygen is 16, its valency is 2, its equivalent is 16/2 = 8;
-its electro-chemical equivalent is equal to .0000105 X 8 = .000840 gram.
-
-
-Electro-chemical Series.
-An arrangement of the elements in the order of their relative electrical
-affinities so that each element is electro-negative to all the elements
-following it, and electro-positive to the elements preceding it. The
-usual series begins with oxygen as the most electro-negative and ends
-with potassium as the most electro-positive element. There is, of
-course, no reason why other series of compound radicals, such as
-sulphion (SO4), etc., should not also be constructed. For each liquid
-acting on substances a separate series of the substances acted on may be
-constructed. Thus for dilute sulphuric acid the series beginning with
-the negatively charged or most attacked one is zinc, amalgamated or
-pure, cadmium, iron, tin, lead, aluminum, nickel, antimony, bismuth,
-copper, silver, platinum. In other liquids the series is altogether
-different.
-
-
-Electro--chemistry.
-The branch of electricity or of chemistry treating of the relations
-between electric and chemical force in different compounds and
-reactions. (See Electrolysis--Electrochemical series--Electro-chemical
-Equivalent .)
-
-
-
-210   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-culture.
-The application of electricity to the cultivation of plants. In one
-system wires are stretched or carried across the bed under the surface,
-and some are connected to one pole and others to the other pole of a
-galvanic battery of two or more elements. In some experiments improved
-results have thus been obtained.
-
-Another branch refers to the action of the electric arc light on
-vegetation. This has an effect on vegetation varying in results.
-
-
-Electrode.
-(a) The terminal of an open electric circuit.
-
-(b) The terminals of the metallic or solid conductors of an electric
-circuit, immersed in an electrolytic solution.
-
-(c) The terminals between which a voltaic arc is formed, always in
-practice made of carbon, are termed electrodes.
-
-(d) In electro-therapeutics many different electrodes are used whose
-names are generally descriptive of their shape, character, or uses to
-which they are to be applied. Such are aural electrodes for the ears,
-and many others.
-
-(e) The plates of a voltaic battery.
-
-
-Electrode, Indifferent.
-A term in electro-therapeutics. An electrode to which no therapeutic
-action is attributed but which merely provides a second contact with the
-body to complete the circuit through the same. The other electrode is
-termed the therapeutic electrode.
-
-
-Electrodes, Erb's Standards of.
-Proposed standard sizes for medical electrodes as follows:
-  Name.          Diameter.
-  Fine     Electrode,   1/2  centimeter   .2      inch
-  Small       "         2       "         .8        "
-  Medium      "       7.5       "        3.0        "
-  Large       "       6X2       "        2.4 X .8   "
-  Very large  "      16x8       "        6.4 x 3.2  "
-
-
-Electrodes, Non-polarizable.
-In electro-therapeutics electrodes whose contact surface is virtually
-porous clay saturated with zinc chloride solution. The series terminate
-in amalgamated zinc ends, enclosed each in a glass tube, and closed with
-clay. Contact of metal with the tissues is thus avoided.
-
-
-Electrode, Therapeutic.
-A term in electro-therapeutics. An electrode applied to the body for the
-purpose of inducing therapeutic action, or for giving the basis for an
-electric diagnosis of the case. The other electrode is applied to
-complete the circuit only; it is termed the indifferent electrode.
-
-
-Electro-diagnosis.
-The study of the condition of a patient by the reactions which occur at
-the terminals or kathode and anode of an electric circuit applied to the
-person. The reactions are divided into kathodic and anodic reactions.
-
-
-211   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-dynamic. adj.
-The opposite of electrostatic; a qualification of phenomena due to
-current electricity.
-
-Synonym--Electro-kinetic.
-
-
-Electro-dynamic Attraction and Repulsion.
-The mutual attraction and repulsion exercised by currents of electricity
-upon each other. The theory of the cause is based upon stress of the
-luminiferous ether and upon the reaction of lines of force upon each
-other. For a resum� of the theory see Induction, Electro-magnetic.
-
-
-Electro-dynamics.
-The laws of electricity in a state of motion; the inter-reaction of
-electric currents. It is distinguished from electro-magnetic induction
-as the latter refers to the production of currents by induction. The
-general laws of electro-dynamics are stated under Induction,
-Electro-magnetic, q. v.
-
-Synonym--Electro-kinetics.
-
-
-Fig. 143. DIAGRAM OF CONNECTIONS OF SIEMENS' ELECTRO-DYNAMOMETER.
-
-
-212   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-dynamometer, Siemens'.
-An apparatus for measuring currents by the reaction between two coils,
-one fixed and one movable, through which the current to be measured
-passes. It is one of the oldest commercial ammeters or current
-measurers. It comprises a fixed coil of a number of convolutions and a
-movable coil often of only one convolution surrounding the other. The
-movable coil is suspended by a filament or thread from a spiral spring.
-The spring is the controlling factor. Connection is established through
-mercury cups so as to bring the two coils in series. In use the spring
-and filament are adjusted by turning a milled head to which they are
-connected until the coils are at right angles. Then the current is
-turned on and deflects the movable coil. The milled head is turned until
-the deflection is overcome. The angle through which the head is turned
-is proportional to the square of the current. The movable coil must in
-its position at right angles to the fixed one lie at right angles to the
-magnetic meridian.
-
-Thus in the diagram, Fig. 143 A B C D is the fixed coil; E F G H is the
-movable coil; S is the spiral spring attached at K to the movable coil.
-The arrows show the course of the current as it goes through the coils.
-
-
-Electrolier.
-A fixture for supporting electric lamps; the analogue in electric
-lighting of the gasolier or gas chandelier. Often both are combined, the
-same fixture being piped and carrying gas burners, as well as being
-wired and carrying electric lamps.
-
-
-Electrolysis.
-The separation of a chemical compound into its constituent parts or
-elements by the action of the electric current. The compound may be
-decomposed into its elements, as water into hydrogen and oxygen, or into
-constituent radicals, as sodium sulphate into sodium and sulphion, which
-by secondary reactions at once give sodium hydrate and sulphuric acid.
-The decomposition proceeds subject to the laws of electrolysis. (See
-Electrolysis, Laws of.) For decomposition to be produced there is for
-each compound a minimum electro-motive force or potential difference
-required. The current passes through the electrolyte or substance
-undergoing decomposition entirely by Electrolytic Conduction, q. v. in
-accordance with Groth�ss' Hypothesis, q. v. The electrolyte therefore
-must be susceptible of diffusion and must be a fluid.
-
-The general theory holds that under the influence of a potential
-difference between electrodes immersed in an electrolyte, the molecules
-touching the electrodes are polarized, in the opposite sense for each
-electrode. If the potential difference is sufficient the molecules will
-give up one of their binary constituents to the electrode, and the other
-constituent will decompose the adjoining molecule, and that one being
-separated into the same two constituents will decompose its neighbor,
-and so on through the mass until the other electrode is reached. This
-one separates definitely the second binary constituent from the
-molecules touching it.
-
-
-213   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thus there is an exact balance preserved. Just as many molecules are
-decomposed at one electrode as at the other, and the exact chain of
-decomposition runs through the mass. Each compound electrolyzed develops
-a binary or two-fold composition, and gives up one constituent to one
-electrode and the other to the other.
-
-
-Fig. 144. ACTION OF MOLECULES IN A SOLUTION
-BEFORE AND DURING ELECTROLYSIS.
-
-
-The cut shows the assumed polarization of an electrolyte. The upper row
-shows the molecules in irregular order before any potential difference
-has been produced, in other words, before the circuit is closed. The
-next row shows the first effects of closing the circuit, and also
-indicates the polarization of the mass, when the potential difference is
-insufficient for decomposition. The third row indicates the
-decomposition of a chain of molecules, one constituent separating at
-each pole.
-
-
-214   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electrolysis, Laws of.
-The following are the principal laws, originally discovered by
-Faraday, and sometimes called Faraday's Laws of Electrolysis:
-
-1. Electrolysis cannot take place unless the electrolyte is a conductor.
-Conductor here means an electrolytic conductor, one that conducts by its
-own molecules traveling, and being decomposed. (See Groth�ss'
-Hypothesis.)
-
-II. The energy of the electrolytic action of the current is the same
-wherever exercised in different parts of the circuit.
-
-III. The same quantity of electricity--that is the same current for the
-same period----- decomposes chemically equivalent quantities of the
-bodies it decomposes, or the weights of elements separated in
-electrolytes by the same quantity of electricity (in coulombs or some
-equivalent unit) are to each other as their chemical equivalent.
-
-IV. The quantity of a body decomposed in a given time is proportional to
-the strength of the current.
-
-To these may be added the following:
-
-V. A definite and fixed electro-motive force is required for the
-decomposition of each compound, greater for some and less for others.
-Without sufficient electro-motive force expended on the molecule no
-decomposition will take place. (See Current, Convective.)
-
-
-Electrolyte.
-A body susceptible of decomposition by the electric current, and capable
-of electrolytic conduction. It must be a fluid body and therefore
-capable of diffusion, and composite in composition. An elemental body
-cannot be an electrolyte.
-
-
-Electrolytic Analysis.
-Chemical analysis by electrolysis. The quantitative separation of a
-number of metals can be very effectively executed. Thus, suppose that a
-solution of copper sulphate was to be analyzed. A measured portion of
-the solution would be introduced into a weighed platinum vessel. The
-vessel would be connected to the zinc plate terminal of a battery. From
-the other terminal of the battery a wire would be brought and would
-terminate in a plate of platinum. This would be immersed in the solution
-in the vessel. As the current would pass the copper sulphate would be
-decomposed and eventually all the copper would be deposited in a firm
-coating on the platinum. The next operations would be to wash the metal
-with distilled water, and eventually with alcohol, to dry and to weigh
-the dish with the adherent copper. On subtracting the weight of the dish
-alone from the weight of the dish and copper, the weight of the metallic
-copper in the solution would be obtained.
-
-In similar ways many other determinations are effected. The processes of
-analysis include solution of the ores or other substances to be analyzed
-and their conversion into proper form for electrolysis. Copper as just
-described can be precipitated from the solution of its sulphate. For
-iron and many other metals solutions of their double alkaline oxalates
-are especially available forms for analysis.
-
-The entire subject has been worked out in considerable detail by
-Classen, to whose works reference should be made for details of
-processes.
-
-
-Electrolytic Convection.
-It is sometimes observed that a single cell of Daniell battery, for
-instance, or other source of electric current establishing too low a
-potential difference for the decomposition of water seems to produce a
-feeble but continuous decomposition. This is very unsatisfactorily
-accounted for by the hydrogen as liberated combining with dissolved
-oxygen. (Ganot.) The whole matter is obscure. (See Current, Convection.)
-
-
-215  STANDARD ELECTRICAL DICTIONARY.
-
-
-Electrolytic Conduction.
-Conduction by the travel of atoms or radicals from molecule to molecule
-of a substance with eventual setting free at the electrodes of the atoms
-or radicals as elementary molecules or constituent radicals. A substance
-to be capable of acting as an electrolytic conductor must be capable of
-diffusion, and must also have electrolytic conductivity. Such a body is
-called an electrolyte. (See Groth�ss' Hypothesis--Electrolysis--
-Electrolysis, Laws of--Electro-chemical Equivalent.)
-
-
-Electro-magnet.
-A mass, in practice always of iron, around which an electric circuit is
-carried, insulated from the iron. When a current is passed through the
-circuit the iron presents the characteristics of a magnet. (See
-Magnetism, Amp�re's Theory of--Solenoid--Lines of Force.) In general
-terms the action of a circular current is to establish lines of force
-that run through the axis of the circuit approximately parallel thereto,
-and curving out of and over the circuit, return into themselves outside
-of the circuit. If a mass of iron is inserted in the axis or elsewhere
-near such current, it multiplies within itself the lines of force, q. v.
-(See also Magnetic Permeability--Permeance--Magnetic Induction,
-Coefficient of Magnetic Susceptibility--Magnetization, Coefficient of
-Induced.) These lines of force make it a magnet. On their direction,
-which again depends on the direction of the magnetizing current, depends
-the polarity of the iron. The strength of an electro-magnet, below
-saturation of the core (see Magnetic Saturation), is proportional nearly
-to the ampere-turns, q. v. More turns for the same current or more
-current for the same turns increase its strength.
-
-In the cut is shown the general relation of current, coils, core and
-line of force. Assume that the magnet is looked at endwise, the observer
-facing one of the poles; then if the current goes around the core in the
-direction opposite to that of the hands of a clock, such pole will be
-the north pole. If the current is in the direction of the hands of a
-clock the pole facing the observer will be the south pole. The whole
-relation is exactly that of the theoretical Amp�rian currents, already
-explained. The direction and course of the lines of force created are
-shown in the cut.
-
-The shapes of electro-magnets vary greatly. The cuts show several forms
-of electro-magnets. A more usual form is the horseshoe or double limb
-magnet, consisting generally of two straight cores, wound with wire and
-connected and held parallel to each other by a bar across one end, which
-bar is called the yoke.
-
-In winding such a magnet the wire coils must conform, as regards
-direction of the current in them to the rule for polarity already cited.
-If both poles are north or both are south poles, then the magnet cannot
-be termed a horseshoe magnet, but is merely an anomalous magnet. In the
-field magnets of dynamos the most varied types of electro-magnets have
-been used. Consequent poles are often produced in them by the direction
-of the windings and connections.
-
-To obtain the most powerful magnet the iron core should be as short and
-thick as possible in order to diminish the reluctance of the magnetic
-circuit. To obtain a greater range of action a long thin shape is
-better, although it involves waste of energy in its excitation.
-
-
-216   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 145 DIAGRAM OF AN ELECTRO-MAGNET SHOWING RELATION OF
-CURRENT AND WINDING TO ITS POLARITY AND LINES OF FORCE.
-
-
-Fig. 146. ANNULAR ELECTRO-MAGNET
-
-
-Electro-magnet, Annular.
-An electro-magnet consisting of a cylinder with a circular groove cut in
-its face, in which groove a coil of insulated wire is placed. On the
-passage of a current the iron becomes polarized and attracts an armature
-towards or against its grooved face. The cut shows the construction of
-an experimental one. It is in practice applied to brakes and clutches.
-In the cut of the electro-magnetic brake (see Brake, Electro-magnetic),
-C is the annular magnet receiving its current through the brushes, and
-pressed when braking action is required against the face of the moving
-wheel. The same arrangement, it can be seen, may apply to a clutch.
-
-
-217  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 147. BAR ELECTRO-MAGNET.
-
-
-Electro-magnet, Bar.
-A straight bar of iron surrounded with a magnetizing coil of wire. Bar
-electromagnets are not much used, the horseshoe type being by far the
-more usual.
-
-
-Electro-magnet, Club-foot.
-An electro-magnet, one of whose legs only is wound with wire, the other
-being bare.
-
-
-Fig. 148. CLUB-FOOT ELECTRO-MAGNETS WITH HINGED ARMATURES.
-
-
-Electro-magnet, Hinged.
-An electro-magnet whose limbs are hinged at the yoke. On excitation by a
-current the poles tend to approach each other.
-
-
-Fig. 149. ELECTRO-MAGNET, HINGED
-
-
-Electro-magnetic Attraction and Repulsion.
-The attraction and repulsion due to electromagnetic lines of force,
-which lines always tend to take as short a course as possible and also
-seek the medium of the highest permeance. This causes them to
-concentrate in iron and steel or other paramagnetic substance and to
-draw them towards a magnet by shortening the lines of force connecting
-the two. It is exactly the same attraction as that of the permanent
-magnet for its armature, Amp�re's theory bringing the latter under the
-same title. In the case of two magnets like poles repel and unlike
-attract. In the case of simple currents, those in the same direction
-attract and those in opposite directions repel each other. This refers
-to constant current reactions. Thus the attraction of unlike poles of
-two magnets is, by the Amp�rian theory, the attraction of two sets of
-currents of similar direction, as is evident from the diagram. The
-repulsion of like poles is the repulsion of unlike currents and the same
-applies to solenoids, q. v. (See Magnetism and do. Amp�re's Theory
-of--Induction, Electro-dynamic--Electro-magnetic Induction.)
-
-
-218   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-magnetic Control.
-Control of a magnet, iron armature, or magnetic needle in a
-galvanometer, ammeter, voltmeter or similar instrument by an
-electro-magnetic field, the restitutive force being derived from an
-electro-magnet. The restitutive force is the force tending to bring the
-index to zero.
-
-
-Electro-magnetic Field of Force.
-A field of electro-magnetic lines of force, q. v., established through
-the agency of an electric current. A wire carrying a current is
-surrounded by circular concentric lines of force which have the axis of
-the wire as the locus of their centres. Electro-magnets produce lines of
-force identical with those produced by permanent magnets. (See Field of
-Force--Magnetic Field of Force--Controlling Field--Deflecting Field.)
-
-
-Electro-magnetic Induction.
-When two currents of unlike direction are brought towards each other,
-against their natural repulsive tendency work is done, and the
-consequent energy takes the form of a temporary increase in both
-currents. When withdrawn, in compliance with the natural tendency of
-repulsion, the currents are diminished in intensity, because energy is
-not expended on the withdrawal, but the withdrawal is at the expense of
-the energy of the system. The variations thus temporarily produced in
-the currents are examples of electro-magnetic induction. The currents
-have only the duration in each case of the motion of the circuits. One
-circuit is considered as carrying the inducer current and is termed the
-primary circuit and its current the primary current, the others are
-termed the secondary circuit and current respectively. We may assume a
-secondary circuit in which there is no current. It is probable that
-there is always an infinitely small current at least, in every closed
-circuit. Then an approach of the circuits will induce in the secondary
-an instantaneous current in the reverse direction. On separating the two
-circuits a temporary current in the same direction is produced in the
-secondary.
-
-
-219  STANDARD ELECTRICAL DICTIONARY.
-
-
-A current is surrounded by lines of force. The approach of two circuits,
-one active, involves a change in the lines of force about the secondary
-circuit. Lines of force and current are so intimately connected that a
-change in one compels a change in the other. Therefore the induced
-current in the secondary may be attributed to the change in the field of
-force in which it lies, a field maintained by the primary circuit and
-current. Any change in a field of force induces a current or change of
-current in any closed circuit in such field, lasting as long as the
-change is taking place. The new current will be of such direction as to
-oppose the change. (See Lenz's Law.)
-
-The action as referred to lines of force may be figured as the cutting
-of such lines by the secondary circuit, and such cutting may be brought
-about by moving the secondary in the field. (See Lines of Force--Field
-of Force.) The cutting of 1E8 lines of force per second by a closed
-circuit induces an electro-motive force of one volt. (See Induction,
-Mutual, Coefficient of.)
-
-
-Electro-magnet, Iron Clad.
-A magnet whose coil and core are encased in a iron jacket, generally
-connected to one end of the core. This gives at one end two poles, one
-tubular, the other solid, and concentric with each other. It is
-sometimes called a tubular magnet.
-
-
-Electro-magnet, One Coil.
-An electro-magnet excited by one coil. In some dynamos the field magnets
-are of this construction, a single coil, situated about midway between
-the poles, producing the excitation.
-
-
-Electro-magnetic Leakage.
-The leakage of lines of force in an electro-magnet; the same as magnetic
-leakage. (See Magnetic Leakage.)
-
-
-Electro-magnetic Lines of Force.
-The lines of force produced in an electro-magnetic field. They are
-identical with Magnetic Lines of Force, q. v. (See also Field of
-Force-Line of Force.)
-
-
-Electro-magnetic Stress.
-The stress in an electro-magnetic field of force, showing itself in the
-polarization of light passing through a transparent medium in such a
-field. (See Magnetic Rotary Polarization.)
-
-
-Electro-magnetic Theory of Light.
-This theory is due to J. Clark Maxwell, and the recent Hertz experiments
-have gone far to prove it. It holds that the phenomena of light are due
-to ether waves, identical in general factors with those produced by
-electro-magnetic induction of alternating currents acting on the ether.
-In a non-conductor any disturbance sets an ether wave in motion owing to
-its restitutive force; electricity does not travel through such a
-medium, but can create ether waves in it. Therefore a non-conductor of
-electricity is permeable to waves of ether or should transmit light, or
-should be transparent. A conductor on the other hand transmits
-electrical disturbances because it has no restitutive force and cannot
-support an ether wave. Hence a conductor should not transmit light, or
-should be opaque. With few exceptions dielectrics or non-conductors are
-transparent, and conductors are opaque.
-
-
-220   STANDARD ELECTRICAL DICTIONARY.
-
-
-Again, the relation between the electrostatic and electro-magnet units
-of quantity is expressed by 1 : 30,000,000,000; the latter figure in
-centimeters gives approximately the velocity of light. The
-electro-magnetic unit depending on electricity in motion should have
-this precise relation if an electro-magnetic disturbance was propagated
-with the velocity of light. If an electrically charged body were whirled
-around a magnetic needle with the velocity of light, it should act in
-the same way as a current circulating around it. This effect to some
-extent has been shown experimentally by Rowland.
-
-A consequence of these conclusions is (Maxwell) that the specific
-inductive capacity of a non-conductor or dielectric should be equal to
-the square of its index of refraction for waves of infinite length. This
-is true for some substances--sulphur, turpentine, petroleum and benzole.
-In others the specific inductive capacity is too high, e. g., vegetable
-and animal oils, glass, Iceland spar, fluor spar, and quartz.
-
-
-Electro-magnetic Unit of Energy.
-A rate of transference of energy equal to ten meg-ergs per second.
-
-
-Electro-magnetism.
-The branch of electrical science treating of the magnetic relations of a
-field of force produced by a current, of the reactions of
-electro-magnetic lines of force, of the electromagnetic field of force,
-of the susceptibility, permeability, and reluctance of diamagnetic and
-paramagnetic substances, and of electro-magnets in general.
-
-
-Electro-magnet, Long Range.
-An electro-magnet so constructed with extended pole pieces or otherwise,
-as to attract its armature with reasonably constant force over a
-considerable distance. The coil and plunger, q. v., mechanisms
-illustrate one method of getting an extended range of action. When a
-true electro-magnet is used, one with an iron core, only a very limited
-range is attainable at the best. (See Electro-magnet, Stopped Coil--do.
-Plunger.)
-
-
-Electro-magnet, Plunger.
-An electro-magnet with hollow coils, into which the armature enters as a
-plunger. To make it a true electro-magnet it must have either a yoke,
-incomplete core, or some polarized mass of iron.
-
-
-Electro-magnet, Polarized.
-An electro-magnet consisting of a polarized or permanently magnetized
-core wound with magnetizing coils, or with such coils on soft iron cores
-mounted on its ends. The coils may be wound and connected so as to
-cooperate with or work against the permanent magnet on which it is
-mounted. In Hughes' magnet shown in the cut it is mounted in opposition,
-so that an exceedingly feeble current will act to displace the armature,
-a, which is pulled away from the magnet by a spring, s.
-
-
-221   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 150 HUGHES' POLARIZED ELECTRO-MAGNET
-
-
-Electro-magnets, Interlocking.
-Electro-magnets so arranged that their armatures interlock. Thus two
-magnets, A A and B B, may be placed with their armatures, M and N, at
-right angles and both normally pulled away from the poles. When the
-armature M is attracted a catch on its end is retained by a hole in the
-end of the other armature N, and when the latter armature N is attracted
-by its magnet the armature M is released. In the mechanism shown in the
-cut the movements of the wheel R are controlled. Normally it is held
-motionless by the catch upon the bottom of the armature M, coming
-against the tooth projecting from its periphery. A momentary current
-through the coils of the magnet A A releases it, by attracting M, which
-is caught and retained by N, and leaves it free to rotate. A momentary
-current through the coils of the magnet B B again releases M, which
-drops down and engages the tooth upon R and arrests its motion.
-
-
-Fig. 151. INTERLOCKING ELECTRO-MAGNETS.
-
-
-222   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-magnet, Stopped Coil.
-An electro-magnet consisting of a tubular coil, in which a short fixed
-core is contained, stopping up the aperture to a certain distance, while
-the armature is a plunger entering the aperture. This gives a longer
-range of action than usual.
-
-
-Electro-magnet, Surgical.
-An electro-magnet, generally of straight or bar form, fitted with
-different shaped pole pieces, used for the extraction of fragments of
-iron or steel from the eyes. Some very curious cases of successful
-operations on the eyes of workmen, into whose eyes fragments of steel or
-iron had penetrated, are on record.
-
-
-Electro-medical Baths.
-A bath for the person provided with connections and electrodes for
-causing a current of electricity of any desired type to pass through the
-body of the bather. Like all electro-therapeutical treatment, it should
-be administered under the direction of a physician only.
-
-
-Electro-metallurgy.
-(a) In the reduction of ores the electric current has been proposed but
-never extensively used, except in the reduction of aluminum and its
-alloys. (See Reduction of Ores, Electric.)
-
-(b) Electro-plating and deposition of metal from solutions is another
-branch. (See Electroplating and Electrotyping.)
-
-(c) The concentration of iron ores by magnetic attraction may come under
-this head. (See Magnetic Concentration of Ores.)
-
-
-Electrometer.
-An instrument for use in the measurement of potential difference, by the
-attraction or repulsion of statically charged bodies. They are
-distinguished from galvanometers as the latter are really current
-measurers, even if wound for use as voltmeters, depending for their
-action upon the action of the current circulating in their coils.
-
-
-Electrometer, Absolute.
-An electrometer designed to give directly the value of a charge in
-absolute units. In one form a plate, a b, of conducting surface is
-supported or poised horizontally below a second larger plate C, also of
-conducting surface. The poised plate is surrounded by a detached guard
-ring--an annular or perforated plate, r g r' g'--exactly level and even
-with it as regards the upper surface. The inner plate is carried by a
-delicate balance. In use it is connected to one of the conductors and
-the lower plate to earth or to the other. The attraction between them is
-determined by weighing. By calculation the results can be made absolute,
-as they depend on actual size of the plates and their distance, outside
-of the potential difference of which of course nothing can be said. If S
-is the area of the disc, d the distance of the plates, V-V1 the
-difference of their potential, which is to be measured, and F the force
-required to balance their attraction, we have:
-
-F = ( ( V - V1 )^2 * S )  / ( 8 * PI * d^2 )
-
-
-223  STANDARD ELECTRICAL DICTIONARY.
-
-
-If  V = 0 this reduces to
-
-  F =  ( V^2 * S ) / ( 8 * PI * d^2 )  (2)
-  or
-  V =  d * SquareRoot( (8 * PI * F ) / S )   (3)
-
-As F is expressed as a weight, and S and a as measures of area and
-length, this gives a means of directly obtaining potential values in
-absolute measure. (See Idiostatic Method--Heterostatic Method.)
-
-Synonyms--Attracted Disc Electrometer--Weight Electrometer.
-
-
-Fig. 152. SECTION OF BASE OF PORTABLE ELECTROMETER.
-
-
-In some forms the movable disc is above the other, and supported at the
-end of a balance beam. In others a spring support, arranged so as to
-enable the attraction to be determined in weight units, is adopted. The
-cuts, Figs. 152 and 154, show one of the latter type, the portable
-electrometer. The disc portion is contained within a cylindrical vessel.
-
-
-Fig. 153. DIAGRAM ILLUSTRATING THEORY OF ABSOLUTE ELECTROMETER.
-
-
-Referring to Fig. 152  g is the stationary disc, charged through the
-wire connection r; f is the movable disc, carried by a balance beam
-poised at i on a horizontal and transverse stretched platinum wire,
-acting as a torsional spring. The position of the end k of the balance
-beam shows when the disc f is in the plane of the guard ring h h. The
-end k is forked horizontally and a horizontal sighting wire or hair is
-fastened across the opening of the fork. When the hair is midway between
-two dots on a vertical scale the lever is in the sighted position, as it
-is called, and the disc is in the plane of the guard ring.
-
-
-224   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 154. PORTABLE ELECTROMETER.
-
-
-The general construction is seen in Fig. 154. There the fixed disc D is
-carried by insulating stem g1. The charging electrode is supported by an
-insulating stem g2, and without contact with the box passes out of its
-cover through a guard tube E, with cover, sometimes called umbrella, V.
-The umbrella is to protect the apparatus from air currents. At m is the
-sighting lens. H is a lead box packed with pumice stone, moistened with
-oil of vitriol or concentrated sulphuric acid, to preserve the
-atmosphere dry. Before use the acid is boiled with some ammonium
-sulphate to expel any corrosive nitrogen oxides, which might corrode the
-brass.
-
-In use the upper disc is charged by its insulated electrode within the
-tube E; the movable disc is charged if desired directly through the case
-of the instrument. The upper disc is screwed up or down by the
-micrometer head M, until the sighted position is reached. The readings
-of the micrometer on the top of the case give the data for calculation.
-
-
-225   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 155. LIPPMAN'S CAPILLARY ELECTROMETER.
-
-
-Electrometer, Capillary.
-An electrometer for measuring potential difference by capillary action,
-which latter is affected by electrostatic excitement. A tube A contains
-mercury; its end drawn out to a fine aperture dips into a vessel B which
-contains dilute sulphuric acid with mercury under it, as shown. Wires
-running from the binding-posts a and b connect one with the mercury in
-A, the other with that in B. The upper end of the tube A connects with a
-thick rubber mercury reservoir T, and manometer H. The surface tension
-of the mercury-acid film at the lower end of the tube A keeps all in
-equilibrium. If now a potential difference is established between a and
-b, as by connecting a battery thereto, the surface tension is increased
-and the mercury rises in the tube B. By screwing down the compressing
-clamp E, the mercury is brought back to its original position. The
-microscope M is used to determine this position with accuracy. The
-change in reading of the manometer gives the relation of change of
-surface tension and therefore of potential. Each electrometer needs
-special graduation or calibration, but is exceedingly sensitive and
-accurate. It cannot be used for greater potential differences than .6
-volt, but can measure .0006 volt. Its electrostatic capacity is so small
-that it can indicate rapid changes. Another form indicates potential
-difference by the movement of a drop of sulphuric acid in a horizontal
-glass tube, otherwise filled with mercury, and whose ends lead into two
-mercury cups or reservoirs. The pair of electrodes to be tested are
-connected to the mercury vessels. The drop moves towards the negative
-pole, and its movement for small potential differences (less than one
-volt) is proportional to the electro-motive force or potential
-difference.
-
-
-226   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electrometer Gauge.
-An absolute electrometer (see Electrometer, Absolute) forming an
-attachment to a Thomson quadrant electrometer. It is used to test the
-potential of the flat needle connected with the inner surface of the
-Leyden jar condenser of the apparatus. This it does by measuring the
-attraction between itself and an attracting disc, the latter connected
-by a conductor with the interior of the jar.
-
-
-Electrometer, Lane's.
-A Leyden jar with mounted discharger, so that when charged to a certain
-point it discharges itself. It is connected with one coating of any jar
-whose charge is to be measured, which jar is then charged by the other
-coating. As the jar under trial becomes charged to a certain point the
-electrometer jar discharges itself, and the number of discharges is the
-measure of the charge of the other jar. It is really a unit jar, q. v.
-
-
-Fig. 156. THOMSON'S QUADRANT ELECTROMETER.
-
-
-Fig. 157. HENLEY'S QUADRANT ELECTROSCOPE.
-
-
-227  STANDARD ELECTRICAL DICTIONARY.
-
-
-Electrometer, Quadrant.
-(a) Sir William Thomson's electrometer, a simple form of which is shown
-in the cut, consists of four quadrants of metal placed horizontally;
-above these a broad flat aluminum needle hangs by a very fine wire,
-acting as torsional suspension. The quadrants are insulated from each
-other, but the opposite ones connect with each other by wires. The
-apparatus is adjusted so that, when the quadrants are in an unexcited
-condition the needle is at rest over one of the diametrical divisions
-between quadrants. The needle by its suspension wire is in communication
-with the interior of a Leyden jar which is charged. The whole is covered
-with a glass shade, and the air within is kept dry by a dish of
-concentrated sulphuric acid so that the jar retains its charge for a
-long time and keeps the needle at approximately a constant potential. If
-now two pairs of quadrants are excited with opposite electricities, as
-when connected with the opposite poles of an insulated galvanic cell,
-the needle is repelled by one pair and attracted by the other, and
-therefore rotates through an arc of greater or less extent. A small
-concave mirror is attached above the needle and its image is reflected
-on a graduated screen. This makes the smallest movement visible.
-Sometimes the quadrants are double, forming almost a complete box,
-within which the needle moves.
-
-(b) Henley's quadrant electrometer is for use on the prime conductor of
-an electric machine, for roughly indicating the relative potential
-thereof. It consists of a wooden standard attached perpendicularly to
-the conductor. Near one end is attached a semi-circular or quadrant arc
-of a circle graduated into degrees or angular divisions. An index,
-consisting of a straw with a pith-bell attached to its end hangs from
-the center of curvature of the arc. When the prime conductor is charged
-the index moves up over the scale and its extent of motion indicates the
-potential relatively.
-
-When the "quadrant electrometer" is spoken of it may always be assumed
-that Sir William Thomson's instrument is alluded to. Henley's instrument
-is properly termed a quadrant electroscope. (See Electroscope.)
-
-
-Electro-motive Force.
-The cause which produces currents of electricity. In general it can be
-expressed in difference of potentials, although the term electro-motive
-force should be restricted to potential difference causing a current. It
-is often a sustained charging of the generator terminals whence the
-current is taken. Its dimensions are
-
-(work done/the quantity of electricity involved),
-
-or ( M * (L^2) /(T^2 ) ) / ((M^.5) * (L^.5)) = ( (M^.5) * (L^1.5) ) /(T^2)
-
-The practical unit of electro-motive force is the volt, q. v. It is
-often expressed in abbreviated form, as E. M. D. P., or simply as D. P.,
-i. e., potential difference.
-
-Electro-motive force and potential difference are in many cases
-virtually identical, and distinctions drawn between them vary with
-different authors. If we consider a closed electric circuit carrying a
-current, a definite electro-motive force determined by Ohm's law from
-the resistance and current obtains in it. But if we attempt to define
-potential difference as proper to the circuit we may quite fail.
-Potential difference in a circuit is the difference in potential between
-defined points of such circuit. But no points in a closed circuit can be
-found which differ in potential by an amount equal to the entire
-electro-motive force of the circuit. Potential difference is properly
-the measure of electro-motive force expended on the portion of a circuit
-between any given points. Electro-motive force of an entire circuit, as
-it is measured, as it were, between two consecutive points but around
-the long portion of the circuit, is not conceivable as merely potential
-difference. Taking the circle divided in to degrees as an analogy, the
-electro-motive force of the entire circuit might be expressed as 360�,
-which are the degrees intervening between two consecutive points,
-measured the long way around the circle. But the potential difference
-between the same two points would be only 1�, for it would be measured
-by the nearest path.
-
-[Transcriber's notes: If 360� is the "long" way, 0� is the "short". A
-formal restatement of the above definition of EMF: "If a charge Q passes
-through a device and gains energy U, the net EMF for that device is the
-energy gained per unit charge, or U/Q. The unit of EMF is a volt, or
-newton-meter per coulomb."]
-
-
-228   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-motive Force, Counter.
-A current going through a circuit often has not only true or ohmic
-resistance to overcome, but meets an opposing E. M. F. This is termed
-counter-electro-motive force. It is often treated in calculations as
-resistance, and is termed spurious resistance. It may be a part of the
-impedance of a circuit.
-
-In a primary battery hydrogen accumulating on the negative plate
-develops counter E. M. F. In the voltaic arc the differential heating of
-the two carbons does the same. The storage battery is changed by a
-current passing in the opposite direction to its own natural current;
-the polarity of such a battery is counter E. M. F.
-
-
-Electro-motive Force, Unit.
-Unit electro-motive force is that which is created in a conductor moving
-through a magnetic field at such a rate as to cut one unit line of force
-per second. It is that which must be maintained in a circuit of unit
-resistance to maintain a current of unit quantity therein. It is that
-which must be maintained between the ends of a conductor in order that
-unit current may do unit work in a second.
-
-
-Electro-motive Intensity.
-The force acting upon a unit charge of electricity. The mean force is
-equal to the difference of potential between two points within the field
-situated one centimeter apart, such distance being measured along the
-lines of force. The term is due to J. Clerk Maxwell.
-
-
-Electro-motive Series.
-Arrangement of the metals and carbon in series with the most
-electro-positive at one end, and electronegative at the other end. The
-following are examples for different exciting liquids:
-
-Dilute Sulphuric   Dilute Hydrochloric   Caustic   Potassium
-Acid               Acid.                 Potash.   Sulphide.
-
-Zinc               Zinc                  Zinc      Zinc
-Cadmium            Cadmium               Tin       Copper
-Tin                Tin                   Cadmium   Cadmium
-Lead               Lead                  Antimony  Tin
-Iron               Iron                  Lead      Silver
-Nickel             Copper                Bismuth   Antimony
-Bismuth            Bismuth               Iron      Lead
-Antimony           Nickel                Copper    Bismuth
-Copper             Silver                Nickel    Nickel
-Silver             Antimony              Silver    Iron
-Gold
-Platinum
-Carbon
-
-In each series the upper metal is the positive, dissolved or attacked
-element.
-
-
-229  STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-motograph.
-An invention of Thomas A. Edison. A cylinder of chalk, moistened with
-solution of caustic soda, is mounted so as to be rotated by a handle. A
-diaphragm has an arm connected to its center. This arm is pressed
-against the surface of the cylinder by a spring. When the cylinder is
-rotated, a constant tension is exerted on the diaphragm. If a current is
-passed through the junction of arm and cylinder the electrolytic action
-alters the friction so as to change the stress upon the diaphragm.
-
-If the current producing this effect is of the type produced by the
-human voice through a microphone the successive variations in strain
-upon the diaphragm will cause it to emit articulate sounds. These are
-produced directly by the movement of the cylinder, the electrolytic
-action being rather the regulating portion of the operation. Hence very
-loud sounds can be produced by it. This has given it the name of the
-loud- speaking telephone.
-
-The same principle may be applied in other ways. But the practical
-application of the motograph is in the telephone described.
-
-
-Fig. 158. ELECTRO-MOTOGRAPH TELEPHONE
-
-
-Electro-motor.
-This term is sometimes applied to a current generator, such as a voltaic
-battery.
-
-
-Electro-muscular Excitation.
-A term in medical electricity indicating the excitation of muscle as the
-effect of electric currents of any kind.
-
-
-Electro-negative. adj.
-Appertaining to negative electrification; thus of the elements oxygen is
-the most electro-negative, because if separated by electrolytic action
-from any combination, it will be charged with negative electricity.
-
-
-230   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-optics.
-The branch of natural science treating of the relations between light
-and electricity. Both are supposed to be phenomena of or due to the
-luminiferous ether. To it may be referred the following:
-
-(a) Electro-magnetic Stress and Magnetic Rotary Polarization;
-
-(b) Dielectric Strain; all of which may be referred to in this book;
-
-(c) Change in the resistance of a conductor by changes in light to which
-it is exposed (see Selenium);
-
-(d) The relation of the index of refraction of a dielectric to the
-dielectric constant (see Electro-magnetic Theory of Light);
-
-(e) The identity (approximate) of the velocity of light in centimeters
-and the relative values of the electrostatic and electro-magnet units
-of intensity, the latter being 30,000,000,000 times greater than the
-former, while the velocity of light is 30,000,000,000 centimeters per
-second.
-
-
-Electrophoric Action.
-The action of an electrophorous; utilized in influence machines. (See
-Electrophorous.)
-
-
-Fig. 159. ELECTROPHOROUS.
-
-
-Electrophorous.
-An apparatus for the production of electric charges of high potential by
-electrostatic induction, q. v. It consists of a disc of insulating
-material B, such as resin or gutta percha, which is held in a shallow
-metal-lined box or form. The disc may be half an inch thick and a foot
-or more in diameter, or may be much smaller and thinner. A metal disc A,
-smaller in diameter is provided with an insulating handle which may be
-of glass, or simply silk suspension strings. To use it the disc B is
-excited by friction with a cat-skin or other suitable substance. The
-metallic disc is then placed on the cake of resin exactly in its centre,
-so that the latter disc or cake projects on all sides. Owing to
-roughness there is little real electric contact between the metal and
-dielectric. On touching the metal disc a quantity of negative
-electricity escapes to the earth. On raising it from the cake it comes
-off excited positively, and gives a spark and is discharged. It can be
-replaced, touched, removed and another spark can be taken from it, and
-so on as long as the cake stays charged.
-
-The successive discharges represent electrical energy expended. This is
-derived from the muscular energy expended by the operator in separating
-the two discs when oppositely excited. As generally used it is therefore
-an apparatus for converting muscular or mechanical energy into electric
-energy.
-
-
-231   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electro-physiology.
-The science of the electric phenomena of the animal system. It may also
-be extended to include plants. The great discovery of Galvani with the
-frog's body fell into this branch of science. The electric fishes,
-gymnotus, etc., present intense phenomena in the same.
-
-
-Electroplating.
-The deposition by electrolysis of a coating of metal upon a conducting
-surface. The simplest system makes the object to be plated the negative
-electrode or plate in a galvanic couple. Thus a spoon or other object
-may be connected by a wire to a plate of zinc. A porous cup is placed
-inside a battery jar. The spoon is placed in the porous cup and the zinc
-outside it. A solution of copper sulphate is placed in the porous cup,
-and water with a little sodium or zinc sulphate dissolved in it,
-outside. A current starts through the couple, and copper is deposited on
-the spoon.
-
-A less primitive way is to use a separate battery as the source of
-current; to connect to the positive plate by a wire the object to be
-plated, and a plate of copper, silver, nickel or other metal to the
-other pole of the battery. On immersing both object and plate (anode) in
-a bath of proper solution the object will become plated.
-
-In general the anode is of the same material as the metal to be
-deposited, and dissolving keeps up the strength of the bath. There are a
-great many points of technicality involved which cannot be given here.
-The surface of the immersed object must be conductive. If not a fine
-wire network stretched over it will gradually fill up in the bath and
-give a matrix. More generally the surface is made conductive by being
-brushed over with plumbago. This may be followed by a dusting of iron
-dust, followed by immersion in solution ot copper sulphate. This has the
-effect of depositing metallic copper over the surface as a starter for
-the final coat.
-
-Attention must be paid to the perfect cleanliness of the objects, to the
-condition of the bath, purity of anodes and current density.
-
-Voltaic batteries are largely used for the current as well as special
-low resistance dynamos. Thermo-electric batteries are also used to some
-extent but not generally.
-
-
-Electro-pneumatic Signals.
-Signals, such as railroad signals or semaphores, moved by compressed
-air, which is controlled by valves operated by electricity. The House
-telegraph, which was worked by air controlled by electricity, might come
-under this term, but it is always understood as applied to railroad
-signals, or their equivalent.
-
-
-232   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electropoion Fluid.
-An acid depolarizing solution for use in zinc-carbon couples, such as
-the Grenet battery. The following are formulae for its preparation:
-
-(a) Dissolve one pound of potassium bichromate in ten pounds of water,
-to which two and one-half pounds of concentrated sulphuric acid have
-been gradually added. The better way is to use powdered potassium
-bichromate, add it to the water first, and then gradually add the
-sulphuric acid with constant stirring.
-
-(b) To three pints of water add five fluid ounces of concentrated
-sulphuric acid; add six ounces pulverized potassium bichromate.
-
-(c) Mix one gallon concentrated sulphuric acid and three gallons of
-water. In a separate vessel dissolve six pounds potassium bichromate in
-two gallons of boiling water. Mix the two.
-
-The last is the best formula. Always use electropoion fluid cold. (See
-Trouv�'s Solution--Poggendorff's Solution--Kakogey's Solution--
-Tissandrier's Solution--Chutaux's Solution.)
-
-
-Electro-positive. adj.
-Appertaining to positive electrification; thus potassium is the most
-electro-positive of the elements. (See Electro-negative.)
-
-
-Electro-puncture.
-The introduction into the system of a platinum point or needle,
-insulated with vulcanite, except near its point, and connected as the
-anode of a galvanic battery. The kathode is a metal one, covered with a
-wet sponge and applied on the surface near the place of puncture. It is
-used for treatment of aneurisms or diseased growths, and also for
-removal of hair by electrolysis. (See Hair, Removal of by Electrolysis.)
-
-Synonym--Galvano-puncture.
-
-
-Electro-receptive. adj.
-A term applied to any device or apparatus designed to receive and absorb
-electric energy. A motor is an example of an electro-receptive
-mechanism.
-
-
-Electroscope.
-An apparatus for indicating the presence of an electric charge, and also
-for determining the sign, or whether the charge is positive or negative.
-The simplest form consists of a thread doubled at its centre and hung
-therefrom. On being charged, or on being connected to a charged body the
-threads diverge. A pair of pith balls may be suspended in a similar way,
-or a couple of strips of gold leaf within a flask (the gold leaf
-electroscope). To use an electroscope to determine the sign of the
-charge it is first slightly charged. The body to be tested is then
-applied to the point of suspension, or other charging point. If at once
-further repelled the charge of the body is of the same sign as the
-slight charge first imparted to the electroscope leaves; the leaves as
-they become more excited will at once diverge more. If of different sign
-they will at first approach as their charge is neutralized and will
-afterwards diverge.
-
-The gold-leaf electroscope is generally enclosed in a glass bell jar or
-flask. Sometimes a pair of posts rise, one on each side, to supply
-points of induction from the earth to intensify the action. (See
-Electrometer, Quadrant--Electroscope, Gold leaf, and others.)
-
-
-233  STANDARD ELECTRICAL DICTIONARY.
-
-
-Electroscope, Bennett's.
-A gold-leaf electroscope, the suspended leaves of which are contained in
-a glass shade or vessel of dry air. On the inside of the glass shade are
-two strips of gold leaf, which rise from the lower edge a short
-distance, being pasted to the glass, and connected to the ground. These
-act by induction to increase the sensitiveness of the instruments.
-
-
-Electroscope, Bohenberger's.
-A condensing electroscope (see Electroscope, Condensing) with a single
-strip of gold leaf suspended within the glass bell. This is at an equal
-distance from the opposite poles of two dry piles (see Zamboni's Dry
-Pile) standing on end, one on each side of it. As soon as the leaf is
-excited it moves toward one and away from the other pile, and the sign
-of its electrification is shown by the direction of its motion.
-
-
-Electroscope, Condensing.
-A gold leaf electroscope, the glass bell of which is surmounted by an
-electrophorous or static condenser, to the lower plate of which the
-leaves of gold are suspended or connected.
-
-In use the object to be tested is touched to the lower plate, and the
-upper plate at the same time is touched by the finger. The plates are
-now separated. This reduces the capacity of the lower plate greatly and
-its charge acquires sufficient potential to affect the leaves, although
-the simple touching may not have affected them at all.
-
-
-Electroscope, Gold Leaf.
-An electroscope consisting of two leaves of gold leaf hung in contact
-with each other from the end of a conductor. When excited they diverge.
-The leaves are enclosed in a glass vessel.
-
-
-Fig. 160. GOLD LEAF ELECTROSCOPE.
-
-
-234   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electroscope, Pith Ball.
-Two pith balls suspended at opposite ends of a silk thread doubled in
-the middle. When charged with like electricity they repel each other.
-The extent of their repulsion indicates the potential of their charge.
-
-
-Electrostatic Attraction and Repulsion.
-The attraction and repulsion of electrostatically charged bodies for
-each other, shown when charged with electricity. If charged with
-electricity of the same sign they repel each other. If with opposite
-they attract each other. The classic attraction and subsequent repulsion
-of bits of straw and chaff by the excited piece of amber is a case of
-electrostatic attraction and repulsion. (See Electricity,
-Static--Electrostatics--Coulomb's Laws of Electrostatic Attraction and
-Repulsion.)
-
-
-Electrostatic Induction, Coefficient of.
-The coefficient expressing the ratio of the charge or change of charge
-developed in one body to the potential of the inducing body.
-
-
-Electrostatic Lines of Force.
-Lines of force assumed to exist in an electrostatic field of force, and
-to constitute the same. In general they correspond in action and
-attributes with elcctro-magnetic lines of force. They involve in almost
-all cases either a continuous circuit, or a termination at both ends in
-oppositely charged surfaces.
-
-
-Fig. 161. ELECTROSTATIC LINES OF FORCE BETWEEN NEAR SURFACES.
-
-
-Fig. 162. ELECTROSTATIC LINKS OF FORCE BETWEEN DISTANT SURFACES.
-
-
-235   STANDARD ELECTRICAL DICTIONARY.
-
-
-The cut, Fig. 161, shows the general course taken by lines of force
-between two excited surfaces when near together. Here most of them are
-straight lines reaching straight across from surface to surface, while a
-few of them arch across from near the edges, tending to spread. If the
-bodies are drawn apart the spreading tendency increases and the
-condition of things shown in the next cut, Fig. 162, obtains. There is
-an axial line whose prolongations may be supposed to extend
-indefinitely, as occupying a position of unstable equilibrium. Here the
-existence of a straight and unterminated line of force may be assumed.
-
-A direction is predicated to lines of force corresponding with the
-direction of an electric current. They are assumed to start from a
-positively charged and to go towards a negatively charged surface. A
-positively charged body placed in an electrostatic field of force will
-be repelled from the region of positive into or towards the region of
-negative potential following the direction of the lines of force, not
-moving transversely to them, and having no transverse component in its
-motion.
-
-[Transcriber's note: More precisely, "A positively charged body placed
-in an electrostatic field of force will be repelled from the region of
-positive into or towards the region of negative potential ACCELERATING
-in the direction of the lines of force, not ACCELERATING transversely to
-them, and having no transverse component in its ACCELERATION."
-Previously acquired momentum can produce a transverse component of
-VELOCITY.]
-
-
-Electrostatics.
-The division of electric science treating of the phenomena of electric
-charge, or of electricity in repose, as contrasted with electro-dynamics
-or electricity in motion or in current form. Charges of like sign repel,
-and of unlike sign attract each other. The general inductive action is
-explained by the use of the electrostatic field of force and
-electrostatic lines of force, q. v. The force of attraction and
-repulsion of small bodies or virtual points, which are near enough to
-each other, vary as the square of the distance nearly, and with the
-product of the quantities of the charges of the two bodies.
-
-
-Electrostatic Refraction.
-Dr. Kerr found that certain dielectrics exposed to electric strain by
-being placed between two oppositely excited poles of a Holtz machine or
-other source of very high tension possess double refracting powers, in
-other words can rotate a beam of polarized light, or can develop two
-complimentary beams from common light. Bisulphide of carbon shows the
-phenomenon well, acting as glass would if the glass were stretched in
-the direction of the electrostatic lines of force. To try it with glass,
-holes are drilled in a plate and wires from an influence machine are
-inserted therein. The discharge being maintained through the glass it
-polarizes light.
-
-Synonym--Kerr Effect.
-
-
-Electrostatic Series.
-A table of substances arranged in the order in which they are
-electrostatically charged by contact, generally by rubbing against each
-other. The following series is due to Faraday. The first members become
-positively excited when rubbed with any of the following members, and
-vice versa. The first elements correspond to the carbon plate in a
-galvanic battery, the succeeding elements to the zinc plate.
-
-Cat, and Bear-skin--Flannel--Ivory--Feathers--Rock Crystal--Flint
-Glass--Cotton--Linen--Canvas--White Silk--the Hand--Wood--Shellac--the
-Metals (Iron-Copper-Brass-Tin-Silver-Platinum)--Sulphur. There are some
-irregularities. A feather lightly drawn over canvas is negatively
-electrified; if drawn through folds pressed against it it is positively
-excited. Many other exceptions exist, so that the table is of little
-value.
-
-
-236   STANDARD ELECTRICAL DICTIONARY.
-
-
-Electrostatic Stress.
-The stress produced upon a transparent medium in an electrostatic field
-of force by which it acquires double refracting or polarizing properties
-as regards the action of such medium upon light. (See Electrostatic
-Refraction.)
-
-
-Electro-therapeutics or Therapy.
-The science treating of the effects of electricity upon the animal
-system in the treatment and diagnosis of disease.
-
-
-Electrotonus.
-An altered condition of functional activity occurring in a nerve
-subjected to the passage of an electric current. If the activity is
-decreased, which occurs near the anode, the state is one of
-anelectrotonus, if the activity is increased which occurs near the
-kathode the condition is one of kathelectrotonus.
-
-
-Electrotype.
-The reproduction of a form of type or of an engraving or of the like by
-electroplating, for printing purposes. The form of type is pressed upon
-a surface of wax contained in a shallow box. The wax is mixed with
-plumbago, and if necessary some more is dusted and brushed over its
-surface and some iron dust is sprinkled over it also. A matrix or
-impression of the type is thus obtained, on which copper is deposited by
-electroplating, q. v.
-
-
-Element, Chemical.
-The original forms of matter that cannot be separated into constituents
-by any known process. They are about seventy in number. Some of the
-rarer ones are being added to or cancelled with the progress of chemical
-discovery. For their electric relations see Electro-chemical
-Equivalents--Electro-chemical Series.
-
-The elements in entering into combination satisfy chemical affinity and
-liberate energy, which may take the form of electric energy as in the
-galvanic battery, or of heat energy, as in the combustion of carbon or
-magnesium. Therefore an uncombined element is the seat of potential
-energy. (See Energy, Potential.) In combining the elements always
-combine in definite proportions. A series of numbers, one being proper
-to each element which denote the smallest common multipliers of these
-proportions, are called equivalents. Taking the theory of valency into
-consideration the product of the equivalents by the valencies gives the
-atomic weights.
-
-
-237   STANDARD ELECTRICAL DICTIONARY.
-
-
-Element, Mathematical.
-A very small part of anything, corresponding in a general way to a
-differential, as the element of a current.
-
-
-Element of a Battery Cell.
-The plates in a galvanic couple are termed elements, as the carbon and
-zinc plates in a Bunsen cell. The plate unattacked by the solution, as
-the carbon plate in the above battery, is termed the negative plate or
-element; the one attacked, as the zinc plate, is termed the positive
-plate or element.
-
-Synonym--Voltaic Element.
-
-
-Elements, Electrical Classification of.
-This may refer to Electro-chemical Series, Electrostatic Series, or
-Thermo-electric Series, all of which may be referred to.
-
-
-Element, Thermo-electric.
-One of the metals or other conductors making a thermo-electric couple,
-the heating of whose junction produces electro-motive force and a
-current, if on closed circuit. The elements of a couple are respectively
-positive and negative, and most conductors can be arranged in a series
-according to their relative polarity. (See Thermo-electric Series.)
-
-
-Elongation.
-The throw of the magnetic needle. (See Throw.)
-
-Synonym--Throw.
-
-
-Embosser, Telegraph.
-A telegraphic receiver giving raised characters on a piece of paper. It
-generally refers to an apparatus of the old Morse receiver type, one
-using a dry point stylus, which pressing the paper into a groove in the
-roller above the paper, gave raised characters in dots and lines.
-
-
-Fig. 163. MORSE RECEIVER.
-
-
-238   STANDARD ELECTRICAL DICTIONARY.
-
-
-E. M. D. P.
-Abbreviation for "electro-motive difference of potential" or for
-electro-motive force producing a current as distinguished from mere
-inert potential difference.
-
-E. M. F.
-Abbreviation for "electro-motive force."
-
-
-Fig. 164. END-ON METHOD.
-
-
-End-on Method.
-A method of determining the magnetic moment of a magnet. The magnet
-under examination, N S, is placed at right angles to the magnetic
-meridian, M O R, and pointing directly at or "end on" to the centre of a
-compass needle, n s. From the deflection a of the latter the moment is
-calculated.
-
-
-Endosmose, Electric.
-The inflowing current of electric osmose. (See Osmose, Electric.)
-
-
-End Play.
-The power to move horizontally in its bearings sometimes given to
-armature shafts. This secures a more even wearing of the commutator
-faces. End play is not permissible in disc armatures, as the attraction
-of the field upon the face of the armature core would displace it
-endwise. For such armatures thrust-bearings preventing end play have to
-be provided.
-
-
-Energy.
-The capacity for doing work. It is measured by work units which involve
-the exercise of force along a path of some length. A foot-pound,
-centimeter-gram, and centimeter-dyne are units of energy and work.
-
-The absolute unit of energy is the erg, a force of one dyne exercised
-over one centimeter of space. (See Dyne.)
-
-The dimensions of energy are
-  force (M * L / T^2) * space (L) = M * (L^2 / T^2).
-Energy may be chemical (atomic or molecular), mechanical,
-electrical, thermal, physical, potential, kinetic, or actual, and other
-divisions could be formulated.
-
-
-239   STANDARD ELECTRICAL DICTIONARY.
-
-
-Energy, Atomic.
-The potential energy due to atomic relations set free by atomic change;
-a form of chemical energy, because chemistry refers to molecular as well
-as to atomic changes. When atomic energy loses the potential form it
-immediately manifests itself in some other form, such as heat or
-electric energy. It may be considered as always being potential energy.
-(See Energy, Chemical.)
-
-[Transcriber's note: This item refers to chemical energy, that is
-manifest in work done by electric forces during re-arrangement of
-electrons. Atomic energy now refers to re-arrangement of  nucleons
-(protons and neutrons) and the resulting conversion of mass into
-energy.]
-
-
-Energy, Chemical.
-A form of potential energy (see Energy, Potential) possessed by elements
-in virtue of their power of combining with liberation of energy, as in
-the combination of carbon with oxygen in a furnace; or by compounds in
-virtue of their power of entering into other combinations more
-satisfying to the affinities of their respective elements or to their
-own molecular affinity. Thus in a galvanic couple water is decomposed
-with absorption of energy, but its oxygen combines with zinc with
-evolution of greater amount of energy, so that in a voltaic couple the
-net result is the setting free of chemical energy, which is at once
-converted into electrical energy in current form, if the battery is on a
-closed circuit.
-
-
-Energy, Conservation of.
-A doctrine accepted as true that the sum of energy in the universe is
-fixed and invariable. This precludes the possibility of perpetual
-motion. Energy may be unavailable to man, and in the universe the
-available energy is continually decreasing, but the total energy is the
-same and never changes.
-
-[Transcriber's note: If mass is counted a energy (E=m*(c^2)) then energy
-is strictly conserved.]
-
-
-Energy, Degradation of.
-The reduction of energy to forms in which it cannot be utilized by man.
-It involves the reduction of potential energy to kinetic energy, and the
-reduction of kinetic energy of different degrees to energy of the same
-degree. Thus when the whole universe shall have attained the same
-temperature its energy will have become degraded or non-available. At
-present in the sun we have a source of kinetic energy of high degree, in
-coal a source of potential energy. The burning of all the coal will be
-an example of the reduction of potential to kinetic energy, and the
-cooling of the sun will illustrate the lowering in degree of kinetic
-energy. (See Energy, Conservation of--Energy, Potential--Energy,
-Kinetic.)
-
-
-Energy, Electric.
-The capacity for doing work possessed by electricity
-under proper conditions. Electric energy may be either kinetic or
-potential. As ordinary mechanical energy is a product of force and
-space, so electric energy is a product of potential difference and
-quantity. Thus a given number of coulombs of electricity in falling a
-given number of volts develop electric energy. The dimensions are found
-therefore by multiplying electric current intensity quantity
-  ((M^.5) * (L^.5)),
-by electric potential
-  ((M^.5)*(L^1.5) / (T^2)),
-giving (M * (L^2)/(T^2)),
-the dimensions of energy in general as it should be.
-
-The absolute unit of electric energy in electro-magnetic measure is
-(1E-7) volt coulombs.
-
-
-240   STANDARD ELECTRICAL DICTIONARY.
-
-
-The practical unit is the volt-coulomb. As the volt is equal to 1E8
-absolute units of potential and the coulomb to 0.1 absolute units of
-quantity, the volt-coulomb is equal to 1E7 absolute units of energy.
-
-The volt-coulomb is very seldom used, and the unit of Electric Activity
-or Power (see Power, Electric), the volt-ampere, is universally used.
-This unit is sometimes called the Watt, q. v., and it indicates the rate
-of expenditure or of production of electric energy.
-
-The storing up in a static accumulator or condenser of a given charge of
-electricity, available for use with a given change of potential
-represents potential electric energy.
-
-The passing of a given quantity through a conductor with a given fall of
-potential represents kinetic electric energy.
-
-In a secondary battery there is no storage of energy, but the charging
-current simply accumulates potential chemical energy in the battery,
-which chemical energy is converted into electric energy in the discharge
-or delivery of the battery.
-
-It is customary to discuss Ohm's law in this connection; it is properly
-treated under Electric Power, to which the reader is referred. (See
-Power, Electric.)
-
-[Transcriber's note: A volt-ampere or watt is a unit of power. A
-volt-coulomb second or watt-second is a unit of energy. Power multiplied
-by time yields energy.]
-
-
-Energy, Electric Transmission of.
-If an electric current passes through a conductor all its energy is
-expended in the full circuit. Part of the circuit may be an electrical
-generator that supplies energy as fast as expended. Part of the circuit
-may be a motor which absorbs part of the energy, the rest being expended
-in forcing a current through the connecting wires and through the
-generator. The electric energy in the generator and connecting wires is
-uselessly expended by conversion into heat. That in the motor in great
-part is utilized by conversion into mechanical energy which can do
-useful work. This represents the transmission of energy. Every electric
-current system represents this operation, but the term is usually
-restricted to the transmission of comparatively large quantities of
-energy.
-
-A typical installation might be represented thus. At a waterfall a
-turbine water wheel is established which drives a dynamo. From the
-dynamo wires are carried to a distant factory, where a motor or several
-motors are established, which receive current from the dynamo and drive
-the machinery. The same current, if there is enough energy, may be used
-for running lamps or electroplating. As electric energy (see Energy,
-Electric,) is measured by the product of potential difference by
-quantity, a very small wire will suffice for the transmission of a small
-current at a high potential, giving a comparatively large quantity of
-energy. It is calculated that the energy of Niagara Falls could be
-transmitted through a circuit of iron telegraph wire a distance of over
-1,000 miles, but a potential difference of 135,000,000 volts would be
-required, something quite impossible to obtain or manage.
-
-[Transcriber's note: Contemporary long distance power transmission lines
-use 115,000 to 1,200,000 volts. At higher voltages corona discharges
-(arcing) create unacceptable losses.]
-
-
-241  STANDARD ELECTRICAL DICTIONARY.
-
-
-Energy, Kinetic.
-Energy due to matter being actually in motion. It is sometimes called
-actual energy. The energy varies directly with the mass and with the
-square of the velocity. It is represented in formula by .5 *M * (v^2).
-
-Synonyms--Actual Energy--Energy of Motion--Dynamic Energy.
-
-
-Energy, Mechanical.
-The energy due to mechanical change or motion, virtually the same as
-molar energy. (See Energy, Molar.)
-
-
-Energy, Molar.
-The energy of masses of matter due to movements of or positions of
-matter in masses; such as the kinetic energy of a pound or of a ton in
-motion, or the potential energy of a pound at an elevation of one
-hundred feet.
-
-
-Energy, Molecular.
-The potential energy due to the relations of molecules and set free by
-their change in the way of combination. It is potential for the same
-reason that applies to atomic and chemical energy, of which latter it is
-often a form, although it is often physical energy. The potential energy
-stored up in vaporization is physical and molecular energy; the
-potential energy stored up in uncombined potassium oxide and water, or
-calcium oxide (quicklime) and water is molecular, and when either two
-substances are brought together kinetic, thermal or heat energy is set
-free, as in slaking lime for mortar.
-
-
-Energy of an Electrified Body.
-An electrified body implies the other two elements of a condenser. It is
-the seat of energy set free when discharged. (See Dielectric, Energy
-of.) The two oppositely charged bodies tend to approach. This tendency,
-together with the distances separating them, represents a potential
-energy.
-
-
-Energy of Stress.
-Potential energy due to stress, as the stretching of a spring. This is
-hardly a form of potential energy. A stressed spring is merely in a
-position to do work at the expense of its own thermal or kinetic energy
-because it is cooled in doing work. If it possessed true potential
-energy of stress it would not be so cooled.
-
-
-Energy of Position.
-Potential energy due to position, as the potential energy of a pound
-weight raised ten feet (ten foot lbs.). (See Energy, Potential.)
-
-
-Energy, Physical.
-The potential energy stored up in physical position or set free in
-physical change. Thus a vapor or gas absorbs energy in its vaporization,
-which is potential energy, and appears as heat energy when the vapor
-liquefies.
-
-
-242   STANDARD ELECTRICAL DICTIONARY.
-
-
-Energy, Potential, or Static Energy.
-The capacity for doing work in a system due to advantage of position or
-other cause, such as the stress of a spring. A pound weight supported
-ten feet above a plane has ten foot lbs. of potential energy of position
-referred to that plane. A given weight of an elementary substance
-represents potential chemical energy, which will be liberated as actual
-energy in its combination with some other element for which it has an
-affinity. Thus a ton of coal represents a quantity of potential chemical
-energy which appears in the kinetic form of thermal energy when the coal
-is burning in a furnace. A charged Leyden jar represents a source of
-potential electric energy, which becomes kinetic heat energy as the same
-is discharged.
-
-
-Energy, Thermal.
-A form of kinetic molecular energy due to the molecular motion of bodies
-caused by heat.
-
-
-Entropy.
-Non-available energy. As energy may in some way or other be generally
-reduced to heat, it will be found that the equalizing of temperature,
-actual and potential, in a system, while it leaves the total energy
-unchanged, makes it all unavailable, because all work represents a fall
-in degree of energy or a fall in temperature. But in a system such as
-described no such fall could occur, therefore no work could be done. The
-universe is obviously tending in that direction. On the earth the
-exhaustion of coal is in the direction of degradation of its high
-potential energy, so that the entropy of the universe tends to zero.
-(See Energy, Degradation of.)
-
-[Transcriber's note: Entropy (disorder) INCREASES, while AVAILABLE
-ENERGY tends to zero.]
-
-
-Entropy, Electric.
-Clerk Maxwell thought it possible to recognize in the Peltier effect, q.
-v., a change in entropy, a gain or loss according to whether the
-thermo-electric junction was heated or cooled. This is termed Electric
-Entropy. (See Energy, Degradation of.)
-
-
-243  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 165. EPINUS' CONDENSER,
-
-
-Epinus' Condenser.
-Two circular brass plates, A and B, are mounted on insulating supports,
-and arranged to be moved towards or away from each other as desired.
-Between them is a plate of glass, C, or other dielectric. Pith balls may
-be suspended back of each brass plate as shown. The apparatus is charged
-by connecting one plate to an electric machine and the other to the
-earth. The capacity of the plate connected to the machine is increased
-by bringing near to it the grounded plate, by virtue of the principle of
-bound charges. This apparatus is used to illustrate the principles of
-the electric condenser. It was invented after the Leyden jar was
-invented.
-
-
-Fig. 166. EPINUS' CONDENSER.
-
-
-E. P. S.
-Initials of Electrical Power Storage; applied to a type of secondary
-battery made by a company bearing that title.
-
-
-Fig. 167. CAM EQUALIZER.
-
-
-244   STANDARD ELECTRICAL DICTIONARY.
-
-Equalizer.
-In electro-magnetic mechanism an arrangement for converting the pull of
-the electro-magnet varying in intensity greatly over its range of
-action, into a pull of sensibly equal strength throughout. The use of a
-rocking lever acting as a cam, with leverage varying as the armature
-approaches or recedes from the magnet core is one method of effecting
-the result. Such is shown in the cut. E is an electro-magnet, with
-armature a. A and B are the equalizer cams. The pull on the short end of
-the cam B is sensibly equal for its whole length.
-
-Many other methods have been devised, involving different shapes of pole
-pieces, armatures or mechanical devices other than the one just shown.
-
-
-Equipotential. adj.
-Equal in potential; generally applied to surfaces. Thus every magnetic
-field is assumed to be made up of lines of force and intersecting those
-lines, surfaces, plane, or more or less curved in contour, can be
-determined, over all parts of each one of which the magnetic intensity
-will be identical. Each surface is the locus of equal intensity. The
-same type of surface can be constructed for any field of force, such as
-an electrostatic field, and is termed an equipotential surface.
-
-
-Equipotential Surface, Electrostatic.
-A surface in an electrostatic field of force, which is the locus of all
-points of a given potential in such field; a surface cutting all the
-lines of force at a point of identical potential. Lines of force are cut
-perpendicularly by an equipotential surface, or are normal thereto.
-
-
-Equipotential Surface, Magnetic and Electro-magnetic.
-A surface bearing the same relation to a magnetic or electro-magnetic
-field of force that an electrostatic equipotential surface (see
-Equipotential Surface, Electrostatic,) does to an electrostatic field of
-force.
-
-
-Equivalent, Chemical.
-The quotient obtained by dividing the atomic weight of an element by its
-valency.
-
-
-Equivalents, Electro-chemical.
-The weight of any substance set free by one coulomb of electricity. The
-following give some equivalents expressed in milligrams:
-
-Hydrogen            .0105    Mercury (mercurous)   2.10
-Gold                .6877    Iron (ferric)          .1964
-Silver             1.134     Iron (ferrous)         .294
-Copper (cupric)     .3307    Nickel                 .3098
-Mercury (mercuric) 1.05      Zinc                   .3413
-Lead               1.0868    Chlorine               .3728
-Oxygen              .89
-
-
-245   STANDARD ELECTRICAL DICTIONARY.
-
-
-Equivalent, Electro-mechanical.
-The work or energy equivalent to unit quantities of electric energy, q.
-v.; or equivalent to a unit current in a conductor whose ends differ one
-unit of potential. The unit of electric energy taken is the watt-second
-or volt-coulomb. One volt-coulomb is equal to
-  Ergs                  1E7   [10000000]
-  Foot Pound           .737337
-  Gram-degree C.       .24068
-  Horse Power Second   .0013406
-  Pound-degree F.      .000955
-  One horse power is equal to 745.943 volt coulombs per second.
-
-
-Equivalent, Electro-thermal.
-The heat produced by a unit current passing through a conductor with
-unit difference of potential at its ends; the heat equivalent of a
-volt-coulomb or watt-second. It is equal to
-  Gram-degree C.   .24068
-  Pound-degree F.  .000955
-
-
-Equivalent, Thermo-chemical.
-The calories evolved by the combination of one gram of any substance
-with its equivalent of another substance being determined, the product
-obtained by multiplying this number by the equivalent (atomic or
-molecular weight / valency) of the first element or substance is the
-thermo-chemical equivalent. If expressed in kilogram calories, the
-product of the thermo-chemical equivalent by 0.43 gives the voltage
-required to effect such decomposition.
-
-The following are thermo-chemical equivalents of a few combinations:
-  Water                34.5
-  Zinc oxide           43.2
-  Iron protoxide       34.5
-  Iron Sesquioxide     31.9 X 3
-  Copper oxide         19.2
-
-
-Equivolt.
-"The mechanical energy of one volt electro-motive force exerted under
-unit conditions through one equivalent of chemical action in grains."
-(J. T. Sprague.) This unit is not in general use as the unit of electric
-energy, the volt-coulomb and (for rate of electric energy) the
-volt-ampere being always used.
-
-
-Erg.
-The absolute or fundamental C. G. S. unit of work or energy. The work
-done or energy expended in moving a body through one centimeter against
-a resistance of one dyne.
-
-
-Erg-ten.
-Ten millions of ergs, or ten meg-ergs.
-
-
-Escape.
-A term applied to leakage of current.
-
-
-Etching, Electric.
-A process of producing an etched plate. The plate is coated with wax,
-and the design traced through as in common etching. It is then placed in
-a bath and is connected to the positive terminal from a generator, whose
-negative is immersed in the same bath, so that the metal is dissolved by
-electrolytic action. By attaching to the other terminal and using a
-plating bath, a rough relief plate may be secured, by deposition in the
-lines of metal by electroplating.
-
-Synonym--Electric Engraving.
-
-
-246   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ether.
-The ether is a hypothetical thing that was invented to explain the
-phenomena of light. Light is theoretically due to transverse vibrations
-of the ether. Since the days of Young the conception of the ether has
-extended, and now light, "radiant heat," and electricity are all treated
-as phenomena of the ether. Electrical attraction and repulsion are
-explained by considering them due to local stresses in the ether;
-magnetic phenomena as due to local whirlpools therein. The ether was
-originally called the luminiferous ether, but the adjective should now
-be dropped. Its density is put at 936E-21 that of water, or equal to
-that of the atmosphere at 210 miles above the earth's surface. Its
-rigidity is about 1E-9 that of steel (see Ten, Powers of); as a whole it
-is comparable to an all-pervading jelly, with almost perfect elasticity.
-The most complete vacuum is filled with ether.
-
-All this is a hypothesis, for the ether has never been proved to exist.
-Whether gravitation will ever be explained by It remains to be seen.
-
-[Transcriber's note: The Michelson-Morley experiment in 1887 (five years
-before this book) cast serious doubt on the ether. In 1905 Einstein
-explained electromagnetic phenomenon with photons. In 1963 Edward M.
-Purcell used special relativity to derive the existence of magnetism and
-radiation.]
-
-
-Eudiometer.
-A graduated glass tube for measuring the volumes of gases. In its
-simplest form it is simply a cylindrical tube, with a scale etched or
-engraved upon it, closed at one end and open at the other. The gas to be
-measured is collected in it over a liquid, generally water, dilute
-sulphuric acid in the gas voltameter, or mercury. Many different shapes
-have been given them by Hoffmann, Ure, Bunsen and others.
-
-
-Evaporation, Electric.
-The superficial sublimation or evaporation of a substance under the
-influence of negative electricity. It is one of the effects investigated
-by Crookes in his experiments with high vacua. He found that when a
-metal, even so infusible as platinum, was exposed to negative
-electrification in one of his high vacuum tubes, that it was volatilized
-perceptibly. A cadmium electrode heated and electrified negatively was
-found to give a strong coating of metal on the walls of the tube. Even
-in the open air the evaporation of water was found to be accelerated by
-negative electrification.
-
-
-Exchange, Telephone.
-The office to which telephone wires lead in a general telephone system.
-In the office by a multiple switch board, or other means, the different
-telephones are interconnected by the office attendants, so that any
-customers who desire it may be put into communication with each other.
-The exchange is often termed the Central Office, although it may be only
-a branch office.
-
-
-Excitability, Faradic.
-The action produced in nerve or muscle of the animal system by an
-alternating or intermitting high potential discharge from an induction
-coil.
-
-
-247   STANDARD ELECTRICAL DICTIONARY.
-
-
-Excitability, Galvanic.
-The same as Faradic excitability, except that it refers to the effects
-of the current from a galvanic battery.
-
-
-Excitability of Animal System, Electric.
-The susceptibility of a nerve or muscle to electric current shown by the
-effect produced by its application.
-
-
-Exciter.
-A generator used for exciting the field magnet of a dynamo. In
-alternating current dynamos, e. g., of the Westinghouse type, a special
-dynamo is used simply to excite the field magnet. In central station
-distribution the same is often done for direct current dynamos.
-
-
-Exosmose, Electric.
-The outflowing current of electric osmose. (See Osmose, Electric.)
-
-
-Expansion, Coefficient of.
-The number expressing the proportional increase in size, either length,
-area or volume, of a substance under the influence generally of heat.
-There are three sets of coefficients, (1) of linear expansion, (2) of
-superficial expansion, (3) of cubic expansion or expansion of volume.
-The first and third are the only ones much used. They vary for different
-substances, and for the same substance at different temperatures. They
-are usually expressed as decimals indicating the mixed number referred
-to the length or volume of the body at the freezing point as unity.
-
-
-Expansion, Electric.
-(a) The increase in volume of a condenser, when charged
-electrostatically. A Leyden jar expands when charged, and contracts when
-discharged.
-
-(b) The increase in length of a bar of iron when magnetized.
-
-This is more properly called magnetic expansion or magnetic elongation.
-
-
-Exploder.
-(a) A small magneto-generator for producing a current for heating the
-wire in an electric fuse of the Abel type (see Fuse, Electric), and
-thereby determining an explosion.
-
-(b) The term may also be applied to a small frictional or influence
-machine for producing a spark for exploding a spark fuse.
-
-
-Explorer.
-A coil, similar to a magnetizing coil (see Coil, Magnetizing), used for
-investigating the electro-magnetic circuit and for similar purposes. If
-placed around an electro-magnet and connected with a galvanometer, it
-will produce a deflection, owing to a momentary induced current, upon
-any change in the magnet, such as removing or replacing the armature. It
-is useful in determining the leakage of lines of force and for general
-investigations of that nature. It is often called an exploring coil.
-Hughes' Induction Balance (see Induction Balance, Hughes') is sometimes
-called a Magnetic Explorer. The exploring coil may be put in circuit
-with a galvanometer for quantitative measurements or with a telephone
-for qualitative ones.
-
-
-248   STANDARD ELECTRICAL DICTIONARY.
-
-
-Extension Bell Call.
-A system of relay connection, q. v., by which a bell is made to continue
-ringing after the current has ceased coming over the main line. It is
-designed to prolong the alarm given by a magneto call bell, q. v., which
-latter only rings as long as the magneto handle is turned. A vibrating
-electric bell (see Bell, Electric,) is connected in circuit with a local
-battery and a switch normally open, but so constructed as to close the
-circuit when a current is passed and continue to do so indefinitely. The
-distant circuit is connected to this switch. When the magneto is worked
-it acts upon the switch, closes the local battery circuit and leaves it
-closed, while the bell goes on ringing until the battery is exhausted or
-the switch is opened by hand.
-
-
-Eye, Electro-magnetic.
-An apparatus used in exploring a field of electro-magnetic radiations.
-It is a piece of copper wire 2 millimeters (.08 inch) in diameter, bent
-into an almost complete circle 70 millimeters (.28 inch) in diameter,
-with terminals separated by an air gap. This is moved about in the
-region under examination, and by the production of a spark indicates the
-locality of the loops or venters in systems of stationary waves.
-
-
-F.
-Abbreviation for Fahrenheit, as 10� F., meaning 10� Fahrenheit. (See
-Fahrenheit Scale.)
-
-
-Fahrenheit Scale.
-A thermometer scale in use in the United States and England. On this
-scale the temperature of melting ice is 32�; that of condensing steam is
-212�; the degrees are all of equal length. Its use is indicated by the
-letter F., as 180� F. To convert its readings into centigrade, subtract
-32 and multiply by 5/9. (b) To convert centigrade into F. multiply by
-9/5 and add 32. Thus 180� F. = ((180-32) * 5/9)� C. = 82.2� C. Again
-180� C. = (180 * 9/5) + 32 = 324� F.
-
-[Transcribers note: 180� C. = (180 * 9/5) + 32 = 356� F. ]
-
-The additions and subtractions must be algebraic in all cases. Thus when
-the degrees are minus or below zero the rules for conversion might be
-put thus: To convert degrees F. below zero into centigrade to the number
-of degrees F. add 32, multiply by 5/9 and place a minus sign (-) before
-it. (b) To convert degrees centigrade below zero into Fahrenheit,
-multiply the number of degrees by 9/5, subtract from 32 if smaller; if
-greater than 32 subtract 32 therefrom, and prefix a minus sign, thus:
--10� C. = 32 - (10 * 9/5) = 14�. Again, -30�C. = (30 * 9/5) - 32 = 22 =
--22� F.
-
-
-249  STANDARD ELECTRICAL DICTIONARY.
-
-
-Farad.
-The practical unit of electric capacity; the capacity of a conductor
-which can retain one coulomb of electricity at a potential of one volt.
-
-The quantity of electricity charged upon a conducting surface raises its
-potential; therefore a conductor of one farad capacity can hold two
-coulombs at two volts potential, and three coulombs at three volts, and
-so on. The electric capacity of a conductor, therefore, is relative
-compared to others as regards its charge, for the latter may be as great
-as compatible with absence of sparking and disruptive discharge. In
-other words, a one farad or two farad conductor may hold a great many
-coulombs. Charging a conductor with electricity is comparable to pumping
-air into a receiver. Such a vessel may hold one cubic foot of air at
-atmospheric pressure and two at two atmospheres, and yet be of one cubic
-foot capacity however much air is pumped into it.
-
-The farad is equal to one fundamental electrostatic unit of capacity
-multiplied by 9E11 and to one electro-magnetic unit multiplied by 1E-9.
-
-The farad although one of the practical units is far too large, so the
-micro-farad is used in its place. The capacity of a sphere the size of
-the earth is only .000636 of a farad.
-
-[Transcriber's note: Contemporary calculations give about .000720
-farad.]
-
-
-Faraday, Effect.
-The effect of rotation of its plane produced upon a polarized beam of
-light by passage through a magnetic field. (See Magnetic Rotary
-Polarization.)
-
-
-Faraday's Cube.
-To determine the surface action of a charge, Faraday constructed a room,
-twelve feet cube, insulated, and lined with tinfoil. This room he
-charged to a high potential, but within it he could detect no excitement
-whatever. The reason was because the electricity induced in the bodies
-within the room was exactly equal to the charge of the room-surface, and
-was bound exactly by it. The room is termed Faraday's cube.
-
-
-Faraday's Dark Space.
-A non-luminous space between the negative and positive glows, produced
-in an incompletely exhausted tube through which a static discharge, as
-from an induction coil, is produced. It is perceptible in a rarefaction
-of 6 millimeters (.24 inch) and upwards. If the exhaustion is very high
-a dark space appears between the negative electrode and its discharge.
-This is known as Crookes' dark space.
-
-
-Faraday's Disc.
-A disc of any metal, mounted so as to be susceptible of rotation in a
-magnetic field of force, with its axis parallel to the general direction
-of the lines of force. A spring bears against its periphery and another
-spring against its axle. When rotated, if the springs are connected by a
-conductor, a current is established through the circuit including the
-disc and conductor. The radius of the disc between the spring contacts
-represents a conductor cutting lines of force and generating a potential
-difference, producing a current. If a current is sent through the
-motionless wheel from centre to periphery it rotates, illustrating the
-doctrine of reversibility. As a motor it is called Barlow's or
-Sturgeon's Wheel. If the disc without connections is rapidly rotated it
-produces Foucault currents, q. v., within its mass, which resist its
-rotation and heat the disc.
-
-
-250   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 168. "FARADAY'S NET."
-
-
-Faraday's Net.
-An apparatus for showing that the electric charge resides on the
-surface. It consists of a net, conical in shape and rather deep, to
-whose apex two threads, one on each side, are attached. Its mouth is
-fastened to a vertical ring and the whole is mounted on an insulating
-support.
-
-It is pulled out to its full extent and is electrified. No charge can be
-detected inside it. By pulling one of the threads it is turned with the
-other side out. Now all the charge is found on the outside just as
-before, except that it is of course on the former inside surface of the
-bag. The interior shows no charge.
-
-
-Faraday's Transformer.
-The first transformer. It was made by Michael Faraday. It was a ring of
-soft iron 7/8 inch thick, and 6 inches in external diameter. It was
-wound with bare wire, calico being used to prevent contact of the wire
-with the ring and of the layers of wire with each other, while twine was
-wound between the convolutions to prevent the wires from touching.
-Seventy-two feet of copper wire, 1/20 inch diameter, were wound in three
-superimposed coils, covering about one-half of the ring. On the other
-half sixty feet of copper wire were wound in two superimposed coils.
-Faraday connected his coils in different ways and used a galvanometer to
-measure the current produced by making and breaking one of the circuits
-used as a primary.
-
-The coil is of historic interest.
-
-
-Faraday's Voltameter.
-A voltameter, in which the coulombs of current are measured by the
-volume of the gas evolved from acidulated water. (See Voltameter, Gas.)
-
-
-Faradic. adj.
-Referring to induced currents, produced from induction coils. As Faraday
-was the original investigator of the phenomena of electro-magnetic
-induction, the secondary or induced electro-magnetic currents and their
-phenomena and apparatus are often qualified by the adjective Faradic,
-especially in electro-therapeutics. A series of alternating
-electrostatic discharges, as from an influence machine (Holtz), are
-sometimes called Franklinic currents. They are virtually Faradic, except
-as regards their production.
-
-
-251   STANDARD ELECTRICAL DICTIONARY.
-
-
-Faradic Brush.
-A brush for application of electricity to the person. It is connected as
-one of the electrodes of an induction coil or magneto generator. For
-bristles wire of nickel plated copper is generally employed.
-
-
-Faradization.
-In medical electricity the analogue of galvanization; the effects due to
-secondary or induced currents; galvanization referring to currents from
-a galvanic battery; also the process of application of such currents.
-
-
-Faults.
-Sources of loss of current or of increased resistance or other troubles
-in electric circuits.
-
-
-Feeder.
-A lead in an electric central station distribution system, which lead
-runs from the station to some point in the district to supply current.
-It is not used for any side connections, but runs direct to the point
-where current is required, thus "feeding" the district directly. In the
-two wire system a feeder may be positive or negative; in the three wire
-system there is also a neutral feeder. Often the term feeder includes
-the group of two or of three parallel lines.
-
-
-Feeder Equalizer.
-An adjustable resistance connected in circuit with a feeder at the
-central station. The object of the feeder being to maintain a definite
-potential difference at its termination, the resistance has to be varied
-according to the current it is called on to carry.
-
-
-Feeder, Main or Standard.
-The main feeder of a district. The standard regulation of pressure
-(potential difference between leads) in the district is often determined
-by the pressure at the end of the feeder.
-
-
-Feeder, Negative.
-The lead or wire in a set of feeders, which is connected to the negative
-terminal of the generator.
-
-
-Feeder, Neutral.
-In the three wire system the neutral wire in a set of feeders. It is
-often made of less diameter than the positive and negative leads.
-
-
-Feeder, Positive.
-The lead or wire in a set of feeders, which wire is connected to the
-positive terminal of the generator.
-
-
-Ferranti Effect.
-An effect as yet not definitely explained, observed in the mains of the
-Deptford, Eng., alternating current plant. It is observed that the
-potential difference between the members of a pair of mains rises or
-increases with the distance the place of trial is from the station.
-
-[Transcriber's note: This effect is due to the voltage drop across the
-line inductance (due to charging current) being in phase with the
-sending end voltages. Both capacitance and inductance are responsible
-for producing this phenomenon.  The effect is more pronounced in
-underground cables and with very light loads.]
-
-
-252  STANDARD ELECTRICAL DICTIONARY.
-
-
-Ferro-magnetic. adj.
-Paramagnetic; possessing the magnetic polarity of iron.
-
-
-Fibre and Spring Suspension.
-A suspension of the galvanometer needle used in marine galvanometers.
-The needle is supported at its centre of gravity by a vertically
-stretched fibre attached at both its ends, but with a spring
-intercalated between the needle and one section of the fibre.
-
-
-Fibre Suspension.
-Suspension, as of a galvanometer needle, by a vertical or hanging fibre
-of silk or cocoon fibre, or a quartz fibre. (See Quartz.)
-
-This suspension, while the most delicate and reliable known, is very
-subject to disturbance and exacts accurate levelling of the instrument.
-
-Fibre suspension is always characterized by a restitutive force. Pivot
-suspension, q. v., on the other hand, has no such force.
-
-
-Field, Air.
-A field the lines of force of which pass through air; the position of a
-field comprised within a volume of air.
-
-
-Field, Alternating.
-Polarity or direction being attributed to lines of force, if such
-polarity is rapidly reversed, an alternating field results. Such field
-may be of any kind, electro-magnetic or electrostatic. In one instance
-the latter is of interest. It is supposed to be produced by high
-frequency discharges of the secondary of an induction coil, existing in
-the vicinity of the discharging terminals.
-
-
-Field Density.
-Field density or density of field is expressed in lines of force per
-unit area of cross-section perpendicular to the lines of force.
-
-
-Field, Distortion of.
-The lines of force reaching from pole to pole of an excited field magnet
-of a dynamo are normally symmetrical with respect to some axis and often
-with respect to several. They go across from pole to pole, sometimes
-bent out of their course by the armature core, but still symmetrical.
-The presence of a mass of iron in the space between the pole pieces
-concentrates the lines of force, but does not destroy the symmetry of
-the field.
-
-When the armature of the dynamo is rotated the field becomes distorted,
-and the lines of force are bent out of their natural shape. The new
-directions of the lines of force are a resultant of the lines of force
-of the armature proper and of the field magnet. For when the dynamo is
-started the armature itself becomes a magnet, and plays its part in
-forming the field. Owing to the lead of the brushes the polarity of the
-armature is not symmetrical with that of the field magnets. Hence the
-compound field shows distortion. In the cut is shown diagrammatically
-the distortion of field in a dynamo with a ring armature. The arrow
-denotes the direction of rotation, and n n * * * and s s * * * indicate
-points of north and south polarity respectively.
-
-
-253  STANDARD ELECTRICAL DICTIONARY.
-
-
-The distorted lines must be regarded as resultants of the two induced
-polarities of the armature, one polarity due to the induction of the
-field, the other to the induction from its own windings. The positions
-of the brushes have much to do with determining the amount and degree of
-distortion. In the case of the ring armature it will be seen that some
-of the lines of force within the armature persist in their polarity and
-direction, almost as induced by the armature windings alone, and leak
-across without contributing their quota to the field. Two such lines are
-shown in dotted lines.
-
-In motors there is a similar but a reversed distortion.
-
-
-Fig. 169. DISTORTION OF FIELD IN A RING ARMATURE OF AN ACTIVE DYNAMO.
-
-
-Fig. 170. DISTORTION OF FIELD IN A RING ARMATURE OF AN ACTIVE MOTOR.
-
-
-254   STANDARD ELECTRICAL DICTIONARY.
-
-
-Field, Drag of.
-When a conductor is moved through a field so that a current is generated
-in it, the field due to that current blends with the other field and
-with its lines of force, distorting the field, thereby producing a drag
-upon its own motion, because lines of force always tend to straighten
-themselves, and the straightening would represent cessation of motion in
-the conductor. This tendency to straightening therefore resists the
-motion of the conductor and acts a drag upon it.
-
-
-Field of Force.
-The space in the neighborhood of an attracting or repelling mass or
-system. Of electric fields of force there are two kinds, the
-Electrostatic and the Magnetic Fields of Force, both of which may be
-referred to. A field of force may be laid out as a collection of
-elements termed Lines of Force, and this nomenclature is universally
-adopted in electricity. The system of lines may be so constructed that
-(a) the work done in passing from one equipotential surface to the next
-is always the same; or (b) the lines of force are so laid out and
-distributed that at a place in which unit force is exercised there is a
-single line of force passing through the corresponding equipotential
-surface in each unit of area of that surface. The latter is the
-universal method in describing electric fields. It secures the following
-advantages:--First: The potential at any point in the field of space
-surrounding the attracting or repelling mass or masses is found by
-determining on which imaginary equipotential surface that point lies.
-Second: If unit length of a line of force cross n equipotential
-surfaces, the mean force along that line along the course of that part
-of it is equal to n units; for the difference of potential of the two
-ends of that part of the line of force = n; it is also equal to F s (F
-= force), because it represents numerically a certain amount of work;
-but s = I, whence n = F. Third: The force at any part of the field
-corresponds to the extent to which the lines of force are crowded
-together; and thence it may be determined by the number of lines of
-force which pass through a unit of area of the corresponding
-equipotential surface, that area being so chosen as to comprise the
-point in question. (Daniell.)
-
-
-Field of Force, Electrostatic.
-The field established by the attracting, repelling and stressing
-influence of an electrostatically charged body. It is often termed an
-Electrostatic Field. (See Field of Force.)
-
-
-255   STANDARD ELECTRICAL DICTIONARY.
-
-
-Field of Force of a Current.
-A current establishes a field of force around itself, whose lines of
-force form circles with their centres on the axis of the current. The
-cut, Fig. 172, shows the relation of lines of force to current.
-
-
-Fig. 171. EXPERIMENT SHOWING LINES OF FORCE
-SURROUNDING AN ACTIVE CONDUCTOR.
-
-
-Fig. 172. DIAGRAM OF FIELD OF FORCE SURROUNDING AN ACTIVE CONDUCTOR.
-
-
-Fig. 173. LINK OF FORCE INDUCED BY A CURRENT SHOWING THE MAGNETIC WHIRLS.
-
-
-The existence of the field is easily shown by passing a conductor
-vertically through a horizontal card. On causing a current to go through
-the wire the field is formed, and iron filings dropped upon the card,
-tend, when the latter is gently tapped, to take the form of circles. The
-experiment gives a version of the well-known magnetic figures, q. v. See
-Fig. 171.
-
-The cut shows by the arrows the relation of directions of current to the
-direction of the lines of force, both being assumptions, and merely
-indicating certain fixed relations, corresponding exactly to the
-relations expressed by the directions of electro-magnetic or magnetic
-lines of force
-
-256   STANDARD ELECTRICAL DICTIONARY.
-
-
-Field, Pulsatory.
-A field produced by pulsatory currents. By induction such field can
-produce an alternating current.
-
-
-Field, Rotating.
-In a dynamo the field magnets are sometimes rotated instead of the
-armature, the latter being stationary. In Mordey's alternator the
-armature, nearly cylindrical, surrounds the field, and the latter
-rotates within it, the arrangement being nearly the exact reverse of the
-ordinary one. This produces a rotating field.
-
-
-Field, Rotatory.
-A magnetic field whose virtual poles keep rotating around its centre of
-figure. If two alternating currents differing one quarter period in
-phase are carried around four magnetizing coils placed and connected in
-sets of two on the same diameter and at right angles to each other, the
-polarity of the system will be a resultant of the combination of their
-polarity, and the resultant poles will travel round and round in a
-circle. In such a field, owing to eddy currents, masses of metal,
-journaled like an armature, will rotate, with the speed of rotation of
-the field.
-
-
-Field, Stray.
-The portion of a field of force outside of the regular circuit;
-especially applied to the magnetic field of force of dynamos expressing
-the portion which contributes nothing to the current generation.
-
-Synonym--Waste Field.
-
-
-Field, Uniform.
-A field of force of uniform density. (See Field Density.)
-
-
-Figure of Merit.
-In the case of a galvanometer, a coefficient expressing its delicacy. It
-is the reciprocal of the current required to deflect the needle through
-one degree. By using the reciprocal the smaller the current required the
-larger is the figure of merit. The same term may be applied to other
-instruments.
-
-It is often defined as the resistance of a circuit through which one
-Daniell's element will produce a deflection of one degree on the scale
-of the instrument. The circuit includes a Daniell's cell of resistance
-r, a rheostat R, galvanometer G and shunt S. Assume that with the shunt
-in parallel a deflection of a divisions is obtained. The resistance of
-the shunted galvanometer is (GS/G+S ; the multiplying power m of the
-shunt is S+G/S; the formula or figure of merit is m d (r+R +G S/G+S).
-
-The figure of merit is larger as the instrument is more sensitive.
-Synonym--Formula of Merit.
-
-
-257  STANDARD ELECTRICAL DICTIONARY.
-
-
-Filament.
-A thin long piece of a solid substance. In general it is so thin as to
-act almost like a thread, to be capable of standing considerable
-flexure. The distinction between filament and rod has been of much
-importance in some patent cases concerning incandescent lamps. As used
-by electricians the term generally applies to the carbon filament of
-incandescent lamps. This as now made has not necessarily any fibres, but
-is entitled to the name of filament, partly by convention, partly by its
-relative thinness and want of stiffness. (See Incandescent
-Lamps--Magnetic Filament.)
-
-
-Fire Alarm, Electric, Automatic.
-A system of telegraph circuits, at intervals supplied with thermostats
-or other apparatus affected by a change of temperature, which on being
-heated closes the circuit and causes a bell to ring. (See Thermostat.)
-
-
-Fire Alarm Telegraph System.
-A system of telegraphic lines for communicating the approximate location
-of a fire to a central station and thence to the separate fire-engine
-houses in a city or district. It includes alarm boxes, distributed at
-frequent intervals, locked, with the place where the key is kept
-designated, or in some systems left unlocked. On opening the door of the
-box and pulling the handle or otherwise operating the alarm, a
-designated signal is sent to the central station. From this it is
-telegraphed by apparatus worked by the central station operator to the
-engine houses. The engines respond according to the discipline of the
-service.
-
-
-Fire Cleansing.
-Freeing the surface of an article to be plated from grease by heating.
-
-
-Fire Extinguisher, Electric, Automatic.
-A modification of the electric fire alarm (see Fire Alarm, Electric,
-Automatic), in which the thermostats completing the circuits turn on
-water which, escaping through the building, is supposed to reach and
-extinguish a fire.
-
-
-Flashing in a Dynamo or Magneto-electric Generator.
-Bad adjustment of the brushes at the commutator, or other fault of
-construction causes the production of voltaic arcs at the commutator of
-a generator, to which the term flashing is applied.
-
-
-Flashing of Incandescent Lamp Carbons.
-A process of treatment for the filaments of incandescent lamps. The
-chamber before sealing up is filled with a hydro-carbon vapor or gas,
-such as the vapor of a very light naphtha (rhigolene). A current is then
-passed through the filament heating it to redness. The more attenuated
-parts or those of highest resistance are heated the highest, and
-decompose most rapidly the hydro-carbon vapor, graphitic carbon being
-deposited upon these parts, while hydrogen is set free. This goes on
-until the filament is of uniform resistance throughout. It gives also a
-way of making the resistance of the filament equal to any desired number
-of ohms, provided it is originally of high enough resistance. The
-process increases the conductivity of the filament.
-
-After flashing the chambers are pumped out and sealed up.
-
-
-258   STANDARD ELECTRICAL DICTIONARY.
-
-
-Flashing Over.
-A phenomenon observed in high potential dynamos. On a sudden alteration
-of the resistance of the circuit a long blue spark will be drawn out
-around the surface of the commutator from brush to brush. The spark is
-somewhat of the nature of an arc, and may seriously injure commutators
-whose sections are only separated by mica, or other thin insulation. In
-the case of commutators whose sections are separated by air spaces it is
-not so injurious.
-
-
-Flats.
-In a commutator of a dynamo, the burning or wearing away of a commutator
-segment to a lower level than the rest. Sometimes two adjacent bars will
-be thus affected, causing a flat place on the commutator. It is not
-always easy to account for the formation of flats. They may have their
-origin in periodic vibrations due to bad mounting, or to sparking at the
-particular point.
-
-
-Floor Push.
-A press or push button constructed to be set into the floor to be
-operated by pressing with the foot. It is used to ring an alarm bell,
-sound a buzzer or for similar service.
-
-
-Fluid, Depolarizing.
-A fluid used in voltaic batteries to dispose of the hydrogen, which goes
-to the negative plate. This it does by oxidizing it. Chromic acid,
-nitric acid, and chloric acids are among the constituents of liquid
-depolarizers. (See Electropoion Fluid.)
-
-
-Fluid, Electric.
-The electric current and charge have sometimes been attributed to a
-fluid. The theory, which never was much more than hypothetical, survives
-to some extent in the single and double fluid theory. (See Single Fluid
-Theory-Double Fluid Theory.)
-
-
-Fluorescence.
-The property of converting ether waves of one length, sometimes of
-invisible length, into waves of another length (visible). AEsculin,
-quinine salts, uranium glass and other substances exhibit this
-phenomenon. The phenomenon is utilized in the production of Geissler
-tubes.
-
-
-Flush Boxes.
-A heavy iron box covered with a heavy hand plate and laid flush (whence
-the name), or even with the surface of a roadway. Into it conductors of
-an underground system lead, and it is used to make connections therewith
-and for examining the leakage of the conductors and for similar
-purposes. It is a "man-hole" (q. v.) in miniature.
-
-Fluviograph.
-An electric registering tide gauge or water level gauge.
-
-
-259  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fly or Flyer, Electric.
-A little wheel, ordinarily poised on a point, like a compass needle. It
-carries several tangentially directed points, all pointing in the same
-sense. When connected with a source of electricity of high potential it
-revolves by reaction. The tension of its charge is highest at the
-points, the air there is highly electrified and repelled, the reaction
-pushing the wheel around like a Barker's mill or Hero's steam engine.
-Sometimes the flyer is mounted with its axis horizontal and across the
-rails on a railroad along which it travels.
-
-Synonym--Reaction Wheel.
-
-
-Foci Magnetic.
-The two points on the earth's surface where the magnetic intensity is
-greatest. They nearly coincide in position with the magnetic poles.
-
-
-Fog, Electric.
-Fogs occurring when the atmosphere is at unusually high potential and
-accompanied by frequent change of such polarity.
-
-
-Following Horns.
-In dynamo-electric machines the projecting ends of the pole pieces
-towards which the outer uncovered perimeter of the armature turns in its
-regular operations. The leading horns are those away from which the
-armature rotates. In considering rotation the exposed portion of the
-superficies of the armature is considered. The definition would have to
-be reversed if the part facing the pole pieces were considered.
-
-Synonym--Trailing Horns.
-
-
-Foot-candle.
-A unit of illuminating power; the light given by one standard candle at
-a distance of one foot. The ordinary units of illuminating power are
-entirely relative; this is definite. It is due to Carl Herring.
-
-
-Foot-pound.
-A practical unit of work or energy. The quantity of work required to
-raise a pound one foot, or one hundred pounds one-hundredth of a foot,
-and so on; or the potential energy represented by a weight at an
-elevation under these conditions.
-
-
-Foot-step.
-In a dynamo with armature at the lower end of its field magnets, the
-plate generally of zinc, interposed between it and the iron base plate
-to prevent the leakage of lines of force outside of the circuit. Any
-diamagnetic material which is mechanically suitable may be used.
-
-
-Force.
-Force may be variously defined.
-(a) Any cause of change of the condition of matter with respect to
-motion or rest.
-
-(b) A measurable action upon a body under which the state of rest of
-that body, or its state of uniform motion in a straight line, suffers
-change.
-
-(c) It may be defined by its measurement as the rate of change of
-momentum, or
-
-(d) as the rate at which work is done per unit of space traversed.
-
-Force is measured by the acceleration or change of motion it can impart
-to a body of unit mass in a unit of time, or, calling
-force, F,
-mass, m
-acceleration per second a
-we have F = m a.
-
-The dimensions of force are
-mass (M) * acceleration (L/(T^2)) = (M*L)/(T^2).
-
-
-260   STANDARD ELECTRICAL DICTIONARY.
-
-
-Force de Cheval. Horse power (French).
-It is the French or metric horse power.
-It is equal to:
-  542.496    Foot lbs. per second.
-     .9864   English Horse Power.
-   75.0      Kilogram-meters per second.
-
-Force, Electro-magnetic.
-The mechanical force of attraction or repulsion acting on the
-electro-magnetic unit of quantity. Its intensity varies with the square
-of the distance. It may also be defined as electric force in the
-electro-magnetic system.
-
-Its dimensions are equal to
-mechanical force ((M*L)/(T^2)) divided by quantity ((M^.5)*(L^.5))
-= ((M^.5)*(L^.5))/(T^2).
-
-
-Force, Electrostatic.
-The force by which electric matter or electrified surfaces attract or
-repel each other. It is also termed electric force (not good) and
-electro-motive intensity. It is the mechanical force acting upon a unit
-quantity of electricity. Its intensity varies with the square of the
-distance.
-
-Its dimensions are therefore equal to
-(quantity * unity / (square of distance) Q. * 1 / (L^2)
- = ((M^.5) * (L^1.5) )/ T*1 / (L^2)
- = ((M^.5) * (L^.5)) / T
-These dimensions are also those of potential difference.
-
-[Transcriber's Note: The image of the preceding paragraph is included
-for "clarity".]
-
-The objection to the term electric force is that it may be applied also
-to electro-magnetic force, and hence be a source of confusion.
-
-
-Forces, Parallelogram of.
-The usual method of composing forces or resolving a force. The sides of
-a parallelogram of forces represent component forces and the diagonal
-represents the resultant. See Component--Resultant--Forces, Composition
-of--Forces, Resolution of.
-
-
-Forces, Composition of.
-When several forces act in a different direction upon a point they may
-be drawn or graphically represented as arrows or lines emanating from
-the point in the proper direction and of lengths proportional to the
-force they exercise. Any two can be treated as contiguous sides of a
-parallelogram and the parallelogram can be completed. Then its diagonal,
-called the resultant, will represent the combined action of the two
-forces, both as regards direction and intensity. This is the composition
-of two forces.
-
-If more than two forces act upon the given point the resultant can be
-composed with any of the others and a new force developed. The new
-resultant can be combined with another force, and the process kept up,
-eliminating the components one by one until a final resultant of all is
-obtained. This will give the exact direction and intensity of the
-forces, however many or varied.
-
-
-261   STANDARD ELECTRICAL DICTIONARY.
-
-Forces, Resolution of.
-The developing from a single force treated as a resultant, two other
-forces in any desired direction. The reverse of composition of forces.
-(See Forces, Composition of--Forces, Parallelogram
-of--Components--Resultant.)
-
-
-Force, Tubes of.
-Aggregations of lines of force, either electrostatic or magnetic. They
-generally have a truncated, conical or pyramidal shape and are not
-hollow. Every cross-section contains the same number of lines. The name
-it will seem is not very expressive.
-
-
-Force, Unit of.
-The fundamental or C. G. S. unit or force is the dyne, q. v.
-
-The British unit of force is the poundal (the force which will produce
-an acceleration of one foot per second in a mass of one pound). It is
-equal to about 10/322 pound. A force cannot be expressed accurately in
-weight units, because weight varies with the latitude.
-
-
-Forming.
-The process of producing secondary battery plates from lead plates by
-alternately passing a charging current through the cell and then
-allowing it to discharge itself and repeating the operation. (See
-Battery, Secondary, Plant�'s.)
-
-
-Foundation Ring.
-In a dynamo armature the ring-shaped core on which Gramme ring armatures
-and other ring armatures are wound.
-
-
-Fourth State of Matter.
-Gas so rarefied that its molecules do not collide, or rarely do so;
-radiant matter, q. v.
-
-[Transcriber's note: This term now refers to plasma, an ionized gas,
-which contains free electrons. The ions and electrons move somewhat
-independently making plasma electrically conductive. It responds
-strongly to electromagnetic fields.]
-
-
-Frame.
-In a dynamo the bed-piece is sometimes called the frame.
-
-
-Franklin's Experiment.
-Franklin proved the identity of lightning and electricity by flying a
-kite in a thunder storm. The kite was of silk so as to endure the
-wetting. When the string became wet sparks could be taken from a key
-attached to its end. The main string was of hemp; at the lower end was a
-length of silk to insulate it. The key was attached near the end of and
-to the hemp string.
-
-
-Franklin's Plate.
-A simple form of condenser. It consists of a plate of glass coated on
-each side with tinfoil with a margin of about an inch of clear glass.
-One coating may be grounded as indicated in the cut, and the plate
-charged like a Leyden jar. Or one side may be connected with one
-terminal, and the other with the other terminal of an influence machine
-and the pane will be thus charged.
-
-Synonym--Fulminating Pane.
-
-
-262   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 174. FRANKLIN'S PLATE.
-
-
-Franklin's Theory.
-The single fluid theory, q. v., of electricity.
-
-Frequency.
-The number of double reversals or complete alternations per second in an
-alternating current.
-
-Synonym--Periodicity.
-
-
-Frictional Electricity.
-Electricity produced by friction of dissimilar substances. (See
-Electrostatic Series.) The contact theory holds that friction plays only
-a secondary r�le in this process; that it increases the thoroughness of
-contact, and tends to dry the rubbing surfaces, but that the charges
-induced are due to contact of dissimilar substances, not to friction of
-one against the other.
-
-
-Frictional Heating.
-The heating of a conductor by the passage of a current; the Joule
-effect, q. v.
-
-
-Fringe.
-The outlying edge of a magnetic field.
-
-
-Frog, Galvani's Experiment With.
-A classic experiment in electricity, leading to the discovery of current
-or dynamic electricity. If a pair of legs of a recently killed frog are
-prepared with the lumbar nerves exposed near the base of the spinal
-column, and if a metallic conductor, one half-length zinc and the other
-half-length copper, is held, one end between the lumbar nerves and the
-spine, and the other end against one of the muscles of the thigh or
-lower legs, the moment contact occurs and the circuit is completed
-through the animal substance the muscles contract and the leg is
-violently drawn upwards. Galvani, in 1786, first performed, by accident,
-this famous experiment, it is said, with a scalpel with which he was
-dissecting the animal. He gave his attention to the nerves and muscles.
-Volta, more happily, gave his attention to the metals and invented the
-voltaic battery, described by him in a letter to Sir Joseph Banks, dated
-1800.
-
-
-Frog, Rheoscopic.
-If the nerve or living muscle of a frog is suddenly dropped upon another
-living muscle so as to come in contact with its longitudinal and
-transverse sections, the first muscle will contract on account of the
-stimulation of its nerve due to the passage of a current derived from
-the second muscle (Ganot). The experiment goes under the above title.
-
-
-263   STANDARD ELECTRICAL DICTIONARY.
-
-Frying.
-A term applied to a noise sometimes produced in a voltaic arc due to too
-close approach of the carbons to each other. It has been suggested that
-it may be due to volatilization of the carbon. (Elihu Thomson.)
-
-
-Fulgurite.
-An irregular and tubular mass of vitrified quartz, believed to be formed
-by melting under the lightning stroke.
-
-
-Fig. 175. CRUCIBLE, ELECTRIC.
-
-
-Furnace, Electric.
-A furnace in which the heat is produced by the electric current. It has
-hitherto been practically used only in the extraction of aluminum and
-silicium  from their ores. The general principle involves the formation
-of an arc between carbon electrodes. The substances to be treated are
-exposed to the heat thus produced. Sometimes the substances in the arc
-form imperfect conductors, and incandescence takes a part in the action.
-Sometimes the substances are merely dropped through the arc.
-
-[Transcriber's note: Silicium is silicon.]
-
-
-Fuse Board.
-A tablet on which a number of safety fuses are mounted. Slate is
-excellent material for the tablet, as it is incombustible, and is easily
-drilled and worked.
-
-
-Fuse Box.
-A box containing a safety fuse. Porcelain is an excellent material for
-its base. No combustible material should enter into its composition.
-
-
-Fuse, Cockburn.
-A safety fuse or cut off which consists of a wire of pure tin running
-from terminal to terminal, to whose centre a leaden ball is secured by
-being cast into position. The connection with the terminals is made by
-rings at the ends of the wire through which the terminal screws are
-passed and screwed home. When the tin softens under too heavy a current
-the weight of the shot pulls it apart.
-
-
-Fig. 176 COCKBURN SAFETY FUSE.
-
-
-264  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 177. ELECTRIC FUSE.
-
-
-Fuse, Electric.
-A fuse for igniting an explosive by electricity. There are two kinds. In
-one a thin wire unites the ends of the two conducting wires as they
-enter the case of the fuse. The larger wires are secured to the case, so
-that no strain comes on the fine wire. On passing a current of
-sufficient strength the small wire is heated. In use the fuse is bedded
-in powder, which again may be surrounded by fulminating powder, all
-contained in a copper or other metallic case. Such a detonator is used
-for exploding guncotton and other high explosives.
-
-The other kind of fuse is similar, but has no thin connecting wire. The
-ends of the conductors are brought nearer together without touching. In
-use a static discharge is produced across from end to end of the
-conductors, igniting a proper explosive placed there as in the other
-case.
-
-The first kind of fuse is generally operated by a battery or small
-mechanical generator--the latter by a spark coil, frictional or
-influence machine or by a Leyden jar.
-
-
-Galvanic. adj.
-Voltaic; relating to current electricity or the electrolytic and
-electro-chemical relations of metals. (For titles in general under this
-head see Voltaic--or the main title.)
-
-
-Galvanic Element.
-A galvanic couple with exciting fluid and adjuncts; a galvanic cell. The
-word element is sometimes applied to the electrodes of a cell, as the
-carbon element or zinc element.
-
-
-265  STANDARD ELECTRICAL DICTIONARY.
-
-
-Galvanic Polarization.
-The polarization of a voltaic couple. (See Polarization.)
-
-
-Galvanism.
-The science of voltaic or current electricity.
-
-
-Galvanization.
-(a) Electroplating or depositing a metal over the surface of another by
-electrolysis.
-
-(b) In medical electricity the effects produced on any part of the
-system by the current of voltaic battery. Various descriptive
-qualifications are prefixed, such as "general" galvanization, indicating
-its application as applied to the whole body, "local" for the reverse
-case, and so on.
-
-
-Galvanization, Labile.
-Application of the galvanic current in electro-therapeutics where one
-sponge electrode is employed which is rubbed or moved over the body, the
-other being in constant contact with the body.
-
-
-Galvanized Iron.
-Iron coated with zinc by cleaning and immersion in melted zinc. The iron
-is prevented from rusting by galvanic action. It forms the negative
-element in a couple of which the zinc is the positive element. From this
-electric protective action the name is derived.
-
-
-Galvano-cautery, Chemical.
-Electro-therapeutic treatment with sharp electrodes, one of which is
-inserted in the tissue and a current passed by completing the circuit
-through the tissue so as to electrolyze or decompose the fluids of the
-tissue. It is applied in the removal of hair or extirpation of the
-follicle. The process is not one of heating, and is improperly named
-cautery.
-
-Galvano-faradization.
-In medical electricity the application of the voltaic and induced or
-secondary current simultaneously to any part of the system.
-
-
-Galvanometer.
-An instrument for measuring current strength and sometimes for measuring
-inferentially potential difference, depending on the action of a
-magnetic field established by the current, such action being exerted on
-a magnetic needle or its equivalent.
-
-A current passing through a conductor establishes circular lines of
-force. A magnetic needle placed in their field is acted on and tends to
-place itself parallel with the lines, in accordance with the principles
-of current induction. (See Induction, Electro-magnetic.) A common
-compass held near a conductor through which a current is passing tends
-to place itself at right angles to such conductor. For a maximum effect
-the conductor or the part nearest the needle should lie in the magnetic
-meridian. If at right angles thereto its action will only strengthen the
-directive force of the earth's induction or magnetic field, as the
-needle naturally points north and south. Such combination is virtually a
-galvanometer.
-
-
-266   STANDARD ELECTRICAL DICTIONARY.
-
-
-A typical galvanometer comprises a flat coil of wire placed horizontally
-within which a magnetic needle is delicately poised, so as to be free to
-rotate with the least possible friction. The needle may be supported on
-a sharp point like a compass needle, or may be suspended by a long fine
-filament. It should be covered by a glass plate and box, or by a glass
-shade. Finally a graduated disc may be arranged to show the amount of
-deflection of the needle.
-
-In use the apparatus is turned about until the needle, as acted on by
-the earth's magnetic field, lies parallel to the direction of the coils
-of wire. On passing a current through the coil the needle is deflected,
-more or less, according to its strength.
-
-By using exceedingly fine wire, long enough to give high resistance, the
-instrument can be used for very high potentials, or is in condition for
-use in determining voltage. By using a coil of large wire and low
-resistance it can be employed in determining amperage. In either case
-the deflection is produced by the current.
-
-The needle is often placed above or below the coil so as only to receive
-a portion of its effect, enough for all practical purposes in the
-commoner class of instruments.
-
-The galvanometer was invented by Schweigger a short time after Oersted's
-discovery, q. v.
-
-
-Galvanometer, Absolute.
-A galvanometer giving absolute readings; properly one whose law of
-calibration can be deduced from its construction. Thus the diameter of
-the coil, and the constants and position of a magnetic needle suspended
-in its field being known, the current intensity required to deflect the
-needle a given number of degrees could be calculated.
-
-
-Galvanometer, Aperiodic.
-A galvanometer whose needle is damped (see Damping) as, for instance, by
-the proximity of a plate of metal, by an air vane or otherwise, so that
-it reaches its reading with hardly any oscillation. A very light needle
-and a strong magnetic field also conduce to vibrations of short period
-dying out very quickly. Such galvanometers are termed "dead-beat." No
-instrument is absolutely dead-beat, only relatively so.
-
-
-267  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 178. ASTATIC GALVANOMETER.
-
-
-Galvanometer, Astatic.
-A galvanometer with a pair of magnetic needles connected astatically, or
-parallel with their poles in opposition. (See Astatic Needle.) Each
-needle has its own coil, the coils being wound in opposite directions so
-as to unite in producing deflections in the same sense. As there should
-be some directive tendency this is obtained by one of the magnets being
-slightly stronger than the other or by the proximity of a fixed and
-adjustable controlling magnet, placed nearer one needle than the other.
-
-For small deflections the currents producing them are proportional to
-their extent.
-
-
-Galvanometer, Ballistic.
-A galvanometer whose deflected element has considerable moment of
-inertia; the exact opposite of an aperiodic or dead beat galvanometer.
-(See Galvanometer, Aperiodic.) All damping by air vanes or otherwise
-must be carefully done away with.
-
-
-Fig. 179. SIEMENS & HALSKE'S GALVANOMETER.
-
-
-Siemens & Halske's galvanometer is of the reflecting or mirror type (see
-Galvanometer, Reflecting) with suspended, bell-shaped magnet, in place
-of the ordinary magnetic needle, or astatic combination of the lightest
-possible weight in the regular instrument. A copper ball drilled out to
-admit the magnet is used as damper in the ordinary use of the
-instrument. To convert it into a ballistic galvanometer the copper ball
-is removed. The heavy suspended magnet then by its inertia introduces
-the desired element into the instrument.
-
-
-268   STANDARD ELECTRICAL DICTIONARY.
-
-
-Referring to the cut, Fig. 179, M is the suspended magnet, with north
-and south poles n and s; S is the reflecting mirror; r is the tube
-containing the suspending thread; R is the damper removed for ballistic
-work.
-
-The ballistic galvanometer is used to measure quantities of electricity
-in an instantaneous discharge, which discharge should be completed
-before the heavy needle begins to move. The extreme elongation or throw
-of the needle is observed, and depends (1) on the number of coulombs (K)
-that pass during the discharge; (2) on the moment of inertia of the
-needle and attached parts; (3) on the moment of the controlling forces,
-i. e., the forces tending to pull the needle back to zero; (4) on the
-moment of the damping forces; (5) on the moment of the deflecting forces
-due to a given constant current. The formula is thus expressed:
-
-K = (P / PI ) * A * sin( k� / 2 ) / tan( a� )
-
-in which K = coulombs discharged; P = periodic time of vibration of
-needle; A = amperes producing a steady deflection equal to  a�  ; k� =
-first angular deflection of needle. For accuracy k� and a� should both
-be small and the damping so slight as to be negligible. Otherwise a
-correction for the latter must be applied. For approximate work for k�
-and a� the deflections read on the scale may be used with the following
-formula:
-
-K = (P / PI ) * ( A / 2 ) * ( k� / a� )
-
-
-Galvanometer Constant.
-Assume a galvanometer with a very short needle and so placed with
-respect to its coils that the magnetic field produced by a current
-circulating in them is sensibly uniform in the neighborhood of the
-needle, with its lines of force at right angles thereto. The field is
-proportional to the current i, so that it may be denoted by G i. Then G
-is the galvanometer constant. If now the angle of deflection of the
-needle is ? against the earth's field H, M being the magnetic moment of
-the needle we have G i M cos ? = H M sin ? or i = (H/G)* tan ?. H/G is
-the reduction factor; variable as H varies for different places.
-
-For a tangent galvanometer the constant G is equal to  2*PI*(n/a), in
-which n denotes the number of turns of wire, and a denotes the radius of
-the circle.
-
-
-Galvanometer, Differential.
-A galvanometer in which the needle is acted on by two coils wound in
-opposition, each of equal deflecting action and of equal resistance. If
-a current is divided between two branches or parallel conductors, each
-including one of the coils, when the needle points to zero the
-resistances of the two branches will bc equal. In the cut, C C'
-represent the coils, and A and B the two leads into which the circuit, P
-Q, is divided.
-
-
-269  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 180. THEORY OF DIFFERENTIAL GALVANOMETER.
-
-
-Fig. 181. DIFFERENTIAL GALVANOMETER.
-
-
-Galvanometer, Direct Reading.
-A calibrated galvanometer, whose scale is graduated by volts or amperes,
-instead of degrees.
-
-
-Galvanometer, Marine. (Sir William Thomson's.)
-A galvanometer of the reflecting type, for use on shipboard. A fibre
-suspension is adopted for the needle. The fibre is attached to a fixed
-support at one end and to a spring at the other, and the needle is
-suspended by its centre of gravity. This secures it to a considerable
-extent from disturbance due to the rolling of the ship. A thick iron box
-encloses the needle, etc., to cut off any magnetic action from the ship.
-(See Galvanometer, Reflecting.)
-
-
-Galvanometer, Potential.
-A galvanometer wound with fine German silver wire to secure high
-resistance used for determination of potential difference.
-
-
-Galvanometer, Proportional.
-A galvanometer so constructed that the deflections of its index are
-proportional to the current passing. It is made by causing the
-deflecting force to increase as the needle is deflected, more and more,
-or by causing the restitutive force to diminish under like conditions,
-or by both. The condition is obtained in some cases by the shape and
-position of the deflecting coils.
-
-
-Galvanometer, Quantity.
-A galvanometer for determining quantities of electricity, by the
-deflections produced by discharging the quantities through their coils.
-It is a ballistic galvanometer with very little or no damping.
-
-
-270   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 182. PRINCIPLE OF REFLECTING GALVANOMETER.
-
-
-Fig. 183. REFLECTING GALVANOMETER.
-
-
-Galvanometer, Reflecting.
-A galvanometer the deflections of whose needle are read by an image
-projected by light reflected from a mirror attached to the needle or to
-a vertical wire carrying the needle. A lamp is placed in front of the
-instrument facing the mirror. The light of the lamp is reflected by the
-mirror upon a horizontal scale above the lamp. An image of a slit or of
-a wire may be caused thus to fall upon the scale, the mirror being
-slightly convex, or a lens being used to produce the projection.
-
-
-271  STANDARD ELECTRICAL DICTIONARY.
-
-
-If the mirror swings through a horizontal arc, the reflected image will
-move, in virtue of a simple geometrical principle, through an arc of
-twice as many degrees. The scale can be placed far from the mirror, so
-that the ray of light will represent a weightless index of very great
-length, and minute deflections of the needle will be shown distinctly
-upon the scale.
-
-In the cut, Fig. 182, the ray of light from the lamp passes through the
-aperture, m m, and is made parallel by the lens, L. At s is the mirror
-attached to the needle and moving with it. A scale placed at t receives
-the reflection from the mirror. The cut, Fig. 183, shows one form of the
-instrument set up for use.
-
-Synonym--Mirror Galvanometer.
-
-
-Galvanometer Shunt.
-To prevent too much current passing through a galvanometer (for fear of
-injury to its insulation) a shunt is sometimes placed in parallel with
-it. The total current will be distributed between galvanometer and shunt
-in the inverse ratio of their respective resistances. (See Multiplying
-Power of a Shunt.)
-
-
-272   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 184. SINE GALVANOMETER.
-
-
-Galvanometer, Sine.
-A galvanometer whose measurements depend upon the sine of the angle of
-deflection produced when the coil and needle lie in the same vertical
-plane.
-
-The needle, which may be a long one, is surrounded by a coil, which can
-be rotated about a vertical axis passing through the point of suspension
-of the needle. Starting with the needle at rest in the plane of the
-coil, a current is passed through the coil deflecting the needle, the
-coil is swung around deflecting the needle still more, until the needle
-lies in the plane of the coil; the intensity of the current will then be
-in proportion to the sine of the angle through which the coil and needle
-move.
-
-In the galvanometer M is a circle carrying the coil, N is a scale over
-which the needles, m and n, move, the former being a magnetic needle,
-the latter an index at right angles and attached thereto; a and b are
-wires carrying the current to be measured. The circles, M and N, are
-carried by a base, O, around which they rotate. H is a fixed horizontal
-graduated circle. In use the circle, M, is placed in the magnetic
-meridian, the current is passed through the coil, M; the needle is
-deflected; M is turned until its plane coincides with the direction of
-the needle, m. The current strength is proportional to the sine of the
-angle of deflection. This angle is measured by the vernier, C, on the
-circle, H. The knob, A, is used to turn the circle, M.
-
-
-273  STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 185. TANGENT GALVANOMETER.
-
-
-Galvanometer, Tangent.
-A galvanometer in which the tangents of the angles of deflection are
-proportional to the currents producing such deflections.
-
-For this law to apply the instrument in general must fulfill the
-following conditions:
-
-(1) The needle must be controlled by a uniform magnetic field such as
-that of the earth;
-
-(2) the diameter of the coil must be large compared to the length of the
-needle;
-
-(3) the centre of suspension of the needle must be at the centre of the
-coil;
-
-(4) the magnetic axis of the needle must lie in the plane of the coil
-when no current is passing.
-
-If a single current strength is to be measured the best results will be
-attained when the deflection is 45�; in comparing two currents the best
-results will be attained when the deflections as nearly as possible are
-at equal distances on both sides of 45�.
-
-The needle should not exceed in length one-tenth the diameter of the
-coil.
-
-For very small deflections any galvanometer follows the law of
-tangential deflection.
-
-As for very small deflections the tangents are practically equal to the
-arcs subtended, for such deflections the currents are proportional to
-the deflections they produce.
-
-The sensibility is directly proportional to the number of convolutions
-of wire and inversely proportional to their diameter.
-
-The tangent law is most accurately fulfilled when the depth of the coil
-in the radial direction is to the breadth in the axial direction as
-squareRoot(3):squareRoot(2), or about as 11:9.
-
-
-Galvanometer, Torsion.
-A galvanometer whose needle is suspended by a long filament or by a
-thread and spiral spring against whose force of torsion the movements of
-the needle are produced. The current strength is determined by bringing
-the needle back to its position of rest by turning a hand-button or
-other arrangement. The angle through which this is turned gives the
-angle of torsion. From this the current strength is calculated on the
-general basis that it is proportional to the angle of torsion.
-
-
-Fig. 186. TORSION GALVANOMETER.
-
-
-274   STANDARD ELECTRICAL DICTIONARY.
-
-
-Galvanometer, Vertical.
-A galvanometer whose needle is mounted on a horizontal axis and is
-deflected in a vertical plane. One of the poles is weighted to keep it
-normally vertical, representing the control. It is not used for accurate
-work.
-
-Synonym--Upright Galvanometer.
-
-
-Fig. 187. VERTICAL GALVANOMETER.
-
-
-Galvanometer, Volt- and Ampere-meter.
-A galvanometer of Sir William Thomson's invention embodying the tangent
-principle, and having its sensibility adjustable by moving the magnetic
-needle horizontally along a scale (the "meter") towards or away from the
-coil. A curved magnet is used to adjust the control. The leads are
-twisted to prevent induction.
-
-The instrument is made with a high resistance coil for voltage
-determinations, and with a low resistance coil for amperage
-determinations.
-
-At one end of a long base board a vertical coil with its plane at right
-angles to the axis of the board is mounted. A scale (the "meter" of the
-name) runs down the centre of the board. A groove also runs down the
-centre. The magnetic needle is contained in a quadrant-shaped
-glass-covered box which slides up and down the groove. A number of short
-parallel needles mounted together, with an aluminum pointer are used.
-
-
-Fig. 188. SIR WILLIAM THOMSON'S AMPERE-METER GALVANOMETER.
-
-
-275   STANDARD ELECTRICAL DICTIONARY.
-
-
-In the cut P is the base board, M is a glass covered case containing the
-magnetic needle, and sliding along the base board, being guided by the
-central groove, C, is the coil. Between the coil and the needle is the
-arched or bent controlling magnet. The long twisted connecting wires are
-seen on the right hand.
-
-
-Galvano-plastics.
-The deposition of metals by electrolysis, a disused term replaced
-by electro-deposition, electroplating, and electro-metallurgy.
-
-
-Galvano-puncture.
-An operation in medical electricity. (See Electro-puncture.)
-
-
-Galvanoscope.
-An instrument, generally of the galvanometer type, used for ascertaining
-whether a current is flowing or not. Any galvanoscope, when calibrated,
-if susceptible thereof, becomes a galvanometer.
-
-
-Gas, Electrolytic.
-Gas produced by the decomposition, generally of water, by electrolysis.
-It may be hydrogen or oxygen, or a mixture of the two, according to how
-it is collected. (See Gases, Mixed.)
-
-
-Gases, Mixed.
-The mixture of approximately one volume of oxygen and two volumes of
-hydrogen collected in the eudiometer of a gas voltameter or other
-electrolytic apparatus.
-
-
-Gassing.
-The evolution of gas from the plates of a storage battery in the
-charging process, due to too high voltage in the circuit of the charging
-dynamo.
-
-
-Gastroscope.
-An apparatus for illuminating by an incandescent lamp the interior of
-the stomach, and with prisms to refract the rays of light so that the
-part can be seen. The stomach is inflated with air, if desirable, to
-give a better view. An incandescent platinum spiral in a water jacket
-has been employed for the illumination.
-
-
-Gassiot's Cascade.
-A goblet lined for half its interior surface with tinfoil. It is placed
-in the receiver of an air pump from the top of whose bell a conductor
-descends into it, not touching the foil. On producing a good
-rarefaction, and discharging high tension electricity from between the
-conductor just mentioned and the metal of the machine, a luminous effect
-is produced, as if the electricity, pale blue in color, was overflowing
-the goblet.
-
-
-Gauss.
-A name suggested for unit intensity of magnetic field. Sylvanus P.
-Thomson proposed for its value the intensity of a field of 1E8 C. G. S.
-electro-magnetic units. J. A. Fleming proposed the strength of field
-which would develop one volt potential difference in a wire 1E6
-centimeters long, moving through such field with a velocity of one
-centimeter per second. This is one hundred times greater than Thomson's
-standard. Sir William Thomson suggested the intensity of field produced
-by a current of one ampere at a distance of one centimeter
-
-The gauss is not used to any extent; practical calculations are based on
-electro-magnetic lines of force.
-
-
-276   STANDARD ELECTRICAL DICTIONARY.
-
-
-Gauss' Principle.
-An electric circuit acts upon a magnetic pole in such a way as to make
-the number of lines of force that pass through the circuit a maximum.
-
-
-Fig. 189. GAUSS' TANGENT POSITION.
-
-
-Gauss, Tangent Positions of.
-The "end on" and "broadside" methods of determining magnetization
-involve positions which have been thus termed. (See Broadside Method and
-End on Method.)
-
-
-Gear, Magnetic Friction.
-Friction gear in which the component wheels are pressed against each
-other by electromagnetic action. In the cut, repeated from Adherence,
-Electro-magnetic, the magnetizing coil makes the wheels, which are of
-iron, press strongly together.
-
-
-Fig. 190. MAGNETIC FRICTION GEAR.
-
-
-277   STANDARD ELECTRICAL DICTIONARY.
-
-
-Geissler Tubes.
-Sealed tubes of glass containing highly rarefied gases, and provided
-with platinum electrodes extending through the glass tightly sealed as
-they pass through it, and often extending a short distance beyond its
-interior surface.
-
-On passing through them the static discharge luminous effects are
-produced varying with the degree of exhaustion, the contents (gas), the
-glass itself, or solutions surrounding it. The two latter conditions
-involve fluorescence phenomena often of a very beautiful description.
-
-The pressure of the gas is less than one-half of a millimeter of
-mercury. If a complete vacuum is produced the discharge will not pass.
-If too high rarefaction is produced radiant matter phenomena (see
-Radiant State) occur.
-
-Geissler tubes have been used for lighting purposes as in mines, or for
-illuminating the interior cavities of the body in surgical or medical
-operations.
-
-
-Generating Plate.
-The positive plate in a voltaic couple, or the plate which is dissolved;
-generally a plate of zinc.
-
-Synonyms--Positive Plate--Positive Element.
-
-
-Generator, Current.
-Any apparatus for maintaining an electric current. It may be as regards
-the form of energy it converts into electrical energy, mechanical, as a
-magneto or dynamo electric machine or generator; thermal, as a
-thermo-electric battery; or chemical, as a voltaic battery; all of which
-may be consulted.
-
-Generator, Secondary.
-A secondary or storage battery. (See Battery, Secondary.)
-
-
-German Silver.
-An alloy of copper, 2 parts, nickel, 1 part, and zinc, 1 part. Owing to
-its high resistance and moderate cost and small variation in resistance
-with change of temperature, it is much used for resistances. From Dr.
-Mathiessen's experiment the following constants are deduced in legal
-ohms:
-  Relative Resistance (Silver = 1),      13.92
-  Specific Resistance at 0� C. (32F.),   20.93 microhms.
-  Resistance of a wire,
-  (a) 1 foot long, weighing 1 grain,      2.622   ohms.
-  1 foot long, 1/1000 inch thick,       125.91     "
-  1 meter long, weighing 1 gram,          1.830    "
-  1 meter long, 1 millimeter thick,       0.2666   "
-  Resistance of a 1 inch cube at 0�C. (32� F.),   8.240 microhms.
-
-Approximate percentage increase of resistance per 1� C. (1.8� F.) at
-about 20� C. (68� F.), 0.044 per cent.
-
-
-Gilding, Electro-.
-The deposition of gold by an electric current, or electrolytically in
-the electroplating bath.
-
-
-Gilding Metal.
-A special kind of brass, with a high percentage of copper, used to make
-objects which are to be gilded by electrolysis.
-
-
-278   STANDARD ELECTRICAL DICTIONARY.
-
-
-Gimbals.
-A suspension used for ships' compasses and sometimes for other
-apparatus. It consists of a ring held by two journals, so as to bc free
-to swing in one plane. The compass is swung upon this ring, being placed
-concentrically therewith. Its journals are at right angles to those of
-the ring. This gives a universal joint by which the compass, weighted
-below its line of support, is always kept horizontal.
-
-
-Fig. 191. COMPASS SUSPENDED IN GIMBALS.
-
-
-Glass.
-A fused mixture of silicates of various oxides. It is of extremely
-varied composition and its electric constants vary greatly. Many
-determinations of its specific resistance have been made. For flint
-glass at 100� C. (212� F.) about (2.06E14) ohms --at 60� C (140� F.)
-(1.020E15) (Thomas Gray) is given, while another observer (Beetz) gives
-for glass at ordinary temperatures an immeasurably high resistance. It
-is therefore a non-conductor of very high order if dry. As a dielectric
-the specific inductive capacity of different samples of flint glass is
-given as 6.57--6.85--7.4--10.1 (Hopkinson), thus exceeding all other
-ordinary dielectrics. The densest glass, other things being equal, has
-the highest specific inductive capacity.
-
-
-Gold.
-A metal, one of the elements; symbol Au. c .; atomic weight, 196.8;
-equivalent, 65.6; valency, 3; specific gravity 19.5.
-It is a conductor of electricity.
-
-                                            Annealed.   Hard drawn.
-Relative Resistance (Annealed Silver = 1),   1.369       1.393
-Specific Resistance,                         2.058       2.094
-Resistance of a wire at 0� C. (32�F.)
-(a) 1 foot long, weighing 1 grain,          57.85     58.84   ohms
-(b) 1 foot long, 1/1000 inch thick,         12.38     12.60    "
-(c) 1 meter long, weighing 1 gram,            .4035     .4104  "
-(d) 1 meter long, 1 millimeter thick,         .02620    .02668 "
-Resistance of a 1 inch cube at 0� C.(32� F.)  .8102     .8247
-
-Approximate increase in resistance per 0� C., (1.8� F)
-at about 20� C. (68� F.), 0.365 per cent.
-
-Electro-chemical equivalent (Hydrogen = .0105), .6888
-
-
-279   STANDARD ELECTRICAL DICTIONARY.
-
-
-Gold Bath.
-A solution of gold used for depositing the metal in the electroplating
-process.
-
-A great number of formulae have been devised, of which a few
-representative ones are given here.
-                            COLD BATHS.              HOT BATHS.
-Water,               10,000   10,000   10,000   10,000   5,000   3,000
-Potassium Cyanide,      200       --      200       10      --      50
-Gold,                   100       15      100       10      10      10
-Potassium Ferrocyanide,  --      200       --       --     150      --
-Potassium Carbonate,     --      150       --       --      50      --
-Ammonium Chloride,       --       30       --       --      20      --
-Aqua Ammoniae,           --       --      500       --      --      --
-Sodium Phosphate,        --       --       --      600      --      --
-Sodium Bisulphite,       --       --       --      100      --      --
-
-(Roseleur.)
-
-In the baths the gold is added in the form of neutral chloride, Auric
-chloride (Au Cl6).
-
-
-Gold Stripping Bath.
-A bath for removing gold from plated articles without dissolving the
-base in order to save the precious metal. A bath of 10 parts of
-potassium cyanide and 100 parts of water may be used, the articles to be
-stripped being immersed therein as the anode of an active circuit. If
-the gilding is on a silver or copper basis, or on an alloy of these
-metals the same solution attacks the base and dissolves it, which is
-objectionable. For silver articles it is enough to heat to cherry red
-and throw into dilute sulphuric acid. The gold scales off in metallic
-spangles. For copper articles, a mixture of 10 volumes concentrated
-sulphuric acid, 1 volume nitric acid, and 2 volumes hydrochloric acid
-may be used by immersion only, or with a battery. The sulphuric acid in
-such large excess is supposed to protect the copper. For copper articles
-concentrated sulphuric acid alone with the battery may be used. This
-does not sensibly attack the copper if it is not allowed to become
-diluted. Even the dampness of the air may act to dilute it.
-
-
-Graduator.
-Apparatus for enabling the same line to be used for telegraph signals
-and telephoning.
-
-One type consists in coils with iron cores or simply electromagnets.
-These act to retard the current in reaching its full power and also
-prolong it. This gives a graduated effect to the signals, so that the
-telephone diaphragm is not audibly affected by the impulses.
-
-The telephoning current is so slight and so rapid in its characteristic
-changes that it is without effect upon the ordinary telegraph.
-
-
-280   STANDARD ELECTRICAL DICTIONARY.
-
-
-Gram.
-The unit of weight in the metric system; accepted as the unit of
-mass in the absolute of C. G. S. system of units. It is the
-one-thousandth part of mass of a standard weight preserved under proper
-conditions in Paris, and supposed to be the mass of a cubic decimeter of
-distilled water at the temperature of the maximum density of water. The
-standard is the kilogram; the temperature is 3.9� C. (39� F.). The
-standard kilogram is found to be not exactly the weight of a cubic
-decimeter of water, the latter weighing 1.000013 kilogram.
-
-If therefore the defined gram on the water basis is taken as the unit it
-varies very slightly from the accepted gram.
-
-1 gram is equal to 15.43234874 grains. (Prof. W. H. Miller.)
-
-
-Gram-atom.
-The number of grams of an element equal numerically to the atomic
-weight, as 16 grams of oxygen, 1 gram of hydrogen, 35.5 grams of
-chlorine; all which might be expressed as gram-atoms of oxygen, hydrogen
-and chlorine respectively.
-
-The gram-atom approximately expresses the number of gram-calories
-required to heat one gram of the substance 1� C. (1.8� F.). This is in
-virtue of Dulong and Petit's discovery that the atomic weight of an
-element multiplied by its specific heat gives approximately a constant
-for all elements.
-
-[Transcriber's note: A gram-atom is the mass, in grams, of one mole of
-atoms in a monatomic element. A mole consists of Avogadro's number of
-atoms, approximately 6.02214E23.]
-
-
-Gram-molecule.
-The number of grams of a substance equal numerically to its molecular
-weight.
-
-
-Graphite.
-Carbon; one of three allotropic modifications of this element. It occurs
-in nature as a mineral.
-
-It is used as a lubricant for machinery; for commutator brushes; for
-making surfaces to be plated conductive, and for mixing with manganese
-binoxide in Leclanch� cells.
-
-
-Gravitation.
-A natural force which causes all masses of matter to attract each other.
-Its cause is unknown; it is often supposed to be due to the luminiferous
-ether.
-
-[Transcriber's note: Einstein's explanation of gravity, General
-Relativity and the curvature of space-time, came 23 years later, 1915.]
-
-
-281  STANDARD ELECTRICAL DICTIONARY.
-
-
-Gravity, Acceleration of.
-The velocity imparted to a body in one second by the action of
-gravitation at any standard point upon the earth's surface in a vacuum.
-This will vary at different places, owing principally to the variation
-in centrifugal force due to the earth's rotation. For standard valuation
-it must be reduced to sea level. The following are examples of its
-variation:
-
-Equator,          978.1028       centimeters per second
-Paris,            980.94                   "
-Greenwich         981.I7                   "
-Edinburgh,        981.54                   "
-Pole (N. or S.),  983.1084 (theoretical)   "
-
-As round numbers for approximate calculations 981 centimeters or 32.2
-feet may be employed.
-
-[Transcriber's note: The acceleration of gravity at the equator is also
-reduced by the increased distance from the center of the earth
-(equatorial bulge). Increased altitude reduces gravity. Reduced air
-density at altitude reduces buoyancy and increases apparent weight.
-Local variations of rock density affects gravity.]
-
-
-Gravity, Control.
-Control by weight. In some ammeters and voltmeters gravity is the
-controlling force.
-
-
-Grid.
-A lead plate perforated or ridged for use in a storage battery as the
-supporter of the active materials and in part as contributing thereto
-from its own substance.
-
-
-Ground.
-The contact of a conductor of an electric circuit with the earth,
-permitting the escape of current if another ground exists.
-
-
-Ground-wire.
-A metaphorical term applied to the earth when used as a return circuit.
-
-
-Fig. 192. GROVE'S GAS BATTERY.
-
-
-Grove's Gas Battery.
-A voltaic battery depending for its action on the oxidation of hydrogen
-instead of the oxidation of zinc. Its action is more particularly
-described under Battery, Gas. In the cut B, B1 * * * are the terminals
-of the positive or hydrogen electrodes, marked H, and A, Al * * * are
-the terminals of the negative or oxygen electrodes marked O, while M, M1
-* * * is dilute sulphuric acid.
-
-
-282   STANDARD ELECTRICAL DICTIONARY.
-
-
-Guard Ring.
-An annular horizontal surface surrounding the balanced disc in the
-absolute electrometer. (See Electrometer, Absolute.)
-
-
-Guard Tube.
-A metal tube surrounding a dry pile used with a quadrant electrometer,
-or other electrometers of that type. It prevents the capacity of the
-lower brass end of the pile (which brass end closes the glass tube
-containing the discs) from momentary change by approach of some
-conductor connected to the earth. There are other guard tubes also.
-
-
-Gun, Electro-magnetic.
-An electro-magnet with tubular core. If, when it is excited a piece of
-an iron rod is pushed into the central aperture of the core and is
-released, the magnetic circle will try to complete itself by pushing the
-rod out so that it can thus be discharged, as if from a popgun.
-
-Synonym--Electric Popgun.
-
-
-Fig. 193. "ELECTRIC POPGUN."
-
-
-Gutta Percha.
-The hardened milky juice of a tree, the Isonandra gutta, growing in
-Malacca and other parts of the Eastern Archipelago. It is much used as
-an insulator or constituent of insulators.
-
-Resistance after several minutes electrification per 1 centimeter cube
-at 54� C. (75� F.),  4.50E14 ohms.
-
-The specific resistance varies--from 2.5E13 to 5.0E14 ohms. A usual
-specification is 2.0E14 ohms. The influence of temperature on its
-resistance is given in Clark & Bright's empirical formula, R = R0 at, in
-which R is the resistance at temperature t� C--Ro the resistance at 0� C
-(32� F), a is the coefficient .8944.
-
-The resistance increases with the time of passage of the current, the
-variation being less the higher the temperature.
-
-
-283   STANDARD ELECTRICAL DICTIONARY.
-
-
-Time of            Relative Resistance     Relative Resistance
-Electrification.   at 0� C (32� F.)        at 24� C (75� F.)
-   1 minute        100                     5.51
-   2   "           127.9                   6.
-   5   "           163.1                   6.66
-  10   "           190.9                   6.94
-  20   "           230.8                   7.38
-  30   "           250.6                   7.44
-  60   "           290.4                   7.6
-  90   "           318.3                   7.66
-
-In cable testing one minute is generally taken as the time of
-electrification.
-
-Pressure increases the resistance by the formula Rp=R (1+ .00327 P) in
-which Rp is the resistance at pressure p--R resistance at atmospheric
-pressure--p pressure in atmospheres. Thus in the ocean at a depth of
-4,000 meters (2.4855 miles), the resistance is more than doubled. The
-longer the pressure is applied, the greater is the resistance.
-
-The specific inductive capacity of gutta percha is 4.2.
-
-Good gutta percha should not break when struck with a hammer, should
-recover its shape slowly, and it should support much more than 300 times
-its own weight.
-
-
-Gyrostatic Action of Armatures.
-Owing to gyrostatic action a rotating armature resists any change of
-direction of its axis. On ships and in railway motors which have to turn
-curves this action occurs. A 148 lb. armature running at 1,300
-revolutions per minute may press with 30 lbs. on each journal as the
-ship rolls through an angle of 20� in 16 seconds.
-
-
-H.
-(a) The symbol for the horizontal component of the earth's
-magnetization.
-
-(b) The symbol for the intensity of a magnetizing force or field. The
-symbol H, as it is generally used, may mean either the number of dynes
-which act upon a unit pole, or the number of lines of force per
-centimeter.
-
-(c) The symbol for the unit of self-induction.
-
-
-Hair, Removal of, by Electrolysis.
-A method of depilation by destruction of individual hair follicles by
-electrolysis.
-
-A fine platinum electrode is thrust into a hair follicle. It is the
-negative electrode. The positive electrode is in contact with the body
-of the person under treatment; it is often a sponge electrode simply
-held in his hand. A current of two to four milliamperes from an E. M. F.
-of 15 to 20 volts, is passed. This destroys the follicle, the hair is
-removed and never grows again. A gradual increase of current is advised
-for the face. As only one hair is removed at once, but a small number
-are taken out at a sitting.
-
-
-284  STANDARD ELECTRICAL DICTIONARY.
-
-
-Haldat's Figures.
-With a pole of a strong bar magnet, used like a pencil, imaginary
-figures are drawn upon a hard steel plate, such as a saw-blade. The
-pattern is gone over several times. By dusting iron filings on a sheet
-of paper laid over the steel plate, while horizontal, very complicated
-magnetic figures are produced.
-
-
-Hall's Experiment.
-A cross of thin metal, such as gold leaf, is secured upon a pane of
-glass. To two opposite arms a battery is connected in circuit with them.
-To the other two arms a galvanometer is connected in circuit. If the
-cross is put into a field of force whose lines are perpendicular
-thereto, the galvanometer will disclose a constant current. The current
-is pushed, as it were, into the galvanometer circuit. Other metals have
-been used with similar results. They must be thin or the experiment
-fails. If the arm receiving the battery current is horizontal, and if it
-flows from left to right, and if the lines of force go from downward
-through the cross, the current in the galvanometer circuit will flow
-from the observer through the other arms of the cross, if the cross is
-of gold, silver, platinum or tin, and the reverse if of iron. The
-experiment has indicated a possible way of reaching the velocity of
-electricity in absolute measure.
-
-
-Hall Effect.
-The effect observed in Hall's experiment, q. v.
-
-
-Hall Effect, Real.
-A transverse electro-motive force in a conductor through which a current
-is passing produced by a magnetic field.
-
-
-Hall Effect, Spurious.
-A spurious electro-motive force produced in a conductor, through which a
-current is passing by changes in conductivity of the conductor brought
-about by a magnetic field.
-
-
-Hanger Board.
-A board containing two terminals, a suspending hook, and a switch, so
-that an arc lamp can be introduced into a circuit thereby, or can be
-removed as desired.
-
-
-Harmonic Receiver.
-A receiver containing a vibrating reed, acted on by an electro-magnet.
-Such a reed answers only to impulses tuned to its own pitch. If such are
-received from the magnet it will vibrate. Impulses not in tune with it
-will not affect it. (See Telegraph, Harmonic.)
-
-
-Head Bath, Electric.
-A fanciful name for an electro-medical treatment of the head. The
-patient is insulated by an insulating stool or otherwise. His person is
-connected with one terminal of an influence machine. An insulated
-metallic circle, with points of metal projecting inward or downward, is
-placed about the head. The circle is connected with the other pole of
-the machine. On working it a silent or brush discharge with air
-convection streams occurs between the patient's head and the circle of
-points.
-
-
-285   STANDARD ELECTRICAL DICTIONARY.
-
-
-Head-light, Electric.
-An electric head-light for locomotives has been experimented with. It
-includes the parabolic reflection of the regular light with an arc-lamp
-in place of the oil lamp. An incandescent lamp may be used in the same
-place, but has no great advantage over oil as regards illuminating
-power.
-
-
-Heat.
-A form of kinetic energy, due to a confused oscillatory movement of the
-molecules of a body. Heat is not motion, as a heated body does not
-change its place; it is not momentum, but it is the energy of motion. If
-the quantity of molecular motion is doubled the momentum of the
-molecules is also doubled, but the molecular mechanical energy or heat
-is quadrupled.
-
-As a form of energy it is measured by thermal units. The calorie is the
-most important, and unfortunately the same term applies to two units,
-the gram-degree C. and the kilogram-degree C. (See Calorie.) Calories
-are determined by a calorimeter, q. v.
-
-Independent of quantity of heat a body may be hotter or colder.
-Thermometers are used to determine its temperature.
-
-Heat is transmitted by conduction, a body conducting it slowly for some
-distance through its own substance. Bodies vary greatly in their
-conductivity for heat. It is also transmitted by convection of gases or
-liquids, when the heated molecules traveling through the mass impart
-their heat to other parts. Finally it is transmitted by ether waves with
-probably the speed of light. This mode of transmission and the phenomena
-of it were attributed to radiant heat. As a scientific term this is now
-dropped by many scientists. This practice very properly restricts the
-term "heat" to kinetic molecular motion.
-
-The mechanical equivalent of heat is the number of units of work which
-the energy of one unit quantity of heat represents. (See Equivalents,
-Mechanical and Physical.)
-
-
-Heat, Atomic.
-The product of the specific heat of an element by its atomic weight. The
-product is approximately the same for all the elements, and varies as
-determined between 5.39 and 6.87. The variations are by some attributed
-principally to imperfection of the work in determining them. The atomic
-heat represents the number of gram calories required to raise the
-temperature of a gram atom (a number of grams equal numerically to the
-atomic weight) one degree centigrade.
-
-
-286   STANDARD ELECTRICAL DICTIONARY.
-
-
-Heat, Electric.
-This term has been given to the heat produced by the passage of a
-current of electricity through a conductor. It is really electrically
-produced heat, the above term being a misnomer.
-
-The rise of temperature produced in a cylindrical conductor by a current
-depends upon the diameter of the conductor and on the current. The
-length of the wire has only the indirect connection that the current
-will depend upon the resistance and consequently upon its length.
-
-The quantity of heat produced in a conductor by a current is in
-gram-degree C. units equal to the product of the current, by the
-electro-motive force or potential difference maintained between the ends
-of the wire, by .24.
-
-The cube of the diameter of a wire for a given rise of temperature
-produced in such conductor by a current is equal approximately to the
-product of the square of the current, by the specific resistance (q. v.)
-of the material of the conductor, by .000391, the whole divided by the
-desired temperature in centigrade units.
-
-
-Heat, Electrical Convection of.
-A term applied to the phenomena included under the Thomson effect, q.
-v., the unequal or differential heating effect produced by a current of
-electricity in conductors whose different parts are maintained at
-different temperatures.
-
-
-Heater, Electric.
-An apparatus for converting electrical energy into thermal energy.
-
-An incandescent lamp represents the principle, and in the Edison meter
-has been used as such to maintain the temperature of the solutions.
-Heaters for warming water and other purposes have been constructed,
-utilizing conductors heated by the passage of the current as a source of
-heat. (See also Heating Magnet.)
-
-
-Heating Error.
-In voltmeters the error due to alteration of resistance of the coil by
-heating. If too strong a current is sent through the instrument, the
-coils become heated and their resistance increased. They then do not
-pass as much current as they should for the potential difference to
-which they may be exposed. Their readings then will be too low. One way
-of avoiding the trouble is to have a key in circuit, and to pass only an
-instantaneous or very brief current through the instrument and thus get
-the reading before the coils have time to heat.
-
-The heating error does not exist for ammeters, as they are constructed
-to receive the entire current, and any heating "error" within their
-range is allowed for in the dividing of the scale.
-
-
-Heating Magnet.
-An electro-magnet designed to be heated by Foucault currents induced in
-its core by varying currents in the windings. It has been proposed as a
-source of artificial heat, a species of electric heating apparatus for
-warming water, or other purposes.
-
-
-287   STANDARD ELECTRICAL DICTIONARY.
-
-
-Heat, Irreversible.
-The heat produced by an electric current in a conductor of identical
-qualities and temperature throughout. Such heat is the same whatever the
-direction of the current. The heating effect is irreversible because of
-the absence of the Thomson effect, q. v.) or Peltier effect, q. v.
-
-
-Heat, Mechanical Equivalent of.
-The mechanical energy corresponding to a given quantity of heat energy.
-Mechanical energy is generally represented by some unit of weight and
-height, such as the foot-pound; and heat energy is represented by a
-given weight of water heated a given amount, such as a pound-degree
-centigrade. Joule's equivalent is usually accepted; it states that
-772.55 foot pounds of mechanical energy are equivalent to 1 pound-degree
-F. (one pound avds. of water raised in temperature one degree
-Fahrenheit). Other equivalencies have also been deduced.
-
-
-Heat, Molecular.
-The product of a specific heat of the compound by its molecular weight.
-It is approximately equal to the sum of the atomic heats of its
-constituent elements.
-
-The molecular heat represents the number of gram calories required to
-raise the temperature of a gram-molecule (a number of grams equal
-numerically to the molecular weight) one degree centigrade.
-
-The molecular heat is approximately equal for all substances.
-
-
-Heat, Specific.
-The capacity of a body for heat; a coefficient representing the relative
-quantity of heat required to raise the temperature of an identical
-weight of a given body a defined and identical amount.
-
-The standard of comparison is water; its specific heat is taken as
-unity. The specific heats by weight of other substances are less than
-unity. The specific heat varies with the temperature. Thus the specific
-heat of water is more strictly 1+.00015 t� C.
-
-Specific heat is greater when a substance is in the liquid than when it
-is in the solid state. Thus the specific heat of ice is 0.489; less
-than half that of water. It differs with the allotropic modifications of
-bodies; the specific heat of graphite is .202; of diamond, .147.
-
-The product of the specific heat by the atomic weight of elements gives
-a figure approximately the same. A similar law applies in the case of
-molecules. (See Heat, Atomic-Heat, Molecular.)
-
-The true specific heat of a substance should be separated from the heat
-expended in expanding a body against molecular and atomic forces, and
-against the atmospheric pressure. So far this separation has not been
-possible to introduce in any calculations.
-
-
-288   STANDARD ELECTRICAL DICTIONARY.
-
-
-Heat, Specific, of Electricity.
-A proposed term to account for the heat absorbed or given out in
-unhomogeneous conductors, by the Thomson effect, or Peltier effect (see
-Effect, Thomson--Effect, Peltier.) If a current of electricity be
-assumed to exist, then under the action of these effects it may be
-regarded as absorbing or giving out so many coulombs of heat, and thus
-establishing a basis for specific heat.
-
-
-Heat Units.
-The British unit of heat is the pound degree F--the quantity of heat
-required to raise the temperature of a pound of water from 32� to 33� F.
-
-The C. G. S. unit is the gram-degree C.; another metric unit is the
-kilogram-degree C. The latter is the calorie; the former is sometimes
-called the small calorie or the joule; the latter is sometimes called
-the large calorie. The term joule is also applied to a quantity of heat
-equivalent to the energy of a watt-second or volt-coulomb. This is equal
-to .24l gram degree calorie.
-
-
-Hecto.
-A prefix to terms of measurement--meaning one hundred times, as
-hectometer, one hundred meters.
-
-
-Heliograph.
-An apparatus for reflecting flashes of light to a distant observer. By
-using the Morse telegraph code messages may thus be transmitted long
-distances. When possible the sun's light is used.
-
-
-Helix.
-A coil of wire; properly a coil wound so as to follow the outlines of a
-screw without overlaying itself.
-
-
-Fig. 194. LEFT-HANDED HELIX.
-
-
-Fig. 195. RIGHT-HANDED HELIX.
-
-
-Henry.
-The practical unit of electro-magnetic or magnetic inductance. It is
-equal to 1E9 C. G. S., or absolute units of inductance. As the
-dimensions of inductance are a length the henry is equal to 1E9
-centimeters, or approximately to one quadrant of the earth measured on
-the meridian.
-
-Synonyms--Secohm--Quadrant--Quad.
-
-
-289   STANDARD ELECTRICAL DICTIONARY.
-
-
-Hermetically Sealed.
-Closed absolutely tight. Glass vessels, such as the bulbs of
-incandescent lamps, are hermetically sealed often by melting the glass
-together over any opening into their interior.
-
-
-Heterostatic Method.
-A method of using the absolute or attracted disc electrometer. (See
-Electrometer Absolute.) The formula for its idiostatic use, q. v.,
-involves the determination of d, the distance between the suspended and
-fixed discs. As this is difficult to determine the suspended disc and
-guard ring may be kept at one potential and the lower fixed disc is then
-connected successively with the two points whose potential difference is
-to be determined. Their difference is determined by the difference
-between d and d', the two distances between the discs. This difference
-is the distance through which the micrometer screw is moved. The
-heterostatic formula is:
-
-V' - V = (d' - d)* squareRoot( 8*PI*F / S )
-
-in which V and V' are potentials of the two points; d' and d the two
-distances between the discs necessary for equilibrium; S the area of the
-disc and F the force of attraction in dynes. (See Idiostatic Method.)
-
-
-High Bars of Commutator.
-Commutator bars, which in the natural wear of the commutator, project
-beyond the others. The surface then requires turning down, as it should
-be quite cylindrical.
-
-
-High Frequency.
-A term used as a noun or as an adjective to indicate in an alternating
-current, the production of a very great number of alternations per unit
-of time--usually expressed as alternations per second.
-
-
-Hissing.
-A term applied to a noise sometimes produced by a voltaic arc; probably
-due to the same cause as frying, q. v.
-
-
-Hittorf's Solution.
-A solution used as a resistance. It is a solution of cadmium iodide in
-amylic alcohol. Ten per cent. of the salt is used. It is contained in a
-tube with metallic cadmium electrodes. (See Resistance, Hittorf' s.)
-
-
-Fig. 196. HITTORF'S RESISTANCE TUBE.
-
-
-290   STANDARD ELECTRICAL DICTIONARY.
-
-
-Holders.
-(a) The adjustable clamps for holding the armature brushes of dynamos
-and motors.
-
-(b) The clamps for holding the carbons of arc lamps.
-
-(c) The clamps for holding safety fuses, q. v.
-
-(d) Holders for Jablochkoff candles and other electric candles. (See
-Candle Holders.)
-
-(e) A box or block of porcelain for holding safety fuses.
-
-
-Hood.
-A tin hood placed over an arc-lamp. Such hoods are often truncated cones
-in shape, with the small end upwards. They reflect a certain amount of
-light besides protecting the lamp to some extent from rain.
-
-
-Horns.
-The extensions of the pole pieces of a dynamo or motor. (See Following
-Horns-Leading Horns.)
-
-Synonym--Pole Tips.
-
-
-Horse Power.
-A unit of rate of work or activity. There are two horse powers.
-
-The British horse power is equal to 33,000 pounds raised one foot per
-minute, or 550 foot pounds per second, or 1.0138 metric horse power.
-
-The metric horse power (French) is equal to 75 kilogram-meters, or 542
-foot pounds per second, or .986356 British horse power.
-
-H. P. is the abbreviation for horse power. (See Horse Power, Electric.)
-
-
-Horse Power, Actual.
-The rate of activity of a machine, as actually developed in condition
-for use. It is less than the indicated or total horse power, because
-diminished by the hurtful resistances of friction, and other sources of
-waste. It is the horse power that can be used in practise, and which in
-the case of a motor can be taken from the fly-wheel.
-
-
-Horse Power, Electric.
-The equivalent of a mechanical horse power in electric units, generally
-in volt-amperes or watts; 745.943 watts are equivalent to the activity
-of one British horse power; 735.75 are equivalent to one metric horse
-power. The number 746 is usually taken in practical calculations to give
-the equivalency.
-
-[Transcriber's note: Contemporary values are: Mechanical (British)
-horsepower = 745.6999 Watts; Metric horsepower = 735.49875 Watts]
-
-
-Horse Power, Indicated.
-The horse power of an engine as indicated by its steam pressure, length
-of stroke, and piston area, and vacuum, without making any deduction for
-friction or hurtful resistances. The steam pressure is in accurate work
-deduced from indicator diagrams.
-
-
-Horse Power, Hour.
-A horse power exerted for one hour, or the equivalent thereof. As the
-horse power is a unit of activity, the horse power hour is a unit of
-work or of energy. It is equal to 1,980,000 foot pounds.
-
-
-H. P.
-Abbreviation for "horse power."
-
-
-291   STANDARD ELECTRICAL DICTIONARY.
-
-
-Hughes' Electro-magnet.
-A horseshoe electro-magnet with polarized core. It is made by mounting
-two bobbins of insulated wire on the ends of a permanent horseshoe
-magnet. It was devised for use in Hughes' printing telegraph, where very
-quick action is required. The contact lasts only .053 second, 185
-letters being transmitted per minute.
-
-
-Fig. 197 HUGHES' ELECTRO-MAGNET.
-
-
-Fig. 198. HUGHES' INDUCTION BALANCE.
-
-
-Hughes' Induction Balance.
-An apparatus for determining the presence of a concealed mass of metal.
-The apparatus is variously connected. The cut shows a representative
-form; a and a' are two primary coils, each consisting of 100 meters (328
-feet) of No. 32 silk covered copper wire (0.009 inch diameter) wound on
-a boxwood spool ten inches in depth; b and b' are secondary coils. All
-coils are supposed to be alike. The primary coils are joined in series
-with a battery of three or four Daniell cells. A microphone m is
-included in the same circuit. The secondary coils are joined in series
-with a telephone and in opposition with each other. The clock is used to
-produce a sound affecting the microphone. If all is exactly balanced
-there will be no sound produced in the telephone. This balance is
-brought about by slightly varying the distance of one of the secondaries
-from the primary, until there is no sound in the telephone. If now a
-piece of metal is placed within either of the coils, it disturbs the
-balance and the telephone sounds.
-
-
-292   STANDARD ELECTRICAL DICTIONARY.
-
-
-To measure the forces acting a sonometer or audiometer is used. This is
-shown in the upper part of the cut. Two fixed coils, c and e are mounted
-at the ends of a graduated bar. A movable coil d is connected in the
-telephone circuit; c and e by a switch can be connected with the battery
-and microphone circuit, leaving out the induction balance coils. The
-ends of the coils c and e, facing each other are of the same polarity.
-If these coils, c and e, were equal in all respects, no sound would be
-produced when d was midway between them. But they are so wound that the
-zero position for d is very near one of them, c.
-
-Assume that a balance has been obtained in the induction balance with
-the coil d at zero. No sound is heard whether the switch is moved to
-throw the current into one or the other circuit. A piece of metal placed
-in one of the balance coils will cause the production of a sound. The
-current is turned into the sonometer and d is moved until the same
-sound, as tested by rapid movements of the switch, is heard in both
-circuits. The displacement of d gives the value of the sound.
-
-A milligram of copper is enough to produce a loud sound. Two coins can
-be balanced against each other, and by rubbing one of them, or by
-breathing on one of them, the balance will be disturbed and a sound will
-be produced.
-
-Prof. Hughes has also dispensed with the audiometer. He has used a strip
-of zinc tapering from a width of 4 mm. (.16 inch) at one end to a sharp
-edge or point at the other. The piece to be tested being in place in one
-coil, the strip is moved across the face of the other until a balance is
-obtained.
-
-As possible uses the detection of counterfeit coins, the testing of
-metals for similarity of composition and the location of bullets in the
-body have been suggested. Care has to be taken that no masses of metal
-interfere. Thus in tests of the person of a wounded man, the presence of
-an iron truss, or of metallic bed springs may invalidate all
-conclusions.
-
-The same principle is carried out in an apparatus in which the parts are
-arranged like the members of a Wheatstone bridge. One pair of coils is
-used, which react on each other as primary and secondary coils. One of
-the coils is in series with a telephone in the member of the bridge
-corresponding to that containing the galvanometer of the Wheatstone
-bridge. The latter is more properly termed an induction bridge.
-
-Synonyms--Inductance Bridge--Inductance Balance--Induction Bridge.
-
-
-293   STANDARD ELECTRICAL DICTIONARY.
-
-
-Hydro-electric. adj.
-(a) A current produced by a voltaic couple or the couple itself is
-sometimes thus characterized or designated as a "hydro-electric current"
-or a "hydro-electric couple." It distinguishes them from
-thermo-electric.
-
-(b) Armstrong's steam boiler electric machine (see Hydroelectric
-Machine) is also termed a hydro-electric machine.
-
-
-Hydro-electric Machine.
-An apparatus for generating high potential difference by the escape of
-steam through proper nozzles.
-
-It consists of a boiler mounted on four glass legs or otherwise
-insulated. An escape pipe terminates in a series of outlets so shaped as
-to impede the escape of the steam by forcing it out of the direct
-course. These jets are lined with hard wood. They are enclosed in or led
-through a box which is filled with cold water.
-
-
-Fig. 199. ARMSTRONG'S HYDRO-ELECTRIC MACHINE.
-
-
-This is to partly condense the steam so as to get it into the vesicular
-state, which is found essential to its action. Dry steam produces no
-excitation. If the boiler is fired and the steam is permitted to escape
-under the above conditions the vesicles presumably, or the "steam" is
-found to be electrified. A collecting comb held against the jet becomes
-charged and charges any connected surface.
-
-
-294   STANDARD ELECTRICAL DICTIONARY.
-
-
-The boiler in the above case is negatively and the escaping "steam" is
-positively charged. By changing the material of the linings of the jets,
-or by adding turpentine the sign of the electricity is reversed. If the
-water contains acid or salts no electricity is produced. The regular
-hydro-electric machine is due to Sir William Armstrong.
-
-Faraday obtained similar results with moist air currents.
-
-
-Hydrogen.
-An element existing under all except the most extreme artificial
-conditions of pressure and cold as a gas. It is the lightest of known
-substances. Atomic weight, 1; molecular weight, 2; equivalent, 1;
-valency, 1; specific gravity, .0691-.0695. (Dumas & Boussingault.)
-
-It is a dielectric of about the same resistance as air. Its specific
-inductive capacity at atmospheric pressure is:
-    .9997 (Baltzman)   .9998 (Ayrton)
-
-Electro-chemical equivalent, .0105 milligram.
-The above is usually taken as correct. Other values are as follows:
-.010521 (Kohllrausch)   .010415 (Mascart)
-
-The electro-chemical equivalent of any element is obtained by
-multiplying its equivalent by the electro-chemical equivalent of
-hydrogen. The value .0105 has been used throughout this book.
-
-
-Hygrometer.
-An instrument for determining the moisture in the air. One form consists
-of a pair of thermometers, one of which has its bulb wrapped in cloth
-which is kept moist during the observation. The evaporation is more or
-less rapid according to the dryness or moisture of the air, and as the
-temperature varies with this evaporation the relative readings of the
-two thermometers give the basis for calculating the hygrometric state of
-the air. Another form determines the temperature at which dew is
-deposited on a silver surface, whence the calculations are made.
-
-
-Hysteresis, Magnetic.
-A phenomenon of magnetization of iron. It may be attributed to a sort of
-internal or molecular friction, causing energy to be absorbed when iron
-is magnetized. Whenever therefore the polarity or direction of
-magnetization of a mass of iron is rapidly changed a considerable
-expenditure of energy is required. It is attributed to the work done in
-bringing the molecules into the position of polarity.
-
-
-295   STANDARD ELECTRICAL DICTIONARY.
-
-
-The electric energy lost by hysteresis may be reduced by vibrations or
-jarring imparted to the iron, thus virtually substituting mechanical for
-electrical work.
-
-On account of hysteresis the induced magnetization of a piece of iron or
-steel for fields of low intensity will depend on the manner in which the
-material has been already magnetized. Let the intensity of field
-increase, the magnetization increasing also; then lower the intensity;
-the substance tends to and does retain some of its magnetism. Then on
-again strengthening the field it will have something to build on, so
-that when it attains its former intensity the magnetization will exceed
-its former value. For a moderate value of intensity of field the
-magnetization can have many values within certain limits.
-
-Synonym--Hysteresis--Hysteresis, Static--Magnetic Friction.
-
-
-Hysteresis, Viscous.
-The gradual increase or creeping up of magnetization when a magnetic
-force is applied with absolute steadiness to a piece of iron. It may
-last for half an hour or more and amount to several per cent. of the
-total magnetization. It is a true magnetic lag.
-
-
-I.
-A symbol sometimes used to indicate current intensity. Thus Ohm's law is
-often expressed I = E/R, meaning current intensity is equal to
-electro-motive force divided by resistance. C is the more general symbol
-for current intensity.
-
-
-Ideoelectrics or Idioelectrics.
-Bodies which become electric by friction. This was the old definition,
-the term originating with Gilbert. It was based on a misconception, as
-insulation is all that is requisite for frictional electrification,
-metals being thus electrified if held by insulating handles. The term is
-virtually obsolete; as far as it means anything it means insulating
-substances such as scaling wax, sulphur, or glass.
-
-
-Idle Coils.
-Coils in a dynamo, in which coils no electro-motive force is being
-generated. This may occur when, as a coil breaks connection with the
-commutator brush, it enters a region void of lines of magnetic force, or
-where the lines are tangential to the circle of the armature.
-
-
-Idiostatic Method.
-A method of using the absolute or attracted disc electrometer. (See
-Electrometer, Absolute.) The suspended disc and guard ring are kept at
-the same potential, which is that of one of the points whose potential
-difference is to be determined; the lower fixed disc is connected to the
-other of the points whose potential difference is to be determined. Then
-we have the formula
-
-V = d * SquareRoot( 8 * PI * F ) / S
-
-in which d is the distance between the discs, V is the difference of
-potential of the two points, F the force of attraction between the discs
-in dynes, and S the area of the suspended disc. (See Heterostatic
-Method.)
-
-
-296   STANDARD ELECTRICAL DICTIONARY.
-
-
-Idle Poles.
-Poles of wire sealed into Crookes' tubes, not used for the discharge
-connections, but for experimental connections to test the effect of
-different excitation on the discharge.
-
-
-Idle Wire.
-In a dynamo the wire which plays no part in generating electro-motive
-force. In a Gramme ring the wire on the inside of the ring is idle wire.
-
-
-Igniter.
-In arc lamps with fixed parallel carbons of the Jablochkoff type (see
-Candle, Jablochkoff) a strip of carbon connects the ends of the carbons
-in the unused candle. This is necessary to start the current. Such strip
-is called an igniter. It burns away in a very short time when an arc
-forms producing the light, and lasts, if all goes well, until the candle
-burns down to its end. Without the igniter the current would not start
-and no arc would form.
-
-
-I. H. P.
-Symbol for indicated horse-power.
-
-
-Illuminating Power.
-The relative light given by any source compared with a standard light,
-and stated in terms of the same, as a burner giving an illuminating
-power of sixteen candles. For standards see Candle, Carcel--Methven
-Standard--Pentane Standard.
-
-
-Illuminating Power, Spherical.
-The illuminating power of a lamp or source of light may vary in
-different directions, as in the case of a gas burner or incandescent
-lamp. The average illuminating power determined by photometric test or
-by calculation in all directions from the source of light is called the
-spherical illuminating power, or if stated in candles is called the
-spherical candle power.
-
-
-Illumination, Unit of.
-An absolute standard of light received by a surface. Preece proposed as
-such the light received from a standard candle (see Candle, Standard) at
-a distance of 12.7 inches. The object of selecting this distance was to
-make it equal to the Carcel Standard (see Carcel), which is the light
-given by a Carcel lamp at a distance of one meter.
-
-From one-tenth to one-fiftieth this degree of illumination was found in
-gas-lighted streets by Preece, depending on the proximity of the gas
-lamps.
-
-
-Image, Electric.
-An electrified point or system of points on one side of a surface which
-would produce on the other side of that surface the same electrical
-action which the actual electrification of that surface really does
-produce. (Maxwell.)
-
-The method of investigating the distribution of electricity by electric
-images is due to Sir William Thomson. The conception is purely a
-theoretical one, and is of mathematical value and interest.
-
-
-297   STANDARD ELECTRICAL DICTIONARY.
-
-
-Impedance.
-The ratio of any impressed electro-motive force to the current which it
-produces in a conductor. For steady currents it is only the resistance.
-For variable currents it may include besides resistance inductance and
-permittance. It is the sum of all factors opposing a current, both ohmic
-and spurious resistances. It is often determined and expressed as ohms.
-
-Synonym--Apparent Resistance--Virtual Resistance.
-
-
-Impedance, Oscillatory.
-The counter-electro-motive force offered to an oscillatory discharge, as
-that of a Leyden jar. It varies with the frequency of the discharge
-current.
-
-Synonym--Impulsive Impedance.
-
-
-Impressed Electro-motive Force.
-The electro-motive force expending itself in producing current induction
-in a neighboring circuit.
-
-
-Impulse.
-(a) An electro-magnetic impulse is the impulse produced upon the
-luminiferous ether by an oscillatory discharge or other varying type of
-current; the impulse is supposed to be identical, except as regards
-wave-length, with a light wave.
-
-(b) An electro-motive impulse is the electro-motive force which rises so
-high as to produce an impulsive or oscillatory discharge, such as that
-of a Leyden jar.
-
-
-Incandescence, Electric.
-The heating or a conductor to red, or, more etymologically, to white
-heat by the passage of an electric current. The practical conditions are
-a high intensity of current and a low degree of conductance of the
-conductor relatively speaking.
-
-
-Inclination Map.
-A map showing the locus of equal inclination or dips of the magnetic
-needle. The map shows a series of lines, each one of which follows the
-places at which the dip of the magnetic needle is identical. The map
-changes from year to year. (See Magnetic Elements.)
-
-
-Independence of Currents in Parallel Circuits.
-If a number of parallel circuits of comparatively high resistance are
-supplied by a single generator of comparatively low resistance, the
-current passed through each one will be almost the same whether a single
-one or all are connected. Under the conditions named the currents are
-practically independent of each other.
-
-[Transcriber's note: The current in each parallel branch depends on the
-resistance/impedance of that branch. Only if they all have the same
-impedance will the current be the same.]
-
-
-Indicating Bell.
-An electric bell arranged to drop a shutter or disclose in some other
-way a designating number or character when rung.
-
-
-298   STANDARD ELECTRICAL DICTIONARY.
-
-
-Indicator.
-(a) An apparatus for indicating the condition of a distant element, such
-as the water level in a reservoir, the temperature of a drying room or
-cold storage room or any other datum. They are of the most varied
-constructions.
-
-(b) The receiving instrument in a telegraph system is sometimes thus
-termed.
-
-
-Indicator, Circuit.
-A galvanometer used to show when a circuit is active, and to give an
-approximate measurement of its strength. It is a less accurate and
-delicate form of instrument than the laboratory appliance.
-
-
-Inductance.
-The property of a circuit in virtue of which it exercises induction and
-develops lines of force. It is defined variously. As clear and
-satisfactory a definition as any is the following, due to Sumpner and
-Fleming: Inductance is the ratio between the total induction through a
-circuit to the current producing it. "Thus taking a simple helix of five
-turns carrying a current of two units, and assuming that 1,000 lines of
-force passed through the central turn, of which owing to leakage only
-900 thread the next adjacent on each side, and again only 800 through
-the end turns, there would be 800 + 900 + 1000 + 900 + 800, or 4,400
-linkages of lines with the wire, and this being with 2 units of current,
-there would be 2,200 linkages with unit current, and consequently the
-self-inductance of the helix would be 2,200 centimetres." (Kennelly.)
-Inductance, as regards its dimensions is usually reduced to a length,
-hence the last word of the preceding quotation.
-
-The practical unit of inductance is termed the henry, from Prof. Joseph
-Henry; the secohm, or the quad or quadrant. The latter alludes to the
-quadrant of the earth, the value in length of the unit in question.
-
-[Transcriber's note: (L (di/dt) = V). A current changing at the rate of
-one ampere per second through a one henry inductance produces one volt.
-A sinusoidal current produces a voltage 90 degrees ahead of the current,
-a cosine (the derivative of sine is cosine). One volt across one henry
-causes the current to increase at one ampere per second.]
-
-
-Induction, Coefficient of Self.
-The coefficient of self-induction of a circuit is the quantity of
-induction passing through it per unit current in it. If a given circuit
-is carrying a varying current it is producing a varying quantity of
-magnetic induction through itself. The quantity of induction through the
-circuit due to its current is generally proportional to its current. The
-quantity for unit current is the coefficient of self-induction.
-(Emtage.)
-
-
-Induction, Cross.
-The induction of magnetic lines of force in a dynamo armature core by
-the current passing around such armature. These lines in a symmetrical
-two pole machine are at right angles to the lines of force which would
-normally extend across the space between the two magnet poles. The joint
-magnetizing effect of the field and of the cross induction produces a
-distorted field between the poles .
-
-Synonym--Cross-magnetizing Effect.
-
-
-299   STANDARD ELECTRICAL DICTIONARY.
-
-
-Induction, Electro-magnetic.
-The inter-reaction of electromagnetic lines of force with the production
-of currents thereby.
-
-A current passing through a conductor establishes around it a field of
-force representing a series of circular lines of force concentric with
-the axis of the conductor and perpendicular thereto. These lines of
-force have attributed to them, as a representative of their polarity,
-direction. This is of course purely conventional. If one is supposed to
-be looking at the end of a section of conductor, assuming a current be
-passing through it towards the observer, the lines of force will have a
-direction opposite to the motion of the hands of a watch. The idea of
-direction may be referred to a magnet. In it the lines of force are
-assumed to go from the north pole through the air or other surrounding
-dielectric to the south pole.
-
-Two parallel wires having currents passing through them in the same
-direction will attract each other. This is because the oppositely
-directed segments of lines of force between the conductors destroy each
-other, and the resultant of the two circles is an approximation to an
-ellipse. As lines of force tend to be as short as possible the
-conductors tend to approach each other to make the ellipse become of as
-small area as possible, in other words to become a circle.
-
-If on the other hand the currents in the conductors are in opposite
-directions the segments of the lines of force between them will have
-similar directions, will, as it were, crowd the intervening ether and
-the wires will be repelled.
-
-
-Fig. 200. ATTRACTION OF CONDUCTORS CARRYING SIMILAR CURRENTS.
-
-
-By Amp�re's theory of magnetism, (see Magnetism, Amp�re's Theory of,) a
-magnet is assumed to be encircled by currents moving in the direction
-opposite to that of the hands of a watch as the observer faces the north
-pole. A magnet near a wire tends to place the Amp�rian currents parallel
-to the wire, and so that the portion of the Amp�rian currents nearest
-thereto will correspond in direction with the current in the wire.
-
-
-300   STANDARD ELECTRICAL DICTIONARY.
-
-
-This is the principle of the galvanometer. A number of methods of
-memoria technica have been proposed to remember it by.
-
-Thus if we imagine a person swimming with the current and always facing
-the axis of the conductor, a magnetic needle held where the person is
-supposed to be will have its north pole deflected to the right hand of
-the person.
-
-
-Fig. 201. REPULSION OF CONDUCTORS CARRYING OPPOSITE CURRENTS.
-
-
-Again if we think of a corkscrew, which as it is turned screws itself
-along with the current, the motion of the handle shows the direction of
-the lines of force and the direction in which the north pole of a needle
-is deflected. This much is perhaps more properly electro-dynamics, but
-is necessary as a basis for the expression of induction.
-
-If a current is varied in intensity in one conductor it will induce a
-temporary current in another conductor, part of which is parallel to the
-inducing current and which conductor is closed so as to form a circuit.
-If the inducing current is decreased the induced current in the near and
-parallel portion of the other circuit will be of identical direction; if
-increased the induced current will be of opposite direction.
-
-This is easiest figured by thinking of the lines of force surrounding
-the inducing conductor. If the current is decreased these can be
-imagined as receiving a twist or turn contrary to their normal
-direction, as thereby establishing a turn or twist in the ether
-surrounding the other wire corresponding in direction with the direction
-of the original lines of force, or what is the same thing, opposite in
-direction to the original twist. But we may assume that the
-establishment of such a disturbance causes a current, which must be
-governed in direction with the requirements of the new lines of force.
-
-The same reasoning applies to the opposite case.
-
-
-301    STANDARD ELECTRICAL DICTIONARY.
-
-
-The general statement of a variable current acting on a neighboring
-circuit also applies to the approach or recession of an unvarying
-current, and to the cutting of lines of force by a conductor at right
-angles thereto. For it is evident that the case of a varying current is
-the case of a varying number of lines of force cutting or being cut by
-the neighboring conductor. As lines of force always imply a current,
-they always imply a direction of such current. The cutting of any lines
-of force by a closed conductor always implies a change of position with
-reference to all portions of such conductor and to the current and
-consequently an induced current or currents in one or the other
-direction in the moving conductor.
-
-As the inducing of a current represents energy abstracted from that of
-the inducing circuit, the direction of the induced current is determined
-by (Lenz's Law) the rule that the new current will increase already
-existing resistances or develop new ones to the disturbance of the
-inducing field.
-
-In saying that a conductor cutting lines of force at right angles to
-itself has a current induced in it, it must be understood that if not at
-right angles the right angle component of the direction of the wire acts
-in generating the current. The case resolves itself into the number of
-lines of force cut at any angle by the moving wire.
-
-The lines of force may be produced by a magnet, permanent or electro.
-This introduces no new element. The magnet may be referred, as regards
-direction of its lines of force, to its encircling currents, actual or
-Amp�rian, and the application of the laws just cited will cover all
-cases.
-
-
-Induction, Coefficient of Mutual.
-The coefficient of mutual induction of two circuits is the quantity of
-magnetic induction passing through either of them per unit current in
-the other. (Emtage.) It is also defined as the work which must be done
-on either circuit, against the action of unit current in each, to take
-it away from its given position to an infinite distance from the other;
-and also as the work which would be done by either circuit on the other
-in consequence of unit current in each, as the other moves from an
-infinite distance to its given position with respect to the other
-conductor. It depends on the form, size, and relative position of the
-two circuits; and on the magnetic susceptibilities of neighboring
-substances.
-
-The ether surrounding two circuits of intensity i' and i" must possess
-energy, expressible (Maxwell) as 1/2 L i2 + M i i + 1/2 N i12. It can be
-shown that M i i1 in any given position of the two circuits is
-numerically equal (1) to the mutual potential energy of the two circuits
-(2) to the number of lines of induction, which being due to A, pass from
-A through B, or equally being due to B, pass from B through A, and M is
-styled the coefficient of mutual induction. (Daniell.)
-
-
-302   STANDARD ELECTRICAL DICTIONARY.
-
-
-Induction, Electrostatic.
-An electrostatic charge has always an opposite and bound charge. This
-may be so distributed as not to be distinguishable, in which case the
-charge is termed, incorrectly but conventionally, a free charge. But
-when a charge is produced an opposite and equal one always is formed,
-which is the bound charge. The region between the two charges and
-permeated by their lines of force, often curving out so as to embrace a
-volume of cross-sectional area larger than the mean facing area of the
-excited surfaces, is an electrostatic field of force. The establishing
-of an electrostatic field, and the production of a bound charge are
-electrostatic induction.
-
-An insulated conductor brought into such a field suffers a
-redistribution of its electricity, or undergoes electrostatic induction.
-The parts nearest respectively, the two loci of the original and the
-bound charges, are excited oppositely to such charges. The conductor
-presents two new bound charges, one referred to the original charge, the
-other to the first bound charge.
-
-
-Induction, Horizontal.
-In an iron or steel ship the induction exercised upon the compass needle
-by the horizontal members of the structure, such as deck-beams, when
-they are polarized by the earth's magnetic induction. This induction
-disappears four times in swinging a ship through a circle; deviation due
-to it is termed quadrantal deviation. (See Deviation, Quadrantal.)
-
-
-Induction, Lateral.
-A term formerly used to express the phenomenon of the alternative
-discharge of a Leyden jar or other oscillatory discharge of electricity.
-(See Discharge, Alternative.)
-
-
-Induction, Magnetic.
-The magnetization of iron or other paramagnetic substance by a magnetic
-field.
-
-On account of its permeability or multiplying power for lines of force,
-a paramagnetic body always concentrates lines of force in itself if
-placed in a magnetic field, and hence becomes for the time being a
-magnet, or is said to be polarized.
-
-As the tendency of lines of force is to follow the most permeable path,
-a paramagnetic bar places itself lengthwise or parallel with the
-prevailing direction of the lines of force so as to carry them as far on
-their way as possible. Every other position of the bar is one of
-unstable equilibrium or of no equilibrium. The end of the bar where the
-lines of force enter (see Lines of Force) is a south pole and is
-attracted towards the north pole of the magnet.
-
-The production of magnetic poles under these conditions in the bar is
-shown by throwing iron filings upon it. They adhere to both ends but not
-to the middle.
-
-
-Induction, Mutual, Electro-magnetic.
-The induction due to two electric currents reacting on each other.
-
-
-303  STANDARD ELECTRICAL DICTIONARY.
-
-
-Induction, Mutual, Electrostatic.
-A charged body always induces a charge upon any other body near it; and
-the same charge in the second body will induce the other charge in the
-first body if the latter is unexcited. In other words the second body's
-induction from the first is the measure of the charge the second would
-require to induce in the first its own (the second's) induced charge.
-This is the law of mutual electrostatic induction.
-
-
-Induction, Open Circuit.
-Inductive effects produced in open circuits. By oscillatory discharges a
-discharge can be produced across a break in a circuit otherwise
-complete. The requirements for its production involve a correspondence
-or relation of its dimensions to the inducing discharge. The whole is
-analogous to the phenomena of sound resonators and sympathetic
-vibrations. Synonym--Oscillatory induction.
-
-
-Induction, Self-.
-(a) A phenomenon of electric currents analogous to the inertia of
-matter. Just as water which fills a pipe would resist a sudden change in
-its rate of motion, whether to start from rest, to cease or decrease its
-motion, so an electric current requires an appreciable time to start and
-stop. It is produced most strongly in a coiled conductor, especially if
-a core of iron is contained within it.
-
-As in the case of two parallel wires, one bearing currents which vary,
-momentary currents are induced in the other wire, so in a single
-conductor a species of inertia is found which retards and prolongs the
-current. If a single conductor is twisted into a helix or corresponding
-shape, its separate turns react one on the other in accordance with the
-general principles of electromagnetic induction. (See Induction,
-Electro-magnetic.) Thus when a current is suddenly formed the coils
-acting upon each other retard for an instant its passage, producing the
-effect of a reverse induced current or extra current opposing the
-principal current. Of course no extra current is perceptible, but only
-the diminution. When the current is passing regularly and the current is
-broken, the corresponding action prolongs the current or rather
-intensifies it for an instant, producing the true extra current. This is
-current self-induction.
-
-[Transcriber's note: See inductance.]
-
-Synonyms--Electric Inertia--Electro-dynamic Capacity.
-
-(b) A permanent magnet is said to tend to repel its own magnetism, and
-thus to weaken itself; the tendency is due to magnetic self-induction.
-
-
-Induction Sheath.
-In the brush dynamo a thin sheet of copper surrounding the magnet cores
-with edges soldered together. The winding is outside of it. Its object
-is to absorb extra currents set up by variations in magnetic intensity
-in the cores. These currents otherwise would circulate in the cores.
-
-
-304   STANDARD ELECTRICAL DICTIONARY.
-
-
-Induction, Unit of Self-.
-The unit of self-induction is the same as that of induction in general.
-It is the henry, q. v.
-
-
-Induction, Unipolar.
-Induction produced in a conductor which continuously cuts the lines of
-force issuing from one pole of a magnet. As the lines of force are
-always cut in the same sense a continuous and constant direction current
-is produced.
-
-
-Induction, Vertical.
-In an iron or steel ship the induction or attraction exercised in the
-compass by vertical elements of the structure. Such vertical masses of
-iron in the northern hemisphere would have their upper ends polarized as
-south poles, and would affect the magnet as soon as the vessel swung out
-of the magnetic meridian. Thus this induction disappears twice in
-swinging a ship through a complete circle; deviation due to it is termed
-semi-circular deviation. (See Deviation, Semi-circular.)
-
-
-Fig. 202. INDUCTOR DYNAMO.
-
-
-Inductophone.
-A method of train telegraphy. The train carries a circuit including a
-coil, and messages are picked up by it from coils along the line into
-which an alternating current is passed. A telephone is used as a
-receiver in place of a sounder or relay. The invention, never
-practically used, is due to Willoughby Smith.
-
-
-305    STANDARD ELECTRICAL DICTIONARY.
-
-
-Inductor.
-(a) In a current generator a mass of iron, generally laminated, which is
-moved past a magnet pole to increase the number of lines of force
-issuing therefrom. It is used in inductor dynamos. (See Dynamo
-Inductor.) In the cut Fig. 202, of an inductor dynamo i, i, are the
-laminated inductors.
-
-(b) In influence machines the paper or tinfoil armatures on which the
-electrification is induced.
-
-
-Inertia.
-A force in virtue of which every body persists in its state of motion or
-rest except so far as it is acted on by some force.
-
-
-Inertia, Electro-magnetic.
-This term is sometimes applied to the phenomena of self-induction, or
-rather to the cause of these phenomena.
-
-
-Infinity Plug.
-A plug in a resistance box, which on being pulled out of its seat opens
-the circuit or makes it of infinite resistance. The plug seats itself
-between two brass plates which are not connected with each other in any
-way. The other plates are connected by resistance coils of varying
-resistance.
-
-
-Influence, Electric.
-Electric induction, which may be either electrostatic, current, or
-electro-magnetic.
-
-
-Insolation, Electric.
-Exposure to powerful arc-light produces effects resembling those of
-sun-stroke. The above term or the term "electric sun-stroke" has been
-applied to them.
-
-[Transcriber's note: Operators of arc welders are prone to skin cancer
-from ultra violet rays if not properly protected.]
-
-
-Installation.
-The entire apparatus, buildings and appurtenances of a technical or
-manufacturing establishment. An electric light installation, for
-instance, would include the generating plant, any special buildings, the
-mains and lamps.
-
-
-Insulating Stool.
-A support for a person, used in experiments with static generators. It
-has ordinarily a wooden top and glass legs. It separates one standing on
-it from the earth and enables his surface to receive an electrostatic
-charge. This tends to make his hair stand on end, and anyone on the
-floor who touches him will receive a shock.
-
-
-Insulating Tape.
-Prepared tape used in covering the ends of wire where stripped for
-making joints. After the stripped ends of two pieces are twisted
-together, and if necessary soldered and carefully cleaned of soldering
-fluid, they may be insulated by being wound with insulating tape.
-
-The tape is variously prepared. It may be common cotton or other tape
-saturated with any insulating compound, or may be a strip of gutta
-percha or of some flexible cement-like composition.
-
-
-306   STANDARD ELECTRICAL DICTIONARY.
-
-
-Insulating Varnish.
-Varnish used to coat the surface of glass electrical apparatus, to
-prevent the deposition of hygrometric moisture, and also in the
-construction of magnetizing and induction coils and the like. Shellac
-dissolved in alcohol is much used. Gum copal dissolved in ether is
-another. A solution of sealing wax in alcohol is also used. If applied
-in quantities these may need baking to bring about the last drying. (See
-Shellac Varnish.)
-
-
-Insulator.
-(a) Any insulating substance.
-
-(b) A telegraph or line insulator for telegraph wires. (See Insulator,
-Line or Telegraph.)
-
-Synonyms--Dielectric--Non-conductor.
-
-
-Insulator Cap.
-A covering or hood, generally of iron, placed over an insulator to
-protect it from injury by fracture with stones or missiles.
-
-
-Insulator, Fluid.
-(a) For very high potentials, as in induction coils or alternating
-circuits, fluid insulators, such as petroleum or resin oil, have been
-used. Their principal merit is that if a discharge does take place
-through them the opening at once closes, so that they are self-healing.
-
-(b) Also a form of telegraph or line insulator in which the lower rim is
-turned up and inwards, so as to form an annular cup which is filled with
-oil.
-
-
-Insulator, Line or Telegraph.
-A support often in the shape of a collar or cap, for a telegraph or
-other wire, made of insulating material. Glass is generally used in the
-United States, porcelain is adopted for special cases; pottery or stone
-ware insulators have been used a great deal in other countries.
-Sometimes the insulator is an iron hook set into a glass screw, which is
-inserted into a hole in a telegraph bracket. Sometimes a hook is caused
-to depend from the interior of an inverted cup and the space between the
-shank of the hook and cup is filled with paraffine run in while melted.
-
-Insulators are tested by measuring their resistance while immersed in a
-vessel of water.
-
-
-Intensity. Strength.
-The intensity of a current or its amperage or strength; the intensity or
-strength of a magnetic field or its magnetic density; the intensity or
-strength of a light are examples of its use. In the case of dynamic
-electricity it must be distinguished from tension. The latter
-corresponds to potential difference or voltage and is not an attribute
-of current; intensity has no reference to potential and is a
-characteristic of current.
-
-
-Intensity of a Magnetic Field.
-The intensity of a magnetic field at any point is measured by the force
-with which it acts on a unit magnet pole placed at that point. Hence
-unit intensity of field is that intensity of field which acts on a unit
-pole with a force of one dyne. (S. P. Thomson.) (See Magnetic Lines of
-Force.)
-
-
-307   STANDARD ELECTRICAL DICTIONARY.
-
-
-Intercrossing.
-Crossing a pair of conductors of a metallic circuit from side to side to
-avoid induction from outside sources.
-
-
-Intermittent.
-Acting at intervals, as an intermittent contact, earth, or grounding of
-a telegraph wire.
-
-
-Interpolar Conductor.
-A conductor connecting the two poles of a battery or current generator;
-the external circuit in a galvanic circuit.
-
-
-Interpolation.
-A process used in getting a closer approximation to the truth from two
-varying observations, as of a galvanometer. The process varies for
-different cases, but amounts to determining an average or deducing a
-proportional reading from the discrepant observed ones.
-
-
-Interrupter.
-A circuit breaker. It may be operated by hand or be automatic. (See
-Circuit Breaker--Circuit Breaker, Automatic--and others.)
-
-
-Interrupter, Electro-magnetic, for a Tuning Fork.
-An apparatus for interrupting a current which passes through an
-electromagnet near and facing one of the limbs of a tuning fork. The
-circuit is made and broken by the vibrations of another tuning fork
-through which the current passes. The second one is thus made to
-vibrate, although it may be very far off and may not be in exact unison
-with the first. The first tuning fork has a contact point on one of its
-limbs, to close the circuit; it may be one which dips into a mercury
-cup.
-
-
-Intrapolar Region.
-A term in medical electricity, denoting the part of a nerve through
-which a current is passing.
-
-
-Ions.
-The products of decomposition produced in any given electrolysis are
-termed ions, the one which appears at the anode or negative electrode is
-the anion. The electrode connected to the carbon or copper plate of a
-wet battery is an anode. Thus in the electrolysis of water oxygen is the
-anion and hydrogen is termed the kation. In this case both anion and
-kation are elements. In the decomposition of copper sulphate the anion
-is properly speaking sulphion (S O4), a radical, and the kation is
-copper, an element. Electro-negative elements or radicals are anions,
-such as oxygen, sulphion, etc., while electro-positive ones are kations,
-such as potassium. Again one substance may be an anion referred to one
-below it and a kation referred to one above it, in the electro-chemical
-series, q. v. Anion means the ion which goes to the anode or positive
-electrode; kation, the ion which goes to the kathode or negative
-electrode.
-
-[Transcriber's note: An ion is an atom or molecule that has lost or
-gained one or more valence electrons, giving it a positive or negative
-electrical charge. A negatively charged ion, with more electrons than
-protons in its nuclei, is an anion. A positively charged ion, with fewer
-electrons than protons, is a cation. The electron was discovered five
-years after this publication.]
-
-
-308   STANDARD ELECTRICAL DICTIONARY.
-
-
-Iron.
-A metal; one of the elements; symbol, Fe; atomic weight, 56;
-equivalent, 28 and 14, ; valency, 4 and 2.
-It is a conductor of electricity. The following data are at
-0� C. 32� F., with annealed metal.
-
-  Specific Resistance,   9.716 microhms.
-  Relative Resistance.   6.460
-  Resistance of a wire,
-  (a) 1 foot long weighing 1 grain,      1.085   ohms.
-  (b) 1 foot long 1/1000 inch thick,    58.45     "
-  (c) 1 meter long weighing 1 gram,       .7570   "
-  (d) 1 meter long, 1 millimeter thick,   .1237   "
-Percentage increase in resistance per degree C. (1.8� F.)
-  at about 20� C. (68�F.), about 0.5 per cent.
-Resistance of a 1 inch cube,   3.825 microhms.
-Electro-chemical equivalent (Hydrogen = .0105), .147 and .294
-
-
-Iron, Electrolytic.
-Iron deposited by electrolytic action. Various baths are employed for
-its formation. (See Steeling.) It has very low coercive power, only
-seven to ten times that of nickel.
-
-
-Ironwork Fault of a Dynamo.
-A short circuiting of a dynamo by, or any connection of its coils with,
-the iron magnet cores or other iron parts.
-
-
-Isochronism.
-Equality of periodic time; as of the times of successive beats of a
-tuning fork, or of the times of oscillations of a pendulum.
-
-
-Isoclinic Lines.
-The lines denoting the locus of sets of equal dips or inclinations of
-the magnetic needle upon the earth's surface, the magnetic parallels, q.
-v. These lines are very irregular. (See Magnetic Elements.)
-
-
-Isoclinic Map.
-A map showing the position of isoclinic lines.
-
-
-Isodynamic Lines.
-Lines marking the locus of places of equal magnetic intensity on the
-earth's surface. (See Magnetic Elements, Poles of Intensity.)
-
-
-Isodynamic Map.
-A map showing the position of isodynamic lines. (See Poles of
-Intensity.)
-
-Isogonic Lines.
-Lines on a map marking the locus of or connecting those points where the
-declination or variation of the magnetic needle is the same. (See
-Magnetic Elements--Declination of Magnetic Needle.)
-
-Synonyms--Isogonal Lines--Halleyan Lines.
-
-
-309  STANDARD ELECTRICAL DICTIONARY.
-
-
-Isogonic Map.
-A map showing the isogonic lines. On such a map each line is
-characterized and marked with the degrees and direction of variation of
-the compass upon itself.
-
-Synonym--Declination Map.
-
-
-Isolated Plant, Distribution or Supply.
-The system of supplying electric energy by independent generating
-systems, dynamo or battery, for each house, factory or other place, as
-contra-distinguished from Central Station Distribution or Supply.
-
-
-Isotropic.
-(Greek, equal in manner.)
-
-Having equal properties in all directions; the reverse of anisotropic,
-q. v. Thus a homogeneous mass of copper or silver has the same specific
-resistance in all directions and is an isotropic conductor. Glass has
-the same specific inductive capacity in all directions and is an
-isotropic medium or dielectric. The same applies to magnetism. Iron is
-an isotropic paramagnetic substance. (See Anisotropic.) The term applies
-to other branches of physics also.
-
-
-I. W. G.
-Contraction for Indian Wire Gauge--the gauge adopted in British India.
-
-
-J.
-Symbol for the unit joule, the unit of electric energy.
-
-
-Jacobi's Law.
-A law of electric motors. It states that the maximum work of a motor is
-performed when the counter-electromotive force is equal to one-half the
-electro-motive force expended on the motor.
-
-
-Jewelry.
-Small incandescent lamps are sometimes mounted as articles of jewelry in
-scarf-pins or in the hair. They may be supplied with current from
-storage or from portable batteries carried on the person.
-
-
-Joint, American Twist.
-A joint for connecting telegraph wires, especially aerial lines. Its
-construction is shown in the cut. The end of each wire is closely wound
-around the straight portion of the other wire for a few turns.
-
-
-Fig. 203. AMERICAN TWIST JOINT.
-
-
-310   STANDARD ELECTRICAL DICTIONARY.
-
-
-Joint, Britannia.
-A joint for uniting the ends of telegraph and electric wires. The ends
-of the wires are scraped clean and laid alongside each other for two
-inches, the extreme ends being bent up at about right angles to the
-wire. A thin wire is wound four or five times around one of the wires,
-back of the joint, the winding is then continued over the lapped
-portion, and a few more turns are taken around the other single wire.
-The whole is then soldered.
-
-
-Fig. 204. BRITANNIA JOINT.
-
-
-Joint, Butt.
-A joint in belting or in wire in which the ends to be joined are cut off
-square across, placed in contact and secured. It ensures even running
-when used in belting. Any irregularity in thickness of a belt affects
-the speed of the driven pulley. As dynamos are generally driven by
-belts, and it is important to drive them at an even speed to prevent
-variations in the electro-motive force, butt joints should be used on
-belting for them, unless a very perfect lap joint is made, which does
-not affect either the thickness or the stiffness of the belt.
-
-When a butt joint is used in wire a sleeve may be used to receive the
-abutting ends, which may be secured therein by soldering. This species
-of joint has been used on lightning rods and may more properly be termed
-a sleeve joint.
-
-
-Joint, Lap.
-(a) In belting a joint in which the ends are overlapped, and riveted or
-otherwise secured in place. If made without reducing the thickness of
-the ends it is a bad joint for electrical work, as it prevents even
-running of machinery to which it is applied. Hence dynamo belts should
-be joined by butt joints, or if by lap joints the ends should be shaved
-off so that when joined and riveted, there will be no variation in the
-thickness of the belt.
-
-(b) In wire lap joints are made by overlapping the ends of the wire and
-soldering or otherwise securing. The Britannia joint (see Joint,
-Britannia,) may be considered a lap-joint.
-
-
-Joint, Marriage.
-A joint for stranded conductors used for Galende's cables. It is made
-somewhat like a sailor's long splice. Each one of the strands is wound
-separately into the place whence the opposite strand is unwound and the
-ends are cut off so as to abutt. In this way all are smoothly laid in
-place and soldering is next applied.
-
-
-Fig. 205. MARRIAGE JOINT.
-
-
-311   STANDARD ELECTRICAL DICTIONARY.
-
-
-Joint, Sleeve.
-A joint in electric conductors, in which the ends of the wires are
-inserted into and secured in a metallic sleeve or tube, whose internal
-diameter is just sufficient to admit them.
-
-
-Joint, Splayed.
-The method of joining the ends of stranded conductors. The insulating
-covering is removed, the wires are opened out, and the center wire,
-heart or core of the cable is cut off short. The two ends are brought
-together, the opened out wires are interlaced or crotched like the
-fingers of the two hands, and the ends are wound around the body of the
-cable in opposite directions. The joint is trimmed and well soldered.
-Tinned wire with rosin flux for the soldering is to be recommended.
-Insulating material is finally applied by hand, with heat if necessary.
-
-Joints in Belts.
-Belt-joints for electric plants where the belts drive dynamos should be
-made with special care. The least inequality affects the electro-motive
-force. Butt joints are, generally speaking, the best, where the ends of
-the belt are placed in contact and laced. Lap-joints are made by
-overlapping the belt, and unless the belt is carefully tapered so as to
-preserve uniform strength, the speed of the dynamo will vary and also
-the electromotive force.
-
-
-Joulad.
-A name proposed to be substituted for "joule," q. v. It has not been
-adopted.
-
-
-Joule.
-This term has been applied to several units.
-
-(a) The practical C. G. S. unit of electric energy and work--the
-volt-coulomb. It is equal to 1E7 ergs--0.73734 foot pound.--.00134 horse
-power seconds. A volt-ampere represents one joule per second.
-
-(b) It has also been used as the name of the gram-degree C. thermal
-unit--the small calorie.
-
-Synonym--Joulad.
-
-
-Joule Effect.
-The heating effect of a current passing through a conductor. It varies
-with the product of the resistance by the square of the current, or with
-(C^2)*R.
-
-
-Joule's Equivalent.
-The mechanical equivalent of heat, which if stated in foot-pounds per
-pound-degree F. units, is 772 (772.55). (See Equivalents.)
-
-
-Junction Box.
-In underground distribution systems, an iron casing or box in which the
-feeders and mains are joined, and where other junctions are made.
-
-Synonym--Fishing Box.
-
-
-K.
-The symbol for electrostatic capacity.
-
-
-Kaolin.
-A product of decomposition of feldspar, consisting approximately of
-silica, 45, alumina, 40, water, 15. It was used in electric candles of
-the Jablochkoff type as a constituent of the insulating layer or
-colombin. Later it was abandoned for another substance, as it was found
-that it melted and acted as a conductor.
-
-
-312   STANDARD ELECTRICAL DICTIONARY.
-
-
-Kapp Line of Force.
-A line of force proposed by Kapp. It is equal to 6,000 C. G. S. lines of
-force, and the unit of area is the square inch. Unfortunately it has
-been adopted by many manufacturers, but its use should be discouraged,
-as it is a departure from the uniform system of units.
-
-One Kapp line per square inch = 930 C. G. S. lines per square
-centimeter.
-
-
-Kathelectrotonus.
-A term used in medical electricity or electro-therapeutics to indicate
-the increased functional activity induced in a nerve by the proximity of
-the kathode of an active circuit which is completed through the nerve.
-The converse of anelectrotonus.
-
-
-Kathode.
-The terminal of an electric circuit whence an electrolyzing current
-passes from a solution. It is the terminal connected to the zinc plate
-of a primary battery.
-
-
-Kathodic Closure Contraction.
-A term in electro-therapeutics; the contractions near where the kathode
-of an active circuit is applied to the body, which are observed at the
-instant when the circuit is closed.
-
-
-Kathodic Duration Contraction.
-A term in electro-therapeutics; the contraction near where the kathode
-of an active circuit is applied to the body for a period of time.
-
-
-K. C. C.
-Abbreviation for Kathodic Closure Contraction, q. v.
-
-
-K. D. C.
-Abbreviation for Kathodic Duration Contraction, q. v.
-
-
-Keeper.
-A bar of soft iron used to connect the opposite poles of a horseshoe
-magnet or the opposite poles of two bar magnets placed side by side. It
-is designed to prevent loss of magnetism. The armature of a horseshoe
-magnet is generally used as its keeper. For bar magnets a keeper is used
-for each end, the magnets being laid side by side, with their poles in
-opposite direction but not touching, and a keeper laid across at each
-end connecting the opposite poles.
-
-
-Kerr Effect.
-The effect of an electrostatic field upon polarized light traversing a
-dielectric contained within the field. (See Electrostatic Refraction.)
-
-
-Kerr's Experiment.
-Polarized light reflected from the polished face of a magnet pole has
-its plane of polarization rotated; when it is reflected from the north
-pole the rotation is from left to right.
-
-
-313    STANDARD ELECTRICAL DICTIONARY.
-
-
-Key.
-A switch adapted for making and breaking contact easily when worked by
-hand, as a Morse telegraph key.
-
-
-Key Board.
-A board or tablet on which keys or switches are mounted.
-
-
-Key-board.
-(a) A switch board, q. v.
-
-(b) A set of lettered keys similar to those of a typewriter employed in
-some telegraph instruments. As each key is depressed it produces the
-contact or break requisite for the sending of the signal corresponding
-to the letter marked upon the key. The signal in printing telegraphs, on
-which such key-boards are used, is the reprinting of the letter at the
-distant end of the line.
-
-
-Key, Bridge.
-A key for use with a Wheatstone Bridge, q.v. It is desirable to first
-send a current through the four arms of the bridge in using it for
-testing resistances and then through the galvanometer, because it takes
-a definite time for the current to reach its full strength. This is
-especially the case if the element being measured has high static
-capacity, as a long ocean cable. If the galvanometer connections were
-completed simultaneously with the bridge connections a momentary swing
-would be produced even if the arms bore the proper relation to each
-other. This would cause delay in the testing. A bridge key avoids this
-by first connecting the battery circuit through the arms of the bridge,
-and then as it is still further depressed the galvanometer circuit is
-completed.
-
-
-314   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 206. CHARGE AND DISCHARGE KEY
-
-
-Key, Charge and Discharge.
-A key for use in observing the discharge of a condenser immediately
-after removing the battery. In one typical form it has two contacts, one
-below and one above, and being a spring in itself is pressed up against
-the upper one. Connections are so made that when in its upper position
-it brings the two coatings of the condenser in circuit with the
-galvanometer. When depressed it does the same for a battery. In use it
-is depressed and suddenly released when the galvanometer receives the
-full charge, before there has been time for leakage. This is one method
-of connection illustrating its principle.
-
-In the cut L is the spring-key proper. S2, is the upper contact screw
-against which the spring normally presses. In this position the
-galvanometer G is in circuit with the opposite coatings of the condenser
-C. On depressing the contact S2, is broken and S1, is made. This brings
-the battery B in circuit with the condenser coatings. On releasing the
-key it springs up and the galvanometer receives the effect of the charge
-of the condenser as derived from the battery.
-
-
-Key, Double Contact.
-A key arranged to close two distinct circuits, holding the first closed
-until the second is completed. It is used for Wheatstone bridge work.
-
-
-Key, Double Tapper.
-A telegraph key giving contacts alternately for currents in opposite
-directions, used in needle telegraphy.
-
-
-Key, Increment.
-A key for use in duplex and quadruplex telegraphy. Its action is to
-increase the line current, not merely to suddenly turn current into it.
-
-
-315   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 207. KEMPE'S DISCHARGE KEY.
-
-
-Key, Kempe's Discharge.
-A key giving a charging, discharging and insulating connection, for
-static condenser work. Referring to the cut l is a lever or spring with
-upper discharging contact s, and lower charging contact s'. In use it is
-pressed down by the insulating handle or finger piece C, until caught by
-the hook attached to the key I. This hook is lower down than that on the
-key D, and holds it in contact with the charging contact piece S'. On
-pressing the key I, marked or designated "Insulate," it springs up,
-breaks contact at S', and catching against the hook on D, which key is
-designated "Discharge," remains insulated from both contacts; next on
-pressing D it is released and springs up and closes the discharge
-contact S. It is a form of charge and discharge key. (See Key, Charge
-and Discharge.)
-
-
-Key, Magneto-electric.
-A telegraph key whose movements operate what is virtually a small
-magneto-generator, so as to produce currents of alternating direction,
-one impulse for each motion of the key. It is employed for telegraphing
-without a line battery, a polarized relay being used. In one very simple
-form a key is mounted on a base with a permanent magnet and connected to
-the armature, so that when the key is pressed downwards it draws the
-armature away from the poles of the magnet. If the magnet or its
-armature is wound with insulated wire this action of the key will cause
-instantaneous currents to go through a circuit connected to the magnet
-or armature coils.
-
-
-Fig. 208. SIEMENS' MAGNETO-ELECTRIC KEY.
-
-
-In Siemens & Halske's key an H armature E is pivoted between the poles N
-S, of a powerful compound horseshoe magnet, G G. It is wound with fine
-wire and a key handle H is provided for working it. In its normal
-position the handle is drawn upward, and the end S S of the armature
-core is in contact with the south pole S of the permanent magnet, and
-the end D D with the north pole. This establishes the polarity of the
-armature. On depressing the key the contacts are broken and in their
-place the end D D comes in contact with the south pole and the end S S
-with the north pole. This suddenly reverses the polarity of the armature
-and sends a momentary current through the armature coil which is in
-circuit with the line. The cut only shows the principle of the key,
-whose construction is quite complicated.
-
-
-316   STANDARD ELECTRICAL DICTIONARY.
-
-
-Key, Make and Break.
-An ordinary electric key, usually making a contact when depressed, and
-rising by spring action when released, and in its rise breaking the
-contact.
-
-
-Fig. 209. PLUG KEY
-
-
-Key, Plug.
-An appliance for closing a circuit. Two brass blocks are connected to
-the terminals, but are disconnected from each other. A brass plug
-slightly coned or with its end split so as to give it spring action is
-thrust between the blocks to complete the circuit. It is used in
-Resistance coils and elsewhere. (See Coil, Resistance.) Grooves are
-formed in the blocks to receive the plug.
-
-
-Key, Reversing.
-(a) A double key, arranged so that by depressing one key a current flows
-in one direction, and by depressing the other a current flows in the
-opposite direction. It is used in connection with a galvanometer in
-experimental, testing or measuring operations.
-
-(b) A key effecting the same result used in quadruplex telegraphy.
-
-
-Key, Sliding-Contact.
-A name given to the key used for making instantaneous contacts with the
-metre wire of a metre bridge, q. v. The name is not strictly correct,
-because it is important that there should be no sliding contact made, as
-it would wear out the wire and make it of uneven resistance.
-
-It is a key which slides along over the wire and which, when depressed,
-presses a platinum tipped knife edge upon the wire. On being released
-from pressure the key handle springs up and takes the knife edge off the
-wire. This removal is essential to avoid wearing the wire, whose
-resistance per unit of length must be absolutely uniform.
-
-
-Key, Telegraph.
-The key used in telegraphy for sending currents as desired over the
-line. It consists of a pivoted lever with finger piece, which lever when
-depressed makes contact between a contact point on its end and a
-stationary contact point on the base. This closes the circuit through
-the line. When released it springs up and opens the line circuit.
-
-
-Kilo.
-A prefix to the names of units; it indicates one thousand times, as
-kilogram, one thousand grams. A few such units are given below.
-
-
-Kilodyne.
-A compound unit; one thousand dynes. (See Dyne.)
-
-
-Kilogram.
-A compound unit; one thousand grams; 2.2046 pounds avds.
-
-
-317  STANDARD ELECTRICAL DICTIONARY.
-
-
-Kilojoule.
-A compound unit; one thousand joules, q. v.
-
-
-Kilometer.
-A compound unit; one thousand meters; 3280.899 feet; 0.621382 statute
-miles. (See Meter.)
-
-
-Kilowatt.
-A compound unit; one thousand watts, q. v.
-
-
-Kine.
-An absolute or C. G. S. unit of velocity or rate of motion; one
-centimeter per second; proposed by the British Association.
-
-
-Kirchoff's Laws.
-These relate to divided circuits.
-
-I. When a steady current branches, the quantity of electricity arriving
-by the single wire is equal to the quantity leaving the junction by the
-branches. The algebraical sum of the intensities of the currents passing
-towards (or passing from) the junction is equal to zero; Summation(C) =
-0 (Daniell.) In the last sentence currents flowing towards the point are
-considered of one sign and those flowing away from it of the other.
-
-II. In a metallic circuit comprising within it a source of permanent
-difference of potential, E, the products of the intensity of the current
-within each part of the circuit into the corresponding resistance are,
-if the elements of current be all taken in cyclical order together,
-equal to E; Summation(C * r) =E. In a metallic circuit in which there is
-no source of permanent difference of potential E = 0, and Summation(C *
-r)  = 0.
-
-This law applies to each several mesh of a wire network as well as to a
-single metallic loop, and it holds good even when an extraneous current
-is passed through the loop. (Daniell.)
-
-In this statement of the two laws E stands for electro-motive force, C
-for current intensity; and r for resistance of a single member of the
-circuit.
-
-[Transcriber's note: These laws may be restated as: At any point in an
-steady-state electrical circuit, the directed sum of currents flowing
-towards that point is zero. The directed sum of the electrical potential
-differences around any closed circuit is zero.]
-
-
-Knife-edge Suspension.
-The suspension of an object on a sharp edge of steel or agate. The knife
-edge should abut against a plane. The knife edge is generally carried by
-the poised object. Its edge then faces downward and on the support one
-or more plane or approximately plane surfaces are provided on which it
-rests. In the ordinary balance this suspension can be seen. It is
-sometimes used in the dipping needle.
-
-It is applied in cases where vertical oscillations are to be provided
-for.
-
-
-Knot.
-The geographical mile; a term derived from the knots on the log line,
-used by navigators. It is equal to 6,087 feet.
-
-Synonyms--Nautical Mile--Geographical Mile.
-
-[Transcriber's note: A knot is a velocity, 1 nautical mile per hour, not
-a distance. The contemporary definition is: 1 international knot = 1
-nautical mile per hour = 1.852 kilometres per hour = 1.1507794 miles per
-hour = 0.51444444 meters per second = 6076.1152 feet per hour.]
-
-
-318   STANDARD ELECTRICAL DICTIONARY.
-
-
-Kohlrausch's Law.
-A law of the rate of travel of the elements and radicals in solutions
-under the effects of electrolysis. It states that each element under the
-effects of electrolysis has a rate of travel for a given liquid, which
-is independent of the element with which it was combined. The rates of
-travel are stated for different elements in centimeters per hour for a
-potential difference of one or more volts per centimeter of path.
-
-[Friedrich Wilhelm Georg Kohlrausch (1840-1910)]
-
-
-Kookogey's Solution.
-An acid exciting and depolarizing solution for a zinc-carbon couple,
-such as a Bunsen battery. Its formula is: Potassium bichromate, 227
-parts; water, boiling, 1,134 parts; while boiling add very carefully and
-slowly 1,558 parts concentrated sulphuric acid. All parts are by weight.
-Use cold.
-
-
-Krizik's Cores.
-Cores of iron for use with magnetizing coils, q. v. They are so shaped,
-the metal increasing in quantity per unit of length, as the centre is
-approached, that the pull of the excited coil upon them will as far as
-possible be equal in all positions. A uniform cylinder is attracted with
-varying force according to its position; the Krizik bars or cores are
-attracted approximately uniformly through a considerable range.
-
-
-L.
-Symbol for length and also for the unit of inductance or coefficient of
-induction, because the dimensions of inductance are length.
-
-
-Lag, Angle of.
-(a) The angle of displacement of the magnetic axis of an armature of a
-dynamo, due to its magnetic lag. The axis of magnetism is displaced in
-the direction of rotation. (See Magnetic Lag.)
-
-(b) The angle expressing the lag of alternating current and
-electro-motive force phases.
-
-
-Laminated. adj.
-Made up of thin plates, as a laminated armature core or converter core.
-
-
-Lamination.
-The building up of an armature core or other thing out of plates. The
-cores of dynamo armatures or of alternating current converters are often
-laminated. Thus a drum armature core may consist of a quantity of thin
-iron discs, strung upon a rod and rigidly secured, either with or
-without paper insulation between the discs. If no paper is used the film
-of oxide on the iron is relied on for insulation. The object of
-lamination is to break up the electrical continuity of the core, so as
-to avoid Foucault currents. (See Currents, Foucault.) The laminations
-should be at right angles to the direction of the Foucault currents
-which would be produced, or in most cases should be at right angles to
-the active parts of the wire windings.
-
-
-319   STANDARD ELECTRICAL DICTIONARY.
-
-
-Lamination of Armature Conductors.
-These are sometimes laminated to prevent the formation of eddy currents.
-The lamination should be radial, and the strips composing it should be
-insulated from each other by superficial oxidation, oiling or
-enamelling, and should be united only at their ends.
-
-
-Fig. 210. PILSEN ARC LAMP.
-
-
-Lamp, Arc.
-A lamp in which the light is produced by a voltaic arc. Carbon
-electrodes are almost universally employed. Special mechanism, operating
-partly by spring or gravity and partly by electricity, is employed to
-regulate the distance apart of the carbons, to let them touch when no
-current passes, and to separate them when current is first turned on.
-
-The most varied constructions have been employed, examples of which will
-be found in their places. Lamps may in general be divided into classes
-as follows, according to their regulating mechanism and other features:
-
-(a) Single light regulators or monophotes. Lamps through whose
-regulating mechanism the whole current passes. These are only adapted to
-work singly; if several are placed in series on the same circuit, the
-action of one regulator interferes with that of the next one.
-
-(b) Multiple light regulators or polyphotes. In these the regulating
-mechanism and the carbons with their arc are in parallel; the regulating
-device may be a single magnet or solenoid constituting a derived or
-shunt-circuit lamp, or it may include two magnets working differentially
-against or in opposition to each other constituting a differential lamp.
-
-
-320   STANDARD ELECTRICAL DICTIONARY.
-
-
-(c) Lamps with fixed parallel carbons termed candles (q. v., of various
-types).
-
-(d) Lamps without regulating mechanism. These include lamps with
-converging carbons, whose object was to dispense with the regulating
-mechanism, but which in some cases have about as much regulating
-mechanism as any of the ordinary arc lamps.
-
-
-Lamp, Contact.
-A lamp depending for its action on loose contact between two carbon
-electrodes. At the contact a species of incandescence with incipient
-arcs is produced. One of the electrodes is usually flat or nearly so,
-and the other one of pencil shape rests upon it.
-
-
-Lamp, Differential Arc.
-An arc lamp, the regulation of the distance between whose carbons
-depends on the differential action of two separate electrical coils. The
-diagram illustrates the principle. The two carbons are seen in black;
-the upper one is movable, The current arrives at A. It divides, and the
-greater part goes through the low resistance coil M to a contact roller
-r, and thence by the frame to the upper carbon, and through the arc and
-lower carbon to B, where it leaves the lamp. A smaller portion of the
-current goes through the coil M1 of higher resistance and leaves the
-lamp also at B. A double conical iron core is seen, to which the upper
-carbon holder is attached. This is attracted in opposite directions by
-the two coils. If the arc grows too long its resistance increases and
-the coil M1 receiving more current draws it down and thus shortens the
-arc. If the arc grows too short, its resistance falls, and the coil M
-receives more current and draws the core upwards, thus lengthening the
-arc. This differential action of the two cores gives the lamp its name.
-R is a pulley over which a cord passes, one end attached to the core and
-the other to a counterpoise weight, W.
-
-
-Fig. 211. DIAGRAM OF THE PILSEN DIFFERENTIAL ARC LAMP.
-
-
-321   STANDARD ELECTRICAL DICTIONARY.
-
-
-Lamp, Holophote.
-A lamp designed for use alone upon its own circuit. These have the
-regulating mechanism in series with the carbon and arc, so that the
-whole current goes through both. (See Lamp, Arc.)
-
-Synonym--Monophote Lamp.
-
-
-Lamp-hour.
-A unit of commercial supply of electric energy; the volt-coulombs
-required to maintain an electric lamp for one hour. A sixteen-candle
-power incandescent lamp is practically the lamp alluded to, and requires
-about half an ampere current at 110 volts, making a lamp-hour equal to
-about 198,000 volt-coulombs.
-
-[Transcriber's note: 0.55 KW hours.]
-
-
-Lamp, Incandescent.
-An electric lamp in which the light is produced by heating to whiteness
-a refractory conductor by the passage of a current of electricity. It is
-distinguished from an arc lamp (which etymologically is also an
-incandescent lamp) by the absence of any break in the continuity of its
-refractory conductor. Many different forms and methods of construction
-have been tried, but now all have settled into approximately the same
-type.
-
-The incandescent lamp consists of a small glass bulb, called the
-lamp-chamber, which is exhausted of air and hermetically sealed. It
-contains a filament of carbon, bent into a loop of more or less simple
-shape. This shape prevents any tensile strain upon the loop and also
-approximates to the outline of a regular flame.
-
-
-Fig. 212. INCANDESCENT ELECTRIC LAMP.
-
-
-322   STANDARD ELECTRICAL DICTIONARY.
-
-
-The loop is attached at its ends to two short pieces of platinum wire,
-which pass through the glass of the bulb and around which the glass is
-fused. As platinum has almost exactly the same coefficient of
-heat-expansion as glass, the wires do not cause the glass to crack.
-
-The process of manufacture includes the preparation of the filament.
-This is made from paper, silk, bamboo fibre, tamidine, q. v., or other
-material. After shaping into the form of the filament the material is
-carbonized at a high heat, while embedded in charcoal, or otherwise
-protected from the air. The flashing process (see Flashing of
-incandescent Lamp Carbons) may also be applied. The attachment to the
-platinum wires is effected by a minute clamp or by electric soldering.
-The loop is inserted and secured within the open globe, which the glass
-blower nearly closes, leaving one opening for exhaustion.
-
-The air is pumped out, perhaps first by a piston pump, but always at the
-end by a mercurial air pump. (See Pump, Geissler--and others.) As the
-exhaustion becomes high a current is passed through the carbons heating
-them eventually to white heat so as to expel occluded gas. The occluded
-gases are exhausted by the pump and the lamp is sealed by melting the
-glass with a blowpipe or blast-lamp flame. For the exhaustion several
-lamps are usually fastened together by branching glass tubes, and are
-sealed off one by one.
-
-The incandescent lamps require about 3.5 watts to the candle power, or
-give about 12 sixteen-candle lamps to the horse power expended on them.
-
-Generally incandescent lamps are run in parallel or on multiple arc
-circuits. All that is necessary in such distribution systems is to
-maintain a proper potential difference between the two leads across
-which the lamps are connected. In the manufacture of lamps they are
-brought to an even resistance and the proper voltage at which they
-should be run is often marked upon them. This may be fifty volts and
-upward. One hundred and ten volts is a very usual figure. As current one
-ampere for a fifty-volt, or about one-half an ampere for a one hundred
-and ten volt lamp is employed.
-
-
-Lamp, Incandescent, Three Filament.
-A three filament lamp is used for three phase currents. It has three
-filaments whose inner ends are connected, and each of which has one
-leading-in wire. The three wires are connected to the three wires of the
-circuit. Each filament receives a current varying in intensity, so that
-there is always one filament passing a current equal to the sum of the
-currents in the other two filaments.
-
-
-Lamp, Lighthouse.
-A special type of arc light. It is adapted for use in a lighthouse
-dioptric lantern, and hence its arc has to be maintained in the same
-position, in the focus of the lenses. The lamps are so constructed as to
-feed both carbons instead of only one, thereby securing the above
-object.
-
-
-323   STANDARD ELECTRICAL DICTIONARY.
-
-
-Lamp, Pilot.
-A lamp connected to a dynamo, and used by its degree of illumination to
-show when the dynamo on starting becomes excited, or builds itself up.
-
-
-Lamp, Polyphote.
-An arc lamp adapted to be used, a number in series, upon the same
-circuit. The electric regulating mechanism is placed in shunt or in
-parallel with the carbons and arc. (See Lamp, Arc.)
-
-
-Lamps, Bank of.
-A number of lamps mounted on a board or other base, and connected to
-serve as voltage indicator or to show the existence of grounds, or for
-other purposes.
-
-
-Lamp, Semi-incandescent.
-A lamp partaking of the characteristics of both arc and incandescence; a
-lamp in which the imperfect contact of two carbon electrodes produces a
-part of or all of the resistance to the current which causes
-incandescence.
-
-The usual type of these lamps includes a thin carbon rod which rests
-against a block of carbon. The species of arc formed at the junction of
-the two heats the carbons. Sometimes the upper carbon or at least its
-end is heated also by true incandescence, the current being conveyed
-near to its end before entering it.
-
-Semi-incandescent lamps are not used to any extent now.
-
-
-Lamp Socket.
-A receptacle for an incandescent lamp; the lamp being inserted the
-necessary connections with the two leads are automatically made in most
-sockets. The lamps may be screwed or simply thrust into the socket and
-different ones are constructed for different types of lamps. A key for
-turning the current on and off is often a part of the socket.
-
-
-Latent Electricity.
-The bound charge of static electricity. (See Charge, Bound.)
-
-
-Law of Intermediate Metals.
-A law of thermo-electricity. The electro-motive force between any two
-metals is equal to the sum of electro-motive forces between each of the
-two metals and any intermediate metal in the thermo-electric series, or
-the electro-motive force between any two metals is equal to the sum of
-the electromotive forces between all the intermediate ones and the
-original two metals; it is the analogue of Volta's Law, q. v.
-
-
-Law of Inverse Squares.
-When force is exercised through space from a point, its intensity varies
-inversely with the square of the distance. Thus the intensity of light
-radiated by a luminous point at twice a given distance therefrom is of
-one-fourth the intensity it had at the distance in question.
-Gravitation, electric and magnetic attraction and repulsion and other
-radiant forces are subject to the same law.
-
-
-324   STANDARD ELECTRICAL DICTIONARY.
-
-
-Law of Successive Temperatures.
-A law of thermo-electricity. The electro-motive force due to a given
-difference of temperature between the opposite junctions of the metals
-is equal to the sum of the electro-motive forces produced by fractional
-differences of temperature, whose sum is equal to the given difference
-and whose sum exactly fills the given range of temperature.
-
-
-Law, Right-handed Screw.
-This rather crude name is given by Emtage to a law expressing the
-relation of direction of current in a circuit to the positive direction
-of the axis of a magnet acted on by such current. It is thus expressed:
-A right-handed screw placed along the axis of the magnet and turned in
-the direction of the current will move in the positive direction, i. e.,
-towards the north pole of the axis of the magnet.
-
-Lead.
-A metal; one of the elements; symbol Pb. Atomic weight, 207;
-equivalent, 103-1/2; valency, 2.
-Lead may also be a tetrad, when its equivalent is 51.75.
-The following data are at 0� C. (32� F.) with compressed metal:
-Relative Resistance, (Silver = l)     13.05
-Specific Resistance,                  19.63   microhms.
-Resistance of a wire,
-(a) 1 ft. long, weighing 1 grain,       3.200   ohms.
-(b) 1 meter long, weighing 1 gram,      2.232  "
-(c) 1 meter long, 1 millimeter thick,    .2498  "
-Resistance of 1 inch cube,              7.728   microhms.
-Electro-Chemical Equivalent (Hydrogen = .0105)   1.086   mgs.
-
-
-Leading Horns.
-The tips of pole pieces in a dynamo, which extend in the direction of
-movement of the armature.
-
-
-Leading-in Wires.
-The platinum wires passing through the glass of an incandescent
-lamp-chamber, to effect the connection of the carbon filament with the
-wires of the circuit.
-
-
-Lead of Brushes, Negative.
-In a motor the brushes are set backwards from their normal position, or
-in a position towards the direction of armature rotation or given a
-negative lead instead of a positive one, such as is given to dynamo
-brushes.
-
-
-Leak.
-A loss or escape of electricity by accidental connection either with the
-ground or with some conductor. There are various kinds of leak to which
-descriptive terms are applied.
-
-
-Leakage.
-The loss of current from conductors; due to grounding at least at two
-places, or to very slight grounding at a great many places, or all along
-a line owing to poor insulation. In aerial or pole telegraph lines in
-wet weather there is often a very large leakage down the wet poles from
-the wire. (See Surface Leakage--Magnetic Leakage.)
-
-
-325   STANDARD ELECTRICAL DICTIONARY.
-
-
-Leakage Conductor.
-A conductor placed on telegraph poles to conduct directly to earth any
-leakage from a wire and thus prevent any but a very small portion
-finding its way into the other wires on the same pole. It presents a
-choice of evils, as it increases the electrostatic capacity of the line,
-and thus does harm as well as good. It consists simply of a wire
-grounded and secured to the pole.
-
-
-Leg of Circuit.
-One lead or side of a complete metallic circuit.
-
-
-Lenz's Law.
-A law expressing the relations of direction of an inducing current or
-field of force to the current induced by any disturbance in the
-relations between such field and any closed conductor within its
-influence. It may be variously expressed.
-
-(a) If the relative position of two conductors, A and B, be changed, of
-which A is traversed by a current, a current is induced in B in such a
-direction that, by its electro-dynamic action on the current in A, it
-would have imparted to the conductors a motion of the contrary kind to
-that by which the inducing action was produced. (Ganot.)
-
-(b) The new (induced) current will increase the already existing
-resistances, or develop new resistance to that disturbance of the field
-which is the cause of induction. (Daniell.)
-
-(c) When a conductor is moving in a magnetic field a current is induced
-in the conductor in such a direction as by its mechanical action to
-oppose the motion. (Emtage.)
-
-(d) The induced currents are such as to develop resistance to the change
-brought about.
-
-
-Letter Boxes, Electric.
-Letter boxes with electrical connections to a bell or indicator of some
-sort, which is caused to act by putting a letter into the box.
-
-
-Leyden Jar.
-A form of static condenser.
-
-In its usual form it consists of a glass jar. Tinfoil is pasted around
-the lower portions of its exterior and interior surfaces, covering from
-one-quarter to three-quarters of the walls in ordinary examples. The
-rest of the glass is preferably shellacked or painted over with
-insulating varnish, q. v. The mouth is closed with a wooden or cork
-stopper and through its centre a brass rod passes which by a short chain
-or wire is in connection with the interior coating of the jar. The top
-of the rod carries a brass knob or ball.
-
-If such a jar is held by the tinfoil-covered surface in one hand and its
-knob is held against the excited prime conductor of a static machine its
-interior becomes charged; an equivalent quantity of the same electricity
-is repelled through the person of the experimenter to the earth and when
-removed from the conductor it will be found to hold a bound charge. If
-the outer coating and knob are both touched or nearly touched by a
-conductor a disruptive discharge through it takes place.
-
-
-326   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 213. LEYDEN JAR WITH DISCHARGER.
-
-
-If one or more persons act as discharging conductors they will receive a
-shock. This is done by their joining hands, a person at one end touching
-the outer coating and another person at the other end touching the knob.
-
-From an influence machine a charge can be taken by connecting the
-coating to one electrode and the knob to the other.
-
-
-Fig. 214. SULPHURIC ACID LEYDEN JAR.
-
-
-327   STANDARD ELECTRICAL DICTIONARY.
-
-
-Leyden Jar, Sir William Thomson's.
-An especially efficient form of Leyden jar. It consists of a jar with
-outer tinfoil coating only. For the interior coating is substituted a
-quantity of concentrated sulphuric acid. The central rod is of lead with
-a foot, which is immersed in the acid and from which the rod rises. A
-wooden cover partly closes the jar, as the central tube through which
-the rod passes is so large as not to allow the wood to touch it. Thus
-any leakage from inner to outer coating has to pass over the inside and
-outside glass surfaces. In the common form of jar the wooden cover may
-short circuit the uncoated portion of the inner glass surface. In the
-cut a simplified form of Thomson's Leyden jar is shown, adapted for
-scientific work.
-
-
-Lichtenberg's Figures.
-If the knob of a Leyden jar or other exited electrode is rubbed over the
-surface of ebonite, shellac, resin or other non-conducting surface it
-leaves it electrified in the path of the knob. If fine powder such as
-flowers of sulphur or lycopodium is dusted over the surface and the
-excess is blown away, the powder will adhere where the surface was
-electrified, forming what are called Lichtenberg's Figures, Lycopodium
-and sulphur show both positive and negative figures, that is to say,
-figures produced by a positively or negatively charged conductor. Red
-lead adheres only to negative figures. If both positive and negative
-figures are made and the surface is sprinkled with both red lead and
-flowers of sulphur each picks out its own figure, the sulphur going
-principally to the positive one.
-
-The red lead takes the form of small circular heaps, the sulphur
-arranges itself in tufts with numerous diverging branches. This
-indicates the difference in the two electricities. The figures have been
-described as "a very sensitive electrosope for investigating the
-distribution of electricity on an insulating surface." (Ganot.)
-
-
-Life of Incandescent Lamps.
-The period of time a lamp remains in action before the carbon filament
-is destroyed. The cause of a lamp failing may be the volatilization of
-the carbon of the filament, causing it to become thin and to break; or
-the chamber may leak. The life of the lamp varies; 600 hours is a fair
-estimate. Sometimes they last several times this period.
-
-The higher the intensity at which they are used the shorter is their
-life. From their prime cost and the cost of current the most economical
-way to run them can be approximately calculated.
-
-[Transcriber's note: Contemporary incandecent buls are rated for 1000
-hours; flourescent bulbs up to 24000 hours; LED lamps up to 100000 hours.]
-
-
-Lightning.
-The electrostatic discharge to the earth or among themselves of clouds
-floating in the atmosphere. The discharge is accompanied by a spark or
-other luminous effect, which may be very bright and the effects, thermal
-and mechanical, are often of enormous intensity.
-
-The lightning flash is white near the earth, but in the upper regions
-where the air is rarefied it is of a blue tint, like the spark of the
-electric machine. The flashes are often over a mile in length, and
-sometimes are four or five miles long. They have sometimes a curious
-sinuous and often a branching shape, which has been determined by
-photography only recently. To the eye the shape seems zigzag.
-
-
-328   STANDARD ELECTRICAL DICTIONARY.
-
-
-In the case of a mile-long flash it has been estimated that 3,516,480 De
-la Rue cells, q. v., would be required for the development of the
-potential, giving the flash over three and one-half millions of volts.
-But as it is uncertain how far the discharge is helped on its course by
-the rain drops this estimate may be too high.
-
-There are two general types of flash. The so-called zigzag flash
-resembles the spark of an electric machine, and is undoubtedly due to
-the disruptive discharge from cloud to earth. Sheet lightning has no
-shape, simply is a sudden glow, and from examination of the spectrum
-appears to be brush discharges (see Discharge, Brush) between clouds.
-Heat lightning is attributed to flashes below the horizon whose light
-only is seen by us. Globe or ball lightning takes the form of globes of
-fire, sometimes visible for ten seconds, descending from the clouds. On
-reaching the earth they sometimes rebound, and sometimes explode with a
-loud detonation. No adequate explanation has been found for them.
-
-The flash does not exceed one-millionth of a second in duration; its
-absolute light is believed to be comparable to that of the sun, but its
-brief duration makes its total light far less than that of the sun for
-any period of time.
-
-If the disruptive discharge passes through a living animal it is often
-fatal. As it reaches the earth it often has power enough to fuse sand,
-producing fulgurites, q. v. (See also Back Shock or Stroke of
-Lightning.)
-
-Volcanic lightning, which accompanies the eruptions of volcanoes, is
-attributed to friction of the volcanic dust and to vapor condensation.
-
-[Transcriber's note: The origin of lightning is still (2008) not fully
-understood, but is thought to relate to charge separation in the
-vertical motion of water droplets and ice crystals in cloud updrafts. A
-lightning bolt carries a current of 40,000 to 120,000 amperes, and
-transfers a charge of about five coulombs. Nearby air is heated to about
-10,000 �C (18,000 �F), almost twice the temperature of the Sun�s
-surface.]
-
-
-Lightning Arrester.
-An apparatus for use with electric lines to carry off to earth any
-lightning discharge such lines may pick up. Such discharge would imperil
-life as well as property in telegraph offices and the like.
-
-Arresters are generally constructed on the following lines. The line
-wires have connected to them a plate with teeth; a second similar plate
-is placed near this with its teeth opposite to those of the first plate
-and nearly touching it. The second plate is connected by a low
-resistance conductor to ground. Any lightning discharge is apt to jump
-across the interval, of a small fraction of an inch, between the
-oppositely placed points and go to earth.
-
-Another type consists of two plates, placed face to face, and pressing
-between them a piece of paper or mica. The lightning is supposed to
-perforate this and go to earth. One plate is connected to the line, the
-other one is grounded.
-
-The lightning arrester is placed near the end of the line before it
-reaches any instrument. (See Alternative Paths.)
-
-
-329   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 215. COMB OR TOOTHED LIGHTNING ARRESTER.
-
-
-Fig. 216. FILM OR PLATE LIGHTNING ARRESTER.
-
-
-Lightning Arrester, Counter-electro-motive Force.
-An invention of Prof. Elihu Thompson. A lightning arrester in which the
-lightning discharge sets up a counter-electro-motive force opposed to
-its own. This it does by an induction coil. If a discharge to earth
-takes place it selects the primary of the coil as it has low
-self-induction. In its discharge it induces in the secondary a reverse
-electro-motive force which protects the line.
-
-
-Lightning Arrester Plates.
-The toothed plates nearly in contact, tooth for tooth, or the flat
-plates of a film lightning arrester, which constitute a lightning
-arrester. Some advocate restricting the term to the plate connected to
-the line.
-
-
-Lightning Arrester, Vacuum.
-A glass tube, almost completely exhausted, into which the line wire is
-fused, while a wire leading to an earth connection has its end fused in
-also.
-
-A high tension discharge, such as that of lightning, goes to earth
-across the partial vacuum in preference to going through the line, which
-by its capacity and self-induction opposes the passage through it of a
-lightning discharge.
-
-It is especially adapted for underground and submarine lines.
-
-
-330   STANDARD ELECTRICAL DICTIONARY.
-
-
-Lightning, Ascending.
-Lightning is sometimes observed which seems to ascend. It is thought
-that this may be due to positive electrification of the earth and
-negative electrification of the clouds.
-
-
-Lightning, Globe or Globular.
-A very unusual form of lightning discharge, in which the flashes appear
-as globes or balls of light. They are sometimes visible for ten seconds,
-moving so slowly that the eye can follow them. They often rebound on
-striking the ground, and sometimes explode with a noise like a cannon.
-They have never been satisfactorily explained. Sometimes the phenomenon
-is probably subjective and due to persistence of vision.
-
-
-Lightning Jar.
-A Leyden jar whose coatings are of metallic filings dusted on to the
-surface while shellacked, and before the varnish has had time to dry. In
-its discharge a scintillation of sparks appears all over the surface.
-
-
-Line of Contact.
-The line joining the points of contact of the commutator brushes in a
-dynamo or motor.
-
-Synonym--Diameter of Commutation.
-
-
-Lines of Force.
-Imaginary lines denoting the direction of repulsion or attraction in a
-field of force, q. v. They may also be so distributed as to indicate the
-relative intensity of all different parts of the field. They are normal
-to equipotential surfaces. (See Electro-magnetic Lines of
-Force--Electrostatic Lines of Force--Magnetic Lines of Force.)
-
-
-Lines of Induction.
-Imaginary lines within a body marking the direction taken within it by
-magnetic induction. These are not necessarily parallel to lines of
-force, but may, in bodies of uniform agglomeration, or in crystalline
-bodies, take various directions.
-
-Synonym--Lines of Magnetic Induction.
-
-
-Lines of Slope.
-Lines in a field of force which mark the directions in which the
-intensity of force in the field most rapidly falls away.
-
-
-Links, Fuse.
-Links made of more or less easily fusible metal, for use as safety
-fuses.
-
-
-Listening Cam.
-In a telephone exchange a cam or species of switch used to connect the
-operator's telephone with a subscriber's line.
-
-
-331  STANDARD ELECTRICAL DICTIONARY.
-
-
-Lithanode.
-A block of compressed lead binoxide, with platinum connecting foils for
-use as an electrode in a storage battery. It has considerable capacity,
-over 5 ampere-hours per pound of plates, but has not met with any
-extended adoption.
-
-
-Load.
-In a dynamo the amperes of current delivered by it under any given
-conditions.
-
-
-Local Action.
-(a) In its most usual sense the electric currents within a battery, due
-to impurities in the zinc, which currents may circulate in exceedingly
-minute circuits, and which waste zinc and chemicals and contribute
-nothing to the regular current of the battery. Amalgamated or chemically
-pure zinc develops no local action.
-
-(b) The term is sometimes applied to currents set up within the armature
-core or pole pieces of a dynamo. (See Currents, Foucault.)
-
-
-Local Battery.
-A battery supplying a local circuit (q. v.); in telegraphy, where it is
-principally used, the battery is thrown in and out of action by a relay,
-and its current does the work of actuating the sounder and any other
-local or station instruments. (See Relay.)
-
-
-Local Circuit.
-A short circuit on which are placed local apparatus or instruments. Such
-circuit is of low resistance and its current is supplied by a local
-battery, q. v. Its action is determined by the current from the main
-line throwing its battery in and out of circuit by a relay, q. v., or
-some equivalent.
-
-
-Local Currents.
-Currents within the metal parts of a dynamo. (See Currents, Foucault.)
-In a galvanic battery. where there is local action, q. v., there are
-also local currents, though they are not often referred to.
-
-
-Localization.
-Determining the position of anything, such as a break in a cable, or a
-grounding in a telegraph line. In ocean cables two typical cases are the
-localization of a break in the conductor and of a defect in the
-insulation admitting water. The first is done by determining the static
-capacity of the portion of the line which includes the unbroken portion
-of the conductor; the other by determining the resistance of the line on
-a grounded circuit.
-
-
-Locus.
-A place. The word is used to designate the locality or position of, or
-series of positions of definite conditions and the like. Thus an
-isogonic line is the locus of equal declinations of the magnetic needle;
-it is a line passing through all places on the earth's surface where the
-condition of a given declination is found to exist.
-
-
-332   STANDARD ELECTRICAL DICTIONARY.
-
-
-Lodestone.
-Magnetic magnetite; magnetite is an ore of iron, Fe3 04 which is
-attracted by the magnet. Some samples possess polarity and attract iron.
-The latter are lodestones.
-
-Synonym--Hercules Stone
-
-
-Logarithm.
-The exponent of the power to which it is necessary to raise a fixed
-number to produce a given number. The fixed number is the base of the
-system. There are two systems; one, called the ordinary system, has 10
-for its base, the other, called the Naperian system, has 2.71828 for its
-base. The latter are also termed hyperbolic logarithms, and are only
-used in special calculations.
-
-
-Log, Electric.
-An apparatus for measuring the speed of a ship. A rotating helical vane
-of known pitch is dragged behind the vessel. As the helix rotates its
-movements may actuate electric machinery for registering its rotations.
-The number of these in a given time, multiplied by the pitch of the
-vane, gives the distance traversed in such time.
-
-
-Loop.
-A portion of a circuit introduced in series into another circuit. The
-latter circuit is opened by a spring-jack, q. v. or other device, and
-the loop inserted. By loops any number of connections can be inserted
-into a circuit in series therewith, and in series or in parallel with
-one another.
-
-
-Loop Break.
-A double bracket or similar arrangement for holding on insulators the
-ends of a conductor which is cut between them, and to which are
-connected the ends of a loop. The space between the insulators may be
-about a foot.
-
-
-Luces.
-This may be used as the plural of lux, q. v. It is the Latin plural.
-
-
-Luminous Jar.
-A Leyden jar whose coatings are of lozenge-shaped pieces of tinfoil
-between which are very short intervals. When discharged, sparks appear
-all over the surface where the lozenges nearly join.
-
-
-Lux.
-A standard of illumination, q. v., as distinguished from illuminating
-power.
-
-It is the light given by one candle at a distance of 12.7 inches--by a
-carcel, q. v., at a distance of one meter---or by 10,000 candles at
-105.8 feet.
-
-It was proposed by W. H. Preece. All the above valuations are identical.
-
-
-M.
-(a) Symbol of gaseous pressure equal to one-millionth of an atmosphere.
-
-(b) The Greek m, �, is used as the symbol of magnetic permeability.
-
-
-333   STANDARD ELECTRICAL DICTIONARY.
-
-
-Machine, Cylinder Electric.
-A frictional electric machine whose rotating glass is in the shape of a
-cylinder instead of a disc as in the more recent machines.
-
-
-Fig. 217. PLATE FRICTIONAL ELECTRIC MACHINE.
-
-
-Machine, Frictional Electric.
-An apparatus for development of high tension electricity by contact
-action, brought about by friction.
-
-It consists of a plate or cylinder of glass mounted on insulating
-standards and provided with a handle for turning it. One or more
-cushions of leather are held on an insulated support, so as to rub
-against the plate or cylinder as it is turned. A metal comb or combs are
-held on another insulating support so as to be nearly in contact with
-the surface of the glass plate at a point as far removed as possible
-from the rubbers. The combs are attached to a brass ball or round-ended
-cylinder, which is termed the prime conductor.
-
-In use either the prime conductor or cushions are connected by a chain
-or otherwise with the earth. Assume it to be the cushions. As the
-machine is worked by turning the plate, the glass and cushion being in
-contact develop opposite electricities. The glass is charged with
-positive electricity, and as it turns carries it off and as it reaches
-the prime conductor by induction and conduction robs it of its negative
-electricity. Meanwhile the cushions negatively excited deliver their
-charge to the earth. The action thus goes on, the prime conductor being
-charged with positive electricity.
-
-
-334   STANDARD ELECTRICAL DICTIONARY.
-
-
-If the prime conductor is connected to the earth and the cushions are
-left insulated, negative electricity can be collected from the cushions.
-
-In some machines both prime conductor and cushions are kept insulated
-and without ground contact. Electrodes connecting with each are brought
-with their ends close enough to maintain a sparking discharge.
-
-
-Machine Influence.
-A static electric machine working by induction to build up charges of
-opposite nature on two separate prime conductors. In general they are
-based on the principle of the electrophorous. Work is done by the
-operator turning the handle. This rotates a disc and draws excited parts
-of it away from their bound charges. This represents a resistance to
-mechanical motion. The work absorbed in overcoming this mechanical
-resistance appears as electric energy. There are various types of
-influence machines, the Holtz, Toeppler-Holtz and Wimshurst being the
-most used. The electrophorous, q. v., is a type of influence machine.
-
-
-Machine, Holtz Influence.
-A static electric machine. It includes two plates, one of which is
-rapidly rotated in front of the other. Two armatures of paper are
-secured to the back of the stationary plate at opposite ends of a
-diameter. To start it one of these is charged with electricity. This
-charge by induction acts through the two thicknesses of glass upon a
-metal bar carrying combs, which lies in front of the further side of the
-movable plate. The points opposite the armature repel electrified air,
-which strikes the movable disc and charges it. A second rod with comb at
-the opposite end of the same diameter acts in the reverse way. Thus
-opposite sections of the disc are oppositely charged and the combs with
-them. By induction these portions of the disc react upon the two
-armatures. The opposite electricities escape from the armatures by paper
-tongues which are attached thereto and press against the back of the
-movable plate. As the plate rotates the opposite electricities on its
-face neutralize the electricity repelled from the combs. The charges on
-the back strengthen the charges of the armatures and brass combs. Thus
-the machine builds up, and eventually a discharge of sparks takes place
-from the poles of the brass combs.
-
-
-335   STANDARD ELECTRICAL DICTIONARY.
-
-
-Machine, Toeppler-Holtz.
-A modification of the Holtz machine. The priming charge of the armatures
-is produced by friction of metallic brushes against metallic buttons on
-the face of the rotating plate. (See Machine, Holtz.)
-
-
-Machine, Wimshurst.
-A form of static influence machine. It consists of two plates of glass,
-on which radial sectors of tinfoil are pasted. Both plates are rotated
-in opposite directions. The sectors of the two plates react one upon the
-other, and electric charges of opposite sign accumulate on the opposite
-sides of the plates and are collected therefrom by collecting combs.
-
-
-Mack.
-A name, derived from Maxwell, and suggested for the unit of inductance.
-It is due to Oliver Heaviside, but has never been adopted. (See Henry.)
-
-
-Magne-Crystallic Action.
-The action of a supposed force of the same name, proposed by Faraday. It
-relates to the different action of a magnetic field upon crystalline
-bodies, according to the position of their axes of crystallization. A
-needle of tourmaline, normally paramagnetic, if poised with its axis
-horizontal, is diamagnetic. Bismuth illustrates the same phenomenon. The
-subject is obscure. Faraday thought that he saw in it the action of a
-specific force.
-
-
-Magnet.
-A body which tends when suspended by its centre of gravity to lay itself
-in a definite direction, and to place a definite line within it, its
-magnetic axis, q. v., in a definite direction, which, roughly speaking,
-lies north and south. The same bodies have the power of attracting iron
-(Daniell), also nickel and cobalt.
-
-Magnets are substances which possess the power of attracting iron.
-(Ganot.)
-
-[Transcriber's note: Edward Purcell and others have explained magnetic
-and electromagnetic phenomenon as relativistic effects related to
-electrostatic attraction. Magnetism is caused by Lorentz contraction of
-space along the direction of a current. Electromagnetic waves are caused
-by charge acceleration and the resulting disturbance of the
-electrostatic field. (Electricity and Magnetism: Berkeley Physics
-Course Volume 2, 1960)]
-
-
-Magnet, Anomalous.
-A magnet possessing more than the normal number (two) of poles. If two
-straight magnets are placed end to end with their south poles in
-juxtaposition the compound bar will seem to possess three poles, one at
-each end and one in the middle. The apparent pole in the middle is
-really made up of two consequent poles, q. v. It sometimes happens that
-when a single long thin bar is magnetized consequent poles are produced,
-although such magnet is in one piece. This may be accidental, as in such
-case it is quite hard to avoid anomalous poles, or, as in the field
-magnets of some forms of dynamos, anomalous poles may be purposely
-produced.
-
-
-Magnet, Artificial.
-A magnet formed artificially by any method of magnetization (see
-Magnetism) applicable to permanent magnets, electro-magnets and
-solenoids. It expresses the distinction from the natural magnets or
-lodestone, q. v. It is made of steel in practice magnetized by some of
-the methods described under Magnetization.
-
-
-336   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnet, Axial.
-A straight-solenoid with axial core.
-
-
-Magnet, Bar.
-A bar magnet is one in the shape of a bar, i. c., straight with parallel
-sides and considerably longer than wide or deep.
-
-
-Magnet, Bell-shaped.
-A form of permanent magnet used in some galvanometers. In shape it is a
-thick-sided cylindrical box with two slots cut out of opposite sides, so
-as to make it represent a horseshoe magnet. Its shape enables it to be
-surrounded closely by a mass of copper, for damping its motion, to
-render the instrument dead-beat. Such a magnet is used in Siemens &
-Halske's galvanometer.
-
-
-Magnet Coil.
-A coil to be thrust over an iron core, to make an electro-magnet. They
-are often wound upon paper or wooden bobbins or spools, so as to be
-removable from the core if desired.
-
-
-Magnet, Compensating.
-(a) A magnet fastened near a compass on an iron or steel ship to
-compensate the action of the metal of the ship upon the magnetic needle.
-The ship itself always has some polarity and this is neutralized by one
-or more compensating magnets.
-
-(b) See below.
-
-
-Magnet, Controlling.
-A magnet attached to a galvanometer by which the directive tendency of
-its magnetic needle is adjusted. In the reflecting galvanometer it often
-is a slightly curved magnet carried by a vertical brass spindle rising
-from the center of the instrument, and which magnet may be slid up and
-down on the spindle to regulate or adjust its action.
-
-Synonym--Compensating Magnet.
-
-
-Magnet, Compound.
-A permanent magnet, built up of a number of magnets. Small bars can be
-more strongly magnetized than large. Hence a compound magnet may be made
-more powerful than a simple one.
-
-
-Magnet Core.
-The iron bar or other mass of iron around which insulated wire is wound
-for the production of an electro-magnet. The shapes vary greatly,
-especially for field magnets of dynamos and motors. For these they are
-usually made of cast iron, although wrought iron is preferable from the
-point of view of permeability.
-
-
-Magnet, Damping.
-A damping magnet is one used for bringing an oscillating body to rest.
-The body may be a metallic disc or needle, and the action of the magnet
-depends on its lines of force which it establishes, so that the body has
-to cut them, and hence has its motion resisted.
-
-
-337   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnet, Deflection of.
-The change of position of a magnet from the plane of the earth's
-meridian in which it normally is at rest into another position at some
-angle thereto, by the effect of an artificial magnetic field, as the
-deflection of a galvanometer needle.
-
-
-Magnet, Electro-.
-A magnet consisting of a bar of iron, bundle of iron wires, iron tube or
-some equivalent, around which a coil of insulated wire is wound. Such
-combination becomes polarized when a current is passed through it and is
-an active magnet. On the cessation of the current its magnetism in part
-or almost completely disappears. (See Electro-magnet.)
-
-
-Magnet, Equator of.
-In a magnet the locus of points of no attractive power and of no
-polarity. In a symmetrical, evenly polarized magnet it is the imaginary
-line girdling the centre. The terms Neutral Point or Neutral Line have
-displaced it.
-
-Synonyms--Neutral Line--Neutral Point.
-
-
-Magnet, Field.
-A magnet, generally an electro-magnet, used to produce the field in a
-dynamo or motor.
-
-
-Magnet, Haarlem.
-Celebrated magnets made in Haarlem, Holland. Logeman, Van Wetteren,
-Funckler and Van der Willigen were the makers who gave the celebrity to
-the magnets. They were generally horseshoe magnets, and would carry
-about twenty times their own weight.
-
-
-Magnet, Horseshoe.
-A magnet of U shape--properly one with the poles brought a little closer
-together than the rest of the limbs. For direct lifting and attractive
-effects it is the most generally adopted type. Its advantage as regards
-lifting effect is due to small reluctance, q. v., offered by a complete
-iron circuit, such as the armature and magnet together produce. As the
-term is now used it is applied to any U shaped magnet.
-
-
-Fig. 218. JOULE'S ELECTRO-MAGNET.
-
-
-Magnet, Joule's Electro.
-An electro-magnet of the shape of a cylinder with a longitudinal segment
-cut-off. It is wound with wire as shown. The segment cut-off is a piece
-of the same shape as the armature. It is of high power.
-
-
-338   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Adherence.
-The tendency of a mass of iron to adhere to the poles of a magnet. It is
-best figured as due to the virtual shortening of lines of force, as the
-more permeable iron gives a better path for them than the air can
-afford, and consequently a virtually shorter one.
-
-
-Magnetic Attraction and Repulsion.
-The attraction of a magnet for iron, steel, nickel and cobalt and of
-unlike poles of magnets for each other. It is identical with
-electro-magnetic attraction, q.v. (Also see Electro-magnetism.)
-
-
-Magnetic Attraction and Repulsion, Coulomb's Law of.
-Magnetic attraction and repulsion are inversely as the square of the
-distance. (Ganot.)
-
-While theoretically true in the case of isolated poles, in practise it
-does not generally apply on account of the large diameter and relative
-shortness of magnets.
-
-
-Magnetic Axis.
-The line connecting the poles of a magnet. It does not generally
-coincide exactly with any symmetrical axis of figure. In such cases an
-error is introduced into the indications of the needle which must be
-determined and allowed for in compasses. To determine it with a magnetic
-needle the suspension cup is made removable, so that the needle can be
-reversed. Readings are taken with one side of the needle and then with
-the other side of the needle up, and the average corresponds with the
-position of the magnetic axis in both positions of the needle.
-
-
-Magnetic Azimuth.
-The angle, measured on a horizontal circle, between the magnetic
-meridian and a great circle of the earth passing through the observer
-and any observed body. It is the astronomical azimuth of a body referred
-to the magnetic meridian and therefore subject to the variation of the
-compass. The angle is the magnetic azimuth of the observed body.
-
-
-Magnetic Battery.
-A name for a compound permanent magnet; one made up by bolting or
-clamping together, or to single soft iron pole pieces, a number of
-single permanent magnets. There are a number of forms of compound
-magnets. In making them care has to be taken to have them of even
-strength. It is also well to have them slightly separated. The object of
-both these precautions is to prevent a stronger element or magnet from
-depolarizing its neighbor.
-
-Synonym--Compound Magnet.
-
-
-Magnetic Bridge.
-An apparatus for testing the relative permeability of iron. It consists
-of a rectangular system of iron cores. Three of the sides are wound with
-wire as shown. The other side is built up of double bars, and from the
-centre two curved arms rise, as shown in the cut. The arms do not touch.
-Between them a short magnet is suspended by a filament, which also
-carries a mirror and an index.
-
-
-339   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 219. MAGNETIC BRIDGE.
-
-
-A lamp and scale are provided as in the reflecting galvanometer. When
-adjusted the magnetic needle hangs as shown in the cut, Fig. 219,
-without any tendency to turn towards either curved pole piece. If all
-iron parts are symmetrical and of similar metal, a current through the
-coils will make no difference. It will work in magnetic opposition upon
-the two arms, or, in other words, will maintain both arms at identical
-potential.
-
-
-Fig. 220. POLE PIECES, MAGNETIC NEEDLE AND MIRROR OF MAGNETIC BRIDGE.
-
-
-If there is the least difference in permeability, length or thickness
-between any of the iron bars the magnetic potential of the two curved
-arms will differ, and the magnetic needle will turn one way or the
-other. In practical use different samples of iron are substituted for
-the unwound members of the fourth side of the parallelogram, and the
-needle by its motions indicates the permeability.
-
-In the cut, Fig. 220, D D are the ends of the curved pole pieces; A the
-wire carrying the mirror B and magnetic needle N, and E is the index
-which shows the larger deflections.
-
-
-340   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Circuit.
-A magnetic field of force is characterized by the presence of lines of
-force, which, while approximately parallel, curve around and tend to
-form closed curves. The polarity of a field of force is referred to an
-imaginary direction of the lines of force from the north pole through
-space to the south pole, and in the part of the field corresponding to
-the body of the magnet, from the south to the north pole. The cut
-indicates these features. Hence the magnetic field of force is termed
-the magnetic circuit, and to it are attributed a species of resistance
-termed reluctance, q. v., and the producing cause of the field or lines
-of force is termed sometimes magneto-motive force, q. v.) corresponding
-to the electro-motive force. The modern treatment of the magnetic
-circuit is similar to the application of Ohm's law and the laws of
-resistance and conductivity to the electric circuit.
-
-
-Magnetic Circuit, Double.
-A magnetic circuit which virtually represents two horseshoe magnets
-placed with their like poles in contact. It is used for field magnets,
-the armatures occupying a place between the consequent poles.
-
-
-Fig. 221. ONE-HALF PORTION OF A DOUBLE MAGNETIC CIRCUIT.
-
-
-Magnetic Concentration of Ores.
-The concentration of ores or the freeing them from their gangue by
-magnetic attraction. It is only applicable to those cases in which
-either the ore itself or the gangue is attracted by the magnet. Its
-principal application is to the concentration of magnetic iron sands.
-(See Magnetic Concentration.)
-
-
-Magnetic Concentrator.
-An apparatus similar to a magnetic separator, q. v., but used to
-concentrate magnetic iron sands. By the action of electro-magnets the
-magnetic iron sand (magnetite) is separated from the sand with which it
-is mixed.
-
-
-Magnetic Conductivity and Conductance.
-The first notion of permeance and of the magnetic circuit included the
-idea of magnetic conductivity, which conducted lines of force urged by
-magneto-motive force through a magnetic circuit. The terms are displaced
-by permeability and permeance.
-
-
-341   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Continuity.
-The completeness of a magnetic circuit, as when the armature of a
-horseshoe magnet is in contact with both poles. It is an attribute of a
-paramagnetic substance only and is identical for permanent magnets or
-for electro-magnets. An air space intervening between armature and
-magnet poles, or a space filled with any diamagnetic substance prevents
-continuity, although the lines of force to some extent still find their
-way around. The leakage is increased by discontinuity.
-
-
-Magnetic Control.
-Control of a magnetic needle, magnet, iron index or armature, in a
-galvanometer, ammeter or voltmeter by a magnetic field; the restitutive
-force being derived from a permanent magnet.
-
-
-Magnetic Couple.
-The couple of magnetic force which tends to bring the magnetic needle
-into the plane of the magnetic meridian. One force is represented by the
-imaginary pull upon the north pole, and the other by the opposite pull
-upon the south pole of the needle. The moment of the couple varies from
-a maximum when the needle is at right angles to the plane of the
-magnetic meridian to zero when it is in such plane.
-
-
-Magnetic Creeping.
-Viscous hysteresis; the slow increase of magnetism in a paramagnetic
-body when exposed to induction.
-
-
-Fig. 222. MAGNETIC CURVES OR FIGURES.
-
-
-Magnetic Curves.
-The pictorial representation of magnetic lines of force. It is generally
-produced by scattering filings on a sheet of paper or pane of glass held
-over a magnet. The filings arrange themselves in characteristic curves.
-Tapping the paper or pane of glass facilitates the arrangement, or
-jarring the filings off a smaller magnet, so that they fall polarized
-upon the paper, is thought by some to improve the effect. The group of
-curves forms what are termed magnetic figures, q. v.
-
-
-342   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Declination.
-The angular deviation of the magnetic needle, causing it to rest at an
-angle with the true meridian; the variation of the compass. (See
-Magnetic Elements.)
-
-
-Magnetic Density.
-The intensity of magnetization expressed in lines of force per stated
-area of cross-section in a plane at right angles to the lines of force.
-
-
-Magnetic Dip.
-The inclination from the horizontal assumed by a magnetic needle free to
-move in the vertical plane. (See Magnetic Elements.) The angle of dip or
-inclination is entirely a function of the earth, not of the needle.
-
-
-Magnetic Discontinuity.
-A break or gap in a magnetic circuit. To make a complete circuit the
-iron or other core must be continuous. If the armature of a horseshoe
-magnet is in contact with both poles the continuity is complete. If the
-armature is not in contact magnetic continuity gives place to
-discontinuity. It is an attribute of a paramagnetic substance only, and
-is identical for permanent magnets, or for electro-magnets.
-
-
-Magnetic Elements.
-The qualities of the terrestrial magnetism at any place as expressed in
-its action upon the magnetic needle. Three data are involved.
-
-I. The Declination or Variation.
-II. The Inclination or Dip.
-III. The Force or Intensity.
-
-I. The Declination is the variation expressed in angular degrees of the
-magnetic needle from the true north and south, or is the angle which the
-plane of the magnetic meridian makes with that of the geographical
-meridian. It is expressed as east or west variation according to the
-position of the north pole; east when the north pole of the needle is to
-the east of the true meridian, and vice versa. Declination is different
-for different places; it is at present west in Europe and Africa, and
-east in Asia and the greater part of North and South America. The
-declination is subject to (a) secular, (b) annual and (c) diurnal
-variations. These are classed as regular; others due to magnetic storms
-are transitory and are classed as irregular, (a) Secular variations. The
-following table shows the secular variations during some three hundred
-years at Paris. These changes are termed secular, because they require
-centuries for their completion.
-
-
-343    STANDARD ELECTRICAL DICTIONARY.
-
-Table of Declination or Variation at Paris.
-Year.   Declination.
-1580   11� 30' E.
-1663    0�
-1700    8� 10' W.
-1780   19� 55' W.
-1785   22� 00' W.
-1805   22�  5' W.
-1814   22� 34' W.
-1825   22� 22' W.
-1830   22� 12' W.
-1835   22�  4' W.
-1850   20� 30' W.
-1855   19� 57' W.
-1860   19� 32' W.
-1865   18� 44' W.
-1875   17� 21' W.
-1878   17� 00' W.
-[Transcriber's note The value for 2008 is about  0� 48' W, changing by
-0� 7' E/year.]
-
-On scrutinizing these figures it will be seen that there is part of a
-cycle represented and that the declination is slowly returning to the
-zero point after having reached its maximum western variation in 1814.
-Upwards of 300 years would be required for its completion on the basis
-of what is known. In other places, notably the coast of Newfoundland,
-the Gulf of the St. Lawrence and the rest of the North American seaboard
-and in the British Channel, the secular variations are much more rapid
-in progress. (b) Annual variations--These were first discovered in 1780
-by Cassini. They represent a cycle of annual change of small extent,
-from 15' to 18' only. In Paris and London the annual variation is
-greatest about the vernal equinox, or March 21st, and diminishes for the
-next three months, and slowly increases again during the nine following
-months. It varies during different epochs. (c) Diurnal variations were
-discovered in 1722 by Graham. A long needle has to be employed, or the
-reflection of a ray of light, as in the reflecting galvanometer, has to
-be used to observe them. In England the north pole of the magnetic
-needle moves every day from east to west from sunrise until 1 or 2 P.
-M.; it then tends towards the east and recovers its original position by
-10 P. M. During the night the needle is almost stationary. As regards
-range the mean amplitude of diurnal variations at Paris is from April to
-September 13' to 15'; for the other months from 8' to 10'. On some days
-it amounts to 25' and sometimes is no more than 5'. The amplitude of
-diurnal variations decreases from the poles to the equator. Irregular
-variations accompany earthquakes, the aurora borealis and volcanic
-eruptions. In Polar regions the auroral variations may be very great;
-even at 40� latitude they may be 1� or 2�. Simultaneous irregularities
-sometimes extend over large areas. Such are attributed to magnetic
-storms. II. The Inclination is the angle which the magnetic needle makes
-with the horizon, when the vertical plane in which the needle is assumed
-to be free to move coincides with the magnetic meridian. It is sometimes
-called the dip of the needle. It varies as does the declination, as
-shown in the following table of inclinations of London.
-
-
-344   STANDARD ELECTRICAL DICTIONARY.
-
-
-Table of Inclination or Dip at London
-Year.   Inclination.
-1576   71� 50'
-1600   72�
-1676   73� 30'
-1723   74� 42'
-1773   72� 19'
-1780   72�  8'
-1790   71� 33'
-1800   70� 35'
-1821   70� 31'
-1828   69� 47'
-1838   69� 17'
-1854   68� 31'
-1859   68� 21'
-1874   67� 43'
-1876   67� 39'
-1878   67� 36'
-1880   67� 35'
-1881   67� 35'
-
-III. Force or Intensity is the directive force of the earth. It varies
-with the squares of the number of oscillations the magnetic needle will
-make if caused to oscillate from a determined initial range. The
-intensity is supposed to be subject to secular change. According to
-Gauss the total magnetic intensity of the earth is equal to that which
-would be exerted if in each cubic yard there were eight bar magnets,
-each weighing one pound. This is, of course, a rough way of expressing
-the degree of intensity. Intensity is least near the magnetic equator
-and greatest near the magnetic poles; the places of maximum intensity
-are termed the magnetic foci. It varies with the time of day and
-possibly with changes in altitude.
-
-
-Magnetic Elongation.
-The elongation a bar of iron or steel undergoes when magnetized. By
-magnetization it becomes a little longer and thinner, there being no
-perceptible change in volume. The change is accompanied by a slight
-sound--the magnetic tick. An exceedingly delicate adjustment of
-apparatus is required for its observation.
-
-
-Magnetic Equator.
-A locus of the earth's surface where the magnet has no tendency to dip.
-It is, approximately speaking, a line equally distant from the magnetic
-poles, and is called also the aclinic line. It is not a great circle of
-the earth.
-
-
-345  STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Field of Force.
-The field of force established by a magnet pole. The attractions and
-repulsions exercised by such a field follow the course of the electro-
-magnetic lines of force. (See also Field of Force.) Thus the tendency of
-a polarized needle attracted or repelled is to follow, always keeping
-tangential to curved lines, the direction of the lines of force, however
-sweeping they may be. The direction of magnetic lines of force is
-assumed to be the direction in which a positive pole is repelled or a
-negative one attracted; in other words, from the north pole of a magnet
-to its south pole in the outer circuit. The direction of lines of force
-at any point, and the intensity or strength of the field at that point,
-express the conditions there. The intensity may bc expressed in terms of
-that which a unit pole at unit distance would produce. This intensity as
-unitary it has been proposed to term a Gauss. (See Weber.)
-
-The direction of the lines of force in a magnetic field are shown by the
-time-honored experiment of sprinkling filings of iron upon a sheet of
-paper held over a magnet pole or poles. They arrange themselves, if the
-paper is tapped, in more or less curved lines tending to reach from one
-pole of the magnet to the other. Many figures may be produced by
-different conditions. Two near poles of like name produce lines of force
-which repel each other. (See Magnetic Curves.)
-
-A magnetic and an electro-magnetic field are identical in all essential
-respects; the magnetic field may be regarded as a special form of the
-electro-magnetic field, but only special as regards its production and
-its defined north and south polar regions.
-
-Synonyms--Magnetic Spin (not much used).
-
-
-Magnetic Field, Uniform.
-A field of identical strength in all parts, such as the earth's magnetic
-field. If artificially produced, which can only be approximately done,
-it implies large cross-section of magnet pole in proportion to the
-length of the magnetic needle affected by it, which is used in
-determining its uniformity.
-
-
-Magnetic Figures.
-The figures produced by iron filings upon paper or glass held near
-magnetic poles. By these figures the direction of lines of force is
-approximately given, and a species of map of the field is shown. (See
-Magnetic Field of Force--Magnetic Curves.)
-
-
-Magnetic Filament.
-The successive rows of polarized molecules assumed to exist in
-magnetized iron. Each molecule represents an infinitely small magnet,
-and its north pole points to the south pole of the next molecule. Such a
-string or row is a theoretical conception based on the idea that the
-molecules in a magnet are all swung in to parallelism in the magnetizing
-process. A magnetic filament may be termed the longitudinal element of a
-magnet. (See Magnetism, Hughes' Theory of.)
-
-[Transcriber's note: This description parallels the modern
-notion of electron spin as the basis of magnetism in materials.]
-
-
-Magnetic Fluids.
-A two-fluid theory of magnetism has been evolved, analogous to the
-two-fluid theory of electricity. It assumes north fluid or "red
-magnetism" and a south fluid or "blue magnetism." Each magnetism is
-supposed to predominate at its own pole and to attract its opposite.
-Before magnetization the fluids are supposed to neutralize each other
-about each molecule; magnetization is assumed to separate them,
-accumulating quantities of them at the poles.
-
-
-Magnetic Flux.
-Magnetic induction; the number of lines of force that pass through a
-magnetic circuit.
-
-Synonym--Magnetic Flow.
-
-
-346   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Force.
-The forces of attraction and repulsion exercised by a magnet. By
-Ampere's theory it is identical with the forces of attraction and
-repulsion of electric currents.
-
-
-Magnetic Friction.
-The damping effect produced on the movements of a mass of metal by
-proximity to a magnet; the phenomenon illustrated in Arago's wheel, q.
-v. When a mass of metal moves in the vicinity of a magnet it cuts the
-lines of force emanating from its poles, thereby producing currents in
-its mass; as the production of these currents absorbs energy a damping
-effect is produced upon the movements of the mass.
-
-
-Magnetic Gear.
-Friction gear in which electro-magnetic adherence is employed to draw
-the wheels together. (See Adherence, Electro-magnetic--Electro-magnetic
-Friction Gear.)
-
-
-Magnetic Inclination.
-The inclination from the horizontal of a magnetic needle placed in the
-magnetic meridian. (See Magnetic Element--Inclination Map.)
-
-Synonym--Magnetic Dip.
-
-
-Magnetic Induction.
-The force of magnetization within an induced magnet. It is in part due
-to the action of the surrounding particles of polarized material; in
-part to the magnetic field. (See Magnetic Induction, Coefficient of.)
-
-In a more general way it is the action of a magnet upon bodies in its
-field of force. In some cases the magnetism induced causes the north
-pole of the induced magnet to place itself as far as possible from the
-north pole of the inducing magnet and the same for the south poles. Such
-substances are called paramagnetic or ferromagnetic. They lie parallel
-or tangential to the lines of force. In other cases the bodies lie at
-right angles or normal to the lines of force. Such bodies are called
-diamagnetic.
-
-Some bodies are crystalline or not homogeneous in structure, and in them
-the lines of magnetic induction may take irregular or eccentric paths.
-(See AEolotropic.)
-
-Synonym--Magnetic Influence.
-
-
-Magnetic Induction, Apparent Coefficient of.
-The apparent permeability of a paramagnetic body as affected by the
-presence of Foucault currents in the material itself. These currents act
-exactly as do the currents in the coils surrounding the cores of
-electro-magnets. They produce lines of force which may exhaust the
-permeability of the iron, or may, if in an opposite direction, add to
-its apparent permeability.
-
-
-Magnetic Induction, Coefficient of.
-The number, obtained by dividing the magnetization of a body, expressed
-in lines of force produced in it, by the magnetizing force which has
-produced such magnetization, expressed in lines of force producible by
-the force in question in air. It always exceeds unity for iron, nickel
-and cobalt. It is also obtained by multiplying the coefficient of
-induced magnetization by 4 PI (4 * 3.14159) and adding 1. (See Magnetic
-Susceptibility--Magnetization, Coefficient of Induced.)
-
-
-347   STANDARD ELECTRICAL DICTIONARY.
-
-
-The coefficient of magnetic induction varies with the material of the
-induced mass, and varies with the intensity of the magnetizing force.
-This variation is due to the fact that as the induced magnetism in a
-body increases, the magnetizing force required to maintain such
-induction, increases in a more rapid ratio. The coefficient of magnetic
-induction is the same as magnetic permeability, and in a certain sense
-is the analogue of conductivity. It is also termed the multiplying power
-of the body or core magnetized. It is the coefficient of induced
-magnetization (see Magnetization, Coefficient of Induced) referred to a
-mass of matter. For diamagnetic bodies the coefficient has a negative
-sign; for paramagnetic bodies it has a positive sign.
-
-Synonyms--Permeability--Multiplying Power--Magnetic Inductive Capacity.
-
-
-Magnetic Induction, Dynamic.
-The induction produced by a magnetic field which moves with respect to a
-body, or where the body if moving moves at a different rate, or where
-the body moves and the field is stationary. In the case where both move,
-part of the induction may be dynamic and part static. (See Magnetic
-Induction, Static.)
-
-
-Magnetic Induction, Static.
-Magnetic induction produced by a stationary field acting upon a
-stationary body.
-
-
-Magnetic Induction, Tube of.
-An approximate cylinder or frustrum of a cone whose sides are formed of
-lines of magnetic induction. (See Magnetic Induction, Lines of.) The
-term tube is very curiously applied in this case, because the element or
-portion of a magnetic field thus designated is in no sense hollow or
-tubular.
-
-
-Magnetic Inertia.
-A sensible time is required to magnetize iron, or for it to part with
-its magnetism, however soft it may be. This is due to its magnetic
-inertia and is termed the lag. Permanent or residual magnetism is a
-phase of it. It is analogous to self-induction of an electric circuit,
-or to the residual capacity of a dielectric.
-
-
-Magnetic Insulation.
-Only approximate insulation of magnetism is possible. There is no
-perfect insulator. The best ones are only 10,000 times less permeable
-than iron. Hence lines of force find their way through air and all other
-substance, being simply crowded together more in paths of iron or other
-paramagnetic substance.
-
-
-348   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Intensity.
-The intensity of the magnetization of a body. It is measured by the
-magnetic lines of force passing through a unit area of the body, such
-area being at right angles to the direction of the lines of force.
-
-
-Magnetic Lag.
-In magnetism the tendency of hard iron or steel especially to take up
-magnetism slowly, and to part with it slowly. (See Magnetic Inertia.)
-The lag affects the action of a dynamo, and is a minor cause of those
-necessitating the lead of the brushes.
-
-Synonym--Magnetic Retardation.
-
-
-Magnetic Latitude.
-Latitude referred to the magnetic equator and isoclinic lines.
-
-
-Magnetic Leakage.
-The lines of force in a field magnet which pass through the air and not
-through the armature are useless and represent a waste of field. Such
-lines constitute magnetic leakage.
-
-
-Magnetic Limit.
-The temperature beyond which a paramagnetic metal cannot be magnetized.
-The magnetic limit of iron is from a red to a white heat; of cobalt, far
-beyond a white heat; of chromium, below a red heat; of nickel at about
-350� C. (662�F.) of manganese, from 15� C. to 20� C. (59� to 68� F.)
-
-
-Magnetic Lines of Force.
-Lines of force indicating the distribution of magnetic force, which is
-due presumably to whirls of the ether. A wire or conductor through which
-a current is passing is surrounded by an electro-magnetic field of
-force, q. v., whose lines of force form circles surrounding the
-conductor in question. A magnet marks the existence of a similar
-electro-magnetic field of force whose lines form circuits comprising
-part of and in some places all of the body of the magnet, and which are
-completed through the air or any surrounding paramagnetic or diamagnetic
-body. They may be thought of as formed by the Amp�rian sheet of current,
-and analogous to those just mentioned as surrounding a conductor.
-
-
-Fig. 223. MAGNETIC LINES OF FORCE, DIRECTION OF.
-
-
-A magnetic line of force may be thought of as a set of vortices or
-whirls, parallel to each other, and strung along the line of force which
-is the locus of their centres.
-
-If as many lines are drawn per square centimeter as there are dynes (per
-unit pole) of force at the point in question, each such line will be a
-unitary c. g. s. line of force.
-
-
-349   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Mass.
-A term for a quantity of magnetism. Unit mass is the quantity which at
-unit distance exercises unit force.
-
-
-Magnetic Matter.
-Imaginary matter assumed as a cause of magnetism. Two kinds, one
-positive and one negative, may be assumed as in the two fluid theory of
-electricity, or only one kind, as in the single fluid theory of
-electricity. Various theories of magnetic matter have been presented
-whose value is only in their convenience.
-
-[Transcriber's note: See "magnet" and Edward Purcell's explanation of
-magnetism using general relativity.]
-
-
-Magnetic Memory.
-The property of retaining magnetism; coercive force; magnetic inertia;
-residual magnetism.
-
-[Transcriber's note: Small ferrite magnetic donuts were used as computer
-main memory from 1950 to 1970.]
-
-
-Magnetic Meridian.
-A line formed on the earth's surface by the intersection therewith of a
-plane passing through the magnetic axis. It is a line determined by the
-direction of the compass needle. The meridians constantly change in
-direction and correspond in a general way to the geographical meridians.
-
-
-Magnetic Moment.
-The statical couple with which a magnet would be acted on by a uniform
-magnetic field of unit intensity if placed with its magnetic axis at
-right angles to the lines of force of the field. (Emtage.) A uniformly
-and longitudinally magnetized bar has a magnetic moment equal to the
-product of its length by the strength of its positive pole.
-
-
-Magnetic Needle.
-A magnet with a cup or small depression at its centre and poised upon a
-sharp pin so as to be free to rotate or oscillate in a horizontal plane.
-The cup is often made of agate. Left free to take any position, it
-places its magnetic axis in the magnetic meridian.
-
-
-Magnetic Parallels.
-Lines roughly parallel to the magnetic equator on all parts of each of
-which the dip of the magnetic needle is the same; also called Isoclinic
-Lines. These lines mark the places of the intersection of equipotential
-surfaces with the earth's surface. They are not true circles, and near
-the poles are irregular ellipses; the magnet there points toward their
-centres of curvature. They correspond in a general way with the
-Geographical Parallels of Latitude.
-
-
-Magnetic Permeability.
-The specific susceptibility of any substance, existing in a mass, for
-magnetic induction. (See Magnetic Induction, Coefficient of, synonym for
-Magnetic Permeability and Magnetization, Coefficient of Induced.)
-
-Synonyms--Magnetic Inductive Capacity--Multiplying Power--Coefficient of
-Magnetic Induction.
-
-
-350   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Perturbations.
-Irregular disturbances of the terrestrial magnetism, as by the aurora
-and in electric storms.
-
-
-Magnetic Poles.
-The points where the equipotential surfaces of the terrestrial field of
-force graze the earth's surface; the points toward which the north or
-south poles of the magnetic needle is attracted. Over a magnetic pole
-the magnetic needle tends to stand in a vertical position. There are two
-poles, Arctic or negative, and Antarctic or positive. Magnetic needles
-surrounding them do not necessarily point toward them, as they point to
-the centres of curvature of their respective magnetic parallels. The
-poles constantly change in position. The line joining them does not
-coincide with anything which may be termed the magnetic axis of the
-earth.
-
-
-Magnetic Poles, False.
-Poles on the earth's surface other than the two regular magnetic poles.
-There seem by observation to be several such poles, while analogy would
-limit true magnetic poles to two in number.
-
-
-Magnetic Potential.
-The potential at any point of a magnetic field is the work which would
-be done by the magnetic forces of the field upon a positive unit of
-magnetism as it moves from that point to an infinite distance. (Emtage.)
-
-
-Magnetic Proof Piece.
-A piece of iron used for testing magnets and the distribution of
-magnetism in bars, by suspending or supporting above or near the magnet,
-by detaching after adherence, and in other ways.
-
-
-Magnetic Proof Plane.
-An exploring coil used for testing the distribution of magnetism. It is
-connected in circuit with a galvanometer, and exposed to alternation of
-current, or to other disturbing action produced by the magnet or field
-under examination. This affects the galvanometer, and from its movements
-the current produced in the coil, and thence the magnetic induction to
-which it was exposed, are calculated.
-
-Synonym--Exploring Coil.
-
-
-Magnetic Quantity.
-The magnetism possessed by a body; it is proportional to the action of
-similar poles upon each other, or to the field produced by the pole in
-question. It is also called the strength of a pole.
-
-The force exercised by two similar poles upon each other varies with
-their product and inversely with the square of the distance separating
-them; or it may be expressed thus (m * m) / (L^2). This is a force, and
-the dimensions of a force are ML/(T^2). Therefore, (m^2)/(L^2) =
-ML/(T^2) or m = (M^.5)*(L^1.5)/T.
-
-
-351   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Reluctance.
-The reciprocal of permeance; magnetic resistance; the relative
-resistance to the passage of lines of force offered by different
-substances. The idea is derived from treating the magnetic circuit like
-an electric one, and basing its action on magneto-motive force acting
-through a circuit possessing magnetic reluctance.
-
-
-Magnetic Reluctivity.
-The reciprocal of magnetic permeability, q. v.
-
-Synonym--Magnetic Resistance.
-
-
-Magnetic Retentivity.
-The property of steel or hard iron by which it slowly takes up and
-slowly parts with a magnetic condition--traditionally (Daniell) called
-coercitive force.
-
-
-Magnetic Rotary Polarization.
-If a plane polarized beam of light is sent through a transparent medium
-in a magnetic field its plane of polarization is rotated, and this
-phenomenon is denoted as above. (Compare Refraction, Electric, and see
-Electro-magnetic Stress.) This has been made the basis of a method for
-measuring current. A field of force varies with the current; the
-polarization produced by such field is therefore proportional to the
-current. (Becquerel & Rayleigh.)
-
-A plane polarized beam of light passing through the transparent medium
-in the magnetic field by the retardation or acceleration of one of its
-circular components has its plane of polarization rotated as described.
-The direction of the lines of force and the nature of the medium
-determine the sense of the rotation; the amount depends upon the
-intensity of the field resolved in the direction of the ray, and on the
-thickness and nature of the medium.
-
-
-Magnetic Saturation.
-The maximum magnetic force which can be permanently imparted to a steel
-bar. A bar may be magnetized beyond this point, but soon sinks to it.
-The magnetism produced in a bar is prevented from depolarization by the
-retentivity or coercive force of the bar. The higher the degree of
-magnetization the greater the tendency to depolarization.
-
-It is also defined as the maximum intensity of magnetism produced in a
-paramagnetic substance by a magnetic field as far as affected by the
-permeability of the substance in question. The more lines of force
-passed through such a substance the lower is its residual permeability.
-It is assumed that this becomes zero after a certain point, and then the
-point of saturation is reached. After this point is reached the addition
-of any lines of force is referred entirely to the field and not at all
-to the permeability of the substance. But such a zero is only definable
-approximately.
-
-
-Magnetic Screen.
-A box or case of soft iron, as thick as practicable, for protecting
-bodies within it from the action of a magnetic field. The lines of force
-to a great extent keep within the metal of the box on account of its
-permeability, and but a comparatively few of them cross the space within
-it.
-
-Such screens are used to prevent watches from being magnetized, and are
-a part of Sir William Thomson's Marine galvanometer.
-
-A magnetic screen may be a sphere, an infinite or very large plane, or
-of the shape of any equipotential surface.
-
-Synonym--Magnetic Shield.
-
-
-352   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Self-induction.
-The cause of a magnet weakening is on account of this quality, which is
-due to the direction of the lines of force within a magnet from the
-positive towards the negative pole. "A magnet thus tends to repel its
-own magnetism and to weaken itself by self-induction." (Daniell.)
-
-
-Magnetic Separator.
-An apparatus for separating magnetic substances from mixtures. Such
-separators depend on the action of electro-magnets. In one form the
-material falls upon an iron drum, magnetized by coils. Any magnetic
-substance adheres to the drum and is thereby separated. They are used by
-porcelain makers for withdrawing iron particles from clay, by machinists
-to separate iron filings and chips from brass, and for similar purposes.
-
-
-Fig. 224. MAGNETIC SEPARATOR.
-
-
-Magnetic Shell.
-A theoretical conception of a cause of a magnetic field or of a
-distribution of magnetism. If we imagine a quantity of very short
-magnets arranged in contact with their like poles all pointing in the
-same direction so as to make a metal sheet, we have a magnetic shell.
-Its magnetic moment is equal to the sum of the magnetic moment of all
-its parts. If the shell is of uniform strength the magnetic moment of a
-unit area gives the strength of the shell; it is equal to the magnetic
-quantity per unit of area, multiplied by the thickness of the shell.
-
-If its strength is uniform throughout a magnetic shell is called simple;
-if its strength varies it is termed complex.
-
-Emtage thus defines it: A magnetic shell is an indefinitely thin sheet
-magnetized everywhere in the direction normal to itself.
-
-
-Magnetic Shell, Strength of.
-The magnetic quantity per unit of area of the shell multiplied by the
-thickness of the shell.
-
-
-353   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Shield.
-In general a magnetic screen, q. v. Sometimes a strong local field is
-made to act as a shield, by its predominance overcoming any local or
-terrestrial field to which the needle to be protected may be exposed.
-
-
-Magnetic Shunt.
-The conception of a magnetic circuit being formed, the shunt is a
-corollary of the theory. It is any piece of iron which connects points
-of a magnet differing in polarity, so as to divert part of the lines of
-force from the armature or yoke. The shunt is especially applicable in
-the case of horseshoe magnets. Thus a bar of iron placed across from
-limb to limb a short distance back from the poles would act as a shunt
-to the armature and would divert to itself part of the lines of force
-which would otherwise go through the armature and would weaken the
-attraction of the magnet for the latter. In dynamos a bar of iron used
-as a magnetic shunt has been used to diminish the lines of force going
-through the armature and hence to weaken the field and diminish the
-electro-motive force. By moving the shunt nearer or further from the
-poles the dynamo is regulated.
-
-In the cut the projections between the yoke and poles of the magnet
-shown act as a shunt to the yoke, taking some lines of force therefrom.
-
-
-Fig. 225. MAGNETIC SHUNT.
-
-
-Magnetic Storms.
-Terrestrial magnetic disturbances sometimes covering very wide areas,
-and affecting the magnetic declination and inclination. One such
-disturbance was felt simultaneously at Toronto, Canada, the Cape of Good
-Hope, Prague and Van Diemen's Land. (Sabine.)
-
-
-354   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Strain.
-The strain produced by magnetic lines of force in substances exposed to
-their action. It is observed in substances placed between the poles of a
-strong electro-magnet, and evinces itself in the alteration of the
-optical properties of transparent substances.
-
-
-Magnetic Stress.
-The stress produced by magnetic lines of force on substances through
-which they pass, evidenced in alteration of the optical properties of
-transparent bodies thus treated.
-
-
-Magnetic Susceptibility.
-The specific intrinsic susceptibility of any material for magnetic
-induction. It refers to the particle of matter, and not to the mass, as
-in the latter its own particles react on each other and bring about what
-is termed permeability, q. v. (See also Magnetization, Coefficient of
-Induced, and Magnetic Induction, Coefficient of.)
-
-Synonym--Coefficient of Induced Magnetization.
-
-
-Magnetic Tick.
-When a bar of iron is suddenly magnetized or demagnetized it emits a
-slight sound, called the Page sound, or the magnetic tick. This has been
-utilized in a telephone by Reiss. The telephone will receive sound, but
-is very weak. It consists of a bar surrounded with a coil of insulated
-wire. Variations in current produce sounds, which may be articulate if
-the currents are produced by a telephonic transmitter.
-
-
-Magnetic Twist.
-A bar of iron held in the magnetic meridian and pointing to the pole and
-twisted becomes to some extent permanently magnetized. Conversely a bar
-when magnetized seems to have a twist set up in it. The latter is
-magnetic twist.
-
-
-Magnetic Variations.
-Changes in the value of magnetic declination or inclination. (See
-Magnetic Elements.)
-
-
-Magnetism, Amp�re's Theory of.
-A theory accounting for magnetic phenomena by assuming the existence of
-currents circulating around the molecules of permanent magnets. If such
-currents so circulate and all in the same direction, the result is the
-same as if the body of the magnet was enveloped in currents representing
-those of an electro-magnet or solenoid. This is because in the interior
-the current around one molecule would counteract the current around its
-neighboring ones in part, so that the only virtual currents left would
-be represented by those on the outer surfaces of the outer shell of
-molecules, and these virtually resolve themselves into one general
-current sheet, surrounding the magnet and coinciding with its surface.
-
-The theory assumes that such currents permanently circulate around the
-molecules of paramagnetic substances. Under ordinary conditions there is
-no coincidence in their direction and no resultant current is produced.
-When magnetized or polarized the molecules are brought into order, so
-that the direction of their current coincides and the body becomes a
-magnet.
-
-
-355   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 226. AMP�RIAN CURRENTS IN MAGNETS.
-
-
-At the north pole of the magnet the direction of the Amp�rian currents
-is the reverse of that of a watch when the observer faces the pole; the
-reverse obtains for the south pole.
-
-The attraction of opposite and repulsion of similar poles is explained
-by the actions of the Amp�rian currents upon each other. If north and
-south pole are placed together these currents will coincide in direction
-and hence will attract each other. If two like poles are put together
-the currents will have opposite directions and will repel each other.
-
-No energy is supposed to be required to maintain currents around or in a
-single molecule.
-
-
-Fig. 227. NORTH AND SOUTH POLES OF A MAGNET SHOWING DIRECTION OF
-AMP�RIAN CURRENTS.
-
-
-Magnetism, Blue.
-A term arising from the two fluid theory of magnetism; the magnetism of
-the south pole of a magnet. (See Magnetic Fluids.) The magnetism of the
-north pole is termed red magnetism. Both terms originated presumably in
-the painting of magnets, and are little used.
-
-Synonym--South Magnetic Fluid.
-
-
-356   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetism, Components of Earth's.
-The magnetic force of the earth acts in the plane of the magnetic
-meridian and in direction generally lies oblique to the plane of the
-horizon. It can be resolved into two components, one vertical, which has
-no directive effect upon the magnetic needle, the other horizontal,
-which represents the directive element for the usual compass needle. For
-the dipping needle, q. v., the vertical component is the only active
-one. A magnetic needle mounted on a universal joint at its centre of
-gravity would be acted on by both components.
-
-
-Magnetism, Creeping of.
-The gradual increase of magnetism when a magnetic force is applied with
-absolute steadiness to a piece of iron. It is a form of magnetic lag. It
-may last for half an hour and involve an increase of several per cent.
-of the total magnetism.
-
-Synonym--Viscous Hysteresis.
-
-
-Magnet, Iron Clad.
-A magnet with a casing of iron connected at one end to the core. The
-term is generally applied to electromagnets of this form.
-
-Synonyms--Tubular Magnet--Jacketed Magnet.
-
-
-Magnetism, Decay of.
-The gradual loss of magnetism by permanent magnets, due to accidental
-shocks, changes of temperature, slow spontaneous annealing of the iron
-and other similar causes.
-
-
-Magnetism, Discharge of.
-The loosing of magnetization. Thus in a shunt-wound dynamo there is a
-critical resistance for the outer circuit, below which the field ceases
-to be magnetized, as enough current ceases to be shunted into it to
-magnetize it. The machine is said to unbuild itself, and a discharge of
-magnetism occurs from the field magnet.
-
-
-Magnetism, Ewing's Theory of.
-Ewing found by a model consisting of a number of pivoted magnetic
-needles that the observed phenomena of magnetization could be
-represented thereby. Thus there would be no need of assuming internal
-frictional forces of Maxwell, nor the closed rings or chains of Hughes.
-The theory retains the notion, however, of paramagnetic matter,
-consisting of an assemblage of molecular magnets. The loss of energy by
-hysteresis is represented in the model by the energy lost by the needles
-in beating against the air.
-
-
-357   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetism, Free.
-The magnetism or magnetic field outside of a magnetic circuit. It is due
-to escape of lines of force and to the magnetic leakage through the air.
-The lines of force are never, under the most favorable circumstances,
-confined to the metallic circuit of the magnet and armature. In a simple
-magnet without armature all the lines of force have to follow an air
-path, and the field is at its strongest. As the magnetism is strongest
-at the surface near the poles, the term is sometimes understood as
-applying to the surface attraction. In such case it is defined as the
-distribution, on a magnetized bar or mass, of magnetic lines of force as
-they emerge from its surface.
-
-Synonym--Surface Magnetization.
-
-
-Magnetism, Hughes' Theory of.
-A theory accounting for magnetic phenomena by assuming that each
-molecule is a magnet, and that in a polarized or magnetized body they
-are all arranged with their poles in the same direction, while in an
-unmagnetized body their poles, alternating in direction, neutralize each
-other.
-
-Magnetization consists in a partial rotation of the molecules so as to
-make them agree in position, thus, as a resultant developing north and
-south poles at the ends of the bar.
-
-The theory is in a certain sense simpler than Ampere's theory, but is
-not so generally adopted.
-
-
-Magnetism, Lamellar Distribution of.
-The distribution of magnetism in thin and uniform or "simple magnetic
-shells," q. v. A given distribution is termed lamellar if the substance
-in which it exists can be divided into simple magnetic shells, which
-either form closed surfaces, or have their edges in the surface of the
-substance. In lamellar distribution the polar area is very large
-compared with the distance between opposite poles.
-
-
-Magnetism of Gases.
-Faraday experimented on this point by coloring gases with a little vapor
-of iodine or other colored gas, and letting them flow between the two
-poles of a powerful electromagnet. In this way he found some are
-repelled, some attracted, and in the case of oxygen, it is attracted at
-one temperature and repelled at another. At ordinary temperatures a
-cubic yard of oxygen possesses the magnetism of 5.5 grains of iron and
-when liquefied it is strongly attracted.
-
-
-Magnetism or Magnetization, Temporary.
-When a mass of iron is magnetized by a current, when the current ceases
-the portion of its magnetism which disappears is the temporary
-magnetism; the portion retained is the residual or permanent magnetism.
-
-
-Magnetism, Red.
-A term arising from the two fluid theory of magnetism; the magnetism of
-the north pole of a magnet. (See Magnetic Fluids.) The magnetism of the
-south pole is termed blue magnetism. Both terms originated in the
-painting of magnets. They are but little used.
-
-Synonym--North Magnetic Fluid.
-
-
-358   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetic Remanence.
-The residual magnetism left in a bar of steel or other paramagnetic
-material after the application of a powerful magnet. It is distinguished
-from coercive force, as the latter is the amount of negative magnetizing
-or of demagnetizing force required to reduce the remanent magnetism to
-zero.
-
-Synonym--Remanence--Residual Magnetism.
-
-
-Magnetism, Solenoidal Distribution of.
-The distribution of magnetism in such a way that the poles are very far
-apart in proportion to their area. The magnetization of a long thin bar
-of steel illustrates solenoidal distribution.
-
-
-Magnetism Sub-permanent.
-The magnetism of a paramagnetic substance which presents a considerable
-degree of permanency, but which gradually disappears, leaving the
-permanent magnetism present. It is noticeable in iron or steel ships
-whose magnetism gradually reduced in quantity, eventually becomes fully
-permanent.
-
-
-Magnetism, Weber's Theory of.
-The molecules of a magnetizable material by this theory are supposed to
-be magnets with their poles lying in every direction, and hence
-neutralizing each other. By magnetization these are supposed to be
-turned with their similar poles in the same direction, and their axis
-parallel, hence acting like a group of magnets. It is practically
-identical with Hughes' theory.
-
-
-Magnetism, Terrestrial.
-The magnetism of the earth. (See Magnetic Elements.)
-
-
-Fig. 228. MAGNETIZATION BY DOUBLE TOUCH.
-
-
-Magnetization by Double Touch.
-The process of magnetizing a steel bar by simultaneously stroking it
-with two poles of a horseshoe magnet or with two opposite poles of two
-bar magnets. The poles must be close but not touching. A block of wood
-may be placed between the ends if single magnets are used. The poles are
-placed on the middle of the bar and carried back and forth to one end,
-then to the other, and so on, ending at the middle of the bar in such
-direction as to give each end the same number of strokes. The poles must
-be close together or consequent poles will be produced. If bar magnets
-are used they may be held inclined at an angle of 15� to 20� with the
-horizontal bar to be magnetized. The ends of the latter may rest on
-poles of two other magnets, each end on a pole of the same name as that
-of the magnetizing magnet on its side. (See Magnetization, Hoffer's
-Method.)
-
-
-359    STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetization by Separate Touch.
-A method of magnetization. Two magnets are used. Held in an inclined
-position two opposite poles are touched to the bar near its centre, and
-are drawn off to the two ends. They are returned through the air and the
-process is repeated.
-
-
-Magnetization by Single Touch.
-A method of polarizing or magnetizing steel bars, by stroking them
-always in one direction with one pole of a magnet, returning it through
-the air. The stroking is best done on both sides. The stroking may begin
-at one end and end at the other, or it may be commenced in the center of
-the bar and be carried to one end with one pole, and the same done for
-the other half with the other pole.
-
-
-Magnetization by the Earth.
-The earth imparts magnetism to iron masses. If a rod of steel is held
-parallel to the inclination and in the magnetic meridian it exhibits
-polarity, which by jarring or hammering, can be made to some extent
-permanent. A piece of soft iron held vertically, or still better in the
-line of the dip as above, and which is twisted when in that position,
-becomes magnetized with some degree of permanence. Many other instances
-are cited, such as fire-irons, lamp-posts, iron gates, lathe turnings,
-all of which often exhibit polarity, having been magnetized by the
-earth's field.
-
-[Transcriber's note: The earth's magnetic field is believed to originate
-it electric currents in the moving molten core.]
-
-
-Magnetization, Coefficient of Induced.
-The coefficient (q. v.) expressing the relation between the specific
-intensity of magnetization of a particle and the magnetizing force. The
-magnetizing force is measured by the lines of force it can produce in a
-field of air. The coefficient of induced magnetization is the factor by
-which the intensity of a magnetizing field must be multiplied to produce
-the magnetization imparted by it to a particle of any substance. This
-coefficient varies for different substances, and is also called magnetic
-susceptibility. It is distinguished from permeability as referring only
-to a particle isolated from influence of a mass of surrounding particles
-of its own kind. It is definable as the intensity of the magnetization
-assumed by an exceedingly long and exceedingly thin bar placed in a unit
-field. If a mass of metal were placed in such a field all its particles
-would become affected and within the mass no unit field could exist.
-Hence magnetic susceptibility (another name for this coefficient) does
-not apply to the case of large cores of electro-magnets and
-dynamo-armatures, but is really a theoretical rather than a practical
-figure.
-
-The sign of the coefficient of diamagnetic bodies is negative; of
-paramagnetic bodies is positive.
-
-Synonym--Magnetic Susceptibility.   \
-
-
-360   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetization, Cycle of.
-A cycle of positive or of positive and negative magnetization represents
-the application of a magnetizing force beginning at a fixed value,
-generally zero, rising to a maximum, or to a value of maximum distance
-from the initial and then returning to the original basis. It is
-virtually a full wave of magnetization and may extend on both sides of a
-zero line giving positive and negative values.
-
-Cycles of magnetization apply especially to transformers and other
-apparatus of that character used with the alternating current system.
-
-
-Magnetization, Hoffer's Method.
-For horseshoe bars an armature is placed against the poles of the magnet
-bar to be treated. The poles of a strong horseshoe magnet are stroked
-over it from poles to bend and returned through the air, or vice versa.
-In the first case the poles will be the same as those of the inducing
-magnet; in the second case they will be opposite. A maximum effect is
-produced in ten strokes. The stroking should be applied to both sides.
-An electro-magnet may be used as inducer as shown, but an armature
-should be used; in the cut it is omitted.
-
-
-Fig. 229. MAGNETIZING A HORSESHOE MAGNET.
-
-
-Magnetization, Intensity of.
-The amount of magnetism induced in or present in a body. It is expressed
-in Magnetic Lines of Force, q. v., per cross-sectional area.
-
-
-Magnetization, Isthmus Method of.
-A method used by Ewing in a research on the magnetization of iron in
-very strong fields. He used samples of iron turned down in the centre to
-a narrow neck, and thus concentrated the lines of force greatly.
-
-
-Magnetization, Elias' Method.
-The bar to be magnetized is surrounded by a magnetizing coil, q. v. A
-strong current is passed through it, and the coil is moved back and
-forth a few times.
-
-
-Magnetization, Jacobi's Method.
-For horseshoe bars. The bar is placed with its poles against those of a
-horseshoe magnet. A bar of soft iron, long enough to reach from outside
-to outside of the legs, is laid across near the junction and is drawn
-along towards the bend of the new bar and away from it. This is repeated
-a few times on both sides.
-
-
-361   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetization, Limit of.
-As the induction of magnetizing force increases, magnetization of
-paramagnetic metals tends towards a limit, the increase in magnetization
-being continually less and less as the metal becomes more highly
-magnetized. In diamagnetic substances no limit is discernible.
-
-Synonym--Maximum Magnetization.
-
-
-Magnetization, Specific.
-The magnetic moment per gram of a substance.
-
-
-Magnet-keeper.
-A bar of iron connecting the two poles of a permanent magnet. Often the
-same bar serves as armature and keeper.
-
-
-Magnet, Lamination of.
-It is advantageous to make magnets of laminated construction, or of thin
-plates of steel. The thin metal can be better tempered or hardened than
-thick metal. A slight separation of the plates is advantageous from some
-points of view. If in actual contact there is some danger that the
-weaker members will have their polarity reversed by the stronger ones.
-This is counteracted to some extent by separation.
-
-
-Magnet, Long Coil.
-A high resistance electro-magnet; one whose coil is of thin wire of
-considerable length.
-
-
-Magnet, Natural.
-The lodestone, q. v.; a variety of magnetite or magnetic oxide of iron,
-exhibiting permanent magnetism, attracting iron, and possessing north
-and south poles.
-
-
-Magnet, Neutral Line of.
-A line at right angles to the magnetic axis of a magnet, q.v., and
-nearly or quite at the centre, so situated with reference to the poles
-on either end that it marks the locus of no polarity. It has been called
-the equator of the magnet. It is defined by the intersection of the
-plane of no magnetism with the surface of the bar.
-
-Synonym--Magnetic Equator.
-
-
-Magnet, Normal.
-A bar or compound bar magnet, magnetized to such an extent that the
-curves of the lines of force run into each other in the middle, is thus
-termed by Jamin.
-
-
-Magneto.
-Abbreviation for Magneto-electric Generator. (See Magneto-electric
-Generator.)
-
-
-Magneto Call Bell.
-A call operated by current from a magneto-electric generator. It is very
-generally used in telephone systems.
-
-
-362  STANDARD ELECTRICAL DICTIONARY.
-
-
-Magneto-electric. adj.
-Relating to induced electric effects due to the cutting of true magnetic
-lines of force by, or equivalent action of or upon a conductor. These
-effects are identical with electro-magnetic effects and are only
-distinguished from them by the field being due to a permanent magnet
-instead of an electromagnet.
-
-
-Magneto-electric Brake.
-A device for bringing to rest an oscillating galvanometer needle. It
-consists essentially of a coil in circuit with a key and with the
-galvanometer. On opening the circuit an inverse current is established
-by induction, tending to bring the needle to rest.
-
-
-Magneto-electric Generator.
-A current generator operating by maintaining a potential difference at
-its terminals, by reactions in a field of force, which field is
-established by a permanent magnet.
-
-The cut, Fig. 230, shows the general principle of construction of a
-direct current generator. The armature is rotated between the poles of a
-permanent magnet. Any of the regular types of dynamo armature can be
-used. From its commutator the current is taken by brushes.
-
-
-Fig. 230. MAGNETO-ELECTRIC GENERATOR.
-
-
-Fig. 231. MAGNETO-ELECTRIC GENERATOR.
-
-
-363   STANDARD ELECTRICAL DICTIONARY.
-
-
-The cut, Fig. 231, shows an alternating current machine. In it a pair of
-bobbins, wound in series, and both either right-handed or left-handed,
-are rotated between permanent magnet poles. The current may be taken off
-by two brushes bearing on two collecting rings on the axis of the
-bobbins, the ends of the wire being connected thereto. Or if a shocking
-current is desired, one of the brushes or springs may strike a series of
-pins forming virtually a broken or interrupted collecting ring. This
-gives a current for medical purposes.
-
-Synonyms--Magneto-dynamo--Magneto-electric Machine.
-
-
-Magnetograph.
-An apparatus for recording variations in magnetic elements. One type
-includes a magnetic needle to which a concave mirror is attached. The
-light ray from the mirror is reflected upon sensitized paper where its
-movements are photographically reproduced. The movements of the spot are
-due to the movements of the needle and act as the record of the same.
-
-
-Magneto-Inductor.
-An instrument for use with a ballistic galvanometer to reproduce a
-definite current impulse. Two magnets are fastened together in one
-straight line, the north poles almost touching. This is mounted at the
-end of a rod like a pendulum, the axis of the magnets transverse to the
-rod. The magnets are carried by a frame and oscillate at the end of the
-rod, back and forth within a fixed coil, which is one-half the length
-of the double magnet. A bob is attached to the bottom of the frame by
-which the whole can be swung. As the magnets are of fixed value, their
-time of oscillation constant, and the coil fixed in size, the apparatus
-provides a means of getting a definite instantaneous current of
-identical value whenever needed.
-
-
-Fig. 232. MAGNETO-INDUCTOR.
-
-
-364   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnetometer.
-(a) A reflecting galvanometer, with heavy magnetic needle, dampened by a
-copper frame. It was devised by Weber.
-
-(b) An apparatus for measuring the intensity of magnetic force. It may
-consist of a magnet suspended by bifilar or by torsion suspension. A
-reflecting mirror and scale as in the reflecting galvanometer may be
-used to act as indicator of its motions. It is used in investigations of
-the intensity of the earth's field.
-
-If the motions of the spot of light are received on a moving strip of
-sensitized paper and are thereby reproduced photographically, the
-instrument is self-recording. Such an apparatus is used in the Kew
-Observatory, Eng., for recording the terrestrial magnetic elements.
-
-
-Magnetometry.
-The determination of the magnetic moment of a magnet.
-
-It involves the determination by experiment of--( a) the product of the
-magnetic moment, M, of the magnet by the horizontal component, H, of the
-earth's magnetism; (b) the quotient of M divided by H. Knowing these two
-quantities, M is given by the formula M = SquareRoot( )M * H) * (M/H) )
-and if desired H is given by the formula H = SquareRoot( (M*H) / (M/H)).
-
-M*H is determined by the method of vibrations. A very long, thin magnet
-suspended by a torsion filament is caused to oscillate, and its period
-is determined. Calling such period T and the moment of inertia of the
-magnet I, we have the formula T= 2* PI * SquareRoot( I / (H*M) )  (a),
-whence H*M is calculated, I of course being known or separately
-determined.
-
-
-Fig. 233 END-ON METHOD.
-
-
-Fig. 234. BROADSIDE METHOD.
-
-
-M/H is determined by the End-on deflection method, or the Broadside
-deflection method. In both cases the deflection of a compass needle by
-the magnet in question is the basis of the work.
-
-In the end-on method AB is the magnet under examination; DE the compass
-needle; a the angle of deflection; d  the distance between C and the
-middle of AB, which should be considerable compared with the length of
-DE; 2l, the length of AB. We then have the formula
-   tan a = (M/H) * (2d / (d^2 - l^2)^2),
-which if 2l is small compared to d reduces to
-   tan a = M/Hd 3
-
-(b), which gives M/H, a and d being known.
-
-
-365   STANDARD ELECTRICAL DICTIONARY.
-
-In the broadside method the line d is the magnetic meridian, and the
-diagram shows the relative positions. We then have the formula
-  tan a = (M/H) / (d2 + l2)^1.5;
-which if 1 is relatively small reduces to
-  tan a = M/(H * d3 )(C.)
-
-[Transcriber's note: The image of the above paragraphs is included here.]
-
-a and c or a and b can be combined giving M and H in C.G.S. measurement.
-
-
-Magnetometer, Differential.
-An apparatus, invented by Eickemeyer, for testing the magnetic qualities
-of different samples of iron. It is very similar in construction and
-principle to the magnetic bridge, q. v.
-
-
-Magneto-motive Force.
-The force producing a magnetic field or forcing lines of force around a
-magnetic circuit. It is usually applied only to electro-magnets and is
-expressible in turns of the wire winding multiplied by amperes of
-current, or in ampere-turns.
-
-
-Magnet Operation.
-A term in surgery; the use of the electro-magnet or permanent magnet for
-removing particles of iron from the eye.
-
-
-Magnetoscope.
-An apparatus for detecting the presence of magnetism, without measuring
-its intensity. A simple magneto-scope consists of a magnetized bit of
-watch-spring suspended in a vertical glass tube by a fine filament. A
-bit of unmagnetized soft iron wire may be used in the same way. The
-first has the advantage of indicating polarity; the latter merely shows
-magnetic attraction. A cork may be used as base of the instrument.
-
-
-Fig. 235. MAGNETOSCOPE.
-
-
-366   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnet, Permanent.
-A bar of steel charged with residual magnetism. Steel possesses high
-coercive force in virtue of which when once magnetized it retains part
-of the magnetization.
-
-Permanent magnets are generally straight bars or U shaped; they are
-termed bar magnets, magnetic needles, horseshoe magnets, machine magnets
-and otherwise, according to their shape or uses.
-
-
-Magnet Pole.
-The part of a magnet showing strongest polarity; the part which attracts
-iron the most powerfully, and acts as the starting point for lines of
-force.
-
-
-Magnet Poles, Secondary.
-Magnet poles are often not situated at the ends. Owing to inequality of
-the material or other causes they may occupy intermediate positions on
-the magnet. Such poles are called secondary poles.
-
-
-Magnet Pole, Unit.
-A unit magnet pole is one which exerts unit force on another unit pole
-placed at unit distance from it. Unit force is the dyne; unit distance
-is one centimeter.
-
-
-Magnet, Portative Power of.
-The power of sustaining a weight by attraction of its armature possessed
-by a magnet. In general terms the adherence of the armature of a magnet
-to the pole varies with the square of the number of lines of force which
-pass through the point of contact. Hence an increased adherence of the
-armature to a horseshoe electro-magnet is sometimes obtained by
-diminishing the area of contact of one pole which concentrates the lines
-of force. Steel magnets were frequently made with rounded ends to
-increase the portative power.
-
-
-Magnet, Simple.
-A magnet made of one piece of metal, or at least magnetized as such; the
-reverse of a compound magnet, which is magnetized piece by piece and
-then fastened together.
-
-
-Magnet, Solenoidal.
-A magnet which is so uniformly magnetized and is so long in proportion
-to its other dimensions that it virtually establishes two magnetic
-poles, one at either end. It is a long thin bar so magnetized that all
-its molecules would, considered as magnets, be absolutely equal.
-(Daniell.) It acts like a solenoid, except that it is longer in
-proportion than the solenoid generally is constructed.
-
-
-Magnet, Sucking.
-A magnet coil with movable or loose axial bar of soft iron.
-
-The whole is usually mounted vertically. When a strong enough current is
-passed the bar is drawn up into the coil as if by suction, whence the
-name.
-
-
-367   STANDARD ELECTRICAL DICTIONARY.
-
-
-Magnet, Unipolar.
-No such thing as a unipolar magnet is possible. The name is given to
-poised or suspended magnets, one of whose poles lies in the axis of
-suspension. It is obvious that such a magnet will act, as far as its
-directive tendency and rotatory movements are concerned, as if it had
-only one pole. As shown in the cut, the pole s in both magnets lies in
-the axis of suspension or directly under the filament by which they are
-suspended, while the other pole n is the active pole in causing rotation
-or directive tendency; c c are counterweights or counterpoises.
-
-
-Fig. 236. UNIPOLAR MAGNETS.
-
-
-Magnetophone.
-An apparatus for producing a loud sound, involving the principles of the
-telephone. A rapidly alternating or make and break current being
-produced by any means and being transmitted through the telephone gives
-a loud note of pitch dependent on the current producing it. Sometimes a
-perforated metallic disc is rotated in a magnetic field, and produces
-the requisite type of current.
-
-
-Magnus' Law.
-A law of thermo-electricity. In a homogeneous circuit, however, the
-temperature varies from point to point; there is no current.
-
-Whatever potential differences may be established by the variations in
-temperature it is evident that they must counteract each other and
-reduce to zero.
-
-
-Mains, Electric.
-The larger conductors in a system of electric light or power
-distribution.
-
-
-Make. v.
-To complete a circuit, as by closing a switch.
-
-
-Make and Break Current.
-A current which is continually broken or interrupted and started again.
-It is applied only where the "makes" and "breaks" succeed each other
-with great rapidity, as in the action of an induction coil or pole
-changer, etc. It has had considerable importance in litigation affecting
-the Bell telephone patents, the courts holding that the original Bell
-patent (No. 174,465, of 1876,) covered the undulating current, for the
-transmission of speech. Many efforts have been made by litigants to
-prove that specific telephones have transmitted articulate speech by the
-make and break current, but without success. If this could have been
-proved the assumption is that the courts would have sustained the use of
-such device as not infringing upon the claims of the Bell patent.
-
-
-Malapterurus.
-A fish, sometimes called the thunder fish, an inhabitant of African
-rivers, occurring in the Nile and Senegal. It possesses considerable
-electric power, similar to that of the gymnotus and torpedo, although
-inferior in amount.
-
-
-368   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 237. MALAPTERURUS.
-
-
-Man-hole.
-The cistern-like depression in the ground for giving access to the ends
-of tubes in electric conduits. (See Conduit, Electric Subway.)
-
-
-Marked End or Pole.
-The north pole or north seeking pole of a magnet, so called because it
-is usually marked with a notch or scratch by the maker. The south pole
-is called the unmarked end.
-
-
-Mass.
-The quantity of matter in a body. The C. G. S. unit of mass is the
-quantity of matter in a gram. While weight varies with latitude and
-other circumstances, mass is invariable.
-
-The unit of mass is also defined as the quantity of matter which in a
-balance will counterpoise a standard mass, the gram or pound. As the
-gram is intended to be the mass of one cubic centimeter of water at
-3.09� C. (39� F.), the C. G. S. unit of mass is really 1.000013 gram.
-
-As a primary unit its dimensions are indicated by M.
-
-
-Mass, Electric.
-A term for quantity of electricity. The unit mass is such a quantity as
-at unit distance will act with unit force.
-
-
-Matter, Electric.
-The imaginary substance constituting electricity; a conception used
-purely as a matter of convenience.
-
-[Transcriber's note: The electron was discovered five years after this
-publication.]
-
-
-Matter, Radiant.
-Matter in the ultra-gaseous or so-called fourth state. In the gaseous
-state the molecules of a gas are in perpetual kinetic motion, colliding
-actually or virtually with each other, rebounding from such approach,
-and striking also the walls of the containing vessel. But except for
-these deflections, which are of enormous frequency, the paths of the
-molecules would be perfectly straight.
-
-In the radiant state matter exists in so high a vacuum that collisions
-of the molecules rarely occur, and the molecules simply beat back and
-forth in straight lines from side to side of the containing vessel.
-
-A layer of gas in this condition is termed a Crookes' layer, from Prof.
-William Crookes, who discovered and investigated these phenomena.
-
-
-369   STANDARD ELECTRICAL DICTIONARY.
-
-
-Luminous streams of the molecules are produced by electric high
-potential discharges between electrodes. The course of the discharge is
-normal, in general terms, to the surfaces of the electrodes, and reaches
-from one to the other in a curve or straight line, as the case may be.
-
-These luminous streams are deflected by a magnetic field; if brought to
-a focus can heat refractory material in that focus to a full white heat,
-and can develop phosphorescence. The latter is termed electric
-phosphorescence. A great variety of experiments have been devised to
-illustrate the phenomena of radiant matter. The vacuum is generally
-produced in a hermetically sealed glass vessel into which the electrodes
-are sealed, and which contain the phosphorescent substances or other
-essentials for the experiments. The vessels are termed Crookes' Tubes.
-
-[Transcriber's note: Crookes reported on "radiant matter" in 1879. It is
-actually electrons, but he failed to distinguish them from ordinary
-atoms. Thompson properly described electrons in 1897.]
-
-
-Matteueci's Experiment.
-An experiment for showing the inductive effect of the discharge of a
-Leyden jar. Two glass plates are supported on standards in a vertical
-position. Flat coils of wire are wound or coiled and secured to one
-surface of each plate. One plate has much finer and longer wire than the
-other. Metal handles are connected to the ends of the coarser wire coil.
-The plates are placed with their coils facing each other. A Leyden jar
-is discharged through the coarser coil, while the handles are grasped by
-a person. The shock of the discharge is felt by him.
-
-
-Matting, Electric Floor.
-Matting or floor covering underlaid with burglar alarm contacts, so
-arranged as to be closed by anyone walking on the matting. The contacts
-are connected to a burglar alarm system. The object is to provide an
-alarm if a burglar enters a house, in case he should enter a door or
-window without sounding the bell. The latter can be done by cutting out
-the window or part of the door instead of opening it.
-
-
-Maxwell's Theory of Light.
-A theory of light. It is due to J. Clerk Maxwell.
-
-It supposes the phenomena of electric induction to be due to the ether,
-q. v. It supposes the condition of the ether when conveying light to be
-the same as if exposed to the induction of rapidly alternating currents
-or discharges (in this case synonymous). It therefore is an
-electro-magnetic effect if the theory is correct.
-
-An electric stress such as one due to the induction of an
-electrostatically charged body is not a wave-creating element or factor,
-but is a simple stress. But let this stress be stopped and renewed and
-at once it appears as a wave-forming agency.
-
-This stoppage and renewal represents evidently a discharge succeeded by
-a charge, or if repeated is equivalent to an intermittent current or an
-alternating one.
-
-
-370   STANDARD ELECTRICAL DICTIONARY.
-
-
-Again the electrostatic stress kept constant may by being carried
-through space carry with it a wave, just as a moving projectile carries
-a wave of air in advance of itself.
-
-Admitting this much the following consequences follow:
-
-Since in non-conductors the displacement produces a restitution force,
-which varies as the displacement which is requisite or is a criterion
-for the propagation of waves, while in conductors no such force is
-manifested and the electric energy appears as heat, it follows that
-light vibrations are not possible in conductors, because
-electro-magnetic waves do not exist in them when they are in circuit,
-and conductors should be opaque, while the reverse is true for
-non-conductors. (Daniell.)
-
-This is carried out often enough to make a striking evidence in favor of
-Maxwell's theory.
-
-The velocity of propagation of an electro-magnetic disturbance in a
-non-conductor should be equal to that of light. This constant is proved
-by mathematical considerations, to be approximately the same as the
-ratio of the electrostatic to the electromagnetic unit of intensity or
-quantity. This ratio is 3E10 (30,000,000,000), which is almost exactly
-the velocity of light.
-
-It also follows from what has been said that if an electrostatically
-charged body were whirled around a galvanometer needle at the rate of
-3E10 revolutions per second it should affect it like a circulating
-current. This rate of rotation cannot be attained, but Rowland has made
-manifest the effect of a rotating statically charged body upon a
-magnetic needle.
-
-The above is the merest outline of Maxwell's theory. The full
-development must be studied in his own and succeeding works.
-
-
-Mayer's Floating Magnets.
-An experiment due to Prof. Mayer. A number of sewing needles are
-magnetized and thrust into bits of cork, almost all the way through,
-with their like poles projecting. They are floated in a basin of water
-and take, under the effects of attraction and repulsion, when approached
-by a magnet pole, regular geometric positions, marking out the positions
-of angles of polygons.
-
-
-Measurements.
-The determination of the value of quantities; determination of the
-factor by which the unitary value must be multiplied to produce the
-quantity under examination. Such are the measurement of the voltage of a
-galvanic battery, or of the ohms of resistance of a conductor.
-Electricity has been termed the science of measurement.
-
-
-Meg or Mega.
-A prefix, meaning one million times. A megohm is one million ohms; a
-megerg is one million ergs; a megadyne is one million dynes.
-
-
-371    STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 238. MAYER'S FLOATING MAGNETS.
-
-
-Mercury.
-A metal; one of the elements; symbol, Hg; atomic weight, 200 ;
-equivalent, 200 or 100; valency, 1 and 2.
-It is a conductor of electricity.
-The following data are 0� C. (32� F.)
-  Relative Resistance,   62.73
-  Specific Resistance,   94.32   microhms.
-  Resistance of a wire,
-  (a) 1 foot long, weighing 1 grain,     18.51   ohms.
-  (b) 1 foot long, 1/1000 inch thick,   572.3     "
-  (c) 1 meter long, weighing 1 gram,     12.91    "
-  (d) I meter long, 1 millimeter thick    1.211   "
-  Resistance of  a 1 inch cube,   37.15   microhms.
-  Percentage increase of resistance per degree C. 1.8� F.
-    at about 20� C. (68� F.),   .72   per cent.
-  Electro-chemical equivalent (Hydrogen = .0105),   2.10   mgs.
-                                                    1.05   "
-
-372   STANDARD ELECTRICAL DICTIONARY.
-
-
-Mercury Cup.
-A cup of iron, wood or some material that does not amalgamate or is
-unattacked by mercury, which is filled with mercury and made an
-electrode of a circuit. By dipping the other terminal of the circuit
-into the mercury a very good contact is obtained. It is well to cover
-the mercury with alcohol. The cup may be filled so that the mercury
-rises in a meniscus or semi-globule above its edges.
-
-For some purposes this form is useful, as for contacts with the end of a
-swinging wire or pendulum, because in such cases the contact can be made
-without the contact point entering the cup. The point swings through the
-projecting meniscus without touching the edges of the cup. A mercury cup
-and contact constitute a mercury break.
-
-
-Meridian, Astronomical.
-The great circle passing through the north and south poles of the
-celestial sphere. It lies in a plane with the corresponding geographical
-or terrestrial meridian.
-
-
-Meridian, Geographic.
-The true north and south meridian; the approximate great circle formed
-by the intersection of a plane passing through north and south poles of
-the earth with the earth's surface.
-
-
-373   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 239. SCHALLENBERG'S ALTERNATING CURRENT METER.
-
-
-Meter, Alternating Current.
-A meter for measuring alternating current, as supplied to consumers,
-from an alternating current system. Like most commercial meters its only
-function is the measurement of quantity; the potential difference is
-maintained at a constant figure by the generating plant.
-
-The cut shows the Schallenberg meter. It is simply an alternating
-current motor (see Motor, Alternating Current), with air vanes mounted
-on its spindle. A main coil passes all the current. Within this is a
-second coil complete in itself, and not touching or connecting with the
-other. The latter is built up of copper rings. Within the two coils, and
-concentric with both is a disc of copper carried by a vertical spindle.
-The same spindle carries air vanes, and is free to rotate. As it does so
-it moves the indicating machinery.
-
-The current in the outer coil induces one in the inner coil. Owing to
-lag, the current in the inner one differs in phase from that in the
-outer one, and a rotatory field is produced. The copper disc acquires
-induced polarity, and rotates with speed which normally would be in
-proportion to the square of the current. But the object of the meter is
-to register the current only. The air vanes effect this. The resistance
-of the air to their motion causes the rate of rotation to vary directly
-as the speed.
-
-
-Meter Bridge.
-A form of Wheatstone's bridge in which one lateral pair of arms is
-represented by a straight wire. The other pair comprise a known
-resistance, and the resistance to be determined. The galvanometer is
-connected on one side between the known and unknown resistance. On the
-other side its connection is moved back and forth along the straight
-wire until the balance is secured and the galvanometer reads zero.
-
-The relative lengths of wire intercepted between the two ends thereof
-and the movable galvanometer connection are proportional to the
-resistance of these parts and give the necessary data with the one known
-resistance for determining the unknown resistance.
-
-
-374   STANDARD ELECTRICAL DICTIONARY.
-
-
-In the original meter bridge the wire was one meter long, whence its
-name, and was stretched straight. In more recent examples the wire
-varies in length and in one form is bent into a circle or spiral, so as
-to make the instrument more compact.
-
-The contact is not a sliding one, but is adjusted by trial. The contact
-piece is slid along, but not touching the wire, and from time to time is
-pressed down against the wire. This prevents wear of the wire. The wire
-may be made of platinum or of platinum-iridium alloy. The latter is
-very hard and not easily worn out.
-
-Sometimes, as shown in the cut, three parallel wires are stretched along
-the baseboard of the instrument, and arranged so that a single wire, two
-wires or three wires in series can be used for the proportional sides of
-the bridge, thus making it a two-meter or three-meter bridge as desired.
-On the other hand some are made of restricted length, as a half or
-quarter meter only.
-
-
-Fig. 240. METER BRIDGE.
-
-
-In the cut J K is the wire, traversed by the contact key. By moving the
-contact C back and forth in the slot it can be brought over any of the
-three divisions of the wire. H is the handle for depressing the key. S
-is a flat spring, carrying the contact piece and holding it up from the
-wires, except when pressed downwards. As shown in the cut, it is in use
-for calibrating a voltmeter V, by Poggendorff's method, G being the
-galvanometer and r1 and r2 being resistances.
-
-Synonyms--Slide Bridge--Slide Balance.
-
-
-Meter Candle.
-A unit of illuminating power; the light given by one standard candle at
-a distance of one meter. The ordinary units of illuminating power are
-altogether relative; this one is definite.
-
-
-375   STANDARD ELECTRICAL DICTIONARY.
-
-
-Meter, Chemical Electric.
-A current meter in which the current is determined by the amount of
-chemical decomposition which it can effect. In the Edison meter the
-solution is one of zinc sulphate. Two electrodes of zinc are immersed in
-it, and a fractional part of the current is passed through it. The gain
-in weight of one electrode and the loss in the other are proportional to
-the current. Both electrodes are weighed periodically, one acting as
-check upon the other.
-
-
-Meter, Current.
-An instrument for measuring the quantity of electricity in current form
-supplied to consumers. It may be of various types. The general principle
-involved is that in commercial installations for incandescent light and
-power supply a fixed potential is usually maintained, the multiple arc
-system being employed. Hence all that is requisite is to measure the
-coulombs or the ampere-hours to know what quantity of energy has been
-supplied.
-
-
-Meter, Electro-magnetic.
-A current meter in which the current is measured by its electro-magnetic
-effects.
-
-
-Meter-millimeter.
-A unit of resistance. (See Resistance, Meter-millimeter.)
-
-
-Meter, Thermal Electric.
-A current meter in which the current is measured by the heat it imparts
-to a conductor. In one meter a very light helix of mica is poised
-horizontally over a conductor, and the whole is enclosed in a case. As
-the wire is heated it causes an ascending current of air which rotates
-the vane, and the latter moves delicate clockwork which moves indicating
-hands. The hotter the wire the more rapidly the air ascends, and
-consequently the speed of the vane is proportional to the current,
-because the heat of the conductor is proportional thereto.
-
-
-Meter, Time Electric.
-An electric meter which measures the length of time during which current
-is used. It assumes a constant current and potential. It is virtually a
-clock, which is turned on when the current passes, and is turned off
-with the current.
-
-
-Meter, Watt.
-A combined current and potential meter. It is constructed on the general
-lines of a Siemens' Electro Dynamometer. If in it one coil is made of
-coarse wire and is placed in series with the current conductor, and if
-the other is wound with fine wire and is connected as a shunt from point
-to point whose potential difference is to be determined, the instrument
-becomes a watt meter.
-
-Synonym--Energy Meter.
-
-
-Methven Standard or Screen.
-A standard of illuminating power. It is the light emitted by a
-three-inch Argand gas flame through a rectangular aperture in a silver
-plate carried by a screen. The aperture is of such size and so far
-distant from the flame as to permit the passage of exactly two candles
-illuminating power.
-
-
-Fig. 241. METHVEN SCREEN
-
-
-376   STANDARD ELECTRICAL DICTIONARY.
-
-
-Mho.
-A unit of conductance, not in very general use. It is the reciprocal of
-the ohm. Thus a resistance of ten ohms is a conductance of one-tenth
-mho.
-
-
-Mica.
-A natural mineral, a silicate of several oxides; muscovite. It is used
-as an insulator and dielectric. Its resistance per centimeter cube after
-several minutes electrification at 20� C. (68� F.) is 8.4E13 ohms
-(Ayrton). Its specific inductive capacity is 5, air being taken at 1.
-
-
-Mica, Moulded.
-An insulating material, whose body is made of mica pulverized and
-cemented together with heat and pressure and some suitable cement.
-Shellac is often used as the cement.
-
-
-Micro.
-A prefix meaning "one-millionth of;" a micro-farad is one-millionth of a
-farad.
-
-
-Micrometer.
-An instrument for measuring small distances or small differences. It
-generally is based upon an accurate screw which may have a worm wheel
-for head, actuated by a worm or helix with graduated head, so that
-exceedingly small advances of the screw may be produced. The pitch of
-the screw being known its actual advance is known.
-
-
-Micrometer, Arc.
-A micrometer for measuring the distance between voltaic arc electrodes.
-
-
-Micron.
-A unit of length. It is one-millionth of a meter or four
-one-hundred-thousandths of an inch.
-
-
-377   STANDARD ELECTRICAL DICTIONARY.
-
-
-Microphone.
-An apparatus which includes a contact of variable resistance; such
-resistance can be varied in amount by slight vibrations, such as those
-produced by sound waves. The apparatus in use forms part of a circuit
-including a telephone and current generator. As the contact is varied
-the resistance of the circuit and consequently the current intensity
-changes and sounds are emitted by the telephone corresponding to such
-changes. If the microphone is spoken to, the telephone will emit
-corresponding sounds, reproducing the voice.
-
-It has been found in practice that carbon gives the best microphone
-contact. One of the simplest and earliest forms is shown in the cut. A
-short rod or pencil of carbon, A, such as used in batteries, is
-sharpened at the ends and rests loosely in a vertical position between
-two blocks of carbon, C C, in each of which a hole is drilled to receive
-one of the points. The blocks are carried on a standard and base D. The
-blocks are connected with two terminals x, y, of a circuit, including a
-telephone and battery. There are two contacts to be disturbed.
-
-If delicately adjusted a fly walking over the base-board will disturb
-the contacts enough to produce sounds in the telephone. These sounds are
-possibly not due only to sound waves, but in part to absolute mechanical
-disturbances.
-
-The various forms of telephone transmitter are generally microphones.
-
-
-Fig. 242. MICROPHONE.
-
-
-Microphone Relay.
-A combined microphone and telephone. A microphone is placed close to the
-diaphragm of a telephone. The slight sound waves emitted by the
-telephone affect the microphone and are repeated in its circuit. The
-microphone circuit includes a local battery and telephone.
-
-
-Microtasimeter.
-An apparatus for indicating minute changes in temperature or atmospheric
-moisture.
-
-
-378   STANDARD ELECTRICAL DICTIONARY.
-
-
-A button of compressed lampblack is placed in series with a battery and
-galvanometer. A strip of some substance, affected in its length either
-by heat or by moisture, is held pressing against the button. A slight
-change in length of the strip varies the resistance of the button and
-hence affects the galvanometer. In this way exceedingly slight changes
-in heat or moisture may be indicated.
-
-For heat indications vulcanite may be used. The heat of the hand held
-near it is enough to affect the galvanometer. For moisture a slip of
-gelatine is used. The moisture of a damp slip of paper two or three
-inches distant is sufficient to affect the galvanometer.
-
-In the cut, Fig. 2, shows the general distribution of the apparatus in
-circuit with a battery and galvanometer. C is the base of the apparatus,
-from which the standard, B, with adjusting screw, H, rises. The strip of
-vulcanite is held between I and G. Within D is the carbon button (F in
-Fig. 3) pressed between G and E; A is a standard to carry the parts last
-described. In Fig. I it is shown as part of a Wheatstone bridge, a, b
-and c being resistance coils; l the tasimeter, and g the galvanometer.
-If a balance is secured, any variation in the resistance of the
-tasimeter will disturb the galvanometer.
-
-Synonym--Tasimeter.
-
-
-Fig. 243. MICROTASIMETER.
-
-
-379   STANDARD ELECTRICAL DICTIONARY.
-
-
-Mil.
-A unit of length; one-thousandth part of a lineal inch.
-
-It is equal to
-.025399 millimeter;
-.000083 foot;
-.001000 inch.
-
-
-Mil, Circular.
-A unit of area; employed in designating the cross-sectional area of
-wires and other circular conductors.
-
-It is equal to
-  .78540  square mil;
-  .000507 square millimeter;
-  7.8E-7 (.00000078) square inch.
-
-If the diameter of a wire is given in mils, the square of its diameter
-gives its cross-sectional area in circular mils.
-
-
-Mil-foot.
-A unit of resistance. (See Resistance, Mil-foot, Unit of).
-
-
-Mil, Square.
-A unit of area; one-millionth of a square inch.
-
-It is equal to
-   .000645 square millimeter;
-  1.2733 circular mil;
-   .000001 square inch.
-
-
-Milli.
-A prefix; one-thousandth. Thus a milligram is one-thousandth of a gram;
-a millimeter is one thousandth of a meter.
-
-
-Milligram.
-A unit of weight ; one-thousandth of a gram, q. v.
-
-It is equal to
-  .015432 grain;
-  .000032 troy ounce.
-
-
-Millimeter.
-A unit of length; one-thousandth of a meter.
-
-It is equal to
-  39.37079 mils;
-    .03937 inch;
-    .00109 yard.
-
-
-380   STANDARD ELECTRICAL DICTIONARY.
-
-
-Milli-oerstedt.
-A proposed but not adopted unit of current; one-thousandth of an
-oerstedt. It is equal to one-thousandth of an ampere.
-
-[Transcriber's note: oersted: 1. CGS unit of magnetic intensity, equal
-to the magnetic pole of unit strength when undergoing a force of one
-dyne in a vacuum. 2. Formerly, the unit of magnetic reluctance equal to
-the reluctance of a centimeter cube of vacuum between parallel
-surfaces.]
-
-
-mm.
-Contraction for millimeters.
-
-Molar.
-Referring to phenomena of mass as gravitation. Mechanics
-generally treats of molar laws and phenomena.
-
-[Transcriber's note: Molar, or mole, often refers to a quantity of a
-substance containing an Avagadro number (6.02E23) of molecules--a weight
-equal to the atomic weight of the molecule. For example, a mole of
-hydrogen (H2) is 2.015 grams; sodium chloride (NaCl) is 58.443 grams.]
-
-
-Molar Attraction.
-The attraction of mass for mass; gravitation. Synonyms--Mass
-Attraction--Gravitation.
-
-
-Molecular Affinity.
-The attraction of molecules for each other as seen in the formation of
-double salts, the combining of water of crystallization with a salt, and
-in other cases; a phase of affinity belonging to chemistry, although
-outside of true atomic attraction.
-
-
-Molecular Attraction.
-The attraction of molecules; physical affinity. Cohesion, the attraction
-of similar molecules for each other, and adhesion, that of dissimilar
-molecules, are examples. This should be distinguished from molecular
-affinity, a phase of chemical force.
-
-
-Molecular Bombardment.
-When a gas contained in a vessel is brought to a sufficient state of
-rarefaction the molecules cease to be subject to the laws of diffusion,
-but move back and forth in straight lines from side to side of the
-vessel. Their courses can be affected by electric discharge, which can
-cause them to all impinge upon one of the electrodes, the positive one,
-producing luminous effects. The path, if referred to the negative
-electrode, tends to be normal to its surface, so that the resultant path
-may be curved, as the stream of molecules go to the positive electrode.
-The fanciful name of molecular bombardment is given to the phenomenon,
-the luminous effect being attributed to the impinging of the molecules
-against the positive electrode as they are projected from the positive.
-The course of the molecules is comparable to the stream of carbon
-particles from the positive to the negative electrode in an arc lamp.
-(See Matter, Radiant.)
-
-
-Molecular Chain.
-The theoretical rows of molecules supposed to extend from anode to
-cathode in an electrolytic cell (see Cell, Electric--Groth�ss'
-Hypothesis) are called molecular chains.
-
-
-381   STANDARD ELECTRICAL DICTIONARY.
-
-
-Molecular Rigidity.
-The tendency of the molecules of a mass to retain their position in a
-mass in resistance to polarizing or depolarizing force, the first being
-the effect of a magnetic field. It is the theoretical cause of coercive
-force, q. v., and of residual magnetism. (See Magnetism, Residual.)
-
-
-Molecule.
-The smallest particle of matter that can exist alone. It is made up of
-atoms, but an atom can never exist alone, but only, with one or two
-possible exceptions, combined with one or more other atoms as a
-molecule. The molecules under present conditions are not in constant
-contact with each other, but are perpetually vibrating through paths, in
-solids probably in defined paths, in liquids and gases in perpetually
-new paths. The molecules collide with each other and rebound. This
-motion is the kinetic motion termed heat. At the absolute zero--minus
-273.72� C. (-460.7� F.) the molecules would be in contact and quiescent.
-In the gaseous state the molecules of most substances occupy the same
-volume; those of a few elements occupy one-half and of others twice the
-normal volume. The mean free path of the molecule of hydrogen is about
-1/20,000 mm. (1/508,000 inch) (Maxwell) or twice this length (Crookes),
-the collisions in hydrogen are about 17,750 millions per second; the
-diameter is about 8/10,000,000 mm. (8/254,000,000 inch) ; A particle of
-matter 1/4,000 mm. (1/102,000 inch) contains, it is supposed, about
-40,000 molecules. The results of different authorities vary so widely as
-to deprive the subject of much of its interest. A Sprengel pump, such as
-used for exhausting Geissler tubes, or incandescent lamp bulbs, may
-leave only one hundred-millionth (1/100,000,000,) of an atmosphere
-present, giving the molecules a capability of an average free path of
-vibration 33 feet long.
-
-
-Moment.
-When a force is applied so as to tend to produce rotation around a
-point, the product of the force by the shortest distance from the point
-of rotation to the extension of the line of the force. Such distance is
-the perpendicular to the extension of the line through the point of
-rotation.
-
-
-Mordey Effect.
-A phenomenon observed in dynamo armatures. At full loads the hysteresis
-decreases. The effect is thus expressed by S. P. Thompson. "When an
-armature core is rotated in a strong magnetic field, the magnetization
-of the iron is being continually carried through a cycle, but in a
-manner quite different from that in which it is carried when the
-magnetizing force is periodically reversed, as in the core of a
-transformer. Mordey has found the losses by hysteresis to be somewhat
-smaller in the former case than in the latter."
-
-
-Morse Receiver.
-The receiving instrument formerly universally used in the Morse system.
-It is now but little employed, the sounder having displaced it. Several
-types were invented.
-
-It consists of machinery which carries a reel of paper ribbon arranged
-to be fed over a roller by clockwork. A pencil, inking roller, or
-embossing stylus (for the latter the roller must have a groove) is
-carried by an arm with restricted range of vibration just over the paper
-and roller. The armature of an electro-magnet is attached to the arm.
-When the magnet is excited the armature is attracted and the marking
-device is pressed on the paper. If the clockwork is in operation the
-marker will make a line as long as the armature is attracted. When
-released no mark will be produced. In this way the dots and dashes of
-the Morse code are made on a ribbon of paper.
-
-As an inking arrangement a small roller is carried by the end of the
-vibrating arm. The embosser, or dry point stylus, was very extensively
-used. The clockwork was generally driven by descending weights.
-
-Synonym--Morse Recorder.
-
-
-382   STANDARD ELECTRICAL DICTIONARY.
-
-
-Mortar, Electric.
-An electric toy which may have various modifications. In the cut a
-wooden mortar with recess to receive a ball is shown. Two wires enter
-the base but do not touch. On placing the ball in position and passing a
-spark from a Leyden jar across the interval between the wires, the heat
-and disturbance are enough to project the ball. Gunpowder may be used,
-the discharge being passed through a wet string to prolong the spark.
-
-
-Fig. 244. ELECTRIC MORTAR.
-
-
-Motor, Compound or Compound Wound.
-A motor which has two windings on the field magnets, one in parallel
-with that on the armature, the other in series therewith, exactly as in
-a compound dynamo. (See Dynamo, Compound.)
-
-
-Motor, Differential.
-A differentially wound motor; with a compound wound field, whose series
-coil and shunt coil are wound in opposition to each other. It is
-virtually a compound wound dynamo. (See Dynamo, Compound Wound.)
-
-
-Motor, Electric.
-A machine or apparatus for converting electric energy into mechanical
-kinetic energy. The electric energy is generally of the dynamic or
-current type, that is to say, of comparatively low potential and
-continuous or virtually continuous flow. Some electrostatic motors have,
-however, been made, and an influence machine can often be operated as a
-static motor.
-
-Electric motors of the current type may be divided into two
-classes--direct current and alternating current motors.
-
-Direct current motors are generally based on the same lines of
-construction as dynamos. One of the great discoveries in modern
-electricity was that if a current is passed through a dynamo, the
-armature will rotate. This fact constitutes the principle of the
-reversibility of the dynamo.
-
-
-383   STANDARD ELECTRICAL DICTIONARY.
-
-
-Motors built on the dynamo model may be series wound, shunt wound, or
-compound wound, or of the magneto type, in the latter case having a
-fixed field irrespective of any current sent through them. The field may
-be produced by an electro-magnet separately excited and unaffected by
-the current sent through the motor.
-
-A current passed through a magneto or motor with separately excited
-field will turn it in the direction opposite to that required to produce
-the same current from it were it worked as a generator.
-
-A current passed through a series wound motor acts exactly as above.
-
-Both these facts follow from Lenz's law, q. v.
-
-A current passed through a shunt wound motor acts oppositely to the
-above. The direction of rotation is the same as that required to produce
-a current of the same direction. This is because the field being in
-parallel with the armature the motor current goes through the magnet
-coils in the direction the reverse of that of the current produced in
-the armature when it is used as a dynamo. Hence this also carries out
-Lenz's law.
-
-The compound wound motor acts one way or the other according as its
-shunt or series winding preponderates. The two may exactly balance each
-other, when there will be no motion at all. The series connections of a
-compound wound dynamo should therefore be reversed, making both series
-and shunt work in unison, if the dynamo is to be used as a motor.
-
-The general principles of the electric motor of the dynamo, or
-continuous rotation type, can only be outlined here. The current passing
-through the field magnets polarizes them and creates a field. Entering
-the armature by the brushes and commutators it polarizes its core, but
-in such a way that the north pole is away from the south pole of the
-field magnet, and the same for the south pole. Hence the armature
-rotates. As it does this the brushes connect with other commutator
-sections, and the poles of the armature are shifted back. This action
-continues indefinitely.
-
-Another class of motors is of the reciprocating type. These are now very
-little used. (See Motor, Reciprocating.)
-
-One valuable feature of continuous rotation electric motors is the fact
-that they absorb energy, to a great extent proportional in amount to the
-work they have to do. The rotation of the armature in the field of the
-motor involves the cutting of lines of force by its coils. This
-generates an electro-motive force contrary in direction to that
-producing the actuating current. The more rapid the rotation the greater
-is this counter-electro-motive force. The motor armature naturally
-revolves faster with diminished resistance to the motion of the
-armature. This increases the counter-electromotive force, so that less
-energy is absorbed. When the motor is called on to do work, the armature
-rotates more slowly, and the counter-electro-motive force diminishes, so
-that the machine absorbs more energy. (See Jacobi's Law.)
-
-
-384   STANDARD ELECTRICAL DICTIONARY.
-
-
-Motor Electro-motive Force.
-The counter-electro-motive force of a motor. (F. J. Sprague.)
-
-A motor rotates in virtue of the pull of the field magnet upon the poles
-of the core of its armature. In responding to this pull the windings of
-the armature cuts lines of force and hence generates a
-counter-electro-motive force, for which the above term was suggested.
-
-
-Motor-Generator.
-A combined motor and generator used to lower the potential difference in
-a portion of a circuit, e. g., that part within a building.
-
-A motor-generator is a dynamo whose armature carries two commutators,
-with two separate windings, one of fine wire of many turns, the other of
-coarse wire of few turns. If the potential of the system is to be
-lowered, the main current is passed through the fine winding. This
-causes the armature to turn motor-fashion, and a potential difference is
-generated by the rotation of the large coils in the field. This
-potential difference is comparatively low and by properly proportioning
-the windings may be lowered to as great a degree as required.
-
-The same apparatus may be inverted so as to raise potential difference.
-It acts for continuous current systems as the induction coil transformer
-does for alternating current systems.
-
-Synonym--Continuous Current Transformer.
-
-
-Motor, Multiphase.
-A motor driven by multiphase currents. It is arranged in general terms
-for distribution of the multi phase currents in coils symmetrically
-arranged around the circle of the field. These coils are wound on cores
-of soft iron. A rotating field is thus produced, and a permanent magnet
-or a polarized armature pivoted in such a field will rotate with the
-field, its poles following the poles of the rotatory field.
-
-The cut, Fig. 245, illustrates the principles of action of a four phase
-current motor, connected to a four phase current dynamo or generator.
-The generator is shown on the left hand of the cut and the motor on the
-right hand. In the generator the armature N S is supposed to be turned
-by power in the direction shown by the arrow. Each one of the pair of
-coils is wound in the reverse sense of the one opposite to it, and the
-two are connected in series with each other, and with a corresponding
-pair in the motor. The connection can be readily traced by the letters A
-A', a a' for one set of coils and B B' b b' for the other set.
-
-
-385   STANDARD ELECTRICAL DICTIONARY.
-
-
-For each rotation of the armature two currents, each in opposite
-direction, are produced in A A', and the same is the case for B B'.
-These currents which have an absolutely constant relation of phase, and
-which it will be seen alternate four times for each rotation of the
-armature, regulate the polarity of the field of the motor. The resultant
-of their action is to keep the poles of the field magnet of the motor
-constantly traveling around its circle. Hence the armature N S of the
-motor, seen on the right hand of the cut, tends to travel around also
-its north and south poles, following the south and north poles of the
-rotatory field respectively.
-
-
-Fig. 245. FOUR-PHASE CURRENT GENERATOR AND MOTOR.
-
-
-It is not essential that the armature should be a magnet or polarized.
-Any mass of soft iron will by induction be polarized and will be
-rotated, although not necessarily synchronously, with the rotatory
-field. Any mass of copper, such as a disc or cylinder, will have
-Foucault currents induced in it and will also rotate. The only
-components of such currents which are useful in driving the motor are
-those which are at right angles to the lines of force and to the
-direction of motion. A very good type of armature based on these
-considerations is a core of soft iron wound with insulated copper wire
-in one or more closed coils; and so wound as to develop the currents of
-proper direction.
-
-Such an armature is used in the Tesla alternating current motor. An
-efficiency of 85 per cent. has been attained with some of the Tesla
-motors.
-
-
-Motor, Prime.
-A machine used for producing mechanical motion against resistance. It
-may operate by converting heat or any other form of kinetic or potential
-energy into mechanical energy of the moving type. A steam-engine and a
-water-wheel are examples of prime motors.
-
-
-Motor, Reciprocating.
-The early type of motor depending upon reciprocating motion, such as the
-motion of a coil in a solenoid. These were based upon the lines of a
-steam engine, and have been abandoned except for special purposes where
-reciprocating motion is especially required, as in the case of rock
-drills.
-
-
-386   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 246. RICORDON'S RECIPROCATING MOTOR.
-
-
-In the cut, B is an electro-magnet; A is an armature; E a pole piece.
-The current enters by the springs, b b, and by commutation is supplied
-and cut off alternately, thus maintaining a reciprocating movement of
-the armature and rotation of the fly-wheel.
-
-Synonym--Pulsating Motor.
-
-
-Motor, Series.
-A motor whose winding on the armature is in series with the winding on
-the field. It is similar to a series dynamo. (See Dynamo, Series.)
-
-
-Motor, Shunt.
-A motor whose winding on the armature is in parallel with the winding on
-the field magnets. It is similar to a shunt wound dynamo. (See Dynamo,
-Shunt.)
-
-
-Fig. 247. MULTIPLE ARC CONNECTION.
-
-
-Multiple.
-A term expressing connection of electric apparatus such as battery
-couples, or lamps in parallel with each other. In the ordinary
-incandescent lamp circuits the lamps are connected in multiple.
-
-Synonym--Multiple Arc.
-
-
-387   STANDARD ELECTRICAL DICTIONARY.
-
-
-Multiple Arc Box.
-A resistance box arranged so that the coils may be plugged in multiple
-instead of in series. Such can be used as a rheostat, as the resistance
-can be very gradually changed by putting the coils one by one into
-parallel with each other. Thus by adding in parallel with a 10 ohm coil
-a 10,000 ohm coil the resistance is decreased to 9.999001 ohms, and thus
-the resistance can be very slowly changed without sudden stops or abrupt
-changes.
-
-[Transcriber's note: The correct value is 9.99001]
-
-
-Multiple Series.
-Arrangements of electric apparatus in a circuit in a number of series,
-which minor series are then arranged in parallel. The term may be used
-as a noun, as "arranged in multiple-series," or as an adjective, as "a
-multiple-series circuit."
-
-
-Fig. 248. MULTIPLE SERIES CONNECTION.
-
-
-Multiple Switch Board.
-A switch board on whose face connecting spring jacks or other devices
-are repeated for the same circuits, so that different operators have
-each the entire set of connections repeated on the section of the board
-immediately in front of and within their reach. This multiplication of
-the same set of connections, giving one complete set to each operator,
-gives the title "multiple" to the type of switch board in question. The
-typical multiple switch board used in telephone exchanges is the best
-example of this construction. The calling annunciators of the
-subscribers are distributed along the bottom of the board extending its
-full length. To each operator a given number is assigned, all within
-reach of the right or left hand. This gives five or six feet length of
-board to each, and an operator only responds to those subscribers within
-his range. But anyone of his subscribers may want to connect with any of
-the others in the entire central station. Accordingly in front of each
-operator spring jacks are arranged, one for each of the entire set of
-subscribers connected in that office. The operator connects as required
-any of the calling subscribers, who are comparatively few, to any one of
-the large number served by the central station. Thus the entire set of
-subscribers' spring jacks are multiplied over and over again so as to
-give one set to each operator.
-
-
-388   STANDARD ELECTRICAL DICTIONARY.
-
-
-Multiple Wire Method for Working Electro-magnets.
-A method for suppressing sparking in working electro-magnets
-intermittently. The magnet core is wound with a number (from four to
-twenty) of separate layers of fine wire. A separate wire is taken for
-each layer and all are wound in the same direction, from one end to the
-other of the space or bobbin without returning. The ends are then joined
-so as to bring all the wires in parallel. The effect of this is that as
-the coils vary in diameter the time constants of each is different from
-that of the others, the coefficient of self-induction being less, and
-the resistance being greater for the coils farthest from the central
-axis. Thus the extra currents run differently in the different coils,
-and only a comparatively small spark can be produced owing to the
-division of forces thus brought about.
-
-
-Fig. 249. DIAGRAM ILLUSTRATING MULTIPLE WIRE WORKING.
-
-
-Multiplex Telegraphy.
-Any system of telegraphy transmitting more than four messages
-simultaneously over a single wire. Properly it should apply to all
-transmitting more than one, but conventionally has the above restricted
-meaning, distinguishing it from duplex and quadruplex telegraphy.
-
-
-Multiplying Power of a Shunt.
-When a resistance is placed in parallel with a galvanometer on a circuit
-the following relation obtains. Let s and g equal the resistances of the
-shunt and galvanometer respectively, S and G the currents in amperes
-passing through them, V the potential difference between their common
-terminals, and A the whole current in amperes. Then we have
-  A = ( (s + g ) / s ) * G
-and ( (s + g ) / s ) is termed the multiplying power of the shunt, as it
-is the factor by which the current passing through the galvanometer must
-be multiplied by to produce the total current.
-
-
-Muscular Pile.
-A species of voltaic battery, often termed Matteueci's pile, made up of
-alternate pieces of muscle cut longitudinally and transversely
-respectively. The different pieces represent the elements of a battery,
-and their difference of potential is naturally possessed by the pieces.
-
-
-Myria.
-A prefix; one million times. Thus myriavolt means one million volts.
-
-[Transcriber's note: Contemporary usage is mega, as in megavolt.]
-
-
-389   STANDARD ELECTRICAL DICTIONARY.
-
-
-N.
-(a) Symbol for north pole or north-seeking pole of a magnet.
-
-(b) Symbol for the number of lines of force in a magnetic circuit.
-
-
-Nairne's Electrical Machine.
-The cylinder electrical machine, q.v.
-
-
-Napierian Logarithms.
-A series of logarithms the base of whose system is 2.72818. They are
-also called hyperbolic logarithms.
-
-
-Nascent State.
-An element just separating from a combination possesses at that time
-higher affinities than after separation, and can effect more powerful
-chemical changes.
-
-It is sometimes attributed to a differential time of existence in the
-atomic modification, before the freed atoms have united to form
-molecules.
-
-
-Natural Currents.
-A term for earth currents. (See Current, Earth.)
-
-
-Needle.
-(a) A term applied to a bar magnet poised horizontally upon a vertical
-point, or suspended in a horizontal position by a filament. Thus the
-magnet in a mariner's compass, which may be a substantial bar magnet, is
-called a magnetic needle.
-
-(b) An indicator in general shape like the hand of a clock. (Sec
-Annunciator, Needle- Telegraph, Needle.)
-
-
-Needle of Oscillation.
-The magnetic needle poised horizontally, and used for measuring the
-intensity of the earth's magnetic field, or of an artificial magnetic
-field, by the method of oscillations. The intensities of the field is
-inversely as the square of the number of oscillations performed in a
-given time.
-
-
-Needle, Telegraphic.
-The index in needle telegraphy (see Telegraph, Needle), whose motions
-indicate the characters it is desired to transmit.
-
-
-Negative Charge.
-One of the two kinds of electric charges. The other is the positive.
-
-By the double fluid hypothesis this is assumed to be a charge of a
-particular kind of electricity--negative electricity.
-
-By the single fluid hypothesis it is supposed to be caused by the
-absence of part of the normal electricity of a surface. The reverse is
-held by some theorists.
-
-The subject is so purely theoretical that neither of the two hypotheses
-is accepted as final.
-
-[Transcriber's note: Current is a wire is the motion of negative
-electrons. Current in a electrolyte is the motion of positive ions and
-negative ions. Current in a plasma is the motion of electrons and
-positive ions.]
-
-
-390   STANDARD ELECTRICAL DICTIONARY.
-
-
-Negative Electricity.
-The kind of electricity with which a piece of amber is charged by
-friction with flannel; resinous electricity. (See Electrostatic Series.)
-
-
-In a galvanic battery the surface of the zinc plate is charged with
-negative electricity.
-
-According to the single fluid theory negative electrification consists
-in a deficiency of electricity.
-
-[Transcriber's note: Negative electrification is an excess of
-electrons.]
-
-
-Negative Element.
-In a voltaic cell the plate not dissolved by the solution; the one which
-is positively charged; the copper, platinum, or carbon plate in the
-usual type of battery.
-
-The current is assumed to flow from negative element to positive element
-(the zinc plate) through the wire or other external conductor.
-
-
-Nerve Currents.
-Currents of electricity obtained from nerves. They are much more feeble
-than those obtained from muscle, but are produced in the same general
-ways.
-
-
-Network.
-Conductors in parallel and crossing each other, with connections at the
-junctions.
-
-The term is sometimes so loosely applied as to include parallel
-conductors.
-
-
-Neutral Line of Commutator.
-The diameter of a commutator which connects its Neutral Points, q. v.;
-sometimes termed the diameter of commutation; the diameter approximately
-at right angles with the lines of force. The commutator brushes are
-applied at the extremities of this diameter.
-
-
-Neutral Point of a Commutator.
-The points of a commutator at which no lines of force are cut; the
-points at the extremities of a diameter which, except for the lag, would
-be at right angles to the lines of force; the points at which the
-brushes touch the commutator.
-
-
-Neutral Point, Thermo-electric.
-A temperature marking a point of no thermo-electric difference of
-potential. If the junctions of a thermo-electric couple are at
-temperatures, one a little over and the other an equal amount under the
-neutral point, no current will be developed. At the neutral point the
-thermo-electric polarities are reversed. Differences of temperature
-above it give currents of reverse direction to those given by
-corresponding differences below it. For an iron-copper couple the
-neutral point is 274.5� C. (526� F.)
-
-Synonym--Neutral Temperature.
-
-
-Neutral Relay Armature.
-An unpolarizable armature for use with a relay; an armature of soft iron
-or iron wire; as distinguished from a polarized armature.
-
-
-391   STANDARD ELECTRICAL DICTIONARY.
-
-
-Neutral Wire.
-The central wire in the three wire system, q. v., of electric
-distribution; the wire connected to a point between the two dynamos, or
-otherwise to the central point of the current generator.
-
-
-Fig. 250. DIAGRAM OF THREE WIRE SYSTEM SHOWING NEUTRAL WIRE.
-
-
-Neutral Wire Ampere Meter.
-An ampere meter connected in the circuit of the neutral wire to
-determine the current passing through it. Such determination is for the
-purpose of ascertaining how much more work is being done by one of the
-lateral leads than by the other.
-
-Synonym--Balance Ampere Meter.
-
-
-N. H. P.
-Symbol or contraction for "nominal horse power." This is a basis for
-rating the size of an engine.
-
-
-Nickel.
-A metal; one of the elements; atomic weight, 58.8 ; equivalent, 29.4;
-valency, 2; specific gravity, 8.8. It is a conductor of electricity.
-  Relative resistance, annealed (Silver = 1),   8.285
-  Specific Resistance,                         12.47   microhms.
-  Resistance of a wire
-  (a) 1 foot long, weighing 1 grain,      15.206   ohms.
-  (b) 1 foot long, 1/1000 inch thick,     74.963    "
-  (c) 1 meter long, weighing 1 gram,       1.060    "
-  (d) 1 meter long, 1 millimeter thick,     .1587   "
-  Resistance of a 1-inch cube,             4.907   microhms.
-  Electro-chemical equivalent, (Hydrogen = .0105)   .3087   mgs.
-
-It is strongly paramagnetic, but loses this quality at 350� C. (662� F.)
-
-It is important as a constituent of German silver, an alloy much used
-for resistance coils.
-
-
-
-Nickel, Bath.
-A bath for the electro-deposition of nickel. A great many
-formulae have been given. Metallic nickel is dissolved in 1 vol.
-sulphuric acid mixed with 2 vols. water. Neutralize with ammonia, and
-add of ammonium sulphate one-half the weight of metallic nickel
-originally used; 135 parts of nickel will be enough for a bath of 10,000
-parts.
-
-
-392   STANDARD ELECTRICAL DICTIONARY.
-
-
-Other formulae are as follows:
-  Double nickel-ammonium sulphate,        4   parts.
-  Ammonium carbonate,                     3   "
-  Water                                 100   "
-  Nickel sulphate, nitrate or chloride,   1   "
-  Sodium bisulphate,                      1   "
-  Water,                                 20   "
-
-Nickel anodes are used in the bath to maintain the strength. Too much
-care cannot be exercised in the absolute cleanliness of the articles to
-be plated. A too alkaline bath gives a disagreeable yellow color to the
-deposit; too acid a bath gives badly adhering deposits.
-
-
-Night Bell.
-An alarm bell in a telegraph office, which bell is connected at night to
-give a loud signal to attract the operator's attention. It is used in
-telephone exchanges and is connected so as to ring as long as a
-subscriber remains unanswered after calling.
-
-
-Nobili's Rings.
-When a dilute solution of copper acetate is placed on a bright silver
-plate and a strip of zinc is touched to the silver beneath the copper, a
-series of rings of copper are formed by electrolysis around the zinc.
-These are Nobili's rings.
-
-If for the copper acetate a solution of lead oxide in potassium hydrate
-solution is substituted, and if the polished plate which may be German
-silver is connected to the positive electrode of a battery, and a
-platinum wire connected to the negative pole is immersed in the liquid,
-it determines the formation of beautiful iridescent rings of lead
-binoxide. The platinum wire is sometimes sealed in glass so that only
-its point projects.
-
-The colors are due to interference of light, the layers of lead oxide
-being extremely thin.
-
-The lead binoxide is formed by secondary reaction. Metallic lead is
-first deposited on the negative pole. The oxygen which goes to the
-positive pole formed by the polished plate produces lead binoxide which
-is deposited there in rings. The reaction is comparable to that of a
-storage battery.
-
-Synonyms--Metallochromes--Electric Rings.
-
-
-Nodular Deposit.
-A deposit obtained in electroplating, characterized by irregular
-thickness; due to too low density of current.
-
-
-Non-conductor.
-A material that does not conduct electricity except with great
-difficulty; a substance of very high resistance.
-
-Synonym--Insulator--Dielectric.
-
-
-North Pole.
-(a) The north-seeking pole of a magnet; the pole of a magnet which tends
-to point to the north, and whence lines of force are assumed to issue on
-their course to the other pole of the magnet.
-
-(b) The North Pole of the earth. Treating the earth as a magnet, and
-accepting the above nomenclature the north pole should be termed the
-south pole. (See Austral Pole--Boreal Pole.)
-
-
-393   STANDARD ELECTRICAL DICTIONARY.
-
-
-North-seeking Pole.
-The pole of a magnet which tends to point to the north; the north pole
-of a magnet.
-
-
-Null Method.
-Any method of obtaining measurements or comparisons, in which the
-measurement is correct when the deflection of the galvanometer or other
-indicator is zero, nought or null. The Wheatstone Bridge (see Bridge,
-Wheatstone) is an example of a null method.
-
-Two obvious advantages attach to null methods in electric galvanometer
-work. One is that an uncalibrated galvanometer can be employed. The
-other is that a galvanometer of any high degree of sensitiveness can be
-employed, there being no restriction as to its fineness of winding or
-highness of resistance.
-
-
-"Upper case Omega Graphic".
-(Greek capital" Omega") symbol for megohm.
-[Transcriber's note: Now used for ohms.]
-
-
-"Lower case Omega Graphic".
-(Greek omega) symbol for ohm.
-[Transcriber's note: Now used for angular velocity, 2*PI*frequency.]
-
-
-Occlusion.
-An absorption of gases by metals. Palladium will, if used as the
-hydrogen evolving electrode in decomposing water, absorb 980 times its
-volume of hydrogen, which is said to be occluded. The metal may also be
-heated in hydrogen and allowed to cool therein, when occlusion occurs.
-Platinum will occlude 4 times its volume of hydrogen; iron, 4.15 times
-its volume of carbon-monoxide; silver, 7 times its volume of oxygen.
-Metals with occluded gases may serve as elements in a galvanic couple.
-(See Gas Battery.) A metal expands in occluding a gas.
-
-In the storage battery it is believed that occlusion plays a part,
-hydrogen and oxygen being respectively absorbed by the two sets of
-plates, and acting as they do in Groves' gas battery.
-
-
-Oerstedt.
-Name proposed for the unit of current strength, but not adopted. The
-ampere is the accepted name.
-
-
-394   STANDARD ELECTRICAL DICTIONARY.
-
-
-Oerstedt's Discovery.
-Oerstedt discovered in 1820 that a magnetic needle tended to place
-itself at right angles to a current of electricity. This fundamental
-experiment is the basis of the galvanometer.
-
-
-Fig. 251. OERSTEDT'S DISCOVERY.
-
-
-Ohm.
-The practical unit of resistance; 1E9 C. G. S. electro-magnetic units.
-The legal ohm is the resistance of a mercury column 1 square millimeter
-in cross-sectional area and 106 centimeters in length. There has been
-considerable confusion, owing to inaccuracy in early determinations, in
-the valuation of the ohm. In this work the legal ohm is used. The
-different ohms will be found defined in their place. Resistance units of
-various names may also be consulted.
-
-The following table gives the relative values of the different ohms.
-
-                 Length of
-                 Mercury                      Board of
-                 Column in    True    B. A.    Trade     Legal
-                 Centimetre.  Ohm.    Ohm.     Ohm.      Ohm.
-
-True Ohm,           106.24    1.      1.0128    .9994    1.0022
-B. A. Ohm,          104.9     .9874   1.        .9868     .9889
-Board of Trade Ohm  106.3    1.00050  1.0133   1.        1.0028
-Legal Ohm,          106.0     .9977   1.0112    .9971    1.
-
-
-Ohmage.
-The Resistance of a circuit expressed in ohms.
-
-
-Ohm, B. A.
-The British Association unit of resistance; the resistance of a column
-of mercury 1 square millimeter in cross sectional area and 104.9
-centimeters long; the B. A. Unit of Resistance.
-
-
-Ohm, Board of Trade.
-The approximate ohm as recommended by the British Board of Trade on the
-advice of a committee (Sir W. Thomson, Dr. J. Hopkinson, Lord Rayleigh
-and others). It is the resistance of a mercury column one square
-millimeter in section, and 106.3 centimeters long at 0� C. (32� F.)
-
-Synonym--New Ohm.
-
-
-395   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ohmic Resistance.
-True resistance as distinguished from spurious resistance, or
-counter-electro-motive force.
-
-
-Ohm, Legal.
-The practical unit of resistance. The resistance of a column of mercury
-one square millimeter in cross-sectional area and 106 centimetres long
-at 0� C. (32� F.) The ohm used previously to 1884 is the B. A. Unit of
-Resistance, q. v.
-
-One legal ohm = 1.0112 B. A. Units, and I B. A. Unit = 0.9889 legal ohm.
-
-The resistance of a copper wire 1 foot long and 1/1000 inch in diameter
-is about 10 ohms. The resistance of 1 mile of iron wire 1/3 inch in
-diameter is about 10 ohms.
-
-Synonym--Congress Ohm.
-
-
-396   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 252. THEORY OF OHMMETER.
-
-
-Fig. 253. OHMMETER.
-
-
-Ohmmeter.
-An instrument for measuring directly the resistance of a conductor or of
-any part of a circuit through which a strong current is passing.  It is
-the invention of Prof. W. E. Ayrton.
-
-It contains two fixed coils at right angles to each other acting on the
-same needle of soft iron. One coil is of thick wire and is placed in
-series with the resistance to be measured. The other is of very thin
-wire and is placed in parallel with the same resistance. One wire acts
-by the total current, the other by the potential difference between the
-ends of the resistance. The action on the soft iron needle is due to the
-ratio of potential difference to total currents, or to the resistance
-itself. By properly designing and proportioning the coils the angular
-deflections of the needle are made proportional to the resistance.
-
-In use the thick wire may be kept permanently in circuit. On connecting
-the binding posts of the thin wire coil to any two parts of the circuit
-its resistance is at once given by the deflection of the needle.
-
-When no current is passing the needle rests in any position. A current
-in the thick coil brings it to zero. A current simultaneously passing
-through the thin high resistance coil brings about the deflection.
-
-The instrument is a commercial rather than a scientific one.
-
-
-Ohm's Law.
-The fundamental law expressing the relations between current,
-electro-motive force and resistance in an active electric circuit. It
-may be expressed thus:
-
-(a) The current strength is equal to the electro-motive force divided by
-the resistance.
-
-(b) The electro-motive force is equal to the current strength multiplied
-by the resistance.
-
-(c) The resistance is equal to the electro-motive force divided by the
-current strength. All these are different forms of the same statement.
-Algebraically the law is usually expressed thus, (a) C = E/R. It may
-also be expressed thus: (b) E = C*R and (c) R= E/C, in which R denotes
-resistance, C denotes current strength, and E denotes electro-motive
-force.
-
-
-Ohm, True.
-The true ohm is the resistance of a column of mercury 1 square
-millimeter in cross-sectional area, and 106.24 centimeters long. (See
-Ohm.)
-
-Synonym-Rayleigh Ohm.
-
-
-Oil Insulation.
-Oil insulation has received several applications in electrical work. It
-has been proposed for use in underground conduits. These it was proposed
-to fill with oil after the insertion of the conductors, the latter
-properly wrapped with cotton or other covering. For induction coils it
-has been very successfully used. Its principal utility depends on the
-fact that it is liquid, so that if pierced by a spark it at once closes
-again. A solid insulator if pierced is permanently injured. It is also
-used in telegraph insulators (see Insulator, Liquid) to prevent surface
-leakage.
-
-
-397   STANDARD ELECTRICAL DICTIONARY.
-
-
-Olefiant Gas.
-A compound gas; C2H4; composed of carbon, 24; hydrogen, 4; molecular
-weight, 28; specific gravity, .981.
-
-It is a dielectric of about the resistance of air. Its specific
-inductive capacity at atmospheric pressure is 1.000722 (Boltzman.)
-
-Synonym--Ethene; heavy carburetted hydrogen.
-
-[Transcriber's note: Also called ethylene. A primary use is polyethylene
-plastic.]
-
-
-Open. adj.
-An electric circuit is said to be open when it is cut or broken so that
-no current can pass through it. The term may be recollected by thinking
-of a switch; when open no current can pass through it. The same
-adjective is applied to magnetic circuits, an air gap implying an open
-circuit.
-
-
-Open Circuit Oscillation.
-An oscillation of current in open circuit so that a spark discharge
-accompanies it. It is produced by electric resonance in a simple circle
-or loop of wire with ends placed near together but not touching, if the
-circuit is of such size that its period of oscillation corresponds with
-that of the inducing discharge. (See Resonance, Electric.) Its period
-depends entirely on the self-induction of the circuit.
-
-
-Ordinate.
-In a system of plane co-ordinates (see Co-ordinates), the distance of
-any point from the axis of abscissas measured parallel to the axis of
-ordinates.
-
-
-Ordinates, Axis of.
-The vertical axis in a system of co-ordinates, q. v.
-
-Synonym--Axis of Y.
-
-
-Organ, Electric.
-An organ in which the air blast is admitted or excluded from the
-different pipes by electric mechanism.
-
-The outlines of the system are a series of contacts worked by the keys
-and stops, which cause, when operated by the organist, a current to pass
-through electro-magnets, opening the valves of the different pipes. Thus
-the manual may be at any distance from the organ, and a number of organs
-may be worked upon the same manual. As many as five in a single
-cathedral are thus connected to a manual in the chancel.
-
-
-Orientation of a Magnetic Needle.
-The acquirement by a magnetic needle of its position of rest, with its
-magnetic axis in the magnetic meridian.
-
-
-Origin of Co-ordinates.
-In a system of linear co-ordinates the point of intersection of the
-axes; the point whose co-ordinates are both zero.
-
-
-398   STANDARD ELECTRICAL DICTIONARY.
-
-
-Oscillating Needle.
-A small light bar magnet suspended by a filament and employed in
-determining the intensity of a magnetic field by the oscillations it
-completes in a given time after a given disturbance.
-
-
-Oscillations, Electric.
-In static electricity the sudden and very rapid alternations in the
-discharge of a static condenser. This discharge of the disruptive order
-seems a single one, but is really composed of a number of discharges
-alternating in direction and producing electro-magnetic ether waves,
-probably identical with light waves except that they are longer and far
-less rapid.
-
-
-Oscillatory Electro-motive Force.
-Electro-motive force rapidly changing in sense or in direction, so that
-it presents an oscillatory character. The alternating current and the
-telephone current as used in practice are actuated by this type of
-electro-motive force.
-
-
-Osmose, Electric.
-When two liquids are separated by a porous diaphragm, and a strong
-current of electricity is passed through from the liquid on one side,
-through the diaphragm, to the liquid on the other side, the liquid on
-the side towards which the current is passing rises in level. The
-process is termed electric osmose. When a liquid is forced through a
-diaphragm a current is produced; in other words electric osmose is
-reversible. The current thus produced is termed a diaphragm current.
-
-
-Oscillation, Electric.
-The phase of discharge of a static condenser in one direction. It is
-usually followed by a discharge in the opposite direction constituting a
-second oscillation, and so on, so that a great number of exceedingly
-short oscillations are comprised. Thus, in the discharge of the Leyden
-jar a large number of oscillations of current back and forth are
-produced, the current alternating like the swings of a pendulum.
-
-These oscillations are supposed to affect the ether, producing waves in
-it identical with light waves, except that we have not been able yet to
-produce them short enough to affect the visual organs. The waves thus
-produced can be reflected or refracted; some substances are transparent
-for them and others opaque. There is a possibility that man may yet
-succeed in producing electric oscillations of sufficient frequency to
-bring about the direct production of light.
-
-
-Oscillatory Displacement.
-Hypothetical displacement currents of rapidly alternating direction
-produced in the oscillatory discharge of a Leyden jar or static
-condenser.
-
-
-Oscillatory Induction.
-Induction produced by sympathetic action of an oscillatory discharge or
-by electric resonance. (See Oscillations, Electric--Resonance,
-Electric--Resonator, Electric.)
-
-
-399   STANDARD ELECTRICAL DICTIONARY.
-
-
-Outlet.
-The part of an electrolier or electric light fixture out of which the
-wires are led for attachment of an incandescent light socket.
-
-
-Output.
-The rate of energy delivered or of work done by a machine. In the case
-of a current generator it is the volt-coulombs per given second, or
-better the volt-amperes delivered at its outer circuit terminals.
-
-
-Output, Magnetic.
-The analogue in a magnetic circuit of the output of an electric circuit.
-It is the product of the magnetizing force by the induced magnetism.
-
-
-Output, Unit of.
-As a unit of output of a dynamo Prof. Sylvanus P. Thompson has proposed
-1,000 watts, or one kilowatt. This unit is now frequently used. To
-completely define the dynamo, however, the amperage or the voltage must
-also be given, as a 10 kilowatt--110 volt machine, or a 10 kilowatt--99
-ampere machine.
-
-[Transcriber's note: 10 kilowatt at 110 volts is 91 amperes.]
-
-
-Over-Compounding.
-A proportioning of the series and shunt windings of a compound dynamo,
-so that the voltage of the terminals rises with the load or output
-enough to allow for the drop in mains, thus maintaining the potential
-for full load at distant points in a district. It is carried out by an
-increase of ampere-turns in the series winding.
-
-
-Overload.
-In an electric motor a mechanical load put upon it so great as to
-prevent economical working. One effect of such a load is to make the
-armature run so slowly as to unduly reduce the counter-electro-motive
-force and hence to permit so much current to pass through the coils as
-to heat them, perhaps injuriously. In this case the production of heat
-implies the waste of energy.
-
-
-Overtype Dynamo or Motor.
-A dynamo or motor whose armature is placed above or in the upper part of
-the field magnets, the yoke piece of the magnets being in or resting
-upon the base of the machine.
-
-
-Ozone.
-An allotropic form of oxygen. It possesses much more energetic chemical
-properties than oxygen. It is supposed to contain three atoms of oxygen
-in its molecule, represented thus:
-    O
-   / \
-  O---O
-
-It is produced by electric discharges and it is its peculiar odor which
-is noticed about an electric machine, and sometimes in a thunderstorm
-near the path of a lightning flash.
-
-In the electrolysis of water some ozone may be produced, thus
-diminishing the volume of the oxygen or of the mixed gases given off.
-This is a source of inaccuracy in a gas voltameter.
-
-
-400   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pacinotti's Inductor.
-The Pacinotti or Gramme Ring. (See Pacinotti's Ring.)
-
-
-Pacinotti's Ring.
-A ring of iron wire wound with coils of insulated wire at right angles
-to its circular axis, and used as the armature of a dynamo or motor. A
-number of connections are taken from the coils to a central commutator.
-
-
-Fig. 254. PACINOTTI'S MACHINE, WITH RING ARMATURE.
-
-
-If such a ring with its coils is rotated in a field, current can be
-taken from points of the commutator on a line at right angles to the
-lines of force entering the ring.
-
-The ring was discovered in 1862 by Pacinotti, and later was
-independently discovered by Gramme. It is often known as the Gramme
-ring.
-
-
-Pacinotti Teeth.
-Projections on a cylindrical or drum armature, between which in the
-grooves formed thereby, the wire is wound. The teeth being of iron tend
-to diminish the reluctance or magnetic resistance of the interpolar
-space, or interval between the poles of the field magnet.
-
-Synonym--Pacinotti Projections.
-
-
-Paillard Alloys.
-Non-magnetic palladium alloys, invented by Paillard, of
-Switzerland, used in anti-magnetic watches. The following are given as
-the compositions of several such alloys:
-
-               I.                II.
-Palladium,  60 to 75   parts   50 to 75  parts
-Copper,     I5 to 25   "       20 to 30   "
-Iron.        1 to 5    "       5 to 20   "
-
-
-401   STANDARD ELECTRICAL DICTIONARY.
-
-
-The following are more complex:
-                 I.                II.
-Palladium,   65 to 75   parts   45 to 50   parts
-Copper,      15 to 25     "     15 to 25   "
-Nickel,       1 to 5      "      2 to 5    "
-Silver,       3 to 10     "     20 to 25   "
-Gold,         1 to 2-1/2  "      2 to 5    "
-Platinum,   1/2 to 2      "      2 to 5    "
-Steel,        1 to 5      "      2 to 5    "
-
-These alloys are used for balance springs, as well as for the balance
-wheels and escapement parts of watches. The elasticity of recently
-produced springs has been found to be very satisfactory.
-
-
-Page Effect.
-The sounds produced by magnetizing and demagnetizing a bar of iron or
-steel; the magnetic tick. The sounds are strong enough to produce a
-telephonic effect. (See Magnetic Tick.)
-
-
-Palladium.
-A metal of the platinum series. It has the highest power of occlusion,
-q.v., of all metals. It is the characteristic ingredient of non-magnetic
-watch alloys.
-
-Palladium used as an electrode in the electrolysis of water will occlude
-936 volumes of hydrogen, and the hydrogen-palladium alloy will exceed in
-size the original electrode.
-
-
-Fig. 255. LUMINOUS PANE.
-
-
-Pane, Luminous.
-A pane of glass, one side of which has pasted to it a long zigzag strip
-of tinfoil. A design is made by cutting through the strip. On
-discharging a Leyden jar or an electric machine through the strip sparks
-appear where the tinfoil is severed, thus producing the design in a
-luminous effect. Many variations can be employed in their construction.
-
-
-402   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pantelegraphy.
-A system of telegraphy for transmitting designs, maps, drawing, and the
-like by telegraphy. (See Telegraphy, Facsimile.)
-
-
-Paper Filaments.
-Filaments of carbon for incandescent lamps made from paper.
-
-This is one of the earliest materials practically used. The paper is cut
-out of proper shape, and is carbonized in a close vessel, while embedded
-in powdered charcoal or some other form of carbon to absolutely cut off
-access of air. It is then placed in the lamp chamber and flashed or
-subjected to the regular treatment.
-
-
-Parabola.
-A curve; one of the conic sections. It is approximately represented by a
-small arc of a circle, but if extended becomes rapidly deeper than a
-half circle.
-
-If, from a point within called the focus, lines are drawn to the curve
-and then other lines are drawn from these points parallel to the axis,
-the angles of incidence will he equal to the angles of reflection as
-referred to tangents at the points where the lines touch the curve.
-
-[Transcriber's note; The general equation of a parabola is
-    A*x^2 + B*x*y + C*y^2 + D*x + E*y + F = 0
-such that B^2 = 4*A*C, all of the coefficients are real, and A and C are
-not zero. A parabola positioned at the origin and symmetrical on the y
-axis is simplified to y = a*x^2 ]
-
-
-Parabolic Reflector.
-A reflector for a light, a paraboloid or surface of revolution whose
-section is a parabola. A light placed at its focus has its rays
-reflected parallel to each other.
-
-Examples of parabolic reflectors are seen in electric search lights and
-in locomotive head-lights. They are employed in electric search lights.
-The arc light must be of such construction as to maintain its ignited
-points always at the same point, the focus of the paraboloid.
-
-
-Paraffine. v.
-To coat or saturate with paraffine wax. Paper may be paraffined by
-dipping in the wax, or by being sprinkled with fragments of wax,
-subsequently melted in with a hot iron or otherwise. The tops of battery
-carbons are often paraffined to prevent the acid from rising in the
-pores by capillary attraction and rusting the connections.
-
-
-403   STANDARD ELECTRICAL DICTIONARY.
-
-
-Paraffine Wax.
-A hydro-carbon composed principally of mixtures of the higher members of
-the paraffine series C n H2 n + 2. It is made from cannel coal, coal
-tar, or petroleum by distillation. It is an insulator. Its resistance at
-46� C. (114.8� F.) per centimeter cube is 3.4E16 ohms, or about the
-highest resistance known.
-
-Its specific inductive capacity (for milky wax) is 2.47 (Schiller). For
-clear wax it is given as follows by different authorities:
-  1.92  Ayrton.
-  1.96  W�llner.
-  1.977 Gibson & Barclay.
-  2.32  Baltzmann.
-
-It is extensively used in condensers and other electric apparatus as a
-dielectric and insulator.
-
-
-Paragr�les.
-Protectors against hail; lightning rods used to guard fields against
-hail; of little or no real utility.
-
-
-Parallax.
-The apparent change in position of an object when looked at from two
-points of view. By looking at an object a few feet distant first with
-one eye and then with the other, the shifting in apparent position is
-seen.
-
-In reading the position of an indicator or needle over a scale parallax
-introduces an error unless the eye is held vertically over the needle.
-By making the dial of looking- glass and holding the eye so that the
-reflection of its pupil is bisected by the needle this verticality is
-ensured.
-
-
-Parallel.
-(a) In the nomenclature of electric circuits two or more conductors
-leading from one point to another, are said to be in parallel.
-
-(b) When two or more conductors connect two main leads of comparatively
-large size and low resistance they are said to be in parallel or in
-multiple arc. This order is easiest pictured as the rungs of a ladder in
-parallel connecting its two sides representing the main leads.
-
-It may be used as a noun as "arranged in parallel," or as an adjective
-as "a parallel circuit," the opposite of series, q. v.
-
-
-Paramagnetic. adj.
-Possessing paramagnetic properties; tending to occupy a position with
-the longer axis parallel to the lines of force of a magnetic field;
-having magnetism; attracted by a magnet.
-
-"If a homogeneous isotropic substance is placed in a magnetic field it
-becomes magnetized at every point in the direction of the magnetic
-intensity at that point, and with an intensity of magnetization
-proportional to the magnetic intensity. When the positive direction of
-the induced magnetization is the same as that of the magnetic intensity
-the substance is called Magnetic or Paramagnetic; when it is opposite,
-the substance is called Diamagnetic." (Emtage.)
-
-A paramagnetic substance has high permeability or multiplying power for
-lines of force, hence in a magnetic field a bar of iron, etc., is in
-unstable equilibrium unless its longer axis is parallel with the lines
-of force in order to reduce as much as possible the reluctance of the
-circuit.
-
-
-404   STANDARD ELECTRICAL DICTIONARY.
-
-
-Iron is the most paramagnetic of all substances. Other paramagnetic
-metals are: Nickel, cobalt, manganese, platinum, cerium, osmium,
-palladium. Diamagnetic metals are bismuth, antimony, zinc, tin, mercury,
-lead, silver, copper, gold, arsenic. Bismuth is the most diamagnetic of
-all metals.
-
-Of gases oxygen is most paramagnetic. Becquerel calculated that a cubic
-yard of oxygen condensed would act on a magnetic needle as powerfully as
-5.5 grains of metallic iron. Liquefied oxygen will adhere to the poles
-of a magnet.
-
-Changes of temperature and of other conditions may affect a body's
-magnetism. Thus hot oxygen is diamagnetic, and a substance paramagnetic
-in a vacuum may be diamagnetic in air.
-
-Of liquids, solutions of iron or cobalt are paramagnetic; water, blood,
-milk, alcohol, ether, oil of turpentine and most saline solutions are
-diamagnetic.
-
-
-Paramagnetism.
-(a) The science or study of paramagnetic substances and phenomena.
-
-(b) The magnetic property of a paramagnetic substance; that of being
-attracted by a magnet, and of arranging itself with its longer axis
-parallel with the lines of force of a magnetic field.
-
-
-Parchmentizing.
-If cellulose is treated with a mixture of two parts of sulphuric acid
-and one part of water perfectly cold, it becomes like parchment. It
-should at once be washed with water, and then with ammonia and water.
-The Swan incandescent light fibres are made of parchmentized cotton
-thread, which is afterward carbonized.
-
-
-Partial Earth.
-A fault in a conductor caused by imperfect connection with the earth,
-where insulation from the earth is desired.
-
-
-Passive State.
-A state of a substance in virtue of which it is unattacked by a solvent
-which ordinarily would dissolve or attack it. Iron in strong nitric acid
-is unattacked or assumes the passive state. This particular case is
-supposed to be due to a coating of magnetic oxide, so that there would
-be properly speaking no question of a passive state, but only one of
-superficial protection.
-
-The existence of a true passive state of any substance is very doubtful.
-
-
-P. D.
-Abbreviation for potential difference or difference of potential, or for
-electro-motive force.
-
-
-405   STANDARD ELECTRICAL DICTIONARY.
-
-
-Peltier Effect.
-The thermal effect produced by the passage of a current through the
-junction of two unlike conductors. Such junction is generally the seat
-of thermo-electric effects, and a current is generally produced by
-heating such a junction. If an independent current is passed in the same
-direction as that of the thermoelectric current, it cools the junction,
-and warms it if passed in the other direction. In general terms,
-referring to thermo-electric couples, if passed through them it tends to
-cool the hot and heat the cool junction. The phenomenon does not occur
-in zinc-copper junctions.
-
-
-Peltier's Cross.
-A bar of bismuth and a bar of antimony soldered centre to centre at
-right angles, being notched or halved there to receive or to set into
-each other. It is used to demonstrate the Peltier effect, q. v. To one
-pair of ends are connected the terminals of a battery circuit; to the
-other pair are connected the terminals of a galvanometer.
-
-The galvanometer by its deflections in one and then in the other
-direction indicates that the junction is heated when the current passes
-from antimony to bismuth and vice versa. It thus illustrates the heating
-and cooling of a thermo-electric junction by a current of electricity.
-The current from the battery by the Peltier effect either heats or cools
-the junction, as the case may be. This heating or cooling them produces
-a thermo-electric current in the galvanometer circuit. The battery has
-no direct influence on the galvanometer.
-
-
-Pendant Cord.
-A double conductor or pair of conductors, insulated from each other and
-covered with a worsted, silk, or cotton covering and used to suspend
-incandescent lamps and at the same time to conduct the current to them.
-It is also used for other similar service, such as acting as conductors
-for small motors. Often each conductor is composed of a number of thin
-wires laid together. This gives flexibility to the cord.
-
-Synonym--Flexible Cord.
-
-
-Pendulum, Electric.
-(a) A pendulum operated by the intermittent action of an electro-magnet,
-whose circuit is opened and closed by the pendulum itself. A point at
-the lower end of the pendulum swinging through a globule of mercury may
-close and open the circuit. Various other methods of accomplishing the
-same end are employed ..
-
-(b) A pith ball suspended by a thread from an insulating stand. It is
-used to show the attraction exercised by a piece of sealing wax or other
-substance excited by rubbing.
-
-
-406   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pen, Electric.
-A stylus for producing a series of perforations in paper, so that the
-paper may act as a stencil for the reproduction of a great number of
-copies of the original matter. Various kinds of electric pens have been
-invented. One kind, invented by Edison, consists of a handle carrying an
-electric motor actuating a needle, which is driven in and out of the
-other end of the handle with high rapidity. It is used by being held
-vertically on the paper with the needle end downward, and is moved so as
-to describe perforated letters or designs. The paper is then used as a
-stencil with an ink roller to reproduce the writing or design ad
-libitum. A simpler kind dispenses with the motor and depends on the
-perforations produced by the electric spark. As shown in the cut the
-stylus is one terminal of an induction coil circuit. The support on
-which the paper rests is the other terminal and must be a conductor. In
-use the induction coil is started, and the stylus is moved over the
-paper; a series of sparks pass through the paper from stylus to the
-supporting tablet, perforating the paper and producing a stencil to be
-used for reproduction.
-
-
-Fig. 256. ELECTRIC PEN.
-
-
-Pentane Standard, Harcourt's.
-A standard of illuminating power; in it the combustible substance is a
-gas made by mixing one cubic foot of air with three cubic inches of
-liquid pentane, measured at 60� F. or, if measured as gases, 20 volumes
-of air to 7 of pentane. It is burned at the rate of 0.5 cubic foot per
-hour from a cylindrical tube one inch in diameter, closed at the top by
-a disc 0.5 inch thick with a hole 0.25 inch in diameter, through which
-the gas issues. It gives a flame 2.5 inches high.
-
-The pentane used is the distillate of petroleum which boils at 50� C.
-(122� F.) ; it has a specific gravity at 15� C. (60� F.) of from 0.628
-to 0.631. It is almost pure pentane (C5H12).
-
-As long as the rate of consumption is between 0.48 and 0.52 cubic foot
-per hour the flame gives practically the same light.
-
-
-407   STANDARD ELECTRICAL DICTIONARY.
-
-
-Perforator.
-An apparatus used in automatic high speed telegraphy for perforating
-strips of paper. These are then used by drawing between a roller and
-contact spring for making and breaking the telegraphic circuit for the
-production of a record, such as the Morse record, at the distant
-receiving station.
-
-The perforated strip has different classes of holes punched in it to
-represent dots or dashes. It is fed by machinery very rapidly, so that
-the message is transmitted with the highest speed. Several operators may
-simultaneously prepare the paper strips, and thus in conjunction with
-its rapid feeding in the transmitter, far surpass the time of ordinary
-direct transmission.
-
-
-Fig. 257. PERFORATOR FOR WHEATSTONE'S AUTOMATIC TELEGRAPH.
-
-
-Perforators may be entirely mechanical but are sometimes pneumatic,
-compressed air being used to operate them. The holes they make are on
-different levels of the paper strip, as shown in the cut.
-
-
-Period.
-The time required for the completion of one complete element of periodic
-motion. This may be a complete alternation (See Alternation, Complete)
-of an alternating current, or of an oscillatory discharge.
-
-
-Periodicity.
-The rate of succession of alternations or of other fixed phases; the
-rate of recurrence of phenomena.
-
-
-408   STANDARD ELECTRICAL DICTIONARY.
-
-
-Permanency.
-In electric current conductors the property of possessing conductivity
-unaffected by lapse of time. Generally the permanency of conductors is
-very high. In some cases a slow annealing takes place which causes a
-gradual change with the lapse of time. Annealed German silver wire has
-been found to increase in conductivity at about .02 per cent. in a year.
-(Matthiessen.) Wire, whether annealed or not, is left in a strained
-condition after the drawing operations, and such a change is consonant
-with this fact. The figure only applies to the samples tested by
-Matthiessen.
-
-
-Permanent State.
-In a telegraph line or other current conductor, the condition when a
-uniform current strength obtains over the whole line. When a current is
-started it advances through the line with a sort of wave front gradually
-increasing in strength. At the further end some time may elapse before
-it attains its full intensity. When its does the permanent state
-prevails. Until then the variable state, q. v., exists in the line.
-
-
-Permeameter.
-An apparatus for determining the permeability of samples of iron. It
-consists of a large slotted block of iron. A coil is placed within the
-slot. A hole is drilled through one end, and a rod of the iron to be
-tested is passed through this hole and through the coil to the bottom of
-the slot. The lower end of the rod must be accurately faced off. The
-current is turned on, upon which the rod adheres to the bottom of the
-slot. The force required to detach it is determined with a spring
-balance. The permeation through its face is proportional to the square
-of the force required.
-
-
-Fig. 258. PERMEAMETER.
-
-
-Permeance.
-The multiplying or the conducting power for magnetic lines of force
-possessed by a given mass of material. It varies with the shape and size
-of the substance as well as with the inducing force. It is distinguished
-from permeability, as the latter is a specific quality proper to the
-material, and expressed as such; the permeance is the permeability as
-affected by size and shape of the object as well as by its material.
-
-
-409   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pfl�ger's Law.
-A law of electro-therapeutics. It states that stimulation of a nerve is
-only produced by successive appearance of the kathelectrotonic state,
-and disappearance of the anelectrotonic state.
-
-
-Phantom Wires.
-The extra transmission circuits obtained in multiplex telegraph systems.
-A single line arranged for four separate simultaneous transmissions by
-quadruplex apparatus is said to establish three phantom wires.
-
-
-Phase.
-In wave motion, oscillating motion, simple harmonic motion, or similar
-periodic phenomena, the interval of time passed from the time the moving
-particle moved through the middle point of its course to the instant
-when the phase is to be stated.
-
-
-Pherope.
-An apparatus for the electric transmission of pictures. (See Telephote.)
-
-[Transcriber's note: Precursor of the contemporary Fax and scanner.]
-
-
-Philosopher's Egg.
-An ellipsoidal vessel mounted with its long axis vertical and with two
-vertical electrodes, the upper one sliding, and arranged to be attached
-to an air pump. A discharge through it when the air is exhausted takes
-the general shape of an egg.
-
-
-Phonautograph.
-An apparatus for registering the vibrations of a stylus, which is
-mounted on a diaphragm and is acted on by sound waves.
-
-It is virtually a resonating chamber, over one of whose ends a parchment
-diaphragm is stretched. To the centre of the parchment a needle or
-stylus is attached. A cylinder covered with soot is rotated in contact
-with the point of the stylus. As the chamber is spoken into the
-diaphragm and stylus vibrate and the vibrations are marked on the
-cylinder. It is of some electric interest in connection with telephony.
-
-
-Phone.
-Colloquial abbreviation for telephone.
-
-
-Phonic Wheel.
-A form of small motor of very simple construction. It consists of a
-toothed wheel of soft iron. A bar electro-magnet is fixed with one pole
-facing the teeth of the wheel. By a tuning fork make and break a
-succession of impulses of rapid frequency and short duration are sent
-through the magnet. The teeth act as armatures and are successively
-attracted by the magnet. The regulated speed is one tooth for each
-impulse, but it may rotate at one-half the speed, giving two teeth for
-each impulse, or at certain other sub-multiples of its regular speed. It
-is the invention of Paul Lecour.
-
-
-410   STANDARD ELECTRICAL DICTIONARY.
-
-
-Phonograph.
-An apparatus for reproducing articulate speech. It is not electric,
-except as it may be driven by electricity.
-
-It consists of a cylinder of wax-like material which is rotated and
-moved slowly, longitudinally, screw fashion, at an even speed. A glass
-diaphragm carrying a needle point is supported with the point barely
-touching the wax. If the diaphragm is agitated, as by being spoken
-against, the needle is driven back and forwards cutting a broken line or
-groove following the direction of the thread of a screw in the wax, the
-depth of which line or groove continually varies.
-
-This imprints the message. If the needle is set back and the cylinder is
-rotated so as to carry the needle point over the line thus impressed,
-the varying depth throws the needle and diaphragm into motion and the
-sound is reproduced.
-
-The cylinder is rotated often by an electric motor, with a centrifugal
-governor.
-
-[Transcriber's note; Due to T. A. Edison, 1877, fifteen years before
-this book.]
-
-
-Phonozenograph.
-An apparatus for indicating the direction of the point where a sound is
-produced. It operates by a microphone and telephone in conjunction with
-a Wheatstone bridge to determine the locality.
-
-
-Phosphorescence.
-The emission of light rays by a substance not heated, but whose
-luminosity is due to the persistence of luminous vibration after light
-has fallen upon it.
-
-A phosphorescent body, after exposure to light, is luminous itself.
-Phosphorescence may be induced by rubbing or friction, by heat, by
-molecular bombardment, as in Crookes' tubes, and by static discharge of
-electricity, as well as by simple exposure to light.
-
-Another form of phosphorescence may be due to slow chemical combustion.
-This is the cause of the luminosity of phosphorous.
-
-
-Phosphorous, Electrical Reduction of.
-Phosphorous is reduced from bone phosphate by the heat of the electric
-arc. The phosphate mixed with charcoal is exposed to the heat of the
-voltaic are, and reduction of the phosphorous with its volatilization at
-once ensues. The phosphorous as it volatilizes is condensed and
-collected.
-
-
-Photo-electricity.
-The development of electrical properties by exposure to light. Crystals
-of fluor spar are electrified not only by heat (see Pyro-electricity)
-but also by exposure to sunlight or to the light of the voltaic arc.
-
-[Transcribers note: Although first observed in 1839 by Becquerel, it
-was not explained until 1905 by Albert Einstein with the introduction of
-photons.]
-
-
-Photo-electric Microscope.
-A projection, solar or magic-lantern microscope worked by the electric
-light.
-
-
-Photo-electro-motive Force.
-Electro-motive force produced in a substance by the action of light.
-
-
-411   STANDARD ELECTRICAL DICTIONARY.
-
-
-Photometer.
-An apparatus for measuring the intensity of light emitted by a given
-lamp or other source of illuminating power. They may be classified into
-several types.
-
-Calorimetric or Heat Photometers act by measuring relatively the heat
-produced by the ether waves (so-called radiant heat) emitted by the
-source. The accuracy of the instrument is increased by passing the rays
-through an alum solution. A thermopile, or an air thermometer, may be
-used to receive the rays.
-
-Chemical Photometers. In these the light falls upon sensitized
-photographic paper. The depth of coloration is used as the index of
-illuminating power.
-
-Direct Visual Photometers. These include Rumford's Shadow Photometer,
-Bunsen's Bar Photometer, and Wheatstone's Bead Photometer, in which the
-light is estimated by direct visual comparison of its effects.
-
-Optical Photometers. These include Polarization Photometers, in which
-the light is polarized; Dispersion Photometers, in which a diverging
-lens is placed in the path of the rays of light so as to reduce the
-illuminating power in more rapid ratio than that of the square of the
-distance.
-
-Selenium Photometers, in which the variations in resistance of selenium
-as light of varying intensity falls upon it is used as the indicator of
-the intensity of the light.
-
-Jet Photometers, for gas only, in which the height of a flame under
-given conditions, or the conditions requisite to maintain a flame of
-given height, is used to indicate the illuminating power.
-
-The subject of photometers has acquired more importance than ever in
-view of the extensive introduction of the electric light. (See Candle,
-Standard--Carcel--Viol�'s Standard--and Photometers of various kinds.)
-
-
-Photometer, Actinic.
-A photometer whose registrations are produced by the action of the light
-being tested upon sensitized paper or plates, such as used in
-photography. Some efforts at self-registering photometers have been
-based on actinic registration of the height of a flame of the gas to be
-tested.
-
-
-Photometer, Bar.
-A photometer in which the two lights to be compared are fixed at or
-opposite to the ends of a bar or scale of known length, generally 60 or
-100 inches. The bar is divided by the rule of the inverse square of the
-distances, so that if a screen is placed on any part of the bar where it
-receives an equal amount of light from both sources, the figure on the
-bar will indicate the relative illuminating power of the larger lamp or
-light in terms of the smaller. The divisions of the bar are laid out on
-the principle that the illuminating power of the two sources of light
-will vary inversely with the square of their distance from the screen.
-
-
-412   STANDARD ELECTRICAL DICTIONARY.
-
-
-The screen used is sometimes the Bunsen disc. This is a disc of paper
-with a spot of paraffine wax in the centre melted thoroughly into the
-paper or with a ring of paraffine wax surrounding the untouched centre.
-When this disc is equally illuminated on both sides the spot is nearly
-invisible. Inequality of illumination brings it out more visibly.
-Sometimes a Leeson disc is used. This consists of three pieces of paper,
-two thin ones between which a thicker piece, out of which a star is cut,
-is laid. When equally illuminated on both sides the star appears equally
-bright on both sides.
-
-The bar photometer is the standard form. A candle or pair of candles may
-be burned at one end and an incandescent lamp at the other, or a gas
-flame may first be rated by candles and used as a standard.
-
-Synonyms--Bunsen's Photometer--Translucent Disc Photometer.
-
-
-Fig. 259. BAR PHOTOMETER.
-
-
-Photometer. Calorimetric.
-A photometer in which the radiant energy, so called radiant heat, is
-used as the measurer of the light.
-
-In one type a differential air thermometer is used, one of whose bulbs
-is blackened. On exposing this bulb to a source of light it will become
-heated, and if lights of the same character are used the heating will be
-in proportion to their illuminating power quite closely. The heating is
-shown by the movements of the index. By careful calibration the
-instrument may be made quite reliable.
-
-
-Photometer, Dispersion.
-A photometer in which the rays from one of the lights under comparison
-are made more divergent by a concave lens. In this way a strong light,
-such as all arc lamp can be photometered more readily than where only
-the natural divergence of the beam exists. The law of the variation of
-the intensity of light with the square of the distance is abrogated for
-a law of more rapid variation by the use of a concave lens.
-
-The diagram, Fig. 260, illustrates the principle. E represents a
-powerful light, an arc light, to be tested. Its distance from the screen
-is e. Its light goes through the concave lens L and is dispersed as
-shown over an area A1, instead of the much smaller area A, which the
-same rays would otherwise cover. Calling l the distance of the lens from
-the screen, f its focus, and c the distance of the standard candle from
-the screen when the shadows are of equal intensity, we have the
-proportion.
-
-Illuminating power of lamps: ditto of standard candle::
- (l (e-l) + fe)2 : (c f)2
-
-
-413   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 260. DIAGRAM OF PRINCIPLE OF THE DISPERSION PHOTOMETER.
-
-
-The cut, Fig. 261, gives a perspective view of Ayrton's Dispersion
-Photometer. C is the standard candle, L the concave lens, R the rod for
-producing the two shadows on the screen S.
-
-
-Fig. 261. AYRTON'S DISPERSION PHOTOMETER.
-
-
-The mirror M is fixed at an angle of 45� with the stem on which it
-rotates. The light of the arc lamp is received by the mirror and is
-reflected through the lens. The candle holder slides along a graduated
-bar C, and at D is an index plate to show the angle at which the spindle
-carrying the mirror is set.
-
-
-414   STANDARD ELECTRICAL DICTIONARY.
-
-
-Dr. J. Hopkinson in his dispersion photometer uses a double convex lens.
-This gives a focal image of the arc-lamp between the lens and screen,
-whence the rays diverge very rapidly, thus giving the desired dispersion
-effect.
-
-It is principally for arc lamps that dispersion photometers are used.
-
-
-Photometer, Shadow.
-A photometer in which the relative intensity of the two lights is
-estimated by the intensity or strength of shadows of the same object
-which they respectively cast.
-
-
-Fig. 262. RUMFORD'S SHADOW PHOTOMETER.
-
-
-Fig. 263. RUMFORD'S SHADOW PHOTOMETER ARRANGED FOR TESTING
-INCANDESCENT LAMPS.
-
-
-415   STANDARD ELECTRICAL DICTIONARY.
-
-
-A rod is supported in a vertical position. Back of it is a screen of
-white paper. The two lights to be compared are arranged in front of the
-rod and at a little distance from each other. They are shifted about
-until the two shadows appear of equal darkness. The relative intensity
-of the lights varies inversely with the square of their distances from
-the shadows cast respectively by them on the screen.
-
-The cut, Fig. 262, shows the simplest type of the shadow photometer. In
-the cut, Fig. 263, a shadow photometer for testing incandescent lamps is
-shown. In it E is the lamp under trial supported by a clamp H. A is an
-ampere meter in circuit with the lamp, and V is a voltmeter. A candle C
-can be moved along a graduated scale G G. R is the vertical rod, and S
-is the screen on which the shadows fall.
-
-
-Photophore.
-An instrument for medical examination of the cavities of the body. It
-includes an incandescent lamp mounted in a tube with a concave mirror
-and convex lens.
-
-
-Photo-voltaic Effect.
-The change in resistance of some substances effected by light. Selenium,
-of all substances, is most susceptible to this effect. (See Selenium.)
-
-
-Piano, Electric.
-A piano whose manual or key-board operates to close electric circuits,
-whereby electro-magnets are caused to operate to drive the hammers
-against the strings.
-
-
-Pickle.
-An acid solution for cleaning metal surfaces before electro-plating,
-galvanizing or other deposition of metal upon them.
-
-
-Picture, Electric.
-A picture produced by passing a strong discharge through a piece of gold
-leaf clamped or firmly pressed upon a sheet of paper. The gold leaf is
-cut out of the desired shape, or else a stencil of paper overlays it.
-The discharge dissipates the gold, and produces a purple colored
-reproduction of the design upon the paper. The design is due to the
-deposition of an exceedingly thin film of metallic gold.
-
-Synonym--Electric Portrait.
-
-
-Pile.
-A galvanic or voltaic battery. It is sometimes restricted to a number of
-voltaic couples connected. It should be only applied to batteries with
-superimposed plates and no containing vessel such as the Dry Pile, q.
-v., or Volta's Pile, q. v.
-
-
-Pilot Transformer.
-In alternating current distribution a small transformer placed at any
-part of the system and connected to a voltmeter in the central station,
-to indicate the potential difference of the leads.
-
-
-Pilot Wires.
-Wires brought from distant parts of electric light or power mains, and
-leading to voltmeters at the central station, so that the potential of
-distant parts of the system can be watched. The wires can be very small,
-as they have but little current to transmit.
-
-
-416   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pistol, Electric.
-An experimental apparatus for exhibiting the power of electric
-incandescence or of the electric spark. A tube is mounted with a handle
-like a pistol. A plug is provided to screw in and out of its side. The
-plug carries two wires connected on its inner side by a fine platinum
-wire, or else disconnected but with their ends brought near together to
-act as terminals for the production of a spark. To use it the tube is
-filled with a mixture of air and gas, the latter either hydrogen,
-hydro-carbon or other combustible gas. The tube when full is corked. The
-wire is heated to incandescence by a current, or a spark is passed from
-a Leyden jar or other source of electrostatic excitation. The mixture,
-if properly proportioned, explodes and expels the cork violently.
-
-
-Fig. 264. ELECTRIC PISTOL.
-
-
-Pith.
-A light and soft cellular tissue forming the central core of exogenous
-trees and plants. In the older parts of the tree the woody tissue often
-encroaches in and partly obliterates it.
-
-For electrical pith-balls, the pith of the elder, of corn, or, best of
-all, of sun-flower stems is used.
-
-
-Pith-balls.
-Ball made of pith. They are used in the construction of electroscopes
-and for other experiments in static electricity.
-
-They are cut out with a sharp knife and their shape may be improved by
-gentle rolling in the hand or between the fingers.
-
-
-Pivot Suspension.
-Suspension poising or supporting of an object on a sharp pivot. This is
-used for the needle in the ordinary compass. A cavity or inverted cup,
-which may be made of agate, is attached to the middle of the needle
-which has a hole for its reception. The centre of gravity of the needle
-comes below the bottom of the cup.
-
-Pivot suspension is not perfect, as it has considerable friction. There
-is no restitution force, as with torsion filaments.
-
-
-417   STANDARD ELECTRICAL DICTIONARY.
-
-
-Plant.
-The apparatus for commercial manufacturing or technical works. An
-electric lighting plant includes the boilers, engines and dynamos for
-producing the current, and the electric mains and subsidiary apparatus.
-
-
-Plant Electricity.
-Electricity manifested by plant life. By means of a galvanometer
-potential differences are found to exist in different parts of trees or
-fruits. The roots and interior portions are negative, and the flowers,
-smaller branches and fruit are positive.
-
-In some cases a contraction of the tissue of plants can be produced by
-an electric current. The sensitive plant and others exhibit this
-phenomenon, exactly analogous to the action of muscular tissue.
-
-
-Plate, Arrester.
-In a lightning arrester the plate connected to the circuit. Sometimes
-both plates are designated arrester plates.
-
-
-Plate Condenser.
-A static condenser having a flat plate of glass for dielectric. (See
-Epinus' Condenser.)
-
-
-Plate Electrical Machine.
-A frictional electric machine, in which a circular plate of glass is
-excited by friction with the cushions. It is the most recent type of
-frictional machine and has superseded the old cylinder machines. In its
-turn it is superseded by influence machines, really plate machines, but
-not so termed in practice.
-
-
-Plate, Ground.
-In a lightning arrester, the plate connected to the earth.
-
-
-Plate, Negative.
-In a voltaic battery, either primary or secondary, the plate which is
-unattacked by the oxygen or negative radical or element of the fluid. It
-corresponds to the carbon plate in the ordinary voltaic battery, and is
-the one charged with positive electricity.
-
-
-Plate, Positive.
-In a voltaic battery, either primary or secondary, the plate which is
-dissolved or attacked by the oxygen or negative radical or element of
-the fluid. It is the plate corresponding to the zinc plate in the
-ordinary voltaic battery, and is the one charged with negative
-electricity.
-
-
-Plating Balance.
-A balance or scales to which articles in an electroplater's bath are
-suspended. A weight exceeding by a known amount that of the article as
-immersed overbalances the article. When the plating is being deposited
-as soon as it exceeds the excess of weight of the counterpoise the
-balance tips, the article descends a little, the electric circuit is
-broken and the plating ceases. Thus the plating is automatically stopped
-when a predetermined amount of metal is deposited.
-
-
-418   STANDARD ELECTRICAL DICTIONARY.
-
-
-Plating Bath.
-A vessel of solution for the deposition of metal by electrolysis as used
-in electro-plating.
-
-
-Plating, Electro-.
-The deposition of metal by electrolysis so as to coat the conducting
-surface of objects therewith. The full details of the many processes are
-very lengthy and cannot be given here.
-
-The general principle includes a battery or source of electric current.
-The object to be plated is connected to the negative terminal and is
-immersed in the solution. Thus with a battery the object is in
-electrical connection with the zinc plate. To the other terminal a
-metallic plate is connected. The object and the plate termed the anode
-being introduced into a suitable bath, the metal whose solution is in
-the bath is deposited upon the surface of the object.
-
-The bath is a solution of the metal in some form that will lend itself
-to the electrolytic action. The anode is often a plate of the metal of
-the bath, so that it dissolves as fast as metal is deposited on the
-object, thus keeping up the strength of the solution.
-
-The objects to be plated must be scrupulously clean, and great care must
-be taken to keep the bath uncontaminated.
-
-When the object has a non-conducting surface, it is made conducting by
-being brushed over with plumbago q.v. In addition iron dust is sometimes
-dusted over it. This acts by precipitating the metal of the bath
-directly and thus giving a conducting basis for the metal to deposit on.
-To avoid getting iron in a bath the object may be dipped in copper
-sulphate solution. This precipitates copper in place of the iron and
-leaves the article in good shape for silver or other plating.
-
-Electro-plating, if made thick enough, gives a reverse of the article
-when separated therefrom. A direct copy can be got by a second plating,
-on the first plating after separation, or a wax impression can be
-employed.
-
-Under the different metals, formulae for the baths will be found. (See
-also Quicking--
-Steeling--Plating Balance.)
-
-
-Platinoid.
-An alloy of copper, nickel, zinc in the proportions of German silver
-with 1 or 2 per cent of tungsten. It is used for resistances. It has a
-specific resistance (or resistance per centimeter cube) of about 34
-microhms. Its percentage variation in resistance per degree C. (1.8� F.)
-is only about .021 per cent., or less than half that of German silver.
-This is its most valuable feature.
-
-
-419   STANDARD ELECTRICAL DICTIONARY.
-
-
-Platinum.
-A metal; one of the elements; symbol, Pt; atomic weight, 197.4;
-equivalent, 49.35; valency, 4; specific gravity, 21.5.
-It is a conductor of electricity.
-The following data refer to the annealed metal at 0� C. (32� F.)
-  Relative Resistance (Silver annealed = 1),   6.022
-  Specific Resistance,   9.057   microhms.
-  Resistance of a wire,
-  (a) 1 foot long, weighing 1 grain,     2.779   ohms.
-  (b) 1 foot long, 1/1000 inch thick,   54.49     "
-  (c) 1 meter long, weighing 1 gram,     1.938    "
-  (d) 1 meter long, 1 millimeter thick,   .1153   "
-Resistance of a 1 inch cube,   3.565
-Electro-chemical equivalent (Hydrogen = .0105),   0.5181.
-
-The coefficient of expansion by heat is almost the same as that of
-glass. It can be passed through holes in glass and the latter can be
-melted about it so as to hermetically seal its place of passage through
-the glass. It is used in incandescent lamps for leading-in wires and
-other similar uses.
-
-
-Platinum Black.
-Finely divided platinum. It is made by boiling a solution of platinic
-chloride with excess of sodium carbonate and a quantity of sugar, until
-the precipitate is perfectly black and the supernatant liquid is
-colorless. It seems to possess a great power of occluding oxygen gas.
-When heated to redness it becomes spongy platinum. The negative plates
-of a Smee battery are coated with platinum black.
-
-
-Platinum-silver Alloy.
-An alloy of 1 part platinum and 2 parts silver, used for resistance coils.
-
-  Relative Resistance (silver annealed = 1 ),   16.21   microhms.
-  Specific Resistance at 0�C. (32� F.),         24.39
-  Resistance of a wire,
-  (a) 1 foot long, weighing 1 grain,         4.197   ohms.
-  (b) 1 foot long, 1/1000 inch diameter,   146.70     "
-  (c)  1 meter long weighing 1 gram,         2.924    "
-  (d) 1 meter long, 1 millimeter diameter,   0.3106   "
-  Resistance of a 1 inch cube,   9.603   microhms.
-  Percentage Variation per degree C. (1.8� F.)
-    at about 20� C. (68� F.), 0.031 per cent.
-
-Synonym--Platinum Alloy.
-
-
-Platinum Sponge.
-Finely divided platinum obtained by igniting platinum black, q.v., and
-also by igniting salts of platinum. It has considerable power of
-condensing or occluding oxygen. It will, if in good condition, set fire
-to a jet of hydrogen impinging upon it.
-
-
-Plow.
-Contact arms projecting downwards from the motors, trucks, or bodies of
-electric street cars, which enter the underground conduit through the
-slot and carry contact pieces or brushes, to take the current for
-driving the motors from the leads within the conduit.
-
-
-420   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pl�cker Tubes.
-A special form of Geissler tube designed for the production of
-stratification and for observing the effects produced in the space
-surrounding the negative electrode.
-
-
-Plug.
-(a) A piece of metal with a handle and a somewhat tapered end, used to
-make connections by insertions between two plates or blocks of metal
-slightly separated and with grooves to receive it.
-
-(b) A plug or wedge with two metallic faces, insulated from each other
-with a separate wire connected to each one. It is used in spring-jacks
-q. v., to introduce a loop in a circuit.
-
-Synonym--Wedge.
-
-
-Plug. v.
-To connect by inserting a plug, as in a resistance box.
-
-
-Fig. 265. PLUGS FOR RESISTANCE COIL BOX.
-
-
-Fig. 266. PLUG SWITCH.
-
-
-Plug, Double.
-A spring-jack plug or wedge with two pairs of insulated faces, one
-behind the other, so as to simultaneously introduce two loops into a
-circuit.
-
-
-Plug, Grid.
-A piece or mass of lead oxide, inserted into the holes in the lead
-plates of storage batteries. The holes are often dovetailed or of uneven
-section to better retain the plugs.
-
-
-Plug Infinity.
-In a box-bridge or resistance box, a plug whose removal from between two
-disconnected discs opens the circuit. All the other discs are connected
-by resistance coils of various resistance.
-
-
-Plug Switch.
-A switch composed of two contact blocks, not touching each other and
-brought into electrical connection by the insertion of a metallic plug.
-The latter is usually provided with an insulating handle, and a seat is
-reamed out for it in the two faces of the contact blocks.
-
-
-421   STANDARD ELECTRICAL DICTIONARY.
-
-
-Plumbago.
-Soft lustrous graphite, a native form of carbon; sometimes chemically
-purified. It is used in electro-plating to give a conducting surface to
-non-conducting objects, such as wax moulds. The surface, after coating
-with plumbago, is sometimes dusted over with iron dust, which
-precipitates the metal of the bath and starts the plating. It is
-sometimes plated with copper, silver or gold, and is then termed
-coppered, silvered, or gilt plumbago. It is gilded by moistening with
-etherial solution of gold chloride and exposing to the air, and drying
-and igniting.
-
-
-Plunger.
-A movable core which is used in connection with a so-called solenoid
-coil, to be drawn in when the coil is excited. (See Coil and Plunger.)
-
-
-Fig. 267 COIL AND PLUNGER WITH SCALES TO SHOW ATTRACTION.
-
-
-P. O.
-Abbreviation for Post Office, q.v.
-
-
-Poggendorf's Solution.
-An acid depolarizing and exciting fluid for zinc-carbon batteries. The
-following is its formula: Water, 100 parts; potassium bichromate, 12
-parts; concentrated sulphuric acid, 25 parts. All parts by weight. Use
-cold.
-
-
-Point, Neutral.
-(a) On a commutator of a dynamo the points at the ends of the diameter
-of commutation, or where the brushes rest upon the surface of the
-commutator, are termed neutral points. At these points there is no
-generation of potential, they marking the union of currents of opposite
-direction flowing from the two sides of the armature into the brushes.
-
-(b) In electro-therapeutics, a place in the intra-polar region of a
-nerve so situated with reference to the kathode and electrode as applied
-in treatment, that its condition is unaffected.
-
-Synonym--Indifferent Point.
-
-(c) In a magnet the point of no attraction, situated between the two
-poles, at about an equal distance from each, so as to mark the centre of
-a magnet of even distribution of polarity.
-
-(d) In thermo-electricity the point of temperature where the
-thermo-electric powers of two metals are zero; in a diagram the point
-where the lines representing their thermo-electric relations cross each
-other; if the metals are arranged in a thermo-electric couple, one end
-at a temperature a given amount above, the other at a temperature the
-same amount below the neutral point, no current or potential difference
-will be produced.
-
-
-422   STANDARD ELECTRICAL DICTIONARY.
-
-
-Point, Null.
-A nodal point in electrical resonators; a point where in a system of
-waves or oscillations, there is rest, the zero of motion being the
-resultant of oppositely directed and equal forces. In electrical
-resonators it is to be sought for in a point symmetrically situated,
-with reference to the spark gap, or in a pair of points, which pair is
-symmetrically placed.
-
-The null point in resonators is found by connecting a lead from one of
-the secondary terminals of an induction coil to different parts of the
-resonator. The null point is one where the connection does not give rise
-to any sparks between the micrometer knobs or spark gap, or where the
-sparks are of diminished size.
-
-The whole is exactly comparable to loops and nodes in a vibrating string
-or in a Chladni plate as described in treatises on sound and acoustics.
-(See Resonance, Electrical--Resonator, Electrical.)
-
-Synonym--Nodal Point.
-
-
-Point Poles.
-Magnet poles that are virtually points, or of no magnitude. A long thin
-magnet with little leakage except close to the ends may be supposed to
-have point poles within itself a short distance back from the ends.
-
-
-Points, Consequent.
-In a magnet with consequent poles, the points where such poles are
-situated.
-
-
-Points, Corresponding.
-In bound electrostatic charges the points of equal charges of opposite
-potentials; the points at opposite extremities of electrostatic lines of
-force. This definition implies that the bound charges shall be on equal
-facing areas of conductors, as otherwise the spread or concentration of
-the lines of force would necessitate the use of areas of size
-proportionate to the spreading or concentrating of the lines of force.
-At the same time it may figuratively be applied to these cases, the
-penetration of the surface by a single line of force including the area
-fixed by its relation to the surrounding lines.
-
-
-Points, Isoelectric.
-In electro-therapeutics, points of equal potential in a circuit.
-
-
-423   STANDARD ELECTRICAL DICTIONARY.
-
-
-Points of Derivation.
-The point where a single conductor branches into two or more conductors,
-operating or acting in parallel with each other.
-
-
-Polar Angle.
-The angle subtended by one of the faces of the pole pieces of the field-
-magnet of a dynamo or motor. The centre of the circle of the angle lies
-in the axis of the armature.
-
-Synonym--Angle of Polar Span.
-
-
-Polar Extension.
-An addition made of iron to the poles of magnets. Various forms have
-been experimented with. The pole pieces of dynamo field magnets are
-polar extensions.
-
-Synonyms--Pole Piece--Polar Tips.
-
-
-Polarity, Diamagnetic.
-The induced polarity of diamagnetic substances; it is the reverse of
-paramagnetic polarity, or of the polarity of iron. A bar of diamagnetic
-material held parallel with the lines of force in a magnetic field has a
-like pole induced in the end nearest a given pole of the field magnet,
-and vice versa. This theory accounts for the repulsion by a magnet of a
-diamagnetic substance. The existence of this polarity is rather an
-assumption. It originated with Faraday.
-
-
-Polarity, Paramagnetic.
-The induced polarity of paramagnetic substances, such as iron, nickel,
-or cobalt.
-
-When such a substance is brought into a magnetic field the part nearest
-a specific pole of a magnet acquires polarity opposite to that of such
-pole and is thereby attracted.
-
-Another way of expressing it, in which the existence of a pole in or
-near to the field is not implied, is founded on the conventional
-direction of lines of force. Where these enter the substance a south
-pole is formed and where they emerge a north pole is formed.
-
-Such polarity tends always to be established in the direction of
-greatest length, if the body is free to rotate.
-
-
-424   STANDARD ELECTRICAL DICTIONARY.
-
-
-Polarization.
-(a) The depriving of a voltaic cell of its proper electro-motive force.
-Polarization may be due to various causes. The solution may become
-exhausted, as in a Smee battery, when the acid is saturated with zinc
-and thus a species of polarization follows. But the best definition of
-polarization restricts it to the development of counter-electro-motive
-force in the battery by the accumulation of hydrogen on the negative
-(carbon or copper) plate. To overcome this difficulty many methods are
-employed. Oxidizing solutions or solids are used, such as solution of
-chromic acid or powdered manganese dioxide, as in the Bunsen and
-Leclanch� batteries respectively; a roughened surface of platinum black
-is used, as in the Smee battery; air is blown through the solution to
-carry off the hydrogen, or the plates themselves are moved about in the
-solution.
-
-(b) Imparting magnetization to a bar of iron or steel, thus making a
-permanent magnet, is the polarization of the steel of which it is made.
-Polarization may be permanent, as in steel, or only temporary, as in
-soft iron.
-
-(c) The strain upon a dielectric when it separates two oppositely
-charged surfaces. The secondary discharge of a Leyden jar, and its
-alteration in volume testify to the strain put upon it by charging.
-
-(d) The alteration of arrangement of the molecules of an electrolyte by
-a decomposing current. All the molecules are supposed to be arranged
-with like ends pointing in the same direction, positive ends facing the
-positively-charged plate and negative ends the negatively-charged one.
-
-(e) The production of counter-electro-motive force in a secondary
-battery, or in any combination capable of acting as the seat of such
-counter-electro-motive force. (See Battery, Secondary--Battery, Gas.)
-The same can be found often in organized cellular tissue such as that of
-muscles, nerves, or of plants. If a current is passed through this in
-one direction, it often establishes a polarization or potential
-difference that is susceptible of giving a return current in the
-opposite direction when the charging battery is replaced by a conductor.
-
-
-Polarization Capacity.
-A voltaic cell in use becomes polarized by its negative plate
-accumulating hydrogen, or other cause. This gradually gives the plate a
-positive value, or goes to set up a counter-electro-motive force. The
-quantity of electricity required to produce the polarization of a
-battery is termed its Polarization Capacity or Capacity of Polarization.
-
-
-Polarization of the Medium.
-The dielectric polarization, q. v., of a dielectric, implying the
-arrangement of its molecules in chains or filaments; a term due to
-Faraday. He illustrated it by placing filaments of silk in spirits of
-turpentine, and introduced into the liquid two conductors. On
-electrifying one and grounding (or connecting to earth) the other one,
-the silk filaments arranged themselves in a chain or string connecting
-the points of the conductors.
-
-
-Polar Region.
-That part of the surface of a magnet whence the internal magnetic lines
-emerge into the air. (S. P. Thompson.) As such lines may emerge from
-virtually all parts of its surface, the polar regions are indefinite
-areas, and are properly restricted to the parts whence the lines emerge
-in greatest quantity.
-
-
-Polar Span.
-A proportion of the circle which represents the transverse section of
-the armature space between the pole pieces of the field magnet in a
-dynamo or motor; it is the proportion which is filled by the faces of
-the pole pieces.
-
-
-425   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pole, Analogous.
-The end of a crystal of a pyroelectric substance, such as tourmaline,
-which end when heated become positively electrified. On reduction of
-temperature the reverse effect obtains.
-
-
-Pole, Antilogous.
-The end of a crystal of a pyroelectric substance, such as tourmaline,
-which end, while increasing in temperature, becomes negatively
-electrified. During reduction of its temperature the reverse effect
-obtains.
-
-
-Pole Changer.
-(a) An automatic oscillating or vibrating switch or contact-breaker
-which in each movement reverses the direction of a current from a
-battery or other source of current of fixed direction, as such current
-goes through a conductor.
-
-(b) A switch moved by hand which for each movement effects the above
-result.
-
-
-Pole, Negative.
-(a) In a magnet the south pole; the pole into which the lines of force
-are assumed to enter from the air or outer circuit.
-
-(b) In a current generator the pole or terminal into which the current
-is assumed to flow from the external circuit. It is the negatively
-charged terminal and in the ordinary voltaic battery is the terminal
-connected to the zinc or positive plate.
-
-
-Pole Pieces.
-The terminations of the cores of field or other electro-magnets, or of
-permanent magnets. These terminations are variously shaped, sometimes
-being quite large compared to the core proper of the magnet.
-
-They are calculated so as to produce a proper distribution of and
-direction of the lines of force from pole to pole. As a general rule the
-active field should be of uniform strength and the pole pieces may be of
-contour calculated to attain this end.
-
-
-Pole, Positive.
-(a) In a magnet the north pole; the pole from which lines of force are
-assumed to emerge into the air.
-
-(b) In a current generator the pole or terminal whence the current is
-assumed to issue into the outer circuit. It is the positively charged
-terminal, and in the ordinary voltaic battery is the terminal connected
-to the copper or carbon plate, termed the negative plate.
-
-
-Poles.
-(a) The terminals of an open electric circuit, at which there
-necessarily exists a potential difference, produced by the generator or
-source of electro-motive force in the circuit.
-
-(b) The terminals of an open magnetic circuit; the ends of a magnetized
-mass of steel, iron or other paramagnetic substance.
-
-(c) The ends in general of any body or mass which show electric or
-magnetic properties more developed than those of the central sections of
-the body.
-
-
-426   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pole, Salient.
-In dynamo and motor field magnets, salient poles are those projecting
-from the base or main body of the field magnet, as distinguished from
-consequent poles formed by coils wound on the main body itself.
-
-
-Fig. 268. SALIENT POLES OF FIELD MAGNET.
-
-
-Poles, Compensating.
-A device for avoiding the cross-magnetizing effect on the commutator
-core due to the lead of the brushes. It consists in maintaining a small
-bar electro-magnet perpendicularly between the pole pieces. This
-compensates the cross-magnetizing effect.
-
-
-Poles of Intensity.
-The locus of highest magnetic force on the earth's surface. One such
-pole is in Siberia, another is about lat. 52� N., long. 92� W.
-
-[Transcriber's note: 52� N., long. 92� W is about 250 miles Northeast of
-Winnipeg.]
-
-
-Poles of Verticity.
-The magnetic poles of the earth. (See Magnetic Poles.)
-
-Pole Tips.
-The extreme ends of the expanded poles of a field magnet. In some
-machines some of the pole tips are made of cast iron, to alter the
-distribution of the lines of force and resulting magnetic pull upon the
-armatures. This is done to take off the weight of the armature from its
-bearings.
-
-
-Pole, Traveling.
-A term applied to the poles produced in the action of a rotatory field,
-whose poles constantly rotate around the circle of the field. (See
-Field, Rotatory.)
-
-
-417   STANDARD ELECTRICAL DICTIONARY.
-
-
-Porous Cup.
-A cup of pipe clay, unglazed earthenware or other equivalent material
-used in voltaic cells to keep two liquids separate and yet to permit
-electrolysis and electrolytic conduction.
-
-They are necessarily only an expedient, as their porous nature permits
-considerable diffusion, and were they not porous electrolytic action
-would be impossible.
-
-Synonym--Porous Cell.
-
-
-Porret's Phenomenon.
-In electro-physiology, an increase in the diameter of a nerve produced
-by the positive pole of a voltaic circuit, when placed in contact with
-the tissue and near to the nerve in question, the other pole being
-connected to a more or less remote part of the body.
-
-
-Portelectric Railroad.
-A railroad worked by solenoidal attraction, the car forming the core of
-the solenoids. It includes a series of solenoids or hollow coils of
-copper wire distributed all along the road and inclosing within
-themselves the track. On this a cylindrical car with pointed ends moves
-on wheels. Current is supplied to the solenoid in advance of the car,
-and attracts it. As it advances it breaks the contacts of the attracting
-solenoid and turns the current into the one next in advance. This
-operation is repeated as the car advances.
-
-The solenoids are placed close together, each including in the trial
-track 630 turns of No. 14 copper wire. The car was of wrought iron, 12
-feet long, 10 inches in diameter and weighing 500 lbs. It was proposed
-to employ the system for transportation of mail matter and similar uses.
-
-
-Position Finder.
-An instrument for determining the position of objects which are to be
-fired at from forts. It is designed for use from forts situated on the
-water.
-
-Fiske's position finder may be thus generally described. On a chart the
-channel is divided into squares, and the position finder determines the
-square in which a vessel lies. For each square the direction and
-elevation of the guns is calculated beforehand. The enemy can therefore
-be continuously located and fired at, although from smoke or other cause
-the object may be quite invisible to the gunner.
-
-It comprises two telescopes situated at distant extremities of as long a
-base line as is obtainable. These telescopes are kept directed upon the
-object by two observers simultaneously. The observers are in constant
-telephonic communication. As each telescope moves, it carries a contact
-over an arc of conducting material. Below each telescope is an arm also
-moving over an arc of conducting material. These arcs enter into a
-Wheatstone bridge and are so connected that when the arm and the distant
-telescope are at the same angle or parallel a balance is obtained. Thus
-each observer has the power of establishing a balance. A chart is
-provided for each of them, and over it the arm connected with the
-distant telescope and an arm or indicator attached to the telescope at
-that station move so that as long as both telescopes point at the object
-and each observer maintains the electric balance, the intersection of
-the arms shows the position on the chart.
-
-The Position Finder is a simplification and amplification of the Range
-Finder, q. v. In practice the observers may be placed far from the
-forts, and may telephone their observations thereto. It has been found
-accurate within one-third of one per cent.
-
-
-428   STANDARD ELECTRICAL DICTIONARY.
-
-
-Positive Direction.
-The direction which lines of force are assumed to take in the air or
-outer circuit from a positive to a negative region. It applies to
-electrostatic, to magnetic and to electro-magnetic lines of force.
-
-
-Positive Electricity.
-The kind of electricity with which a piece of glass is charged when
-rubbed with silk; vitreous electricity.
-
-In a galvanic cell the surface of the copper or carbon plate is charged
-with positive electricity. (See Electrostatic Series.)
-
-According to the single fluid theory positive electrification consists
-in a surplus of electricity.
-
-[Transcriber's note: "Positive electricity" is a deficiency of electrons.]
-
-
-Post Office. adj.
-Many pieces of electric apparatus of English manufacture are thus
-qualified, indicating that they are of the pattern of the apparatus used
-by the British Post Office in its telegraph department.
-
-Potential.
-Potential in general may be treated as an attribute of a point in space,
-and may express the potential energy which a unit mass would have if
-placed at that point.
-
-This conception of potential is that of a property attributable to a
-point in space, such that if a unit mass were placed there the forces
-acting upon it would supply the force factor of energy, while the body
-would supply the mass factor. This property is expressible in units,
-which produce, if the supposed mass is a unit mass, units of work or
-energy, but potential itself is neither.
-
-Thus taking gravitation, a pound mass on the surface of the earth
-(assuming it to be a sphere of 4,000 miles radius) would require the
-expenditure of 21,120,000 foot pounds to remove it to an infinite
-distance against gravity. The potential of a point in space upon the
-surface of the earth is therefore negative and is represented by
--21,120,000*32.2 foot poundals (32.2 = acceleration of gravity). (See
-Poundal.) In practice and conventionally all points on the earth's
-surface are taken as of zero potential.
-
-[Transcriber's note; 21,120,000 foot pounds is about 8 KWh.]
-
-
-429   STANDARD ELECTRICAL DICTIONARY.
-
-
-Potential, Absolute.
-The absolute electrical potential at a point possesses a numerical value
-and measures the tendency which the existing electric forces would have
-to drive an electrified particle away from or prevent its approach to
-the point, if such a particle, one unit in quantity, were brought up to
-or were situated at that point. It is numerically equal to the number of
-ergs of work which must be done to bring a positive unit of electricity
-from a region where there is absolutely no electric force up to the
-point in question. (Daniell.) Two suppositions are included in this. The
-region where there is an electric force has to be and only can be at an
-infinite distance from all electrified bodies. The moving of the
-particle must take place without any effect upon the distribution of
-electricity on other particles.
-
-
-Potential, Constant.
-Unchanging potential or potential difference.
-
-The ordinary system of incandescent lighting is a constant potential
-system, an unvarying potential difference being maintained between the
-two leads, and the current varying according to requirements.
-
-
-Potential Difference, Electric.
-If of any two points the absolute potentials are determined, the
-difference between such two expresses the potential difference.
-Numerically it expresses the quantity of work which must be done to
-remove a unit of electricity from one to the other against electric
-repulsion, or the energy which would be accumulated in moving it the
-other way.
-
-A positively charged particle is driven towards the point of lower
-potential. A negatively charged body is driven in the reverse direction.
-
-
-Potential Difference, Electro-motive.
-A difference of potential in a circuit, or in part of a circuit, which
-difference produces or is capable of producing a current, or is due to
-the flow of such current.
-
-It may be expressed as the fall in potential or the electro-motive force
-included between any two points on a circuit. The current in an active
-circuit is due to the total electro-motive force in the circuit. This is
-distributed through the circuit in proportion to the resistance of its
-parts. Owing to the distribution of electro-motive force throughout a
-circuit including the generator, the terminals of a generator on closed
-circuit may show a difference of potential far lower than the
-electro-motive force of the generator on closed circuit. Hence potential
-difference in such a case has been termed available electro-motive
-force.
-
-
-Potential, Electric Absolute.
-The mathematical expression of a property of a point in space, measuring
-the tendency which existing electric forces would have to drive an
-electrified unit particle away from or prevent its approach to the point
-in question, according to whether the point was situated at or was at a
-distance from the point in question.
-
-Potential is not the power of doing work, although, as it is expressed
-always with reference to a unit body, it is numerically equal to the
-number of ergs of work which must be done in order to bring a positive
-unit of electricity from a region where there is no electric
-force--which is a region at an infinite distance from all electrified
-bodies--up to the point in question. This includes the assumption that
-there is no alteration in the general distribution of electricity on
-neighboring bodies. (Daniell.)
-
-In practice the earth is arbitrarily taken as of zero electric potential.
-
-
-430   STANDARD ELECTRICAL DICTIONARY.
-
-
-Potential, Fall of.
-The change in potential between any two points on an active circuit. The
-change in potential due to the maintenance of a current through a
-conductor.
-
-The fall in potential multiplied by the current gives work or energy
-units.
-
-The fall of potential in a circuit and its subsequent raising by the
-action of the generator is illustrated by the diagram of a helix. In it
-the potential fall in the outer circuit is shown by the descent of the
-helix. This represents at once the outer circuit and the fall of
-potential in it. The vertical axis represents the portion of the circuit
-within the battery or generator in which the potential by the action of
-the generator is again raised to its original height.
-
-In a circuit of even resistance the potential falls evenly throughout
-it.
-
-A mechanical illustration of the relation of fall of potential to
-current is shown in the cut Fig. 269. A vertical wire is supposed to be
-fixed at its upper end and a lever arm and cord at its lower end, with
-weight and pulley imparts a torsional strain to it. The dials and
-indexes show a uniform twisting corresponding to fall of potential. For
-each unit of length there is a definite loss of twisting, corresponding
-to fall of potential in a unit of length of a conductor of uniform
-resistance. The total twisting represents the total potential
-difference. The weight sustained by the twisting represents the current
-maintained by the potential difference. For a shorter wire less twisting
-would be needed to sustain the weight, as in a shorter piece of the
-conductor less potential difference would be needed to maintain the same
-current.
-
-
-Fig. 269. MECHANICAL ILLUSTRATION OF FALL OF POTENTIAL AND CURRENT
-STRENGTH.
-
-
-431   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 270. ILLUSTRATION OF THE FALL AND REDEVELOPMENT OF POTENTIAL IN AN
-ELECTRIC CIRCUIT.
-
-
-The fall of potential in a circuit in portions of it is proportional to
-the resistance of the portions in question. This is shown in the
-diagram. The narrow lines indicate high and the broad lines low
-resistance. The fall in different portions is shown as proportional to
-the resistance of each portion.
-
-
-Fig. 271. DIAGRAM OF FALL OF POTENTIAL IN A CONDUCTOR OF UNEVEN
-RESISTANCE.
-
-
-Potential, Magnetic.
-The magnetic potential at any point of a magnetic field expresses the
-work which would be done by the magnetic forces of the field on a
-positive unit of magnetism as it moves from that point to an infinite
-distance therefrom. The converse applies to a negative unit.
-
-It is the exact analogue of absolute electric potential.
-
-The potential at any point due to a positive pole m at a distance r is
-m/r;. that due to a negative pole - m at a distance r' is equal to
--m/r';. that due to both is equal to m/r - m/r' or m(1/r - 1/r').
-
-Like electric potential and potential in general, magnetic potential
-while numerically expressing work or energy is neither, although often
-defined as such.
-
-
-432   STANDARD ELECTRICAL DICTIONARY.
-
-
-Potential, Negative.
-The reverse of positive potential. (See Potential, Positive.)
-
-
-Potential, Positive.
-In general the higher potential. Taking the assumed direction of lines
-of force, they are assumed to be directed or to move from regions of
-positive to regions of negative potential. The copper or carbon plate of
-a voltaic battery is at positive potential compared to the zinc plate.
-
-
-Potential, Unit of Electric.
-The arbitrary or conventional potential--or briefly, the potential of a
-point in an electric field of force--is, numerically, the number of ergs
-of work necessary to bring a unit of electricity up to the point in
-question from a region of nominal zero potential--i. e., from the
-surface of the earth. (Daniell.) This would give the erg as the unit of
-potential.
-
-
-Potential, Zero.
-The potential of the earth is arbitrarily taken as the zero of electric
-potential.
-
-The theoretical zero is the potential of a point infinitely distant from
-all electrified bodies.
-
-
-Fig. 272. DIAGRAM OF POTENTIOMETER CONNECTIONS.
-
-
-Potentiometer.
-An arrangement somewhat similar to the Wheatstone Bridge for determining
-potential difference, or the electro-motive force of a battery. In
-general principle connection is made so that the cell under trial would
-send a current in one direction through the galvanometer. Another
-battery is connected, and in shunt with its circuit the battery under
-trial and its galvanometer are connected, but so that its current is in
-opposition. By a graduated wire, like that of a meter bridge, the
-potential of the main battery shunt can be varied until no current
-passes. This gives the outline of the method only.
-
-
-433   STANDARD ELECTRICAL DICTIONARY.
-
-
-In the cut A B is the graduated potentiometer wire through which a
-current is passed in the direction of the arrow. E is the battery under
-trial, placed in opposition to the other current, with a galvanometer
-next it. Under the conditions shown, if the galvanometer showed no
-deflection, the E. M. F. of the battery would be to the E. M. F. between
-the ends of the potentiometer wire, 1 . . . . .10, as 1.5 the distance
-between the points of connection, A and D of the battery circuit, is to
-10, the full length of the potentiometer wire.
-
-
-Poundal.
-The British unit of force; the force which acting on a mass of one pound
-for one second produces an acceleration of one foot.
-
-[Transcriber's note: The force which acting on a mass of one pound
-produces an acceleration of ONE FOOT PER SECOND PER SECOND.]
-
-
-Power. Activity;
-the rate of activity, of doing work, or of expending energy. The
-practical unit of electric power is the volt-ampere or watt, equal to
-1E7 ergs per second. The kilowatt, one thousand watts or volt-amperes,
-is a frequently adopted unit.
-
-
-Power, Electric.
-As energy is the capacity for doing work, electric energy is represented
-by electricity in motion against a resistance. This possesses a species
-of inertia, which gives it a species of kinetic energy. To produce such
-motion, electro- motive force is required. The product of E. M. F. by
-quantity is therefore electric energy. (See Energy, Electric.)
-
-Generally the rate of energy or power is used. Its dimensions are
- ( ( (M^.5)*(L^.5) ) / T )  *   ( ( (M^.5) *(L^1.5) )/( T^2) )
- (intensity or current rate)   *   (electro-motive force or potential)
-  = (M * (L^2) ) / (T^3),
-which are the dimensions of rate of work or activity. The practical unit
-of electric rate of energy or activity is the volt-ampere or watt. By
-Ohm's law, q. v., we have C = E/R (C = current; E = potential difference
-or electro-motive force; R = resistance.) The watt by definition = C*E.
-By substitution from Ohm's formula we deduce for it the following
-values: ((C^2) * R) and ((E^2) /R). From these three expressions the
-relations of electric energy to E.M.F., Resistance, and Current can be
-deduced.
-
-
-Power of Periodic Current.
-The rate of energy in a circuit carrying a periodic current. In such a
-circuit the electro-motive force travels in advance of the current it
-produces on the circuit. Consequently at phases or intervals where,
-owing to the alternations of the current, the current is at zero, the
-electro-motive force may be quite high. At any time the energy rate is
-the product of the electro-motive force by the amperage. To obtain the
-power or average rate of energy, the product of the maximum
-electro-motive force and maximum current must be divided by two and
-multiplied by the cosine of the angle of lag, which is the angle
-expressing the difference of phase.
-
-[Transcriber's note; The voltage phase will lead if the load is
-inductive. The current phase will lead if the load is capacitive.
-Capacitors or inductors may be introduced into power lines to correct
-the phase offset introduced by customer loads.]
-
-
-434   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pressel.
-A press-button often contained in a pear-shaped handle, arranged for
-attachment to the end of a flexible conductor, so as to hang thereby. By
-pressing the button a bell may be rung, or a distant lamp may be
-lighted.
-
-
-Pressure.
-Force or stress exerted directly against any surface. Its dimensions are
-force/area or ((M*L)/(T^2)) / (L^2) = M/(L* (T^2)).
-
-
-Pressure, Electric.
-Electro-motive force or potential difference; voltage. An expression of
-metaphorical nature, as the term is not accurate.
-
-
-Pressure, Electrification by.
-A crystal of Iceland spar (calcium carbonate) pressed between the
-fingers becomes positively electrified and remains so for some time.
-Other minerals act in a similar way. Dissimilar substances pressed
-together and suddenly separated carry off opposite charges. This is
-really contact action, not pressure action.
-
-
-Primary.
-A term used to designate the inducing coil in an induction coil or
-transformer; it is probably an abbreviation for primary coil.
-
-
-Primary Battery.
-A voltaic cell or battery generating electric energy by direct
-consumption of material, and not regenerated by an electrolytic process.
-
-The ordinary voltaic cell or galvanic battery is a primary battery.
-
-
-Prime. vb.
-To impart the first charge to one of the armatures of a Holtz or other
-influence machine.
-
-
-Fig. 273. PRIME CONDUCTOR AND PROOF PLANE.
-
-
-435   STANDARD ELECTRICAL DICTIONARY.
-
-
-Prime Conductor.
-A metal or metal coated sphere or cylinder or other solid with rounded
-ends mounted on insulating supports and used to collect electricity as
-generated by a frictional electric machine.
-
-According to whether the prime conductor or the cushions are grounded
-positive or negative electricity is taken from the ungrounded part.
-Generally the cushions are grounded, and the prime conductor yields
-positive electricity.
-
-
-Probe, Electric.
-A surgeon's probe, designed to indicate by the closing of an electric
-circuit the presence of a bullet or metallic body in the body of a
-patient.
-
-Two insulated wires are carried to the end where their ends are exposed,
-still insulated from each other. In probing a wound for a bullet if the
-two ends touch it the circuit is closed and a bell rings. If a bone is
-touched no such effect is produced. The wires are in circuit with an
-electric bell and battery.
-
-
-Projecting Power of a Magnet.
-The power of projecting its lines of force straight out from the poles.
-This is really a matter of magnetic power, rather than of shape of the
-magnet. In electromagnets the custom was followed by making them long to
-get this effect. Such length was really useful in the regard of getting
-room for a sufficient number of ampere turns.
-
-
-436   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 274. PRONY BRAKE.
-
-
-Prony Brake.
-A device for measuring the power applied to a rotating shaft. It
-consists of a clamping device to be applied more or less rigidly to the
-shaft or to a pulley upon it. To the clamp is attached a lever carrying
-a weight. The cut shows a simple arrangement, the shaft A carries a
-pulley B to which the clamp B1 B2 is applied. The nuts C1 C2 are used
-for adjustment.
-
-A weight is placed in the pan E attached to the end of the lever D. The
-weight and clamp are so adjusted that the lever shall stand horizontally
-as shown by the index E. If we call r the radius of the pulley and F the
-friction between its surface and the clamp, it is evident that r F, the
-moment of resistance to the motion of the pulley, is equal to the weight
-multiplied by its lever arm or to W*R, where W indicates the weight and
-R the distance of its point of application from the centre of the pulley
-or r*F = R*W. The work represented by this friction is equal to the
-distance traveled by the surface of the wheel multiplied by the
-frictional resistance, or is 2*PI*r*n*F, in which n is the number of
-turns per minute. But this is equal to 2*PI*R*W. These data being known,
-the power is directly calculated therefrom in terms of weight and feet
-per minute.
-
-
-Proof-plane.
-A small conductor, usually disc shaped, carried at the end of an
-insulating handle. It is used to collect electricity by contact, from
-objects electrostatically charged. The charge it has received is then
-measured (see Torsion Balance) or otherwise tested. (See Prime
-Conductor.)
-
-
-Proof-sphere.
-A small sphere, coated with gold-leaf or other conductor, and mounted on
-an insulated handle. It is used instead of a proof-plane, for testing
-bodies whose curvature is small.
-
-
-Fig. 275. BOX BRIDGE.
-
-
-437   STANDARD ELECTRICAL DICTIONARY.
-
-
-Proportionate Arms. In general terms the arms of a Wheatstone bridge
-whose proportion has to be known to complete the measurement. There is a
-different system of naming them. Some designate by this title the two
-arms in parallel with each other branching at and running from one end
-of the bridge to the two galvanometer connections. In the cut of the Box
-Bridge, A C and A B are the proportionate arms. The third arm is then
-termed the Rheostat arm. (Stewart & Gee.)
-
-Others treat as proportionate arms the two side members of the bridge in
-parallel with the unknown resistance and third or rheostat arm.
-
-Synonym--Ratio Arms.
-
-
-Prostration, Electric.
-Too great exposure to the voltaic arc in its more powerful forms causes
-symptoms resembling those of sunstroke. The skin is sometimes affected
-to such a degree as to come off after a few days. The throat, forehead
-and face suffer pains and the eyes are irritated. These effects only
-follow exposure to very intense sources of light, or for very long
-times.
-
-[Transcriber's note: Arcs emit ultraviolet rays.]
-
-
-Protector, Comb.
-A lightning arrester, q. v., comprising two toothed plates nearly
-touching each other.
-
-
-Protector, Electric.
-A protective device for guarding the human body against destructive or
-injurious electric shocks. In one system, Delany's, the wrists and
-ankles are encircled by conducting bands which by wires running along
-the arms, back and legs are connected. A discharge it is assumed
-received by the hands will thus be short circuited around the body and
-its vital organs. India rubber gloves and shoe soles have also been
-suggested; the gloves are still used to some extent.
-
-
-Pull.
-A switch for closing a circuit when pulled. It is used instead of a push
-button, q.v., in exposed situations, as its contacts are better
-protected than those of the ordinary push button.
-
-
-Pump, Geissler.
-A form of mercurial air pump. It is used for exhausting Geissler tubes,
-incandescent lamp bulbs and similar purposes.
-
-Referring to the cut, A is a reservoir of mercury with flexible tube C
-connected to a tube at its bottom, and raised and lowered by a windlass
-b, the cord from which passes over a pulley a. When raised the mercury
-tends to enter the chamber B, through the tube T. An arrangement of
-stopcocks surmounts this chamber, which arrangement is shown on a larger
-scale in the three figures X, Y and Z. To fill the bulb B, the cocks are
-set in the position Z; n is a two way cock and while it permits the
-escape of air below, it cuts off the tube, rising vertically from it.
-This tube, d in the full figure connects with a vessel o, pressure gauge
-p, and tube c, the latter connecting with the object to be exhausted.
-The bulb B being filled, the cock m is closed, giving the position Y and
-the vessel A is lowered until it is over 30 inches below B.
-
-438   STANDARD ELECTRICAL DICTIONARY.
-
-This establishes a Torricellian vacuum in B. The cock n is now turned,
-giving the position X, when air is at once exhausted from the vessel
-connected to C. This process is repeated until full exhaustion is
-obtained. In practice the first exhaustion is often effected by a
-mechanical pump. By closing the cock on the outlet tube c but little air
-need ever find its way to the chambers o and B.
-
-
-Fig. 276. GEISSLER AIR PUMP.
-
-
-439   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pumping.
-In incandescent lamps a periodical recurring change in intensity due to
-bad running of the dynamos, or in arc lamps to bad feeding of the
-carbons.
-
-
-Fig. 277. SPRENGEL AIR PUMP.
-
-
-Pump, Sprengel.
-A form of mercurial air pump. A simple form is shown in the cut. Mercury
-is caused to flow from the funnel A, through c d to a vessel B. A side
-connection x leads to the vessel R to be exhausted. As the mercury
-passes x it breaks into short columns, and carries air down between
-them, in this way exhausting the vessel R. In practice it is more
-complicated. It is said to give a better vacuum than the Sprengel pump,
-but to be slower in action.
-
-
-440   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pump, Swinburne.
-A form of mechanical air pump for exhausting incandescent lamp bulbs.
-Referring to the cut, A is a bulb on the upper part of a tube G; above A
-are two other bulbs C and D. From the upper end a tube runs to the bulb
-E. Through the cock L, and tube F connection is made with a mechanical
-air pump. The tube H leads to a drying chamber I, and by the tube J
-connects with the lamp bulbs or other objects to be exhausted. The tube
-G enters the bottle B through an airtight stopper, through which a
-second tube with stopcock K passes. In use a vacuum is produced by the
-mechanical pumps, exhausting the lamp bulbs to a half inch and drawing
-up the mercury in G. The bent neck in the bulb E, acts with the bulb as
-a trap to exclude mercury from F. When the mechanical pumps have
-produced a vacuum equal to one half inch of mercury, the cock L is
-closed and K is opened, and air at high pressure enters. This forces the
-mercury up to the vessel D, half filling it. The high pressure is now
-removed and the mercury descends. The valve in D closes it as the
-mercury falls to the level G. Further air from the lamps enters A, and
-by repetition of the ascent of the mercury, is expelled, through D. The
-mercury is again lowered, producing a further exhaustion, and the
-process is repeated as often as necessary.
-
-
-Fig. 278. SWINBURNE'S AIR PUMP.
-
-
-Push-Button.
-A switch for closing a circuit by means of pressure applied to a button.
-The button is provided with a spring, so that when pushed in and
-released it springs back. Thus the circuit is closed only as long as the
-button is pressed. The electric connection may be made by pressing
-together two flat springs, each connected to one of the wires, or by the
-stem of the button going between two springs, not in contact, forcing
-them a little apart to secure good contact, and thereby bridging over
-the space between them.
-
-
-441   STANDARD ELECTRICAL DICTIONARY.
-
-Pyro-electricity.
-A phenomenon by which certain minerals when warmed acquire electrical
-properties. (Ganot.) The mineral tourmaline exhibits it strongly. It was
-originally observed in this mineral which was found to first attract and
-then to repel hot ashes.
-
-The phenomenon lasts while any change of temperature within certain
-limits is taking place. In the case of tourmaline the range is from
-about 10� C. (50� F.) to 150� C. (302� F.) Above or below this range it
-shows no electrification.
-
-The effect of a changing of temperature is to develop poles, one
-positive and the other negative. As the temperature rises one end is
-positive and the other negative; as the temperature becomes constant the
-polarity disappears; as the temperature falls the poles are reversed.
-
-If a piece of tourmaline excited by pyro-electricity is broken, its
-broken ends develop new poles exactly like a magnet when broken.
-
-The following minerals are pyro-electric: Boracite, topaz, prehnite,
-zinc silicate, scolezite, axenite. The following compound substances are
-also so: Cane sugar, sodium- ammonium racemate and potassium tartrate.
-
-The list might be greatly extended.
-
-The phenomenon can be illustrated by sifting through a cotton sieve upon
-the excited crystal, a mixture of red lead and flowers of sulphur. By
-the friction of the sifting these become oppositely electrified; the
-sulphur adheres to the positively electrified end, and the red lead to
-the negatively electrified end. (See Analogous Pole-Antilogous Pole.)
-
-
-Pyromagnetic Motor.
-A motor driven by the alternation of attraction and release of an
-armature or other moving part, as such part or a section of it is
-rendered more or less paramagnetic by heat.
-
-Thus imagine a cylinder of nickel at the end of a suspension rod, so
-mounted that it can swing like a pendulum. A magnet pole is placed to
-one side to which it is attracted. A flame is placed so as to heat it
-when in contact with the magnet pole. This destroys its paramagnetism
-and it swings away from the magnet and out of the flame. It cools,
-becomes paramagnetic, and as it swings back is reattracted, to be again
-released as it gets hot enough. This constitutes a simple motor.
-
-A rotary motor may be made on the same lines. Nickel is particularly
-available as losing its paramagnetic property easily.
-
-
-442   STANDARD ELECTRICAL DICTIONARY.
-
-
-Various motors have been constructed on this principle, but none have
-attained any practical importance. Owing to the low temperature at which
-it loses its paramagnetic properties nickel is the best metal for
-paramagnetic motors.
-
-In Edison's motor, between the pole pieces of an electro-magnet a
-cylinder made up of a bundle of nickel tubes is mounted, so as to be
-free to rotate. A screen is placed so as to close or obstruct the tubes
-farthest from the poles. On passing hot air or products of combustion of
-a fire or gas flame through the tubes, the unscreened ones are heated
-most and lose their paramagnetism. The screened tubes are then attracted
-and the armature rotates, bringing other tubes under the screen, which
-is stationary. Then the attracted tubes are heated while the others
-cool, and a continuous rotation is the result.
-
-
-Fig. 279. EDISON'S PYROMAGNETIC MOTOR.
-
-
-Pyromagnetic Generator.
-A current generator producing electric energy directly from thermal
-energy by pyromagnetism.
-
-Edison's pyromagnetic generator has eight electro-magnets, lying on
-eight radii of a circle, their poles facing inward and their yokes
-vertical. Only two are shown in the cut. On a horizontal iron disc are
-mounted eight vertical rolls of corrugated nickel representing
-armatures. On each armature a coil of wire, insulated from the nickel by
-asbestus is wound. The coils are all in series, and have eight
-connections with a commutator as in a drum armature. There are two main
-divisions to the commutator. Each connects with an insulated collecting
-ring, and the commutator and collecting rings are mounted on a spindle
-rotated by power. Below the circle of vertical coils is a horizontal
-screen, mounted on the spindle and rotating with it.
-
-A source of heat, or a coal stove is directly below the machine and its
-hot products of combustion pass up through the coils, some of which are
-screened by the rotating screen. The effect is that the coils are
-subjecting to induction owing to the change in permeability of the
-nickel cores, according as they are heated, or as they cool when the
-screen is interposed. The two commutator segments are in constant
-relation to the screen, and current is collected therefrom and by the
-collecting rings is taken to the outside circuit.
-
-
-443   STANDARD ELECTRICAL DICTIONARY.
-
-
-Pyromagnetism.
-The development of new magnetic properties or alteration of magnetic
-sensibility in a body by heat. Nickel and iron are much affected as
-regards their paramagnetic power by rise of temperature.
-
-
-Fig. 280. PYROMAGNETIC GENERATOR.
-
-
-Pyrometer, Siemens' Electric.
-An instrument for measuring high temperatures by the variations in
-electric resistance in a platinum wire exposed to the heat which is to
-be measured.
-
-
-Q.
-Symbol for electric quantity.
-
-
-Quad.
-(a) A contraction for quadrant, used as the unit of inductance; the henry.
-
-(b) A contraction for quadruplex in telegraphy.
-
-[Transcriber's note: A modern use of "quad" is a unit of energy equal to
-1E15  (one quadrillion) BTU, or 1.055E18 joules. Global energy
-production in 2004 was 446 quad.]
-
-
-Quadrant.
-A length equal to an approximate earth quadrant, equal to 1E9
-centimeters. It has been used as the name for the unit of inductance,
-the henry, q. v.
-
-Synonym--Standard Quadrant.
-
-
-444   STANDARD ELECTRICAL DICTIONARY.
-
-
-Quadrant, Legal.
-The accepted length of the quadrant of the earth, 9.978E8 instead of 1E9
-centimeters; or to 9,978 kilometers instead of 10,000 kilometers.
-
-
-Quadrature.
-Waves or periodic motions the angle of lag of one of which, with
-reference to one in advance of it, is 90�, are said to be in quadrature
-with each other.
-
-[Transcriber's note: If the voltage and current of a power line are in
-quadrature, the power factor is zero (cos(90�) = 0)  and no real power
-is delivered to the load.]
-
-
-Qualitative.
-Involving the determination only of the presence or absence of a
-substance or condition, without regard to quantity. Thus a compass held
-near a wire might determine qualitatively whether a current was passing
-through the wire, but would not be sufficient to determine its quantity.
-(See Quantitative.)
-
-
-Quality of Sound.
-The distinguishing characteristic of a sound other than its pitch; the
-timbre.
-
-It is due to the presence with the main or fundamental sound of other
-minor sounds called overtones, the fundamental note prevailing and the
-other ones being superimposed upon it. The human voice is very rich in
-overtones; the telephone reproduces these, thus giving the personal
-peculiarities of every voice.
-
-Synonym--Timbre.
-
-
-Quantitative.
-Involving the determination of quantities. Thus a simple test would
-indicate that a current was passing through a wire. This would be a
-qualitative test. If by proper apparatus the exact intensity of the
-current was determined, it would be a quantitative determination. (See
-Qualitative.)
-
-
-Quantity.
-This term is used to express arrangements of electrical connections for
-giving the largest quantity of current, as a quantity armature, meaning
-one wound for low resistance.
-
-A battery is connected in quantity when the cells are all in parallel.
-It is the arrangement giving the largest current through a very small
-external resistance.
-
-The term is now virtually obsolete (Daniell); "in surface," "in
-parallel," or "in multiple arc" is used.
-
-
-Quantity, Electric.
-Electricity may be measured as if it were a compressible gas, by
-determining the potential it produces when stored in a defined
-recipient. In this way the conception of a species of quantity is
-reached. It is also measured as the quantity of current passed by a
-conductor.
-
-Thus a body whose surface is more or less highly charged with
-electricity, is said to hold a greater or less quantity of electricity.
-
-It may be defined in electrostatic or electro-magnetic terms. (See
-Quantity, Electrostatic--Quantity, Electro-magnetic.)
-
-
-445   STANDARD ELECTRICAL DICTIONARY.
-
-
-Quantity.
-Electro-magnetic. Quantity is determined electro-magnetically by the
-measurement of current intensity for a second of time: its dimensions
-are therefore given by multiplying intensity or current strength by
-time. The dimensions of intensity are
-  ( (M^.5) * (L^.5) ) / T
-therefore the dimensions of electro-magnetic quantity are
-  ( ( (M^.5) * (L^.5) ) / T ) * T = ( (M^.5) * (L^.5) )
-
-
-Quantity, Electro-magnetic, Practical Unit of.
-The quantity of electricity passed by a unit current in unit time; the
-quantity passed by one ampere in one second; the coulomb.
-
-It is equal to 3E9 electrostatic absolute units of quantity and to 0.1
-of the electro- magnetic absolute unit of quantity.
-
-One coulomb is represented by the deposit of
-  .00111815 gram, or .017253 grain of silver,
-  .00032959 gram, or .005804 grain of copper,
-  .0003392 gram,  or .005232 grain of zinc.
-
-If water is decomposed by a current each coulomb is represented by the
-cubic centimeters of the mixed gases (hydrogen and oxygen) given by the
-following formula.
-  ( 0.1738 * 76 * (273 + C� ) ) / ( h * 273 )
-in which C� is the temperature of the mixed gases in degree centigrade
-and h is the
-pressure in centimeters of mercury column; or by
-  ( 0.01058 * 30 (491 + F� - 32)  ) / (h * 491 )
-for degrees Fahrenheit and inches of barometer.
-
-[Transcriber's note: 6.24150962915265E18 electrons is one coulomb.]
-
-
-Quantity, Electrostatic.
-Quantity is determined electro-statically by the repulsion a charge of
-given quantity exercises upon an identical charge at a known distance.
-The force evidently varies with the product of the two quantities, and
-by the law of radiant forces also inversely with the square of the
-distance. The dimensions given by these considerations is Q * Q/(L*L).
-This is the force of repulsion. The dimensions of a force are
-(M * L) /(T^2). Equating these two expressions we have:
-  (Q^2)/(L^2) = (M*L)/(T^2)
-  or
-  Q = ((M^.5)*(L^1.5)) / T
-which are the dimensions of electrostatic quantity.
-
-
-Quantity, Meter.
-An electric meter for determining the quantity of electricity which
-passes through it, expressible in coulombs or ampere hours. All
-commercial meters are quantity meters.
-
-
-446   STANDARD ELECTRICAL DICTIONARY.
-
-
-Quartz.
-A mineral, silica, SiO2. It has recently been used by C. V. Boys and
-since by others in the making of filaments for torsion suspensions. The
-mineral is melted, while attached to an arrow or other projectile. It is
-touched to another piece of quartz or some substance to which it adheres
-and the arrow is fired off from the bow. A very fine filament of
-surpassingly good qualities for galvanometer suspension filaments is
-produced.
-
-As a dielectric it is remarkable in possessing but one-ninth the
-residual capacity of glass.
-
-
-Quicking.
-The amalgamating of a surface of a metallic object before silver
-plating. It secures better adhesion of the deposit. It is executed by
-dipping the article into a solution of a salt of mercury. A solution of
-mercuric nitrate 1 part, in water 100 parts, both by weight, is used.
-
-
-R.
-(a) Abbreviation and symbol for Reamur, as 10� R., meaning 10� by the
-Reamur thermometer. (See Reamur Scale.)
-
-(b) Symbol for resistance, as in the expression of Ohm's Law C=E/R.
-(rho, Greek r) Symbol for specific resistance.
-
-
-Racing of Motors.
-The rapid acceleration of speed of a motor when the load upon it is
-removed. It is quickly checked by counter-electro-motive force. (See
-Motor, Electric.)
-
-
-Radian.
-The angle whose arc is equal in length to the radius; the unit angle.
-
-
-Radiant Energy.
-Energy, generally existing in the luminiferous ether, kinetic and
-exercised in wave transmission, and rendered sensible by conversion of
-its energy into some other form of energy, such as thermal energy.
-
-If the ether waves are sufficiently short and not too short, they
-directly affect the optic nerve and are known as light waves; they may
-be so short as to be inappreciable by the eye, yet possess the power of
-determining chemical change, when they are known as actinic waves; they
-may be also so long as to be inappreciable by the eye, when they may be
-heat-producing waves, or obscure waves.
-
-Other forms of energy may be radiant, as sound energy dispersed by the
-air, and gravitational energy, whose connection with the ether has not
-yet been demonstrated.
-
-
-Radiation.
-The traveling or motion of ether waves through space.
-
-[Transcriber's note: The modern term corresponding to this definition is
-photons. The modern concept of radiation also includes particles--
-neutrons, protons, alpha (helium) and beta (electrons) rays and other
-exotic items.]
-
-
-Radicals.
-A portion of a molecule, possessing a free bond and hence free to
-combine directly. A radical never can exist alone, but is only
-hypothetical. An atom is a simple radical, an unsaturated group of atoms
-is a compound radical.
-
-
-447   STANDARD ELECTRICAL DICTIONARY.
-
-
-Radiometer.
-An instrument consisting of four vanes poised on an axis so as to be
-free to rotate, and contained in a sealed glass vessel almost perfectly
-exhausted. The vanes of mica are blackened on one side.
-
-On exposure to light or a source of heat (ether waves) the vanes rotate.
-The rotation is due to the beating back and forth of air molecules from
-the surface of the vanes to the inner surface of the glass globe.
-
-
-Radiometer, Electric.
-A radiometer in which the motion of the molecules of air necessary for
-rotation of the vane is produced by electrification and not by heating.
-
-
-Radio-micrometer.
-An instrument for detecting radiant energy of heat or light form. It
-consists of a minute thermopile with its terminals connected by a wire,
-the whole suspended between the poles of a magnet. A minute quantity of
-heat produces a current in the thermopile circuit, which, reacted on by
-the field, produces a deflection. A convex mirror reflecting light is
-attached so as to move with the thermopile. The instrument is of
-extraordinary sensitiveness. It responds to .5E-6 of a degree Centigrade
-or about 1E-6 degree Fahrenheit.
-
-
-Radiophony.
-The production of sound by intermittent action of a beam of light upon a
-body. With possibly a few exceptions all matter may produce sound by
-radiophouy.
-
-
-Range Finder.
-An apparatus for use on shipboard to determine the distance of another
-ship or object. It is designed for ships of war, to give the range of
-fire, so as to set the guns at the proper elevation. The general
-principle involved is the use of the length of the ship if possible, if
-not of its width, as a base line. Two telescopes are trained upon the
-object and kept trained continuously thereon. The following describes
-the Fiske range finder.
-
-The range finder comprises two fairly powerful telescopes, each mounted
-on a standard, which can be rotated round a vertical axis, corresponding
-with the center of the large disc shown in the engraving. One-half of
-the edge of this disc is graduated to 900 on either side of a zero
-point, and below the graduation is fixed a length of platinum silver
-wire. This wire only extends to a distance of 81.10 on either side of
-zero, and is intended to form two arms of a Wheatstone bridge. The
-sliding contact is carried by the same arm as the telescope standards,
-so that it moves with the telescope. The two instruments are mounted at
-a known distance apart on the ship, as shown diagrammatically in the
-cut. Here A and B are the centers of the two discs, C and D the arms
-carrying the telescopes, and E and F the platinum silver wires. Suppose
-the object is at T, such that A B T is a right angle, then
-AT=AB/sin(ATB).
-
-
-448   STANDARD ELECTRICAL DICTIONARY.
-
-
-If the two sectors are coupled up as shown, with a battery, h, and a
-galvanometer, by the wires, a b and c d, then since the arm, e, on being
-aligned on the object takes the position c1 while d remains at zero, the
-Wheatstone bridge formed by these segments and their connections will be
-out of balance, and a current will flow through the galvanometer, which
-may be so graduated as to give the range by direct reading, since the
-current through it will increase with the angle A T B.
-
-
-Fig. 281. RANGE FINDER.
-
-
-In general, however, the angle A B T will not be a right angle, but some
-other angle. In this case AT = AB / sin(A T B) * sin( A B T), and hence
-it will only be necessary to multiply the range reading on the
-galvanometer by the sine of the angle A B T, which can be read directly
-by the observer at B. This multiplication is not difficult, but by
-suitably arranging his electrical appliances Lieutenant Fiske has
-succeeded in getting rid of it, so that the reading of the galvanometer
-always gives the range by direct reading, no matter what the angle at B
-may be. To explain this, consider the two telescopes shown in the cut in
-the positions C and D; the whole current then has a certain resistance.
-
-
-449   STANDARD ELECTRICAL DICTIONARY.
-
-
-Next suppose them, still remaining parallel, in the positions C1 and D1.
-The total resistance of the circuit is now less than before, and hence
-if C1, one of the telescopes, is moved out of parallel to the other,
-through a certain angle, the current through the galvanometer will be
-greater than if it were moved through an equal angle out of a parallel
-when the telescopes were in the positions C and D. The range indicated
-is, therefore, decreased, and by properly proportioning the various
-parts it is found that the range can always be read direct from the
-galvanometer, or in other words the multiplication of A B/sin( A T B )
-by sin( A B T ) is to all intents and purposes performed automatically.
-There is, it is true, a slight theoretical error; but by using a small
-storage battery and making the contents carefully it is said to be
-inappreciable. Each telescope is fitted with a telephone receiver and
-transmitter, so that both observers can without difficulty decide on
-what point to align their telescopes. It will be seen that it is
-necessary that the lines of sight of two telescopes should be parallel
-when the galvanometer indicates no current. It has been proposed to
-accomplish this by sighting both telescopes on a star near the horizon,
-which being practically an infinite distance away insures the
-parallelism of the lines of sight.
-
-
-Rate Governor.
-An apparatus for securing a fixed rate of vibration of a vibrating reed.
-It is applied in simultaneous telegraphy and telephoning over one wire.
-The principle is that of the regular make and break mechanism, with the
-feature that the contact is maintained during exactly one-half of the
-swing of the reed. The contact exists during the farthest half of the
-swing of the reed away from the attracting pole.
-
-
-Fig. 282. LANGDON DAVIRS' RATE GOVERNOR.
-
-
-In the left hand figure of the cut, K is the key for closing the
-circuit. A is the base for attachment of the reed. V is the
-contact-spring limited in its play to the right by the screw S. C is the
-actuating magnet. By tracing the movements of the reed, shown on an
-exaggerated scale in the three right hand figures, it will be seen that
-the reed is in electric contact with the spring during about one-half
-its movement. The time of this connection is adjustable by the screw S.
-
-Synonym--Langdon Davies' Rate Governor or Phonophone.
-
-
-450   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ray, Electric. Raia torpedo.
-The torpedo, a fish having the same power of giving electric shocks as
-that possessed by the electric eel, q. v. (See also Animal Electricity.)
-
-
-Fig. 283. TORPEDO OR ELECTRIC RAY
-
-
-Reaction of Dynamo, Field and Armature.
-A principle of the dynamo current generator, discovered by Soren Hjorth
-of Denmark.
-
-When the armature is first rotated it moves in a field due to the
-residual magnetism of the field magnet core. This field is very weak,
-and a slight current only is produced. This passing in part or in whole
-through the field magnet cores slightly strengthens the field, whose
-increased strength reacts on the armature increasing its current, which
-again strengthens the field. In this way the current very soon reaches
-its full strength as due to its speed of rotation.
-
-The operation is sometimes termed building up.
-
-Sometimes, when there is but a trace of residual magnetism, it is very
-hard to start a dynamo.
-
-
-Reading Telescope.
-A telescope for reading the deflections of a reflecting galvanometer.
-
-A long horizontal scale is mounted at a distance from the galvanometer
-and directly below or above the centre of the scale a telescope is
-mounted. The telescope is so directed that the mirror of the
-galvanometer is in its field of view, and the relative positions of
-mirror, scale and telescope are such that the image of the scale in the
-galvanometer mirror is seen by the observer looking through the
-telescope.
-
-Under these conditions it is obvious that the graduation of the scale
-reflected by the mirror corresponds to the deflection of the
-galvanometer needle.
-
-The scale may be straight or curved, with the galvanometer in the latter
-case, at its centre of curvature.
-
-
-Reamur Scale.
-A thermometer scale in use in some countries of Continental Europe. The
-temperature of melting ice is 0�; the temperature of condensing steam
-is 80�; the degrees are all equal in length. For conversion to
-centigrade degrees multiply degrees Reamur by 5/4. For conversion to
-Fahrenheit degrees multiply by 9/4 and add 32 if above 0� R., and if
-below subtract 32. Its symbol is R., as 10� R.
-
-
-451   STANDARD ELECTRICAL DICTIONARY.
-
-
-Recalescence.
-A phenomenon occurring during the cooling of a mass of steel, when it
-suddenly emits heat and grows more luminous for an instant. It is a
-phase of latent heat, and marks apparently the transition from a
-non-magnetizable to a magnetiz  able condition.
-
-
-Receiver.
-In telephony and telegraphy, an instrument for receiving a message as
-distinguished from one used for sending or transmitting one.
-
-Thus the Bell telephone applied to the ear is a receiver, while the
-microphone which is spoken into or against is the transmitter.
-
-
-Receiver, Harmonic.
-A receiver including an electro-magnet whose armature is an elastic
-steel reed, vibrating to a particular note. Such a reed responds to a
-series of impulses succeeding each other with the exact frequency of its
-own natural vibrations, and does not respond to any other rapid series
-of impulses. (See Telegraph Harmonic.)
-
-
-Reciprocal.
-The reciprocal of a number is the quotient obtained by dividing one by
-the number. Thus the reciprocal of 8 is 1/8.
-
-Applied to fractions the above operation is carried out by simply
-inverting the fraction. Thus the reciprocal of 3/4 is 4/3 or 1-1/3.
-
-
-Record, Telephone.
-Attempts have been made to produce a record from the vibrations of a
-telephone disc, which could be interpreted by phonograph or otherwise.
-
-
-Fig. 284. MORSE RECORDER OR EMBOSSER.
-
-
-452   STANDARD ELECTRICAL DICTIONARY.
-
-
-Recorder, Morse.
-A telegraphic receiving apparatus for recording on a strip of paper the
-dots and lines forming Morse characters as received over a telegraph
-line. Its general features are as follows:
-
-A riband or strip of paper is drawn over a roller which is slightly
-indented around its centre. A stylus or blunt point carried by a
-vibrating arm nearly touches the paper. The arm normally is motionless
-and makes no mark on the paper. An armature is carried by the arm and an
-electro-magnet faces the armature. When a current is passed through the
-magnet the armature is attracted and the stylus is forced against the
-paper, depressing it into the groove, thus producing a mark. When the
-current ceases the stylus is drawn back by a spring.
-
-
-Fig. 285. INKING ROLLER MECHANISM OF MORSE RECORDER.
-
-
-In some instruments a small inking roller takes the place of the stylus,
-and the roller is smooth. The cut, Fig. 285, shows the plan view of the
-ink-roller mechanism. J is the roller, L is the ink well, Cl is the arm
-by which it is raised or lowered by the electro-magnet, as in the
-embosser. S S is the frame of the instrument, and B the arbor to which
-the arm carrying the armature is secured, projecting to the right. A
-spring is arranged to rub against the edge of the inking roller and
-remove the ink from it.
-
-The paper is fed through the apparatus by clockwork. At the present day
-sound reading has almost entirely replaced the sight reading of the
-recorder.
-
-
-Recorder, Siphon.
-A recording apparatus in which the inked marks are made on a strip of
-paper, the ink being supplied by a siphon terminating in a capillary
-orifice.
-
-In the cut N S represents the poles of a powerful electro-magnet. A
-rectangular coil bb of wire is suspended between the coils. A stationary
-iron core a intensifies the field. The suspension wire f f 1 has its
-tension adjusted at h. This wire acts as conductor for the current.
-
-
-453   STANDARD ELECTRICAL DICTIONARY.
-
-
-The current is sent in one or the other direction or is cut off in
-practice to produce the desired oscillations of the coil b b. A glass
-siphon n l works upon a vertical axis l. One end l is immersed in an ink
-well m. Its longer end n touches a riband of paper o o. The thread k
-attached to one side of the coil pulls the siphon back and forth
-according to the direction of current going through the electro-magnet
-cores. A spiral spring adjusted by a hand-screw controls the siphon. In
-operation the siphon is drawn back and forth producing a zigzag line.
-The upward marks represent dots, the downward ones dashes. Thus the
-Telegraphic Code can be transmitted on it. To cause the ink to issue
-properly, electrification by a static machine has been used, when the
-stylus does not actually touch the paper, but the ink is ejected in a
-series of dots.
-
-
-Fig. 286. SIPHON RECORDER.
-
-
-Reducteur for Ammeter.
-A resistance arranged as a shunt to diminish the total current passing
-through an ammeter. It is analogous to a galvanometer shunt. (See
-Multiplying Power of Shunt.)
-
-
-Reducteur for Voltmeter.
-A resistance coil connected in series with a Voltmeter to diminish the
-current passing through it. Its resistance being known in terms of the
-resistance of the voltmeter it increases the range of the instrument so
-that its readings may cover double or more than double their normal
-range.
-
-
-Reduction of Ores, Electric.
-Treatment of ores by the electric furnace (see Furnace, Electric.) The
-ore mixed with carbon and flux is melted by the combined arc and
-incandescent effects of the current and the metal separates. In another
-type the metal is brought into a fusible compound which is electrolyzed
-while fused in a crucible. Finally processes in which a solution of a
-salt of the metal is obtained, from which the metal is obtained by
-electrolysis, may be included. Aluminum is the metal to whose extraction
-the first described processes are applied.
-
-
-454   STANDARD ELECTRICAL DICTIONARY.
-
-
-Refraction, Electric Double.
-Double refraction induced in some materials by the action of either an
-electrostatic, magnetic or an electro-magnetic field.
-
-The intensity or degree of refracting power is proportional to the
-square of the strength of field.
-
-
-Refreshing Action.
-In electro-therapeutics the restoration of strength or of nerve force by
-the use of voltaic alternatives, q. v.
-
-
-Region, Extra-polar.
-In electro-therapeutics the area or region of the body remote from the
-therapeutic electrode.
-
-
-Region, Polar.
-In electro-therapeutics the area or region of the body near the
-therapeutic electrode.
-
-
-Register, Electric.
-There are various kinds of electric registers, for registering the
-movements of watchmen and other service. Contact or press buttons may be
-distributed through a factory. Each one is connected so that when the
-circuit is closed thereby a mark is produced by the depression of a
-pencil upon a sheet or disc of paper by electro-magnetic mechanism. The
-paper is moved by clockwork, and is graduated into hours. For each
-push-button a special mark may be made on the paper. The watchman is
-required to press the button at specified times. This indicates his
-movements on the paper, and acts as a time detector to show whether he
-has been attending to his duty.
-
-
-Register, Telegraphic.
-A term often applied to telegraph recorders, instruments for producing
-on paper the characters of the Morse or other alphabet.
-
-
-Regulation, Constant Current.
-The regulation of a dynamo so that it shall give a constant current
-against any resistance in the outer circuits, within practical limits.
-It is carried out in direct current machines generally by independent
-regulators embodying a controlling coil with plunger or some equivalent
-electro-magnetic device inserted in the main circuit and necessarily of
-low resistance. In some regulators the work of moving the regulator is
-executed mechanically, but under electrical control; in others the
-entire work is done by the current.
-
-A typical regulator or governor (Golden's) of the first class comprises
-two driven friction wheels between which is a driving friction wheel,
-which can engage with one driven wheel only at once. It is brought into
-engagement with one or the other by a solenoid and plunger.
-
-
-455   STANDARD ELECTRICAL DICTIONARY.
-
-
-As it touches one wheel it turns it in one direction. This moves a
-sliding contact in one direction so as to increase a resistance. This
-corresponds to a motion of the plunger in one direction. As the driving
-wheel moves in the opposite direction by a reverse action it diminishes
-the resistance. Thus the increase and decrease of resistance correspond
-to opposite movements of the solenoid plunger, and consequently to
-opposite variations in the current. The whole is so adjusted that the
-variations in resistance maintain a constant amperage. The resistance is
-in the exciting circuit of the dynamo.
-
-In Brush's regulator, which is purely mechanical, a series dynamo is
-made to give a constant current by introducing across the field magnets
-a shunt of variable resistance, whose resistance is changed by an
-electro-magnet, whose coils are in circuit with the main current. Carbon
-resistance discs are used which the electro-magnet by its attraction for
-its armature, presses with varying intensity. This alters the
-resistance, decreasing it as the current increases and the reverse. As
-the connection is in shunt this action goes to maintain a constant
-current.
-
-
-Regulation, Constant Potential.
-The regulation of constant potential dynamos is executed on the same
-lines as that of constant current dynamos. If done by a controlling
-coil, it must for constant potential regulation be wound with fine wire
-and connected as a shunt for some part of the machine.
-
-
-Regulation of Dynamos.
-The regulation of dynamos so that they shall maintain a constant
-potential difference in the leads of their circuit for multiple arc
-systems or shall deliver a constant current in series systems. Hence two
-different systems of regulation are required, (a) constant potential
-regulation--(b) constant current regulation. The first named is by far
-the more important, as it concerns multiple arc lighting, which is the
-system universally used for incandescent lighting.
-
-S. P. Thompson thus summarizes the methods of governing or regulating
-dynamos. Premising that alteration of the magnetic flux is the almost
-universal way of control, it can be done in two ways; first, by varying
-the excitation or ampere turns of the field, and second by varying the
-reluctance of the magnetic circuit. The excitation or magnetic flux may
-be varied
-
-(a) by hand, with the aid of rheostats and commutators in the exciting
-circuit;
-
-(b) automatically, by governors, taking the place of the hand;
-
-(c) by compound windings. The magnetic circuit may have its reluctance
-caused to vary in several ways;
-
-(d) by moving the pole pieces nearer to or further from the armature;
-
-(e) by opening or closing some gap in the magnetic circuit (field-magnet
-core);
-
-(f) by drawing the armature endways from between the pole pieces;
-
-(g) by shunting some of the magnetic lines away from the armature by a
-magnetic shunt.
-
-The latter magnetic circuit methods d, e, f, and g, have never met with
-much success except on small machines or motors. Method e is adopted in
-the Edison motor, the yoke being withdrawn or brought nearer the cores
-of the coils. (See Regulation, Constant Current-Regulation, constant
-Potential.)
-
-
-456   STANDARD ELECTRICAL DICTIONARY.
-
-
-Reguline. adj.
-Having the characteristics of a piece of metal, being flexible,
-adherent, continuous, and coherent. Applied to electrolytic deposits.
-
-
-Relative.
-Indicating the relation between two or more things without reference to
-absolute value of any one of them. Thus one lamp may be of relatively
-double resistance compared to another, but this states nothing of the
-resistance in ohms of either lamp.
-
-
-Relay.
-A receiving instrument which moves in accordance with impulses of
-currents received, and in so moving opens and closes a local circuit,
-which circuit may include as powerful a battery as required or
-desirable, while the relay may be on the other hand so delicate as to
-work with a very weak current.
-
-
-Fig. 287. RELAY.
-
-
-The typical relay includes an electro-magnet and armature. To the latter
-an arm is attached and the lower end of the arm works in pivots. As the
-armature is attracted the arm swings towards the magnet. When the
-current is cut off, the armature and arm are drawn back by a spring.
-When the arm swings towards the magnet its upper end touching a contact
-screw closes the local circuit. When it swings back it comes in contact
-with a second screw, with insulated point, and opens the circuit as it
-leaves the first named screw.
-
-One terminal connects with the arm through the pivots and frame. The
-other connects with the contact screw through the frame carrying it.
-
-Synonym--Relay Magnet.
-
-
-457   STANDARD ELECTRICAL DICTIONARY.
-
-
-Relay Bells.
-Bells connected by relay connection to a main line for acoustic
-telegraphy. A stroke on one bell indicates a dot and on the other a
-dash. The system is now nearly extinct.
-
-
-Relay, Box-sounding.
-A relay which is surrounded by or mounted on a resonator or wooden box
-of such proportions and size as to reinforce the sound. This enables a
-relay to act as a sounder, its weak sounds being virtually magnified so
-as to be audible.
-
-
-Relay Connection.
-A connection used in telegraphy, including a local battery, with a short
-circuit normally open, but closed by a switch and a sounder or other
-appliance. The latter is made very sensitive so as to be worked by a
-feeble current, and is connected to the main line. A very slight current
-closes the switch and the local battery comes into operation to work a
-sounder, etc. When the current ceases on the main line the switch opens
-and throws the local battery out of action. The switch is termed a
-relay, q. v. A long main line may thus produce strong effects at distant
-stations, the intensity of action depending on the local battery.
-
-
-Fig. 288. RELAY OR LOCAL CIRCUIT.
-
-
-Relay, Differential.
-A relay containing two coils wound differentially, and of the same
-number of turns and resistance. If two equal currents pass through the
-coils they counteract each other and no action takes place. If there is
-a difference in the currents the relay acts as one coil preponderates.
-The coils may be wound for uneven currents with different resistance and
-number of turns.
-
-
-Relay, Microphone.
-A relay connection applied to a telephone circuit. It consists of a
-microphone mounted in front of the diaphragm of a telephone receiver. In
-circuit with the microphone is a battery and second telephone receiver.
-The microphone is supposed to intensify the sounds of the first
-telephone.
-
-
-458   STANDARD ELECTRICAL DICTIONARY.
-
-
-Relay, Polarized.
-A relay whose armature is of steel, and polarized or permanently
-magnetized, or in which a permanent magnet is used as the basis for the
-electro-magnets. In the relay shown in the cut the coils shown are
-mounted on cores carried on the end of a powerful bent permanent magnet.
-Thus when no current passes their upper poles are both of the same sign,
-and the horizontally vibrating tongue is held by the magnetic attraction
-against one or the other pole piece. If a current is sent through the
-electro-magnet it gives opposite polarity to the two polar extensions.
-As the end of the vibrating tongue is of polarity determined by the
-permanent magnet it is attracted to one pole and  repelled from the
-other. On cessation of current it remains attached by the permanent
-magnetism. If now a current is sent in the opposite direction the two
-poles again acquire opposite polarity, the reverse of the former, and
-the tongue flies across to the opposite side. On cessation of current it
-remains attached as before by the permanent magnetism.
-
-In its movements to and fro the relay tongue opens and closes a contact,
-so as to work a sounder or other apparatus. The polarized relay is of
-high sensibility, and requires little or no change of adjustment.
-
-
-Fig. 288. POLARIZED RELAY
-
-
-Reluctance.
-In a magnetic circuit or portion thereof, the resistance offered to the
-flow of lines of force. The magnetic circuit as has already been stated
-is treated like an electric circuit, and in it reluctance occupies the
-place of resistance in the electric circuit. It is the reciprocal of
-permeance. S. P. Thompson expresses the law thus:
-
-Total number of magnetic lines = (magneto-motive force) / (magnetic
-reluctance)
-
-Synonyms--Magnetic Reluctance-Magnetic Resistance.
-
-
-Reluctance, Unit of.
-The reluctance of a circuit through which unit magnetizing power
-(magneto-motive force) can produce a unit of induction or one line of
-force. This value is very high; the reluctance of ordinary magnetic
-circuits ranges from 1E-5 to 1E-8 unit of reluctance.
-
-
-Reluctivity.
-Specific reluctance; the reluctance of a cube of material whose edge
-measures one centimeter in length. It is a quality bearing the same
-relation to reluctance that permeability does to permeance.
-
-It is defined as the reciprocal of magnetic permeability. (Kenelly.) If
-plotted as a curve for different values of the magnetizing force it is
-found to be nearly a straight line, a linear function of the magnetizing
-force, H with the equation a + b H. Reluctivity is the property of a
-substance; reluctance is the property of a circuit.
-
-
-459   STANDARD ELECTRICAL DICTIONARY.
-
-
-Remanence.
-The residual magnetism left after magnetic induction, expressed in lines
-of force per square centimeter.
-
-
-Repeater.
-In telegraphy an instrument for repeating the signals through a second
-line. It is virtually a relay which is operated by the sender, and which
-in turn operates the rest of the main line, being situated itself at
-about the middle point of the distance covered. In the simpler forms of
-repeater two relays are used, one for transmission in one direction the
-other for transmission in the other. An attendant switches one or the
-other in as required.
-
-Thus a common relay is virtually a repeater for its local circuit. If
-such a relay is placed half way down a line, and if the line beyond it
-is connected as its local, it becomes a repeater.
-
-Some forms of repeaters are automatic, and repeat both ways without the
-need of an attendant.
-
-It is the practice to somewhat prolong the signals sent through a
-repeater.
-
-
-Replenisher, Sir William Thomson's.
-A static accumulating influence machine contained in Thomson's quadrant
-electrometer and used to change the quadrants. The cut shows the
-horizontal section and construction of the apparatus.
-
-It contains two gilt brass inductors A B, and two eccentric sectors or
-carriers, C, D, which are mounted on an ebonite spindle, which is spun
-around by the fingers. The springs s s1 connect each with its inductor;
-the springs S S1 connect only each other, and touch the sectors as they
-turn around.
-
-One of the inductors may be always assumed to be of slightly higher
-potential than that of the other one. When the carriers are in contact
-with the springs S S1 they are each charged by induction with
-electricity opposite in sign to that of the nearest quadrant. As they
-leave the springs S S1 in their rotation, they next touch the springs s
-s1, but of the recently opposite inductor. They share each a portion of
-its charge with the inductors building up their charges. The action is
-repeated over and over again as they rotate.
-
-
-Fig. 290. THOMSON'S REPLENISHER.
-
-
-460   STANDARD ELECTRICAL DICTIONARY.
-
-
-Reservoir, Common.
-A term applied to the earth, because all electrified bodies discharge
-into it if connected thereto.
-
-
-Fig. 289. DIAGRAM OF THOMSON'S REPLENISHER.
-
-
-Residual Atmosphere.
-The air left in a receiver after exhaustion by an air pump. The
-quantity, where good air pumps are used, is very minute.
-
-
-Residue, Electric.
-The residual charge of a condenser. (See Charge, Residual.)
-
-
-Resin.
-(a) The product obtained by non-destructive distillation of the juice of
-the pitch pine. It is the solid residue left after the turpentine has
-been evaporated or distilled. It is a mixture of abietic acid C44 H64 O5
-and pinic acid C20 H30 O2. It is an insulator; its specific inductive
-capacity is 2.55. (Baltzmann.)
-
-Synonyms--Colophony--Rosin.
-
-(b) The name is also generally applied to similar substances obtained
-from the sap of other trees; thus shellac is a resin. The resins are a
-family of vegetable products; the solid portions of the sap of certain
-trees. Common resin, lac, dragons blood, are examples. They are all
-dielectrics and sources of resinous or negative electricity when rubbed
-with cotton, flannel, or silk. (See Electrostatic Series.)
-
-
-461   STANDARD ELECTRICAL DICTIONARY.
-
-
-Resinous Electricity.
-Negative electricity; the electricity produced upon the surface of a
-resinous body by rubbing it; such a body is shellac or sealing wax;
-flannel and other substances may be used as the rubbing material. (See
-Electrostatic Series.)
-
-
-Resistance.
-(a) The quality of an electric conductor, in virtue of which it opposes
-the passage of an electric current, causing the disappearance of
-electro-motive force if a current passes through it, and converting
-electric energy into heat energy in the passage of a current through it.
-If a current passes through a conductor of uniform resistance there is a
-uniform fall of potential all along its length. If of uneven resistance
-the fall in potential varies with the resistance. (See Potential, Fall
-of.)
-
-The fall of potential is thus expressed by Daniell. "In a conductor, say
-a wire, along which a current is steadily and uniformly passing, there
-is no internal accumulation of electricity, no density of internal
-distribution; there is, on the other hand, an unequally distributed
-charge of electricity on the surface of the wire, which results in a
-potential diminishing within the wire from one end of the wire to the
-other."
-
-Resistance varies inversely with the cross section of a cylindrical or
-prismatic conductor, in general with the average cross-section of any
-conductor, and in the same sense directly with its true or average or
-virtual length. It varies for different substances, and for different
-conditions as of temperature and pressure for the same substance. A rise
-of temperature in metals increases the resistance, in some bad
-conductors a rise of temperature decreases the resistance.
-
-
-462   STANDARD ELECTRICAL DICTIONARY.
-
-
-Approximately, with the exception of iron and mercury, the resistance of
-a metallic conductor varies with the absolute temperature. This is very
-roughly approximate.
-
-Except for resistance energy would not be expended in maintaining a
-current through a circuit. The resistance of a conductor may be supposed
-to have its seat and cause in the jumps from molecule to molecule, which
-the current has to take in going through it. If so a current confined to
-a molecule would, if once started, persist because there would be no
-resistance in a molecule. Hence on this theory the Amp�rian currents
-(see Magnetism, Ampere's Theory of) would require no energy for their
-maintenance and Amp�re's theory would become a possible truth.
-
-When metals melt their resistance suddenly increases.
-
-Light rays falling on some substances, notably selenium, q. v., vary the
-resistance.
-
-Longitudinal stretching of a conductor decreases it, it increases with
-longitudinal compression, and increases in iron and diminishes in tin
-and zinc when a transverse stress tends to widen the conductor.
-
-(b) The term resistance is used to express any object or conductor used
-in circuit to develop resistance.
-
-[Transcriber's note: At room temperatures, the thermal motion of ions in
-the conductor's crystal lattice scatters the electrons of the current.
-Imperfections of the lattice contribute slightly. At low temperatures
-superconductivity (zero resistance) can occur because an energy gap
-between the electrons and the crystal lattice prevents any interaction.
-At the time of this book, none of this was known. "Jumps from molecule
-to molecule" is a good guess.]
-
-
-Resistance, Apparent.
-Impedance; the virtual resistance of a circuit including the spurious
-resistance due to counter-electromotive force. It may be made up of true
-resistance and partly of an inductive reaction, as it represents the net
-factor, the entire obstruction to the passage of a current, and not
-merely a superadded resistance or counter-electro-motive force.
-
-Synonym--Impedance.
-
-[Transcriber's note: Impedance can also have a component due to
-capacitance.]
-
-
-Resistance, Asymmetrical.
-Resistance which varies in amount in different directions through a
-conductor. It implies a compound or composite conductor such as the
-human system. The presence of counter-electro-motive force in different
-parts of a conductor may bring about asymmetrical resistance.
-
-
-Resistance, B. A. Unit of.
-The British Association Ohm. (See Ohm, B. A.)
-
-
-463   STANDARD ELECTRICAL DICTIONARY.
-
-
-Resistance Box.
-A box filled with resistance coils. The coils are connected in series so
-that a circuit including any given number has their aggregate resistance
-added to its own. The terminals of consecutive coils are connected to
-short blocks of brass which are secured to the top of the box, lying
-flatwise upon it, nearly but not quite in contact with each other. Plugs
-of brass are supplied which can go in between pairs of blocks, which
-have a pair of grooves reamed out to receive them. Such plugs short
-circuit the coil below them when in position. The cut shows how such
-coils are connected and the use of plugs to short circuit them. The
-diagram shows the top of a Wheatstone bridge, q. v., resistance box with
-connections for determining resistances.
-
-
-Fig. 291. RESISTANCE BOX.
-
-
-Resistance Box, Sliding.
-A resistance box whose coils are set in a circle. Two metal arms with
-handles are pivoted at the centre of the circle and by moving them
-around they make and break contacts so as to throw the coils in and out
-of circuit. The object is to permit an operator to adjust resistance
-without looking at the box--an essential in duplex telegraphy.
-
-
-Resistance, Breguet Unit of.
-The same in origin as the Digney Unit. (See Resistance, Digney Unit of.)
-
-It is equal to 9.652 Legal Ohms.
-
-
-Resistance, Carbon.
-A resistance, a substitute for a resistance coil; it is made of carbon,
-and is of various construction. In the Brush dynamo regulator a set of
-four vertical piles of plates of retort carbon, q. v., is used as a
-resistance, whose resistance is made to vary by changing the pressure.
-This pressure automatically increases as the current strength increases,
-thus reducing the resistance.
-
-
-464   STANDARD ELECTRICAL DICTIONARY.
-
-
-Resistance Coil, Standard.
-A standard or resistance issued by the Electric Standard Committee of
-Great Britain. The cut shows the standard ohm. It is formed either of
-German silver, or of an alloy of silver, 66.6 per cent. and platinum,
-33.4 per cent. The wire is insulated and doubled before winding as
-described before. (See Coil, Resistance.) The two ends of the wire are
-soldered, each one to a heavy copper wire or rod r. The whole coil is
-enclosed in a brass case, and is enclosed with paraffine melted in at A.
-A place for a thermometer is provided at t. By immersing the lower part
-of the case B in water of different degrees of heat any desired
-temperature can be attained.
-
-
-Fig. 292. STANDARD OHM COIL.
-
-
-Resistance, Combined.
-The actual resistance of several parallel conductors starting from the
-same point and ending at the same point. If the individual resistance be
-a b c d .. and the combined resistance be x then we   have
-x = 1 / (( 1/a)  + (1/b) + (1/c) + (1/d) + �)
-
-Synonym--Joint Resistance.
-
-
-Resistance, Critical.
-In a series wound dynamo the resistance of the outer circuit above which
-the machine will refuse to excite itself.
-
-
-Resistance, Dielectric.
-The mechanical resistance of a dielectric to the tendency to perforation
-or to the strains due to electrification. This is a phase of mechanical
-resistance, and is distinct from the electrical or ohmic resistance of
-the same substance.
-
-
-Resistance, Digney Unit of.
-The resistance of an iron wire, 1 kilometer long, 4 millimeters
-diameter, temperature unknown.
-
-It is equal to 9.163 legal ohms.
-
-
-Resistance, Electrolytic.
-The resistance of an electrolyte to the passage of a current decomposing
-it. It is almost entirely due to electrolysis and is added to by
-counter- electro-motive force, yet it is not treated specifically as
-such, but as an actual resistance. When a current of a circuit of too
-low voltage to decompose an electrolyte is caused by way of immersed
-terminals to pass through an electrolyte the resistance appears very
-high and sometimes almost infinite. If the voltage is increased until
-the electrolyte is decomposed the resistance suddenly drops, and what
-should be termed electrolytic resistance, far lower than the true
-resistance, appears.
-
-
-465   STANDARD ELECTRICAL DICTIONARY.
-
-
-Resistance, English Absolute or Foot-Second Unit of.
-A unit based on the foot and second. It is equal to (( foot / second ) *
-1E7) , being based on these dimensions.
-
-It is equal to 0.30140 legal ohm.
-
-
-Resistance, Equivalent.
-A resistance equivalent to other resistances, which may include
-counter-electro-motive force.
-
-
-Resistance, Essential.
-The resistance of the generator in an electric circuit; the same as
-internal resistance.
-
-
-Resistance, External.
-In an electric circuit the resistance of the circuit outside of the
-generator, or battery.
-
-Synonym--Non-essential Resistance.
-
-
-Fig. 293. RESISTANCE FRAME.
-
-
-Resistance Frame.
-An open frame filled with resistance coils of iron, or German silver
-wire. It is used as a resistance for dynamos and the larger or working
-class of plant. The coils are sometimes connected so that by a switch
-moving over a row of studs one or more can be thrown into series
-according to the stud the switch is in contact with.
-
-
-Resistance, German Mile Unit of.
-The resistance of 8,238 yards of iron wire 1/6 inch in diameter. It is
-equal to 56.81 legal ohms.
-
-
-466   STANDARD ELECTRICAL DICTIONARY.
-
-
-Resistance, Hittorf's.
-A high resistance, often a megohm, composed of Hittorf's solution, q. v.
-It is contained in a vertical glass tube near whose upper and lower ends
-are electrodes of metallic cadmium attached to platinum wires. The
-cadmium is melted in glass tubes, the platinum wire is inserted into the
-melted metal and the tube is broken after all is solid. The resistance
-should show no polarization current.
-
-
-Fig. 294. HITTORF'S RESISTANCE
-
-
-Resistance, Inductive.
-A resistance in which self-induction is present; such as a coil of
-insulated wire wound around an iron core.
-
-
-Resistance, Insulation.
-The resistance of the insulation of an insulated conductor. It is stated
-in ohms per mile. It is determined by immersing a section of the line in
-water and measuring the resistance between its conductor and the water.
-The section must be of known length, and its ends must both be above the
-liquid.
-
-
-Resistance, Internal.
-The resistance of a battery, or generator in an electric circuit as
-distinguished from the resistance of the rest of the circuit, or the
-external resistance.
-
-Synonym--Essential Resistance.
-
-
-Resistance, Jacobi's Unit of.
-The resistance of a certain copper wire 25 feet long and weighing 345
-grains.
-
-It is equal to 0.6296 legal ohm.
-
-
-Resistance, Matthiessen's Meter-gram Standard.
-The resistance of a pure hard drawn copper wire of such diameter that
-one meter of it weighs one gram. It is equal to .1434 Legal Ohms at 0�
-C. (32� F.)
-
-
-Resistance, Matthiessen's Unit of.
-The resistance of a standard mile of pure annealed copper wire 1/16 inch
-diameter, at a temperature of 15.5� C. (60� F.).
-
-It is equal to 13.44 legal ohms.
-
-
-467   STANDARD ELECTRICAL DICTIONARY.
-
-
-Resistance, Meter-millimeter Unit of.
-The resistance of a wire of copper one meter long and one square
-millimeter in section. It is equal to .02057 ohms at 0� C. (32� F.) The
-term may also be applied to the resistance of similar sized wire of
-other metals.
-
-
-Resistance, Mil-foot Unit of.
-The resistance of a foot of copper wire one-thousandth of an inch in
-diameter. It is equal to 9.831 ohms at 0� C. (32� F.) The term may also
-be applied to the resistance of similar sized wire of other metals.
-
-
-Resistance, Non-essential.
-The resistance of the portion of an electric circuit not within the
-generator; the same as external resistance.
-
-Synonym--External Resistance.
-
-
-Resistance, Non-inductive.
-A resistance with comparatively little or negligible self-induction.
-
-Resistance of Human Body.
-The resistance of the human body is largely a matter of perfection of
-the contacts between its surface and the electrodes. It has been
-asserted that it is affected by disease. From 350 to 8,000 ohms have
-been determined as resistances, but so much depends on the contacts that
-little value attaches to the results.
-
-
-Resistance, Ohmic.
-True resistance measured in ohms as distinguished from
-counter-electro-motive force, q. v. The latter is called often spurious
-resistance.
-
-Synonym--True Resistance.
-
-[Transcriber's note: "True" vs. "spurious" are interesting terms,
-considering that today we define impedance as a combination of "real"
-resistance and "imaginary" capacitive and inductive reactance.]
-
-
-Resistance, Reduced.
-The resistance of a conductor reduced to ohms, or to equivalent lengths
-of a column of mercury, 1 square millimeter in cross area.
-
-
-Resistance, Siemen's Unit of.
-The resistance of a column of mercury 1 meter long and 1 square
-millimeter cross-sectional area at 0� C. (32� F.)
-
-It is equal to .9431 legal ohm.
-
-
-Resistance, Specific.
-The relative resistance of a substance. It is expressed as the actual
-resistance of a cube of the substance which is one centimeter on each
-edge. For metals it is usually expressed in microhms, for liquids in
-ohms.
-
-The resistances of a specified length of wire of specified diameter of
-different substances is often given, and is really a particular way of
-stating specific resistances.
-
-Synonym--Specific Conduction Resistance.
-
-
-Resistance, Spurious.
-The counter-electro-motive force, q. v., operating to prevent a current
-being produced of what should be its full strength were the true
-resistance and actuating electro-motive force only concerned. Such
-counter-electro-motive force may be treated as a spurious resistance and
-such a value in ohms assigned to it as would correspond to its proper
-effect.
-
-
-468   STANDARD ELECTRICAL DICTIONARY.
-
-
-In its effect on opposing a current and in resisting its formation it
-differs from true resistance. The latter in diminishing current strength
-absorbs energy and develops heat; spurious resistance opposes and
-diminishes a current without absorption of energy or production of heat.
-
-[Transcriber's note: "Spurious resistance" is now called reactance,
-consisting of capacitive reactance and inductive reactance. The
-combination of reactance and (Ohmic/true) resistance is called
-impedance. The calculation of impedance requires complex algebra, not
-just real values used in DC circuit analysis.]
-
-
-Resistance, Steadying.
-When arc lamps are connected in parallel or multiple arc a small
-resistance coil is sometimes placed in series with each lamp for
-steadying purposes. It reduces the percentage of variation of resistance
-in each lamp, which may be caused by a change in the position of the
-carbons.
-
-
-Resistance, Swiss Unit of.
-A unit constructed by the "Administration Suisse," based on the same
-data as the Breguet and the Digney Units. (See Resistance, Digney Unit
-of)
-
-It is equal to 10.30 legal ohms.
-
-
-Resistance, Thomson's Unit of.
-A unit of resistance based on the foot and second.
-
-It is equal to 0.3166 legal ohm.
-
-
-Resistance, Unit.
-Unit resistance is that of a conductor in which unit current is produced
-by unit electro-motive force.
-
-
-Resistance, Varley's Unit of.
-The resistance of a standard mile of a special copper wire 1/16 inch
-diameter.
-
-It is equal to 25.33 ohms.
-
-
-Resistance, Weber's Absolute Unit.
-A metric system unit; (meter / second) * 1E7
-
-It is equal to 0.9089 legal ohm.
-
-
-Resonance, Electric.
-A set of phenomena known as the Hertz experiments are grouped under this
-title, which phenomena are incidents of and depend on the propagation of
-electric waves through wires or current conductors, as well as through
-the ether. Ordinarily a wire is only a seat of current, and is in its
-nature inconsistent with wave propagation through its mass. Such waves
-are virtually confined to the exterior of the wire. The point is that
-the current-producing force is supposed to enter the wire at all points
-from without, the current not being produced by an end-push. Hence in
-rapidly recurring waves which are produced by a rapidly pulsatory or
-alternating current, no time is afforded for the current-producing
-force, in this case the wave-producing force, to penetrate into the
-substance of the wire. In one of his experiments Dr. Hertz surrounded a
-wire by a glass tube chemically silvered. The coating was so thin as to
-be translucent. Through this metallic layer a current could be induced
-in the wire in its interior. Any mechanical layer of metal took up the
-induction itself, and protected the central wire. This gave a clue to
-the thickness of metal penetrated by the rapid induced waves used by Dr.
-Hertz.
-
-
-469   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 295. ELECTRICAL RESONANCE EXCITER.
-
-
-The method used for the production of rapid oscillations is the
-following. To the terminals of an induction coil two metal spheres AA1
-are connected as shown. This apparatus is termed the exciter; in its
-discharge a series of isochronous discharges takes place, alternating in
-direction. The period of duration T of a single one is given by the
-formula T= 2* PI * squareRoot( LC ),  in which C is the capacity and L
-is the self-induction. The spheres may be 30 centimeters (11.8 inches)
-in diameter, connected each to conductors 0.5 centimeter (.2 inch) in
-diameter and 40 centimeters (15.7 inches) long each. For the length of
-an undulation the formula gives for this apparatus 4.8 meters (15.75
-feet) as the length of a wave, assuming for them the velocity of
-propagation equal to that of light. The exciter may have 10,000 times
-the rate of oscillation possessed by the plain induction coil.
-
-When this apparatus is worked it produces induced waves in every
-neighboring conductor. The resonance effects appear in the size of the
-spark induced. Thus a wire bent into a circle with its ends nearly
-touching will give a spark, but if made of proper electrostatic
-capacity, corresponding with the particular waves employed, the spark
-will be very much larger. The ring, with its spark gap is termed a
-resonator. It is used as an explorer to trace the waves.
-
-Waves thus produced are transmitted by stone walls and nonconductors in
-general. A plate of zinc reflects part and transmits part. The reflected
-waves can be traced by the resonator, their angle of reflection being
-equal to their angle of incidence. They can be received by one parabolic
-reflector, reflected to another and brought to a focus. They can be
-reflected so as to produce interference or loops and nodes, and the
-loops and nodes can be traced by the resonator. By a prism of asphalt
-they are refracted exactly like light.
-
-From all this it is concluded that an additional proof is furnished of
-the identity of light and electro-magnetic waves, and a very strong
-experimental proof of Maxwell's theory of light is furnished.
-
-Synonym--Hertz's Experiments.
-
-
-470   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 296. ELECTRICAL RESONATOR.
-
-
-Resonator, Electric.
-A small open electric circuit, with ends nearly touching. When exposed
-to electric resonance, or to a sympathetic electric oscillatory
-discharge, a spark passes from across the gap. The production of this
-spark is altogether a matter of the inductance of the resonator. The
-simplest form is a circle of copper wire with its ends nearly touching.
-The length of the gap is adjustable by bending. A screw adjustment may
-also be provided. Another form is shown in the cut, Fig. 296. Here
-sheets of tinfoil are used to regulate the electrostatic capacity, while
-at m is shown the finger piece for regulating the size of the spark gap
-a.
-
-Synonym--Spark Micrometer.
-
-
-Resultant.
-The line indicating the result of the application of two or more forces
-to a point. Its direction and length give the elements of direction and
-intensity. (See Forces, Resolution of Forces, Composition of
-Components.)
-
-
-Resultant Polarity.
-The magnetic polarity imparted to a mass of iron acted on by two or more
-separate inducing forces or currents. It appears in dynamos and motors.
-The final polarity is the resultant of the inducing effect of the field
-magnet poles and of the windings.
-
-
-Retardation.
-In telegraphy a retardation of the rate of transmission of signals. It
-is due to several causes.
-
-(a) The self-induction of the circuit, especially if it includes many
-electro-magnets, produces extra currents (see Currents, Extra.) These
-are opposed to the main current on closing it and hence retard the
-action. They are in the same direction on opening it and hence again
-retard the action.
-
-(b) Every line has a certain static capacity. This is affected by the
-proximity of the lines to the earth. For each signal electricity has to
-be charged upon the line until the line is charged to its end with a
-certain proportion of the initial density. This charging takes time and
-hence introduces retardation.
-
-(c) The cores of the electro-magnets of the relays or sounders are not
-instantly magnetized and demagnetized. This magnetic lag, q. v.,
-introduces retardation.
-
-
-471   STANDARD ELECTRICAL DICTIONARY.
-
-
-Retardation of Phase.
-The fractional lagging behind of waves or alternating currents; by
-lagging behind a portion of a wave length the corresponding phases, as
-of full amplitude, are kept back or retarded. The phase of current
-intensity may be retarded with reference to the electro-motive force by
-the introduction of transformers of high capacity with high resistance
-on open secondary circuits.
-
-[Transcriber's note: Capacitors are used to correct current phase lag.]
-
-
-Retentivity.
-Coercitive or coercive force; by virtue of which steel retains its
-magnetism. It is the more modern name, "coercive force" as a term being
-rejected by many.
-
-Synonyms--Coercive Force--Coercitive Force.
-
-
-Retort Carbon.
-Carbon deposited in coal gas retorts from decomposition of the
-hydrocarbons. It is a very hard, pure form, and is of graphitic
-modification. Owing to its great hardness it is little used for
-electrical purposes, the molded carbons being easier to make. The
-deposition occurs in the regular gas-making process, and is a
-disadvantage to the working.
-
-
-Return.
-A line or conductor which is supposed to carry current back to its
-starting point, after it has traversed a line. It may be a wire or the
-grounding of the ends of a line [or] may make the earth act as a return,
-termed ground- or earth-return. The best distinction of a return is to
-so term the portion of a circuit on which no apparatus is placed.
-
-
-Reversibility.
-The principal in virtue of which a device for producing a given form of
-energy can absorb the same and do work. The reversibility of the dynamo
-is its quality in virtue of which it can act as a current generator,
-thereby converting mechanical energy into electric energy, or if a
-current is passed through it, it rotates, doing work, and thereby
-converting electric energy into mechanical energy. The knowledge of this
-principle can be traced back to Jacobi in 1850.
-
-
-Reversible Bridge.
-A form of Wheatstone's Bridge adapted for reversal of the positions or
-interchange of the proportionate arms, v., so that the accuracy of the
-coils can be tested.
-
-
-Rheochord.
-An apparatus by means of which variable quantities of wire are thrown
-into the circuit; a rheostat using wire. (See Rheostat, Wheatstone's.)
-
-
-Rheometer.
-A galvanometer. (Obsolete.)
-
-
-472   STANDARD ELECTRICAL DICTIONARY.
-
-
-Rheomotor.
-A source of current; a current generator; a producer of potential
-difference. (Obsolete.)
-
-
-Rheophore.
-The portion of an active circuit capable of deflecting a magnetic
-needle. This properly includes all of the metallic conductor of a
-circuit. (Obsolete.)
-
-
-Rheoscope.
-A galvanoscope; an instrument for qualitatively detecting potential
-difference, fall or rise. (See Galvanoscope.)
-
-
-Rheostat.
-An adjustable resistance; an apparatus for changing the resistance
-without opening the circuit. Its action may depend on the introduction
-of variable lengths of mercury column, of some other liquid, or of wire
-into a circuit. (See Rheostat, Wheatstone's.)
-
-
-Rheostat Arm.
-The third arm of known resistance in a Wheatstone bridge. (See
-Proportionate Arms.)
-
-
-Rheostatic Machine.
-An apparatus for increasing potential difference. It consists of a
-number of static condensers. They are charged in multiple arc or in
-parallel, and are discharged in series. Secondary batteries may be used
-for the charging; thus a static effect is produced from a galvanic
-battery.
-
-
-Rheostat, Wheatstone's.
-This apparatus consists of two cylinders, one, A, made of brass, the
-other, B, of wood, with a spiral groove. At its end is a copper ring a.
-A fine brass wire has one end attached to this ring. Its other end is
-fastened at e, and it is wound as shown; n and o are binding screws
-connected, one with the cylinder-ring a, the other with the brass
-cylinder, A. The current entering at o, traverses the wire on B, as
-there the windings are insulated by the grooves, thence it passes to m
-and by A, whose metal short circuits all the wire on it, to the
-binding-post n. The handle, d, is turned one way or the other to
-regulate the length of the wire through which the current must pass. On
-each cylinder there is a square head, one of which is shown at c, so
-that the handle can be shifted from one to the other as required; to A
-if the wire is to be wound on that cylinder, to B if the reverse is
-desired.
-
-
-Fig. 297. WHEATSTONE'S RHEOSTAT.
-
-
-473   STANDARD ELECTRICAL DICTIONARY.
-
-
-Rheotome.
-An automatic circuit breaker, one which rapidly opens and closes a
-circuit, as in the case of the primary of an induction coil an
-interrupter. (Obsolete.)
-
-
-Rheotrope.
-A pole changer, current reverser, or commutator, g., such as the
-commutator of an induction coil. (Obsolete.)
-
-
-Rhigolene.
-A petroleum product; a hydrocarbon of low boiling point. Its vapor is
-used in flashing (q. v.) carbon filaments for incandescent lamps.
-
-
-Rhumbs.
-In a mariners' compass, the thirty-two points, designated, north, north
-by east, north north east, etc. (See Compass Mariner's-Compass, Points
-of the.)
-
-
-Rhumkorff Coil.
-The induction coil, q. v.
-
-
-Rigidity, Molecular.
-The tendency of molecules to resist rotation or change of position; the
-assumed cause of magnetic coercive force, or retentivity.
-
-
-Ring Contact.
-A contact formed by a terminal clip in the shape of a ring, split or cut
-at one point so that its ends tend to spring together. The other
-terminal is a bar which passes into the cut and is tightly pressed by
-the elastic ring.
-
-
-Fig. 298. SWITCH WITH RING CONTACTS.
-
-
-474   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ring, Faraday.
-A closed ring of iron used as the core of a transformer or induction
-coil. The term is derived from Faraday's classic experiment with such an
-apparatus when he produced a spark by induction in a secondary circuit.
-
-
-Roaring.
-A term applied to the noise sometimes produced in a voltaic arc, when
-the electrodes are close together and a heavy current is passing.
-
-
-Rocker.
-In a dynamo the movable piece, mounted concentrically with the
-commutator, and carrying the rocker-arms and brush-holders. By moving it
-the brushes are adjusted for proper lead.
-
-
-Rocker Arms.
-The arms projecting from a rocker and each carrying one of the
-brush-holders.
-
-
-Roget's Spiral.
-An experimental apparatus for illustrating the mutual attraction of
-currents going in like direction. A cylindrical helix or spiral of wire
-is suspended by one end. Its lower end just dips into a mercury cup. An
-active circuit is connected, one terminal to the upper end, the other
-terminal to the mercury cup, bringing the apparatus in series into the
-circuit. The current as it passes causes the coil to shorten, each
-spiral attracting its neighbors. This breaks the circuit by drawing the
-lower end out of the mercury cup. The current being cut off the coils
-cease to attract each other, and the end dips into the mercury cup
-again. This closes the circuit, the coils again attract each other and
-the same sequence follows and is repeated over and over again. A bright
-spark is produced at each break of the mercury contact.
-
-
-Rotation of Liquids, Electro-dynamic.
-By passing a current through a liquid, such as dilute sulphuric acid, it
-rotates if exposed to the induction of a current flowing at right angles
-to it. The condition resolves itself into a liquid traversed by
-horizontal currents from centre to circumference or vice versa, rotated
-by a current passing through a circular conductor below it.
-
-
-475   STANDARD ELECTRICAL DICTIONARY.
-
-
-Rotation of Liquids, Electro-magnetic.
-The rotation produced in a liquid carrying centripetal or centrifugal
-currents by an electromagnet. It is practically an intensification of
-electro-dynamic rotation. (See Rotation of Liquids, Electro-dynamic.)
-
-
-Rubber.
-In a frictional electric machine the cushion of leather which is pressed
-against the plate as it rotates.
-
-
-S.
-(a) Symbol for second.
-
-(b) Symbol for space, or length; L is preferable.
-
-(c) Symbol for south-seeking pole of a magnet.
-
-
-Saddle Bracket.
-A bracket carried on the top of telegraph poles, carrying an insulator
-for the upper wire.
-
-
-Safety Device.
-(a) A device to prevent overheating of any portion of a circuit by
-excess of current. It generally consists of a slip of fusible metal
-which if the current attains too much strength melts and opens the
-circuit. To ensure its breaking a weight is sometimes suspended from the
-strip. In one form an insulated German silver wire is wrapped around the
-end of the fusible strip a number of times and its end is connected to
-it. The other end of the German silver wire connects with the main lead,
-so that all the current goes through both in series. If the German
-silver wire becomes heated from excess of current the coil wrapped
-tightly around the end of the fusible strip melts it and opens the
-circuit.
-
-(b) Lightning arresters, q. v., may be cited under this heading.
-
-Synonyms--Automatic Cut Out--Safety Fuse, Plug, or Strip.
-
-
-Fig. 299. COCKBURN SAFETY FUSE.
-
-
-Safety Fuse.
-A strip of metal inserted so as to form part of a circuit and of such
-size that a smaller current [than] would heat the regular wire of the
-circuit dangerously, so as to cause a conflagration for instance, would
-melt the fuse and open the circuit. As it sometimes happens that a
-safety fuse melts without parting a weight is sometimes hung upon it, so
-as to break it as it softens.
-
-
-Salt.
-A salt is a chemical compound containing two atoms of two radicals,.
-which saturate each other. One atom or radical is electro-positive
-referred to the other, which is electro-negative. By electrolysis salts
-are decomposed, the atoms or radicals separating and uniting to form new
-molecules.
-
-
-476   STANDARD ELECTRICAL DICTIONARY.
-
-
-Saturated. adj.
-A liquid is saturated with a substance when it has dissolved all that it
-can, while an excess is present in the liquid. It is possible, by
-dissolving some salts in hot water and allowing the solution to cool
-without access of air, to obtain a supersaturated solution. On
-introduction of a crystal of the salt, or often on mere access of air,
-the solution forms crystals and the liquid left is saturated.
-
-
-Saw, Electric.
-A platinum coated steel wire mounted and connected to be raised to
-incandescence for cutting purposes.
-
-
-Schweigger's Multiplier.
-An old term for the galvanometer as invented by Schweigger soon after
-Oerstedt's discovery.
-
-
-Scratch Brushes.
-Brushes for cleaning the surface of articles to be electroplated to give
-a good metallic surface suitable for deposition. They have often wire
-instead of bristles.
-
-
-477   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 300. WIRE GAUZE ELECTRIC SCREEN.
-
-
-Screen, Electric.
-A large plate or a hollow case or cage of conducting material connected
-with the earth, and used to protect any body placed within it from
-electrostatic influences.
-
-If within a hollow conducting sphere an electrified body is placed, the
-inner surface of the sphere will be charged with electricity of opposite
-kind to that of the sphere, and the outer surface with the same kind as
-that of the sphere. Thus the sum of the electricities called into action
-by induction is zero. The two inner charges are bound to each other. The
-induced charge on the outer surface of the sphere is all that has any
-effect on objects in the outer air.
-
-If the outer surface is connected to the earth it becomes discharged,
-and however highly electrified the body introduced into the sphere and
-the inner surface of such sphere may be, they produce no external
-effects, as they are bound one to the other.
-
-If the sphere is connected to the earth and an unelectrified object is
-placed within it, such object will be perfectly shielded from the
-effects of an outer electrostatic field. Perforated tinfoil or wire
-gauze has just as good a result. A large plate of metal connected to the
-earth has the same effect. The screen whether plane or hollow simply
-retains a bound charge due to the field of force, thereby neutralizing
-it, and the electricity of the opposite sign escapes to the earth. Thus
-a true shielding or screening effect is produced.
-
-In the cut an experiment is shown in which an electric screen is carried
-by a Leyden jar. Pith balls are suspended outside and inside of it. By
-the approach of an electrified body the outer pith balls will diverge,
-while no effect is produced upon the inner ones.
-
-
-Secondary Actions.
-In electrolysis the direct products of the electrical decomposition are
-not always obtained at the electrodes, but products due to their
-reaction on the water and other chemicals may appear. These constitute
-secondary actions. Thus if a solution of copper sulphate is electrolyzed
-with platinum electrodes, metallic copper appears at one pole and
-sulphuric acid and oxygen gas at the other. But the products of
-electrolysis by the current are copper (Cu) and sulphion (SO4). The
-latter reacting on water sets free oxygen gas and forms sulphuric acid.
-The latter is a secondary action.
-
-
-Secondary Generator.
-(a) An alternating current converter generating a so-called secondary
-current.
-
-(b) A secondary battery, q. v., may be thus termed.
-
-
-Secondary, Movable.
-The term movable secondaries has been applied to rings, spheres and
-discs of conducting material, such as copper, whose behavior when near
-the pole of an electro-magnet traversed by an alternating current, have
-been studied by Elihu Thomson. Such masses are subjected to very
-peculiar movements and mutual reactions. As the phenomena are due to
-induced currents the above term has been applied to the masses in which
-the currents are induced.
-
-
-478   STANDARD ELECTRICAL DICTIONARY.
-
-
-Secondary Plates, Colors of.
-In a secondary battery of the lead plate type, the color of the plates
-is a good indication of the condition of the battery. The negative plate
-should be brown or deep-reddish, the other should be slate-colored.
-
-
-Secondary Poles.
-Poles sometimes found in magnets existing in positions intermediate
-between the end or true poles.
-
-Synonym--Consequent Poles.
-
-
-Seebeck Effect.
-The production of a current by heating the junction of two different
-metals forming part of a circuit, or the thermo-electric production of
-current, is stated as the Seebeck effect, having been discovered by that
-investigator.
-
-
-Selenium.
-A non-metallic element. It is interesting electrically on account of the
-changes its electric resistance undergoes when it is subjected to light.
-
-In one set of experiments it was found that diffused light caused the
-resistance to fall in the ratio of 11 to 9. Full sunlight reduced it to
-one-half. Of the spectrum colors red was most powerful and the ultra red
-region still more strongly affected its resistance.
-
-The effect produced by exposure to light is instantaneous, but on
-removal to the dark only slowly disappears.
-
-A vessel of hot water was found to have no effect, showing that short
-ether waves are essential to the effect.
-
-
-Selenium Cell.
-A selenium resistance box. Vitreous selenium is made by keeping ordinary
-selenium for some hours at a temperature of about 220� C. (428� F.)
-after fusing. It is placed in an electric circuit as part of the
-conductor.
-
-Its resistance can then be determined. It decreases in sunlight to about
-one-half its resistance in the dark.
-
-The selenium cell is used in the Photophone, q. v. Otherwise it is
-little more than a subject of experiment.
-
-
-Selenium Eye.
-A model eye in which selenium in circuit with a battery and galvanometer
-takes the place of the retina of the human eye.
-
-
-Self-repulsion.
-When a body is electrified each molecule repels its neighbor and the
-condition in question is thus designated. An electrified soap-bubble
-expands in virtue of self-repulsion.
-
-
-Semi-conductors.
-Substances which conduct static electricity poorly, but quite
-appreciably and beyond the extent of leakage. The following are
-examples: Alcohol and ether, powdered glass, flowers of sulphur, dry
-wood, paper, ice at 0� C. (32� F.)
-
-
-479   STANDARD ELECTRICAL DICTIONARY.
-
-
-Sensibility.
-The measure of the effect of a current upon a galvanometer, or any
-similar case.
-
-
-Sensitiveness, Angle of Maximum.
-Every galvanometer has its angle of maximum sensitiveness, which is the
-angle of deflection at which a small increment of current will produce
-the greatest deflection. For every tangent galvanometer 45� is the angle
-in question. In using a galvanometer for direct reading methods it is an
-object to have it work at its angle of maximum sensitiveness.
-
-
-Separately Excited Dynamo.
-A dynamo-electric machine whose field magnet is excited from an outside
-source, which may be another dynamo or a battery. Alternating current
-dynamos are often of this description.
-
-
-Separate Touch.
-In magnetism a method of inducing magnetism in a steel bar. The opposite
-poles of two magnets are applied at the center of the bar to be
-magnetized, but without touching each other, and are drawn apart to its
-ends. They are returned through the air and the process is repeated a
-number of times and on both sides of the bar if necessary.
-
-
-Separation of Electricities.
-Under the double fluid theory of electricity the action of
-electrification in accumulating positive electricity in one conductor
-and negative on the other of the excited surfaces of two conductors.
-
-
-Separator.
-India rubber bands or other forms used in batteries to keep the plates
-from touching in the cell; especially applied to secondary batteries,
-where the plates are so near together as to require separators to
-prevent short circuiting.
-
-
-Fig. 301. SERIES CONNECTION.
-
-
-Series.
-(a) Arranged in succession as opposed to parallel. Thus if a set of
-battery jars are arranged with the zinc of one connected to the carbon
-of the next one for the entire number, it is said to be arranged in
-series. When incandescent lamps are arranged in succession so that the
-current goes through one after the other they are arranged in series.
-
-The opposite of parallel, q. v., or multiple arc, q. v.; it may be used
-as a noun or as an adjective.
-
-(b) See Electro-Chemical Series;
-
-(c) Thermo-Electric Series
-
-(d) Electrostatic Series;
-
-(e) Electro-motive Series.
-
-Synonym--Cascade Connection (but little used.)
-
-
-480   STANDARD ELECTRICAL DICTIONARY.
-
-Series-multiple.
-Arrangement of electric apparatus, in which the parts are grouped in
-sets in parallel and these sets are connected in series. It is used as a
-noun, as "arranged in series-multiple," or as an adjective, as "a
-series-multiple circuit or system."
-
-
-Fig. 302. SERIES-MULTIPLE CONNECTION.
-
-
-Service Conductors.
-In electric distribution the equivalents of service pipes in the
-distribution of gas; wires leading from the street mains to the houses,
-where current is to be supplied.
-
-
-Serving.
-The wrapping or winding of a cable composed of small size wire, laid
-closely and smoothly with a tool called a serving mallet, or serving
-block, or by machinery. It serves to protect the cable from wear.
-
-
-Shackle.
-In telegraph lines a swinging insulator bracket for use where wires make
-an angle with the pole. A journal box is attached to the pole, like half
-of a gate hinge. To this a short iron arm is pivoted so as to be free to
-swing through a considerable angle. At its end an insulator is carried
-to which the wire is attached. The shackle swings into line with the
-wire, or takes a position for two wires corresponding to the resultant
-of their directions of pull.
-
-
-Fig. 303. DOUBLE SHACKLE
-
-
-Shadow. Electric.
-A term applied to a phenomenon of high vacua. If an electric discharge
-is maintained in a Crookes' tube the glass opposite the negative
-electrode tends to phosphoresce. A plate of aluminum, used also as the
-positive electrode, protects the glass directly behind it so as to
-produce the effect of a shadow.
-
-Synonym--Molecular Shadow.
-
-[Transcriber's note: The effect is due to the "shadowing" of the
-electrons streaming past the plate.]
-
-
-481   STANDARD ELECTRICAL DICTIONARY.
-
-
-Sheath for Magnet Coils.
-In 1867 C. E. Varley proposed the use of a copper sheath surrounding a
-magnet core to diminish self-induction. It has since been used by Brush
-and others. Sometimes metallic foil is laid between the successive coils
-of wire.
-
-Synonym--Mutual Induction Protector.
-
-
-Sheath for Transformers.
-A protective sheath of copper, interposed between the primary and
-secondary circuits of an alternating current transformer. It is
-connected to the earth. If the primary coil loses its insulation before
-it can leak to the secondary it is grounded. This protects the secondary
-circuit from the high electro-motive force of the primary circuit.
-
-
-Shellac.
-A resin; produced as an exudation upon the branches of certain Asiatic
-trees, such as the banyan (Ficus religiosa). It is due to punctures in
-the bark of the trees in question, which punctures are made by the
-female of the insect coccus ficus or c. lacca.
-
-Commercial shellac contains about 90 per cent. of resinous material, the
-rest is made up of wax, gluten, coloring matter and other substances.
-
-Shellac is soluble in alcohol, and in aqueous solutions of ammonium
-chloride, of borax and in strong ammonia solution. Long standing is
-required in the case of the last named solvent. Dilute hydrochloric and
-acetic acids dissolve it readily; nitric acid slowly; strong sulphuric
-acid is without action on it. Alkalies dissolve it.
-
-In electric work it is used as an insulator and dielectric. Its
-alcoholic solution is used to varnish glass plates of influence
-machines, for the coils of induction coils and similar purposes.
-
-Resistance in ohms per centimeter cube at 28� C. (82.4 F.)--(Ayrton),
-9.0E15
-
-Specific Inductive Capacity (W�llner),   2.95 to 3.73
-
-The same substance in less pure forms occurs in commerce, as stick lac,
-lump lac, seed lac, button lac.
-
-
-Shellac Varnish.
-Solution of shellac in alcohol; methylic alcohol (wood alcohol or wood
-naphtha) is often used as solvent.
-
-Dr. Muirhead recommends button lac, dissolved in absolute alcohol, and
-the top layers decanted. For highest insulation he dissolves the lac in
-ordinary alcohol, precipitates by dropping into water, collects the
-precipitate, dries and dissolves in absolute alcohol.
-
-
-Shielded. adj.
-An electric measuring instrument of the galvanometer type is shielded
-when it is so constructed that its indications are not seriously
-affected by the presence of neighboring magnets or by fields of force.
-Shielding can be effected by using a very strong permanent magnet to
-produce a field within which the magnetic needle moves and which reacts
-upon it, or by enclosing the instrument in a thick iron box.
-
-
-482   STANDARD ELECTRICAL DICTIONARY.
-
-
-S. H. M.
-Symbol or abbreviation for "simple harmonic motion."
-
-
-Shock, Break.
-A term in electro-therapeutics; the shock received when an electric
-circuit, including the patient in series, is broken or opened.
-
-Synonym--Opening Shock.
-
-
-Shock, Electric.
-The effect upon the animal system of the discharge through it of
-electricity with high potential difference. Pain, nervous shock, violent
-muscular contortions accompany it. Of currents, an alternating current
-is reputed worse than a direct current; intermediate is the pulsatory
-current.
-
-The voltage is the main element of shock, amperage has also some direct
-influence.
-
-
-Shock, Static.
-A term in electro-therapeutics. The application of static discharges
-from small condensers or Leyden jars to a patient who is insulated from
-the ground with one electrode applied to the conducting surface on which
-he rests, while the other, a spherical electrode, is brought near the
-body so as to produce a disruptive or spark discharge.
-
-
-Short Circuit.
-A connection between two parts of a circuit, which connection is of low
-resistance compared to the intercepted portion. The term is used also as
-a verb, as "to short circuit a lamp."
-
-
-Fig. 304. DIAGRAM ILLUSTRATING SHORT CIRCUIT WORKING.
-
-
-Short Circuit Working.
-A method of working intermittently an electro-magnet so as to avoid
-sparking. It consists in providing a short circuit in parallel with the
-magnetic coils. This short circuit is of very low resistance. To throw
-the magnet into action the short circuit is opened; to throw it out of
-action the short circuit is closed. The shunt or short circuit must be
-of negligibly small resistance and inductance.
-
-
-483   STANDARD ELECTRICAL DICTIONARY.
-
-
-Shovel Electrodes.
-Large plate electrodes used in a medical bipolar bath. (See Bath,
-Bipolar.)
-
-
-Shunt.
-In a current circuit a connection in parallel with a portion of the
-circuit. Thus in a dynamo a special winding for the field may have its
-ends connected to the bushes, from which the regular external circuit
-also starts. The field is then wound in shunt with the armature. In the
-case of a galvanometer a resistance coil may be put in parallel with it
-to prevent too much current going through the galvanometer; this
-connection is a shunt.
-
-The word is used as a noun, as "a shunt," or "a connection or apparatus
-in shunt with another," and as an adjective, as "a shunt connection," or
-as a verb, as "to shunt a battery."
-
-
-Shunt Box.
-A resistance box designed for use as a galvanometer shunt. (See Shunt,
-Galvanometer.) The box contains a series of resistance coils which can
-be plugged in or out as required.
-
-
-Shunt, Electro-magnetic.
-In telegraphy a shunt for the receiving relay consisting of the coils of
-an electro-magnet. It is placed in parallel with the relay. Its poles
-are permanently connected by an armature. Thus it has high
-self-induction.
-
-On opening and closing the circuit by the sending key, extra currents
-are produced in the shunt. The connections are so arranged that on
-making the circuit the extra current goes through the relay in the same
-direction as the principal current, while on breaking the circuit the
-induced current goes in the opposite direction.
-
-Thus the extra currents accelerate the production and also the cessation
-of signalling currents, tending to facilitate the operations of sending
-despatches.
-
-
-Shunt, Galvanometer.
-A resistance placed in parallel with a galvanometer, so as to short
-circuit its coils and prevent enough current passing through it to
-injure it. By knowing the resistance of the shunt and of the
-galvanometer coils, the proportion of current affecting the galvanometer
-is known. This gives the requisite factor for calculation. (See
-Multiplying Power of Shunt.)
-
-
-Shunt Ratio.
-The coefficient expressing the ratio existing between the current in a
-shunt and in the apparatus or conductor in parallel with it. (See
-Multiplying Power of/ Shunt.)
-
-
-Shunt Winding.
-A dynamo or motor is shunt-wound when the field magnet winding is in
-shunt or in parallel with the winding of the armature.
-
-
-Shuttle Current.
-A current alternating in direction; an alternating current.
-
-
-484   STANDARD ELECTRICAL DICTIONARY.
-
-
-Side-Flash.
-A bright flashing lateral discharge from a conductor conveying a current
-due to a static discharge.
-
-
-Sighted Position.
-In an absolute electrometer (see Electrometer, Absolute) the position of
-the balanced arm carrying the movable disc or plate, when the disc and
-guard plate are in one plane. The cross-hair on the lever-end is then
-seen midway between two stops, or some other equivalent position is
-reached which is discerned by sighting through a magnifying glass or
-telescope.
-
-
-Silver.
-A metal; one of the elements; symbol Ag.; atomic weight, 108; valency, 1;
-equivalent, 108; specific gravity, 10.5. It is a conductor of electricity.
-  Relative resistance, annealed,   1.0
-  Specific Resistance, annealed, at 0� C. (32� F.)   1.504 microhms.
-  Resistance of a wire at 0� C. (32� F.), Annealed.   Hard Drawn.
-  (a) 1 foot long, weighing 1 grain,      .2190 ohms   .2389 ohms.
-  (b) 1 foot long, 1/1000 inch thick,    9.048   "    9.826    "
-  (c) 1 meter long, weighing 1 gram,      .1527  "     .1662   "
-  (d) 1 meter long, 1 millimeter thick,   .01916 "     .02080  "
-
-  Resistance annealed of a 1-inch cube, at 0� C. (32�F.) .5921 microhms.
-
-  Percentage increase in resistance per degree C.
-  (1.8 F.) at about 20� C. (68� F.), annealed,   0.377 per cent.
-
-  Electro-chemical equivalent, (Hydrogen = .0105)   .1134 mgs.
-
-
-Silver Bath.
-A solution of a salt of silver for deposition in the electroplating
-process.
-
-The following is a typical formula:
-  Water,              10.0   parts by weight.
-  Potassium Cyanide,   5       "        "
-  Metallic Silver,     2.5     "        "
-
-The silver is first dissolved as nitrate and converted into cyanide and
-added in that form, or for 2.5 parts metallic silver we may read:
-  Silver cyanide,   3   parts by weight.
-
-While many other formulas have been published the above is
-representative of the majority. Other solvents for the silver than
-potassium cyanide have been suggested, such as sodium hyposulphite, but
-the cyanide solution remains the standard.
-
-
-Silver Stripping Bath.
-Various baths are used to remove silver from old electroplated articles.
-Their composition depends upon the base on which the metal is deposited.
-Silvered iron articles are placed as anodes in a solution of 1 part
-potassium cyanide in 20 parts of water. As kathode a silver anode or a
-copper one lightly oiled may be used. From the latter the silver easily
-rubs off. For copper articles a mixture of fuming sulphuric acid and
-nitric acid (40� Beaum�) may be used. The presence of any water in this
-mixture will bring about the solution of the copper. Or fuming sulphuric
-acid may be heated to between 300� and 400� F., some pinches of dry
-pulverized potassium nitrate may be thrown in and the articles at once
-dipped. These methods effect the solution of the silver, leaving the
-copper unattacked.
-
-
-485   STANDARD ELECTRICAL DICTIONARY.
-
-
-Simple Substitution.
-A method of obtaining a resistance equal to that of a standard. The
-standard is put in circuit with a galvanometer and the deflection is
-noted. For the standard another wire is substituted and its length
-altered until the same deflection is produced. The two resistances are
-then evidently identical. The standard can be again substituted to
-confirm the result.
-
-
-Sine Curve.
-If we imagine a point moved back and forth synchronously with a
-pendulum, and if such point made a mark upon paper, it would trace the
-same line over and over again. If now the paper were drawn steadily
-along at right angles to the line of motion of the point, then the point
-would trace upon it a line like the profile of a wave. Such line is a
-sine curve. It derives its name from the following construction. Let a
-straight line be drawn, and laid off in fractions, such as degrees, of
-the perimeter of a circle of given diameter. Then on each division of
-the line let a perpendicular be erected equal in height to the sine of
-the angle of the circle corresponding to that division; then if the
-extremities of such lines be united by a curve such curve will be a sine
-curve.
-
-In such a curve the abscissas are proportional to the times, while the
-ordinates are proportional to the sines of angles, which angles are
-themselves proportional to the times. The ordinates pass through
-positive and negative values alternately, while the abscissas are always
-positive.
-
-Any number of sine curves can be constructed by varying the diameter of
-the original circle, or by giving to the abscissas a value which is a
-multiple of the true length of the divisions of circle. If the pendulum
-method of construction were used this would be attained by giving a
-greater or less velocity to the paper as drawn under the pendulum.
-
-A species of equation for the curve is given as follows: y = sin( x )
-
-In this x really indicates the arc whose length is x, and reference
-should be made to the value of the radius of the circle from which the
-curve is described. It will also be noticed that the equation only
-covers the case in which the true divisions of the circle are laid off
-on the line. If a multiple of such divisions are used, say n times, or
-1-n times, then the equation should read
-y = n sin( x ) or y = sin( x ) / n
-
-Synonyms--Curve of Sines--Sinusoidal Curve--Harmonic Curve.
-
-
-486   STANDARD ELECTRICAL DICTIONARY.
-
-
-Sine Law.
-The force acting on a body is directly proportional to the sine of the
-angle of deflection when--
-
-I. The controlling force is constant in magnitude and direction; and
-
-II. The deflecting force, although variable in its direction in space,
-is fixed in direction relatively to the deflecting body.
-
-
-Single Fluid Theory.
-A theory of electricity. Electricity, as has been said, being
-conveniently treated as a fluid or fluids, the single fluid theory
-attributes electrical phenomena to the presence or absence of a single
-fluid. The fluid repels itself but attracts matter; an excess creates
-positive, a deficiency, negative electrification; friction, contact
-action or other generating cause altering the distribution creates
-potential difference or electrification. The assumed direction (see
-Direction) of the current and of lines of force are based on the single
-fluid theory. Like the double fluid theory, q. v., it is merely a
-convenience and not the expression of a truth. (See Fluid, Electric, and
-Double Fluid Theory.)
-
-Synonym--Franklin's Theory.
-
-
-Single Fluid Voltaic Cell.
-A galvanic couple using only a single fluid, such as the Smee or Volta
-cell.
-
-
-Simple Harmonic Motion.
-Motion of a point or body back and forth along a line; the motion of a
-pendulum, as regards its successive swings back and forth, is an example
-of harmonic motion.
-
-
-Sinistrotorsal. adj.
-The reverse of dextrotorsal, q. v. A helix with left-handed winding, the
-reverse of an ordinary screw, such as a wood-screw or corkscrew.
-
-
-Skin Effect.
-A current of very brief duration does not penetrate the mass of a
-conductor. Alternating currents for this reason are mainly conducted by
-the outer layers of a conductor. The above is sometimes called the skin
-effect.
-
-
-Sled.
-A contact for electric cars of the conduit system. It is identical with
-the plow, q.v., but is drawn after the cars instead of being pushed
-along with them.
-
-
-Slide Meter Bridge.
-A name for a Slide Bridge one meter long. There are also slide half
-meter and slide quarter meter bridges and others. (See Meter Bridge.)
-
-
-S. N. Code.
-Abbreviation for single needle code, the telegraphic alphabet used with
-the single needle system.
-
-
-Soaking-in-and-out.
-A term for the phenomena of the residual electrostatic charge; the
-gradual acquirement or loss by a condenser of a portion of its
-electrostatic charge.
-
-
-487   STANDARD ELECTRICAL DICTIONARY.
-
-
-Soldering, Electric.
-(a) Soldering in which the solder is melted by means of electricity;
-either current incandescence or the voltaic arc may be used. It is
-identical in general with electric welding. (See Welding, Electric.)
-
-(b) The deposition by electric plating of a metal over the ends of two
-conductors held in contact. This secures them as if by soldering. It is
-used in connecting the carbon filament of an incandescent lamp with the
-platinum wires that pass through the glass. Copper is the metal usually
-deposited.
-
-
-Solenoid.
-The ideal solenoid is a system of circular currents of uniform
-direction, equal, parallel, of equal diameter of circle, and with their
-centers lying on the same straight line, which line is perpendicular to
-their planes.
-
-
-Fig. 305. EXPERIMENTAL SOLENOID.
-
-
-The simple solenoid as constructed of wire, is a helical coil, of
-uniform diameter, so as to represent a cylinder. After completing the
-coil one end of the wire is bent back and carried through the centre of
-the coil, bringing thus both ends out at the same end. The object of
-doing this is to cause this straight return member to neutralize the
-longitudinal component of the helical turns. This it does approximately
-so as to cause the solenoid for its practical action to correspond with
-the ideal solenoid.
-
-Instead of carrying one end of the wire through the centre of the coil
-as just described, both ends may be bent back and brought together at
-the centre.
-
-A solenoid should always have this neutralization of the longitudinal
-component of the helices provided for; otherwise it is not a true
-solenoid.
-
-Solenoids are used in experiments to represent magnets and to study and
-illustrate their laws. When a current goes through them they acquire
-polarity, attract iron, develop lines of force and act in general like
-magnets.
-
-A solenoid is also defined as a coil of insulated wire whose length is
-not small as compared with its diameter.
-
-
-488   STANDARD ELECTRICAL DICTIONARY.
-
-
-Sonometer, Hughes'.
-A sound measurer; a modification of a portion of Hughes' induction
-balance, used for testing the delicacy of the ear or for determining the
-relative intensity of sounds. (See Hughes' Induction Balance.) It is the
-arrangement of three coils, two mounted one at each of the ends of a
-graduated bar, and the third one between them and free to slide back and
-forth thereon.
-
-
-Sonorescence.
-The property of producing sounds under the influence of momentary light
-radiations rapidly succeeding each other. It is the property utilized in
-the photophone, q. v.
-
-
-Fig. 306. MORSE SOUNDER.
-
-
-Sounder.
-In telegraphy an instrument consisting of an electromagnet with armature
-attached to an oscillating bar, the range of whose movements is
-restricted by adjusting screws. The armature is drawn away from the
-magnet by a spring. When a current is sent through the magnet the
-armature is drawn towards the poles and produces a sound as the bar
-strikes a striking piece or second adjusting screw. When the current
-ceases the bar and armature are drawn back, striking the first mentioned
-screw with a distinct sound, the back stroke.
-
-The sounder is used to receive Morse and analogous character messages.
-The forward strokes correspond to the beginnings of the dots or dashes
-of the code, the back strokes to beginnings of the intervals. The
-distinction between dots and dashes is made by observing the interval
-between forward and back stroke.
-
-Various devices are used to increase the sound. Sometimes a resonance
-box is used on which the sounder is mounted.
-
-In practice sounders are generally placed on local circuits and are
-actuated by relays.
-
-
-489   STANDARD ELECTRICAL DICTIONARY.
-
-
-Sound Reading.
-The art or method of receiving telegraph messages by ear. It is now
-universally used by all expert Morse operators. It can only be applied
-to telegraph systems producing audible sounds; in some cases, as in
-needle telegraphy, it may be quite inapplicable.
-
-
-Space, Clearance.
-The space between faces of the pole pieces and the surface of the
-armature in a dynamo. It is really the air gap, but in calculating
-dynamo dimensions the thickness of the insulated copper wire windings of
-the commutator are counted in as part of the air gap, because copper is
-almost the same as air in impermeability. Clearance space is a
-mechanical factor; the air gap is an electric or magnetic factor.
-
-Synonym--Inter-air Space.
-
-
-Space, Crookes' Dark.
-In an exhausted tube, through which an electric discharge is caused to
-pass, the space surrounding the negative electrode of the tube. This
-space is free from any luminous effect, and by contrast with the light
-of the discharge appears dark. The vacuum may be made so high that the
-dark space fills the whole space between the electrodes. It is less for
-a less vacuum and varies for other factors, such as the temperature of
-the negative electrode from which it originates, the kind of residual
-gas present, and the quality of the spark.
-
-
-Space, Faraday's Dark.
-The space in an exhausted tube between the luminous glows about the two
-electrodes.
-
-
-Space, Interferric.
-A term for the air-gap in a magnetic circuit. It is etymologically more
-correct than air-gap, for the latter is often two-thirds or more filled
-with the insulating material and copper wire of the armature windings.
-(See Space, Clearance.)
-
-
-Spark Arrester.
-A screen of wire netting fitting around the carbons of an arc lamp above
-the globe to prevent the escape of sparks from the carbons.
-
-
-Spark Coil.
-A coil for producing a spark from a source of comparatively low
-electro-motive force. It consists of insulated wire wound round a core
-of soft iron, best a bundle of short pieces of wire. Such a coil may be
-eight inches long and three inches thick, and made of No. 18-20 copper
-wire, with a core one inch in diameter. On connecting a battery
-therewith and opening or closing the circuit, a spark is produced by
-self-induction, q. v. It is used for lighting gas.
-
-
-490   STANDARD ELECTRICAL DICTIONARY.
-
-
-Spark, Duration of Electric.
-Wheatstone determined the duration of the spark given by a Leyden jar as
-1/24000 second. Feddersen by interposing a tube of water 9 millimeters
-(.36 inch) long in its path found that it lasted 14/10000 second, and
-with one 180 millimeters (7.2 inches) long, 188/10000 second. Lucas and
-Cazin for a 5 millimeter (.2 inch) spark, with different numbers of
-Leyden jars, found the following:
-Number of jars.   Duration of Spark.
-     2           .000026 second
-     4           .000041 "
-     6           .000045 "
-     8           .000047 "
-
-The duration increases with the striking distance, and is independent of
-the diameter of the balls between which it is produced.
-
-
-Spark Gap.
-The space left between the ends of an electric resonator (see Resonator,
-Electric) across which the spark springs. Its size may be adjustable by
-a screw, something like the arrangement of screw calipers.
-
-
-Sparking.
-In dynamo-electric machines, the production of sparks at the commutator
-between the brushes and commutator sections. The sparks are often true
-voltaic arcs, and in all cases are injurious if in any quantity, wearing
-out the commutator and brushes.
-
-
-Sparking, Line or Points of Least.
-In a dynamo or electric motor the diameter of the commutator
-determining, or the points on the commutator marking the position of the
-brushes where the sparking is a minimum. Field magnets powerful in
-proportion to the armature are a preventative cause. The direction of
-the line fixes the angle of lead to be given to the brushes.
-
-
-Sparking, Resistance to.
-The resistance to disruptive discharge through its substance offered by
-a dielectric or insulator. It does not depend on its insulating
-qualities, but on its rigidity and strength.
-
-
-Spark, Length of.
-The length of the spark accompanying the disruptive discharge is counted
-as the distance from one electrode to the other in a straight line. It
-is longer for an increased potential difference between the two
-electrodes. If the gas or air between the electrodes is exhausted the
-length increases, until the vacuum becomes too high, when the length
-begins to decrease, and for a perfect vacuum no spark however small can
-be produced. The shape of the conductor which is discharged, the
-material of the electrodes, and the direction of the current are all
-factors affecting the length of spark producible.
-
-
-491   STANDARD ELECTRICAL DICTIONARY.
-
-
-Spark Tube.
-A tube used as a gauge or test to determine when the exhaustion of the
-vacuum chamber or bulb of an incandescent lamp is sufficiently high.
-
-The interior of the tube is connected with the interior of the bulb or
-chamber of the lamps in process of exhaustion, and hence shares their
-degree of exhaustion. From time to time connections with an induction
-coil are made. When the exhaustion is carried far enough no discharge
-will take place through the vacuum. As long as the tube acts like a
-Geissler tube the exhaustion is not considered perfect.
-
-
-Specific Heat of Electricity.
-The heat absorbed or given out by a fluid in passing from one
-temperature to another depends on its specific heat. In the Peltier and
-the Thomson effects. q. v., the electric current acts as the producer of
-a change of temperature, either an increase or decrease as the case may
-be. This suggests an absorption of and giving out of heat which amount
-of heat corresponding to a current of known amount is determinable, and
-may be referred to any unit of quantity such as the coulomb. This or
-some equivalent definite quantity of heat it has been proposed (Sir
-William Thomson) to term the Specific Heat of Electricity.
-
-
-Spent Acid.
-Acid which has become exhausted. In a battery the acid becomes spent
-from combination with zinc. It also loses its depolarizing power, if it
-is a chromic acid solution or of that type, and then may be said to be
-spent.
-
-
-Spent Liquor.
-The liquor of a plating bath which has become exhausted from use, the
-metal it contained being all or partly deposited.
-
-
-Sphygmograph, Electric.
-An electric apparatus for recording the beat of the pulse, both as
-regards its rate and strength.
-
-
-Sphygmophone.
-An apparatus for examination of the pulse by the microphone and
-telephone.
-
-
-Spiders.
-Core-discs of a dynamo or motor armature are sometimes perforated with a
-large central aperture, are fastened together with insulated bolts, and
-the whole mass is secured to the shaft by three- or four-armed spiders.
-These are like rimless wheels, the ends of their arms being secured to
-the hollow cylinder constituting the armature core, and a central
-aperture in their hub receiving the shaft.
-
-
-492   STANDARD ELECTRICAL DICTIONARY.
-
-
-Spiral.
-This term is sometimes used instead of coil, as the primary spiral or
-secondary spiral of an induction coil or transformer.
-
-
-Spiral Winding.
-The winding used on ring armatures. This may diagrammatically be
-represented by a spiral carried around the ring shaped core. With two
-field poles it gives two collecting points, positive and negative, with
-four field poles it gives four collecting points, alternately positive
-and negative.
-
-
-Splice Box.
-A box in which the splices in underground cables and electric lines are
-contained. The splicing is generally done in the boxes with the cables
-in place. They may be two-way for straight lines, or be four-way for two
-side or lateral connections.
-
-
-Spluttering.
-A term applied to a sound sometimes produced in a voltaic arc, perhaps
-caused by impure or insufficiently baked electrodes. (Elihu Thomson.)
-
-
-Spring Control.
-Control of or giving the restitutive force to the needle of a
-galvanometer, core of a solenoid ammeter or moving part of any similar
-instrument by a spring. As an example see Ammeter, Ayrton's.
-
-
-Fig. 307. SPRING JACKS.
-
-
-Spring Jack.
-An arrangement for effecting, at one insertion of a species of plug, the
-opening or breaking of a circuit and for the simultaneous connection to
-the terminals formed by the breaking of two terminals of another system
-or loop. Thus let a line include in its circuit two springs pressing
-against each other, thereby completing the circuit. If a plug or wedge
-of insulating material were inserted between the springs so as to press
-them apart it would break the circuit and the whole would constitute a
-spring jack cut-out. If each side of the plug had a strip of brass or
-copper attached to it, and if the ends of another circuit were connected
-to these strips, then the insertion of the plug would throw the new line
-into the circuit of the other line.
-
-
-493   STANDARD ELECTRICAL DICTIONARY.
-
-
-Spring Jack Cut-out.
-A cut-out, of the general construction of a spring jack, q. v., except
-that a simple insulating plug or wedge is used in place of the
-metal-faced wedge with its connections of the regular spring jack. The
-insertion of an insulating wedge opens the circuit, which on its removal
-is closed. The regular spring jack wedge will operate in the same way,
-if its connections are kept open.
-
-
-Spurious Voltage.
-The voltage in excess of that developed by a secondary battery which is
-required in the charging process. It is about .25 volt.
-
-
-Square Wire.
-Wire whose cross-section is a square. It has been used of iron for
-building up the cores of armatures for dynamos or motors, for which it
-is peculiarly suitable, and also of copper as a winding for armatures.
-
-
-Staggering. adj.
-When the brushes of a dynamo are set, one a little in advance of the
-other on the surface of the commutator, they are said to be set
-staggering. It is used to get over a break in the armature circuit.
-
-
-State, Electrotonic.
-A term expressing an abandoned theory. Faraday at one time proposed the
-theory that a wire had to be in the electrotonic state to produce
-electro-motive force by movement through an electric field. Any such
-idea was ultimately abandoned by Faraday.
-
-
-Static Breeze.
-The electric breeze obtained by the silent discharge of high tension
-electricity.
-
-
-Static Electricity.
-Electricity at rest or not in the current form ordinarily speaking. The
-term is not very definite and at any rate only expresses a difference in
-degree, not in kind. The recognition of the difference in degree has now
-to a great extent also disappeared.
-
-
-Station, Central.
-The building or place in which are placed electrical apparatus, steam
-engines and plant supplying a district with electric energy.
-
-
-Station, Distant.
-The place at the further end of a telegraph line, as referred to the
-home station.
-
-
-Station, Home.
-The end of a telegraph line where the operators using the expression are
-working.
-
-
-494   STANDARD ELECTRICAL DICTIONARY.
-
-
-Station, Transforming.
-In alternating current distribution, a building or place where a number
-of transformers are worked, so that low potential or secondary circuits
-are distributed therefrom.
-
-
-Steel.
-A compound of iron with carbon. The carbon may range from a few
-hundredths of one per cent. up to two per cent. For magnets, tool steel
-drawn to a straw color or a little lower is good. All shaping and filing
-should be done before magnetization.
-
-
-Steeling.
-The deposition of iron on copper plates by electrolysis. In
-electrotyping a thin deposit of iron is thus given the relief plates
-before printing from them. The deposit is very hard and exceedingly
-thin, so that it does not interfere with the perfection of the
-impression in the printing process. As the iron becomes worn it can be
-dissolved off with hydrochloric acid, which does not dissolve the
-copper, and a new deposit can be given it. Thus the plate may last for
-an indefinite number of impressions.
-
-The iron bath may be prepared by immersing in a solution of ammonium
-chloride, two plates of iron, connected as anode and kathode in a
-circuit. One plate dissolves while hydrogen is given off from the other.
-The solution thus produced is used for a bath.
-
-The hardness of the deposit, which is really pure iron, gives the name
-of "steeling."
-
-Synonym--Acierage.
-
-
-St. Elmo's Fire.
-Luminous static discharge effects sometimes seen on objects elevated in
-the air. They are especially noticed on ships' masts. The sailors term
-them corpusants (holy bodies). They resemble tongues or globes of fire.
-
-
-Step-by-step Telegraphy.
-A system of telegraphy in which in the receiving instrument a hand is
-made to move step-by-step, with an escape movement around a dial. For
-each step there is a letter and the hand is made to stop at one or the
-other letter until the message is spelled out. (See Dial Telegraph.)
-
-
-Step-down. adj.
-A qualification applied to a converter or transformer in the alternating
-current distribution, indicating that it lowers potential difference and
-increases current from the secondary.
-
-
-Step-up. adj.
-The reverse of step-down; a qualification of a transformer or converter
-indicating that it raises the potential and decreases the current in the
-secondary.
-
-
-Sticking.
-The adherence, after the current is cut off, of the armature to the
-poles of a magnet. In telegraphy it is a cause of annoyance and
-obstructs the working. It may, in telegraphy, be due to too weak a
-spring for drawing back the armature, or to imperfect breaking of the
-contact by the despatcher's key or by the receiver's relay.
-
-
-495   STANDARD ELECTRICAL DICTIONARY.
-
-
-Stopping Off.
-In electroplating the prevention of deposition of the plating metal on
-any desired portions of the object. It is effected by varnishing the
-places where no coating is desired. An article can be plated with
-silver, stopped off in any desired design, and the unvarnished portions
-may then be plated with gold in another bath. Various effects can be
-produced by such means.
-
-
-Storage Capacity.
-A term for the ampere-hours of electricity, which can be taken in
-current form from a storage battery.
-
-
-Storage of Electricity.
-Properly speaking electricity can only be stored statically or in static
-condensers, such as Leyden jars. The term has been popularly applied to
-the charging of secondary or storage batteries, in which there is really
-no such thing as a storage of electricity, but only a decomposition and
-opposite combination brought about, which leave the battery in a
-condition to give a current.
-
-
-Storms, Electric.
-Wide-spread magnetic and electric disturbances, involving the
-disturbance of the magnetic elements and other similar phenomena. (See
-Magnetic Storms.)
-
-
-Strain.
-The condition of a body when subjected to a stress. Various consequences
-may ensue from strain in the way of disturbance of electric and other
-qualities of the body strained.
-
-
-Stratification Tube.
-A Geissler tube, q. v., for showing the stratification of the electric
-discharge through a high vacuum.
-
-The stratifications are greatly intensified by the presence of a little
-vapor of turpentine, alcohol, bisulphide of carbon and other substances.
-
-
-Stray Field.
-In a dynamo or motor the portion of the field whose lines of force are
-not cut by the armature windings.
-
-
-Stray Power.
-The proportion of the energy wasted in driving a dynamo, lost through
-friction and other hurtful resistances.
-
-
-Streamlets, Current.
-A conception bearing the same relation to an electric current that lines
-of force do to a field of force; elementary currents. If evenly
-distributed the current is of uniform density; if unevenly distributed,
-as in alternating currents, the current density varies in different
-parts of the cross section of the conductor. This evenness or unevenness
-may be referred to the number of streamlets per unit of area of
-cross-section.
-
-[Transcriber's note: Streamlets per unit of area is redundant with
-current density.]
-
-
-Stress.
-Force exercised upon a solid tending to distort it, or to produce a
-strain.
-
-
-496   STANDARD ELECTRICAL DICTIONARY.
-
-
-Stress, Dielectric.
-The condition of a dielectric when maintaining a charge; its two
-extremities are in opposite states of polarity, or are under permanent
-potential difference. As the two opposite polarities tend to unite a
-condition of stress is implied in the medium which separates them.
-
-
-Stress, Electro-magnetic.
-The stress produced upon transparent substances in an electro-magnetic
-field of force. It is shown in the modified optical properties of glass
-and similar substances placed between the poles of a strong
-electro-magnet.
-
-
-Stress, Electrostatic.
-The stress produced upon substances in an electrostatic field of force;
-the exact analogue of electro-magnetic stress, and affecting transparent
-substances in the same general way.
-
-
-Striae, Electric.
-In Geissler tubes the light produced by the electric discharge is filled
-with striae, bright bands alternating with dark spaces; these may be
-termed electric striae.
-
-
-Striking Distance.
-The distance that separates two conductors charged with electricity of
-different potential, when a spark starts between them.
-
-
-Striking Solution.
-In silver-plating a bath composed of a weak solution of silver
-cyanide-with a large proportion of free potassium cyanide. It is used
-with a strong current and a large silver anode. This gives an
-instantaneous deposition of metallic silver over the surface of the
-article which goes to insure a perfect coating in the silver bath
-proper. After a few seconds in the striking solution, the article is at
-once removed to the plating bath.
-
-
-Stripping.
-The removal of electroplating from an object. It may be effected in
-several ways. An object whose plating is to be removed is placed in a
-plating bath of the solution of the metal with which it is coated. It is
-connected as the anode to the positive plate of the battery or
-corresponding terminal of the generator. A kathode connected to the
-other terminal being placed in the bath, the coating is dissolved by
-electrolytic action. Sometimes simple treatment with acid is employed.
-Different stripping baths are described under the heads of the different
-metals.
-
-
-S. U.
-Symbol or abbreviation for Siemens' Unit of Resistance. (See Resistance,
-Siemens' Unit of.)
-
-
-Sub-branch.
-A branch or lead of wire taken from a branch lead: a term used in
-electric distribution.
-
-
-Sub-main.
-In electric distribution a conductor connected directly to a main; a
-branch.
-
-
-497   STANDARD ELECTRICAL DICTIONARY.
-
-
-Subway, Electric.
-A subterranean system of conduits for electric cables. As generally
-constructed in this country it includes manholes, q. v., at the street
-corners connected by ducts or pipes. These pipes are large enough to
-hold a cable. To introduce a cable into a duct, which latter may be two
-or three inches in diameter, and from two hundred to six or seven
-hundred feet long, a wire or rope is first passed through the duct. This
-is done by a set of short wooden rods with screws at the end so as to be
-screwed together. Each rod must be shorter than the diameter of the
-manhole. A rod is thrust in, another is screwed to it and thrust in, and
-thus a set of rods is made to extend as far as desired. In pulling them
-out a rope is attached and drawn through. This rope or a larger one is
-used in drawing the cable through the duct. A windlass is employed to
-draw the rope with cable attached through the ducts.
-
-
-Sulphating.
-In storage battery cells, the formation of a hard white basic lead
-sulphate, Pb2 S05. Its formation is due to over-exhaustion of the cells.
-As long as the voltage is not allowed to fall below 1.90 volts per cell
-little of it forms. As it accumulates it is apt to drop off the plate
-and fall to the bottom, thus weakening the plate possibly, and depriving
-it of active material, and clogging up the cell. If it carries a film of
-metallic lead with it, there is danger of short circuiting the cell.
-
-The presence of some sodium sulphate in the solution is said to tend to
-prevent sulphating, or to diminish it.
-
-Sulphur Dioxide.
-A compound gas, S O2; composed of
-  Sulphur,            32
-  Oxygen,             32
-  Molecular weight,   64
-  Specific gravity,    2.21.
-
-It is a dielectric of about the same resistance as air. Its specific
-inductive capacity at atmospheric pressure is: 1.0037 (Ayrton).
-
-Synonyms--Sulphurous Acid--Sulphurous Acid Gas.
-
-
-Sunstroke, Electric.
-Exposure to the arc light sometimes produces the effects observed in
-cases of sunstroke. It is said that, in the case of workmen at electric
-furnaces, these effects are very noticeable. (See Prostration,
-Electric.)
-
-[Transcriber's note: Effects are due to ultraviolet light.]
-
-
-Supersaturated. adj.
-A liquid is supersaturated when it has dissolved a substance at a
-temperature favorable to its solubility and its temperature has been
-allowed to change, the liquid being kept free from agitation or access
-of air, provided crystallization or precipitation has not taken place.
-It expresses the state of a liquid when it holds in solution more than
-the normal quantity of any substance soluble in it.
-
-
-Surface.
-A galvanic battery is arranged in surface when all the positive plates
-are connected together and all the negative plates are also connected.
-This makes it equivalent to one large cell, the surface of whose plates
-would be equal to the aggregate surface of the plates of the battery. It
-is also used as an adjective, as "a surface arrangement of battery."
-
-
-498   STANDARD ELECTRICAL DICTIONARY.
-
-
-Surface Density.
-The relative quantity of an electric charge upon a surface.
-
-
-Surface, Equipotential.
-A surface over all of which the potential is the same. In a general
-sense equipotential surfaces are given by planes or surfaces which cut
-lines of force at right angles thereto, or which are normal to lines of
-force. The conception applies to electrostatic and electro-magnetic
-fields of force, and for current conductors the planes normal to the
-direction of the current are equipotential surfaces.
-
-The contour of an equipotential surface of a field of force which is
-drawn or represented by delineations of its lines of force can be
-obtained by drawing a line normal thereto. This line will ordinarily be
-more or less curved, and will be a locus of identical potentials.
-
-An electric equipotential surface may be described as electro-static,
-electro- magnetic, or magnetic; or may be an equipotential surface of a
-current conductor. Besides these there are mechanical and physical
-equipotential surfaces, such as those of gravitation.
-
-
-Surface Leakage.
-Leakage of current from one part of an insulating material to another by
-the film of moisture or dirt on the surface.
-
-
-Suspension.
-This term is applied to methods of supporting galvanometer needles,
-balance beams, magnetic compass needles and similar objects which must
-be free to rotate. (See Suspension, Bifilar--Fibre and Spring
-Suspension--Fibre Suspension--Knife Edge Suspension--Pivot
-Suspension--Suspension, Torsion.)
-
-
-308. DIAGRAM OF BIFILAR SUSPENSION.
-
-
-Suspension, Bifilar.
-Suspension by two vertical parallel fibres, as of a galvanometer needle.
-The restitution force is gravity, the torsion being comparatively slight
-and negligible. Leaving torsion out of account the restitution force is
-(a) proportional to the distance between the threads;. (b) inversely
-proportional to their length; (c) proportional to weight of the needle
-or other object suspended; (d) proportional to the angle of
-displacement.
-
-
-499   STANDARD ELECTRICAL DICTIONARY.
-
-
-Assume two masses A and B at the end of a weightless rod, suspended by
-the parallel cords a A, b B. Let the rod be rotated through an angle
-theta. Consider the cord a A. Its lower end is swung through the angle
-theta, as referred to the center O; the cord is deflected from the
-vertical by an angle psi, such that a A tang(psi)= O A 2 sin (theta/2).
-The component of gravitation tending to restore A to A, acting towards A
-is equal to m g tan(psi). Its moment around O is equal to (m g tan(psi))
-* (O A cos(theta/2). The whole moment of the couple is 2 m g  tan(psi).
-0 A. cos(theta/2) = 2 m g (O A2/ a A) 2 sin(theta/2). Cos(theta/2) =
-2mgl(OA2/aA) sin(theta). The moment of the restoring force is thus
-proportional to the sine of the angle of deflection, and the
-oscillations of such a system are approximately simple harmonic.
-(Daniell.)
-
-If the twisting is carried so far as to cause the threads to cross and
-come in contact with each other the suspension ceases to be a bifilar
-suspension, but assumes the nature of a torsional suspension.
-
-[Transcriber's note: This is the image of the first paragraph.]
-
-
-Swaging, Electric.
-Mechanical swaging in which the objects to be swaged are heated by an
-electric current as in electric welding.
-
-
-S. W. G.
-Abbreviation for Standard Wire Gauge.
-
-
-Fig. 309. SIMPLE SWITCH.
-
-
-Switch.
-A device for opening and closing an electric circuit.
-
-A simple type is the ordinary telegrapher's switch. A bar of metal is
-mounted horizontally by a pivot at one end, so as to be free to rotate
-through an arc of a circle. In one position its free end rests upon a
-stud of metal. One terminal of a circuit is attached to its journal, the
-other to the stud. Resting on the stud it closes the circuit, in other
-positions it opens the circuit.
-
-
-500   STANDARD ELECTRICAL DICTIONARY.
-
-
-Switch, Automatic.
-A switch opened and closed by the electric current. It is used for
-lighting distant incandescent lamps. It includes one or two
-electro-magnets operated by two push buttons. In the usual arrangement
-one button is black and the other white, for extinguishing and lighting
-respectively. When the white button is pushed it causes a current to
-pass through one of the electro-magnets. This attracts its armature,
-thereby making a contact and throwing the lamps into the lighting
-circuit. Then they remain lighted until the black button is pressed.
-This excites the other magnet, which attracts its armature, breaks the
-contact and extinguishes the lights.
-
-The object of the automatic switch is to enable distant lamps to be
-lighted without the necessity of carrying the electric leads or wires to
-the place whence the lighting is to be done. A very small wire will
-carry enough current to operate the magnets, and open circuit batteries,
-such as Leclanch� batteries, may be used as the source of current for
-the switch, but generally the lighting current is used for the purpose.
-
-A single magnet may do the work. When the lighting button is pressed the
-magnet is excited, attracts its armature and holds it attracted, until
-by pressing the black button the current is turned off from it. In this
-case the lighting current is used to excite the magnet.
-
-
-Switch Board.
-A board or tablet to which wires are led connecting with cross bars or
-other switching devices, so as to enable connections among themselves or
-with other circuits to be made.
-
-
-Switch, Circuit Changing.
-A switch whose arm in its swing breaks one contact and swinging over
-makes another. It is employed to change the connections of circuits from
-one dynamo to another.
-
-Synonyms--Changing Switch--Changing Over Switch.
-
-
-Switch, Double Break.
-A form of switch in which double contact pieces are provided to give a
-better contact. One form consists of a hinged bar whose end swings down
-between two pairs of springs. Both pairs are connected to one terminal,
-and the bar to the other terminal of a circuit.
-
-
-Switch, Double Pole.
-A heavy switch for central station work, that connects and disconnects
-two leads simultaneously.
-
-
-Switch, Feeder.
-A heavy switch, often of double contact type, for connecting and
-disconnecting feeders from bus bars in central stations.
-
-
-501   STANDARD ELECTRICAL DICTIONARY.
-
-
-Switch, Knife.
-A switch whose movable arm is a narrow, deep bar of copper or brass, and
-which in making contact is forced in edgeways between two springs
-connected to one terminal. The bar is connected to the other terminal.
-
-Synonyms--Knife Break Switch--Knife Edge Switch.
-
-
-Switch, Multiple.
-A switch which in the swing of its bar connects one by one with a number
-of contacts so that ultimately the end of its bar is in contact with all
-at once. It is used to throw lights in and out in succession, and it
-can, if the multiple contacts connect with resistances, make them
-operate as a rheostat.
-
-
-Switch, Pole Changing.
-A switch for changing the direction of the current in a circuit.
-
-
-Switch, Reversing.
-A switch, often of the plug type (see Plug Switch) for changing the
-direction of current passing through a galvanometer.
-
-
-Switch, Snap.
-A switch constructed to give a quick, sharp break. It has a spiral
-spring interposed between the handle and arm. As the handle is drawn
-back to open it the spring is first extended, the bar being held by the
-friction of the contacts, until the spring suddenly jerks it up, thus
-breaking the contact.
-
-
-Switch, Storage Battery Changing.
-A switch for changing storage battery connections from series to
-multiple and back again.
-
-
-Switch, Three Way.
-A switch, so constructed that by turning its handle connection can be
-made from one lead to either of two other leads, and also so that
-connection can be completely cut off.
-
-
-Sympathetic Vibration.
-The establishment of periodic movement in one body by impulses of the
-same period communicated to it from another body in motion. Thus if two
-tuning forks are of the same pitch and one is sounded the other will
-begin to sound by sympathy, the sound waves communicating the necessary
-periodic impulses to it.
-
-Sympathetic vibrations are utilized in harmonic telegraphy. (See
-Harmonic Receiver--Telegraph, Harmonic.)
-
-
-T.
-Symbol of time.
-
-
-Tailings.
-(a) In high speed transmission of telegraph signals by the automatic
-system, the definiteness of the signal marks is sometimes interfered
-with by retardation. Wrong marks are thus produced called tailings.
-
-(b) The prolongation of the current at the distant receiving station of
-a telegraph line due to the discharge of the line and to self-induction.
-
-Synonyms--Tailing--Tailing Current.
-
-
-502   STANDARD ELECTRICAL DICTIONARY.
-
-
-Tamidine.
-Reduced nitro-cellulose. Nitro-cellulose is dissolved in a proper
-solvent and is obtained by evaporation as a translucent solid mass. By
-ammonium sulphide or other reagent it is reduced so as to be virtually
-cellulose. It is cut into shape for filaments of incandescent lamps,
-which shapes are carbonized and flashed.
-
-
-Tangent Law.
-In a galvanometer the tangents of the angles of deflection of the needle
-are proportional to the deflecting force--
-
-I.  When the controlling force is unaltered in absolute magnitude and
-direction by the motion of the needle.
-
-II. When the deflecting force acts at right angles always to the
-controlling force.
-
-These conditions are usually secured by having the actuating coil
-through which the current passes flat and of large diameter compared to
-the length of the needle; by using the uniform field of the earth as the
-control; by having a short needle; by placing the coil with its plane in
-the magnetic meridian.
-
-For best proportions of tangent galvanometer coils see Bobbins.
-
-
-Fig. 310. GRAPHIC CONSTRUCTION OF TANGENT SCALE.
-
-
-Tangent Scale.
-An arc of a circle in which the number of graduations in any arc
-starting from zero are proportional to the tangent of the angle
-subtended by such arc. The system is for use with tangent galvanometers.
-Thus if for 45� a value of 100 is taken and marked on the scale then for
-the arc 26� 33' + a value of 50 should be marked on the scale because
-such are the relative values of the tangents.
-
-Thus the scale instead of being divided into degrees is divided into
-arcs of varying length, growing shorter as they are more distant from
-the zero point, of such length that the first division being subtended
-by a tangent of length 1, the first and second divisions added or taken
-together as one arc are subtended by a tangent of length 2, and so on.
-
-In the cut a simple method of graphically laying out a tangent scale is
-shown. In it C is the centre of the arc, and H the radius running to the
-zero of the instrument. From C a circle is described and on H a vertical
-line tangent to the arc is erected. Taking any part of the tangent, as
-the length shown ending at D, it is divided into any number of equal
-parts. Radii of the circle are now drawn whose prolongations pass
-through the divisions on the tangent. These radii, where they intersect
-the arc of the circle, determine equal divisions of the tangent scale,
-which, as is evident from the construction, are unequal angular
-divisions of the arc.
-
-
-503   STANDARD ELECTRICAL DICTIONARY.
-
-
-Tanning, Electric.
-The tanning of hides in the manufacture of leather by the aid of
-electrolysis. A current of electricity is maintained through the tanning
-vats in which regular tanning liquor is contained. Very extraordinary
-claims are made for the saving of time in the tanning process. What is
-ordinarily a process of several months, and sometimes of a year, is said
-to be reduced to one occupying a few days only. The action of
-electrolysis is the one relied on to explain the results.
-
-
-Tapper.
-The key used in single needle telegraph transmitters. It comprises two
-flat springs L, E, each with a handle, normally pressed upward against
-one contact bar Z, and when pressed down by the operator making contact
-against a lower bar C when messages are to be transmitted. A double
-tapper, such as shown, is used for each instrument.
-
-Synonyms--Double Tapper Key--Pedal Key.
-
-
-Fig. 311. TAPPER.
-
-
-Target, Electric.
-A target registering or indicating electrically upon an annunciator the
-point of impact of each bullet.
-
-
-Taste, Galvanic.
-The effect produced upon the gustatory nerves by the passage of an
-electric current, or by the maintenance of potential difference between
-two portions of the tongue. It is very simply produced by placing a
-silver coin above, and a piece of zinc below the tongue, or the reverse,
-and touching their edges. A sour, peculiar taste is at once perceived.
-It cannot be due to any measurable quantity of current or of
-electrolytic decomposition, because the couple can do little more than
-establish a potential difference. With a strong current the taste
-becomes too strong for comfort, and if on a telegraph line the extra
-currents produced by the signaling make the operation of tasting the
-current a very unpleasant one. It is said that messages have been
-received in this way, the receiver placing one terminal of the line on
-his tongue, and a terminal attached to a grounded wire below it, and
-then receiving the Morse characters by taste.
-
-
-504   STANDARD ELECTRICAL DICTIONARY.
-
-
-Teazer.
-Originally a fine wire coil wound on the field magnets of a dynamo in
-shunt with the regular winding to maintain the magnetism. It was
-originally used in electroplating machines to prevent inversion of the
-magnetism, but has since developed into a component part of the winding
-of the compound dynamo. (See Dynamo, Compound.)
-
-
-Tee, Lead.
-A lead pipe of T shape used for connecting branches to electric cables.
-The tee is soldered by wiped joints to the lead sheathings of the cable
-and branches after the wires have been connected, and the junctions
-coated with insulating tape or cement, or both.
-
-It is sometimes made in two halves, and is known as a split tee.
-
-
-Tel-autograph.
-A telegraph for reproducing the hand-writing of the sender at the
-receiving end of the line. To save time a special spelling is sometimes
-used.
-
-
-Teleautograph.
-The special spelling used with the Tel-Autograph telegraph.
-
-
-Tele-barometer, Electric.
-A barometer with electric attachment for indicating or recording at a
-distance the barometric readings.
-
-
-Telegraph, ABC.
-This term is applied to alphabet telegraphs indicating the message by
-the movements of a pointer on a dial marked with the characters to be
-sent. In England the Wheatstone ABC system is much employed.
-
-
-Telegraph, Automatic.
-A telegraph system based on the operation of the transmitting instrument
-by a perforated strip of paper drawn through it. The perforations made
-by an apparatus termed a perforator, are so arranged as to give
-telegraphic characters of the Morse or International Code in the
-transmitting instrument. (See Perforator.) Bain in the year 1846 was the
-originator of the system. He punched a fillet of paper with dots and
-dashes, and drew it between two terminals of the line, thus sending over
-the line a corresponding series of short and long currents which were
-received by his chemical receiver. (See Chemical Receiver.) The method
-was not successful. Its modern development, the Wheatstone Automatic
-Telegraph, is highly so. The perforated paper by its perforations
-controls the reciprocating movement of two rods, which pass through each
-hole in two rows, corresponding to the two rods respectively as the
-holes come opposite to the ends of the rods. The rods are kept
-constantly moving up and down. If unperforated paper is above them their
-upward motion is limited. This gives three positions for the rods, (a)
-both down, (b) one up and the other down, (c) both up. These positions
-of the rods work a pole changing key by which dots, spaces, and dashes
-are transmitted to the receiving instrument, which is an exceedingly
-delicate ink-printer. The latter can have its speed adjusted to receive
-from 200 to 450 words per minute.
-
-
-505   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Dial.
-A telegraph in which as receiver a dial instrument is used. A pointer or
-index hand moves around a dial. The dial is marked with letters of the
-alphabet. The movements of the pointer are controlled by the
-transmitting operator at a distant station. He by the same actions moves
-a pointer on a duplicate instrument before him and the two are
-synchronized to give identical indications. Thus a message is spelled
-out letter by letter on both dials simultaneously. The motions of the
-index are generally produced by what is virtually a recoil escapement.
-The scape wheel is carried by the axle of the index, and a pallet or
-anchor is vibrated by an electro-magnet whose armature is attached to
-the stem of the pallet. As the pallet is vibrated it turns the wheel and
-index one tooth for each single movement. There are as many teeth in the
-wheel as there are characters on the dial. The two instruments being in
-duplicate and synchronized, the pallets move exactly in unison, so that
-identical readings of the dials are given. The pallets may be moved by
-any kind of make and break mechanism, such as an ordinary telegraph key.
-The index moves by steps or jerks, so that the system is sometimes
-called step-by-step telegraphy.
-
-
-Fig. 312. DIAL TELEGRAPH.
-
-
-In the cut the make and break transmitter is shown at v v, with its
-handle and contacts g and t. This mechanism sends impulses of current by
-F and Z to the receiving magnet l. This attracts and releases its
-armature K from contact into the position indicated by the dotted lines.
-This works the rocker n on the pin o, and actuates the double or anchor
-pawl s r, which turns the pallet or scrape wheel m.
-
-The system is dropping into disuse, being supplanted by the telephone.
-
-Synonym--Step-by-step Telegraph.
-
-
-506   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Double Needle.
-A telegraph system in which the message is read by the motions of two
-vertical needles on the face of the instrument in front of the receiving
-operator. An identical instrument faces the transmitting operator. By
-two handles, one for each hand, the needles are caused by electric
-impulses to swing to right and to left so as to give a telegraphic code.
-It has been generally superseded by the single needle telegraph.
-
-
-Telegraph, Duplex.
-A telegraph capable of transmitting simultaneously two messages over one
-wire. The methods of effecting it are distinct from those of multiplex
-telegraphy. This term is used as a distinction from diode multiplex
-telegraphy, in which the work is done on other principles. There are two
-systems of duplex telegraphy, the differential and the bridge systems.
-
-
-Telegraph, Duplex Bridge.
-A system of duplex telegraphy employing the principle of the Wheatstone
-bridge. The other or differential system depends on equality or
-difference of currents; the bridge method on equality or difference of
-potentials. The cut shows the system known as Steam's Plan.
-
-At the ends of the line wire are two cross connections like duplicate
-galvanometer connections in a Wheatstone bridge, each including a
-receiving relay. The rest of the connections are self-explanatory.
-
-When A depresses his key the current splits at the point indicating the
-beginning of the bridge. One portion goes through the line to B and to
-earth, the other goes to earth at A through the rheostats indicated by
-the corrugated lines.
-
-On reaching B's end the current divides at the cross-connection and part
-goes through the receiving relay shown in the center of that
-cross-connection.
-
-Thus if A sends to B or B to A it is without effect on the home
-receiving instrument. Now suppose that both simultaneously are sending
-in opposite directions. If the connections be studied it will be seen
-that every movement of the transmitting key will affect the balance of
-the distant or receiving end of the bridge and so its instrument will
-record the signals as they are sent.
-
-As shown in the cut the sending keys are on local circuits, and work
-what are known as duplex transmitters. These are instruments which send
-line signals without breaking the connection.
-
-
-Fig. 313. STEARN'S PLAN OF DUPLEX BRIDGE TELEGRAPHY.
-
-
-In Stearn's plan condensers are introduced as shown. By this plan
-different receiving instruments can be used. The inventor once worked a
-Morse instrument at one end of the line, and a Hughes' instrument at the
-other end.
-
-
-507   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Duplex, Differential.
-A system of duplex telegraphy employing the differential action of two
-exciting or magnetizing coils. The general principles are the following.
-Suppose that at each of two stations, there is a magnet working as a
-sounder or relay. Each magnet is differentially wound, with two coils of
-opposite direction, of identical number of turns.
-
-When the sending key at a station A is depressed two exactly equal
-currents go through the magnet in opposite directions. One called the
-compensation current goes to the earth at the stations. The other called
-the line current goes through the line, through the line coil of the
-distant station E, thereby actuating the relay or sounder armature.
-
-The instrument of the sender A is unaffected because he is sending
-opposite and equal currents through its two coils. A special resistance
-is provided on the compensation circuit for keeping the currents exactly
-equal in effect. Nothing the sender at A does affects his own
-instrument.
-
-Now suppose E desires to telegraph back at the same time that A is
-telegraphing to his station. He works his key. This does not affect his
-own instrument except by sending the equal and opposite currents through
-its coils. When his key is depressed and A's key is untouched, he works
-A's receiving instrument.
-
-
-508   STANDARD ELECTRICAL DICTIONARY.
-
-
-When A's key is depressed simultaneously with B's key, the two line
-currents are in opposition and neutralize each other. This throws out
-the balance in the instruments and both armatures are attracted by the
-compensation currents left free to act by the neutralization of the line
-currents.
-
-
-Fig. 314. DUPLEX TELEGRAPH, DIFFERENTIAL SYSTEM
-
-
-Suppose that B is sending a dash, and it begins while A's key is raised.
-The line and compensation currents in B's receiving instrument
-neutralize each other and no effect is produced, while A's receiving
-instrument begins to register or indicate a dash. Now suppose A starts
-to send a dash while B's is half over. He depresses his key. This sends
-the two opposite currents through his magnet. His line current
-neutralizes B's working current so that the compensation currents in
-both receiving instruments hold the armatures attracted for the two
-dashes. Meanwhile A's dash ends and he releases his key. At once his
-line current ceases to neutralize B's line current, his receiving
-instrument is actuated now by B's line current, while B's receiving
-instrument ceases to be actuated by the compensation current.
-
-Two assumptions are made in the above description. The line currents are
-assumed to be equal in strength and opposite in direction at each
-station. Neither of these is necessary. The line current received at a
-station is always weaker than the outgoing line current, and it is the
-preponderance of the compensation current over the partly neutralized
-line current that does the work. As this preponderance is very nearly
-equal to the line current received from the distant station, the signals
-are actuated by almost the same current, whether it is compensation or
-line current.
-
-
-509   STANDARD ELECTRICAL DICTIONARY.
-
-
-Both line currents may coincide in direction. Then when the two keys are
-depressed, a line current of double strength goes through both receiving
-instruments and both work by preponderance of the double line current
-over the compensation current. In other respects the operation is the
-same as before described.
-
-
-Fig. 315. DUPLEX TELEGRAPH, DIFFERENTIAL SYSTEM.
-
-
-Fig. 316. DIFFERENTIAL DUPLEX TELEGRAPH CONNECTIONS.
-
-
-The cut shows a diagram of the operation of one end of the line. R and R
-are resistances, E and E are earth contacts, and the two circles show
-the magnet of the receiving instrument wound with two coils in
-opposition. The battery and key are also shown. It also illustrates what
-happens if the key of the receiver is in the intermediate position
-breaking contact at both 1 and 2. The sender's line current then goes
-through both coils of the receiving instrument magnet, but this time in
-series, and in coincident direction. This actuates the instrument as
-before. Owing to the resistance only half the normal current passes, but
-this half goes through twice as many coils or turns as if the receiver's
-key was in either of the other two positions.
-
-In actual practice there are many refinements. To compensate for the
-varying resistance of the line a rheostat or resistance with sliding
-connection arm is connected in the compensation circuit so that the
-resistance can be instantly changed. As the electro-static capacity of
-the line varies sectional condensers are also connected in the
-compensation circuits.
-
-
-510   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Facsimile.
-A telegraph for transmitting facsimiles of drawing or writing. The
-methods employed involve the synchronous rotation of two metallic
-cylinders, one at the transmitting end, the other at the receiving end.
-
-On the transmitter the design is drawn with non-conducting ink. A tracer
-presses upon the surface of each cylinder and a circuit is completed
-through the two contacts. In operation a sheet of chemically prepared
-paper is placed over the surface of the receiving cylinder. The two
-cylinders are rotated in exact synchronism and the tracers are traversed
-longitudinally as the cylinders rotate. Thus a number of makes and
-breaks are produced by the transmitting cylinder, and on the receiving
-cylinder the chemicals in the paper are decomposed, producing marks on
-the paper exactly corresponding to those on the transmitting cylinder.
-
-Synonyms--Autographic Telegraph--Pantelegraphy.
-
-
-Telegraph, Harmonic Multiplex.
-A telegraph utilizing sympathetic vibration for the transmission of
-several messages at once over the same line. It is the invention of
-Elisha Gray. The transmitting instrument comprises a series of vibrating
-reeds or tuning-forks, each one of a different note, kept in vibration
-each by its own electro-magnet. Each fork is in its own circuit, and all
-unite with the main line so as to send over it a make and break current
-containing as many notes superimposed as there are tuning forks. At the
-other end of the line there are corresponding tuning forks, each with
-its own magnet. Each fork at this end picks up its own note from the
-makes and breaks on the main line, by the principle of sympathetic
-vibration.
-
-To each pair of operators a pair of forks of identical notes are
-assigned. As many messages can be transmitted simultaneously as there
-are pairs of forks or reeds.
-
-The movements of a telegraph key in circuit with one of the transmitting
-reeds sends signals of the Morse alphabet, which are picked out by the
-tuning fork of identical note at the other end of the line.
-
-
-511   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Hughes'.
-A printing telegraph in very extensive use in continental Europe. Its
-general features are as follows:
-
-The instruments at each end of the line are identical. Each includes a
-keyboard like a piano manual, with a key for each letter or character.
-On each machine is a type wheel, which has the characters engraved in
-relief upon its face. With the wheel a "chariot" as it is termed also
-rotates. The type wheels at both stations are synchronized. When a key
-is depressed, a pin is thrown up which arrests the chariot, and sends a
-current to the distant station. This current causes a riband of paper to
-be pressed up against the face of both type wheels so as to receive the
-imprint of the character corresponding to the key. The faces of the
-wheels are inked by an inking roller.
-
-
-Fig. 317. ELECTRO-MAGNET OF HUGHES' PRINTING TELEGRAPH.
-
-
-The most characteristic feature is the fact that the current sent by
-depressing a key does not attract an armature, but releases one, which
-is then pulled back by a spring. The armature is restored to its
-position by the mechanical operation of the instrument. The magnet used
-is a polarized electro-magnet. Coils are carried on the ends of a strong
-powerful magnet. The coils are so connected that a current sent through
-them by depressing a key is in opposition to the magnetism of the
-permanent magnet so that it tends to release the armature, and in
-practice does so. This release permits the printing mechanism to act.
-The latter is driven by a descending weight, so that very slight
-electric currents can actuate the instruments.
-
-Synonym--Hughes' Type Printer.
-
-
-Telegraphic Code.
-(a) The telegraphic alphabet, as of the Morse System. (See Alphabet,
-Telegraphic.)
-
-(b) A code for use in transmitting messages either secretly, or
-comprising several words or short sentences in one word, in order to
-economize in transmission. Such codes are extensively used in commercial
-cable messages.
-
-
-512   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Magneto-electric.
-A telegraph in which the current is produced by magneto-electric
-generators. It has been applied to a considerable extent in England. The
-Wheatstone ABC or dial telegraph is operated by a magneto-generator
-turned by hand.
-
-In this country the magneto-electric generator by which the calling bell
-of a telephone is rung is an example. The magneto-electric key (See Key,
-Magneto-electric) is for use in one kind of magneto-electric
-telegraphing.
-
-
-Telegraph, Morse.
-A telegraph, characterized by the use of a relay, working a local
-circuit, which circuit contains a sounder, or recorder for giving dot
-and dash signals constituting the Morse alphabet. The signals are sent
-by a telegraph key, which when depressed closes the circuit, and when
-released opens it. The two underlying conceptions of the Morse Telegraph
-system are the use of the dot and dash alphabet, and the use of the
-local circuit, which circuit includes a receiving instrument, and is
-worked by a relay, actuating a local battery. It would be difficult to
-indicate any invention in telegraphy which has had such far-reaching
-consequences as the one known as the Morse telegraph.
-
-In other places the principal apparatus of the system will be found
-described. The cut Fig. 318, repeated here gives the general disposition
-of a Morse system. (See Circuit, Local.)
-
-
-Fig. 318. DIAGRAM OF MORSE SYSTEM.
-
-
-513   STANDARD ELECTRICAL DICTIONARY.
-
-
-The key by which the messages are transmitted is shown in Fig. 319. M is
-a base plate of brass. A is a brass lever, mounted on an arbor G carried
-between adjustable set screws D. C is the anvil where contact is made by
-depressing the key by the finger piece B of ebonite. E, Fl are adjusting
-screws for regulating the vertical play of the lever. H is the switch
-for opening or closing the circuit. It is opened for transmission, and
-closed for receiving. By screws, L L, with wing nuts, K K, the whole is
-screwed down to a table.
-
-
-Fig. 319. MORSE TELEGRAPH KEY.
-
-
-In the United States the simplest disposition of apparatus is generally
-used. The main line is kept on closed circuit. In it may be included a
-large number of relays at stations all along the line, each with its own
-local circuit. There may be fifty of such stations. Battery is generally
-placed at each end of the line. Very generally gravity batteries are
-used, although dynamos now tend to supplant them in important stations.
-
-As relays the ordinary relay is used. Its local circuit includes a
-sounder and local battery. The latter is very generally of the gravity
-type, but oxide of copper batteries (See Battery, Oxide of Copper) are
-now being introduced. At main or central offices, the terminals of the
-lines reach switch boards, where by spring-jacks and plugs, any desired
-circuits can be looped into the main circuit in series therewith.
-
-In European practise the main line is kept on open circuit. Polarized
-relays are used to work the local circuits. The currents for these have
-to be alternating in direction. When the line is not in use its ends are
-connected to earth at both ends, leaving the battery out of circuit.
-Each intermediate station has its own main, or line battery for use when
-it desires to send a message. In the American system as first described,
-it will be seen that the main batteries are at most two in number.
-
-For the details of the different apparatus, the following definitions
-may be consulted: Embosser, Telegraphic--Recorder, Morse--Relay--Relay
-Connection--Sounder.
-
-
-514   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Multiplex.
-A system of telegraphy by which a number of messages can be transmitted
-in both directions over a single wire. The principles underlying the
-systems are the following:
-
-Suppose that at the two extremities of a telegraph line two arms are
-kept in absolute synchronous rotation. Let the arms in their rotation,
-press upon as many conducting segments as there are to be transmissions
-over the line. A transmitting and receiving set of instruments may be
-connected to one segment at one end of the line, and another set to the
-corresponding segment at the distant station. For each pair of segments
-two sets can be thus connected. Then if the arm rotates so rapidly that
-the contacts succeed each other rapidly enough each pair of sets of
-instruments can be worked independently of the others. In practice this
-rapid succession is effected by having a number of contacts made for
-each pair during a single rotation of the arm or equivalent.
-
-The multiplex system has been perfected by the use of La Cour's phonic
-wheel (see Phonic Wheel), and brought into a practical success by
-Patrick B. Delany, of New York.
-
-Two phonic wheels rotate at each end of the line. They are kept in
-synchronous motion by two vibrating steel reeds of exactly the same
-fundamental note, and the axle of each wheel carries an arm whose end
-trails over the contacts or distributor segments already spoken of. The
-reeds are adjusted to vibrate at such speed that the trailer is in
-contact with each segment about 1/500 second. The number of groups of
-segments required for each working is determined by the retardation of
-the signals owing to the static capacity of the line. To convert the
-rapidly recurring impulses of current into practically a single current,
-condensers are connected across the coils of the relay. One battery
-serves for all the arms.
-
-Multiplex telegraphy can effect from two to six simultaneous
-transmissions over one wire. For two or four transmissions the method
-only distinguishes it from duplex or quadruplex telegraphy. The terms
-diode, triode, tetrode, pentode and hexode working are used to indicate
-respectively the simultaneous transmission of two, three, four, five, or
-six messages over one wire.
-
-It will be seen that the multiplex process really assigns to each
-transmission separate times, but divides these times into such short and
-quickly recurring intervals that the work is executed as if there was
-continuous contact. In no case is there the popular conception of the
-sending of several messages actually simultaneously over one wire. Each
-signal in reality has its own time assigned it, divided into short
-periods of high frequency, and only utilizes the line when it is free.
-
-
-515   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Over-house.
-An English term for telegraph lines led over houses and supported on
-standards on the roofs.
-
-
-Telegraph Pole Brackets.
-Arms for carrying insulators, which arms are attached to telegraph poles
-or other support. They vary in style; sometimes they are straight bars
-of wood gained into and bolted or spiked in place; sometimes they are of
-iron.
-
-
-Telegraph, Printing.
-Various telegraphs have been invented for printing in the ordinary
-alphabet the messages at the receiving end of the line.
-
-Representative instruments of this class are used for transmitting
-different market and stock reports to business offices from the
-exchanges. The type faces are carried on the periphery of a printing
-wheel, which is rotated like the hand of a dial telegraph, and against
-whose face a paper riband is pressed whenever the proper letter comes
-opposite to it. As each letter is printed the paper moves forward the
-space of one letter. Spacing between words is also provided for. In the
-recent instruments two lines of letters are printed on the paper one
-above the other.
-
-In England, and on the continent of Europe, printing instruments have
-received considerable use for ordinary telegraphic work. Hughes' type
-printer and Wheatstone's ABC telegraph meet with extensive use there for
-ordinary transmission.
-
-
-Telegraph, Quadruplex.
-Duplex telegraphy is the sending of two messages in opposite directions
-simultaneously through the same wire. Duplex telegraphy is the sending
-of two messages simultaneously in the same direction. The two combined
-constitute quadruplex telegraphy. [SIC]
-
-The system was suggested by Stark of Vienna and Bosscha of Leyden in
-1855; the successful problem was solved by Edison in 1874.
-
-The principle is based on the two orders of difference in electric
-currents; they may vary in strength or in direction. Thus we may have
-one instrument which works with change of strength of current only, the
-other with change of direction only. The two can be worked together if
-the direction of the current can be altered without alteration of
-strength, and if strength can be altered without alteration of
-direction. Double current and single current working are so combined
-that one relay works by one system of currents and another relay by the
-other system. A current is constantly maintained through the line. The
-relay operated by change in direction is a simple polarized relay which
-works by change of direction of current. The relay operated by change in
-strength is the ordinary unpolarized relay.
-
-
-516   STANDARD ELECTRICAL DICTIONARY.
-
-
-For the following description and the cuts illustrating it we are
-indebted to Preece and Sivewright. The cut shows the arrangement of the
-apparatus and connections for terminal offices.
-
-"Sufficient table room is provided to seat four clerks. The apparatus is
-arranged for the two senders to sit together in the centre, the messages
-to be forwarded being placed between them. The section on the left of
-the switch Q is known as the 'A' side, that on the right as the 'B' side
-of the apparatus.
-
-K1 the reversing key, reverses the direction of the current. K2 is a
-simple key, known as the increment key; it is used simply to increase
-the strength of the current.
-
-
-Fig. 320. QUADRUPLEX TELEGRAPH CONNECTIONS.
-
-
-The way in which the keys K1 and K2 combine their action is shown by
-Fig. 321. E1 and E2 are the line batteries, the one having two and
-one-third (2-1/3) the number of cells of the other, so that if E1 be the
-electro-motive force of the smaller, that of the whole combined battery
-will be 3.3 E1. The negative pole of E1 is connected to z and z1 of  K1
-and the positive pole of E2 to a of K2 through a resistance coil s. A
-wire, called the 'tap' wire, connects the positive pole of E1 and the
-negative pole of E2 to b of K2. This wire has in it a resistance coil
-r2. The springs c and c1 of Kl are connected to the lever L of K2. Now,
-when both keys are at rest, the negative pole of E1 is to line through
-z, and the positive pole of E1 to earth through b of K2 and c of K1; the
-positive pole of E2 being insulated at a of K2.
-
-
-517   STANDARD ELECTRICAL DICTIONARY.
-
-
-There is thus a weak negative current flowing to line. When K1 alone is
-worked, the current of E1 is reversed. When K2 is worked alone, c of K1
-is transferred from b to a, and the strength of the negative current
-going to line is increased through the increase of the electro-motive
-force from E1 to 3.3 E1 for the whole battery is brought into play. When
-K1 and K2 are depressed together, then the negative pole of E1 goes to
-earth through Z1; and the positive pole of E2 to line through a of K2
-and c1 of K1 and a positive current, due to the whole electro-motive
-force 3.3 E1 goes to line. Hence the effect of working K1 is simply to
-reverse the current, whatever its strength, while that of K2 is to
-strengthen it, whatever its direction.
-
-The resistance coil s, of 100� resistance, is called a spark coil,
-because it prevents the high electro-motive force of the whole battery
-from damaging the points of contact by sparking or forming an arc across
-when signals are sent; and the resistance r2 is made approximately equal
-to the combined resistance of E2 and the spark coil, so that the total
-resistance of the circuit may not be altered by the working of the
-apparatus.
-
-
-Fig. 321. QUADRUPLEX TELEGRAPH.
-
-
-A1 and B1 (Fig. 320) are the relays which are used to respond to the
-changes in the currents sent by the keys K1 and K2 at the distant
-station.
-
-A, is a simple polarized relay wound differentially, each wire having a
-resistance of 200 [omega], and so connected up as to respond to the working of
-the reversing key K1 of the distant station. It acts independently of
-the strength of the current, and is therefore not affected by the
-working of the increment key K2. It is connected up so as to complete
-the local circuit of the sounder S1 and the local battery l1 and forms
-the receiving portion of the 'A' side.
-
-B, is a non-polarized relay also wound differentially, each coil having
-a resistance of 200 [omega]. It responds only to an increase in the
-strength of the current, and therefore only to the working of the
-increment key K2 of the distant station.
-
-[Transcriber's note: In current usage upper case omega indicates ohms and
-lower case omega denotes angular frequency, 2*PI*f.]
-
-
-518   STANDARD ELECTRICAL DICTIONARY.
-
-
-The relay spring is so adjusted that the armatures are not actuated by
-the weak current sent from E by the key K1.
-
-In its normal position this relay completes the circuit of the local
-battery through the sounder S. This sounder S, called the uprighting
-sounder, acts as a relay to a second sounder, S2, called the reading
-sounder, which is worked by another local battery, l2. Of course,
-normally, the armature of S is held down and that of S2 is up, but when
-the tongue t moves, as it does when the increment key K2 is depressed so
-as to send the whole current to line, then the current from l is
-interrupted, and the circuit of l2 is completed by the rising of the
-armature of S, causing the reading sounder S2 to work. This is the 'B'
-side.
-
-R is a rheostat for balancing the resistance of the line, as used in
-duplex working.
-
-C is a condenser used for compensating the static charge of the line. It
-is provided with an adjustable retardation coil, R1, to prolong the
-effect of the compensating current from the condenser.
-
-G is a differential galvanometer, used for testing, and for facilitating
-adjustment and balancing.
-
-Q is a switch for putting the line to earth, either for balancing, or
-for any other purpose. There is on the earth wire leading from Q a
-resistance coil, r1, equalling approximately the resistance of the whole
-battery, 3.3 E1, and the resistance s.
-
-The connections shown in Fig. 321, are for an 'up' office. At a 'down'
-office it is necessary to reverse the wires on the two lower terminals
-of the galvanometer and the two battery wires on the reversing key K1.
-
-The keys K1 and K2 are, for repeaters, replaced by transmitters.
-
-The adjustment of this apparatus requires great care and great accuracy.
-Its good working depends essentially on technical skill that can only be
-acquired by patience and perseverance.
-
-Faults in working generally arise from careless adjustments, dirty
-contacts, loose connections, battery failures, and the ordinary line
-interruptions, but there are no troubles that are beyond the reach of
-ordinary skill, and it can be safely said that, within moderate
-distances, wherever and whenever duplex working is practicable, then
-quadruplex working is so too."
-
-The above is a typical quadruplex bridge system. There is also a
-differential system, the full description of which, in addition to what
-has been given, is outside of the scope of this work.
-
-
-519   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph Repeater.
-An extension of the relay system, adopted for long lines. A repeating
-station comprises in general terms duplicate repeating apparatus. One
-set is connected for messages in one direction, the other for messages
-in the opposite direction. The general operation of a repeating set is
-as follows. The signals as received actuate a relay which by its local
-circuit actuates a key, which in ordinary practise would be the sounder,
-but in the repeater its lever opens and closes a circuit comprising a
-battery and a further section of the line.
-
-Repeaters are placed at intervals along the line. Each repeater repeats
-the signals received for the next section of line with a new battery. It
-represents an operator who would receive and repeat the message, except
-that it works automatically.
-
-The Indo-European line from London to Teheran, 3,800 miles long, is
-worked directly without any hand retransmission, it being carried out by
-five repeaters. This gives an average of over 500 miles for each
-repeater.
-[Transcriber's note: � 650 miles for each repeater.]
-
-Repeaters introduce retardation, and each repeater involves a reduction
-in the rate of working. Yet in many cases they increase the speed of a
-line greatly, as its speed is about equal to that of its worst section,
-which may be far greater than that of the whole line in one.
-
-Synonym--Translater.
-
-
-Telegraph Signal.
-In the telegraph alphabet, a dot, or dash; the signal or effect produced
-by one closing of the circuit. A dash is equal in length to three dots.
-The space between signals is equal to one dot; the space between letters
-to three dots; and the space between words to six dots.
-
-
-Telegraph, Single Needle.
-A telegraph system in which the code is transmitted by the movements of
-a needle shaped index which oscillates to right and left, the left hand
-deflection corresponding to dots, the right hand deflection to dashes.
-The instruments for sending and receiving are combined into one. The
-needles are virtually the indexes of vertical galvanometers. In one form
-by a tapper key (see Tapper), in another form by a key worked by a
-drop-handle (the drop handle instrument), currents of opposite
-directions are sent down the line. These pass through both instruments,
-affecting both needles and causing them to swing to right or left, as
-the operator moves his key.
-
-As galvanometer needle or actuating needle a soft iron needle is
-employed, which is polarized by the proximity of two permanent magnets.
-This avoids danger of reversal of polarity from lightning, a trouble
-incident to the old system.
-
-
-520   STANDARD ELECTRICAL DICTIONARY.
-
-
-The cut, Fig. 322, shows a single needle telegraph instrument of the
-tapper form. The action of the tapper can be understood from the next
-cut.
-
-
-Fig. 322. SINGLE NEEDLE TELEGRAPH INSTRUMENT, DOUBLE
-TAPPER FORM.
-
-
-Fig. 323. DOUBLE TAPPER KEY FOR SINGLE NEEDLE TELEGRAPH.
-
-
-C and Z are two strips of metal to which the positive and negative poles
-of the battery are respectively connected. E and L are two metallic
-springs; E is connected to earth, L is connected to the line; at rest
-both press against Z. If L is depressed so as to touch C, the current
-from the battery goes to the line by the key L, goes through the coils
-of the distant instrument and deflects the needle to one side, and then
-goes to the earth. If the key E is depressed, L retaining its normal
-position, the direction of the current is reversed, for the other pole
-of the battery is connected to the earth and the reverse current going
-through the coils of the distant instrument deflects the galvanometer
-needle to the other side.
-
-In the drop-handle type an analogous form of commutator worked by a
-single handle produces the same effects.
-
-
-521   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telegraph, Wheatstone, A. B. C.
-A magneto-electric telegraph of the dial system. An alternating current
-magneto-generator is turned by hand and by depressing keys its current
-is admitted to or cut off from the line and receiver's instrument. The
-message is received by a dial instrument working by the escapement
-motion described under Telegraph, Dial.
-
-
-Telegraph, Writing.
-A telegraph in which the message is received in written characters. The
-transmitter includes a stylus which is held in the hand and whose point
-bears against the upper end of a vertical rod. The rod is susceptible of
-oscillation in all directions, having at its base a spring support
-equivalent to a universal joint.
-
-The stylus is moved about in the shape of letters. As it does this it
-throws a series of resistances in and out of the circuit.
-
-At the receiving end of the line the instrument for recording the
-message includes two electro-magnets with their cores at right angles to
-each other and their faces near together at the point of the angle. An
-armature is supported between the faces and through it a vertical rod
-carried by a spring at its bottom rises. These magnets receive current
-proportional to the resistances cut in and out by the motions of the
-other rod at the transmitting end of the line. These resistances are
-arranged in two series at right angles to each other, one for each
-magnet. Thus the movements of the transmitting stylus and rod are
-repeated by the end of the rod in the receiving instrument. A species of
-pen is carried at the end of the rod of the receiving instrument, which
-marks the letters upon a riband of paper which is fed beneath it.
-
-
-Telemanometer. Electric.
-A pressure gauge with electric attachment for indicating or recording
-its indications at a distance.
-
-It is applicable to steam boilers, so as to give the steam pressure in
-any desired place.
-
-
-Telemeter, Electric.
-An apparatus for electrically indicating or recording at a distance the
-indications of any instrument such as a pressure gauge, barometer or
-thermometer, or for similar work. The telemanometer applied to a boiler
-comes into this class of instrument.
-
-
-Telephotography.
-The transmission of pictures by the electric current, the requisite
-changes in the current being effected by the action of light upon
-selenium. The picture is projected by a magic lantern. Its projection is
-traversed by a selenium resistance through which the current passes.
-This is moved systematically over its entire area, thus constituting the
-transmitter, and synchronously with the motion of the selenium a contact
-point at the other end of the line moves systematically over a sheet of
-chemically prepared paper. The paper, which may be saturated with a
-solution of potassium ferrocyanide and ammonium nitrate, is stained by
-the passage of the current, and by the variation in intensity of
-staining, which variation is due to variations in the current, produced
-by the effects of the light upon the selenium, the picture is
-reproduced.
-
-
-522   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telepherage.
-An electric transportation system, hitherto only used for the carrying
-of ore, freight, etc. Its characteristic feature is that the electric
-conductors, suspended from poles, supply the way on which carriages
-provided with electric motors run. The motors take their current
-directly from the conductors.
-
-There are two conducting lines, running parallel with each other,
-supported at the opposite ends of transverse brackets on a row of
-supporting poles. At each pole the lines cross over so that right line
-alternates with left, between consecutive pairs of poles.
-
-The cars are suspended from pulleys running on one or the other of the
-conductors. A train of such cars are connected and the current is taken
-in near one end and leaves near the other end of the train. These
-current connections are so distant, their distance being regulated by
-the length of the train, that they are, for all but an instant at the
-time of passing each of the poles, in connection with segments of the
-line which are of opposite potential. To carry out this principle the
-distance between contacts is equal to the distance between poles. Owing
-to the crossing over of the lines the contacts are in connection as
-described and thereby the actuating current is caused to go through the
-motors.
-
-Cars running in one direction go on the electric conductors on the one
-side, those running in the other direction go on the other conductor.
-
-A great many refinements have been introduced, but the system has been
-very little used.
-
-
-Telephone.
-An instrument for the transmission of articulate speech by the electric
-current. The current is defined as of the undulatory type. (See Current,
-Undulatory.)
-
-The cut shows what may be termed the fundamental telephone circuit. A
-line wire is shown terminating in ground plates and with a telephone in
-circuit at each end. The latter consists of a magnet N S with a coil of
-insulated wire H surrounding one end. Facing the pole of the magnet is a
-soft iron diaphragm D, held in a frame or mouthpiece T. Any change of
-current in the line affects the magnetism of the magnet, causing it to
-attract the diaphragm more or less. The magnet and diaphragm really
-constitute a little electric motor, the diaphragm vibrating back and
-forth through an exceedingly short range, for changes in the magnetic
-attraction.
-
-The principle of the reversibility of the dynamo applies here. If the
-magnet is subjected to no change in magnetism, and if the diaphragm is
-moved or vibrated in front of its poles, currents will be induced in the
-wire bobbin which surrounds its end. If two such magnets with bobbins
-and diaphragms are arranged as shown, vibrations imparted to one
-diaphragm will send currents through the line which, affecting the
-magnetism of the distant magnet, will cause its diaphragm to vibrate in
-exact accordance with the motions of the first or motor diaphragm. In
-the combination one telephone represents a dynamo, the other a motor.
-
-If the vibrations of the diaphragm are imparted by the voice, the voice
-with all its modulations will be reproduced by the telephone at the
-distant end of the line.
-
-
-523   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 324. DIAGRAM OF BELL TELEPHONES AND LINE WITH EARTH CONNECTIONS.
-
-
-Fig. 325. SECTION OF BELL TELEPHONE.
-
-
-The above gives the essential features of the Bell telephone. In
-practice the telephone is used only as the receiver. As transmitter a
-microphone is employed. To give the current a battery, generally of the
-open circuit type, is used, and the current in the line is an induced or
-secondary one.
-
-The microphone which is talked to, and which is the seat of the current
-variations which reproduce original sound, is termed the transmitter,
-the telephone in which the sounds are produced at the distant end of the
-line is termed the receiver.
-
-Fig. 325 shows the construction of the Bell telephone in universal use
-in this country as the receiver. M is a bar magnet, in a case L L. B B
-is a bobbin or coil of insulated wire surrounding one end of the magnet.
-D is the diaphragm of soft iron plate (ferrotype metal), and E is the
-mouthpiece. The terminals of the coil B B connect with the binding
-screws C C. The wire in the coil is No. 36, A. W. G., and is wound to a
-resistance of about 80 ohms.
-
-
-524   STANDARD ELECTRICAL DICTIONARY.
-
-
-As typical transmitter the Blake instrument may be cited. It is a carbon
-microphone. It is shown in section in the cut; a is the mouthpiece and e
-is a diaphragm of iron plate, although other substances could be used; f
-is a steel spring, with a platinum contact piece at its end. One end
-bears against the diaphragm, the other against a carbon block k. The
-latter is carried by a brass block p, and pressure is maintained between
-these contacts by the spring g and weight of the piece c, which by
-gravity tends to press all together. The current passes by way of the
-spring f, carbon button k and spring g through the circuit indicated.
-
-A battery is in circuit with these parts. If a telephone is also in
-circuit, and the transmitter is spoken against, the diaphragm vibrating
-affects the resistance of the carbon-platinum contact, without even
-breaking the contact, and the telephone reproduces the sound. The heavy
-piece of metal C acts by its inertia to prevent breaking of the contact.
-The position of this piece c, which is carried by the brass plate m, is
-adjusted by the screw n.
-
-
-Fig. 326. SECTION OF BLAKE TRANSMITTER.
-
-
-In practice the transmitter and battery are usually on a local circuit,
-which includes the primary of an induction coil. The line and distant
-receiving telephone are in circuit with the secondary of the induction
-coil, without any battery.
-
-Telephone, Bi-.
-A pair of telephones carried at the ends of a curved bar or spring so
-that they fit the head of a person using them. One telephone is held
-against each ear without the use of the hands.
-
-
-525   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telephone, Capillary.
-A telephone utilizing electro-capillarity for the production of
-telephonic effects. The following describes the invention of Antoine
-Breguet.
-
-The point of a glass tube, drawn out at its lower end to a capillary
-opening dips vertically into a vessel. This vessel is partly filled with
-mercury, over which is a layer of dilute sulphuric acid. The end of the
-immersed tube dips into the acid, but does not reach the mercury. One
-line contact is with mercury in the tube, the other with the mercury in
-the vessel. The arrangement of tube and vessel is duplicated, giving one
-set for each end of the line. On introducing a battery in the circuit
-the level of the mercury is affected by electro-capillarity. The tubes
-are closed by plates or diaphragms at their tops, so as to enclose a
-column of air. It is evident that the pressure of this air will depend
-upon the level of the mercury in the tube, and this depends on the
-electro-motive force. On speaking against the diaphragm the sound waves
-affect the air pressure, and consequently the level, enough to cause
-potential differences which reproduce the sound in the other instrument.
-
-
-Fig. 327. BREGURT'S CAPILLARY TELEPHONE.
-
-
-Telephone, Carbon.
-A telephone transmitter based on the use of carbon as a material whose
-resistance is varied by the degree of pressure brought to bear upon it.
-Undoubtedly the surface contact between the carbon and the other
-conducting material has much to do with the action. Many carbon
-telephones have been invented. Under Telephone the Blake transmitter is
-described, which is a carbon telephone transmitter. The Edison carbon
-transmitter is shown in section in the cut. E is the mouth piece and D
-the diaphragm. I is a carbon disc with adjusting screw V. A platinum
-plate B B, with ivory button b, is attached to the upper surface of the
-carbon disc. C C is an insulating ring. The wire connections shown bring
-the disc into circuit. It is connected like a Blake transmitter. It is
-now but little used.
-
-
-Fig. 328. SECTION OF EDISON CARBON TRANSMITTER.
-
-
-526   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telephone, Chemical.
-A telephone utilizing chemical or electrolytic action in transmitting or
-receiving. The electro-motograph is an example of a chemical receiver.
-(See Electro-motograph.)
-
-
-Telephone, Electrostatic.
-A telephone utilizing electrostatic disturbances for reproduction of the
-voice. In the cut D and C are highly charged electrophori. The
-diaphragms A and B when spoken to affect the potential of the
-electrophorus so as to produce current variations which will reproduce
-the sound. Dolbear and others have invented other forms of transmitters
-based on electrostatic action. Receivers have also been constructed. A
-simple condenser may be made to reproduce sound by being connected with
-a powerful telephone current.
-
-
-Fig. 329. DIAGRAM OF EDISON'S ELECTROSTATIC TELEPHONE.
-
-
-Telephone Induction Coil.
-The induction coil used in telephone circuits for inducing current on
-the main line. It is simply a small coil wound with two separate
-circuits of insulated wire. In the Edison telephone the primary coil, in
-circuit with the transmitter, is of No. 18 to 24 wire and of 3 to 4 ohms
-resistance. The secondary in circuit with the line and receiving
-instrument is of No. 36 wire and of 250 ohms resistance. The Bell
-telephone induction coil has its primary of No. 18 to 24 wire wound to a
-resistance of 1/2 ohm, and its secondary of No. 36 wire, and of 80 ohms
-resistance.
-
-
-527   STANDARD ELECTRICAL DICTIONARY.
-
-
-Telephone, Reaction.
-A form of telephone containing two coils of insulated wire, one of which
-is mounted on the disc, and the other on the magnet pole in the usual
-way. These coils react upon each other so as to strengthen the effect.
-
-
-Telephone, Thermo-electric.
-A telephone transmitter including a thermo-electric battery, placed in
-circuit with the line. A plate of vulcanite faces it. When the sound
-waves strike the vulcanite they move it backward and forward. These
-movements, owing to the elasticity of the vulcanite, produce minute
-changes of temperature in it, which affecting the thermo-electric pile
-produce in the circuit currents, which passing through a Bell telephone
-cause it to speak. This type of instrument has never been adopted in
-practice.
-
-
-Telephote.
-An apparatus for transmitting pictures electrically, the properties of
-selenium being utilized for the purpose.
-
-Synonym--Pherope.
-
-
-Teleseme.
-An annunciator, displaying on a dial the object wanted by the person
-using it. It is employed to transmit messages from rooms in a hotel to
-the office, or for similar functions.
-
-
-Tele-thermometer.
-A thermometer with electric attachment for indicating or recording its
-indications at a distance.
-
-
-Tempering, Electric.
-A process of tempering metals by electrically produced heat. The article
-is made part of an electric circuit. The current passing through it
-heats it, thereby tempering it. For wire the process can be made
-continuous. The wire is fed from one roll to another, and if required
-one roll may be immersed in a liquid bath or the wire between the rolls
-may be led therein. The current is brought to one roll and goes through
-the wire to the other. As it does this the wire is constantly fed from
-one roll to another. The bath may be used as described to cool it after
-the heating. The amount of heating may be regulated by the rate of
-motion of the wire.
-
-
-528   STANDARD ELECTRICAL DICTIONARY.
-
-
-Ten, Powers of.
-This adjunct to calculations has become almost indispensable in working
-with units of the C. G. S. system. It consists in using some power of 10
-as a multiplier which may be called the factor. The number multiplied
-may be called the characteristic. The following are the general
-principles.
-
-The power of 10 is shown by an exponent which indicates the number of
-ciphers in the multiplier. Thus 10^2 indicates 100; 10^3 indicates 1,000
-and so on.
-
-The exponent, if positive, denotes an integral number, as shown in the
-preceding paragraph. The exponent, if negative, denotes the reciprocal
-of the indicated power of 10. Thus 10^-2 indicates 1/100; 10^-3 indicates
-1/1000 and so on.
-
-The compound numbers based on these are reduced by multiplication or
-division to simple expressions. Thus: 3.14 X 10^7 = 3.14 X 10,000,000 =
-31,400,000. 3.14 X 10^-7 = 3.14/10,000,000 or 314/1000000000. Regard must
-be paid to the decimal point as is done here.
-
-To add two or more expressions in this notation if the exponents of the
-factors are alike in all respects, add the characteristics and preserve
-the same factor. Thus:
-
-  (51X 10^6) + (54 X 10^6) = 105 X 10^6.
-  (9.1 X 10^-9) + (8.7 X 10^-9) = 17.8 X 10^-9.
-
-To subtract one such expression from another, subtract the
-characteristics and preserve the same factor. Thus:
-
-  (54 X 10^6) - (51 X 10^6) = 3 X 10^6.
-
-If the factors have different exponents of the same sign the factor or
-factors of larger exponent must be reduced to the smaller exponent, by
-factoring. The characteristic of the expression thus treated is
-multiplied by the odd factor. This gives a new expression whose
-characteristic is added to the other, and the factor of smaller exponent
-is preserved for both,
-
-Thus:
-  (5 X 10^7) + (5 X10^9) = (5 X 10^7) + (5 X 100 X 10^7) = 505 X 10^7.
-
-The same applies to subtraction. Thus:
-  (5 X 10^9) - (5 X 10^7) = (5 X 100 X 10^7) - (5 X 10^7) = 495 X 10^7.
-
-If the factors differ in sign, it is generally best to leave the
-addition or subtraction to be simply expressed. However, by following
-the above rule, it can be done. Thus:
-
-Add
-  5 X 10^-2 and 5 X 10^3.
-  5 X 10^3 = 5 X 10^5 X 10^-2
-  (5 X 10^5 X 10^-2) + (5 X 10^-2) = 500005 X 10^-2
-
-This may be reduced to a fraction 500000/100 = 5000.05.
-
-To multiply add the exponents of the factors, for the new factor, and
-multiply the characteristics for a new characteristic. The exponents
-must be added algebraically; that is, if of different signs the
-numerically smaller one is subtracted from the other one, and its sign
-is given the new exponent.
-
-Thus;
-  (25 X 10^6) X (9 X 10^8) = 225 X 10^14.
-  (29 X 10^ -8) X (11 X 10^7) = 319 X 10^-1
-  (9 X 10^8) X (98 X 10^2) = 882 X 10^1
-
-
-529   STANDARD ELECTRICAL DICTIONARY.
-
-
-To divide, subtract (algebraically) the exponent of the divisor from
-that of the dividend for the exponent of the new factor, and divide the
-characteristics one by the other for the new characteristic. Algebraic
-subtraction is effected by changing the sign of the subtrahend,
-subtracting the numerically smaller number from the larger, and giving
-the result the sign of the larger number.
-(Thus to subtract 7 from 5 proceed thus; 5 - 7 = -2.)
-
-Thus;
-  (25 X 10^6) / (5 X 10^8) = 5 X 10^-2
-  (28 X 10^-8) / (5 X 10^3) = 5.6 X 10^-11
-
-[Transcriber's note: I have replaced ordinary exponential notation by
-the more compact and simpler "programming" representation. The last two
-example would be:
-  25E6 / 5E8  = 5E-2
-  28E-8 / 5E3 = 5.6E-11
-]
-
-
-Tension.
-Electro-motive force or potential difference in a current system is
-often thus termed. It is to be distinguished from intensity or current
-strength, which word it too greatly resembles.
-
-
-Tension, Electric.
-(a) The condition an electrified body is brought into by
-electrification, when each molecule repels its neighbor. The condition
-is described as one of self-repulsion.
-
-(b) The voltage or potential difference of a circuit is also thus
-termed.
-
-
-Terminal.
-The end of any open electric circuit, or of any electric apparatus; as
-the terminals of a circuit, dynamo, or battery.
-
-
-Terminal Pole.
-In telegraph line construction the last pole of a series; one beyond
-which the line is not carried. Such pole, as the pull of the wires is
-all in one direction, requires special staying or support. The regular
-line poles are free from this strain, as the wire pulls in both
-directions.
-
-
-Tetanus, Acoustic.
-A term in electro-therapeutics. An effect produced on a nerve by very
-rapidly alternating induced currents. The currents are produced by an
-induction coil with a vibrator giving a musical note. This is a species
-of gauge of proper frequency of alternations.
-
-
-Theatrophone.
-An apparatus worked by automatic paying machinery by which a telephone
-connection is made with a theatre or opera by the deposition of a coin
-in a slot.
-
-
-Therm.
-A unit of heat. It has been proposed by the British Association and
-amounts to a redefinition of the smaller calorie. It is the amount of
-heat required to raise the temperature of one gram of water one degree
-centigrade, starting at the temperature of maximum density of water.
-
-
-530   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thermaesthesiometer.
-An electro-therapeutic instrument for testing the sensitiveness of the
-surface of the body to changes of temperature. Vessels of mercury are
-provided with thermometers to indicate their temperature. One vessel is
-surrounded by an electric conductor wound in a number of turns. The
-temperature is raised by passing a current through this. By successive
-applications of the vessels to the same spot upon the skin the power of
-differentiating temperatures is determined.
-
-
-Thermo Call.
-(a) An electric alarm or call bell operated by thermo-electric currents.
-It may serve as a fire alarm or heat indicator, always bearing in mind
-the fact that differential heat is the requisite in a thermo-electric
-couple.
-
-(b) See Thermo-electric Call.
-
-
-Thermo-chemical Battery.
-A voltaic battery in which the electro-motive force is generated by
-chemical action induced by heat.
-
-The chemical used generally is sodium nitrate or potassium nitrate. The
-positive plate is carbon. On heating the battery the nitrate attacks the
-carbon, burning it and produces potential difference. For negative plate
-some metal unattacked by the nitrate may be employed.
-
-
-Fig. 330. POUILLET'S THERMO-ELECTRIC BATTERY.
-
-
-Thermo-electric Battery or Pile.
-A number of thermo-electric couples q. v., connected generally in
-series.
-
-In Nobili's pile the metals are bismuth and antimony; paper bands
-covered with varnish are used to insulate where required. In Becquerel's
-pile copper sulphide (artificial) and German silver, (90 copper, 10
-nickel) are the two elements. The artificial copper sulphide is made
-into slabs 4 inches long, 3/4 inch wide, and 1/2 inch thick (about).
-Water is used to keep one set of junctions cool, and gas flames to heat
-the other set. In Fig. 331, c, d represent the binding screws. The
-couples are mounted on a vertical standard, with adjusting socket and
-screw B, so that its lower end can be immersed in cold water, or raised
-therefrom as desired.
-
-
-531   STANDARD ELECTRICAL DICTIONARY.
-
-
-FIG. 331. BECQUEREL'S THERMO-ELECTRIC BATTERIES.
-
-
-Fig. 332 shows one couple of the battery. S is artificial antimony
-sulphide; M is German silver; m is a protecting plate of German silver
-to save the sulphide from wasting in the flame.
-
-
-Fig. 332. ELEMENTS OF BECQUEREL'S THERMOELECTRIC BATTERIES.
-
-
-Clamond's pile has been used in practical work. The negative element is
-an alloy of antimony, 2 parts, zinc, 1 part. The positive element is tin
-plate. Mica in some parts, and a paste of soluble glass and asbestus in
-other parts are used as insulators. They are built up so as to form a
-cylinder within which the fire is maintained. The air is relied on to
-keep the outer junctions cool. The temperature does not exceed 200� C.
-(392� F.)
-
-Sixty such elements have an electro-motive force of 300 volts and an
-internal resistance of 1.5 ohms. Such a battery requires the consumption
-of three cubic feet of gas per hour. (See Currents, Thermo-electric. )
-
-
-532   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thermo-electric Call.
-A thermostat arranged to ring a bell or to give some indication when the
-temperature rises or falls beyond certain points. It may be a compound
-bar of brass and steel fixed at one end and free for the rest of its
-length. Its end comes between two adjustable contacts. As the
-temperature rises it bends one way (away from the brass side) and, if
-hot enough, touching a contact gives one signal. If the temperature
-falls it curves the other way, and if cold enough touches the other
-contact, giving another signal. (See Thermostat, Electric.)
-
-
-Thermo-electric Couple.
-If two dissimilar conductors form adjacent parts of a closed circuit,
-and their junction is at a different temperature than that of the rest
-of the circuit, a current will result. Such pair of conductors are
-called a thermo-electric couple. They may be joined in series so as to
-produce considerable electro-motive force. (See Thermo-electricity and
-other titles in thermo-electricity.)
-
-The efficiency of a thermo-electric couple according to the second law
-of thermo-dynamics is necessarily low--not over 10 per cent.
-
-
-Thermo-electric Diagram.
-A diagram indicating the change in potential difference for a fixed
-difference of temperature between different metals at different
-temperatures. It is laid out with rectangular co-ordinates. On one axis
-temperatures are laid off, generally on the axis of abscissas. On the
-other axis potential differences are marked. Different lines are then
-drawn, one for each metal, which show the potential difference, say for
-one degree centigrade difference of temperature between their junctions,
-produced at the different temperatures marked on the axis of abscissas.
-
-
-Fig. 333� THERMO-ELECTRIC DIAGRAM, GIVING POTENTIAL DIFFERENCE IN
-C. G. S. UNITS.
-
-
-Thus taking copper and iron we find at the temperature 0� C. (32� F.) a
-difference of one degree C. (1.8� F.) in their junctions will produce a
-potential difference of 15.98 micro volts, while at 274.5� C. (526.1�
-F.) the lines cross, and zero difference of potential is indicated.
-Taking the lead line on the same diagram it crosses the iron line a
-little above 350� C. (662� F.), indicating that if one junction is
-heated slightly above and the other is heated slightly below this
-temperature no potential difference will be produced. Lead and copper
-lines, on the other hand, diverge more and more as the temperature
-rises.
-
-
-533   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thermo-electric Inversion.
-The thermo-electric relations of two conductors vary at different
-temperatures. Sometimes at a definite point they have no electro-motive
-force and after passing this point the positive plate becomes a negative
-one and vice versa. This is inversion, or reversal. (See Thermo-electric
-Diagram.)
-
-Synonym-- Thermo-electric Reversal.
-
-
-Thermo-electricity.
-Electric energy, electro-motive force or electrification produced from
-heat energy by direct conversion. It is generally produced in a circuit
-composed of two electric conductors of unlike material, which circuit
-must possess at least two junctions of the unlike substances. By heating
-one of these to a higher temperature than that of the other, or by
-maintaining one junction at a different temperature from that of the
-other a potential difference is created accompanied by an electric
-current.
-
-In many cases differential application of heat to an identical material
-will develop potential difference. This effect, the converse of the
-Thomson effect, is not used to produce currents, as in a closed circuit
-the potential differences due to differential heating would neutralize
-each other.
-
-
-Thermo-electric Junction.
-A junction between two dissimilar conductors, which when heated or
-cooled so as to establish a differential temperature, as referred to the
-temperature of the other junction, produces potential difference and an
-electric current.
-
-
-Thermo-electric Pile, Differential.
-A thermo-electric pile arranged to have opposite faces subjected to
-different sources of heat to determine the identity or difference of
-temperature of the two sources of heat. It corresponds in use to a
-differential air thermometer.
-
-
-Thermo-electric Power.
-The coefficient which, multiplying the difference of temperature of the
-ends of a thermo-electric couple, gives the potential difference,
-expressed in micro-volts. It has always to be assigned to a mean or
-average temperature of the junctions, because the potential difference
-due to a fixed difference of temperature between two metals varies with
-the average temperature of the two junctions. (See Thermo-electric
-Diagram.)
-
-For bismuth and antimony at 19.5� C. (67.1� F.) it is 103 microvolts per
-degree Centigrade (1.8� F.). This means that if one junction is heated
-to 19� C. and the other to 20� C. (66.2� F. and 68.0� F.) a potential
-difference of 103 micro-volts will be produced.
-
-The potential difference is approximately proportional to the difference
-of temperature of the two junctions if such difference is small. Hence
-for large differences of potential the thermo-electric power coefficient
-does not apply.
-
-As a differential function it is thus deduced by Sir William Thomson,
-for expressing the E. M. F. in a thermo-electric circuit: If a circuit
-is formed of two metals with the junctions at indefinitely near
-temperatures, t and t + dt, and dE is the E. M. F. of the circuit, then
-the differential coefficient dE/dt is called the thermo-electric power
-of the two metals for the temperature t.
-
-
-534   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thermo-electric Series.
-The arrangement of possible thermoelectric elements, q. v., in a table
-in the order of their relative polarity. Bismuth and antimony form a
-couple in which when their junction is heated the bismuth acts as the
-positive or negatively charged element and antimony as the negative or
-positively charged. Between these two extremes according to Seebeck the
-series runs as follows:
-
-  Antimony,   Silver,      Copper,
-  Arsenic,    Gold,        Platinum,
-  Iron,       Molybdenum,  Palladium,
-  Steel,      Tin,         Cobalt,
-  Cadmium,    Lead,        Nickel,
-  Tungsten,   Mercury,     Bismuth.
-  Zinc,       Manganese,
-
-A differential temperature of 1� C. (1.8� F.) in a bismuth-antimony
-couple maintains a potential difference of 103 micro-volts.
-
-Matthiessen gives a different series; it is arranged in two columns; the
-first column has positive coefficients annexed the second has negative.
-On subtracting the greater one from the lesser, which, if the two
-elements are in different columns, of course amounts to adding after
-changing the negative sign, the relative potential difference due to the
-combination is obtained.
-            +                           -
-  Bismuth    25      Gas Coke          0.1
-  Cobalt      9      Zinc              0.2
-  Potassium   5.5    Cadmium           0.3
-  Nickel      5      Strontium         2.0
-  Sodium      3.     Arsenic           3.8
-  Lead        1.03   Iron              5.2
-  Tin         1      Red Phosphorous   9.6
-  Copper      1      Antimony          9.8
-  Silver      1      Tellurium       179.9
-  Platinum    0.7    Selenium        290
-
-Thus the relative E. M. F. of a bismuth-nickel couple, as both are in
-the + column, would be 25 - 5 = 20; that of a cobalt-iron couple, one
-being in the + column the other in the - column, would be 9 + 5.2 =
-14.2. Alloys are not always intermediate to their constituents, and
-small amounts of impurities affect the results largely. This may account
-for the discrepancies of different observers. Other compounds could be
-introduced into the series.
-
-Artificial silver sulphide has been used by Becquerel in a
-thermo-electric battery.
-
-
-535   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thermo-electric Thermometer.
-A species of differential thermometer. It consists of two
-thermo-electric junctions connected in opposition with a galvanometer in
-the circuit. Any inequality of temperature in the two ends or junctions
-produces a current shown by the galvanometer. It may be used to
-determine the temperature of a distant place, one of the junctions being
-located there and the other being under control of the operator. If the
-latter junction is heated until no current is produced its temperature
-is evidently equal to that of the distant couple or junction. The
-heating may be done with hot water or mercury, or other melted metal.
-The temperature of the water, or other substance, gives the temperature
-of the distant place.
-
-
-Thermolysis.
-Decomposition by heat; dissociation. All compound bodies are
-decomposable by heat if it is intense enough. Hence at very elevated
-temperatures there can be no combustion.
-
-Synonym--Dissociation.
-
-
-Thermometer.
-An instrument for indicating the intensity of heat. Three scales of
-degrees of heat are used in practise, the Fahrenheit, R�amur, and
-Centigrade, each of which is described under its own title. (See Zero,
-Thermometric-Zero, Absolute.) The ordinary thermometer depends on the
-expansion of mercury; in some cases alcohol is used. Besides these the
-compound bar principle as used in the thermostat (see Thermostat,
-Electric) is employed.
-
-
-Thermometer, Electric.
-(a) A thermometer whose indications are due to the change of resistance
-in conductors with change of temperature. Two exactly similar resistance
-coils maybe electrically balanced against each other. On exposing one to
-a source of heat, its resistance will change and it will disturb the
-balance. The balance is restored by heating the other coil in a vessel
-of water when the temperature of the water gives the temperature of both
-coils. The coils are enclosed in water-tight metallic cases.
-
-Synonym--Electric Resistance Thermometer.
-
-(b) A differential thermometer may be made by connecting with a pair of
-conductors, two thermo-electric couples in opposition to each other, and
-including a galvanometer in series. On heating the junction of one
-couple more than that of the other a current at once goes through the
-galvanometer.
-
-(c) (See Thermometer, Kinnersley's.)
-
-Synonym--Thermo-electrometer.
-
-
-536   STANDARD ELECTRICAL DICTIONARY.
-
-
-Fig. 334. KINNERSLEY'S THERMOMETER.
-
-
-Thermometer, Kinnersley's.
-A thermo-electrometer. A large glass tube is mounted on a standard and
-communicates with a small tube parallel to it. Water is poured in so as
-to rise in the small tube. Two wires terminating in bulbs enter the
-large tube by its top and bottom. The upper wire can be adjusted by
-moving up and down through a stuffing box. On discharging a Leyden jar
-through the space between the knobs on the two wires the water for a
-moment rises in the small tube. There is little or no accuracy in the
-instrument. It is allied to the electric mortar (see Mortar, Electric)
-as a demonstrative apparatus.
-
-Synonyms--Electric Thermometer--Thermo-electrometer.
-
-
-Thermo-multiplier.
-A thermo-electric battery including a number of couples. The term is
-generally applied to a small battery with its similar junctions facing
-in one direction and used for repeating Melloni's experiments on radiant
-energy, or so-called radiant heat.
-
-
-537   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thermophone.
-An apparatus for reproducing sounds telephonically by the agency of
-heat; a receiving telephone actuated by heat. Thus a wire may be
-attached to the centre of a diaphragm and kept in tension therefrom, and
-the transmitting telephone current may be caused to pass through it. The
-wire changes in temperature and consequently in length with the pulses
-of current going through it and vibrates the diaphragm, reproducing the
-sound. It is to be distinguished from the thermo-electric telephone
-which involves the action of potential difference produced by
-thermo-electric action.
-
-
-Thermostat, Electric.
-A thermostat or apparatus, similar to a thermometer in some cases, for
-closing an electric circuit when heated. It is used in connection with
-automatic fire alarms to give warning of fire. For this use a
-temperature of 52� C. (125� F.) is an approved one for setting one at,
-to complete the circuit. It is also applied to regulation of
-temperature, as in incubators.
-
-(a) One kind of thermostat consists of a compound bar wound into a
-spiral and fastened at one end, to which a terminal of a circuit is
-connected. The bar may be made of two strips of brass and iron riveted
-together, and wound into a spiral. When such a bar is submitted to
-changes of temperature it bends in different directions, because brass
-expands and contracts more under changes of temperature than does iron.
-A contact point, to which the other terminal is connected, is arranged
-to make contact with the spiral at any desired degree of temperature,
-thus closing an electric circuit and ringing a bell, opening or closing
-a damper, or doing anything else to notify an attendant or to directly
-change the temperature.
-
-If the brass forms the outside of the spiral, increase of temperature
-makes the bending of the spiral bring the coils still closer. If the
-brass forms the inside, increase of temperature makes the spiral tend to
-become less close. As shown in the cut, the brass should lie along the
-inside of the spiral.
-
-Sometimes a straight compound bar is used, one of whose ends is fastened
-and the other is free. As the temperature changes such a bar curves more
-or less, its free end moving to and fro. Two contact screws are
-provided, one on each side of its free end. If the temperature falls it
-makes contact with one of these; if the temperature rises, it makes
-contact with the other. Thus it may close one of two circuits, one for a
-fall and the other for a rise in temperature.
-
-It is well to introduce a third bar between the brass and iron ones,
-made of some material of intermediate coefficient of expansion.
-
-(b) Another kind of thermostat comprises a vessel of air or other gas,
-which, expanding by heat, actuates a piston or other device and closes
-an electric circuit. Synonym--Electro-pneumatic Thermostat.
-
-(c) Another form utilizes the expansion of mercury. The mercury is made
-part of an open electric circuit. As it expands it comes in contact with
-the other terminal of the circuit, thus completing it, when the current
-gives an alarm or does as is provided for in the apparatus employed.
-
-Thermostats may be worked on either open or closed circuits; normally
-the circuit may be open as described and may close on rise of
-temperature, or it may be normally closed and open as the temperature
-rises.
-
-
-Fig. 335. ELECTRIC THERMOSTAT.
-
-
-538   STANDARD ELECTRICAL DICTIONARY.
-
-
-Thomson Effect.
-In an unequally heated conductor the differential heating is either
-increased as in iron, or diminished as in copper by a current. In lead
-the phenomenon does not occur. It is termed the Thomson effect. It is
-intimately related to the Peltier effect.
-
-In a thermo-electric couple a heated junction is the source of
-electro-motive force, if heated more than other parts of the circuit.
-The current in a copper-iron junction flows from the copper to the iron
-across the heated junction. A hot section of an iron conductor next to a
-cold section of the same is a source of thermoelectricity, in the sense
-that the hot section is negative to the colder. A current passing from
-the hot to the cold iron travels against rising potentials, and cools
-the iron in the cooler parts. As it passes to the hotter parts it
-travels against falling potentials and hence heats the iron in these
-parts. In this way a current intensifies differential heating in an iron
-conductor.
-
-In copper the reverse obtains. In it the thermo-electric relations of
-hot and cold copper are the reverse of those of iron, and a current
-tends to bring all parts of a differentially heated copper conductor to
-an identical temperature.
-
-As a current travels in iron from hot to cold it absorbs heat; in copper
-traveling from cold to hot it absorbs heat.
-
-The convection of heat by a current of electricity in unequally heated
-iron is negative, for it is opposed to that convection of heat which
-would be brought about by the flow of water through an unequally heated
-tube. In copper, on the other hand, the electric convection of heat is
-positive. (Daniell.)
-
-The above effects of the electric current upon an unequally heated
-conductor are termed the Thomson effects. In iron, at low red heat, they
-are reversed and are probably again reversed at higher temperatures.
-
-
-539   STANDARD ELECTRICAL DICTIONARY.
-
-
-Three Wire System.
-A system of distribution of electric current for multiple arc or
-constant potential service. It is the invention of Thomas A. Edison.
-
-It includes three main wires which start from the central station or
-generating plant, and ramify with corresponding reduction in size,
-everywhere through the district or building to be lighted. As ordinarily
-carried out when dynamos are used, the dynamos are arranged in groups of
-two. One lateral lead starts from the negative binding post of one
-dynamo. The positive terminal of this dynamo connects to the negative of
-the other. Between the two dynamos the central or neutral lead is
-connected. The other lateral lead starts from the positive binding post
-of the second dynamo.
-
-The lamps or other appliances are calculated for the potential
-difference of a single dynamo. They are arranged between the neutral
-wire and the laterals, giving as even a disposition as possible to the
-two laterals.
-
-
-Fig. 336. DIAGRAM OF THREE WIRE SYSTEM SHOWING NEUTRAL WIRE.
-
-
-If evenly arranged and all burning or using current, no current goes
-through the neutral wire. If all the lamps situated on one lateral are
-on open circuit all the current goes through the neutral wire. In other
-cases the neutral wire receives the excess of current only.
-
-The advantages of the system are that it uses smaller wire than the two
-wire system for lamps of the same voltage. If lamps of double the
-voltage were used the two wire system would be most economical.
-
-
-540   STANDARD ELECTRICAL DICTIONARY.
-
-
-Four wire and five wire systems have been more or less used, based on
-identical considerations, and involving in each case the coupling of
-three or of four dynamos respectively, or else employing a dynamo with
-special armature connections to give the requisite three-fold or
-four-fold division of total potential. In the five wire system the total
-voltage is four times that of a single lamp, the lamps are arranged four
-in series across the leads and the central wire is the only one that can
-be considered a neutral wire. When lamps are burning entirely from three
-side-leads they constitute a sort of three wire system by themselves,
-and their central wire may for the time be a neutral wire.
-
-In some of the three wire mains, especially in the larger sizes, the
-neutral wire is made of much smaller section than that of a lateral
-conductor, because in extensive districts it is practically impossible
-that the current should be concentrated in the neutral wire.
-
-
-Throw.
-In a galvanometer the instantaneous deflection of the needle when the
-contact or closing of the circuit is instantaneous, or when the
-discharge is completed before the needle begins to move. The throw of
-the needle is the datum sought when the ballistic galvanometer is used.
-
-Synonym--Elongation.
-
-
-Throw-back Indicator.
-A drop annunciator, whose shutter or drop is electrically replaced.
-
-
-Thrust-bearings.
-Bearings to support the end-thrust or push of a shaft. In disc armatures
-where the field-magnets attract the armatures in the direction of their
-axis of rotation, thrust-bearings have to be provided. In ordinary
-cylinder or drum armatures end-thrust is not applied, as a little end
-motion to and fro is considered advantageous as causing more even wear
-of the commutator surface.
-
-
-Thunder.
-The violent report which, as we hear it, succeeds the lightning flash in
-stormy weather. It is really produced simultaneously with the lightning
-and is supposed to arise from disturbance of the air by the discharge.
-The rolling noise has been attributed to successive reflections between
-clouds and earth, and to series of discharges reaching the ear from
-different distances and through air of varying density. The subject is
-obscure. By timing the interval from lightning flash to the report of
-the thunder an approximate estimate of the distance of the seat of
-discharge can be made. The first sound of the thunder should be timed.
-An almost concurrence of thunder and lightning indicates immediate
-proximity of the discharge.
-
-[Transcriber's note: The speed of sound at sea level is about 5 seconds
-per mile.]
-
-
-Ticker.
-A colloquial name for a stock or market report automatic printing
-telegraph, which prints its quotations and messages on a long tape.
-
-
-541   STANDARD ELECTRICAL DICTIONARY.
-
-
-Time Constant.
-(a) When current is first turned into a circuit of considerable
-self-induction it is resisted rather by the inductance than by the
-resistance. It is governed by the ratio of resistance and self-induction
-and this factor represents the time which it takes for the current to
-reach a definite fraction of its final strength. This fraction is
-(2.7183 - 1)/2.7183  or 0.63. 2.7183 is the base of the Napierian system
-of logarithms. Thus if in any circuit we divide the inductance in
-henries by the resistance in ohms, the ratio gives the time-constant of
-the circuit, or it expresses the time which it will take for the current
-to reach 0.63 of its final value.
-
-(b) In a static condenser the time required for the charge to fall to
-1/2.7183th part of its original value.
-
-
-Time Cut-outs.
-Cut-outs which automatically cut storage batteries out of the charging
-circuit when they are sufficiently charged.
-
-
-Time-fall.
-In a secondary battery the decrease with use of electromotive force
-maintained by a primary or secondary battery. As the battery becomes
-spent its voltage falls. The conditions of the fall are represented by
-its discharging curve. (See Curve, Discharging.)
-
-
-Time-reaction.
-A term in electro-therapeutics; the period of time occupied in the
-passage of the effects of an electric current from nerve to muscle.
-
-
-Time-rise.
-In a secondary battery the increase of electromotive force produced
-during the charging process. Its rate and conditions are graphically
-shown in the charging curve. (See Curve, Charging.)
-
-
-Tin.
-A metal; one of the elements; symbol, Sn; atomic weight, 117.8;
-equivalent, 58.9 and 29.5; valency, 2 and 4; specific gravity, 7.3.
-It is a conductor of electricity.
-
-  Relative resistance, compressed, (Silver = 1)   8.784
-  Specific resistance at 0� C. (32� F.),   13.21   microhms.
-  Resistance of a wire at 0� C. (32� F.),
-  (a) 1 foot long, weighing 1 grain,       1.380   ohms.
-  (b) 1 foot long, 1/1000 inch thick,     79.47     "
-  (c) 1 meter long, weighing 1 gram,        .9632   "
-  (d) 1 meter long, 1 millimeter thick,     .1682   "
-  Resistance of a 1 inch cube at 0� C. (32� F.),   5.202   microhms.
-  Percentage of variation in resistance
-    per degree C. (1.8� F.), at about 20� C. (68� F.),  .0365
-  Electro-chemical equivalent (hydrogen = .0105),   .619   mgs.
-                                                    .310   "
-
-542   STANDARD ELECTRICAL DICTIONARY.
-
-
-Tinnitus, Telephone.
-A nervous affection of the ear, of the order of professional cramp; it
-is attributed to too much use of the telephone.
-
-
-Tin Sounders.
-A recent addition to the single needle telegraph. (See Telegraph, Single
-Needle.) It consists of small tin plates, cut and bent, and so fitted in
-pairs to the instrument, that the needle as deflected strikes one or the
-other on its right and left hand movements. The sounders can be made to
-give sufficiently distinctive sounds to make sound-reading, q. v.,
-possible. Commercial tin plate, which is really tinned iron, seems to
-give the best results.
-
-
-Fig. 337. TIN SOUNDERS.
-
-
-Tissandier's Solution.
-A solution for bichromate batteries. It is composed as follows:
-  Water,                100 parts by weight
-  potassium bichromate,  16 parts
-  66� sulphuric acid,    37 parts.
-
-
-Tongue of Polarized Relay.
-The German silver extension of the vibrating or oscillating member of a
-polarized relay, corresponding to the armature of an ordinary relay.
-
-
-Tongue of Polarized Relay, Bias of.
-In a Siemens' polarized relay the pole pieces are adjustable so that
-they may be brought nearer to or withdrawn from the tongue. One of the
-poles is adjusted so as to be nearer the tongue. This one-sided
-adjustment is the bias. Its effect is that when the relay is unexcited
-this pole attracts the armature so that it normally is drawn towards it.
-This ensures the normal contact of the tongue either with the contact
-point, or with the insulated stop piece or adjustment screw. Without
-bias the armature remains in contact with or drawn towards whichever
-pole it was last attracted to. In its usual use a bias is given it.
-
-
-Top, Magnetic.
-A toy illustrating magnetic attraction. It consists of a disc or body of
-lead or other material, through which a magnetized steel spindle pointed
-at its lower end is thrust. A number of short pieces of iron wire are
-used with it. It is spun like an ordinary top upon the point of the
-spindle and one of the pieces of iron wire is laid by the side of its
-point. As it turns the magnetic adherence causes the piece of wire to be
-carried along in one direction by the rotation of the spindle, until the
-end is reached, when it goes over to the other side of the spindle and
-travels back again.
-
-By using bent pieces of wire of various shapes the most curious effects
-are produced. Circles and S shaped pieces give good effects. To increase
-the mysterious effect covered iron wire (bonnet wire) may be employed.
-
-
-Fig. 338. MAGNETIC TOP.
-
-
-543   STANDARD ELECTRICAL DICTIONARY.
-
-
-Torpedo, Electric.
-(a) A fish, the Raia Torpedo, which possesses the power of giving
-electric shocks. (See Ray, Electric.)
-
-(b) An instrument of war; a torpedo whose operations include electrical
-discharge or other electric function or factor of operation.
-
-
-Torpedo, Sims-Edison.
-A torpedo driven by an electric motor, and also steered by electricity.
-Its motions are all controlled from the shore. The torpedo proper is
-carried some distance below the surface of the water by a vessel
-immediately above it, from which it is suspended by two rigid bars. In
-the torpedo is a cable reel on which the conducting cable is disposed.
-An electric motor and controlling gear are also contained within the
-torpedo. In its front the explosive is placed. It is driven by a screw
-propeller actuated by the electric motor. As it moves it pays out cable
-so that it has no cable to draw after it through the water, the cable
-lying stationary in the water behind it. This avoids frictional
-resistance to its motion. The maintenance of the torpedo at a proper
-depth is one of the advantages of the system.
-
-
-544   STANDARD ELECTRICAL DICTIONARY.
-
-
-Torque.
-A force tending to produce torsion around an axis. An example is the
-pulling or turning moment of an armature of an electric motor upon its
-shaft. It is often expressed as pounds of pull excited at the end of a
-lever arm one foot long.
-
-The expression is due to Prof. James Thompson, then of the University of
-Glasgow.
-
-"Just as the Newtonian definition of force is that which produces or
-tends to produce motion (along a line), so torque may be defined as that
-which produces or tends to produce torsion (around an axis). It is
-better to use a term which treats this action as a single definite
-entity than to use terms like 'couple' and 'moment,' which suggest more
-complex ideas." (S. P. Thompson.)
-
-A force, acting with radius r gives a torque equal to f X r ;  f and r
-may be expressed in any units. S. P. Thompson gives the following
-equivalents :
-
-To reduce
-  dyne-centimeters to gram centimeters, divide by   981
-  dyne-centimeters to meter-kilograms   divide by   981E5
-  dyne-centimeter, to pound-feet        divide by   13.56E6
-  pound-feet to meter-kilograms         divide by   7.23
-
-In each of these compound units the first unit is the force and the
-second unit is the radius or lever arm of the torque.
-
-Synonyms--Turning Moment--Moment of Couple--Axial Couple--Angular
-Force--Axial Force.
-
-
-Torsion Balance, Coulomb's.
-Originally an apparatus in which electrostatic attraction or repulsion
-is measured against the torsion of a filament, often of silk-worm cocoon
-fibre. It consists in one form of a cylindrical glass vessel in which a
-light shellac needle is suspended horizontally by a fibre. This needle
-carries at one end a gilded disc or sphere and is suspended by a fine
-wire, or filament. A proof plane, q. v., is excited by touching it to
-the body under trial; it is then inserted in the case. The disc on the
-needle is first attracted and then repelled. The position finally taken
-by the needle is noted. The force of torsion thus produced is determined
-by twisting the filament by the torsion head on the top of the apparatus
-so as to move the needle a certain distance towards the proof plane. The
-more the torsion-head has to be turned to carry the needle through a
-specified arc the greater is the torsion effected or the greater is the
-repulsion exerted, The torsional force of a wire is proportional to the
-angle of torsion; this gives the basis for the measurement.
-
-With magnetic needle it is used to measure magnetic repulsion and
-attraction. The best material for the filament is quartz, but the
-instrument is not very much used.
-
-
-Torsion Galvanometer.
-A galvanometer in which the torsion required to bring the index back to
-zero, when the current tends to displace it, is made the measure of the
-current strength or of the electro-motive force. It involves the use of
-a torsion head, q. v., or its equivalent.
-
-
-545   STANDARD ELECTRICAL DICTIONARY.
-
-
-Torsion Head.
-The handle and disc from whose undersurface the filament depends to
-which the needle or magnet is attached. It is turned to measure the
-torsional effect, the edge of the disc being marked or graduated so as
-to give the angle of deflection required to overcome the effect of the
-torque of the needle.
-
-
-Torsion Suspension.
-Suspension by one or more wires, fibres, or ribands, involving the
-restitutive force of torsion. Thus fibre suspension, q. v., is a variety
-of torsion suspension.
-
-Often a single riband of steel stretched horizontally and secured at
-both ends is used, the suspended object, e. g., a balance beam, being
-attached at its own centre to the centre of the stretched riband. Quite
-sensitive balances are constructed on this principle. It is peculiarly
-available where an electric current is to be transmitted, as absolute
-contact is secured, as in William Thomson's ampere balances.
-
-
-Touch.
-A term applied to methods of magnetization, as "single touch," "double
-touch," or "separate touch," indicating how the poles of the inducing
-magnet or magnets are applied to the bar to be magnetized. Under the
-titles of Magnetization the different methods are described.
-
-
-Tourmaline.
-A mineral; a subsilicate; characterized by the presence of boric
-trioxide, which replaces aluminum oxide. It is notable for possessing
-pyro-electric properties. (See Pyro-electricity.)
-
-
-Tower, Electric.
-The tower used in the tower system, q. v., of arc light illumination.
-
-
-Tower System.
-In electric lighting the system of lighting extended areas by powerful
-arc lamps placed on high towers, generally of iron or steel frame-work.
-The lights are thus maintained at a high elevation, giving greater
-uniformity of illumination than if they were lower, but at the expense
-of considerable light which is lost. Sometimes wooden masts are employed
-instead of towers.
-
-The principle involved is that the intensity of light at any place given
-by a source of illumination varies with the square of its distance from
-the place in question. Hence in using strong arc lights it is an object
-to have the distances of all parts of the area illuminated at as nearly
-uniform distances from the light as possible. An approximation to
-uniformity is secured by placing the lamps at a very high elevation.
-
-
-546   STANDARD ELECTRICAL DICTIONARY.
-
-
-Transformer.
-In alternate current lighting the induction coil by which the primary
-current with high initial electro-motive force is caused to produce a
-secondary current with low initial electromotive force.
-
-A typical transformer consists of a core of thin iron sheets. The
-primary is of comparatively thin wire and often of ten or more times as
-many turns as the secondary. The latter is of thicker wire. Where the
-ratio of 10 to 1 as regards number of turns in the primary and secondary
-obtains, the initial E. M. F. of the secondary is one-tenth that of the
-primary circuit.
-
-The cores are laminated, as described, to avoid the formation of
-Foucault currents.
-
-The counter-electro-motive force of the transformer when the secondary
-circuit is open, prevents any but the slightest current from passing
-through the primary. In proportion as the secondary is closed and its
-resistance diminished, as by lighting more lamps in parallel, the
-counter-electro-motive force of the transformer falls and more current
-passes through the primary.
-
-
-Fig. 339. FERRANTI'S TRANSFORMER.
-
-The economy of the apparatus is in the fact that counter-electromotive
-force reduces current through a conductor without absorbing any energy.
-A resistance coil cuts down a current, but absorbs energy equal to the
-current multiplied by the potential difference between the terminals of
-the coil. This electric energy is converted into heat energy and is
-wasted. But the counter-electromotive force of a transformer is exerted
-to reduce current without production of heat and with little waste of
-energy. This is one of the advantages of the alternating current system
-of distribution of electric energy.
-
-The object of a transformer being to secure safety to the person or to
-life by the separation of the high potential primary or street circuit,
-and the low potential house circuit, any contact of the two circuits in
-the converter is a source of danger. Special care should be taken to
-ensure absence of leakage, as it is termed. Mica or other insulation is
-sometimes employed to prevent the wires from coming in contact by
-piercing or sparking with the core and with each other.
-
-
-547   STANDARD ELECTRICAL DICTIONARY.
-
-
-Transformer, Commuting.
-A type of continuous current transformer, resembling a dynamo with
-armature and field both stationary, but with revolving commutator, by
-which the magnetic polarity of a double wound armature is made to
-rotate. This secures the desired action, of a change or lowering of
-potential.
-
-
-Transformer, Continuous Alternating.
-An apparatus for transforming a continuous into an alternating current
-or the reverse. The combination of a continuous current dynamo with an
-alternating current one is sometimes employed. It is a form of motor
-dynamo.
-
-Another type is a regular dynamo with ordinary commutator and with, in
-addition thereto, two, three or four contact rings, connecting to as
-many symmetrically disposed points in the winding of the armature. This
-will give out or receive alternating currents of two, three or four
-phases according to the number of collecting rings. One winding serves
-for both alternating and continuous currents.
-
-
-Transformer, Continuous Current.
-A machine of the dynamo type for changing the potential of a circuit. In
-one form two armatures are mounted on one shaft in a single field or in
-separate fields; one is a motor armature driven by the original current;
-the other generates the new current. This is a motor dynamo. In 1874
-Gramme constructed a machine with ring armature with two windings, of
-coarse and fine wire respectively, and with independent commutators.
-Such dynamo could transform currents up or down.
-
-Continuous current transformers have attained an efficiency of 83 per
-cent. at full load, and of 75 per cent. at half load. Owing to the
-balancing of the self-inductions of the two windings these machines do
-not spark. As the driven and driving parts are contained in one rotating
-part their friction is very slight.
-
-
-Transformer, Core.
-A transformer wound upon an enclosed core, such as the hedgehog
-transformer (see Transformer, Hedgehog), or common induction coil.
-
-
-548   STANDARD ELECTRICAL DICTIONARY.
-
-
-Transformer, Hedgehog.
-An induction coil transformer whose iron core is composed of a bundle of
-iron wires, which after the wire windings are in place have their ends
-spread out to reduce to some extent the reluctance of the circuit, which
-at the best is high, as the air acts as the return circuit.
-
-This transformer has a low degree of hysteresis; and its efficiency for
-very small loads or for no load is superior to that of the closed
-magnetic circuit transformer.
-
-
-Fig. 340. SWINBURNE'S HEDGEHOG TRANSFORMER.
-
-
-Transformer, Multiple.
-A transformer connected in parallel with others between the two leads of
-the primary circuit. The term refers to the connection only and not to
-any peculiarity of the transformer itself.
-
-
-Transformer, Oil.
-A transformer with oil insulation. The advantage of this insulation is
-that if pierced it at once closes, so that no permanent injury ensues.
-It is a self-healing form of insulation.
-
-
-Transformer, Series.
-Transformers connected in series upon the primary circuits. The term,
-like "multiple transformers," only applies to the connection, not to the
-transformer. Series transformers are but little used.
-
-
-Transformer, Shell.
-A transformer with its iron core entirely outside of and enclosing the
-primary and secondary winding. It may be made by the use of outer iron
-wire windings as core.
-
-
-Transformer, Welding.
-The transformer used for electric welding. (See Welding, Electric.) It
-is a transformer with very long primary and exceedingly short and thick
-secondary. It is used with the alternating current in the primary, and
-produces in the secondary circuit which includes the bars to be welded a
-very low potential difference.
-
-Owing to the very low resistance of the secondary circuit this low
-electro-motive force produces a very strong current, which develops the
-requisite heat. The same type of transformer is used for brazing and
-similar purposes.
-
-
-549   STANDARD ELECTRICAL DICTIONARY.
-
-
-Transmitter.
-In general electric phraseology, any instrument which produces signals
-to be transmitted through a line or circuit is a transmitter. Thus the
-Morse key in telegraphy or the Blake transmitter in telephony are
-examples of such.
-
-
-Transmitter, Carbon.
-A form of microphone used as a telephone transmitter. (See Carbon
-Telephone.)
-
-
-Transposing.
-A method of laying metallic circuits for telephoning. The wires at short
-intervals are crossed so that alternate sections lie on opposite sides
-of each other. It is done to avoid induction.
-
-
-Transverse Electro-motive Force.
-Electro-motive force in a substance in which electric displacement is
-taking place, produced by a magnetic field. It is sometimes assigned as
-the cause of the Hall effect, q. v.
-
-
-Trimmer, Brush.
-A shears for cutting off evenly and squarely the ends of copper dynamo
-brushes. The brushes when uneven from wear are removed from the brush
-holders, and their ends are sheared off in the trimmer.
-
-
-Trolley.
-A grooved metallic pulley or set of pulleys which runs along an active
-wire of a circuit, a lead from which trolley goes to earth or connects
-with another wire, so that the trolley takes current generally for
-operating a street car motor placed upon the circuit leading from it; a
-rolling contact with an electric lead.
-
-Trolleys are principally used on electric railroads, and are now
-universally of the sub-wire system, being at the end of a pole which is
-inclined backward and forced upward by springs, so as to press the
-trolley against the bottom of the wire. Thus the trolley does not
-increase the sagging of the wire, but tends to push it up a little in
-its passage.
-
-
-Trolley, Double.
-A trolley with two rollers or grooved wheels, placed side by side, and
-running on two parallel leads of wire. It is adapted to systems
-employing through metallic trolley lines with the motors in multiple
-arc, connecting or across the two leads.
-
-
-Trolley Section.
-An unbroken or continuous section of trolley wire.
-
-
-Trouv�'s Solution.
-An acid exciting and depolarizing solution for a zinc-carbon battery.
-Its formula is as follows: Water, 80 parts; pulverized potassium
-bichromate, 12 parts; concentrated sulphuric acid, 36 parts; all parts
-by weight. The pulverized potassium bichromate is added to the water,
-and the acid is added slowly with constant stirring. As much as 25 parts
-potassium bichromate may be added to 100 parts of water. The heating
-produced by the acid and water dissolves nearly all the potassium salt.
-Use cold.
-
-
-550   STANDARD ELECTRICAL DICTIONARY.
-
-
-True Contact Force.
-A species of electro-motive force whose existence is supposed to be
-proved by the Peltier effect. The lowering in temperature of a contact
-of dissimilar metals is attributed to a force that helps the current on
-its way if in the direction of thermo-current proper to the junction and
-opposing it if in the reverse. The true contact force is taken to
-explain this phenomenon; thermo-electric force cannot, as there is no
-heat or cold applied to the junction.
-
-
-Trumpet, Electric.
-An apparatus consisting of a vibrating tongue, kept in motion by
-electricity as in the buzzer, q. v., placed in the small end of a
-trumpet-shaped tube.
-
-
-Trunking Switchboard.
-A telephone switchboard arranged in sections, which sections are
-connected by trunk lines, through which trunk lines the desired
-connections
-are made.
-
-
-Trunk Lines.
-In telephone distribution systems, the lines connecting different
-stations, or different sections of a switch-board and used by anyone
-requiring such connections; one trunk line answers for a number of
-subscribers.
-
-
-Tube, Electric.
-A tube of glass around which is pasted a series of tinfoil circles,
-diamonds, or little squares, or other form of interrupted conductor. The
-pieces generally are placed in the line of a spiral. When a static
-discharge of electricity takes place along the conductor a row of bright
-sparks is produced at the breaks in the conductor. These by reflection
-are multiplied apparently, and a beautiful effect of intersecting or
-crossing spirals of sparks is presented.
-
-The experiment is in line with the luminous pane and lightning jar, and
-is used merely as a demonstration, or lecture experiment.
-
-Synonym--Luminous Tube.
-
-
-Tubular Braid.
-A braid woven of tissue or worsted, and tubular or hollow. Its object is
-to provide a covering which can be drawn over joints in covered wires.
-In making the joint the ends of the wires are necessarily bared, and a
-short piece of tubular braid is used for covering them. It is drawn by
-hand over the joint.
-
-
-Turns.
-An expression applied to the convolutions of wire in a solenoid,
-electro-magnet, or other apparatus or construction of that kind. A turn
-indicates a complete encircling of the core or axis of the object. Thus
-a wire wound five times around a bar gives five turns.
-
-While this is its primary meaning the term if compounded may refer to
-virtual turns. Thus an ampere-turn means one ampere passing through one
-turn. But ten ampere-turns may mean ten amperes passing through ten
-turns, five amperes passing through two turns, and so on. This use is
-analogous to a dimension of length in a compound word, as foot-pound.
-
-[Transcriber's note: "But ten ampere-turns may mean ten amperes passing
-through ONE turn or one ampere through ten turns, and so on."]
-
-There may be a number of kinds of turns qualified by descriptive
-adjectives, as series-turns, the turns of wire in a series circuit of a
-compound dynamo. In the same way there are shunt-turns. If series
-ampere-turns or shunt ampere-turns are meant the word ampere should be
-included.
-
-
-551   STANDARD ELECTRICAL DICTIONARY.
-
-
-Turns, Dead, of a Dynamo.
-The rotations of a dynamo armature while it is building itself up or
-exciting itself. The expression is a bad one, as it is likely to be
-confounded with the dead turns of armature wire.
-
-
-Turns, Primary Ampere-.
-The ampere-turns in a primary circuit of an induction coil or
-transformer. In an electric welding transformer, or in the transformer
-used in the alternating current system, where efficiency is an important
-element, the ampere-turns in primary and secondary for an efficiency of
-100 per cent. should be equal. In the case of an experimental induction
-coil other considerations outweigh that of mere efficiency. Insulation,
-including security from piercing, and the production of as long a spark
-as possible, are, in these cases, the controlling consideration.
-
-[Transcriber's note: A 100 per cent efficient transformer is impossible,
-but over 99 per cent is common. At room temperature there is always some
-lost flux, eddy currents and resistive losses.]
-
-
-Turns, Secondary Ampere-.
-The ampere-turns on the secondary circuit of an induction coil or
-transformer. These depend on the path provided for the current. If of
-negligible inductance, such as a number of incandescent lamps would
-provide, the ampere-turns should be equal to those of the primary coil.
-(See Turns, Primary Ampere.)
-
-
-Typewriter, Electric.
-A typewriter in which the work of printing or of pressing the type faces
-against the paper, or printing ribbon, is done by electro-magnetic
-attraction. The keys close electric circuits, throwing the
-electro-magnetic action into play. This involves the use of electricity
-for what is ordinarily only a mechanical process. The strength of the
-impression, however, is independent of the touch of the operator. It has
-not come into very extensive use.
-
-[Transcriber's note: IBM introduced widely used electric typewriters in
-1935.]
-
-
-Ultra-gaseous Matter.
-Gas so rarefied that its molecules do not collide or very rarely do so.
-
-Experiments of very striking nature have been devised by Crookes and
-others to illustrate the peculiar phenomena that this matter presents.
-The general lines of this work are similar to the methods used in
-Geissler tube experiments, except that the vacua used are very much
-higher.
-
-When the vacuum is increased so that but one-millionth of the original
-gas is left the radiant state is reached. The molecules in their kinetic
-movements beat back and forth in straight lines without colliding, or
-with very rare collisions. Their motions can be guided and rendered
-visible by electrification. A tube or small glass bulb with platinum
-electrodes sealed in it, is exhausted to the requisite degree and is
-hermetically sealed by melting the glass. The electrodes are connected
-to the terminals of an induction coil or other source of high tension
-electrification. The molecules which come in contact with a negatively
-electrified pole are repelled from it in directions normal to its
-surface. They produce different phosphorescent or luminous effects in
-their mutual collisions.
-
-Thus if they are made to impinge upon glass, diamond or ruby, intense
-phosphorescence is produced. A piece of platinum subjected to molecular
-bombardment is brought to white heat. A movable body can be made to move
-under their effects. Two streams proceeding from one negative pole repel
-each other. The stream of molecules can be drawn out of their course by
-a magnet.
-
-The experiments are all done on a small scale in tubes and bulbs,
-resembling to a certain extent Geissler tubes.
-
-[Transcriber's note: These effects are caused by plasma--ionized gas and
-electrons.]
-
-
-552   STANDARD ELECTRICAL DICTIONARY.
-
-
-Unbuilding.
-The loss of its charge or excitation by a self-exciting dynamo. It is
-the reverse of building-up. The latter indicates the exciting of the
-field by the action of the machine itself; the former the spontaneous
-loss of charge on open circuit or from other cause.
-
-
-Underground Conductor.
-An electric conductor insulated and placed under the surface of the
-earth, as distinguished from aerial conductors.
-
-
-Underground Electric Subway.
-A subway for the enclosing of electric telegraph and other conductors
-under the surface, generally in the line of streets, to do away with
-telegraph poles and aerial lines of wire. Many systems have been
-devised. The general type includes tubes called ducts in sets, called
-conduits, bedded in concrete or otherwise protected. Every two or three
-hundred feet the sets lead into a cistern-like cavity called a manhole.
-The insulated wires or cables, generally sheathed with a lead alloy are
-introduced into the tubes through the man-holes. A rope is first fed
-through the tube. To do this short rods which screw together are
-generally employed. One by one they are introduced, and each end one is
-screwed to the series of rods already in the duct. When the end of the
-duct is reached the rope is fastened to the last rod, and the rods are
-then drawn through, unscrewed one by one and removed, the rope following
-them. By means of the rope a windlass or capstan may be applied to draw
-the cable into the duct. At least at every second man-hole the cables
-have to be spliced.
-
-Each cable may contain a large number of conductors of small size for
-telephoning, or a smaller number for electric light and power. The
-tendency is now to separate the different classes of wires in important
-lines, placing the heavier wires on one side of the street and the
-telephone and telegraph wires on the other. This of course necessitates
-two separate conduits.
-
-The advantage of underground distribution affects not only the
-appearance of streets in doing away with unsightly telegraph poles, but
-it also removes an element of danger at fires. Aerial wires interfere
-greatly with the handling of ladders at fires, and expose the firemen
-who attempt to cut them to danger to their lives from shock.
-
-
-533   STANDARD ELECTRICAL DICTIONARY.
-
-
-Unidirectional. adj.
-Having one direction as a "unidirectional current" or "unidirectional
-leak." The term is descriptive, and applicable to many cases.
-
-
-Uniform. adj.
-Unvarying; as a uniform potential difference, uniform current or
-conductor of uniform resistance per unit of length. The term is
-descriptive, and its application and meaning are obvious.
-
-
-Uniform Field of Force.
-A field of evenly distributed force; one in which the number of lines of
-force per unit of area of any equipotential surface is the same.
-
-
-Unipolar. adj.
-Strictly speaking this term means having only one pole, and is applied
-to magnets, armatures and the like. In its use a solecism is involved,
-for there is no such condition possible as unipolar magnetism or
-distribution of magnetism. An example of its use is shown in unipolar
-magnets. (See Magnet, Unipolar.)
-
-
-Unipolar Armature.
-An armature of a unipolar dynamo; an armature whose windings
-continuously cut the lines of force about the one pole, and hence whose
-polarity is unchanged in its rotation.
-
-
-Unipolar Current Induction.
-Current induction produced by moving a conductor through a magnetic
-field of force so that it always cuts the lines in similar relation to
-itself. Thus it produces a constant current through its own circuit, if
-a closed one, and no commutator is required. As this case always in
-practice amounts to the cutting of lines of force in the neighborhood of
-a single pole the term unipolar is employed to designate the action.
-
-The simplest representation of unipolar induction is the rotating of a
-conductor around the end of a bar magnet, its axis of rotation
-corresponding with the axis of the magnet.
-
-
-Unipolar Dynamo.
-A dynamo in which one part of the conductor slides on or around the
-magnet, so as always to cut lines of force near the same pole of the
-magnet.
-
-
-Unit.
-A directly or indirectly conventional and arbitrary quantity, in terms
-of which measurements of things with dimensions expressible in the
-chosen units are executed.
-
-Thus for length the c. g. s. unit is the centimeter; the B. E. unit is
-the foot.
-
-
-554   STANDARD ELECTRICAL DICTIONARY.
-
-
-Unit, Absolute.
-A unit based on the three fundamental units of length, mass and time.
-These units are the centimeter, gram and second. Each one in itself may
-be termed a fundamental absolute unit. The system of such units is
-termed the centimeter-gram-second system.
-
-
-Unit, Angle.
-A factor or datum in angular velocity, q. v. It is the angle subtended
-by a portion of the circumference equal in length to the radius of the
-circle. It is equal very nearly to 57.29578� or 57� 17' 44.8".
-
-
-Unit, B. A.
-This term, while logically applicable to any of the British Association
-units, is often restricted to the ohm as formerly defined by the British
-Association, the B. A. Unit of Resistance, q. v.
-
-
-Unit, Fundamental.
-The three units of length, mass and time, the centimeter, gram and
-second, are termed fundamental units. On them is based the absolute
-system of units, and on multiples of them the practical system of units.
-
-
-Unit Jar.
-A Leyden jar which is used as a unit of measure of charge.
-
-It consists of a Leyden jar about 4 inches long and 3/4 inch diameter,
-with about 6 square inches of its outer and the same of its inner
-surface coated with tinfoil. It is placed between a source of
-electricity and a larger jar or battery of jars which is to be charged.
-The inner coating connects with the machine; the outer coating with the
-jars to be charged. Short conductors terminating in knobs connect with
-inner and outer coatings, and the knobs are adjusted at any desired
-distance apart.
-
-By the charging operation the large jar or battery of jars receives a
-charge by induction, and the charge of the small jar is at first equal
-to this quantity. After a while a spark passes from knob to knob,
-discharging the small jar. This indicates the reception by the large
-jars of the quantity of electricity represented by the charge of the
-small jar. The charging goes on, and for every spark approximately the
-same quantity of electricity is received by the larger jars.
-
-The sparking distance m is directly proportional to the quantity of
-electricity, and inversely proportional to the area of coated surface,
-or is proportional to the potential difference of the two coats. This is
-only true for short sparking distance, hence for accuracy the knobs
-should be adjusted not too far from each other.
-
-
-555   STANDARD ELECTRICAL DICTIONARY.
-
-
-Unit of Supply.
-A commercial unit for the sale of electric energy, as defined
-provisionally by the English Board of Trade; 1,000 amperes flowing for
-one hour under an E. M. F. of 1 volt; 3,600,000 volt-coulombs, or 1,000
-watt-hours, are its equivalent. It is equal to 1000/746 = 1.34 electric
-horse power.
-
-Synonym--Board of Trade Unit.
-
-[Transcriber's note: Now called a kilowatt-hour.]
-
-
-Units, Circular.
-A system of units of cross-sectional area, designed especially for use
-in describing wire conductors. The cross-sectional area of such is
-universally a circle, and the areas of two wires of different sizes vary
-with the square of their radii or diameters. Hence if the area of a
-circle of known diameter is determined it may be used as a unit for the
-dimensions of other circles. Any other circle will have an area
-proportioned to the area of the unit circle, as the squares of the
-diameters are to each other.
-
-In practise the commonest circular unit is the circular mil. This is the
-area of a circle one mil, 1/1000 inch, in diameter and is equal to
-.0000007854 square inch. A wire two mils in diameter has an area of four
-circular mils; one ten mils in diameter has an area of one hundred
-circular mils.
-
-Thus if the resistance of a given length of wire 1 mil in diameter is
-stated, the corresponding resistance of the same length of wire of the
-same material, but of other diameter, is given by dividing the first
-wire's resistance by the square of the diameter in mils of the wire in
-question.
-
-As it is a basic unit, most conveniently applied by multiplication, the
-smaller units are used; these are the circular mil, and circular
-millimeter.
-
-
-Units, Derived.
-Units derived by compounding or other processes, from the three
-fundamental units. Such are the units of area, volume, energy and work,
-momentum and electric units generally. In some cases the dimensions of
-the derived unit may reduce to those of a simple unit as inductance
-reduces to length, but the unit, as deduced from the fundamental ones,
-is still a derived unit.
-
-
-Units, Practical.
-A system of units employed in practical computation. The absolute units,
-especially in electricity, have been found too large or too small, and
-the attempt to make them more convenient has resulted in this system. It
-is based on exactly the same considerations as the absolute system of
-units, except that multiples of the original fundamental units of
-length, mass, and time have been taken as the base of the new system.
-These basic units are multiples of the fundamental units. They are the
-following: The unit of length is 1E9 centimeters; the unit of mass is
-1E-11 gram; the unit of time remains 1 second.
-
-While this has conduced to convenience in giving better sized units,
-micro- and mega-units and other multiples or fractions have to be used.
-The following are the principal practical electric units:
-
-                             Electrostatic     Electromagnetic
-                             C. G. S Units.    C. G. S. Units.
-Intensity-Ampere   equal to     3E9               1E-1
-Quantity-Coulomb     "          3E9               1E-1
-Potential-Volt       "         (1/3)* E-2         1E8
-Resistance-Ohm       "         (1/9)* E-11        1E9
-Capacity-Farad       "         9E11               1E-9
-
-
-556   STANDARD ELECTRICAL DICTIONARY.
-
-
-Universal Battery System.
-A term in telegraphy. If several equal and high resistance telegraphic
-circuits are connected in parallel with each other from terminal to
-terminal of a battery of comparatively low resistance each circuit will
-receive the same current, and of practically the same strength as if
-only one circuit was connected. This is termed the universal battery
-system. It is a practical corollary of Ohm's law. The battery being of
-very low resistance compared to the lines the joining of several lines
-in parallel practically diminishes the total resistance of the circuit
-in proportion to their own number. Thus suppose a battery of ten ohms
-resistance and ten volts E. M. F. is working a single line of one
-hundred ohms resistance. The total resistance of the circuit is then one
-hundred and ten ohms. The total current of the circuit, all of which is
-received by the one line is 10/110 = .09 ampere, or 90 milliamperes. Now
-suppose that a second line of identical resistance is connected to the
-battery in parallel with the first. This reduces the external resistance
-to fifty ohms, giving a total resistance of the circuit of sixty ohms.
-The total current of the circuit, all of which is received by the two
-lines in equal parts, is 10/60 = .166 amperes. But this is equally
-divided between two lines, so that each one receives .083 ampere or 83
-milliamperes; practically the same current as that given by the same
-battery to the single line. It will be seen that high line resistance
-and low battery resistance, relatively speaking, are required for the
-system. For this reason the storage battery is particularly available.
-The rule is that the resistance of the battery shall be less than the
-combined resistance of all the circuits worked by it.
-
-
-Unmarked End.
-The south-seeking pole of a magnet, so called because the other end,
-called the marked end, is usually marked with a scratch or notch by the
-maker, while the south pole is unmarked.
-
-
-V.
-(a) Symbol for velocity.
-
-(b) Symbol or abbreviation for volume.
-
-(c) Symbol or abbreviation for volt.
-
-
-557   STANDARD ELECTRICAL DICTIONARY.
-
-
-V. A.
-Symbol or abbreviation for voltaic alternatives, q. v.
-
-
-Vacuum.
-A space destitute of any substance. The great pervading substance is in
-general sense the atmosphere. It is the gaseous mixture which surrounds
-and envelopes the earth and its inhabitants. It consists of a simple
-mixture of oxygen, 1 part, nitrogen, 4 parts, with 4 to 6 volumes of
-carbonic acid gas in 10,000 volumes of air, or about one cubic inch to
-one cubic foot. It presses with a force of about 14.7 lbs. per square
-inch under the influence of the force of gravity. The term vacuum in
-practise refers to any space from which air has been removed. It may be
-produced chemically. Air may be displaced by carbonic acid gas and the
-latter may be absorbed by caustic alkali or other chemical. The air may
-be expelled and the space may be filled with steam which is condensed to
-produce the vacuum. Of course in all cases the space must be included in
-an hermetically sealed vessel, such as the bulb of an incandescent lamp.
-But the universal method of producing a vacuum is by air pumps. An
-absolute vacuum means the entire absence of gas or air, something almost
-impossible to produce. A high vacuum is sometimes understood to mean one
-in which the path of the molecules is equal in length to the diameter of
-the containing vessels, as in Crookes' Radiometer and other apparatus
-for illustrating the radiant condition of matter. The air left after
-exhaustion is termed residual air or residual atmosphere.
-
-[Transcriber's note: Dry air is about .78 nitrogen, .21 oxygen, .01
-argon, .00038 carbon dioxide, and trace amounts of other gases. Argon
-was suspected by Henry Cavendish in 1785. It was discovered in 1894 by
-Lord Rayleigh and Sir William Ramsay.]
-
-
-Vacuum, Absolute.
-A space free of all material substance. It is doubtful whether an
-absolute vacuum has ever been produced.
-
-
-Vacuum, High.
-An approximate vacuum, so nearly perfect that the molecules of the
-residual gas in their kinetic motions rarely collide, and beat back and
-forth between the walls of the containing vessel, or between any solid
-object contained in the vessel and the walls of the vessel. The gas in
-such a vacuum is in the radiant or ultra-gaseous state. (See
-Ultra-gaseous Matter.)
-
-
-Vacuum, Low.
-A vacuum inferior to a high vacuum; a vacuum in which the molecules
-collide with each other and do not move directly from side to side of
-the containing vessel.
-
-
-Vacuum, Partial.
-A space partially exhausted of air so as to contain less than an equal
-volume of the surrounding atmosphere. It really should come below a low
-vacuum, but is often treated as synonymous therewith.
-
-
-Vacuum, Torricellian.
-The vacuum existing above the mercurial column in a barometer tube. The
-principle of this vacuum is applied in the Geissler and other air pumps.
-(See Pump, Geissler--Pump, Sprengel--Pump, Swinburne.)
-
-
-558   STANDARD ELECTRICAL DICTIONARY.
-
-
-Valency.
-The relative power of replacing hydrogen or combining therewith
-possessed by different elements; the number of atomic bonds belonging to
-any element. Thus oxygen has a twofold valency, is bivalent or is a
-dyad, and combines with two atoms of hydrogen because the latter has a
-unitary atomicity, is monovalent or is a monad.
-
-
-Valve, Electrically Controlled.
-A valve which is moved by or whose movements are regulated by
-electricity.
-
-In the block system of railroad signaling the semaphores are worked by
-weights and pneumatic cylinders and pistons. The valves for admitting or
-releasing the compressed air are operated by coil and plunger mechanism.
-There are many other instances of the control of valves by the electric
-current.
-
-
-Vapor Globe.
-A protecting glass globe surrounding an incandescent lamp, when the lamp
-is to be used in an atmosphere of explosive vapor, as in mines or
-similar places; or when in a place where it is exposed to dripping water
-which would break the hot lamp bulb if it fell upon it.
-
-
-Variable Period.
-The period of adjustment when a current is started through a conductor
-of some capacity. It is the period of duration of the variable state, q.
-v., in a conductor. As indicated in the next definition in a cable of
-high electrostatic capacity a variable period of nearly two minutes may
-exist. This indicates the retardation in signaling to be anticipated in
-cables and other lines of high capacity.
-
-
-Variable State.
-When an electric circuit is closed the current starts through the
-conductor with its full strength from the point of closure, and advances
-with a species of wave front so that some time elapses before it attains
-its full strength in the most distant parts of the conductor, owing to
-its having to charge the conductor to its full capacity at the given
-potential. The state of the line while the current thus varies is called
-the variable state.
-
-A long telegraph line when a message is being transmitted may be always
-in the variable state. The current at the receiving end may never attain
-its full strength.
-
-In the case of such a conductor as the Atlantic cable, 108 seconds would
-be required for a current to attain 9/10 of its full strength at the
-distant end, and but 1/5 second to attain 1/100 of its final value.
-During the period of increase of current the variable state exists.
-
-
-Variation of the Compass.
-The declination of the magnetic needle. (See Elements, Magnetic.) As the
-declination is subject to daily, annual and secular variations, it is
-unfortunate that this term is synonymous with declination. Thus the
-variation of the compass means its declination, while there is also the
-variation of the declination and of other elements. The term variation
-of the compass is more colloquial than the more definite expression
-"declination," or "magnetic declination."
-
-
-559   STANDARD ELECTRICAL DICTIONARY.
-
-
-Variometer.
-An apparatus used in determining the relative values of the horizontal
-component of the earth's magnetic field in different places.
-
-
-Varley's Condenser.
-A static condenser whose conducting surfaces are platinum electrodes
-immersed in dilute sulphuric acid. When the potential difference is
-1/50th that of a Daniell's cell, two square inches of platinum have a
-capacity equal to that of an air condenser whose plates have an area of
-80,000,000 square inches, and separated 1/8th of an inch from each
-other. As the E. M. F. increases the capacity also increases.
-
-
-Varley's Resistances.
-Variable resistances formed of discs of carbonized cloth, q. v., piled
-up, and pressed together more or less firmly to vary the resistance as
-desired.
-
-
-Varnish.
-A glossy transparent coating of the nature of paint, applied as a
-protective, or ornamental coating to objects.
-
-
-Varnish, Electric.
-Alcoholic or etherial varnishes are the best for electrical apparatus.
-They dry quickly and perfectly, and tend to form surfaces unfavorable to
-the hygroscopic collection of water. Sealing wax dissolved in alcohol,
-or shellac dissolved in the same solvent are used for electrical
-apparatus, although the first is rather a lacquer than a varnish.
-Etherial solution of gum-copal is used to agglomerate coils of wire. It
-is well to bake varnished objects to harden the coating.
-
-
-Varnish, Red.
-A solution of sealing wax in 90 per cent. alcohol. It is best made thin
-and applied in several coats, each coat being allowed to dry perfectly
-before the next is applied. It is often seen on Leyden jars. It is a
-protector from surface leakage.
-
-
-Vat.
-A vessel for chemical or other solutions. A depositing vat is one in
-which a plating solution is worked, for the deposition of electroplate
-upon articles immersed in the liquid, and electrolyzed by an electric
-current.
-
-
-Velocity.
-The rate of motion of a body. It is usually expressed in distance
-traversed per second of time. The absolute unit is one centimeter per
-second or kine. The foot per second is very largely used also.
-
-The dimensions of velocity are length (L) divided by time (T) or L/T.
-
-
-Velocity, Angular.
-Velocity in a circle defined by the unit angle, or the angle which
-subtends a circular arc equal in length to itself. The radius of the
-circle traversed by the moving body does not enter into this definition,
-as the real velocity of the object is not stated. If its angular
-velocity and the radius of the path it travels are given its actual
-velocity can be deduced.
-
-
-560   STANDARD ELECTRICAL DICTIONARY.
-
-
-Velocity of Signaling.
-The speed of transmission of electric signals is affected by the nature
-of the line, as regards its static capacity, and by the delicacy of the
-receiving instruments, which may need a more or less strong current to
-be affected. Thus of an original current one per cent. may suffice to
-operate a sensitive instrument. This might give almost the velocity of
-light, while if the instrument would only respond to the full current
-nearly two minutes (see Variable State) might be required for the
-production of a signal.
-
-
-Velocity Ratio.
-A term applied to the ratios existing between the electrostatic and
-electro-magnetic units. If we take as numerators the dimensions of the
-different qualities in the electrostatic system, and their dimensions in
-the electro-magnetic system as denominators, the fractions thus obtained
-reduce to expressions containing only velocity or V in some form. Thus
-if we divide the dimensions of the electrostatic quantity by the
-dimensions of electro-magnetic quantity the quotient is simply V or
-velocity. A like division for potential, electrostatic and
-electro-magnetic gives (1/V), and so on.
-
-The value of the velocity ratio is very nearly 3E10 (sometimes given as
-2.98E10) centimeters per second. This is almost exactly that of light
-(2.9992E10 centimeters per second.) This is one of the proofs of Clerk
-Maxwell's magnetic theory of light. (See Maxwell's Theory of Light.)
-
-[Transcriber's note: The SI metre was defined in 1983 such that the
-speed of light in a vacuum is exactly 299,792,458 metres per second or
-about 186,282.397 miles per second.]
-
-
-Ventilation of Armature.
-In a dynamo or motor ventilation of the armature is often provided for
-by apertures through it in order to prevent heating. This heating is
-caused by Foucault currents. By proper disposition of the interior of
-the armature with properly disposed vanes and orifices an action like
-that of a fan blower can be produced, which by creating a current of air
-cools the machine very efficiently.
-
-
-Verticity, Poles of.
-Points upon the earth's surface where the horizontal component of
-magnetic force disappears, leaving only the vertical component active.
-The term is derived from the verticity of the dipping needle when over
-either of them.
-
-
-561   STANDARD ELECTRICAL DICTIONARY.
-
-
-Vibration Period.
-In electrical resonance the period of a vibration in an electrical
-resonator. The length of this period indicates the quality of the
-resonator in responding to electrical oscillations by sympathetic
-vibration. For conductors of small resistance the period is thus
-calculated. Let T be the period of one-half a full vibration; L the
-absolute coefficient of self-induction expressed in centimeters or in
-henries X 10-9; C the electrostatic capacity of the terminals, also
-expressed in the same unit; v the velocity of light in centimeters per
-second. Then we have the formula
-
-  T = PI * SquareRoot( L * C ) / v
-
-[Transcriber's note: If the inductance is in henries and the capacitance
-in farads, frequency in hertz = 1/(2 * PI * squareRoot( L * C ) )]
-
-
-Vibration, Sympathetic.
-A vibration in a cord or other body susceptible of elastic vibration
-produced by the vibrations of exactly the same period in a neighboring
-vibrating body. Thus if two tuning forks are tuned to precisely the same
-pitch, and are placed near each other, if one is sounded it will start
-the other into vibration by sympathy.
-
-In electricity its application is found in electric resonance
-experiments. The resonator has a definite period of electric resonance,
-and is made to give a spark by the exciter of identical period. This is
-by what may be called electric sympathetic vibration, and is exactly
-analogous to the action of the tuning forks upon each other.
-
-
-Vibrator, Electro-magnetic.
-The make and break mechanism used on induction coils, or other similar
-apparatus in which by alternate attractions by and releases from an
-electro-magnet an arm or spring is kept in motion. In most cases the
-work is done by a single magnet, whose armature is attracted to the
-magnet, when the latter is excited, but against the action of a spring
-which tends to pull it away from the magnet. In its motions a make and
-break action is produced, to give the requisite alternations of
-attraction and release. Two electro-magnets may be connected so as
-alternately to be excited and keep an arm carrying a mutual armature in
-vibration, or the same result may be attained by a polarized relay. The
-make and break is illustrated under Bell, Electric--Coil, Induction--
-Anvil.
-
-
-Villari's Critical Value.
-Magnetization induced or residual in a wire is diminished on stretching,
-provided that the magnetization corresponds to an inducing force above a
-certain critical value, known as above; this being (Sir Wm. Thomson)
-about 24 times the terrestrial intensity. Below that critical value
-tension increases the magnetization of a magnetized wire. The effects of
-transverse expansive stress are opposed to those of longitudinal
-stretching. (Daniell.)
-
-
-Viole's Standard of Illuminating Power.
-A standard authorized by the International Congress of 1881. It is the
-light given by one square centimeter of platinum, melted, but just at
-the point of solidification. It is equal to 20 English standard candles
-almost exactly.
-
-It has not been very widely accepted, the tendency among photometrists
-being to adhere to the old standards, carcel or candle. It is obvious
-that actual use of the Viole would be very inconvenient and would
-involve expensive apparatus, difficult to work with.
-
-Synonym--Viole.
-
-
-562   STANDARD ELECTRICAL DICTIONARY.
-
-
-Vis Viva.
-The kinetic energy of a body in motion; "mechanical energy."
-
-
-Vitreous Electricity.
-Positive electricity; the electricity produced on the surface of glass
-by rubbing it with silk and other substances. (See Electrostatic
-Series.)
-
-The term "positive electricity" should be allowed to supplant it. It is
-the analogue and opposite of resinous electricity.
-
-
-Vitriol, Blue.
-A colloquial or trade name for copper sulphate (Cu SO4).
-
-
-Vitriol, Green.
-A colloquial or trade name for ferrous sulphate (Fe SO4).
-
-
-Vitriol, White.
-A colloquial or trade name for zinc sulphate (Zn SO4).
-
-
-Volt.
-The practical unit of electro-motive force or potential difference. It
-may be referred to various data.
-
-An electro-motive force of one volt will cause a current of one ampere
-to flow through a resistance of one ohm.
-
-A condenser of one farad capacity charged with one coulomb will have a
-rise of potential of one volt.
-
-The cutting of 100,000,000 lines of force per second by a conductor
-induces one volt E. M. F.
-
-A Daniell's battery gives an E. M. F. of 1.07 volts; about the most
-familiar approximate standard that can be cited.
-
-It is equal to 1/300 absolute electrostatic unit.
-
-It is equal to 1E8 absolute electro-magnetic units.
-
-[Transcriber's note: The SI definition of a volt: The potential
-difference across a conductor when a current of one ampere dissipates
-one watt of power.]
-
-
-Voltage.
-Potential difference or electro-motive force expressed in volts; as a
-voltage of 100 volts. Thus voltage may express the electro-motive force
-absorbed in a conductor, while electro-motive force is a term generally
-applied where it is produced, evolved or present in the object. The term
-voltage of a lamp expresses simply the volts required, but does not
-suggest the possession of electromotive force.
-
-
-563   STANDARD ELECTRICAL DICTIONARY.
-
-
-Voltage, Terminal.
-The voltage or potential difference at the terminals of an electric
-current generator, such as a dynamo, as distinguished from the total
-electro-motive force of the dynamo or generator.
-
-In batteries the distinction is not generally made in practice; the
-total electro-motive force of the battery is made the basis of
-calculations.
-
-
-Voltaic. adj.
-This adjective is used to qualify a great many things appertaining to or
-connected with current electricity. It is derived from Volta, the
-inventor of the voltaic battery, and now tends to displace the term
-"galvanic," formerly in general use.
-
-
-Voltaic Alternatives.
-A term used in electro-therapeutics or medical electricity to indicate
-an alternating battery current.
-
-Synonym--Alternative current.
-
-
-Voltaic Effect.
-The potential difference developed by contact of different conductors.
-It is the basis of the contact theory, q. v., of electricity, although
-it may be accepted as the expression for a condition of things by those
-who reject the above theory. This potential difference is slight when
-the conductors are separated, but it is calculated that it would be
-enormous could the metals be so quickly separated as to hold each its
-own charge.
-
-Thus if a copper and a zinc plate are assumed to be in contact, really
-1/20000000 centimeter or 1/50000000 inch apart, they may be treated as a
-pair of condenser plates. Being so near, their density of charge, which
-is a strongly bound charge, is enormous. If it were possible to separate
-them without permitting any discharge, their potential would rise by the
-separation, on the principle of Epinus' condenser, q. v., to such an
-extent that they would spark through twenty feet of air. (See Volta's
-Fundamental Experiment.)
-
-
-Voltaic Electricity.
-Electricity of low potential difference and large current intensity;
-electricity such as produced by a voltaic battery; current or dynamic
-electricity as opposed to static electricity.
-
-
-Voltameter.
-In general an apparatus for determining the quantity of electricity
-passing through a conductor by measuring the electrolytic action it can
-perform.
-
-
-Voltameter, Copper.
-An apparatus which may be of similar construction with the silver
-voltameter (see Voltameter, Silver), but in which a copper anode and a
-solution of copper sulphate are substituted for the silver anode and
-silver nitrate solution. One coulomb corresponds to .329 milligram or
-.005084 grain of copper deposited. It is not accepted as of as high a
-standard as the silver voltameter.
-
-The electrodes should be placed half an inch from each other. Two square
-plate electrodes may conveniently be used, and not less than two square
-inches on each plate should be the area per ampere of current.
-
-
-564   STANDARD ELECTRICAL DICTIONARY.
-
-
-Voltameter, Differential, Siemens'.
-A volume or gas voltameter with duplicate eudiometers and pairs of
-electrodes. It is used for determining the resistance of the platinum
-conductor used in his pyrometer. A current divides between the two
-voltameters; in one branch of the circuit the platinum conductor is
-placed, in the other a known resistance. The current strength varying
-inversely with the resistance, the resistances of the two conductors are
-inversely proportional to the gas evolved.
-
-
-Voltameter, Gas.
-A voltameter whose indications are based on the electrolysis of water,
-made an electrolyte by the addition of sulphuric acid. The gases evolved
-are measured. It may take several forms.
-
-In one form it is an apparatus consisting of a single eudiometer or
-graduated glass tube with upper end closed and its lower end or mouth
-open, collecting the mixture of hydrogen and oxygen.
-
-In the form shown in the cut three tubes are connected, the side tubes
-representing eudiometers. For each side tube there is a platinum
-electrode. In this apparatus the oxygen and hydrogen are connected in
-opposite tubes. A is an open tube filled with dilute sulphuric acid. By
-opening the cocks on B and C they can both be completely filled with
-acid. As shown in the cut, this operation is not yet completed. The
-hydrogen alone may in this case be measured.
-
-The mixed gas voltameter has only one eudiometer.
-
-The exact equivalents are only approximately known. The volume of mixed
-gases per coulomb is given as .1738 cubic centimeters (Ayrton); .172
-cubic centimeters (Hospitalier); and other values by other authorities.
-The hydrogen is equal to 1/3 of the mixed gases almost exactly.
-
-Synonyms--Volume Voltameter--Sulphuric Acid Voltameter.
-
-The gas is measured at 0� (32� F.) and 76 centimeters, or 30 inches
-barometer.
-
-
-Fig. 341. GAS VOLTAMETER.
-
-
-565   STANDARD ELECTRICAL DICTIONARY.
-
-
-If the gas is measured in cubic inches, the temperature in degrees F.,
-and the barometric height in inches, the following formula may be used
-for reduction to standard pressure and temperature. It is the volume
-corresponding to one coulomb.
-  ( .01058 * 30 * (491 + F� - 32) ) / (h* 491)
-
-For the metric measurements and degrees C.
-  (.1738 * 76 * (273 + C�)) / (h X 273)
-
-
-Voltameter, Silver.
-An apparatus consisting of a platinum vessel containing a solution of
-silver nitrate into which solution a silver anode dips, whose end is
-wrapped in muslin to prevent the detachment of any particles. When a
-current is passed by connecting one terminal to the dish and the other
-to the rod, securing a proper direction of current, silver will be
-deposited on the dish and the same amount will be dissolved from the
-rod. The dish is weighed before and after the test. Its increase in
-weight gives the silver deposited.
-
-
-FIG. 342. SILVER VOLTAMETER.
-
-
-In the cut Ag is the silver anode, Pt is the platinum dish, r is the
-conducting rod, p is a wooden standard, Cu is a copper plate on which
-the dish rests and which also serves as a conductor and contact surface,
-b is a muslin cloth to place over the silver plate to prevent detached
-particles falling in the dish; s s' are the binding screws.
-
-The weight of silver corresponding to a coulomb is given variously by
-different authorities. Ayrton and Daniell take 1.11815 milligrams or
-.017253 grain of metallic silver. Other determinations are as follows:
-  1.1183 milligrams   (Kohlrausch).
-  1.124   "           (Merscart).
-
-The solution of silver nitrate should be from 15 to 30 per cent. of
-strength. The current should not exceed one ampere per six square
-inches; or in other words not more than about 3/1000 grain of silver
-should be deposited per second on a square inch area of the dish. The
-edge of the silver disc or anode should be about equidistant from the
-side and bottom of the dish. The latter notes are due to Lord Rayleigh.
-
-
-566   STANDARD ELECTRICAL DICTIONARY.
-
-
-Voltameter, Weight.
-A voltameter in which the amount of decomposition is determined by
-weighing the products, or one of the products of the electrolysis. The
-titles Voltameter, Copper, and Voltameter, Silver, may be cited.
-
-
-Fig. 343. WEIGHT VOLTAMETERS.
-
-
-In the cuts are shown examples of weight gas voltameters. These are
-tubes light enough to be weighed when charged. Each contains a
-decomposition cell T, with its platinum electrodes, and charged with
-dilute sulphuric acid, while t is calcium chloride or other drying agent
-to collect any water carried off as vapor or as spray by the escaping
-gases; c are corks placed in position when the weighing is being
-executed, so as to prevent the calcium chloride from absorbing moisture
-from the air.
-
-In use the tubes are weighed. They are then connected to the circuit,
-after removal of the corks, and the decomposition proceeds. After a
-sufficient time they are removed, the corks put in place, and they are
-weighed again. The loss gives the water decomposed.
-
-The water corresponding to one coulomb is
-  .09326 milligram   .001430 grain,   Ayrton,
-  .092      "                         Hospitalier,
-  .0935     "                         Daniell.
-
-
-567   STANDARD ELECTRICAL DICTIONARY.
-
-
-Voltametric Law.
-The law on which voltameters are based. The amount of chemical
-decomposition produced by an electric current in a given electrolyte is
-proportional to the quantity of electricity passed through the solution.
-
-
-Fig. 344. VOLTA'S FUNDAMENTAL EXPERIMENT.
-
-
-Volta's Fundamental Experiment.
-The moistened finger is placed on the upper plate of a condensing or
-electrophorous electroscope. The other hand holds a plate of zinc z,
-soldered to a plate of copper c. The lower plate is touched with the
-copper. On removing the cover the gold leaves l diverge and with
-negative electricity. Hence zinc is supposed to be positively
-electrified when in contact with copper. The experiment is used to
-demonstrate the contact theory of electricity.
-
-
-568   STANDARD ELECTRICAL DICTIONARY.
-
-
-Volta's Law of Galvanic Action.
-The electro-motive force between any two metals in an electro-chemical
-series (see Electro-Chemical Series) is equal to the sum of the
-electro-motive forces between all the intervening metals.
-
-
-Volta's Law of Thermo-electricity.
-In a compound circuit, consisting of a number of different metals, all
-points of which are at the same temperature, there is no current.
-
-
-Volt, B. A.
-The volt based on the B. A. ohm. It is equal to .9889 legal volt.
-
-
-Volt, Congress.
-The volt based upon the congress or legal ohm; the legal volt.
-
-
-Volt-coulomb.
-The unit of electric work; the watt-second; it is equivalent to
-  1.0E7     ergs.
-   .24068   gram degree C. (calorie)
-   .737337  foot lbs.,
-   .00134   horse power seconds.
-
-
-Volt Indicator.
-A form of easily read voltameter for use in electric light stations and
-for similar work.
-
-
-Volt, Legal.
-The legal volt based upon the legal ohm. It is equal to 1.00112 B. A.
-volt.
-
-
-Voltmeter.
-An instrument for determining the potential difference of any two
-points.
-
-In many cases it is a calibrated galvanometer wound with a coil of high
-resistance. The object to be attained is that it shall receive only an
-insignificant portion of current and that such portion shall suffice to
-actuate it. If connected in parallel with any portion of a circuit, it
-should not noticeably diminish its resistance.
-
-The divisions into which ammeters range themselves answer for
-voltmeters. In practice the same construction is adopted for both. The
-different definitions of ammeters in disclosing the general lines of
-these instruments are in general applicable to voltmeters, except that
-the wire winding of the coils must be of thin wire of great length. The
-definitions of ammeters may be consulted with the above understanding
-for voltmeters.
-
-In the use made of voltmeters there is a distinction from ammeters. An
-ammeter is a current measurer and all the current measured must be
-passed through it. But while a voltmeter is in fact a current measurer,
-it is so graduated and so used that it gives in its readings the
-difference of potential existing between two places on a circuit, and
-while measuring the current passing through its own coils, it is by
-calibration made to give not the current intensity, but the
-electro-motive force producing such current.
-
-In use it may be connected to two terminals of an open circuit, when as
-it only permits an inconsiderable current to pass, it indicates the
-potential difference existing between such points on open circuit. Or it
-may be connected to any two parts of a closed circuit. Owing to its high
-resistance, although it is in parallel with the intervening portion of
-the circuit, as it is often connected in practice, it is without any
-appreciable effect upon the current. It will then indicate the potential
-difference existing between the two points.
-
-
-569    STANDARD ELECTRICAL DICTIONARY.
-
-
-Voltmeter, Battery.
-A voltmeter for use in running batteries. In one form (Wirt's) it is
-constructed for a low range of voltage, reading up to two and a half
-volts and having exactly one ohm resistance, thus giving the battery
-some work to do.
-
-
-Voltmeter, Cardew.
-A voltmeter in which the current passing through its conductor heats
-such conductor, causing it to expand. Its expansion is caused to move an
-index needle. By calibration the movements of the needle are made to
-correspond to the potential differences producing the actuating currents
-through it. The magnetic action of the current plays no part in its
-operation. It is the invention of Capt. Cardew, R. E.
-
-The construction of the instrument in one of its most recent forms is
-shown in the cut. On each side of the drum-like case of the instrument
-are the binding screws. These connect with the blocks m and n. To these
-the fine wire conductor is connected and is carried down and up over the
-two pulleys seen at the lowest extremity, its centre being attached to
-c. From c a wire is carried to the drum p, shown on an enlarged scale on
-the left of the cut. A second wire from the same drum or pulley connects
-to the spring S. The winding of the two wires is shown in the separate
-figure of c, where it is seen that they are screwed fast to the
-periphery of the little drum, and are virtually continuations of each
-other. By the screw A the tension of the spring S is adjusted.
-
-On the shaft of the little drum p is a pinion, which works into the
-teeth of the cog-wheel r. The shaft of r is extended through the dial
-of the instrument, and carries an index. The dial is marked off for
-volts; g g and h h are standards for carrying the pulleys.
-
-
-570   STANDARD ELECTRICAL DICTIONARY.
-
-
-The action of the instrument is as follows. The current passing through
-the wire heats it. This current by Ohm's law is proportional to the
-electro-motive force between the terminals. As it is heated it expands
-and as it cools contracts, definite expanding and contracting
-corresponding to definite potential differences. As the wire expands and
-contracts the block or pin c moves back and forth, thus turning the drum
-p and cogwheel r one way or permitting it to turn the other way under
-the pull of the spring S.
-
-
-Fig. 345. CARDEW VOLTMETER.
-
-
-In this construction for a given expansion of the wire the piece c only
-moves one half as much. The advantage of using a wire twice as long as
-would be required for the same degree of movement were the full
-expansion utilized is that a very thin wire can be employed. Such a wire
-heats and cools more readily, and hence the instrument reaches its
-reading more quickly or is more deadbeat, if we borrow a phraseology
-properly applicable only to instruments with oscillating indexes.
-
-In the most recent instruments about thirteen feet of wire .0025 inch in
-diameter, and made of platinum-silver alloy is used.
-
-
-571   STANDARD ELECTRICAL DICTIONARY.
-
-
-If the potential difference to be measured lies between 30 and 120 volts
-the wire as described suffices. But to extend the range of the
-instrument a resistance in series is required. If such resistance is
-double that of the instrument wire, and remains double whether the
-latter is hot or cold the readings on the scale will correspond to
-exactly twice the number of volts. This is brought about in some
-instruments by the introduction in series of a duplicate wire, precisely
-similar to the other wire, and like it, carried around pulleys and kept
-stretched by a spring.
-
-[Transcriber's note: If the series resistance is twice that of the
-voltmeter, the indicated voltage will be ONE THIRD of the total
-voltage.]
-
-Thus whatever ratio of resistance exists between the two wires cold, it
-is always the same at any temperature, as they both increase in
-temperature at exactly the same rate. Tubes are provided to enclose the
-stretched wires and pulleys, which tubes are blackened.
-
-The voltmeter is unaffected by magnetic fields, and, as its
-self-induction is very slight, it is much used for alternating currents.
-The tubes containing the wire may be three feet long.
-
-Its disadvantages are thus summarized by Ayrton. It absorbs a good deal
-of energy; it cannot be constructed for small potential differences, as
-the wire cannot be made thicker, as it would make it more sluggish;
-there is vagueness in the readings near the zero point and sometimes
-inaccuracy in the upper part of the scale.
-
-
-Volts, Lost.
-The volts at the terminals of a dynamo at full load fall short of their
-value on open circuit. The difference of the two values are termed lost
-volts.
-
-
-Voltmeter, Electrostatic.
-A voltmeter based on the lines of the quadrant electrometer. It includes
-two sets of quadrants, each oppositely excited by one of the two parts,
-whose potential difference is to be determined. They attract each other
-against a controlling force as of gravity.
-
-One form has the two sets poised on horizontal axes, bringing the parts
-so that the flat quadrants move in vertical planes.
-
-In another form a number of quadrants are used in each set, the members
-of the two sets alternating with each other. One set is fixed, the
-others move and carry the index.
-
-
-Vulcanite.
-Vulcanized india rubber which by high proportion of sulphur and proper
-vulcanization has been made hard. It is sometimes distinguished from
-ebonite as being comparatively light in color, often a dull red, while
-ebonite is black. For its electrical properties see Ebonite.
-
-Both substances have their defects, in producing surface leakage.
-Washing with weak ammonia, or with dilute soda solution, followed by
-distilled water, is recommended for the surface, if there is any trouble
-with surface leakage. It may also be rubbed over with melted paraffine
-wax.
-
-
-572   STANDARD ELECTRICAL DICTIONARY.
-
-
-W.
-(a) A symbol or abbreviation for watt.
-
-(b) A symbol or abbreviation for work.
-
-(c) A symbol or abbreviation for weight.
-
-
-Wall Bracket.
-A telegraph bracket to be attached to the external walls of buildings to
-which wires are attached as they come from the poles to reach
-converters, or for direct introduction into a building.
-
-
-Wall Sockets.
-Sockets for incandescent lamps constructed to be attached to a wall.
-
-
-Ward.
-Direction in a straight line; a term proposed by Prof. James Thompson.
-The words "backward" and "forward" indicate its scope.
-
-
-Water.
-A compound whose molecule consists of two atoms of hydrogen and one atom
-of oxygen; formula, H2 O.
-
-Its specific gravity is 1, it being the base of the system of specific
-gravities of solids and liquids.
-
-If pure, it is almost a non-conductor of electricity. If any impurity is
-present it still presents an exceedingly high, almost immeasurable true
-resistance, but becomes by the presence of any impurity an electrolyte.
-
-
-Water Equivalent.
-In a calorimeter of any kind the weight of water which would be raised
-as much as is the calorimeter with its contents by the addition of any
-given amount of heat received by the calorimeter.
-
-
-Waterproof Lamp Globe.
-An outer globe for incandescent lamps, to protect them from water.
-
-
-Watt.
-(a) The practical unit of electric activity, rate of work, or rate of
-energy. It is the rate of energy or of work represented by a current of
-one ampere urged by one volt electro-motive force; the volt-ampere.
-
-It is the analogue in electricity of the horse power in mechanics;
-approximately, 746 watts represent one electric horse power.
-
-Ohm's law, taken as C = E/R, gives as values for current, C and E/R, and
-for electro- motive force C R. In these formulas, C represents current
-strength, R represents resistance and E represents electro-motive force.
-Then a watt being the product of electro-motive force by current
-strength, we get the following values for rate of electric energy, of
-which the watt is the practical unit: (1) E2/R -- (2) C*E -- (3) C2 * R.
-
-
-The equivalents of the watt vary a little according to different
-authorities. Ayrton gives the following equivalents: 44.25 foot pounds
-per minute--.7375 foot pounds per second--1/746 horse power. These
-values are practically accurate. Hospitalier gives .7377 foot pounds per
-second. Hering gives .737324 foot pounds per second, and 1000/745941
-horse power.
-
-
-573   STANDARD ELECTRICAL DICTIONARY.
-
-
-It is equal to 1E7 ergs per second.
-
-Synonym--Volt-ampere.
-
-(c) It has been proposed to use the term as the unit of energy, instead
-of activity or rate of energy (Sir C. W. Siemens, British Association,
-1882); this use has not been adopted and may be regarded as abandoned.
-
-[Transcriber's note; Watt is a unit of POWER--energy per unit of time.]
-
-
-Watt-hour.
-A unit of electric energy or work; one watt exerted or expended for one
-hour.
-
-It is equivalent to :
-   866.448  gram-degrees C. (calories)
-  2654.4    foot lbs.
-  3600      watt-seconds or volt-coulombs.
-    60      watt-minutes.
-
-
-Watt-minute.
-A unit of electric energy or work; one watt exerted or expended for one
-minute.
-
-It is equivalent to
-  14.4408  gram-degrees C. (calories),
-  44.240   foot pounds,
-  60       watt seconds or volt-coulombs,
-  1/60     watt hour.
-
-
-Watts, Apparent.
-The product in an alternating current dynamo of the virtual amperes by
-the virtual volts. To give the true watts this product must be
-multiplied by the cosine of the angle of lead or lag. (See Current,
-Wattless.)
-
-[Transcriber's note: This is now called a volt-amp. The usual usage is
-KVA, or kilovolt-ampere.]
-
-
-Watt-second.
-A unit of electric energy or work. One watt exerted or expended for one
-second.
-
-It is equivalent to
-  .24068     gram degree C. (calorie),
-  .000955    lb. degree F.,
-  .737337    foot lbs.,
-  .0013406   horse power second (English),
-  .0013592   horse power second (metric).
-
-Synonym--Volt-coulomb.
-
-
-Waves, Electro-magnetic.
-Ether waves caused by electromagnetic disturbances affecting the
-luminiferous ether. (See Discharge, Oscillatory--Maxwell's Theory of
-Light--Resonance. Electric.)
-
-[Transcriber's note: The Michaelson-Morley experiment (1887) had already
-called ether into question, but quantum theory and photons are decades
-in the future.]
-
-
-574   STANDARD ELECTRICAL DICTIONARY.
-
-
-Weber.
-(a.) A name suggested by Clausius and Siemens to denote a magnet pole of
-unit strength. This use is abandoned.
-
-(b.) It has been used to designate the unit of quantity--the coulomb.
-This use is abandoned.
-
-(c.) It has been used to designate the unit of current strength the
-ampere. This use is abandoned.
-
-[Transcriber's note: Definition (a) is now used. One weber of magnetic
-flux linked to a circuit of one turn produces an electromotive force of
-1 volt if it is reduced to zero at a uniform rate in 1 second.]
-
-
-Weber-meter.
-An ampere-meter or ammeter. The term is not used since the term "weber,"
-indicating the ampere or coulomb, has been abandoned.
-
-
-Welding, Electric.
-Welding metals by heat produced by electricity. The heat may be produced
-by a current passing through the point of junction (Elihu Thomson) or by
-the voltaic arc. (Benardos & Olzewski.)
-
-
-Fig. 346. ELECTRIC WELDING INDUCTION COIL.
-
-
-The current process is carried out by pressing together the objects to
-be united, while holding them in conducting clamps. A heavy current is
-turned on by way of the clamps and rapidly heats the metals at the
-junction, which is of course the point of highest resistance. As the
-metal softens, it is pressed together, one of the clamps being mounted
-with feed motion, flux is dropped on if necessary, and the metal pieces
-unite.
-
-The most remarkable results are thus attained; almost all common metals
-can be welded, and different metals can be welded together. Tubes and
-other shapes can also be united. In many cases the weld is the strongest
-part.
-
-
-575   STANDARD ELECTRICAL DICTIONARY.
-
-
-The alternating current is employed. A special dynamo is sometimes used
-to produce it. This dynamo has two windings on the armature. One is of
-fine wire and is in series with the field magnets and excites them. The
-other is of copper bars, and connects with the welding apparatus, giving
-a current of high intensity but actuated by low potential.
-
-Where the special dynamo is not used, an induction coil or transformer
-is used. The primary includes a large number of convolutions of
-relatively fine wire; the secondary may only be one turn of a large
-copper bar.
-
-The cut shows in diagram an electric welding coil. P is the primary coil
-of a number of turns of wire; S S is the secondary, a single copper bar
-bent into an almost complete circle. It terminates in clamps D D for
-holding the bars to be welded. B C, B' C are the bars to be welded. They
-are pressed together by the screw J. The large coil I of iron wire
-surrounding the coils represents the iron core.
-
-The real apparatus as at present constructed involves many
-modifications. The diagram only illustrates the principle of the
-apparatus.
-
-In welding by the voltaic arc the place to be heated is made an
-electrode of an arc by connection with one terminal of an electric
-circuit. A carbon is connected to the other terminal. An arc is started
-by touching and withdrawal of the carbon. The heat may be used for
-welding, soldering, brazing, or even for perforating or dividing metal
-sheets.
-
-
-Welding Transformer.
-The induction coil or transformer used in electric welding. For its
-general principles of construction, see Welding, Electric.
-
-
-Wheatstone's Bridge.
-A system of connections applied to parallel circuits, including
-resistance coils for the purpose of measuring an unknown resistance. A
-single current is made to pass from A through two parallel connected
-branches, joining together again at C. A cross connection B D has a
-galvanometer or other current indicator in circuit. In any conductor
-through which a current is passing, the fall of potential at given
-points is proportional to the resistance between such points. Referring
-to the diagram a given fall of potential exists between A and C. The
-fall between A and B is to the fall between A and C as the resistance r
-between A and B is to the resistance r + r' between A and C. The same
-applies to the other branch, with the substitution of the resistances s
-and S' and the point D for r r' and B. Therefore, if this proportion
-holds, r : r' : : s : S'. No current will go through B D , and the
-galvanometer will be unaffected. Assume s' to be of unknown resistance,
-the above proportion will give it, if r, r' and s are known, or if the
-ratio of r to r' and the absolute value of s is known.
-
-
-576   STANDARD ELECTRICAL DICTIONARY.
-
-
-In use the resistances r, r', and s are made to vary as desired. To
-measure an unknown resistance it is introduced at S', and one of the
-other resistances is varied until the galvanometer is unaffected. Then
-the resistance of S' is determined by calculation as just explained. The
-artificial resistances may be resistance coils, q. v., or it is enough
-to have one unknown resistance at s. Then if the length of wire ABC is
-accurately known, the point B can be shifted along it until the balance
-is attained. The relative lengths A B, and B C, will then give the ratio
-r : r' needed for the calculation. This assumes the wire ABC to be of
-absolutely uniform resistance. This is the principle of the meter-bridge
-described below. The use of coils is the more common method and is
-carried out by special resistance boxes, with the connections arranged
-to carry out the exact principle as explained. The principle of
-construction and use of a resistance box of the Wheatstone bridge type,
-as shown in the cut, is described under Box Bridge, q. v.
-
-
-FIG. 347. WHEATSTONE BRIDGE CONNECTIONS.
-
-
-FIG. 348. TOP OF BOX BRIDGE.
-
-
-577   STANDARD ELECTRICAL DICTIONARY.
-
-
-The next cut shows the sliding form of bridge called the meter bridge,
-if the slide wire is a meter long or a half- or a quarter-meter bridge,
-etc., according to the length of this wire. It is described under Meter
-Bridge, q. v. Many refinements in construction and in proper proportion
-of resistances for given work apply to these constructions.
-
-Synonyms--Electric Balance--Resistance Bridge--Wheatstone's Balance.
-
-
-Fig. 349. METER BRIDGE.
-
-
-Whirl, Electric.
-(a) A conductor carrying an electric current is surrounded by circular
-lines of force, which are sometimes termed an electric whirl.
-
-(b) The Electric Flyer. (See Flyer, Electric.)
-
-
-Wimshurst Electric Machine.
-An influence machine for producing high potential or static electricity.
-
-Two circular discs of thin glass are mounted on perforated hubs or
-bosses of wood or ebonite. Each hub has a groove turned upon it to
-receive a cord. Each disc is shellacked. They are mounted on a
-horizontal steel spindle so as to face and to be within one-eighth of an
-inch of each other. On the outside of each disc sixteen or eighteen
-sectors of tinfoil or thin metal are cemented.
-
-
-578   STANDARD ELECTRICAL DICTIONARY.
-
-
-Two curved brass rods terminating in wire brushes curved into a
-semi-ellipse just graze the outer surfaces of the plates with their
-brushes. They lie in imaginary planes, passing through the axis of the
-spindle and at right angles from each other.
-
-Four collecting combs are arranged horizontally on insulating supports
-to collect electricity from the horizontal diameters of the discs. These
-lie at an angle of about 45� with the other equalizing rods. Discharging
-rods connect with the collecting combs.
-
-The principle of the machine is that one set of sector plates act as
-inductors for the other set. Its action is not perfectly understood.
-
-It works well in damp weather, far surpassing other influence machines
-in this respect. On turning the handle a constant succession or stream
-of sparks is produced between the terminals of the discharging rods.
-
-
-Windage.
-In a dynamo the real air gap between the armature windings and pole
-pieces is sometimes thus termed.
-
-
-Wind, Electric.
-The rush of air particles from a point connected to a statically charged
-condenser.
-
-
-Winding, Compound.
-A method of winding a generator or motor in which a shunt winding is
-used for the field magnets and in which also a second winding of the
-magnet is placed in series with the outer circuit. (See Winding,
-Series--Winding, Shunt.)
-
-
-Fig. 350. CHARACTERISTIC CURVES OF SHUNT AND SERIES WINDING.
-
-
-The object of compound winding is to make a self-regulating dynamo and
-this object is partly attained for a constant speed.
-
-The characteristic curves of shunt and series winding are of opposite
-natures. The first increases in electro-motive force for resistance in
-the outer circuit, the latter decreases under the same conditions. If
-the windings are so proportioned that these conditions for each one of
-the two windings are equal and opposite, it is evident that the
-characteristic may be a straight line. This, however, it will only be at
-a single speed of rotation.
-
-
-579   STANDARD ELECTRICAL DICTIONARY.
-
-
-Winding, Disc.
-A winding which (S. P. Thompson) may be treated as a drum winding
-extended radially, the periphery corresponding to the back end of the
-drum. The magnet poles are generally placed so as to face the side or
-sides of the disc.
-
-
-Winding, Lap.
-A method of winding disc and drum armatures. It consists in lapping back
-each lead of wire towards the preceding lead upon the commutator end of
-the armature. Thus taking the letter U as the diagrammatical
-representation of a turn of wire in connecting its ends to the
-commutator bars they are brought towards each other so as to connect
-with contiguous commutator bars. This carries out the principle of
-keeping the two members of the U moving in regions of opposite polarity
-of field, so that the currents induced in them shall have opposite
-directions, thus producing a total current in one sense through the bent
-wire.
-
-
-Winding, Long Shunt.
-A system of compound winding for dynamos and motors. The field is wound
-in series and, in addition thereto, there is a shunt winding connected
-across from terminal to terminal of the machine, and which may be
-regarded either as a shunt to the outer circuit, or as a shunt to the
-series-field and armature winding. (See Winding, Short Shunt.)
-
-Synonyms--Series and Long Shunt Winding.
-
-
-Winding, Multiple.
-A winding of an electro-magnet, in which separate coils are wound on the
-core, so that one or any number may be used as desired in parallel or in
-series. For each coil a separate binding post should be provided.
-
-
-Winding, Multipolar.
-Winding adapted for armatures of multi-polar dynamos or motors.
-
-
-Winding, Series.
-A method of winding a generator or motor, in which one of the
-commutator-brush connections is connected to the field-magnet winding;
-the other end of the magnet winding connects with the outer circuit. The
-other armature-brush connects with the other terminal of the outer
-circuit.
-
-
-Winding, Series and Separate Coil.
-A method of automatic regulation applied to alternating current dynamos.
-
-
-Winding, Short Shunt.
-A method of compound winding for dynamos and motors. The field is wound
-in series, and in addition thereto there is a shunt winding connected
-from brush to brush only, thus paralleling the armature. (See Winding,
-Long Shunt.)
-
-Synonyms--Series and Short Shunt Winding.
-
-
-580   STANDARD ELECTRICAL DICTIONARY.
-
-
-Winding, Shunt.
-A method of winding a generator or motor. Each commutator-brush has two
-connections. One set are the terminals of the outer circuit, the other
-set are the terminals of the field-magnet windings. In other words, the
-field-magnet windings are in shunt or in parallel with the outer
-circuit.
-
-
-Winding, Shuttle.
-A method of dynamo or motor-armature winding. A single groove passes
-longitudinally around the core and in this the wire is continuously
-wound. The system is not now used. The old Siemens' H armature
-illustrates the principle.
-
-
-Winding, Wave.
-A method of winding disc and drum armatures. It consists in advancing
-the commutator ends of the U shaped turns progressively, so that as many
-commutator bars intervene between any two consecutive commutator
-connections of the wire as there are leads of wire on the drum between
-consecutive leads of the wire. This is carried out with due regard to
-the principle that taking the letter U as the diagrammatical
-representation of a turn of wire, its two members must move through
-regions of the field of opposite polarity.
-
-
-Wire Finder.
-A galvanometer or other instrument used for identifying the ends of a
-given wire in a cable containing several.
-
-
-Work.
-When a force acts upon a body and the body moves in the direction of the
-force, the force does work. Hence, work is the action of a force through
-space against resistance.
-
-It is generally expressed in compound units of length and weight, as
-foot-pounds, meaning a pound raised one foot.
-
-
-Work, Electric, Unit of.
-The volt-coulomb, q. v., or watt-second, as it is often termed.
-
-
-Working, Diode.
-In multiplex telegraphy the transmission of two messages,
-simultaneously, over one wire. (See Telegraphy, Multiple.)
-
-
-Working, Contraplex.
-A variety of duplex telegraphy in which the messages are sent from
-opposite ends of the line, simultaneously, so as to be transmitted in
-opposite directions. (See Working, Diplex.)
-
-
-Working, Diplex.
-In duplex telegraphy the sending of two independent messages from the
-same end of the line in the same direction.
-
-
-581   STANDARD ELECTRICAL DICTIONARY.
-
-
-Working, Double Curb.
-A method of working telegraph lines. When a signal is sent the line is
-charged. This has to be got rid of, and is an element of retardation. In
-double curb working it is disposed of by sending a momentary current
-first in the reverse, and then in the same, and finally in the reverse
-direction. This is found to reduce the charge to a very low point.
-
-
-Working, Hexode.
-In multiplex telegraphy the transmission of six messages simultaneously
-over one wire. (See Telegraphy, Multiplex.)
-
-
-Working, Pentode.
-In multiplex telegraphy the transmission of five messages simultaneously
-over one wire. (See Telegraphy, Multiplex.)
-
-
-Working, Reverse Current.
-A method of telegraphy, in which the currents are reversed or alternated
-in direction.
-
-
-Working, Single Curb.
-A simpler form of telegraph signaling than double curb working. It
-consists in sending a reverse current through the line for each signal
-by reversing the battery connection.
-
-
-Working, Tetrode.
-In multiplex telegraphy the transmission of four messages simultaneously
-over the same line. (See Telegraphy, Multiplex.)
-
-
-Working, Triode.
-In multiplex telegraphy the transmission of three messages
-simultaneously over the same wire. (See Telegraphy, Multiplex.)
-
-
-Work, Unit of.
-The erg, q. v. It is the same as the unit of energy, of which work is
-the corelative, being equal and opposite to the energy expended in doing
-it. There are many other engineering units of work, as the foot-pound
-and foot-ton.
-
-
-Yoke.
-In an electro-magnet, the piece of iron which connects the ends furthest
-from the poles of the two portions of the core on which the wire is
-wound.
-
-
-Zamboni's Dry Pile.
-A voltaic pile or battery. It is made of discs of paper, silvered or
-tinned on one side and sprinkled on the other with binoxide of
-manganese. Sometimes as many as 2,000 of such couples are piled up in a
-glass tube and pressed together with two rods which form the terminals.
-They maintain a high potential difference, but having very high
-resistance and slight polarization capacity, give exceedingly small
-quantities.
-
-Zero.
-(a) The origin of any scale of measurement.
-
-(b) An infinitely small quantity or measurement.
-
-
-582   STANDARD ELECTRICAL DICTIONARY.
-
-
-Zero, Absolute.
-From several considerations it is believed that at a certain temperature
-the molecules of all bodies would touch each other, their kinetic motion
-would cease, and there would be no heat. This temperature is the
-absolute zero. It is put at -273� C. (-459� F.)
-
-[Transcriber's note; The modern value is 0� Kelvin,  -273.15� C, or
--459.67� F. The lowest reported temperature observed is 1E-10� K.]
-
-
-Zero, Potential.
-Conventionally, the potential of the earth. True zero potential could
-only exist in the surface of a body infinitely distant from other
-electrified bodies.
-
-
-Zero, Thermometric.
-There are three thermometric zeros. In the R�aumur and centigrade
-scales, it is at the temperature of melting ice; in the Fahrenheit
-scale, it is 32� F. below that temperature, or corresponds to -17.78� C.
-
-The third is the absolute zero. (See Zero, Absolute.)
-
-
-Zinc.
-A metal; one of the elements; atomic weight, 65.1;
-specific gravity, 6.8 to 7.2.
-
-                                                   microhms.
-Resistance at 0� C. (32� F.), per centimeter cube,   5.626
-Resistance at 0� C. (32� F.), per inch cube,         2.215
-
-Relative resistance (silver = 1),                    3.741
-
-                                                        ohms.
-Resistance of a wire, 1 foot long, weighing 1 grain,   .5766
-  (a) 1 foot long, 1 millimeter diameter,            33.85
-  (b) 1 meter long, weighing 1 gram,                   .4023
-  (c) 1 meter long, 1 millimeter diameter,             .07163
-
-Zinc is principally used in electrical work as the positive plate in
-voltaic batteries.
-
-
-Zincode.
-The terminal connecting with the zinc plate, or its equivalent in an
-electric circuit; the negative electrode; the kathode. A term now little
-used.
-
-
-Zinc Sender.
-An apparatus used in telegraphy for sending a momentary reverse current
-into the line after each signal, thus counteracting retardation.
-
-
-Zone, Peripolar.
-In medical electricity, the region surrounding the polar zone, q. v.
-
-
-Zone, Polar.
-In medical electricity, the region surrounding the electrode applied to
-the human body.
-
-
-583-624  INDEX.
-
-  Page
-A  7
-Absolute  7
-Absolute Calibration  97
-Absolute Electric Potential  429
-Absolute Electrometer  222
-Absolute Galvanometer  266
-Absolute Measurement  8
-Absolute Potential  428
-Absolute Temperature  8
-Absolute Unit  554
-Absolute Unit Resistance, Weber's   468
-Absolute Vacuum  557
-Absolute Zero  581
-Abscissa  7
-Abscissas, Axis of   54
-Absorption, Electric   8
-A. C. C.  8
-Acceleration  8
-Accumulator  8
-Accumulator, Electrostatic  8
-Accumulator, Water Dropping   9
-Acetic Acid Battery   58
-Acheson Effect   208
-Acid, Carbonic  108
-Acid, Chromic, Battery  61
-Acid, Hydrochloric, Battery   66
-Acid, Spent  491
-Acid, Sulphuric    497
-Acidometer  10
-Acierage  494
-Aclinic Line  10
-Acoustic Telegraphy   10
-Acoutemeter  10, 53
-Action, Electrophoric   230
-Action, Local  331
-Action, Magne-crystallic   335
-Action, Refreshing  454
-Action, Secondary  477
-Actinic Photometer  411
-Actinic Rays.   11
-Actinism  11
-Actinometer, Electric   11
-Active Electric Circuit,   123
-Activity  11
-Actual Horse Power  290
-Adapter  11
-A. D. C.,   11
-Adherence, Electro-magnetic   11
-Adherence, Magnetic  338
-Adjuster, Cord   152
-Adjustment of Brushes  90
-Admiralty Rules of Heating  12
-AEolotropic  34
-Aerial Cable  95
-Aerial Conductor  12
-Affinity  12
-Affinity, Molecular   380
-After Current,.   159
-Agglomerate Leclanch� Battery  66
-Agir Motor   13
-Agone  13
-Agonic Line,   13
-Air  13
-Air Blast  13
-Air Condenser  14
-Air Field  252
-Air Gaps  15
-Air Line Wire  15
-Air Pump, Heated   15
-Air Pump, Mercurial   16
-Air Pumps, Short Fall   16
-Alarm, Burglar   16
-Alarm, Electric  17
-Alarm, Fire, Electric Automatic   257
-Alarm, Fire and Heat  17
-Alarm, Overflow   18
-Alarm, Water Level   18
-Alcohol, Electric Rectification of   18
-Alignment,   18
-Allotropy  18
-Alloy  18
-Alloy, Platinum  419
-Alloy, Platinum-Silver  419
-Alloys, Paillard  400
-Alphabet, Telegraphic   19
-Alternating  23
-Alternating Current  159
-Alternating Current Arc  23
-Alternating Current Dynamo  193
-Alternating Current Generator or Dynamo  24
-Alternating Current Meter  373
-Alternating Current System  23
-Alternating Field  252
-Alternative Current  563
-Alternative Path  24
-Alternatives, Voltaic   563
-Alternator  24
-Alternator, Constant Current   24
-Alternator, Dead Point of an   177
-Alternation  23
-Alternation, Complete   23
-Alternation, Cycle of   175
-Alum Battery  58
-Aluminum  24
-Aluminum Battery  58
-Amalgam  24
-Amalgamation  25
-Amber  25
-American Twist Joint   309
-Ammeter  26
-Ammeter, Ayrton   26
-Ammeter, Commutator   26
-Ammeter, Cunynghame's   26
-Ammeter, Eccentric Iron Disc  27
-Ammeter, Electro-magnetic  27
-Ammeter, Gravity  27
-Ammeter, Magnetic Vane  27
-Ammeter, Magnifying Spring   28
-Ammeter, Permanent Magnet   28
-Ammeter, Reducteur for   453
-Ammeter, Solenoid   28
-Ammeter, Spring   28
-Ammeter, Steel Yard  28
-Ammunition Hoist, Electric   29
-Amperage  29
-Ampere  29
-Ampere- and Volt-meter Galvanometer  274
-Ampere Arc   30
-Ampere Balance  56
-Ampere Currents  30
-Ampere Feet  30
-Ampere-hour  30
-Amperes, Lost   30
-Amp�re's Memoria Technica   30
-Ampere Meters  26, 30
-Ampere Meter, Balance  391
-Ampere Meter, Neutral Wire   391
-Ampere-minute  30
-Ampere Ring  30
-Ampere-second  30
-Ampere's Theory of Magnetism  354
-Ampere-turns  31
-Ampere-turns, Primary   31
-Ampere-turns, Secondary   31, 551
-Ampere Windings  31
-Amp�rian Currents  165
-Amplitude of Waves  31
-Analogous Pole  31, 425
-Analysis  31
-Analysis, Electric  32
-Analysis, Electrolytic  214
-Analyzer, Electric   32
-Anelectrics  32
-Anelectrotonus  32
-Angle of Declination  32, 177
-Angle of the Polar Span  32
-Angle of Inclination or Dip  33
-Angle of Lag  33-318
-Angle of Lead  33
-Angle of Maximum Sensitiveness  479
-Angle of Polar Span  423
-Angle, Polar   423
-Angle, Unit  554
-Angular Currents  165
-Angular Currents, Laws of   165
-Angular Force  544
-Angular Velocity  32, 559
-Animal Electricity  33
-Animal System, Electric Excitability of   247
-Anion  33
-Anisotropic  34
-Annealing, Electric  34
-Annular Electro-magnet  216
-Annunciator  34
-Annunciator Clock  35
-Annunciator Clock, Electric   127
-Annunciator Drop  35
-Annunciator, Gravity Drop   35
-Annunciator, Needle  35
-Annunciator, Swinging or Pendulum  35
-Anodal Diffusion  35
-Anode  36
-Anodic Closure Contraction  36
-Anodic Duration Contraction  36
-Anodic Opening Contraction  36
-Anodic Reactions  36
-Anomalous Magnet  335
-Anti-induction Conductor   36, 145
-Anti-magnetic Shield  37
-Antilogous Pole,   425
-Antimony  37
-Anvil  37
-A. O. C.  38
-Aperiodic  38
-Aperiodic Galvanometer  266
-Apparent Coefficient of Magnetic Induction  346
-Apparent Resistance  297, 462
-Apparent Watts  573
-Arago's Disc  88
-Arc  39
-Arc, Ampere   30
-Arc, Compound.   39
-Arc, Electric Blow-pipe   84
-Arc, Metallic  39
-Arc, Micrometer   39, 376
-Arc, Multiple   387
-Arc, Simple  39
-Arc, Voltaic   39
-Arc Box, Multiple   387
-Arc Lamp  319
-Arc Lamp, Differential   320
-Arc Lamp, Double Carbon   191
-Areometer  41
-Areometer, Bead   41
-Argyrometry  41
-Arm   41
-Armature  41
-Armature, Bar   42
-Armature, Bipolar   42
-Armature Bore  42
-Armature Chamber  42
-Armature, Closed Coil   43
-Armature Coil, or Coils   43
-Armature Conductors, Lamination of   319
-Armature Core  43
-Armature, Cylinder   43
-Armature, Cylindrical   45
-Armature, Disc   43
-Armature, Drum  45
-Armature Factor  45
-Armature, Flat Ring   45
-Armature, Girder   49
-Armature, H  49
-Armature, Hinged   45
-Armature, Hole  45
-Armature, Intensity   45
-Armature Interference  45
-Armature, Load of   46
-Armature, Multipolar   46
-Armature, Neutral   46
-Armature, Neutral Relay  46, 390
-Armature, Non-polarized   46
-Armature of Influence Machine  46
-Armature of Leyden Jar or Static Condenser  46
-Armature, Open Coil   46
-Armature, Perforated   45
-Armature, Pivoted   47
-Armature Pockets  47
-Armature, Polarized   47
-Armature, Pole   47
-Armature, Quantity   47
-Armature, Radial   47
-Armature Reactions  41
-Armature, Revolving, Page's   47
-Armature, Ring   48
-Armature, Rolling  49
-Armatures, Gyrostatic Action of   288
-Armature, Shuttle  49
-Armature, Siemens' Old  49
-Armature, Spherical  49
-Armature, Stranded Conductor   49
-Armature, Unipolar  50, 553
-Armature, Ventilation of   560
-Armor of Cable  50
-Arm, Rheostat   472
-Arms, Proportionate   436
-Arms, Ratio  437
-Arms, Rocker  50-474
-Arrester, Lightning   328
-Arrester, Lightning, Counter-electro-motive Force   329
-Arrester, Lightning, Plates   329
-Arrester, Lightning, Vacuum.   329
-Arrester Plate  417
-Arrester, Spark   489
-Arrival Curve  168
-Articulate Speech  50
-Artificial Carbon  106
-Artificial Magnet  335
-Ascending Lightning  330
-Assymmetrical Resistance  462
-Astatic  50
-Astatic Circuit  12
-Astatic Couple  157
-Astatic Galvanometer  266
-Astatic Needle  50
-Astronomical Meridian,   372
-Asymptote  51
-Atmosphere  51
-Atmosphere, Residual  51, 460
-Atmospheric Electricity  51
-Atom  52
-Atomic Attraction   52
-Atomic Current  160
-Atomic Energy  238
-Atomic Heat  52-285
-Atomic Weight  53
-Atomicity   52
-Attracted Disc Electrometer  223
-Attraction  53
-Attraction, Atomic  52
-Attraction, Magnetic   338
-Attraction, Molar   380
-Attraction, Molecular  380
-Attraction and Repulsion, Electro-dynamic  211
-Attraction and Repulsion, Electro-magnetic  217
-Attraction and Repulsion, Electro-static   234
-Attraction and Repulsion, Electro-static, Coulomb's Law of   155
-Audiometer  53
-Aura, Electrical   53
-Aurora  53
-Austral Pole  54
-Autographic Telegraph  510
-Automatic Circuit Breaker  121
-Automatic Cut Out  175, 475
-Automatic Drop  192
-Automatic Electric Bell  78
-Automatic Electric Fire Alarm  257
-Automatic Switch   500
-Automatic Telegraph  504
-A. W. G.,    54
-Axial Couple  514
-Axial Force  544
-Axial Magnet  336
-Axis, Electric   54
-Axis, Magnetic   338
-Axis of Abscissas   54
-Axis of Ordinates  54, 397
-Axis of X  54
-Axis of Y  54, 397
-Ayrton's Ammeter  26
-Azimuth    54
-Azimuth Circle  54
-Azimuth Compass  141
-Azimuth, Magnetic   338
-
-B   55
-B. A.   55
-Back Electro-motive Force of Polarization  156
-Back Induction  55
-Back Shock or Stroke of Lightning  55
-Back Stroke  55
-Bagration Battery  59
-Balance  55
-Balance, Ampere  56
-Balance Ampere Meter  391
-Balance, Electric  577
-Balance, Inductance   293
-Balance, Plating  417
-Balance, Slide  374
-Balance, Thermic   85
-Balance, Torsion, Coulomb's   544
-Balance, Wheatstone's  577
-Balata  56
-Ballistic Galvanometer  567
-Balloon Battery  59
-B. and S. W. G.   56
-Banked Battery  59
-Bank of Lamps  323
-B. A. Ohm  394
-Barad  56
-Bar, Armature   42
-Bar, Bus  94
-Bar Electro-magnet  217
-Bar Magnet  336
-Barometer  56
-Bar, Omnibus   94
-Bar Photometer  411
-Bars, Commutator   56, 140
-Bath  57
-Bath, Bipolar Electric   57
-Bath, Copper  152
-Bath, Copper Stripping   152
-Bath, Electric Head   284
-Bath, Electric Shower   57
-Bath, Gold  279
-Bath, Gold Stripping  279
-Bath, Multipolar Electric   57
-Bath, Nickel  391
-Bath, Plating  418
-Baths, Electro-medical   222
-Bath, Silver  484
-Bath, Silver Stripping   484
-Bath, Stripping  57
-Bath, Unipolar Electric   57
-Batten  57-58
-Battery, Acetic Acid   58
-Battery, Alum  58
-Battery, Aluminum  58
-Battery, Bagration  59
-Battery, Balloon   59
-Battery, Banked  59
-Battery, Bichromate   59
-Battery, Bunsen   59
-Battery, Cadmium   60
-Battery, Callan  60
-Battery, Camacho's   60
-Battery, Carr�'s   60
-Battery, Cautery   61
-Battery Cell, Element of a   237
-Battery, Chloric Acid  61
-Battery, Chloride of Lime   61
-Battery, Chromic Acid   61
-Battery, Closed Circuit   61
-Battery, Column   61
-Battery, d'Arsonval's   62
-Battery, de la Rue  .62
-Battery, de la Rive's Floating   179
-Battery, Dry  63
-Battery, Elements of   63
-Battery, Faradic  63
-Battery, Ferric Chloride   63
-Battery, Fuller's  63
-Battery, Gas  63
-Battery, Gas, Grove's   281
-Battery Gauge  64
-Battery, Gravity   64
-Battery, Grenet   65
-Battery, Grove's  65
-Battery, Hydrochloric Acid   66
-Battery, Lalande & Chaperon   69
-Battery, Lalande-Edison   69
-Battery, Lead Chloride   66
-Battery, Lead Sulphate  66
-Battery, Leclanch�   66
-Battery, Leclanch� Agglomerate  66
-Battery, Local   66, 831
-Battery, Magnetic   338
-Battery, Main  66
-Battery, Mari� Davy's   67
-Battery, Maynooth's   67
-Battery, Medical  67
-Battery, Meidinger's  68
-Battery, Mercury Bichromate   63
-Battery Mud  68
-Battery, Multiple Connected   68
-Battery, Niaudet's  61
-Battery, Nitric Acid   68
-Battery of Dynamos  6S
-Battery of Leyden Jars,   68
-Battery, Open Circuit  68
-Battery or Pile, Thermo-electric   530
-Battery, Oxide of Copper   68
-Battery, Peroxide of Lead   69
-Battery, Platinized Carbon   69
-Battery, Plunge   69
-Battery, Pneumatic   69
-Battery, Primary   69, 434
-Battery, Pulvermacher's Electro-medical   69
-Battery, Sal Ammoniac   69
-Battery, Salt, or Sea Salt  69
-Battery, Sand  70
-Battery, Secondary  70
-Battery, Secondary, Plant�'s   72
-Battery, Secondary, Real Efficiency of   205
-Battery, Sir William Thomson's   72
-Battery, Siemens and Halske's  72
-Battery, Skrivanow   72
-Battery, Smee's   73
-Battery Solutions, Chromic Acid   73
-  119, 178, 192, 232, 318, 421, 542, 549
-Battery, Spiral  73
-Battery, Split   73
-Battery, Sulphate of Mercury   67
-Battery System, Universal  556
-Battery, Thermo-chemical   530
-Battery, Trough  73
-Battery, Trouv�'s Blotting Paper   73
-Battery, Tyer's  74
-Battery, Upward's  75
-Battery, Varley's  76
-Battery, Volta's   76
-Battery, Voltaic or Galvanic   76
-Battery Voltmeter  569
-Battery, Water  77
-Battery, Wollaston  78
-B. A. Unit,  554
-B. A. Unit of Resistance  78, 462
-B. A. Volt  568
-B. E.   78
-Bead Areometer  41
-Becquerel's Laws of Thermo-electricity   78
-Beaum� Hydrometer  78
-Bed-piece  78
-Bell, Automatic Electric    78
-Bell, Call   78, 98
-Bell Call  79
-Bell Call, Extension   248
-Bell, Circular  79
-Bell, Differentially Wound   79
-Bell, Electric  79
-Bell, Electro-mechanical    80
-Bell, Indicating   80, 297
-Bell, Magneto  80
-Bell, Magneto Call   361
-Bell, Night  392
-Bell-shaped Magnet,   336
-Bells, Relay  80, 457
-Bell, Trembling   78
-Bell, Vibrating.    78
-Belts, Joints in  311
-Bennett's Electroscope  233
-Bias  80
-Bias of Tongue of Polarized Relay  542
-Bichromate Battery  59
-Bichromate Mercury Battery  63
-Bifilar Suspension  498
-Bifilar Winding  81
-Binary Compound  81
-Binding   81
-Binding Posts or Screws  81
-Binnacle  81
-Biology, Electro-  208
-Bioscopy, Electric   82
-Bipolar Armature  42
-Bipolar Electric Bath  57
-Bisected Coils  132
-Bismuth  82
-Bi-telephone  82, 524
-Black, Platinum   419
-Blasting, Electric  83
-Bleaching, Electric   83
-Block, Branch   87
-Block, Cross-over   158
-Block System  83
-Block Wire  83
-Blotting Paper Battery, Trouv�'s   73
-Blow-pipe  83
-Blow-pipe, Electric Arc   84
-Blue Magnetism  355
-Bluestone  84
-Blue Vitriol   562
-Board, Cross-connecting   157
-Board, Fuse   263
-Board, Hanger   284
-Board, Key   313
-Board, Multiple Switch   387
-Board of Trade Ohm  394
-Board of Trade Unit  555
-Board, Switch  500
-Boat, Electric   84
-Bobbins  84
-Body Protector  84
-Bohenberger's Electroscope  233
-Boiler Feed, Electric  84
-Boiling   84
-Boll  85
-Bolometer   85
-Bombardment, Molecular   380
-Bore, Armature   42
-Boreal Pole  85
-Bot  85
-Bound Charge  115
-Box Bridge  85
-Box, Cable  95
-Box, Cooling  151
-Box, Distributing   190
-Boxes, Flush  258
-Box, Fishing  311
-Box, Fuse  263
-Boxing the Compass  86
-Box, Junction  311
-Box, Multiple Arc   387
-Box, Resistance  462
-Box, Resistance, Sliding   463
-Box Sounding Relay  457
-Box, Splice   492
-Bracket, Saddle   475
-Bracket, Wall   572
-Braid, Tubular  550
-Brake, Electro-magnetic   86
-Brake, Magneto-electric   362
-Brake, Prony  435
-Branch   87
-Branch Block  87
-Branch Circuit  121
-Branch Conductor  87
-Branding, Electric   87
-Brassing  87
-Brazing, Electric   87
-Break  88
-Break, Circuit Loop   125
-Break-down Switch  88
-Breaker, Automatic Circuit   121
-Breaker, Circuit  121
-Breaker, Circuit, File   121
-Breaker, Contact  121, 146
-Break Induced Current  162
-Breaking Weight  89
-Break, Loop    332
-Break Shock  482
-Breath Figures, Electric   89
-Breeze, Electric   89
-Breeze, Static  493
-Breguet Unit of Resistance  463
-Bridge   89
-Bridge, Box  89
-Bridge, Inductance   293
-Bridge, Induction   293
-Bridge Key   313
-Bridge, Magnetic  338
-Bridge, Meter  373
-Bridge, Resistance   577
-Bridge, Reversible    472
-Bridge, Slide  374
-Bridge, Wheatstone .   575
-Bridge, Wheatstone, Commercial   36
-British Association Bridge  89
-Britannia Joint  309
-Broadside Method  89
-Broken Circuit  125
-Bronzing  89
-Brush  90
-Brush, Carbon  90
-Brush, Collecting  90
-Brush, Discharge   187
-Brushes, Adjustment of   90
-Brushes, Lead of   90
-Brushes, Negative Lead of   324
-Brushes, Scratch   476
-Brush, Faradic   251
-Brush Holders  91
-Brush, Pilot  91
-Brush, Rotating    91
-Brush, Third  91
-Brush Trimmer  549
-Brush, Wire Gauge   92
-Buckling  92
-Bug  92
-Bug Trap  92
-Bunched Cable  95
-Bunsen Battery  59
-Bunsen Disc  92
-Bunsen's Photometer   412
-Buoy, Electric  93
-Burglar Alarm  16
-Burner, Electric Gas   93
-Burning  94
-Bus Bar  94
-Bus Rod  94
-Bus Wire  94
-Butt Joint  310
-Button, Call   98
-Button, Press   94
-Button, Push   93, 98
-Buzzer  94
-B. W. G.  94
-
-C  95
-C. C.  109
-Cable  95
-Cable, Aerial  95
-Cable, Armature of   50
-Cable, Armor of   50
-Cable Box  95
-Cable, Bunched  95
-Cable, Capacity of   95
-Cable Clip  97
-Cable Core  96
-Cable, Duplex   96
-Cable, Flat   96
-Cablegram  96
-Cable Grip  96
-Cable Hanger  96
-Cable Hanger Tongs  97
-Cable, Suspension Wire of   97
-Cable Tank  97
-Cadmium Battery  60
-Calamine  97
-Cal Electricity  208
-Calibration  97
-Calibration, Absolute   97
-Calibration, Invariable   97
-Calibration, Relative  98
-Call Bell  78, 79, 98
-Call Bell, Extension   248
-Call Bell, Magneto   361
-Call Button  98
-Call, Thermo  530
-Call, Thermo-electric   531
-Callan Battery   60
-Calling Drop  98
-Calorie or Calory  98
-Calorimeter  98
-Calorimetric Photometer  412
-Calory or Calorie  98
-Cam, Listening   330
-Camacho's Battery  60
-Candle  99
-Candle, Concentric   99
-Candle, Debrun   99
-Candle, Decimal  99
-Candle, Electric   99
-Candle-foot  259
-Candle, German Standard   99
-Candle Holder  99
-Candle, Jablochkoff   100
-Candle, Jamin   100
-Candle, Meter    374
-Candle Power  100
-Candle Power, Nominal   101
-Candle Power, Rated  101
-Candle Power, Spherical   101
-Candle, Standard   101
-Candle, Wilde   101
-Caoutchouc  101
-Cap, Insulator  306
-Capacity, Carrying   108
-Capacity, Dielectric   102
-Capacity, Electric or Electrostatic   102
-Capacity, Instantaneous  102
-Capacity, Magnetic Inductive   346, 349
-Capillarity, Electro-  209
-Capillary Electrometer  224
-Capacity of a Telegraph Conductor  103
-Capacity of Cable  95
-Capacity of Polarization of a Voltaic Cell  103
-Capacity, Polarization  424
-Capacity, Residual  103
-Capacity, Specific Inductive   103
-Capacity, Storage  105, 495
-Capacity, Unit of   105
-Capillarity  105
-Capillary Telephone  525
-Carbon  106
-Carbon, Artificial  106
-Carbon Brush  90
-Carbon, Concentric  107
-Carbon, Cored   107
-Carbon Dioxide  107
-Carbon Holders  107
-Carbonic Acid,   108
-Carbonic Acid Gas  108
-Carbonization  107
-Carbonized Cloth  107
-Carbon, Platinized, Battery   69
-Carbon Resistance   463
-Carbon, Retort    471
-Carbons, Lamp, Flashing of Incandescent   257
-Carbon, Telephone  525
-Carbon Transmitter  549
-Carbon, Volatilization of   108
-Carburetted Hydrogen, Heavy   397
-Carcel  108
-Carcel Gas Jet  108
-Carcel Lamp  108
-Card, Compass   142
-Cardew Voltmeter  569
-Carr�'s Battery  60
-Carrying Capacity  108
-Cascade  108
-Cascade, Charging and Discharging Leyden Jars in   108
-Cascade, Gassiot's   275
-Case-hardening, Electric   109
-Cataphoresis  109
-Catch, Safety  175
-Cathode, etc. See Kathode   312
-Caustry, Galvano  109
-Cautery Battery   61
-Cautery, Electric  109
-Cautery, Galvano  109
-Cautery, Galvano-electric  109
-Cautery, Galvano-thermal   109
-Cell, Battery, Element of a   237
-Cell, Constant  109
-Cell, Electrolytic   109
-Cell, Porous    427
-Cell, Selenium   478
-Cell, Standard Voltaic  109
-Cell, Standard Voltaic, Daniells'  109
-Cell, Standard Voltaic, Latimer Clark's  110
-Central Station  493
-Central Station Distribution or Supply  112
-Centre of Gravity  112
-Centre of Gyration  112
-Centre of Oscillation  112
-Centre of Percussion  112
-Centrifugal Force  112
-Centrifugal Governor  113
-C. G. S.  113
-Chain, Molecular  380
-Chamber, Armature  42
-Chamber of Incandescent Lamp  113
-Change, Chemical  116
-Changer, Pole  425
-Changing Over Switch  500
-Changing Switch  500
-Chaperon, Lalande &, Battery   69
-Characteristic  169
-Characteristic Curve  113, 168
-Characteristic Curve, External  171
-Characteristic Curve of Converter  169
-Characteristic, Drooping   114
-Characteristic, External   114
-Characteristic, Internal   114
-Characteristics of Sound  114
-Charge  114
-Charge and Discharge Key    313
-Charge, Bound   115
-Charge Current  160
-Charge, Density of   115, 180
-Charge, Dissipation of   115
-Charge, Distribution of   115
-Charge, Free  115
-Charge, Negative  389
-Charge, Residual   116
-Charging Curve  170
-Chatterton's Compound  116
-Chemical Change  116
-Chemical Electric Meter   375
-Chemical, Electro-, Equivalents   244
-Chemical Element  236
-Chemical Energy  239
-Chemical Equivalent  244
-Chemical, Cautery Galvano   265
-Chemical Recorder  117
-Chemical Telephone  526
-Chemical Equivalent, Thermo-   245
-Chemistry  118
-Chemistry, Electro-   209
-Cheval, Force de  260
-Chicle  56
-Chimes, Electric   118
-Chloric Acid Battery  61
-Chloride, Ferric, Battery   63
-Chloride, Lead, Battery  66
-Chloride of Lime Battery  61
-Chlorimeter   73
-Choking Coil  132
-Chronograph, Electric   118
-Chromic Acid Battery   61
-Chromic Acid Battery Solutions  73
-Chromoscope  119
-Chutaux's Solution  119
-Cipher Code  130
-Circle, Azimuth   54
-Circle, Delezenne's  133
-Circle, Galvanic or Voltaic   119
-Circle, Magic  119
-Circuit  120
-Circuit, Astatic   120
-Circuit, Branch  121
-Circuit Breaker  121
-Circuit Breaker, Automatic   121
-Circuit Breaker, File  121
-Circuit Breaker, Mercury  121
-Circuit Breaker, Pendulum  121
-Circuit Breaker, Tuning-fork  121
-Circuit, Broken  125
-Circuit Changing Switch  500
-Circuit, Closed, Battery   61
-Circuit, Derivative  123
-Circuit, Derived   123
-Circuit, Electrostatic   123
-Circuit, Electric, Active   123
-Circuit, External   123
-Circuit, Grounded   123
-Circuit, Incomplete  125
-Circuit Indicator  298
-Circuit Induction, Open   303
-Circuit, Leg of   325
-Circuit, Local   331
-Circuit, Loop  125
-Circuit, Loop Break  125
-Circuit, Magnetic  340
-Circuit, Magnetic Double   340
-Circuit, Main  125
-Circuit, Main Battery   125
-Circuit, Metallic  125
-Circuit, Negative Side of   125
-Circuit, Open  125
-Circuit, Positive Side of   125
-Circuit, Recoil   125
-Circuit, Return  125
-Circuits, Forked   126
-Circuit, Short   482
-Circuit, Shunt   123, 126
-Circuit, Simple  126
-Circuits, Parallel   123, 126
-Circuit, Voltaic  126
-Circuit Working, Short   482
-Circular Bell,  79
-Circular Current,   160
-Circular, Mil   379
-Circular Units  126, 555
-Circumflux  126
-Clamp  126
-Clark's Compound  126
-Cleansing, Fire   257
-Clearance Space,   489
-Cleat, Crossing   127
-Cleats  127
-Cleavage, Electrification by   127
-Clip, Cable  97
-Clock, Annunciator   35
-Clock, Controlled   127
-Clock, Controlling   127
-Clock, Electric Annunciator   127
-Clock, Electrolytic   128
-Clock, Master  127
-Clock, Secondary  127
-Clock, Self-winding, Electric  128
-Clockwork Feed  128
-Cloisons  128
-Closed Circuit Battery  61
-Closed Coil Armature  43
-Closure  128
-Closure Contraction, Kathodic   312
-Cloth, Carbonized  107
-Club-foot Electro-magnet  217
-Clutch  128
-Clutch, Electro-magnetic  128
-Coatings of a Condenser, or Prime Conductor  129
-Cockburn Fuse   263
-Code, Cipher  130
-Code, S. N.   486
-Code, Telegraphic   130, 511
-Coefficient  130
-Coefficient, Apparent, of Magnetic Induction   346
-Coefficient, Economic   130, 204, 205
-Coefficient of Electrical Energy  205
-Coefficient of Expansion  247
-Coefficient of Induced Magnetization  359, 354
-Coefficient of Magnetic Induction  346, 349
-Coefficient of Mutual Induction  301
-Coefficient of Self-induction  298
-Coercitive Force  471
-Coercive Force   471
-Coercive or Coercitive Force  131
-Coil and Plunger  131
-Coil and Coil Plunger  131
-Coil and Plunger, Differential    132
-Coil, Armature   43
-Coil, Choking   132
-Coil, Earth   133
-Coil, Electric    133
-Coil, Exploring   350
-Coil, Flat   133
-Coil, Induction   133
-Coil, Induction, Inverted    136
-Coil, Induction, Telephone   137
-Coil. Kicking  132
-Coil, Magnet  336
-Coil, Magnetizing   137
-Coil, Reaction   132
-Coil, Resistance    137
-Coil, Resistance, Standard   464
-Coil, Rhumkorff   138
-Coil, Ribbon   138
-Coils, Bisected  132
-Coils, Compensating   138
-Coils, Sectioned   138
-Coils, Henry's   138
-Coils, Idle  295
-Coil, Single, Dynamo   202
-Coil, Spark   489
-Coil, Sucking  132
-Collecting Brush  90
-Collecting Ring  139
-Collector  139
-Colombin,  139
-Colophony  460
-Colors of Secondary Plates  478
-Column Battery  61
-Column, Electric    139
-Comb  140
-Combined Resistance  464
-Comb Protector  437
-Commercial Efficiency   204
-Commercial Efficiency of Dynamo  195
-Commercial Wheatstone Bridge  86
-Common Reservoir  460
-Communicator  140
-Commutation, Diameter of   182
-Commutator  140
-Commutator Ammeter  26
-Commutator Bars  140, 56
-Commutator, Flats in   140
-Commutator, High Bars of   289
-Commutator, Neutral Line of   390
-Commutator, Neutral Point of   390
-Commutator of Current Generators and Motors  140
-Commutators, Bars of   56
-Commutator Segments  56
-Commutator, Split Ring   141
-Commuted Current  160
-Commuter  140
-Commuting Transformer  547
-Compass  141
-Compass, Azimuth  141
-Compass, Boxing the   86
-Compass Card,  142
-Compass, Declination   142
-Compass, Inclination   142
-Compass, Mariners'  142
-Compass, Points of the   143
-Compass, Spirit  143
-Compass, Surveyors   143
-Compass, Variation of the   32, 558
-Compensating Coils  138
-Compensating Magnet  336
-Compensating Poles  426
-Compensating Resistance  144
-Complementary Distribution  144
-Complete Alternation  23
-Component  144
-Components of Earth's Magnetism  356
-Composition of Forces  260
-Compound Arc  39
-Compound, Binary  81
-Compound, Chatterton's   116
-Compound, Clark's   126
-Compound Dynamo  195
-Compounding, Over-   399
-Compound Magnet  336
-Compound or Compound Wound Motor  382
-Compound Winding   578
-Concentration of Ores, Magnetic   340
-Concentrator, Magnetic    340
-Concentric Candle  99
-Concentric Carbon  107
-Condenser  144
-Condenser, Coatings of a, or Prime Conductor   129
-Condenser, Epinus'   242
-Condenser, Plate  417
-Condenser, Sliding  144
-Condenser, Varley's   559
-Condensing Electroscope  233
-Conductance  144
-Conductance, Magnetic  340
-Conduction  144
-Conduction, Electrolytic    215
-Conductive Discharge  187
-Conductivity  144
-Conductivity, Magnetic   340
-Conductivity, Specific  145
-Conductivity, Unit of   145
-Conductivity, Variable   145
-Conductor  145
-Conductor, Anti-induction   145
-Conductor, Branch  87
-Conductor, Capacity of a Telegraph  103
-Conductor, Conical  145
-Conductor, Imbricated   146
-Conductor, Interpolar  307
-Conductor, Leakage   325
-Conductor, Prime  146, 434
-Conductors, Equivalent  146
-Conductors, Lamination of Armature  319
-Conductors, Service  481
-Conductor, Underground   552
-Congress Ohm  395
-Congress Volt   568
-Conical Conductor  145
-Conjugate  146
-Connect  146
-Connection, Cross   158
-Connection, Relay   457
-Connector   146
-Consequent Points  422
-Consequent Poles  146, 478
-Conservation of Electricity  146
-Conservation of Energy  239
-Constant Current  160
-Constant Current Alternator  24
-Constant Current Regulation  454
-Constant, Dielectric  183
-Constant, Galvanometer   268
-Constant Potential  429
-Constant Potential Regulation  455
-Constant, Time    54l
-Contact Breaker  121, 146
-Contact, Electric   147
-Contact Electricity  147
-Contact Faults  147
-Contact Key, Double   314
-Contact Key, Sliding    316
-Contact Lamp  320
-Contact, Line of   330
-Contact Point  147
-Contact Potential Difference  147
-Contact Ring  473
-Contact Spring  148
-Contact Series  147
-Contact Theory  148
-Continuity, Magnetic   340
-Continuous Alternating Transformer  547
-Continuous Current  161
-Continuous Current Transformer  384, 547
-Contraction, Anodic Closure  36
-Contraction, Anodic Duration   36
-Contraction, Anodic Opening  36
-Contraction, Kathodic Closure   312
-Contraction, Kathodic Duration  312
-Contractures  148
-Contraplex Working  580
-Control, Electro-magnetic   218
-Control, Gravity   281
-Controlled Clock,  127
-Controlling Clock  127
-Controlling Field  148
-Controlling Force  148
-Controlling Magnet  185, 336
-Control, Magnetic   341
-Control, Spring  492
-Convection, Electric   149
-Convection, Electrolytic   149, 214
-Convection of Heat, Electric   149
-Convective Discharge  187
-Conversion, Efficiency of   205
-Converter  149
-Cooling Box  151
-Co-ordinates, Origin of   391
-Co-ordinates, System of   150
-Copper  151
-Copper Bath  152
-Copper Stripping Bath  152
-Copper Voltameter  563
-Cord Adjuster  152
-Cord, Flexible   152
-Cord, Pendant   405
-Core  152
-Core, Armature   43
-Core, Cable    96
-Cored Carbon  107
-Core-discs  152
-Core-discs, Perforated   154
-Core-discs, Pierced   152
-Core-discs, Toothed   154
-Core, Laminated   154
-Core, Magnet   336
-Core Ratio  154
-Core, Ribbon   154
-Core, Ring  155
-Cores, Krizik's   318
-Core, Stranded   155
-Core, Tangentially Laminated   155
-Core Transformer  155
-Core, Tubular  155
-Corpusants  155
-Corresponding Points  422
-Coulomb  155
-Coulomb's Law of Electrostatic Attraction and Repulsion  155
-Coulomb's Law of Magnetic Attraction and Repulsion  338
-Coulomb's Torsion Balance  544
-Coulomb, Volt-   568
-Counter, Electric   156
-Counter Electro-motive Force  156, 228
-Counter-electro-motive Force Lightning Arrester  329
-Counter Inductive Effect  204
-Couple  156
-Couple, Astatic  157
-Couple, Axial  544
-Couple, Magnetic    341
-Couple, Moment of  544
-Couple, Thermo-electric   532
-Couple, Voltaic or Galvanic   156
-Coupling  259
-Coupling of Dynamo  201
-C. P.  157
-Crater  157
-Creep, Diffusion   184
-Creeping  157
-Creeping, Magnetic  341
-Creeping of Magnetism  356
-Crith  157
-Critical Current  161
-Critical Distance of Alternative Path  190
-Critical Resistance  464
-Critical Speed  157
-Critical Value, Villari's   561
-Crookes' Dark Space  489
-Cross  157
-Cross-connecting Board  157
-Cross Connection  158
-Cross Induction  298
-Crossing Cleat  127
-Crossing Wires  158
-Cross-magnetizing Effect  158, 298
-Cross-over Block  158
-Cross, Peltier's  405
-Cross Talk  158
-Crucible, Electric    158
-Crystallization, Electric   158
-Cube, Faraday's   249
-Culture. Electro-  209
-Cunynghame's Ammeter  26
-Cup, Mercury   371
-Cup, Porous   159, 426
-Current  159
-Current, After  159
-Current, Alternating  159
-Current, Alternating System   23
-Current, Alternative  563
-Current Arc, Alternating   23
-Current, Atomic  160
-Current, Break Induced   162
-Current, Charge  160
-Current, Circular   160
-Current, Commuted   160
-Current, Constant   160
-Current, Continuous  161
-Current, Continuous, Transformer   384
-Current, Critical   161
-Current, Daniel  161
-Current, U. S. or Siemens' Unit   161
-Current, Demarcation   161
-Current Density  161
-Current, Derived   164
-Current, Diacritical   161
-Current, Diaphragm   161
-Current, Direct  162
-Current, Direct Induced   162
-Current, Direction of  162
-Current, Displacement   162
-Current, Extra   162
-Current, Faradic   162
-Current, Field of Force of a   255
-Current, Foucault   163
-Current, Franklinic   163
-Current Generator  277
-Current, Induced  163
-Current Induction  163
-Current Induction, Unipolar   553
-Current Intensity  163
-Current, Inverse Induced   163
-Current, Jacobi's Unit of   163
-Current, Joint   163
-Current, Linear   164
-Current, Make and Break   164, 367
-Current, Make Induced   163
-Current Meter  164, 375
-Current Meter, Alternating   373
-Current, Negative  164
-Current, Nerve and Muscle   164
-Current, Opposed   164
-Current, Partial   164
-Current, Polarizing   164
-Current, Positive   164
-Current, Power of Periodic   433
-Current, Pulsatory  164
-Current, Rectified   164
-Current, Rectilinear   165
-Current, Redressed   165
-Current Regulation, Constant    454
-Current, Reverse Induced   163
-Current Reverser  165
-Currents, Ampere  30
-Currents, Amp�rian   165
-Currents, Angular.   165
-Currents, Angular, Laws of   165
-Currents, Earth   166
-Current, Secondary  166
-Current, Secretion   166
-Currents, Eddy   163
-Currents, Eddy Displacement  162
-Currents in Parallel Circuits, Independence of   297
-Current, Sinuous   166
-Current, Sheet   166
-Current, Shuttle   483
-Currents, Local   163
-Currents, Local  331
-Currents, Multiphase   166
-Currents, Natural   166, 389
-Currents, Nerve   390
-Currents of Motion  167
-Currents of Rest  167
-Currents, Orders of   167
-Currents, Parasitical   163
-Currents, Polyphase   167
-Currents, Rotatory  167
-Currents, Thermo-electric   167
-Current Streamlets  495
-Current, Swelling   167
-Current, Tailing  501
-Current, Undulatory   167
-Current, Unit  167
-Current, Wattless   168
-Curve, Arrival  168
-Curve, Characteristic   113, 168
-Curve, Characteristic, of Converter   169
-Curve, Charging   170
-Curve, Discharging   170
-Curve, Elastic  206
-Curve, Electro-motive Force   170
-Curve, External Characteristic   . 171
-Curve, Harmonic  174, 485
-Curve, Horse Power   171
-Curve, Isochasmen   171
-Curve, Life    171
-Curve, Load  172
-Curve, Magnetization   172
-Curve of Distribution of Potential in Armature  172
-Curve of Dynamo  173
-Curve of Saturation of Magnetic Circuit  174
-Curve of Sines  173, 485
-Curve of Torque  174
-Curve, Permeability Temperature   174
-Curve, Sine   174, 485
-Curve, Sinusoidal  174, 485
-Curves, Magnetic   341
-Cut In  174
-Cut Out  174
-Cut Out, Automatic   175, 475
-Cut Out, Magnetic  175
-Cut Out, Plug   175
-Cut Out, Safety  175
-Cut Out, Spring Jack   493
-Cut Outs, Time  541
-Cut Out, Wedge  175
-Cutting of Lines of Force  175
-Cycle of Alternation  175
-Cycle of Magnetization  360
-Cylinder, Armature  43
-Cylinder, Electric Machine   333
-Cylindrical Armature  45
-Cystoscopy  175
-
-Damper  176
-Damping  176
-Damping Magnet  336
-Daniell's Standard Voltaic Cell  109
-Dark Space, Faraday's   249
-D'Arsonval's Battery  62
-Dash-pot  176
-Dead Beat  38, 176
-Dead Beat Discharge  187
-Dead Earth  176, 203
-Dead Point of an Alternator  177
-Dead Turns  177
-Dead Turns of a Dynamo  551
-Dead Wire  177
-Death, Electrical   177
-Debrun Candle  99
-Decalescence  177
-Decay of Magnetism  356
-Deci  177
-Decimal Candle  99
-Declination, Angle of   32-177
-Declination Compass  142
-Declination, Magnetic   342
-Declination Map  309
-Declination of the Magnetic Needle  178
-Decomposition  178
-Decomposition, Electrolytic   178
-Decrement  178
-De-energize  178
-Deflagration  178
-Deflagrator, Hare's   73
-Deflecting Field  178
-Deflection  178
-Deflection Method  178
-Deflection of Magnet  337
-Degeneration, Reaction of   179
-Degradation of Energy  239
-Deka  179
-De la Rive's Floating Battery  179
-De la Rue Battery  62
-Delaurier's Solution  179
-Delezenne's Circle  133
-Demarcation Current  161
-Demagnetization  179
-Density, Current   161
-Density, Electrical  115
-Density, Electric Superficial   180
-Density, Field   252
-Density, Magnetic   342
-Density of Charge  115, 180
-Dental Mallet, Electric   180
-Deposit, Electrolytic   180
-Deposit, Nodular   392
-Depolarization  180
-Depolarizing Fluid  258
-Derivation, Points of   180, 423
-Derivative Circuit  123
-Derived Circuit  123
-Derived Current  164
-Derived Units  555
-Desk Push  180
-Detector  180
-Detector, Lineman's  180
-Deviation of Discharge  188
-Deviation, Quadrantal   180
-Deviation, Semi-circular   181
-Device, Safety  475
-Dextrotorsal  181
-Diacritical  181
-Diacritical Current  161
-Diagometer  181
-Diagnosis, Electro-  181, 210
-Diagram, Thermo-electric   532
-Dial Telegraph  505
-Diamagnetic  181
-Diamagnetic Polarity  181, 423
-Diamagnetism  182
-Diameter of Commutation  182
-Diapason, Electric  182
-Diaphragm  182
-Diaphragm Current  161
-Dielectric,  182
-Dielectric Capacity   102
-Dielectric Constant  183
-Dielectric, Energy of   183
-Dielectric Polarization  183
-Dielectric Resistance  183, 464
-Dielectric Strain  183
-Dielectric Strength  183
-Dielectric Stress  496
-Differential Arc Lamp  320
-Differential Coil and Plunger  132
-Differential Galvanometer  268
-Differentially Wound Bell,   79
-Differential Magnetometer  365
-Differential Motor  382
-Differential Relay  457
-Differential Thermo-electric Pile  533
-Differential Winding Working  183
-Diffusion  184
-Diffusion, Anodal .   35
-Diffusion Creep  184
-Digney Unit of Resistance  464
-Dimensions and Theory of Dimensions  184
-Dimmer  185
-Diode Working  580
-Dioxide, Carbon   107
-Dioxide, Sulphur  497
-Dip, Magnetic  342, 346
-Dip of Magnetic Needle  185
-Dipping  185
-Dipping Needle  185
-Direct Current  162
-Direct Current Dynamo  197
-Direct Induced Current,  .  162
-Direct Reading Galvanometer  269
-Directing Magnet  185
-Direction  185
-Direction of Current  162
-Direction, Positive   428
-Directive Power  187
-Disc, Arago's   38
-Disc, Armature  43
-Disc, Bunsen   92
-Disc, Dynamo  197
-Disc, Faraday's  249
-Discharge and Charge Key  313
-Discharge, Brush  187
-Discharge, Conductive  187
-Discharge, Convective  187
-Discharge, Dead Beat   187
-Discharge, Disruptive   187
-Discharge, Duration of   188
-Discharge, Glow  187
-Discharge, Impulsive   188
-Discharge Key, Kempe's   315
-Discharge, Lateral  188
-Discharge of Magnetism  356
-Discharge, Oscillatory  188
-Discharger  188
-Discharger, Henley's Universal   189
-Discharger, Universal  189
-Discharger, Universal, Henley's  189
-Discharge, Silent  187, 189, 206
-Discharge, Spark   189
-Discharge, Surging   188
-Discharging Curve  170
-Discharging Rod  189
-Discharging Tongs  189
-Disconnection  189
-Discontinuity, Magnetic  342
-Discovery, Oerstedt's  394
-Disc Winding  579
-Dispersion Photometer  412
-Displacement Current  162
-Displacement, Electric   188
-Displacement, Oscillatory   398
-Disruptive Discharge  187
-Disruptive Tension  189
-Dissimulated Electricity  189
-Dissipation of Charge  115
-Dissociation  189, 535
-Distance, Critical, of Alternative Path   190
-Distance, Explosive   190
-Distance, Sparking   190
-Distance, Striking    496
-Distant Station  493
-Distillation  190
-Distortion of Field  252
-Distributing Box  190
-Distributing Switches  190
-Distribution, Complementary   144
-Distribution, Isolated   309
-Distribution of Charge  115
-Distribution of Electric Energy, Systems of   190
-Distribution of Magnetism, Lamellar,   357
-Distribution of Magnetism, Solenoidal  358
-Distribution of Supply, Central Station   112
-Door Opener, Electric   190
-Dosage, Galvanic  190
-Double Break Switch  500
-Double Carbon Arc Lamp  191
-Double Contact Key  314
-Double Curb Working  581
-Double Fluid Theory  191
-Double Fluid Voltaic Cell  191
-Double Magnetic Circuit  340
-Double Needle Telegraph  506
-Double Plug  191
-Double Pole Switch  500
-Double Tapper Key  314
-Double Touch, Magnetization by  358
-Double Trolley  549
-Double Wedge  191
-Doubler  191
-D. P.  191
-Drag  191
-Drag of Field  254
-Dreh-Strom  191
-Drill, Electric   191
-Drip Loop  192
-Driving Horns  192
-Dronier's Salt  192
-Drooping Characteristic  114
-Drop, Annunciator   35
-Drop, Automatic   192
-Drop, Calling   98
-Drum Armature  45
-Drum, Electric   193
-Dry Battery  63
-Dry Pile, Zamboni's   581
-Dub's Laws  193
-Duct  193
-Duplex Bridge Telegraph  506
-Duplex Cable  96
-Duplex Differential Telegraph  507
-Duplex Telegraph,  506
-Duration Contraction, Kathodic  312
-Duration of Electric Spark  490
-Dyad  193
-Dyeing, Electric  193
-Dynamic Electricity  193
-Dynamic, Electro-   211
-Dynamic Induction, Magnetic   347
-Dynamo, Alternating Current   193
-Dynamo, Alternating Current Regulation of   195
-Dynamos, Battery of    68
-Dynamo, Commercial Efficiency of   195
-Dynamo, Compound   195
-Dynamo, Coupling of   201
-Dynamo, Curve of  173
-Dynamo, Dead Turns of a   551
-Dynamo, Direct Current   197
-Dynamo, Disc  197
-Dynamo-electric Machine  197
-Dynamo, Electroplating  198
-Dynamo, Equalizing  198
-Dynamo, Field and Armature Reaction of  450
-Dynamo, Far Leading  198
-Dynamo or Magneto-electric Generator, Flashing in a   257
-Dynamo, Inductor   199
-Dynamo, Interior Pole  199
-Dynamo, Iron Clad  200
-Dynamo, Ironwork Fault of a   308
-Dynamo, Motor  200
-Dynamo, Multipolar   200
-Dynamo, Non-polar   200
-Dynamo, Open Coil  200
-Dynamo, Overtype  399
-Dynamos, Regulation of   455
-Dynamo, Ring  200
-Dynamo, Self Exciting  201
-Dynamo, Separate Circuit  201
-Dynamo, Separately Excited   201, 479
-Dynamo, Series   201
-Dynamo, Shunt   202
-Dynamo, Single Coil  202
-Dynamo, Tuning Fork   202
-Dynamo, Unipolar  202, 553
-Dynamograph  199
-Dynamometer  200
-Dyne  203
-
-Earth  203
-Earth Coil  133
-Earth Currents  166
-Earth, Dead  176, 203
-Earth, Magnetization by   359
-Earth, Partial  203, 404
-Earth Plate  203
-Earth Return  203
-Earth's Magnetism, Components of   356
-Earth, Solid  203
-Earth, Swinging    203
-Earth, Total   203
-Ebonite  203
-Eccentric Iron Disc Ammeter  27
-Economic Coefficient  130, 204, 205
-Eddy Currents  163
-Eddy Displacement Currents  162
-Ediswan  204
-Edison Effect  204
-Edison-Lalande Battery  69
-Eel, Electric  204
-Effect, Acheson  208
-Effect, Counter-inductive   204
-Effect, Cross-magnetizing   158, 298
-Effect, Edison  204
-Effect, Faraday   249
-Effect, Ferranti   251
-Effect, Hall   284
-Effect, Joule   311
-Effect, Kerr  235, 312
-Effect, Mordey   381
-Effect, Page   401
-Effect, Peltier  404
-Effect, Photo-voltaic   415
-Effect, Seebeck  478
-Effect, Skin  486
-Effect, Thomson   538
-Effect, Voltaic   563
-Efficiency  204
-Efficiency, Commercial   204
-Efficiency, Electrical   205
-Efficiency, Gross  205
-Efficiency, Intrinsic  205
-Efficiency, Net  205
-Efficiency of Conversion  205
-Efficiency of Secondary Battery Quantity   205
-Efficiency of Secondary Battery, Real   205
-Efflorescence  206
-Effluvium, Electric   206
-Egg, Philosopher's   409
-Elastic Curve  206
-Elasticity, Electric   206
-Electrepeter   206
-Electric, Absolute, Potential   429
-Electric Absorption  8
-Electric Actinometer  11
-Electric Alarm  17
-Electrical Classification of Elements   237
-Electrically Controlled Valve  558
-Electric Ammunition Hoist  29
-Electric Analysis  32
-Electric Analyzer  32
-Electric Annealing  34
-Electric Annunciator Clock  127
-Electric Arc Blow-pipe  84
-Electric Aura  53
-Electric Automatic Fire Extinguisher  257
-Electric Axis  54
-Electric Balance  577
-Electric Bath, Bipolar  57
-Electric Bath, Multipolar   57
-Electric Bath, Unipolar   57
-Electric Bell  79
-Electric Bell, Automatic   78
-Electric Bioscopy  82
-Electric Blasting  83
-Electric Bleaching  83
-Electric Boat  84
-Electric Boiler Feed  84
-Electric Branding  87
-Electric Brazing  87
-Electric Breath Figures  89
-Electric Breeze  89
-Electric Buoy  93
-Electric Candle  99
-Electric Case Hardening  109
-Electric Cautery  109
-Electric Chimes  118
-Electric Chronograph  118
-Electric Circuit, Active  123
-Electric Clock, Self-winding    128
-Electric Coil  133
-Electric Column  139
-Electric Contact  147
-Electric Convection  149
-Electric Convection of Heat  149, 286
-Electric Counter  156
-Electric Crucible  158
-Electric Crystallization  158
-Electric Death  177
-Electric Density  115
-Electric Dental Mallet  180
-Electric Diapason  182
-Electric Displacement  189
-Electric Door Opener  190
-Electric Double Refraction  454
-Electric Drill   191
-Electric Drum  193
-Electric Dyeing  193
-Electric Eel  204
-Electric Efficiency   205
-Electric Effluvium  206
-Electric Elasticity  206
-Electric Endosmose  238
-Electric Energy  239
-Electric Energy, Coefficient of  205
-Electric Energy, Systems of Distribution of   190
-Electric Engraving  245
-Electric Entropy  242
-Electric Etching  245
-Electric Evaporation  246
-Electric Excitability of Animal Systems  247
-Electric Exosmose  247
-Electric Expansion  247
-Electric Fire Alarm, Automatic  257
-Electric Floor Matting  369
-Electric Fluid  258
-Electric Fly or Flyer  259
-Electric Fog  259
-Electric Furnace  263
-Electric Fuse  264
-Electric Gas Burners  93
-Electric Headlight  285
-Electric Head Bath  284
-Electric Heat  285
-Electric Heater  286
-Electric Horse Power  290
-Electric Image  296
-Electric Incandescence  297
-Electric Influence  305
-Electric Insulation  305
-Electricities, Separation of   479
-Electricity  206
-Electricity, Animal   33
-Electricity, Atmospheric    51
-Electricity, Cal  208
-Electricity, Conservation of   146
-Electricity, Contact  147
-Electricity, Dissimulated   189
-Electricity, Dynamic   193
-Electricity, Frictional   262
-Electricity, Latent   323
-Electricity, Negative   389
-Electricity, Plant   317
-Electricity, Positive  428
-Electricity, Specific Heat of   491
-Electricity, Static  493
-Electricity, Storage of   495
-Electricity, Voltaic   563
-Electricity, Vitreous   562
-Electric Machine, Plate  417
-Electric Machine, Wimshurst   577
-Electric Mains  367
-Electric Mass  368
-Electric Matter  368
-Electric Meter, Chemical   375
-Electric Meter, Thermal   375
-Electric Meter, Time   375
-Electric Mortar  382
-Electric Motor  382
-Electric or Electrostatic Capacity  102
-Electric Organ  397
-Electric Oscillations  398
-Electric Osmose  398
-Electric Pen  405
-Electric Pendulum  405
-Electric Piano  415
-Electric Picture   415
-Electric Pistol  416
-Electric Popgun  282
-Electric Portrait  415
-Electric Potential Difference   429
-Electric Potential, Unit of   432
-Electric Power   433
-Electric Pressure  434
-Electric Probe  435
-Electric Prostration  437
-Electric Protector   437
-Electric Radiometer  447
-Electric Ray  450
-Electric Rectification of Alcohol  18
-Electric Reduction of Ores  453
-Electric Reduction of Phosphorous   410
-Electric Register  454
-Electric Residue  116, 460
-Electricity, Resinous   461
-Electric Resonance   468
-Electric Resonator  470
-Electric Rings  392
-Electrics  208
-Electric Saw  476
-Electric Screen,   476
-Electric Shadow   480
-Electric Shock  482
-Electric Shower Bath   57
-Electric Soldering  487
-Electric Spark, Duration of   490
-Electric Sphygmophone  491
-Electric Storms  495
-Electric Striae  496
-Electric Subway   496
-Electric Subway, Underground   552
-Electric Sunstroke   497
-Electric Superficial Density  180
-Electric Swaging  499
-Electric Tele-barometer  504
-Electric Telemanometer   521
-Electric Telemeter  521
-Electric Tempering  527
-Electric Tension  529
-Electric Thermometer  535
-Electric Thermostat  537
-Electric Torpedo  543
-Electric Tower  545
-Electric Transmission of Energy  240
-Electric Trumpet  550
-Electric Tube  550
-Electric Typewriter  551
-Electric Unit of Work  580
-Electric Varnish  559
-Electric Welding   574
-Electric Whirl  577
-Electric Wind  578
-Electrification  208
-Electrification by Cleavage  127
-Electrification by Pressure  434
-Electrified Body, Energy of an   . 241
-Electrization  208
-Electro-biology  208
-Electro-capillarity  209
-Electro-chemical Equivalents  209, 244
-Electro-chemical Series  209
-Electro-chemistry   209
-Electro-culture  209
-Electrode  210
-Electrode, Indifferent   210
-Electrodes, Erb's Standard of   210
-Electrodes, Non-polarizable  210
-Electrodes, Shovel   483
-Electrode, Therapeutic   210
-Electro-diagnosis  181, 210
-Electro-dynamic  211
-Electro-dynamic Attraction and Repulsion,   211
-Electro-dynamic Rotation of Liquids  474
-Electro-dynamometer, Siemens'  212
-Electro-gilding  277
-Electro-kinetic  211
-Electrolier  212
-Electrolysis  212
-Electrolysis, Laws of   213
-Electrolyte  214
-Electrolytic Analysis  214
-Electrolytic Cell  109
-Electrolytic Clock  128
-Electrolytic Conduction  215
-Electrolytic Convection  149, 214
-Electrolytic Deposit  180
-Electrolytic Iron  308
-Electrolytic Resistance  464
-Electro-magnet  215, 337
-Electro-magnet, Annular   216
-Electro-magnet, Bar  217
-Electro-magnet, Club-foot   217
-Electro-magnet, Hinged  217
-Electro-magnet, Hughes'    291
-Electro-magnetic Ammeter  27
-Electro-magnetic and Magnetic Equipotential Surface  244
-Electro-magnetic Attraction and Repulsion  217
-Electro-magnetic Brake  86
-Electro-magnetic Clutch  128
-Electro-magnetic Control  218
-Electro-magnetic Eye  248
-Electro-magnetic Field of Force  218
-Electro-magnetic Force  260
-Electro-magnetic Gun  282
-Electro-magnetic Induction  218, 299
-Electro-magnetic Inertia  305
-Electro-magnetic Induction, Mutual  302
-Electro-magnetic Interrupter for Tuning Fork  307
-Electro-magnetic Leakage  219
-Electro-magnetic Lines of Force  219
-Electro-magnetic Liquids, Rotation of   475
-Electro-magnetic Meter  375
-Electro-magnetic Quantity  445
-Electro-magnetic Quantity, Practical Unit of   445
-Electro-magnetic Shunt  .483
-Electro-magnetic Stress  219, 496
-Electro-magnetic Theory of Light  219
-Electro-magnetic Unit of Energy  220
-Electro-magnetic Vibrator  561
-Electro-magnetic Waves,   573
-Electro-magnet, Ironclad   219
-Electro-magnetism  220
-Electro-magnet, Joule's  337
-Electro-magnet, Long Range  220
-Electro-magnet, One Coil  219
-Electro-magnet, Plunger  220
-Electro-magnet, Polarized  220
-Electro-magnets, Interlocking   221
-Electro-magnets, Multiple Wire Method of Working   388
-Electro-magnet, Stopped Coil  221
-Electro-magnets, Surgical   222
-Electro-mechanical Bell  80
-Electro-mechanical Equivalent  244
-Electro-medical Baths  222
-Electro-medical Battery, Pulvermacher's  69
-Electro-metallurgy  222
-Electrometer  222
-Electrometer, Absolute  222
-Electrometer. Attracted Disc   223
-Electrometer, Capillary  224
-Electrometer Gauge  226
-Electrometer, Lane's   226
-Electrometer, Quadrant   226
-Electrometer, Thermo-   536
-Electrometer, Weight  223
-Electro-motive Force  227
-Electro-motive Force, Counter-   228
-Electro-motive Force Curve  170
-Electro-motive Force, Impressed   297
-Electro-motive Force, Motor  384
-Electro-motive Force. Oscillatory  398
-Electro-motive Force, Transverse  549
-Electro-motive Force, Unit   228
-Electro-motive Intensity  228
-Electro-motive Potential Difference  429
-Electro-motive Series  228
-Electro-motograph  229
-Electro-motor  229
-Electro-muscular Excitation  229
-Electro-negative   229
-Electro-optics  229
-Electrophoric Action  230
-Electrophorus  230
-Electro-physiology  231
-Electroplating  231, 418
-Electroplating Dynamo  198
-Electro-pneumatic Signals  231
-Electropoion Fluid  232
-Electro-positive  232
-Electro-puncture  232
-Electro-receptive  232
-Electroscope  232
-Electroscope, Bennett's   233
-Electroscope, Bohenberger's   233
-Electroscope, Condensing  233
-Electroscope, Gold Leaf   233
-Electroscope, Pith Ball  234
-Electrostatic Attraction and Repulsion  234
-Electrostatic Attraction and Repulsion. Coulomb's Law of   155
-Electrostatic Circuit  123
-Electrostatic Equipotential Surface  244
-Electrostatic Field of Force  254
-Electrostatic Force  260
-Electrostatic Induction  302
-Electrostatic Induction, Coefficient of   234
-Electrostatic Induction, Mutual   303
-Electrostatic Lines of Force  234
-Electrostatic Quantity  445
-Electrostatic Refraction  235
-Electrostatics  235
-Electrostatic Series  235
-Electrostatic Stress  236, 496
-Electrostatic Telephone  526
-Electrostatic Voltmeter  571
-Electro-thermal Equivalent  245
-Electro-therapeutics or Therapy  236
-Electrotonic State  493
-Electrotonus  236
-Electrotype  236
-Element, Chemical   236
-Element, Galvanic  264
-Element, Mathematical   237
-Element, Negative  390
-Element of a Battery Cell  237
-Element, Positive  277
-Elements, Electrical Classification of   237
-Elements, Magnetic   342
-Elements of Battery  63
-Elements, Thermo-electric   237
-Element, Voltaic  237
-Elias' Method of Magnetization  360
-Elongation  237, 540
-Elongation, Magnetic   344
-Embosser, Telegraph   237
-E. M. D. P.  238
-E. M. F.  238
-Energy  238
-Energy, Atomic  238
-Energy, Chemical  239
-Energy, Conservation of    239
-Energy, Degradation of   239
-Energy, Electric  239
-Energy, Electrical, Coefficient of   205
-Energy, Electric Transmission of   240
-Energy, Electro-magnetic, Unit of   220
-Energy, Kinetic  241
-Energy, Mechanical   241
-Energy Meter  375
-Energy, Molar  241
-Energy, Molecular   241
-Energy of an Electrified Body  241
-Energy of Dielectric  183
-Energy of Position  211
-Energy of Stress  241
-Energy, Physical   241
-Energy, Potential, or Static   241
-Energy, Radiant    446
-Energy, Thermal   242
-End-on Method  238
-End or Pole, Marked  368
-Endosmose, Electric   238
-End Play  238
-End, Unmarked   556
-English Absolute or Foot Second Unit of Resistance  465
-Engraving, Electric   245
-Entropy  242
-Entropy, Electric  242
-Epinus Condenser  242
-E. P. S.  243
-Equator, Magnetic   344
-Equator of Magnet   337
-Equipotential  244
-Equipotential Surface  498
-Equipotential Surface, Electrostatic  244
-Equipotential Surface, Magnetic and Electro-magnetic   244
-Equalizer  243
-Equalizer, Feeder  251
-Equalizing Dynamo  198
-Equivalent, Chemical   116, 244
-Equivalent Conductors  146
-Equivalent, Electro-thermal   245
-Equivalent, Joule's  311
-Equivalent Resistance  465
-Equivalents, Electro-chemical  209, 244
-Equivalent, Thermo-chemical   245
-Equivalent, Water   572
-Equivolt  245
-Erb's Standard of Electrodes  210
-Erg   245
-Erg-ten  245
-Error, Heating  286
-Escape  245
-Essential Resistance  465, 466
-Etching, Electric   245
-Ethene  397
-Ether  246
-Eudiometer   246
-Evaporation, Electric  246
-Ewing's Theory of Magnetism  356
-Exchange, Telephone  246
-Excitation, Electro-muscular   229
-Excitability, Faradic   246
-Excitability, Galvanic   247
-Excitability of Animal System, Electric   247
-Exciter  247
-Exosmose, Electric  247
-Expansion, Coefficient of   247
-Expansion, Electric  247
-Experiment, Franklin's   261
-Experiment, Hall's   284
-Experiment, Kerr's  312
-Experiment, Matteueci's   369
-Experiments, Hertz's  470
-Experiment, Volta's Fundamental  567
-Experiment with Frog, Galvani's   262
-Exploder  247
-Explorer  247
-Exploring Coil  350
-Explosive Distance  190
-Extension Bell Call  248
-Extension, Polar  423
-External Characteristic  114
-External Characteristic Curve  171
-External Circuit  123
-External Resistance  465, 467
-Extinguisher, Automatic Electric Fire    257
-Extra Current  162
-Extra-polar Region  454
-Eye, Electro-magnetic  248
-Eye, Selenium  478
-
-Facsimile Telegraph  510
-Factor, Armature   45
-Fahrenheit Scale  248
-Fall of Potential  430
-False Poles, Magnetic   350
-Farad  248
-Faraday, Effect   249
-Faraday's Cube  249
-Faraday's Dark Space  249, 489
-Faraday's Disc  249
-Faraday's Net  250
-Faraday's Ring  473
-Faraday's Transformer  250
-Faraday's Voltameter  250
-Faradic  250
-Faradic Battery  63
-Faradic Brush  251
-Faradic Current  162
-Faradic Excitability  246
-Faradization   251
-Faradization, Galvano-  265
-Far Leading Dynamo  198
-Fault of a Dynamo, Ironwork   308
-Faults  251
-Faults, Contact   147
-Feed Clockwork  128
-Feeder  251
-Feeder, Equalizer   251
-Feeder, Main or Standard   251
-Feeder, Negative   251
-Feeder, Neutral   251
-Feeder, Positive   251
-Feeder, Switch   500
-Feet, Ampere   30
-Ferranti Effect  251
-Ferric Chloride Battery  63
-Ferro-magnetic  252
-Fibre and Spring Suspension   252
-Fibre Suspension  252
-Field, Air  252
-Field, Alternating   252
-Field and Armature Reaction of Dynamo,  450
-Field, Controlling    148
-Field, Deflecting   178
-Field Density  252
-Field, Distortion of   252
-Field, Drag of  254
-Field, Intensity of a Magnetic   306
-Field Magnet  337
-Field of Force  .  254
-Field of Force, Electro-magnetic  218
-Field of Force, Electrostatic   254
-Field of Force, Magnetic   344
-Field of Force of a Current  255
-Field of Force, Uniform   553
-Field, Pulsatory   256
-Field, Rotating   256
-Field, Stray  256, 495
-Field, Uniform  256
-Field, Uniform Magnetic   345
-Field, Waste   256
-Figure of Merit  256
-Figures, Haldat's   284
-Figures, Lichtenberg's   327
-Figures, Magnetic   345
-Filament  256
-Filament, Magnetic   345
-Filaments, Paper   402
-File, Circuit Breaker   121
-Finder, Position   427
-Finder, Range   447
-Finder, Wire  580
-Fire Alarm, Electric Automatic  257
-Fire and Heat Alarm  17
-Fire Extinguisher, Electric Automatic  257
-Fire Cleansing  257
-Fire, St. Elmo's   494
-Fishing Box  311
-Flashing in a Dynamo or Magneto-Electric Generator  257
-Flashing of Incandescent Lamp Carbons  257
-Flashing Over  258
-Flash, Side   484
-Flat Cable  96
-Flat Coil  133
-Flat Ring Armature  45
-Flats  258
-Flats in Commutator  140
-Flexible Cord  152
-Floating Battery, De la Rive's   179
-Floating Magnets, Meyer's  370
-Floor Matting, Electric  369
-Floor Push  258
-Fluid, Depolarizing   258
-Fluid, Electric  258
-Fluid, Electropoion   232
-Fluid, Insulator.   306
-Fluid, North Magnetic   357
-Fluids, Magnetic  345
-Fluid, South Magnetic  356
-Fluid Theory, Single   486
-Fluorescence  258
-Flush Boxes  258
-Fluviograph  259
-Flux, Magnetic  345
-Fly or Flyer, Electric   259
-Foci Magnetic  259
-Fog, Electric  259
-Following Horns  259
-Foot-candle  259
-Foot, Mil-  379
-Foot-pound  259
-Foot-step  259
-Force  259
-Force, Annular  544
-Force, Axial  544
-Force, Centrifugal   112
-Force, Coercive or Coercitive   131-471
-Force, Controlling  148
-Force, Counter-electro-motive   156
-Force de Cheval  260
-Force, Electro-magnetic  260
-Force, Electro-motive   227
-Force, Electro-motive, Transverse   549
-Force, Electrostatic   260
-Force, Field of  254
-Force, Field of, of a Current   255
-Force, Field of, Electrostatic  254
-Force, Kapp Line of   312
-Force, Lines of  330
-Force, Magnetic  346
-Force, Magnetic Field of   344
-Force, Magnetic Lines of   348
-Force, Magneto-motive  365
-Force, Motor Electro-motive   384
-Force of Polarization, Back Electro-motive  156
-Force, Oscillatory, Electro-motive   398
-Force, Photo-electro-motive   410
-Forces, Composition of   260
-Forces, Parallelogram of   260
-Forces, Resolution of  261
-Force, True Contact   549
-Force, Tubes of   261
-Force, Unit of  261
-Forked Circuits  126
-Fork, Tuning, Dynamo   202
-Forming  261
-Formula of Merit  256
-Foucault Current  163
-Foundation Ring  261
-Fourth State of Matter  261
-Frame  261
-Frame, Resistance   465
-Franklinic Current  163
-Franklin's Experiment  261
-Franklin's Plate  262
-Franklin's Theory  262-486
-Free Charge  115
-Free Magnetism  356
-Frequency  262
-Frequency, High  289
-Frictional Electricity  262
-Frictional Electric Machine  333
-Frictional Heating  262
-Friction Gear, Magnetic   276
-Friction, Magnetic  295-346
-Fringe  262
-Frog, Galvani's Experiment with   262
-Frog, Rheoscopic   262
-Frying  263
-Fulgurite  263
-Fuller's Battery  63
-Fulminating Pane  262
-Fundamental Unit  554
-Furnace, Electric   263
-Fuse Block  175
-Fuse Board  263
-Fuse Box  263
-Fuse, Cockburn   263
-Fuse, Electric   264
-Fuse Links  330
-Fuse, Safety   175-475
-
-Galvanic  264
-Galvanic Action, Volta's Law of  568
-Galvanic Dosage  190
-Galvanic Element  264
-Galvanic Excitability  247
-Galvanic or Voltaic Battery  76
-Galvanic or Voltaic Circle  119
-Galvanic or Voltaic Couple  156
-Galvanic Polarization  265
-Galvani's Experiment with Frog  262
-Galvanism  265
-Galvanization  265
-Galvanization, Labile   265
-Galvanized Iron  265
-Galvano-cautery  109
-Galvano-cautery, Chemical   265
-Galvano-electric Cautery  109
-Galvano-faradization  265
-Galvanometer  265
-Galvanometer, Absolute   266
-Galvanometer, Aperiodic   266
-Galvanometer, Astatic   266
-Galvanometer, Ballistic   267
-Galvanometer Constant  268
-Galvanometer, Differential   268
-Galvanometer, Direct Reading   269
-Galvanometer, Marine   269
-Galvanometer, Mirror   271
-Galvanometer, Potential  269
-Galvanometer, Proportional   269
-Galvanometer, Quantity   269
-Galvanometer, Reflecting   270
-Galvanometer, Shunt   271-483
-Galvanometer, Sine  271
-Galvanometer, Tangent    272
-Galvanometer, Torsion   273-544
-Galvanometer, Upright   274
-Galvanometer, Vertical  274
-Galvanometer, Volt and Ampere Meter  274
-Galvano-plastics   275
-Galvano-puncture  232-275
-Galvanoscope  275
-Galvano-thermal Cautery  100
-Gap, Spark   490
-Gas Battery  63
-Gas Battery, Grove's   281
-Gas Burner, Electric   93
-Gas, Carbonic Acid   108
-Gas, Electrolytic  275
-Gases, Magnetism of   357
-Gases, Mixed  275
-Gas Jet, Carcel   108
-Gas, Olefiant  397
-Gassing   275
-Gassiot s Cascade  275
-Gastroscope  275
-Gas Voltameter  564
-Gauge, Battery  64
-Gauge, Electrometer   226
-Gauss  275
-Gauss' Principle  276
-Gauss, Tangent Positions of   276
-Gauze Brush, Wire  92
-Gear, Magnetic  346
-Gear, Magnetic Friction    276
-Geissler Pump  437
-Geissler Tubes  276
-Generating Plate  277
-Generator, Current   277
-Generator Inductor  199
-Generator, Magneto-electric  362
-Generator, Magneto-electric, Flashing in a Dynamo or   257
-Generator, Motor  384
-Generator, Pyromagnetic.   442
-Generators and Motors, Commutator of Current  140
-Generator, Secondary   277-477
-Geographic Meridian  372
-German Mile Unit of Resistance  466
-German Silver  277
-German Standard Candle  99
-Gilding, Electro-  277
-Gilding Metal   277
-Gimbals  278
-Girder Armature  49
-Glass  278
-Globe or Globular Lightning  330
-Glow Discharge  187
-Gold  278
-Gold Bath  279
-Gold Leaf Electroscope  233
-Gold Stripping Bath  279
-Governor, Centrifugal   113
-Governor, Rate   449
-Graduator  279
-Gram  280
-Gram-atom  280
-Gram-molecule  280
-Graphite  280
-Gravitation  280
-Gravity, Acceleration of   280
-Gravity Ammeter  27
-Gravity Battery  64
-Gravity, Centre of   112
-Gravity Control  281
-Gravity Drop Annunciator  35
-Grease Spot  92
-Green Vitriol  562
-Grenet Battery  65
-Grid  281
-Grid Plug   420
-Grip, Cable   96
-Gross Efficiency  205
-Ground  281
-Grounded Circuit  123
-Ground Plate  417
-Ground Wire  281
-Grove's Battery  65
-Grove's Gas Battery  281
-Guard Ring  282
-Guard Tube  282
-Gun, Electro-magnetic   282
-Gutta Percha  282
-Gyration, Centre of   112
-Gyrostatic Action of Armatures  283
-
-H   283
-H Armature  49
-Haarlem Magnet  337
-Hair, Removal of, by Electrolysis   283
-Haldat's Figures  284
-Hall Effect  284
-Hall Effect, Real  284
-Hall Effect, Spurious   284
-Halleyan Lines  308
-Hall's Experiment  284
-Halske's and Siemens' Battery  72
-Hand Hole  190
-Hanger Board  284
-Hanger, Cable   96
-Hanger, Cable, Tongs  97
-Harcourt's Pentane Standard  406
-Hare's Deflagrator  73
-Harmonic   23
-Harmonic Curve  174, 485
-Harmonic Motion, Simple   486
-Harmonic Receiver  284, 451
-Head Bath, Electric   284
-Head-light, Electric  285
-Head, Torsion   544
-Heat  285
-Heat and Fire Alarm  17
-Heat, Atomic   52, 285
-Heat, Electric   285
-Heat, Electric, Convection of   149, 286
-Heat, Irreversible.  286
-Heat, Mechanical Equivalent of  286
-Heat, Molecular  286
-Heat, Specific  286
-Heat, Specific, of Electricity   288
-Heat Units  288
-Heater, Electric  286
-Heating, Admiralty Rules of  12
-Heating Error  286
-Heating, Frictional   262
-Heating Magnet  286
-Heavy Carburetted Hydrogen,   397
-Hecto  288
-Hedgehog Transformer  548
-Heliograph  288
-Helix  288
-Henley's Universal Discharger  189
-Henry  288
-Henry's Coils  138
-Hermetically Sealed   289
-Hertz's Experiments  470
-Heterostatic Method  280
-Hexode Working  581
-High Bars of Commutator  289
-High Frequency  289
-High Vacuum  557
-Hinged Armature  45
-Hinged Electro-magnet  217
-Hissing  289
-Hittorf's Resistance  466
-Hittorf's Solution  289
-Hoffer's Method of Magnetization  360
-Hole Armature  45
-Hole, Hand   190
-Holders  289
-Holder, Brush   91
-Holder, Candle   99
-Holders, Carbon   107
-Holophote Lamp  321
-Holtz's Influence Machine  334
-Home Station  493
-Hood  290
-Horizontal Induction  302
-Horns  290
-Horns, Driving   132
-Horns, Following   259
-Horns, Leading   324
-Horns, Trailing   259
-Horse Power  290
-Horse Power, Actual   290
-Horse Power Curve  171
-Horse Power, Electric   290
-Horse Power Hour  290
-Horse Power, Indicated   290
-Horseshoe Magnet  337
-Hour, Ampere-  30
-Hour, Horse Power   290
-H. P.  290
-Hughes' Electro-magnet  291
-Hughes' Induction Balance  291
-Hughes' Sonometer  488
-Hughes' Telegraph   511
-Hughes' Theory of Magnetism  357
-Hughes' Type Printer  511
-Human Body, Resistance of   467
-Hydrochloric Acid Battery  66
-Hydro-electric  293
-Hydro-electric Machine  293
-Hydrogen  294
-Hydrogen, Carburetted, Heavy  397
-Hydrometer, Beaum�   78
-Hygrometer  294
-Hyperbolic Logarithms  389
-Hysteresis  295
-Hysteresis, Magnetic   294
-Hysteresis, Static  295
-Hysteresis, Viscous   295, 356
-
-Idioelectrics  295
-Idiostatic Method  295
-Idle Coils  295
-Idle Poles  296
-Idle Wire  291
-Igniter  296
-I. H P.  296
-Illuminating Power  296
-Illuminating Power, Spherical  296
-Illuminating Power, Standard of, Viole's   561
-Illumination, Unit of   296
-Image, Electric  296
-Imbricated Conductor  146
-Immersion, Simple  185
-Impedance  297, 462
-Impedance, Impulsive   297
-Impedance, Oscillatory   297
-Impressed Electro-motive Force  297
-Impulse  297
-Impulsive Discharge  188
-Impulsive Impedance  297
-In-and-out, Soaking  486
-Incandescence, Electric   297
-Incandescent Lamp  321
-Incandescent Lamp Carbons, Flashing of   257
-Incandescent Lamp, Chamber of   113
-Incandescent Lamp, Life of   327
-Incandescent Lamp, Three Filament   322
-Inclination Compass  142
-Inclination, Magnetic   346
-Inclination Map  297
-Inclination or Dip, Angle of   33
-Incomplete Circuit  125
-Increment Key  314
-Independence of Currents in Parallel Circuits  297
-India Rubber  102
-Indicated Horse Power  290
-Indicating Bell   80, 297
-Indicator  298
-Indicator, Circuit  298
-Indicator, Throw-back   540
-Indicator, Volt  568
-Indifferent Electrode  210
-Indifferent Point  421
-Induced Current  163
-Induced Magnetization, Coefficient of  354, 359
-Inductance  298
-Inductance Balance  293
-Inductance Bridge  293
-Induction, Anti-, Conductor   36
-Induction, Back  55
-Induction Balance, Hughes  291
-Induction, Coefficient of Magnetic  349
-Induction, Coefficient of Mutual   301
-Induction, Coefficient of Self-   298
-Induction Coil  133
-Induction Coil, Inverted   136
-Induction Coil, Telephone   137, 526
-Induction, Cross   298
-Induction Current  163
-Induction, Electro-magnetic   218, 299
-Induction, Electrostatic  302
-Induction, Electrostatic, Coefficient of  234
-Induction, Horizontal   302
-Induction, Lateral   302
-Induction, Lines of   330
-Induction, Magnetic   302, 346
-Induction, Magnetic, Apparent Coefficient of  346
-Induction, Magnetic, Coefficient of  346
-Induction, Magnetic Dynamic   347
-Induction, Magnetic, Self-  352
-Induction, Magnetic Static   347
-Induction, Magnetic, Tube of   347
-Induction, Mutual, Electro-magnetic   302
-Induction, Mutual, Electrostatic  303
-Induction, Open Circuit   303
-Induction, Oscillatory  398
-Induction Protector, Mutual   481
-Induction, Self-   303
-Induction Sheath  303
-Induction. Unipolar   304
-Induction, Unit of Self-   304
-Induction, Vertical  304
-Inductive Capacity, Magnetic   346, 349
-Inductive Effect, Counter-   204
-Inductive Resistance  466
-Inductophone  304
-Inductor  305
-Inductor Dynamo  199
-Inductor Generator  199
-Inductor, Magneto-  363
-Inductor, Pacinotti's   400
-Inductorium  138
-Inertia  305
-Inertia, Electro-magnetic   305
-Inertia, Magnetic  347
-Infinity Plug  305, 420
-Influence, Electric   305
-Influence Machine  334
-Influence Machine, Armature of   46
-Influence Machine, Holtz   334
-Influence, Magnetic  346
-Installation  305
-Instantaneous Capacity  102
-Insulating Stool  305
-Insulating Tape  305
-Insulating Varnish  306
-Insulation, Electric   305
-Insulation, Magnetic   347
-Insulation, Oil  396
-Insulation Resistance  466
-Insulator  306
-Insulator Caps  306
-Insulator, Fluid   306
-Insulator, Line or Telegraph   306
-Intensity  306
-Intensity Armature  45
-Intensity Current  163
-Intensity, Electro-motive   228
-Intensity, Magnetic  348
-Intensity of a Magnetic Field  306
-Intensity of Magnetization  360
-Intensity, Poles of  426
-Inter-air Space  489
-Intercrossing  307
-Interference, Armature   45
-Interferric Space  489
-Interior Pole Dynamo  191
-Interlocking- Electro-magnets.   229
-Intermediate Metals, Law of   323
-Intermittent,  307
-Internal Characteristic  114
-Internal Resistance  466
-lnterpolar Conductor  307
-Interpolar Region  307
-Interpolation  307
-Interrupter, Electro-magnetic, for Tuning Fork   307
-Intrinsic Efficiency  205
-Invariable Calibration   97
-Inverse Induced Current  163
-Inverse Squares, Law of   323
-Inversion, Thermo-electric   533
-Ions  307
-Iron  308
-Ironclad Dynamo  200
-Ironclad Electro-magnet,   219
-Ironclad Magnet  356
-Iron Disc Ammeter, Eccentric   27
-Iron, Electrolytic   308
-Iron, Galvanized   265
-Ironwork Fault of a Dynamo  308
-Irreversible Heat  286
-Isochasmen Curve  171
-Isochronism  308
-Isoclinic Lines  308
-Isoclinic Map  308
-Isodynamic Lines  308
-Isodynamic Map  308
-Isoelectric Points  422
-Isogonal Lines  308
-Isogonic Map  309
-Isolated Distribution  309
-Isolated Plant  309
-Isolated Supply  309
-Isotropic  309
-Isthmus Method of Magnetization  360
-I. W. G.,   309
-
-J  309
-Jablochkoff Candle  160
-Jack. Spring-  492
-Jacketed Magnet  356
-Jacobi's Law  309
-Jacobi's Method of Magnetization  360
-Jacobi's Unit of Current  163
-Jacobi's Unit of Resistance   466
-Jamin Candle  100
-Jar, Leyden   325
-Jar, Lightning   330
-Jar, Luminous  332
-Jars, Leyden, Charging and Discharging   108
-Jar, Unit   554
-Jewelry  309
-Joulad  311
-Joule  311
-Joule Effect  311
-Joule's Electro-magnet  337
-Joule's Equivalent,   311
-Joint, American Twist  309
-Joint, Britannia   309
-Joint, Butt   310
-Joint Current  160
-Joint, Lap  310
-Joint, Marriage   310
-Joint, Resistance   464
-Joints in Belts  311
-Joint, Sleeve   310
-Joint, Splayed   311
-Junction Box  311
-Junction, Thermo-electric   533
-
-K.   311
-Kaolin  311
-Kapp. Line of Force   312
-Kathelectrotonus  312
-Kathode  312
-Kathodic Closure Contraction  312
-Kathodic Duration Contraction  312
-K. C. C.  312
-K. D. C.  312
-Kempe's Discharge Key  315
-Keeper  312
-Kerr Effect  235, 312
-Kerr's Experiment  312
-Key  313
-Key Board  313
-Key, Bridge   313
-Key, Double Contact  314
-Key, Double Tapper  314
-Key, Charge and Discharge   313
-Key, Increment  314
-Key, Kempe's Discharge   315
-Key, Magneto-electric   315
-Key, Make and Break   316
-Key, Plug   316
-Key, Reversing  316
-Key, Sliding-contact   316
-Key, Telegraph   316
-Kicking Coil  132
-Kilo  316
-Kilodyne  316
-Kilogram  317
-Kilojoule  317
-Kilometer  317
-Kilowatt  317
-Kine  317
-Kinnersley's Thermometer  536
-Kinetics, Electro-   211
-Kinetic Energy  241
-Kirchoff's Laws  317
-Knife Break Switch  501
-Knife Edge Suspension  317
-Knife Edge Switch  501
-Knife Switch  501
-Knot  317
-Kohlrausch's Law  317
-Kookogey's Solution   318
-Krizik's Cores  318
-
-L  318
-Lag, Angle of   33, 318
-Lag, Electric   332
-Lag, Magnetic   348
-Lalande & Chaperon Battery  69
-Lalande-Edison Battery  69
-Lamellar Distribution of Magnetism  357
-Laminated  318
-Laminated Core  154
-Laminated Core, Tangentially   155
-Lamination  318
-Lamination of Armature Conductors  319
-Lamination of Magnet  361
-Lamp, Arc  319
-Lamp, Arc, Double Carbon   191
-Lamp Carbons, Flashing of Incandescent   257
-Lamp, Carcel   108
-Lamp, Contact  320
-Lamp, Differential Arc   320
-Lamp Globe, Waterproof   572
-Lamp, Holophote  321
-Lamp-hour  321
-Lamp, Incandescent   321
-Lamp, Incandescent, Chamber of   113
-Lamp, Incandescent, Three Filament  322
-Lamp, Life of Incandescent   327
-Lamp, Lighthouse   322
-Lamp, Monophote   321
-Lamp, Pilot  323
-Lamp, Polyphote  323
-Lamp, Semi-Incandescent   323
-Lamp-socket  323
-Lamps, Bank of  323
-Lane's Electrometer  226
-Langdon Davies' Rate Governor or Phonophone  450
-Lenz's Law  325
-Lap Joint  310
-Lap Winding  570
-Latent Electricity  323
-Lateral Discharge  188
-Lateral Induction  302
-Latitude, Magnetic   348
-Law, Jacobi's  309
-Law, Kohlrausch's   317
-Law, Lenz's  325
-Law of Angular Currents  165
-Law of Electrolysis  213
-Law of Intermediate Metals  323
-Law of Inverse Squares  323
-Law of Magnetic Attraction and Repulsion. Coulomb's   338
-Law of Successive Temperatures  324
-Law, Magnus'   367
-Law, Ohm's  396
-Law, Pfl�ger's.   409
-Law, Right Handed Screw  324
-Law, Sine  486
-Laws, Kirchoff's  317
-Laws of Thermo-electricity, Becquerel's   78
-Law, Tangent   502
-Law, Voltametric   567
-Lead  324
-Lead, Angle of   33
-Lead Chloride Battery  66
-Lead of Brushes  90
-Lead of Brushes, Negative  324
-Lead, Peroxide of, Battery   69
-Lead Sulphate Battery  66
-Lead Tee  504
-Leading Horns  324
-Leading-in Wires  324
-Leak  324
-Leakage  324
-Leakage Conductor  325
-Leakage, Electro-magnetic   219
-Leakage, Magnetic.   348
-Leakage, Surface  498
-Leclanch� Agglomerate Battery  66
-Leclanch� Battery  66
-Leg of Circuit  325
-Legal Ohm  395
-Legal Quadrant  444
-Legal Volt  568
-Length of Spark  490
-Letter Boxes, Electric   325
-Leyden Jar  325
-Leyden Jar, Armature of   46
-Leyden Jars, Battery of   68
-Leyden Jars, Charging and Discharging  108
-Leyden Jars, Sir William Thomson's   326
-Lichtenberg's Figures  327
-Life Curve  171
-Life of Incandescent Lamp  327
-Light, Electro-magnetic, Theory of   219
-Light, Maxwell's Theory of  369
-Lighthouse Lamp  322
-Lightning  327
-Lightning Arrester  328
-Lightning Arrester, Counter-electro-motive Force  329
-Lightning Arrester Plates  329
-Lightning Arrester, Vacuum   329
-Lightning, Ascending  330
-Lightning, Globe or Globular   330
-Lightning Jar  330
-Lightning, Back Stroke or Shock of  55
-Lime, Chloride of, Battery   61
-Limit, Magnetic  348
-Limit of Magnetization  361
-Linear Current  164
-Lineman's Detector  180
-Line of Commutator, Neutral   300
-Line of Contact  330
-Line of Force, Kapp  312
-Line of Magnet, Neutral  361
-Line or Telegraph Insulator  306
-Lines, Halleyan   308
-Lines, Isoclinic  308
-Lines, Isodynamic  308
-Lines, Isogonal   308
-Lines, Isogonic   308
-Lines of Force  330
-Lines of Force, Cutting of  175
-Lines of Force, Electro-magnetic  219
-Lines of Force, Electrostatic   234
-Lines of Force, Magnetic   348
-Lines of Induction  330
-Lines of Slope  330
-Lines or Points of Least Sparking  490
-Lines, Trunk   550
-Links, Fuse  330
-Liquids, Electro-dynamic Rotation of   474
-Liquids, Electro-magnetic Rotation of    475
-Liquor, Spent   491
-Listening Cam  330
-Lithanode  331
-Load  331
-Load Curve  172
-Load of Armature  46
-Local Action  331
-Local Battery  331
-Local Circuit  331
-Local Currents  163, 331
-Localization  331
-Locus  331
-Lodestone  332
-Logarithm  332
-Logarithms, Hyperbolic   389
-Logarithms, Napierian  389
-Local Battery  66
-Long Coil Magnet   361
-Long Range Electro-magnet  220
-Long Shunt and Series Winding  579
-Long Shunt Winding  579
-Loop  332
-Loop Break  332
-Loop, Circuit   125
-Loop, Drip   192
-Lost Amperes  30
-Lost Volts  571
-Low Vacuum  557
-Luces  332
-Luminous Jar  332
-Luminous Pane  401
-Luminous Tube  550
-Lux  332
-
-M  332
-Machine, Cylinder Electric  333
-Machine, Electric, Wimshurst   577
-Machine, Frictional Electric   333
-Machine, Holtz Influence   334
-Machine, Hydro-electric   293
-Machine, Influence  334
-Machine, Nairne's Electrical   389
-Machine, Plate Electrical   417
-Machine, Rheostatic  472
-Machine, Toeppler-Holtz   334
-Machine, Wimshurst  335
-Mack  335
-Magic Circle  119
-Magne-crystallic Action  335
-Magnet  335
-Magnet, Anomalous   335
-Magnet, Artificial  335
-Magnet, Axial   336
-Magnet, Bar  336
-Magnet, Bell Shaped   336
-Magnet Coils, Sheath for   481
-Magnet, Compensating   336
-Magnet, Compound   336
-Magnet, Controlling   185, 336
-Magnet, Damping   336
-Magnet, Deflection of   337
-Magnet, Directing   185
-Magnet, Electro-   215, 337
-Magnet, Equator of   337
-Magnet, Field   337
-Magnet, Haarlem   337
-Magnet, Heating   286
-Magnet, Horseshoe   337
-Magnet, Ironclad   356
-Magnet, Joule's Electro-   337
-Magnet-keeper  361
-Magnet, Lamination of   361
-Magnet, Long Coil  361
-Magnet, Natural  361
-Magnet, Neutral Line of   361
-Magnet, Normal   361
-Magnet Operation  365
-Magnet, Permanent  365
-Magnet Pole  365
-Magnet, Portative Power of   366
-Magnet, Projecting Power of a   435
-Magnet, Relay   457
-Magnet, Simple   366
-Magnet, Solenoidal   366
-Magnet, Sucking   366
-Magnet, Unipolar  366
-Magnet Coil  336
-Magnet Core  336
-Magnet Poles, Secondary   366
-Magnet Pole, Unit  366
-Magnetic Adherence  338
-Magnetic and Electro-magnetic Equipotential Surface  244
-Magnetic Attraction  338
-Magnetic Attraction and Repulsion, Coulomb's Law of   338
-Magnetic Axis  338
-Magnetic Azimuth  338
-Magnetic Battery  338
-Magnetic Bridge  338
-Magnetic Circuit  340
-Magnetic Circuit, Curve of Saturation of   174
-Magnetic Concentration of Ores  340
-Magnetic Concentrator  340
-Magnetic Continuity  340
-Magnetic Conductance and Conductivity  340
-Magnetic Control  341
-Magnetic Couple  341
-Magnetic Creeping  341
-Magnetic Curves  341
-Magnetic Cut Out  175
-Magnetic Declination  342
-Magnetic Density  342
-Magnetic Dip  342, 346
-Magnetic Discontinuity  342
-Magnetic Double Circuit  340
-Magnetic Eye, Electro-   248
-Magnetic Elements  342
-Magnetic Elongation  344
-Magnetic Equator  344
-Magnetic False Poles  350
-Magnetic, Ferro-  252
-Magnetic Field, Intensity of a   306
-Magnetic Field of Force  344
-Magnetic Field, Uniform   345
-Magnetic Figures  345
-Magnetic Filament  345
-Magnetic Fluid, North   357
-Magnetic Fluids  345
-Magnetic Flux  345
-Magnetic Force  346
-Magnetic Friction  295, 346
-Magnetic Friction Gear   276
-Magnetic Fluid, South   356
-Magnetic Foci  259
-Magnetic Gear  346
-Magnetic Hysteresis  294
-Magnetic Inclination  346
-Magnetic Induction  302
-Magnetic Induction, Apparent Coefficient of   346
-Magnetic Induction, Coefficient of   346-349
-Magnetic Induction, Dynamic   347
-Magnetic Induction, Static   347
-Magnetic Induction, Tube of   347
-Magnetic Inductive Capacity  349
-Magnetic Inertia  347
-Magnetic Influence  346
-Magnetic Insulation  347
-Magnetic Intensity   348
-Magnetic Lag  348
-Magnetic Latitude  348
-Magnetic Leakage  348
-'Magnetic Limit  348
-Magnetic Lines of Force  348
-Magnetic Mass  349
-Magnetic Matter  349
-Magnetic Memory  349
-Magnetic Meridian  349
-Magnetic Moment  349
-Magnetic Needle  349
-Magnetic Needle, Declination of the  178
-Magnetic Needle, Dip of   185
-Magnetic Needle, Oscillation of a   397
-Magnetic Output  399
-Magnetic Parallels  349
-Magnetic Permeability  349
-Magnetic Perturbations  350
-Magnetic Poles  350
-Magnetic Potential  350, 431
-Magnetic Proof Piece  350
-Magnetic Proof Plane  350
-Magnetic Quantity  350
-Magnetic Reluctance  351, 458
-Magnetic Reluctivity  351
-Magnetic Remanence  358
-Magnetic Repulsion  338
-Magnetic Resistance  458
-Magnetic Retentivity  351
-Magnetic Rotatory Polarization  351
-Magnetic Saturation  251
-Magnetic Screen  351
-Magnetic Self-induction  352
-Magnetic Separator  352
-Magnetic Shell  352
-Magnetic Shell, Strength of   352
-Magnetic Shield  353
-Magnetic Shunt  353
-Magnetic Storms  353
-Magnetic Strain  354
-Magnetic Stress  354
-Magnetic Susceptibility  254, 359
-Magnetic Tick  354
-Magnetic Top  542
-Magnetic Twist  354
-Magnetic Vane Ammeter  27
-Magnetic Variations  354
-Magnetism, Ampere's Theory of   354
-Magnetism, Blue  355
-Magnetism, Components of Earth's   356
-Magnetism, Creeping of   356
-Magnetism, Decay of   356
-Magnetism, Discharge of   356
-Magnetism, Electro  220
-Magnetism, Ewing's Theory of  356
-Magnetism, Free   356
-Magnetism, Hughes' Theory of  357
-Magnetism, Lamellar Distribution of  357
-Magnetism of Gases  357
-Magnetism, Red  357
-Magnetism, Residual  358
-Magnetism, Solenoidal Distribution of   358
-Magnetism, Sub-permanent   358
-Magnetism, Terrestrial  358
-Magnetism, Weber's Theory of   358
-Magnetization by the Earth  359
-Magnetization by Double Touch  358
-Magnetization by Separate Touch  359
-Magnetization by Single Touch  359
-Magnetization, Coefficient of Induced  359
-Magnetization Curve  172
-Magnetization, Cycle of  360
-Magnetization, Elias' Method of   360
-Magnetization, Hoffer's Method of   360
-Magnetization, Intensity of   360
-Magnetization, Isthmus Method of  360
-Magnetization, Jacobi's Method  360
-Magnetization, Limit of  361
-Magnetization, Maximum   361
-Magnetization, Specific   361
-Magnetization, Surface   356
-Magnetizing Coil   127
-Magneto  361
-Magneto Bell  80
-Magneto Call Bell  361
-Magneto-electric  361
-Magneto-electric Brake  362
-Magneto-electric Generator  362
-Magneto-electric Generator, or Dynamo, Flashing in a   257
-Magneto-electric Key  315
-Magneto-electric Telegraph  512
-Magnetograph  363
-Magneto-inductor  363
-Magnetometer  363
-Magnetometer, Differential   365
-Magnetometry  364
-Magneto-motive Force  365
-Magnetophone  367
-Magnetoscope  365
-Magnifying Spring Ammeter  28
-Magnus' Law  367
-Main Battery  66
-Main Battery Circuit  125
-Main Circuit  125
-Main or Standard Feeder  251
-Mains, Electric   367
-Make   367
-Make and Break Current  164, 367
-Make and Break Key  316
-Make-induced Current  163
-Malapterurus  367
-Map, Declination   309
-Map, Inclination   297
-Map, Isoclinic   308
-Map, Isodynamic   308
-Map, Isogonic  309
-Mari� Davy's Battery  67
-Marine Galvanometer  269
-Mariner's Compass  142
-Marked End or Pole  368
-Marriage Joint  310
-Mass, Electric   368
-Mass, Magnetic   349
-Master Clock  127
-Mathematical Element  237
-Matteueci's Experiment  369
-Matter, Electric  368
-Matter, Fourth State of   261
-Matter, Magnetic   349
-Matter, Radiant  368
-Matter, Ultra Gaseous  551
-Matthiessen's Meter-gram Standard Resistance,.   466
-Matthiessen's Unit of Resistance   466
-Matting, Electric Floor   369
-Maximum Magnetization  361
-Maxwell's Theory of Light  369
-Mayer's Floating Magnet  370
-Maynooth's Battery  67
-Measurement, Absolute   8
-Measurements  370
-Mechanical Equivalent of Heat  286
-Mechanical Energy  241
-Mechanical Equivalent, Electro-   244
-Medical Battery  67
-Medium, Polarization of the   424
-Meg or Mega  370
-Meidinger's Battery  68
-Memoria Technica, Amp�re's   30
-Memory, Magnetic   349
-Mercury  371
-Mercury Bichromate, Battery  63
-Mercury Circuit Breaker  121
-Mercury Cups  371
-Mercury, Sulphate of, Battery   67
-Mercurial Air Pump  16
-Meridian, Astronomical   372
-Meridian, Geographic   372
-Meridian, Magnetic.   349
-Merit, Figure of   256
-Merit, Formula of   256
-Metal, Gilding   277
-Metallic Arc  39
-Metallic Circuit  125
-Metallochromes  392
-Metallurgy, Electro-  222
-Metals, Law of Intermediate  323
-Meter. Alternating Current   373
-Meter, Ampere and Volt, Galvanometer .   274
-Meter, Balance Ampere   391
-Meter Bridge  373
-Meter Bridge, Slide   486
-Meter Candle  374
-Meter, Chemical Electric   375
-Meter, Current  375
-Meter, Electro-magnetic   375
-Meter, Energy  375
-Meter Gram Standard Resistance, Matthiesen's   466
-Meter-millimeter  375
-Meter-millimeter Unit of Resistance   466
-Meter, Neutral Wire Ampere.   391
-Meter, Quantity  445
-Meters. Ampere  39
-Meter, Thermal-Electric   375
-Meter, Time Electric   375
-Meter, Watt  375
-Method, Broadside   89
-Method, Deflection   178
-Method, End on   238
-Method, Idiostatic   295
-Method, Multiple Wire  388
-Method, Null  393
-Method of Magnetization, Elias'  360
-Method of Magnetization, Isthmus   360
-Method of Magnetization, Jacobi's   360
-Methven Standard or Screen  376
-Mho,   376
-Mica  376
-Mica, Moulded   376
-Micro  376
-Micrometer  376
-Micrometer, Arc   39, 376
-Micrometer, Spark   470
-Micron  376
-Microphone  376
-Microphone Relay  377, 457
-Microscope. Photo-electric   410
-Microtasimeter  377
-Mil  379
-Mil, Circular   379
-Mil-foot  379
-Mil-foot Unit of Resistance  467
-Milli  379
-Milligram  379
-Millimeter  379
-Milli-oerstedt  380
-Mil, Square  379
-Minute, Ampere-  30
-Mirror Galvanometer.   271
-Mixed Gases  275
-mm.  380
-Molar  380
-Molar Energy  241
-Molecular Affinity  380
-Molecular Attraction  380
-Molecular Bombardment  380
-Molecular Chain  380
-Molecular Energy  241
-Molecular Heat  286
-Molecular Rigidity  380, 473
-Molecular Shadow  480
-Molecule  380
-Moment  381
-Moment, Magnetic   349
-Moment of Couple  544
-Moment, Turning   544
-Monophote Lamp  321
-Mordey Effect  381
-Morse Receiver  381
-Morse Recorder  451
-Morse Telegraph  512
-Mortar, Electric   382
-Motion, Currents of   167
-Motograph, Electro-   229
-Motor. Compound or Compound Wound,.   382
-Motor, Differential   382
-Motor, Dynamo   200
-Motor, Electric   382
-Motor, Electro-   229
-Motor, Electro-motive Force   384
-Motor-generator  384
-Motor, Multiphase  384
-Motor, Overtype   399
-Motor, Prime  385
-Motor, Pulsating  386
-Motor, Pyromagnetic   442
-Motor, Reciprocating   385
-Motor, Series   386
-Motor, Shunt   386
-Moulded Mica  376
-Moulding  58
-Movable Secondary  477
-Mud, Battery  68
-Multiphase Currents  166
-Multiphase Motor  384
-Multiple  386
-Multiple Arc  387
-Multiple Arc Box  387
-Multiple Connected Battery  68
-Multiple-series  387, 480
-Multiple Switch  501
-Multiple Switch Board  387
-Multiple Transformer  548
-Multiple Winding  579
-Multiple Wire Method  388
-Multiplex Harmonic Telegraph  510
-Multiplex Telegraph  514
-Multiplex Telegraphy  388
-Multiplier, Schweigger's  476
-Multiplying Power  347, 349
-Multiplying Power of a Shunt  388
-Multipolar Armature  46
-Multipolar Dynamo  200
-Multipolar Electric Bath  57
-Multipolar Winding  579
-Muscular Pile  388
-Mutual Electro-magnetic Induction  302
-Mutual Electrostatic Induction  303
-Mutual Induction, Coefficient of   301
-Mutual Induction Protector  481
-Myria  388
-
-Nairne's Electrical Machine  389
-Napierian Logarithms  389
-Nascent State  389
-Natural Currents  166, 389
-Natural Magnet  361
-Needle  389
-Needle Annunciator  35
-Needle, Astatic   50
-Needle, Dipping  185
-Needle, Magnetic  349
-Needle, Orientation of a Magnetic   397
-Needle of Oscillation  389
-Needle Telegraph, Single   519
-Needle, Telegraphic  389
-Negative Charge  389
-Negative Current  164
-Negative Electricity  389
-Negative, Electro-   229
-Negative Element  390
-Negative Feeder  251
-Negative Lead of Brushes  324
-Negative Plate  417
-Negative Pole  425
-Negative Potential  432
-Negative Side of Circuit  125
-Nerve and Muscle Current  164
-Nerve Currents  390
-Net Efficiency  205
-Net, Faraday's   250
-Network  390
-Neutral Armature  46
-Neutral Feeder  251
-Neutral Line of Commutator  390
-Neutral Line of Magnet  361
-Neutral Point  421
-Neutral Point of Commutator  390
-Neutral Point, Thermo-electric   390
-Neutral Relay Armature  46, 390
-Neutral Temperature  390
-Neutral Wire  390
-Neutral Wire Ampere Meter  391
-N. H. P.  391
-Niaudet's Battery   61
-Nickel  391
-Nickel Bath  391
-Night Bell  392
-Nitric Acid Battery  68
-Nobili's Rings  392
-Nodal Point  422
-Nodular Deposit  392
-Nominal Candle Power  101
-Non-conductor  392
-Non-essential Resistance  465-467
-Non-inductive Resistance  467
-Non-polar Dynamo   200
-Non-polarizable Electrodes  210
-Non-Polarized Armature  46
-Normal Magnet  361
-North Magnetic Fluid  357
-North Pole  392
-North Seeking Pole  393
-Null Method  393
-Null Point  422
-
-Occlusion  393
-Oerstedt  394
-Oerstedt's Discovery  394
-Oerstedt, Milli-  380
-Ohm  394
-Ohmage  394
-Ohm, B. A.  394
-Ohm, Board of Trade   394
-Ohm, Congress   395
-Ohmic Resistance  394, 467
-Ohm, Legal  395
-Ohmmeter  395
-Ohm, Rayleigh   396
-Ohm's Law  396
-Ohm, True  396
-Oil Insulation  396
-Oil Transformer  548
-Old Armature, Siemens'   49
-Olefiant Gas  397
-Omnibus Bar  94
-Omnibus Rod  94
-Omnibus Wire  94
-One Coil Electro-magnet  219
-Open  397
-Open Circuit  125
-Open Circuit Battery  68
-Open Circuit Induction  303
-Open Circuit Oscillation  397
-Open Coil Armature  46
-Open Coil Dynamo  200
-Opening Shock  482
-Operation, Magnet  365
-Opposed Current  164
-Optics, Electro-   229
-Orders of Currents  167
-Ordinate  397
-Ordinates, Axis of  54, 397
-Ores, Electric Reduction of  453
-Ores, Magnetic Concentration of   340
-Organ, Electric  397
-Orientation of a Magnetic Needle  397
-Origin of Co-ordinates  397
-Oscillation, Centre of  112
-Oscillation, Electric  398
-Oscillation, Needle of   389
-Oscillation, Open Circuit   397
-Oscillatory  23
-Oscillatory Discharge  188
-Oscillatory Displacement  398
-Oscillatory Electro-motive Force  398
-Oscillatory Impedance  297
-Oscillatory Induction  398
-Osmose, Electric  398
-Outlet  399
-Output  399
-Output, Magnetic   399
-Output, Unit of   399
-Over-compounding  399
-Over, Flashing   258
-Overflow Alarm  18
-Over-house Telegraph  515
-Overload  399
-Overtype Dynamo or Motor  399
-Oxide of Copper Battery  68
-Ozone  399
-
-Pacinotti's Inductor   400
-Pacinotti's Ring  400
-Pacinotti Teeth  400
-Page Effect  401
-Page's Revolving Armature  47
-Paillard Alloys  400
-Palladium  401
-Pane, Fulminating   262
-Pane, Luminous   401
-Pantelegraphy  402, 510
-Paper Filaments  402
-Parabola  402
-Parabolic Reflector  402
-Paraffine  402
-Paraffine Wax  402
-Paragr�les  403
-Parallax  403
-Parallel  403
-Parallel Circuits  123-126
-Parallelogram of Forces  260
-Parallels, Magnetic  349
-Paramagnetic  403
-Paramagnetism   404
-Parasitical Currents  163
-Parchmentizing  404
-Partial Current  164
-Partial Earth  203, 404
-Partial Vacuum  557
-Passive State  404
-Path, Alternative   24
-P. D.  404
-Peltier's Cross  405
-Peltier Effect  404
-Pen, Electric   405
-Pendant Cord  405
-Pendulum Circuit Breaker  121
-Pendulum, Electric  405
-Pendulum or Swinging Annunciator  35
-Pentane Standard, Harcourt's   406
-Pentode Working  581
-Percussion, Centre of   112
-Perforated Armature  45
-Perforated Core Discs  154
-Perforator  407
-Period   407
-Period, Vibration   560
-Periodic  23
-Periodic Current, Power of   433
-Periodicity  262, 408
-Peripolar Zone  582
-Permanency  408
-Permanent Magnet  365
-Permanent Magnet Ammeter  28
-Permanent State  408
-Permeability  346-349
-Permeability-temperature Curve,   174
-Permeameter  408
-Permeance  408
-Peroxide of Lead Battery  69
-Perturbations, Magnetic   350
-Pfl�ger's Law  409
-Phantom Wires  409
-Phase  409
-Phase, Retardation of   471
-Phenomenon, Porret's   427
-Pherope  409, 527
-Philosopher's Egg  409
-Phonautograph,   409
-Phone   409
-Phonic Wheel  409
-Phonograph  410
-Phonophone or Rate Governor, Langdon Davies'   450
-Phonozenograph  410
-Phosphorescence  410
-Phosphorous, Electrical Reduction of   410
-Photo-electric Microscope  410
-Photo-electricity  410
-Photo-electro-motive Force  410
-Photometer  411
-Photometer, Actinic   411
-Photometer, Bar  411
-Photometer, Bunsen's  412
-Photometer, Calorimetric   412
-Photometer, Dispersion  412
-Photometer, Shadow  414
-Photometer, Translucent Disc   412
-Photophore  415
-Photo-voltaic Effect  415
-Physical Energy  241
-Physiology, Electro-   231
-Piano, Electric   415
-Pickle  415
-Picture, Electric   415
-Piece, Bed  78
-Piece, Magnetic Proof  350
-Piece, Pole   423
-Pierced Core-discs,   152
-Pile  415
-Pile, Differential Thermo-electric   533
-Pile, Muscular  388
-Pile or Battery, Thermo-electric   530
-Pilot Brush  91
-Pilot Lamp  323
-Pilot Transformer  415
-Pilot Wires  415
-Pistol, Electric  416
-Pith  416
-Pith Ball Electroscope  234
-Pith-balls  416
-Pivoted Armature  47
-Pivot Suspension  416
-Plane, Magnetic Proof   350
-Plant  417
-Plant Electricity  417
-Plant, Isolated   309
-Plant�'s Secondary Battery,   72
-Plate, Arrester   417
-Plate Condenser  417
-Plate, Earth  203
-Plate Electrical Machine  417
-Plate, Franklin's  262
-Plate, Generating   277
-Plate, Ground   417
-Plate, Negative   417
-Plate, Positive   277, 417
-Plating Balance  417
-Plating Bath  418
-Plating, Electro-   418
-Platinized Carbon Battery  69
-Platinoid  418
-Platinum  419
-Platinum Alloy  419
-Platinum Black  419
-Platinum Silver Alloy  419
-Platinum Sponge  419
-Play, End  238
-Plow  420
-Pl�cker Tubes  420
-Plug  420
-Plug Cut Out  175
-Plug, Double  191
-Plug, Grid   420
-Plug, Infinity   305, 420
-Plug Key  316
-Plug Switch  420
-Plumbago  421
-Plunge Battery  69
-Plunge  421
-Plunger and Coil  131
-Plunger and Coil, Differential   132
-Plunger, Coil and  131
-Plunger Electro-magnet   220
-Pneumatic Battery  69
-Pneumatic Signals, Electro-   231
-P.O.  421
-Pockets, Armature  47
-Poggendorf's Solution  421
-Point, Contact  147
-Point, Indifferent   421
-Point, Neutral  421
-Point. Nodal  422
-Point, Null   422
-Point of Commutator, Neutral   390
-Point Poles  422
-Points, Consequent   422
-Points, Corresponding   422
-Points, Iso-electric   422
-Points of Derivation  180, 423
-Point, Thermo-electric Neutral   390
-Polar Angle   423
-Polar Extension  423
-Polarity, Diamagnetic   181, 423
-Polarity, Resultant   470
-Polarization  423
-Polarization, Back Electro-motive force of   156
-Polarization Capacity  424
-Polarization, Dielectric   183
-Polarization, Galvanic  265
-Polarization, Magnetic Rotary   351
-Polarization of the Medium  424
-Polarized Armature  47
-Polarized Electro-magnet  220
-Polarized Relay  458
-Polarized Relay, Tongue of   542
-Polarizing Current  164
-Polar Region  424
-Polar Span  424
-Polar Span, Angle of   32, 423
-Polar Tips  423
-Polar Zone  582
-Pole, Analogous   31, 425
-Pole, Antilogous   425
-Pole, Armature   47
-Pole, Austral  54
-Pole, Boreal   85
-Pole Brackets, Telegraph   515
-Pole Changer  425
-Pole Changing Switch,   501
-Pole Dynamo, Interior   199
-Pole, Magnet   366
-Pole, Negative   425
-Pole, North  392
-Pole, North-seeking  393
-Pole or End, Marked   368
-Pole Piece  423
-Pole Pieces  425
-Pole, Positive   425
-Pole, Salient  426
-Pole, Terminal   529
-Pole Tips  290, 426
-Pole, Traveling  426
-Pole, Unit Magnet   366
-Poles  425
-Poles, Compensating   426
-Poles, Consequent   146
-Poles, Idle  296
-Poles, Magnetic  350
-Poles, Magnetic, False   350
-Poles of Intensity  426
-Poles of Verticity  426, 560
-Poles, Point  422
-Poles, Secondary  478
-Poles, Secondary Magnet   366
-Polyphase Currents  167
-Polyphote Lamp  323
-Popgun, Electric  282
-Porous Cell  427
-Porous Cup  159, 426
-Porret's Phenomenon  427
-Portative Power of Magnet  366
-Portelectric Railroad  427
-Portrait, Electric  415
-Position, Energy of   241
-Position Finder  427
-Position, Sighted   484
-Positive Current  164
-Positive Direction  428
-Positive Electricity  428
-Positive Element  277
-Positive Feeder  251
-Positive Plate  277, 417
-Positive Pole  425
-Positive Potential  432
-Positive Side of Circuit  125
-Post Office  428
-Posts, Binding, or Screws  81
-Potential  428
-Potential, Absolute   428
-Potential, Constant  429
-Potential Difference, Contact   147
-Potential Difference, Electric   429
-Potential Difference, Electro-motive   429
-Potential, Electric Absolute  429
-Potential, Fall of  430
-Potential Galvanometer  269
-Potential in Armature, Curve of Distribution of   172
-Potential, Magnetic   350, 431
-Potential, Negative  432
-Potential or Static Energy  241
-Potential, Positive  432
-Potential Regulation, Constant   455
-Potential, Unit of Electric   432
-Potential, Zero   432, 582
-Potentiometer   432
-Poundal  433
-Pound-foot  259
-Power  438
-Power, Candle   100
-Power, Directive   187
-Power, Electric   433
-Power, Horse  290
-Power, Illuminating  296
-Power, Multiplying  349
-Power of Magnet, Portative   366
-Power of Periodic Current  433
-Powers of Ten  527
-Power, Stray  495
-Power, Thermo-electric   533
-Press Button  94
-Pressel  434
-Pressure  434
-Pressure, Electric  434
-Pressure, Electrification by   434
-Primary  434
-Primary Ampere-turns  31, 551
-Primary Battery  69, 434
-Prime  434
-Prime Conductor  146, 434
-Prime Conductor, Coatings of a  129
-Prime Motor   385
-Principle, Gauss'   276
-Printing Telegraph  515
-Probe, Electric  435
-Projecting Power of a Magnet  435
-Prony Brake  435
-Proof Piece, Magnetic  350
-Proof-plane  436
-Proof Plane, Magnetic   350
-Proof-sphere  436
-Proportional Galvanometer  269
-Proportionate Arms  436
-Prostration, Electric  437
-Protector, Body   84
-Protector, Comb   437
-Protector, Electric    437
-Pull  437
-Pulsatory Current  164
-Pulsatory Field  256
-Pulsating Motor  386
-Pulvermacher's Electro-medical Battery  69
-Pump, Geissler   437
-Pump, Sprengel   439
-Pump, Swinburne   440
-Pumping  439
-Puncture-electro  232
-Puncture-galvano  232
-Push Button  93. 98, 440
-Push, Desk   180
-Push, Floor  258
-Pyro-electricity  441
-Pyromagnetic Generator  442
-Pyromagnetic Motor  441
-Pyromagnetism  443
-Pyrometer, Siemens' Electric   443
-
-Q  443
-Quad  288, 443
-Quadrant  288, 443
-Quadrantal Deviation  180
-Quadrant, Legal  444
-Quadrant, Standard   444
-Quadrature   444
-Quadruplex Telegraph  515
-Qualitative  444
-Quality of Sound  444
-Quantitative  444
-Quantity  444
-Quantity Armature  47
-Quantity, Electric  444
-Quantity, Electro-magnetic  445
-Quantity, Electro-magnetic, Practical Unit of   445
-Quantity, Electrostatic  445
-Quantity Galvanometer  269
-Quantity, Magnetic  350
-Quantity Meter  445
-Quartz  445
-Quicking  446
-
-R  446
-Racing of Motors  446
-Radial Armature  47
-Radian  446
-Radiant Energy  446
-Radiant Matter  368
-Radiation  446
-Radicals  446
-Radiometer  447
-Radiometer, Electric   447
-Radio-micrometer  447
-Radiophony  447
-Railroad, Portelectric   427
-Range Finder  447
-Rate Governor  449
-Rate Governor or Phonophone, Langdon Davies'   450
-Rated Candle Power  101
-Ratio Arms  437
-Ratio, Core   154
-Ratio, Shunt  483
-Ratio, Velocity  560
-Ray, Electric  450
-Rayleigh Ohm  396
-Reaction Coil  132
-Reaction of a Dynamo Field and Armature  450
-Reaction of Degeneration  179
-Reactions, Anodic  36
-Reactions, Armature   47
-Reaction Telephone  527
-Reaction Wheel  259
-Reading Galvanometer, Direct   269
-Reading, Sound   489
-Reading Telescope  450
-Real Efficiency of Secondary Battery  205
-Real Hall Effect  284
-R�aumur Scale  450
-Recalescence  451
-Receiver  451
-Receiver, Harmonic   284, 451
-Receiver, Morse   381
-Receptive, Electro-   232
-Recharge  115
-Reciprocal  451
-Reciprocating Motor  385
-Recoil Circuit  125
-Recorder, Chemical  117
-Recorder, Morse  451
-Recorder, Siphon   452
-Record, Telephone   451
-Rectification of Alcohol, Electric  18
-Rectified Current  164
-Rectilinear Current  165
-Red Varnish  559
-Red Magnetism  357
-Redressed Current  165
-Reduced Resistance  467
-Reducteur for Ammeter  453
-Reducteur for Voltmeter  453
-Reduction of Ores, Electric   453
-Reduction of Phosphorous, Electrical  410
-Reflecting Galvanometer  270
-Reflector, Parabolic  402
-Refraction, Electric Double   454
-Refraction, Electrostatic   235
-Refreshing Action  454
-Region, Extra-polar   454
-Region, Intrapolar   307
-Region, Polar  424
-Register, Electric  454
-Register, Telegraphic   454
-Regulation, Constant Current   454
-Regulation, Constant Potential   455
-Regulation of Alternating Current Dynamo  195
-Regulation of Dynamos  455
-Reguline  456
-Relative  456
-Relative Calibration  98
-Relay  456
-Relay Bell  80
-Relay Bells  457
-Relay, Box Sounding  457
-Relay Connection  457
-Relay, Differential  457
-Relay Magnet  457
-Relay, Microphone  377, 457
-Relay, Neutral, Armature   390
-Relay, Polarized   457
-Reluctance  458
-Reluctance, Magnetic   351, 458
-Reluctance, Unit of   438
-Reluctivity  459
-Reluctivity, Magnetic   351
-Remanence  459
-Remanence, Magnetic  358
-Removal of Hair by Electrolysis  283
-Renovate  115
-Repeater  459
-Repeater, Telegraph   518
-Replenisher, Sir Wm. Thomson's  459
-Repulsion, Magnetic  338
-Repulsion and Attraction, Electrostatic   234
-Repulsion and Attraction, Electro-magnetic  217
-Reservoir, Common   460
-Residual Atmosphere  460
-Residual Capacity  103
-Residual Charge  116
-Residual Magnetism  358
-Residue, Electric  116, 460
-Resin  460
-Resinous Electricity  461
-Resistance  461
-Resistance, Apparent  297, 462
-Resistance, Assymmetrical   462
-Resistance Box  462
-Resistance, B. A. Unit of   462
-Resistance Box, Sliding  463
-Resistance, Breguet Unit of   463
-Resistance Bridge  577
-Resistance Coil  137
-Resistance Coil, Standard   464
-Resistance, Carbon   463
-Resistance, Combined  464
-Resistance, Compensating   144
-Resistance, Critical  464
-Resistance, Dielectric  183, 464
-Resistance, Digney Unit of   464
-Resistance, Electrolytic  464
-Resistance, English Absolute or Foot-second Unit of  465
-Resistance, Equivalent   465
-Resistance, Essential   465
-Resistance, External   465
-Resistance Frame  465
-Resistance, German Mile Unit of   466
-Resistance, Hittorf's   466
-Resistance, Inductive  466
-Resistance, Insulation   466
-Resistance, Internal   466
-Resistance, Jacobi's Unit of   466
-Resistance, Joint  464
-Resistance, Magnetic   351, 458
-Resistance, Matthiessen's Meter-gram Standard of    466
-Resistance, Matthiessen's Unit of   466
-Resistance, Meter-millimeter Unit of   466
-Resistance, Mil-foot Unit of   467
-Resistance, Non-essential  465, 467
-Resistance, Non-inductive   467
-Resistance of Human Body  467
-Resistance, Ohmic  394, 467
-Resistance, Reduced  467
-Resistance, Siemens' Unit of  467
-Resistance, Specific  467
-Resistance. Specific Conduction  467
-Resistance, Spurious   467
-Resistance, Steadying  468
-Resistance, Swiss Unit of   468
-Resistance, Thomson's Unit of   468
-Resistance to Sparking  490
-Resistance, True  467
-Resistance, Unit  468
-Resistance, Unit of, B. A.   78
-Resistance, Varley's  559
-Resistance, Varley's Unit of  468
-Resistance, Virtual   297
-Resistance, Weber's Absolute Unit   468
-Resolution of Forces  261
-Resonator, Electric   468-470
-Rest, Currents of   167
-Resultant  470
-Resultant Polarity  470
-Retardation  470
-Retardation of Phase  471
-Retentivity  471
-Retentivity, Magnetic   351
-Retort Carbon  471
-Return  471
-Return Circuit  125
-Return, Earth  203
-Return Stroke  55
-Reversal, Thermo-Electric   533
-Reverse Current Working  581
-Reverse-induced Current  163
-Reverser, Current   165
-Reversibility  471
-Reversible Bridge  472
-Reversing Key  316
-Reversing Switch  501
-Revivify  115
-Revolving Armature, Page's   47
-Rheochord  472
-Rheometer  472
-Rheomotor  472
-Rheophore  472
-Rheoscope  472
-Rheoscopic Frog  262
-Rheostat  472
-Rheostat Arm  472
-Rheostatic Machine  472
-Rheostat, Wheatstone's   472
-Rheotome  473
-Rheotrope  473
-Rhigolene  473
-Rhumbs  473
-Rhumkorff Coil  138, 473
-Ribbon Coil  138
-Ribbon Core  154
-Right-handed Screw Law  324
-Rigidity, Molecular  380, 473
-Ring, Ampere   30
-Ring Armature  48
-Ring. Collecting   139
-Ring Contact  473
-Ring Core  155
-Ring, Dynamo  200
-Ring, Faraday's   473
-Ring, Foundation   261
-Ring, Guard  282
-Ring, Pacinotti's   400
-Rings, Electric   392
-Rings, Nobili's  392
-Ring, Split, Commutator   141
-Roaring  474
-Rocker  474
-Rocker Arms  50, 474
-Rod, Bus  94
-Rod, Discharging   189
-Rod, Omnibus   94
-Roget's Spiral  474
-Rolling Armature  49
-Rosin  460
-Rotary Polarization, Magnetic   351
-Rotating Brush   91
-Rotating Field  256
-Rotation of Liquids, Electro-dynamic   474
-Rotation of Liquids, Electro-magnetic   475
-Rotatory Currents  167
-Rubber  102, 475
-Rubber, India   102
-
-Saddle Bracket  475
-Safety Catch  175
-Safety Cut Out  175
-Safety Device  475
-Safety Fuse  175, 475
-Safety Fuse, Plug, or Strip   475
-Sal Ammoniac Battery  69
-Salient Pole  426
-Salt  475
-Salt, Dronier's  192
-Salt or Sea-salt Battery  69
-Sand Battery  90
-Saturated  476
-Saturation, Magnetic   351
-Saw, Electric   476
-Scale, Fahrenheit   248
-Scale, R�aumur   450
-Scale, Tangent  502
-Schweigger's Multiplier  476
-Scratch Brushes  476
-Screen, Electric   476
-Screen, Magnetic   351
-Screen, Methven  376
-Screws or Posts, Binding   81
-Sealed, Hermetically  289
-Sea Salt or Salt Battery  69
-Secohm  288
-Second, Ampere-   30
-Secondary Actions  477
-Secondary Ampere-turns  31, 551
-Secondary Battery  70
-Secondary Battery, Efficiency of, Quantity  205
-Secondary Battery, Plant�'s   72
-Secondary Clock  127
-Secondary Current  166
-Secondary Generator  277, 477
-Secondary Magnet Poles  366
-Secondary, Movable  477
-Secondary Plates, Colors of   478
-Secondary Poles  478
-Secretion Current  166
-Section Trolley  549
-Sectioned Coils  138
-Seebeck Effect  478
-Segments  56
-Segments, Commutator   56
-Selenium  478
-Selenium Cell  478
-Selenium Eye  478
-Self-exciting Dynamo  201
-Self-induction  303
-Self-induction, Magnetic   352
-Self-induction, Unit of   304
-Self-repulsion  478
-Self-winding Electric Clock  128
-Semi-circular Deviation  181
-Semi-conductors  478
-Semi-incandescent Lamp  323
-Sender, Zinc  582
-Sensibility  479
-Sensitiveness, Angle of Maximum   479
-Separate Circuit Dynamo  201
-Separate Touch  359, 479
-Separate Touch, Magnetization by   359
-Separately Excited Dynamo  201, 479
-Separation of Electricities  479
-Separator  479
-Separator, Magnetic   352
-Series  479
-Series and Long Shunt Winding  579
-Series and Separate Coil Winding  579
-Series and Short Shunt Winding  580
-Series, Contact  147
-Series Dynamo  201
-Series, Electro-chemical   209
-Series, Electro motive   228
-Series, Electrostatic   235
-Series Motor  386
-Series, Multiple-   387
-Series-multiple  480
-Series, Thermo-electric   534
-Series Transformer  548
-Series Winding  579
-Service Conductors  480
-Serving  480
-Shackle  480
-Shadow, Electric   480
-Shadow, Molecular   480
-Shadow Photometer  414
-Sheath for Magnet Coils  481
-Sheath for Transformers  481
-Sheath, Induction  303
-Sheet Current  166
-Shell, Magnetic  352
-Shell, Strength of Magnetic  352
-Shellac  481
-Shellac Varnish  481
-Shield, Anti-magnetic   37
-Shield, Magnetic   351, 353
-Shielded  481
-S. H. M.  482
-Shock, Back, or Stroke of Lightning   55
-Shock, Break   482
-Shock, Electric   482
-Shock, Opening   482
-Shock, Static  482
-Short Circuit  482
-Short Circuit Working  482
-Short Fall Air Pumps  16
-Short Shunt Winding   579
-Shovel Electrodes  483
-Shower Bath, Electric   57
-Shunt  483
-Shunt Box   483
-Shunt Circuit  123, 126
-Shunt Dynamo  202
-Shunt, Electro-magnetic   483
-Shunt, Galvanometer   271, 483
-Shunt, Magnetic   353
-Shunt Motor  386
-Shunt. Multiplying Power of a   388
-Shunt Ratio  483
-Shunt Winding  580
-Shuttle Armature  49
-Shuttle Current  483
-Shuttle Winding  483, 580
-Side Flash  484
-Siemens and Halske's Battery  72
-Siemens' Differential Voltameter  564
-Siemens' Electro-dynamometer  212
-Siemens' Old Armature  49
-Siemens' Unit of Resistance  467
-Sighted Position  484
-Signaling, Velocity of  560
-Signals, Electro-pneumatic   231
-Signal, Telegraph  519
-Silent Discharge  187, 189, 206
-Silver  484
-Silver Bath  484
-Silver, German   277
-Silver Stripping Bath  484
-Silver Voltameter  565
-Simple Arc  39
-Simple Circuit  126
-Simple Harmonic Motion  486
-Simple Immersion  185
-Simple Magnet  366
-Simple Substitution  485
-Sims-Edison Torpedo  543
-Sine Curve  174, 485
-Sine Galvanometer  271
-Sine Law  486
-Sines, Curve of  173, 485
-Single Coil Dynamo  202
-Single Curb Working  581
-Single Fluid Theory  486
-Single Fluid Voltaic Cell  486
-Single Needle Telegraph  519
-Single Touch, Magnetization by  359
-Sinistrotorsal  486
-Sinuous Current  166
-Sinusoidal Curve  174, 485
-Siphon Recorder  452
-Sir William Thomson's Battery  72
-Skin Effect  486
-Skrivanow Battery  72
-Sled  486
-Sleeve, Joint   310
-Slide, Balance   374
-Slide Bridge  374
-Slide Meter Bridge  486
-Sliding Condenser  144
-Sliding-contact Key  316
-Sliding Resistance Box  463
-Slope, Lines of   330
-Smee's Battery  73
-S. N. Code  486
-Snap Switch  501
-Soaking-in-and-out  486
-Socket, Lamp   323
-Socket, Wall  572
-Soldering, Electric   487
-Solenoid  487
-Solenoid Ammeter  28
-Solenoidal Distribution of Magnetism  358
-Solenoidal Magnet  366
-Solid Earth  203
-Solutions, Battery, Chromic Acid   73
-Solution, Chutaux's  119
-Solution, Delaurier's    179
-Solution, Hittorf's   289
-Solution, Kookogey's   318
-Solution, Poggendorf's  421
-Solution, Striking  496
-Solution, Tissandier's  542
-Solution, Trouv�'s   549
-Sonometer, Hughes'   488
-Sonorescence  488
-Sound, Characteristics of   114
-Sounder  488
-Sounders, Tin   542
-Sound, Quality of   444
-Sound Reading  489
-South Magnetic Fluid  356
-Space, Clearance  489
-Space, Crookes' Dark    489
-Space, Dark, Faraday's   249, 489
-Space, Faraday's Dark   249, 489
-Space, Inter-air   489
-Space, Interferric   489
-Span, Polar  424
-Span, Polar, Angle of the   32
-Spark Arrester  489
-Spark Coil  489
-Spark Discharge  189
-Spark, Duration of Electric   490
-Spark Gap  490
-Spark, Length of   490
-Spark Micrometer  470
-Spark Tube  491
-Sparking  490
-Sparking Distance  190
-Sparking, Lines or Points of Least   490
-Sparking, Resistance to   490
-Specific Conduction Resistance  467
-Specific Conductivity  145
-Specific Heat  286
-Specific Heat of Electricity  491
-Specific Inductive Capacity  103
-Specific Magnetization  361
-Specific Resistance  467
-Speech, Articulate   50
-Speed, Critical   157
-Spent Acid  491
-Spent Liquor  491
-Spherical Armature  49
-Spherical Candle Power  101
-Spherical Illuminating Power  296
-Sphygmophone  491
-Sphygmophone, Electric  491
-Spiders  491
-Spiral   492
-Spiral Battery  73
-Spiral, Roget's    474
-Spiral Winding  492
-Spirit Compass  143
-Splayed Joint  311
-Splice Box  492
-Split Battery  73
-Split Ring Commutator  141
-Spluttering  492
-Sponge, Platinum   419
-Spot, Grease  92
-Sprengel Pump  439
-Spring Ammeter  28
-Spring and Fibre Suspension  252
-Spring-contact  148
-Spring Control  492
-Spring Jack Cut-out  493
-Spurious Hall Effect  284
-Spurious Resistance  467
-Spurious Voltage  493
-Square Mil  379
-Square Wire  493
-Squares, Law of Inverse   323
-St. Elmo's Fire  494
-Staggering  493
-Standard Candle  101
-Standard Candle, German  99
-Standard, Harcourt's Pentane   406
-Standard, Methven   376
-Standard of Illuminating Power, Viole's   561
-Standard or Main Feeder  251
-Standard Quadrant  444
-Standard Resistance Coil  464
-Standard Voltaic Cell  109
-Standard Voltaic Cell, Daniell's  109
-Standard Voltaic Cell, Latimer Clark's.   110
-State, Electrotonic   493
-State, Nascent  389
-State of Matter, Fourth   261
-State, Passive  404
-State, Permanent   408
-Static Breeze  493
-Static Condenser, Armature of   46
-Static Electricity  493
-Static Hysteresis  295
-Static Induction, Magnetic   347
-Static Shock  482
-Station, Central    493
-Station, Distant   493
-Station, Home  493
-Station, Transforming  494
-Steadying Resistance  468
-Steel  494
-Steeling  494
-Steel Yard Ammeter  28
-Step-by-step Telegraph  506
-Step-by-step Telegraphy  494
-Step-down  494
-Step, Foot-    259
-Sticking  494
-Stool, Insulating  305
-Stopped Coil Electro-magnets  221
-Stopping Off  495
-Storage Battery  70
-Storage Battery Changing Switch  501
-Storage Battery, Plant�'s   72
-Storage Capacity  105, 495
-Storage of Electricity  495
-Storms, Electric   495
-Storms. Magnetic   353
-Strain  495
-Strain, Dielectric   183
-Strain, Magnetic  354
-Stranded Conductor Armature  49
-Stranded Core  155
-Stray Field  256, 495
-Stray Power  495
-Streamlets. Current  495
-Strength, Dielectric   183
-Strength of Magnetic Shell  352
-Stress  495
-Stress, Dielectric  496
-Stress, Electro-magnetic   219, 496
-Stress, Electrostatic  236, 496
-Stress, Energy of   241
-Stress, Magnetic   354
-Striae, Electric   496
-Striking Distance  496
-Striking Solution  496
-Stripping  496
-Stripping Bath  57
-Stripping Bath, Gold   279
-Stripping Bath, Silver   484
-Stroke, Back   55
-Stroke or Shock of Lightning, Back   55
-Stroke, Return  55
-Sub-branch  496
-Sub-main  496
-Sub-permanent Magnetism  358
-Substitution, Simple   485
-Subway, Electric  496
-Successive Temperatures, Law of   324
-Sucking Coil  182
-Sucking Magnet  366
-Sulphate of Lead Battery  66
-Sulphate of Mercury Battery  67
-Sulphating  497
-Sulphur Dioxide  497
-Sulphuric Acid  497
-Sulphuric Acid Voltameter  564
-Sulphurous Acid Gas   497
-Sunstroke, Electric  497
-Superficial Density, Electric   180
-Supersaturated,   497
-Supply, Isolated   309
-Surface  497
-Surface Density  498
-Surface, Equipotential   498
-Surface Leakage  498
-Surface Magnetization  356
-Surgical Electro-magnet  222
-Surging Discharge  188
-Surveyors' Compass  143
-Susceptibility, Magnetic  354, 359
-Suspension  498
-Suspension, Bifilar  498
-Suspension, Fibre  252
-Suspension, Knife Edge  317
-Suspension, Pivot  416
-Suspension, Spring and Fibre   252
-Suspension, Torsion  545
-Suspension Wire of Cable   97
-Swaging. Electric  499
-Swelling Current  167
-S. W. G.  499
-Swinburne Pump  440
-Swinging Earth  203
-Swinging or Pendulum Annunciator  35
-Swiss Unit of Resistance   468
-Switch  499
-Switch, Automatic  500
-Switch Board  500
-Switch Board, Multiple   387
-Switch Board, Trunking   550
-Switch, Break-down   88
-Switch, Changing  500
-Switch, Changing Over   500
-Switch, Circuit Changing   500
-Switch, Double Break   500
-Switch, Double Pole   500
-Switch Feeder  500
-Switch, Knife   501
-Switch, Knife Break   501
-Switch, Knife Edge   501
-Switch, Multiple  501
-Switch, Plug  420
-Switch, Pole Changing   501
-Switch, Reversing   501
-Switch, Snap   501
-Switch, Storage Battery Changing   501
-Switch, Three Way   501
-Switches, Distributing   190
-Symmer's Theory  191
-Sympathetic Vibration  501, 561
-System, Block   83
-System of Co-ordinates  150
-System, Tower   545
-
-T  501
-Tailing Current  501
-Tailings  501
-Talk, Cross  158
-Tamidine  502
-Tangent Galvanometer  272
-Tangent Law  502
-Tangent Positions of, Gauss   276
-Tangent Scale  502
-Tangentially Laminated Core  155
-Tank, Cable  97
-Tape, Insulating   305
-Tapper Key, Double   314
-Teazer  504
-Technica, Memoria, Amp�re's   30
-Tee, Lead  504
-Teeth, Pacinotti   400
-Tel-autograph  504
-Tele-barometer, Electric   504
-Telegraph, A. B. C.  504
-Telegraph, Autographic   510
-Telegraph, Automatic  504
-Telegraph, Dial  505
-Telegraph, Double Needle   506
-Telegraph, Duplex  506
-Telegraph, Duplex, Bridge  506
-Telegraph, Duplex, Differential   507
-Telegraph Embosser  237
-Telegraph, Facsimile  510
-Telegraph, Harmonic Multiplex   510
-Telegraph. Hughes'   511
-Telegraph Insulator  306
-Telegraph Key  316
-Telegraph, Magneto-electric   512
-Telegraph, Morse  512
-Telegraph, Multiplex  514
-Telegraph, Single Needle   519
-Telegraph, Overhouse  515
-Telegraph Pole Brackets  515
-Telegraph, Printing  515
-Telegraph, Quadruplex   515
-Telegraph Repeater  518
-Telegraph Signal  519
-Telegraph, Step-by-step  506
-Telegraph, Wheatstone's, A. B. C.   521
-Telegraph. Writing  521
-Telegraphic Alphabet  19
-Telegraphic Code  130, 511
-Telegraphic Needle  389
-Telegraphic Register  454
-Telegraphy, Multiplex  388
-Telegraphy, Step-by-step   494
-Telemanometer, Electric   521
-Telemeter, Electric   521
-Telepherage  522
-Telephone  522
-Telephone, Bi-  524
-Telephone, Capillary   525
-Telephone, Carbon   525
-Telephone, Chemical   526
-Telephone, Electrostatic   526
-Telephone Exchange  246
-Telephone Induction Coil  137, 526
-Telephone, Reaction   527
-Telephone Record  451
-Telephone, Thermo-electric   527
-Telephone Tinnitus  542
-Telephotography  521
-Telephote  527
-Telescope, Reading  450
-Teleseme  527
-Tele-thermometer  527
-Terminal  529
-Terminal Pole  529
-Terminal Voltage  562
-Temperature, Absolute   8
-Temperature, Neutral  390
-Temperatures, Laws of Successive   324
-Tempering, Electric  527
-Temporary Magnetism or Magnetization  357
-Ten, Powers of    527
-Tension  529
-Tension, Disruptive  189
-Tension, Electric  529
-Terrestrial Magnetism   358
-Tetanus, Acoustic   529
-Tetrode Working  581
-Theatrophone  529
-Theory, Contact  148
-Theory, Double Fluid   191
-Theory, Franklin's  262
-Theory of Dimensions  184
-Theory of Light, Electro-magnetic  219
-Theory of Light, Maxwell's  369
-Theory of Magnetism, Amp�re's  354
-Theory of Magnetism, Ewing's  356
-Theory of Magnetism, Hughes'   357
-Theory of Magnetism, Weber's   358
-Theory, Symmer's  191
-Therapeutic Electrode  210
-Therapeutics, Electro-   236
-Therm  529
-Thermaesthesiometer  530
-Thermal Electric Meter  375
-Thermal Equivalent, Electro-   245
-Thermal Energy  242
-Thermic Balance  85
-Thermo Call  530
-Thermo-chemical Battery  530
-Thermo-chemical Equivalent  245
-Thermo-electric Battery or Pile  530
-Thermo-electric Call  531
-Thermo-electric Couple  532
-Thermo-electric Current  167
-Thermo-electric Diagram  532
-Thermo-electric Element  237
-Thermo-electric Inversion  533
-Thermo-electric Junction  533
-Thermo-electric Neutral Point   390
-Thermo-electric Pile, Differential  533
-Thermo-electric Power  533
-Thermo-electric Reversal  533
-Thermo-electric Series  534
-Thermo-electric Telephone  527
-Thermo-electric Thermometer  535
-Thermo-electricity  533
-Thermo-electricity, Laws of, Becquerel's  78
-Thermo-electricity, Volta's Law of  568
-Thermo-electrometer  536
-Thermolysis  535
-Thermo-multiplier  536
-Thermometer  535
-Thermometer, Electric   535
-Thermometer, Kinnersley's   536
-Thermometer, Tele-   527
-Thermometer, Thermo-electric   535
-Thermophone  537
-Thermostat, Electric   537
-Third Brush  91
-Thomson Effect  538
-Thomson's Replenisher, Sir William   459
-Thomson's Battery, Sir William  72
-Thomson's Unit of Resistance  468
-Three Filament Incandescent Lamp  322
-Three Way Switch  501
-Three Wire System  539
-Throw  237, 540
-Throw-back Indicator  540
-Thrust Bearings  540
-Thunder  540
-Ticker   540
-Tick, Magnetic   354
-Timbre   444
-Time Constant  541
-Time Cut-outs  541
-Time Electric Meter  375
-Time-fall   541
-Time-reaction  541
-Time-rise  541
-Tin  541
-Tin Sounders  542
-Tinnitus, Telephone   542
-Tips, Polar   423
-Tips, Pole   290, 426
-Tissandier's Solution  542
-Toeppler-Holtz Machine  334
-Tongs, Cable Hanger  97
-Tongs, Discharging  189
-Tongue of Polarized Relay  542
-Tongue of Polarized Relay, Bias of   542
-Toothed Core-discs  154
-Top, Magnetic   542
-Torpedo, Electric  543
-Torpedo, Sims-Edison   543
-Torque  543
-Torque, Curve of   174
-Torricellian Vacuum  557
-Torsion Balance, Coulomb's   544
-Torsion Galvanometer  273, 544
-Torsion Head  544
-Torsion Suspension  545
-Total Earth  203
-Touch  545
-Touch, Separate   479
-Tourmaline   545
-Tower, Electric   545
-Tower System   545
-Trailing Horns  259
-Transformer  545
-Transformer, Commuting  547
-Transformer, Continuous Alternating   547
-Transformer, Continuous Current   384, 547
-Transformer, Core  547
-Transformer, Faraday's   250
-Transformer, Hedgehog   548
-Transformer, Multiple   548
-Transformer, Oil  548
-Transformer, Pilot   415
-Transformer, Series   548
-Transformer. Sheath for  481
-Transforming Station  494
-Transformer, Welding   548, 575
-Translator  519
-Translucent Disc Photometer  412
-Transmitter  548
-Transmitter, Carbon   549
-Transmission of Energy, Electric   240
-Transposing  549
-Transverse Electro-motive Force  549
-Trap, Bug  92
-Traveling Pole  426
-Trembling Bell  78
-Trolley  549
-Trolley, Double   549
-Trolley Section  549
-Trough Battery   73
-Trouv�'s Blotting Paper Battery  73
-Trouv�'s Solution  549
-True Contact Force  549
-True Ohm  396
-True Resistance  467
-Trimmer, Brush   549
-Trumpet, Electric   550
-Trunk Lines  550
-Trunking Switch Board  550
-Tube, Electric   550
-Tube, Guard  282
-Tube, Luminous   550
-Tube of Magnetic Induction  347
-Tube, Spark  491
-Tube, Stratification   495
-Tubes, Geissler   276
-Tubes of Force   261
-Tubes, Pl�cker  420
-Tubular Braid  550
-Tubular Core  155
-Tubular Magnet  356
-Tuning Fork Circuit Breaker  121
-Tuning Fork Dynamo  202
-Tuning Fork, Interrupter for  307
-Turning Moment  544
-Turns  550
-Turns, Ampere-  31
-Turns, Dead, of a Dynamo   551
-Turns, Primary Ampere-   551
-Turns, Secondary Ampere-   551
-Twist Joint, American  309
-Twist, Magnetic   354
-Tyer's Battery  74
-Typewriter, Electric   551
-Type Printer, Hughes'   511
-
-Ultra-gaseous Matter  551
-Unbuilding  552
-Underground Conductor  552
-Underground Electric Subway  552
-Undulatory  23
-Undulatory Current  167
-Unidirectional  553
-Uniform Field  256
-Uniform Field of Force  553
-Uniform Magnetic Field  345
-Unipolar  553
-Unipolar Armature  50, 553
-Unipolar Current Induction  553
-Unipolar Dynamo  202-553
-Unipolar Electric Bath  57
-Unipolar Induction   304
-Unipolar Magnet  366
-Unit  553
-Unit, Absolute   554
-Unit Angle  554
-Unit. B. A.   554
-Unit, B. A., of Resistance   462
-Unit Current  167
-Unit Electro-motive Force  228
-Unit, Fundamental   554
-Unit Jar  554
-Unit Magnet Pole  366
-Unit of Capacity  105
-Unit of Conductivity  145
-Unit of Electric Potential  432
-Unit of Energy, Electro-magnetic   220
-Unit of Force  261
-Unit of Illumination  296
-Unit of Output  399
-Unit of Reluctance  458
-Unit of Resistance, B. A.   78
-Unit of Resistance, Breguet   463
-Unit of Resistance, Digney  464
-U nit of Resistance, English Absolute or Foot-second   465
-Unit of Resistance, German Mile  466
-Unit of Resistance, Jacobi's  466
-Unit of Resistance, Meter-millimeter.   466
-Unit of Resistance, Mil-foot   467
-Unit of Resistance, Siemens'  467
-Unit of Resistance, Swiss  468
-Unit of Resistance, Thomson's   468
-Unit of Resistance, Varley's   468
-Unit of Self-induction  304
-Unit of Supply  554
-Unit of Work  581
-Unit Resistance  468
-Units, Circular  126, 555
-Units, Derived   555
-Units, Heat   288
-Units, Practical  555
-Universal Battery System  556
-Universal Discharger  189
-Unmarked End  556
-Upright Galvanometer  274
-Upward's Battery  75
-
-V  556
-V. A.  557
-Vacuum  557
-Vacuum, Absolute  557
-Vacuum, High  557
-Vacuum Lightning Arrester  329
-Vacuum, Low   557
-Vacuum, Partial  557
-Vacuum, Torricellian   557
-Valency  557
-Valve, Electrically Controlled   558
-Vapor Globe  558
-Variable Conductivity  145
-Variable Period  558
-Variable State  558
-Variation of the Compass  32, 558
-Variations, Magnetic   354
-Variometer  559
-Varley's Battery  76
-Varley's Condenser   559
-Varley's Resistance  559
-Varley's Unit of Resistance   468
-Varnish  559
-Varnish, Electric    559
-Varnish, Insulating   306
-Varnish, Red  559
-Varnish, Shellac  481
-Vat  559
-Velocity  559
-Velocity, Angular  32, 559
-Velocity of Signaling  560
-Velocity Ratio  560
-Ventilation of Armature  560
-Vertical Galvanometer  274
-Vertical Induction  304
-Verticity, Poles of   426, 560
-Vibrating Bell  78
-Vibration Period  560
-Vibration, Sympathetic   501, 561
-Vibrator, Electro-magnetic   561
-Villari's Critical Value   561
-Viole  562
-Viole's Standard of Illuminating Power  561
-Virtual Resistance  297
-Viscous Hysteresis  295, 356
-Vis Viva  562
-Vitreous Electricity  562
-Vitriol, Blue  562
-Vitriol, Green    562
-Vitriol, White   562
-Volatilization of Carbon  108
-Volt  562
-Volt-ampere  573
-Volt and Ampere Meter Galvanometer  274
-Volt, B. A.  568
-Volt, Congress   568
-Volt, Coulomb   568, 573
-Volt Indicator  568
-Volt. Legal   568
-Voltage  562
-Voltage, Spurious  493
-Voltage, Terminal   562
-Voltaic  563
-Voltaic Alternatives  563
-Voltaic Arc  39
-Voltaic Cell, Daniell's Standard  109
-Voltaic Cell, Double Fluid  191
-Voltaic Cell, Capacity of Polarization of a   103
-Voltaic Cell, Single Fluid   486
-Voltaic Cell, Standard   109
-Voltaic Cell, Standard, Latimer Clark's   110
-Voltaic Circuit  126
-Voltaic Effect  563
-Voltaic Electricity  563
-Voltaic Element  237
-Voltaic or Galvanic Battery  76
-Voltaic or Galvanic Circle  119
-Voltaic or Galvanic Couple  156
-Voltameter   563
-Voltameter, Copper   563
-Voltameter, Differential, Siemens'   564
-Voltameter, Faraday's   250
-Voltameter, Gas   564
-Voltameter, Silver  565
-Voltameter, Sulphuric Acid    564
-Voltameter, Volume   564
-Voltameter, Weight   566
-Voltametric Law  567
-Volta's Battery  76
-Volta's Fundamental Experiments   567
-Volta's Law of Galvanic Action  568
-Volta's Law of Thermo-electricity  568
-Voltmeter  568
-Voltmeter, Battery   569
-Voltmeter, Cardew  569
-Voltmeter, Electrostatic   571
-Voltmeter, Reducteur for   453
-Volts, Lost  571
-Volume Voltameter  564
-Vulcanite  571
-
-W  572
-Wall Bracket  572
-Wall Socket  572
-Ward  572
-Waste Field  256
-Water  572
-Water Battery  77
-Water Equivalent  572
-Water Level Alarm  18
-Waterproof Lamp Globe  572
-Wattless Current  168
-Watt  572
-Watt-hour  573
-Watt Meter  375
-Watt-minute  573
-Watt-second  573
-Watts, Apparent  573
-Wave Winding  580
-Waves, Amplitude of   31
-Waves. Electro-magnetic   573
-Wax, Paraffine   402
-Weber   574
-Weber s Absolute Unit Resistance  468
-Weber-meter  574
-Weber's Theory of Magnetism  358
-Wedge Cut-out  175
-Wedge. Double   191
-Weight, Atomic   53
-Weight, Breaking   89
-Weight Electrometer  223
-Weight Voltameter  566
-Welding, Electric  574
-Welding Transformer  548, 575
-Wheatstone's A. B. C. Telegraph  521
-Wheatstone's Balance   577
-Wheatstone's Bridge   575
-Wheatstone's Bridge, Commercial   86
-Wheatstone's Rheostat    472
-Wheel, Phonic   409
-Wheel, Reaction   259
-Whirl, Electric   577
-White Vitriol   562
-Wilde Candle   101
-Wimshurst Electric Machine  335, 577
-Wimshurst Machine  335, 577
-Wind, Electric  578
-Windage  578
-Windings, Ampere   31
-Winding, Bifilar  81
-Winding, Compound   578
-Winding, Disc  579
-Winding, Lap  579
-Winding, Long Shunt  579
-Winding, Long Shunt and Series  579
-Winding, Multiple   579
-Winding, Multipolar   579
-Winding, Series  579
-Winding, Series and Separate Coil   579
-Winding, Series and Short Shunt   580
-Winding, Short Shunt   579
-Winding, Shunt  483, 580
-Winding Shuttle  580
-Winding, Wave  580
-Winding Working, Differential  183
-Wire, Block  83
-Wire, Bus  94
-Wire, Dead   177
-Wire Finder   580
-Wire Gauze Brush  92
-Wire, Idle  296
-Wire, Neutral   390
-Wire, Omnibus   94
-Wire, Square  493
-Wire System, Three   539
-Wires, Crossing   158
-Wires, Leading-in   324
-Wires, Phantom   409
-Wires, Pilot  415
-Wollaston Battery  78
-Work  580
-Work, Electric, Unit of   580
-Work, Unit of  581
-Working, Contraplex   580
-Working, Diode   580
-Working, Diplex   580
-Working, Double Curb   581
-Working, Hexode   581
-Working, Pentode   581
-Working, Reverse Current  581
-Working, Single Curb   581
-Working Tetrode  581
-Writing Telegraph  521
-
-X, Axis of   54
-
-Y, Axis of   54, 397
-Yoke  581
-
-Zamboni's Dry Pile  581
-Zero  581
-Zero, Absolute  581
-Zero Potential  432, 582
-Zero, Thermometric   582
-Zinc   582
-Zinc Sender  582
-Zincode  582
-Zone, Peripolar   582
-Zone, Polar   582
-
-
-
-
-
-End of the Project Gutenberg EBook of The Standard Electrical Dictionary, by 
-T. O'Conor Slone
-
-*** END OF THIS PROJECT GUTENBERG EBOOK THE STANDARD ELECTRICAL DICTIONARY ***
-
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@@ -1,38359 +0,0 @@
-<!DOCTYPE html PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN">
-<html>
-<head>
-  <meta content="text/html;charset=ISO-8859-1" http-equiv="Content-Type">
-  <title>STANDARD ELECTRICAL DICTIONARY</title>
-</head>
-<body>
-
-
-<pre>
-
-Project Gutenberg's The Standard Electrical Dictionary, by T. O'Conor Slone
-
-This eBook is for the use of anyone anywhere at no cost and with
-almost no restrictions whatsoever.  You may copy it, give it away or
-re-use it under the terms of the Project Gutenberg License included
-with this eBook or online at www.gutenberg.org
-
-
-Title: The Standard Electrical Dictionary
-       A Popular Dictionary of Words and Terms Used in the Practice
-              of Electrical Engineering
-
-Author: T. O'Conor Slone
-
-Release Date: September 5, 2008 [EBook #26535]
-
-Language: English
-
-Character set encoding: ISO-8859-1
-
-*** START OF THIS PROJECT GUTENBERG EBOOK THE STANDARD ELECTRICAL DICTIONARY ***
-
-
-
-
-Produced by Don Kostuch
-
-
-
-
-
-</pre>
-
-<big><big>STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-</big></big><big><big><br>
-[Transcriber's Notes]<br>
-<br>
-Obvious spelling errors have been corrected. I have not reconciled the<br>
-variety of spellings of names and other words. Obvious factual errors,<br>
-typographical errors, discoveries made after 1892, and contemporary<br>
-(2008) theories and use of words are noted in the text within square<br>
-brackets. I have not researched and checked every assertion by the<br>
-author.<br>
-<br>
-This book was published 5 years before discovery of the electron. See<br>
-the labored and completely inaccurate explanations of aurora and<br>
-"energy, atomic". The author and his contemporaries were like fifteenth<br>
-century sailors. They had a good idea of their latitude and direction<br>
-(Ampere, Kirkoff, Maxwell, Gauss, Faraday, Edison, &#8230;), but only the<br>
-vaguest notion of their longitude (nuclear structure, electrons, ions).<br>
-Altitude (special relativity, quantum theory) was not even imagined.<br>
-<br>
-Some relevant dates:<br>
-Franklin's Kite--1752<br>
-Faraday's Law of Induction--1831<br>
-Maxwell's Equations--1861<br>
-Edison's Phonograph--1877<br>
-Edison's light bulb--1879<br>
-Edison's first DC power station--1882<br>
-Michelson-Morley experiment disproving ether--1887<br>
-Hertz demonstrates radio waves--1888<br>
-Westinghouse first AC power station--1891<br>
-This book--1892<br>
-Discovery of the electron--1897<br>
-Marconi radio signals cross the English Channel--1897<br>
-First Vacuum Tube--1904<br>
-Special Relativity, photo-electric effect explained with photons--1905<br>
-General Relativity: space-time dilation and curvature--1915<br>
-Confirmation of general relativity's prediction of the deflection<br>
-&nbsp; of starlight by the Sun--1919<br>
-Discovery of the proton--1920<br>
-Quantum theory--1926<br>
-Discovery of neutron--1932<br>
-First transistor--1947<br>
-Soviet satellite Luna measures solar wind--1959<br>
-Edward M. Purcell explains magnetism with special relativity--1963<br>
-<br>
-Purcell's explanation of magnetism as a result of Lorentz contraction of<br>
-space along the direction of a current is a welcome relief from the<br>
-convoluted descriptions in this book.<br>
-<br>
-Mathematical notation is rendered using "programming" notation.<br>
-^&nbsp;&nbsp;&nbsp; &nbsp;&nbsp; Power--Exponential; A^3 means "A cubed"<br>
-*&nbsp;&nbsp;&nbsp; &nbsp;&nbsp; Multiply<br>
-/&nbsp;&nbsp;&nbsp; &nbsp;&nbsp; Divide<br>
-+&nbsp;&nbsp;&nbsp; &nbsp;&nbsp; Add<br>
--&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Subtract<br>
-( )&nbsp;&nbsp;&nbsp;&nbsp; Precedence--Perform before enclosing
-expression<br>
-2E6&nbsp;&nbsp; Scientific Notation (2,000,000)<br>
-<br>
-<br>
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; A<br>
----------------------<br>
-4.452 X 10^12 X t<br>
-<br>
-is rendered as<br>
-<br>
-A / ( 4.452E12 *&nbsp; t&nbsp; )<br>
-<br>
-<br>
-Where the rendering of a mathematical expression is in doubt, an image<br>
-of the original text is included.<br>
-<br>
-<br>
-Here are some definitions absent from the text.<br>
-<br>
-Foucault currents.<br>
-&nbsp; Eddy currents.<br>
-<br>
-inspissate<br>
-&nbsp; To thicken, as by evaporation.<br>
-<br>
-riband<br>
-&nbsp; Ribbon.<br>
-<br>
-sapotaceous<br>
-&nbsp; Order Sapotace[ae] of trees and shrubs, including the star
-apple, the<br>
-&nbsp; Lucuma, or natural marmalade tree, the gutta-percha tree
-(Isonandra),<br>
-&nbsp; and the India mahwa, as well as the sapodilla, or sapota, after
-which<br>
-&nbsp; the order is named.<br>
-<br>
-<br>
-Don Kostuch, MS, Electrical Engineering.<br>
-[End Transcriber's notes.]<br>
-</big></big><br>
-<br>
-<br>
-<big><big><br>
-WORKS OF<br>
-T. O'CONOR SLOANE, A.M., E.M., Ph.D.<br>
-<br>
-<br>
-ARITHMETIC OF ELECTRICITY<br>
-A MANUAL OF ELECTRICAL CALCULATIONS<br>
-BY ARITHMETICAL METHODS.<br>
-Third Edition. Illustrated. $1.00.<br>
-It is very useful to that class of readers to whom Algebra is a<br>
-comparatively unknown quantity, and will meet its wants<br>
-admirably.--Electrical World.<br>
-<br>
-<br>
-<br>
-ELECTRICITY SIMPLIFIED.<br>
-A POPULAR TREATMENT OF THE SUBJECT.<br>
-Illustrated. $1. 00.<br>
-We especially recommend it to those who would like to acquire a popular<br>
-idea of the subject.--Electric Age.<br>
-<br>
-<br>
-<br>
-ELECTRIC TOY MAKING.<br>
-FOR AMATEURS.<br>
-INCLUDING BATTERIES, MAGNETS, MOTORS, MISCELLANEOUS TOYS,<br>
-AND DYNAMO CONSTRUCTION.<br>
-Fully Illustrated. $1.00.<br>
-<br>
-<br>
-THE STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-A POPULAR DICTIONARY OF WORDS AND TERMS<br>
-USED IN THE PRACTICE OF ELECTRICAL ENGINEERING.<br>
-<br>
-<br>
-BY<br>
-T. O'CONOR SLOANE, A.M., E.M., Ph.D.<br>
-<br>
-<br>
-NEW YORK<br>
-GEORGE D. HURST<br>
-PUBLISHER<br>
-<br>
-<br>
-<br>
-Copyright 1892<br>
-by<br>
-NORMAN W. HENLEY &amp; CO.<br>
-<br>
-<br>
-<br>
-PREFACE<br>
-<br>
-The purpose of this work is to present the public with a concise and<br>
-practical book of reference, which it is believed will be appreciated in<br>
-this age of electricity. The science has expanded so much that the<br>
-limits of what may be termed strictly a dictionary of the present day<br>
-would a few years ago have sufficed for an encyclopedia. It follows that<br>
-an encyclopedia of electricity would be a work of great size. Yet a<br>
-dictionary with adequate definitions, and kept within the closest limits<br>
-by the statement of synonyms, and by the consigning of all the<br>
-innumerable cross-references to a concise index will be far more than a<br>
-mere dictionary in the ordinary sense of the term.<br>
-<br>
-Duplication of matter is to be avoided. This makes many definitions<br>
-appear short. Yet, by the assistance of the reader's own general<br>
-knowledge, and by referring to the very complete index, almost any<br>
-subject can be found treated in all its aspects. There are exceptions to<br>
-this statement. So much has been done in the way of mechanical detail,<br>
-so many inventions in telegraphy and other branches have sprung into<br>
-prominence only to disappear again, or to be modified out of<br>
-recognition, that to embody descriptions of many ingenious and<br>
-complicated apparatus has been absolutely impossible for want of space.<br>
-<br>
-A word as to the use of the book and the system of its construction may<br>
-be given here. Each title or subject is defined once in the text. Where<br>
-a title is synonymous with one or more others the definition is only<br>
-given under one title, and the others appear at the foot of the article<br>
-as synonyms. It may be that the reader is seeking the definition of one<br>
-of these synonyms. If so a reference to the index shows him at once what<br>
-page contains the information sought for. The use of an index in a work,<br>
-necessarily of an encyclopedic form, will be appreciated by all users of<br>
-this book.<br>
-<br>
-vi&nbsp;&nbsp; PREFACE.<br>
-<br>
-Where a title embraces several words, all orders of the words will be<br>
-cited in the index. To make the operation of finding references easy<br>
-this rule has been carried out very fully.<br>
-<br>
-It is customary to regard electricity as a growing science. It is<br>
-unquestionably such, but the multiplication of terms and words is now<br>
-not nearly so rapid as it has been, and the time for the compiling of a<br>
-work of this character seems most propitious. It is hoped that the<br>
-public will indulgently appreciate the labor it has entailed on all<br>
-concerned in its production.<br>
-<br>
-<br>
-SYMBOLS AND ABBREVIATIONS.<br>
-<br>
-</big></big>
-<table style="width: 794px; height: 328px;" border="1" cellpadding="2"
- cellspacing="2">
-  <tbody>
-    <tr>
-      <td><big><big>adj.</big></big></td>
-      <td><big><big> Adjective.</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big>v. </big></big></td>
-      <td><big><big>Verb.</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big>q.v. </big></big></td>
-      <td><big><big> "Which see.'</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big>/ </big></big></td>
-      <td><big><big>A mark of division, as A/B, meaning "A divided by
-B."</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big>./. </big></big></td>
-      <td><big><big>The same as above.</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big><br>
-      </big></big></td>
-      <td><big><big> [Transcriber's note: / will be substituted for
-this divide symbol.]</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big>= </big></big></td>
-      <td><big><big> A mark of equality, meaning "is equal to."</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big>X </big></big></td>
-      <td><big><big> A mark of multiplication, meaning "multiplied by."</big></big></td>
-    </tr>
-    <tr>
-      <td><big><big><br>
-      </big></big></td>
-      <td><big><big> [Transcriber's note: * will be substituted for
-this divide symbol.]</big></big></td>
-    </tr>
-  </tbody>
-</table>
-<big><big><br>
-<br>
-Fractional exponents indicate the roots expressed by their denominators<br>
-and the powers expressed by their numerators. Thus, A^1/2 means the<br>
-"square root of A;" A^1/3 means the "cube root of A;" B^3/2 means the<br>
-"square root of the cube or third power of B."<br>
-<br>
-The use of powers of ten, as 10^10, 10^11, as multipliers, will be found<br>
-explained at length in the definition "Ten, Powers of."<br>
-</big></big><br>
-<br>
-<big><big><br>
-vii&nbsp; STANDARD ELECTRICAL DICTIONARY<br>
-<br>
-<span style="font-weight: bold;">A. </span><br>
-Abbreviation for anode, employed in text relating to<br>
-electro-therapeutics. It is sometimes written An.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Abscissa. </span><br>
-In a system of plane co-ordinates (see Co-ordinates) the<br>
-distance of any point from the axis of ordinates measured parallel to<br>
-the axis of abscissas.<br>
-<br>
-In the cut the abscissa of the point a is the line or distance a c.<br>
-<br>
-<img style="width: 867px; height: 668px;" alt="" src="images/007F1.jpg"><br>
-Fig. 1. AXES OF CO-ORDINATES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Absolute.</span> adj.<br>
-In quantities it may be defined as referring to fixed units of quantity,<br>
-and it is opposed to "relative," which merely refers to the relation of<br>
-several things to each other. Thus the relative resistance of one wire<br>
-may be n times that of another; its absolute resistance might be 5 ohms,<br>
-when the absolute resistance of the second wire would be 5/n ohms. A<br>
-galvanometer gives absolute readings if it is graduated to read directly<br>
-amperes or volts; if not so graduated, it may by "calibration" q. v. be<br>
-made to do practically the same thing.<br>
-<br>
-8&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Absolute Measurement.</span><br>
-Measurement based upon the centimeter, gram, and second. (See<br>
-Centimeter-Gram-Second System.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Absolute Temperature.</span><br>
-Temperature reckoned from absolute zero (see "Zero, Absolute"). It is<br>
-obtained by adding for the centigrade scale 273, and for the Fahrenheit<br>
-scale 459, to the degree readings of the regular scale.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Absorption, Electric.</span><br>
-A property of the static charge. When a Leyden jar is being charged it<br>
-dilates a little and the capacity increases, so that it can take a<br>
-little more charge for a given potential difference existing between its<br>
-two coatings. This phenomenon occurs with other static condensers,<br>
-varying in degree with the dielectric. With shellac, paraffin, sulphur<br>
-and resin, for instance, the absorption is very slight; with<br>
-gutta-percha, stearine, and glass, the absorption is relatively great.<br>
-The term is due to Faraday. Iceland spar seems almost or quite destitute<br>
-of electric absorption.<br>
-<br>
-<br>
-<span style="font-weight: bold;">A. C. C.</span><br>
-Symbol of or abbreviation for "anodic closure contraction" q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Acceleration.</span><br>
-The rate of change of velocity. If of increase of velocity it is<br>
-positive; if of decrease, it is negative. It can only be brought about<br>
-by the exercise of force and is used as the measure of or as determining<br>
-the unit of force. It is equal to velocity (L/T) imparted, divided by<br>
-time (T); its dimensions therefore are L/(T^2). The c. g. s. unit of<br>
-acceleration is one centimeter in one second.<br>
-<br>
-[Transcriber's note: The unit of acceleration is "centimeters per second<br>
-per second."]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Accumulator.</span><br>
-(a) A term sometimes applied to the secondary or storage battery. (See<br>
-Battery, Secondary.)<br>
-(b) See Accumulator, Electrostatic<br>
-(c) See Accumulator, Water Dropping.<br>
-(d) See Wheel, Barlow's<br>
-<br>
-<br>
-<span style="font-weight: bold;">Accumulator, Electrostatic.</span><br>
-Two conducting surfaces oppositely placed, and separated by a<br>
-dielectric and arranged for the opposite charging of the two surfaces,<br>
-constitute an accumulator, sometimes termed a condenser. As this<br>
-arrangement introduces the element of a bound and of a binding charge,<br>
-the electrostatic capacity of such is greater than that of either or of<br>
-both of its component surfaces. The thinner the dielectric which<br>
-separates the conducting surfaces, and the larger the surfaces the<br>
-greater is the capacity; or the less will be the potential difference<br>
-which a given charge will establish between its two coatings. The nature<br>
-of the dielectric also determines its capacity. (See Capacity, Specific<br>
-Inductive.)<br>
-<br>
-<br>
-9&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 885px; height: 795px;" alt="" src="images/009F2.jpg"><br>
-Fig. 2. SIR WILLIAM THOMSON'S WATER-DROPPING ACCUMULATOR.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Accumulator, Water Dropping.</span><br>
-This is also known as Sir William Thomson's Water-Gravity Electric<br>
-Machine. It is an apparatus for converting the potential energy of<br>
-falling water drops, due to gravity, into electric energy. Referring to<br>
-the illustration, G represents a bifurcated water pipe whose two faucets<br>
-are adjusted to permit a series of drops to fall from each. C and F are<br>
-two metallic tubes connected by a conductor; E and D are the same. Two<br>
-Leyden jars, A and B, have their inner coatings represented by strong<br>
-sulphuric acid, connected each to its own pair of cylinders, B to D and<br>
-E, and A to F and C. The outer coatings are connected to earth, as is<br>
-also the water supply. One of the jars, say A, is charged interiorily<br>
-with positive electricity. This charge, C and F, share with it, being in<br>
-electric contact therewith. Just before the drops break off from the jet<br>
-leading into C, they are inductively charged with negative electricity,<br>
-the positive going to earth. Thus a series of negatively excited drops<br>
-fall into the metal tube D, with its interior funnel or drop arrester,<br>
-charging it, the Leyden jar B, and the tube E with negative electricity.<br>
-This excitation causes the other stream of drops to work in the converse<br>
-way, raising the positive potential of F and C and A, thus causing the<br>
-left-hand drops to acquire a higher potential. This again raises the<br>
-potential of the right-hand drops, so that a constant accumulating<br>
-action is kept up. The outer coatings of the Leyden jars are connected<br>
-to earth to make it possible to raise the potential of their inner<br>
-coatings. In each case the drops are drawn by gravity into contact with<br>
-objects similarly excited in opposition to the electric repulsion. This<br>
-overcoming of the electric repulsion is the work done by gravity, and<br>
-which results in the development of electric energy.<br>
-<br>
-<br>
-10&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Acidometer.</span><br>
-A hydrometer or areometer used to determine the specific gravity of<br>
-acid. They are employed in running storage batteries, to determine when<br>
-the charging is completed. (See Areometer.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Aclinic Line.</span><br>
-A terrestrial element; the locus on the earth's surface of no<br>
-inclination of the magnetic needle; the magnetic equator. (See Magnetic<br>
-Elements.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Acoustic Telegraphy.</span><br>
-The system of sound-reading in telegraphy, universally used in the Morse<br>
-system. The direct stroke of the armature of the electro-magnet and its<br>
-"back stroke" disclose to the ear the long and short strokes, dots and<br>
-lines, and long and short spaces as produced by the dispatcher of the<br>
-message. In the Morse system a special magnet and armature is used to<br>
-produce the sound called the "sounder;" in other systems, e. g.,<br>
-Steinheil's and Bright's apparatus, bells are used. (See Alphabets,<br>
-Telegraphic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Acoutemeter.</span><br>
-A Hughes audiometer or sonometer applied to determining the quality of a<br>
-person's hearing (See Hughes' Induction Balance,--Audiometer). The<br>
-central coil by means of a tuning fork and microphone with battery<br>
-receives a rapidly varying current tending to induce currents in the<br>
-other two coils. Telephones are put in circuit with the latter and pick<br>
-up sound from them. The telephones are applied to the ears of the person<br>
-whose hearing is to be tested. By sliding the outer coils back and forth<br>
-the intensity of induction and consequent loudness of the sounds in the<br>
-telephones is varied. The position when the sounds grow so faint as to<br>
-be no longer audible, gives the degree of delicacy of the person's<br>
-hearing. By using a single telephone the same apparatus affords a means<br>
-of testing the relative capacity of the right and left ears.<br>
-<br>
-<br>
-11&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Actinic Rays.</span><br>
-The rays of light at the violet end of the spectrum; also the invisible<br>
-rays beyond such end, or the ether waves of short periods which most<br>
-strongly induce chemical change.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Actinism.</span><br>
-The power possessed by ether waves of inducing chemical change, either<br>
-of decomposition or of combination. The violet and ultra-violet end of<br>
-the spectrum of white light, generally speaking, represent the most<br>
-highly actinic rays.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Actinometer, Electric.</span><br>
-Properly an apparatus for measuring the intensity of light by its action<br>
-upon the resistance of selenium. A current produced by fixed<br>
-electro-motive force passing through the selenium affects a galvanometer<br>
-more or less according to the intensity of the light. It is more<br>
-properly an electric photometer. The term has also been applied to a<br>
-combination of a thermo-electric pile and galvanometer, the light<br>
-falling on the pile affecting the motions of the galvanometer.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Action, Local.</span><br>
-(a) The wasteful oxydation of the zinc in a galvanic battery due to<br>
-local impurities and variations in the composition of the zinc. These<br>
-act to constitute local galvanic couples which cause the zinc to<br>
-dissolve or oxydize, without any useful result. Amalgamation of the zinc<br>
-prevents local action. Chemically pure zinc is also exempt from local<br>
-action, and can be used in an acid battery without amalgamation. (See<br>
-Amalgamation.)<br>
-<br>
-(b) The same term has been employed to indicate the eddy or foucault<br>
-currents in dynamo electric machines. (Sec Current, Foucault.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Activity.</span><br>
-The rate of doing work; the work done per second by any expenditure of<br>
-energy. The activity of a horse-power is 550 foot lbs. per second, or<br>
-746 volt-coulombs per second. The practical electric unit is the<br>
-volt-ampere, often called the watt. (Sec Energy, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Adapter.</span><br>
-A screw coupling to engage with a different sized screw on each end; one<br>
-of the uses is to connect incandescent lamps to gas-fixtures.<br>
-<br>
-<br>
-<span style="font-weight: bold;">A. D. C.</span><br>
-Abbreviation for Anodic Duration Contraction, q. v.; a term in<br>
-electro-therapeutics.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Adherence, Electro-magnetic.</span><br>
-The adherence between surfaces of iron due to elcctro-magnetic<br>
-attraction. It has been applied to the driving-wheels of an engine and<br>
-rail, whose grip is increased by such action. In one method a deep<br>
-groove was cut around the wheel which was wound with a magnetizing coil.<br>
-Thus one rim becomes a north and the other a south pole, and the rail<br>
-completing the circuit acts as the armature. Such an arrangement<br>
-prevents a wheel from sliding. Electro-magnetic adherence has also been<br>
-employed to drive friction gear wheels. In one arrangement the two<br>
-wheels are surrounded by a magnetizing coil, under whose induction each<br>
-attracts the other, developing high adherence between their peripheries.<br>
-<br>
-<br>
-12&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 430px; height: 615px;" alt="" src="images/012F3.JPG"><br>
-Fig. 3. ELECTRO-MAGNETIC CAR WHEEL.<br>
-<br>
-<br>
-<img style="width: 510px; height: 688px;" alt="" src="images/012F4.JPG"><br>
-Fig. 4. ELECTRO-MAGNETIC FRICTION GEAR.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Admiralty Rule of Heating.</span><br>
-The British Admiralty specifications for the permissible heating of<br>
-dynamos. It holds that at the end of a run of six hours no part of the<br>
-dynamo under trial shall show a rise of temperature greater than
-11&ordm; C.<br>
-(20&ordm; F.) above the temperature of the air surrounding it. This is<br>
-thought to be a very stringent and unnecessarily high requirement.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Aerial Conductor.</span><br>
-An electric conductor carried from housetops, poles, or otherwise so as<br>
-to be suspended in the air, as distinguished from an underground or<br>
-submarine conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Affinity.</span><br>
-The attraction of atoms and in some cases perhaps of molecules for each<br>
-other by the force of chemical attraction. When the affinity is allowed<br>
-to act or is carried out, a chemical change, as distinguished from a<br>
-physical or mechanical change, ensues. Thus if sulphur and iron are each<br>
-finely powdered and are mixed the change and mixture are mechanical. If<br>
-slightly heated the sulphur will melt, which is a physical change. If<br>
-heated to redness the iron will combine with the sulphur forming a new<br>
-substance, ferric sulphide, of new properties, and especially<br>
-characterized by unvarying and invariable ratios of sulphur to iron.<br>
-Such change is a chemical one, is due to chemical affinity, is due to a<br>
-combination of the atoms, and the product is a chemical compound.<br>
-<br>
-<br>
-13&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Agir Motor.</span><br>
-The Anderson and Girdlestone motor. The term "agir" is made up from the<br>
-first portions of each name.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Agonic Line.</span><br>
-The locus of points on the earth's surface where the magnetic needle<br>
-points to the true north; an imaginary line determined by connecting<br>
-points on the earth's surface where the needle lies in the true<br>
-geographical meridian. Such a line at present, starting from the north<br>
-pole goes through the west of Hudson's Bay, leaves the east coast of<br>
-America near Philadelphia, passes along the eastern West Indies, cuts<br>
-off the eastern projection of Brazil and goes through the South Atlantic<br>
-to the south pole. Thence it passes through the west of Australia, the<br>
-Indian Ocean, Arabia, the Caspian sea, Russia and the White sea to the<br>
-North Pole. It crosses the equator at 70&deg; W. and 55&deg; E.
-approximately.<br>
-(See Magnetic Elements.)<br>
-<br>
-Synonym--Agone.<br>
-<br>
-<br>
-<img style="width: 700px; height: 615px;" alt=""
- src="images/309_Declination_1590_1990.gif"><br>
-[Transcriber's note: The file Earth_Declination_1590_1990.gif provided<br>
-by the U.S. Geological Survey (http://www.usgs.gov) is an animation of<br>
-the declination of the entire earth.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Air.</span><br>
-Air is a dielectric whose specific inductive capacity at atmosphere<br>
-pressure is taken as 1. It is practically of exactly the same<br>
-composition in all places and hence can be taken as a standard. When dry<br>
-it has high resistance, between that of caoutchouc and dry paper.<br>
-Dampness increases its conductivity.<br>
-<br>
-It is a mixture of oxygen and nitrogen, with a little carbonic acid gas<br>
-and other impurities. Its essential composition is:<br>
-<small><br>
-</small></big></big><big><big><small><span
- style="font-family: monospace;">Oxygen: &nbsp;&nbsp;&nbsp; (by weight)
-23.14 &nbsp;&nbsp;&nbsp; (by volume) 21&nbsp;&nbsp;&nbsp; </span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Nitrogen: &nbsp;&nbsp; &nbsp;
-&nbsp; &nbsp; &nbsp; &nbsp;&nbsp; 76.86 &nbsp;&nbsp; &nbsp; &nbsp;
-&nbsp; &nbsp; &nbsp; &nbsp;&nbsp; 79</span></small><br>
-<br>
-The specific inductive capacity varies for different pressures thus:<br>
-<br>
-</big></big><big style="font-family: monospace;">Approximate&nbsp;&nbsp;
-</big><big style="font-family: monospace;"> (.001 mm., .0004 inch)
-&nbsp; 0.94 (Ayrton)&nbsp; <br>
-</big><big style="font-family: monospace;">Vacuum &nbsp; </big><small
- style="font-family: monospace;"><br>
-</small><big style="font-family: monospace;">&nbsp; &nbsp; &nbsp;
-&nbsp; &nbsp; &nbsp;&nbsp;&nbsp; </big><big
- style="font-family: monospace;">( 5 mm. , .2 inches )&nbsp;&nbsp;&nbsp;</big><big><big><small
- style="font-family: monospace;"> 0.9985 (Ayrton)<br>
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&nbsp; &nbsp; 0.99941 (Boltzman.)</small><br>
-<br>
-The specific gravity of air under standard conditions 15.5&deg; C
-(60&deg; F.)<br>
-and 760 mm. barometric pressure (30 inches) is taken as unity as a<br>
-standard for gases.<br>
-<br>
-[Transcriber's note: Argon accounts for 0.9340%. It was discovered in<br>
-1894, two years after this book.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Air-Blast.</span><br>
-(a) In the Thomson-Houston dynamo an air-blast is used to blow away the<br>
-arc-producing spark liable to form between the brushes and commutator.<br>
-It is the invention of Prof. Elihu Thomson. The air is supplied by a<br>
-positive action rotary blower connected to the main shaft, and driven<br>
-thereby. The wearing of the commutator by destructive sparking is thus<br>
-prevented.<br>
-<br>
-A drum H H is rotated, being mounted on the axis X of the dynamo. As it<br>
-rotates the three vanes are thrown out against the irregular shaped<br>
-periphery of the outer case T T. The arrow shows the direction of<br>
-rotation. The air is thus sent out by the apertures a a. O is the<br>
-oil-cup.<br>
-<br>
-(b) The air-blast has also been used by Prof. Thomson in experiments<br>
-with high frequency currents of high potential. By directing a blast of<br>
-air against a spark discharge between ball terminals of an alternating<br>
-current, the nature of the current was changed and it became capable of<br>
-producing most extraordinary effects by induction.<br>
-<br>
-<br>
-14&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 527px; height: 629px;" alt="" src="images/014F5.jpg"><br>
-Fig. 5. AIR BLOWER FOR THOMSON'S DYNAMO.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Air Condenser.</span><br>
-A static condenser whose dielectric is air. The capacity of an air<br>
-condenser in farads is equal to<br>
-&nbsp; A / ( 4.452E12 * t )<br>
-in which A is the area of one sheet or sum of the areas of one set of<br>
-connected sheets in square inches and t is the thickness of the layer of<br>
-air separating them.<br>
-<br>
-A convenient construction given by Ayrton consists in a pile of glass<br>
-plates P separated by little bits of glass F of known thickness, three<br>
-for each piece. Tin-foil T is pasted on both sides of each piece of<br>
-glass and the two coatings are connected. The tin-foil on each second<br>
-plate is smaller in area than that on the others. The plates are<br>
-connected in two sets, each set comprising every second plate. For A in<br>
-the formula the area of the set of smaller sheets of tin-foil is taken.<br>
-By this construction it will be seen that the glass does not act as the<br>
-dielectric, but only as a plane surface for attachment of the tin-foil.<br>
-Posts E E keep all in position. One set of sheets connects with the<br>
-binding post A, the other with B.<br>
-<br>
-The capacity of any condenser with a dielectric of specific inductive<br>
-capacity i is given by the formula:<br>
-&nbsp;&nbsp;&nbsp;&nbsp; ( i *A^1 ) / ( 4.452E12 * t1 )<br>
-<br>
-The air condenser is used for determining the value of i for different<br>
-dielectrics.<br>
-<br>
-<br>
-<img style="width: 496px; height: 513px;" alt="" src="images/015F6.jpg"><br>
-Fig. 6. AIR CONDENSER.<br>
-<br>
-<br>
-15&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Air Gaps.</span><br>
-In a dynamo or motor the space intervening between the poles of the<br>
-field magnet and the armature. They should be of as small thickness, and<br>
-of as extended area as possible. Their effect is to increase the<br>
-magnetic reluctance of the circuit, thereby exacting the expenditure of<br>
-more energy upon the field. They also, by crowding back the potential<br>
-difference of the two limbs, increase the leakage of lines of force from<br>
-limb to limb of the magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Air Line Wire.</span><br>
-In telegraphy the portion of the line wire which is strung on poles and<br>
-carried through the air.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Air Pump, Heated.</span><br>
-It has been proposed to heat portions of a mercurial air pump to secure<br>
-more perfect vacua, or to hasten the action. Heating expands the air and<br>
-thus produces the above effects.<br>
-<br>
-<br>
-16&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Air Pump, Mercurial.</span><br>
-An air pump operated by mercury. The mercury acts virtually as the<br>
-piston, and the actuating force is the weight of the column of mercury,<br>
-which must exceed thirty inches in height. There are many types.<br>
-Mercurial air pumps are largely used for exhausting incandescent lamp<br>
-chambers. (See Geissler Air Pump,--Sprengel Air Pump.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Air Pumps, Short Fall.</span><br>
-A mercurial air pump in which the fall of mercury or the height of the<br>
-active column is comparatively small. It is effected by using several<br>
-columns, one acting after the other. A height of ten inches for each<br>
-column suffices in some forms. Enough columns must be used in succession<br>
-to make up an aggregate height exceeding 30 inches.<br>
-<br>
-<br>
-<img style="width: 525px; height: 212px;" alt="" src="images/016F7.jpg"><br>
-Fig. 7. BURGLAR ALARM SWITCH OR CIRCUIT BREAKER.<br>
-<br>
-<br>
-<img style="width: 440px; height: 325px;" alt="" src="images/016F8.jpg"><br>
-Fig. 8. BURGLAR ALARM SWITCH OR CIRCUIT BREAKER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alarm, Burglar.</span><br>
-A system of circuits with alarm bell extending over a house or<br>
-apartments designed to give notice of the opening of a window or door.<br>
-As adjuncts to the system the treads of the stairs are sometimes<br>
-arranged to ring the bell, by completing a circuit when trod on. Door<br>
-mats are also arranged to close circuits in like manner.<br>
-<br>
-<br>
-17&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-For doors and windows switches are provided which are open as long as<br>
-the door or window is closed, but which, on being released by opening<br>
-the door or windows, automatically close the circuit. The circuit<br>
-includes an alarm bell and battery, and the latter begins to ring and<br>
-continues until stopped, either by the closing of the door or by a<br>
-switch being turned. The connections are sometimes so contrived that the<br>
-reclosing of the door or window will not stop the bell from ringing.<br>
-<br>
-The cuts show various switches for attachment to doors and windows. It<br>
-will be seen that they normally keep the circuit closed, and that it is<br>
-only open when pressure, as from a closed door, is brought upon them. In<br>
-the case of a door a usual place for them is upon the jamb on the hinge<br>
-side, where they are set into the wood, with the striking pin<br>
-projecting, so that as the door is closed the pin is pressed in, thus<br>
-breaking the circuit.<br>
-<br>
-Sometimes the connections are arranged so as to switch on the electric<br>
-lights if the house is entered. Special annunciators showing where the<br>
-house has been entered are a part of the system. A clock which turns the<br>
-alarm on and off at predetermined hours is also sometimes used.<br>
-<br>
-The circuits may be carried to a central station or police station. One<br>
-form of burglar alarm device is the Yale lock switch. This is a contact<br>
-attached to a Yale lock which will be closed if the wrong key is used,<br>
-completing a circuit and ringing a bell.<br>
-<br>
-<br>
-<img style="width: 746px; height: 253px;" alt="" src="images/017F9.jpg"><br>
-Fig. 9. BURGLAR ALARM SWITCH OR CIRCUIT BREAKER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alarm, Electric. </span><br>
-An appliance for calling attention, generally by <br>
-ringing a bell. It is used to notify of water-level in boilers or
-tanks, <br>
-of entrance of a house, or of other things as desired. It is evident <br>
-that any number of alarms could be contrived.<br>
-<br>
-<br>
-18&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alarm, Fire and Heat.</span><br>
-An alarm for giving notice of the existence of a conflagration. Such are<br>
-sometimes operated by a compound bar thermostat (see Thermostat), which<br>
-on a given elevation of temperature closes a circuit and rings an<br>
-electric bell. Sometimes the expansion of a column of mercury when<br>
-heated is used. This, by coming in contact with one or two platinum<br>
-points, completes a circuit, and rings the bell.<br>
-<br>
-The identical apparatus may be used in living rooms, greenhouses.<br>
-factories and elsewhere, to give an alarm when the temperature rises or<br>
-falls beyond predetermined limits.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alarm, Overflow.</span><br>
-An alarm to indicate an overflow of water has been suggested on the<br>
-lines of a contact completed by water, or of the elements of a battery<br>
-which would be made active by water. Thus two sheets of metal might be<br>
-separated by bibulous paper charged with salt. If these sheets were<br>
-terminals of a circuit including a bell and battery, when water reached<br>
-them the circuit would be closed and the bell would ring. It was also<br>
-proposed to use one copper and one zinc sheet so as to constitute a<br>
-battery in itself, to be thrown into action by moisture. These contacts<br>
-or inactive batteries could be distributed where water from an overflow<br>
-would be most likely to reach them.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alarm, Water Level.</span><br>
-An alarm operated by a change of water level in a tank or boiler. By a<br>
-float a contact is made as it rises with the water. Another float may be<br>
-arranged to fall and close a contact as the level falls. The closing of<br>
-the contacts rings an electric bell to notify the attendant in charge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alcohol, Electrical Rectification of.</span><br>
-A current of electricity passed through impure alcohol between zinc<br>
-electrodes is found to improve its quality. This it does by decomposing<br>
-the water present. The nascent hydrogen combines with the aldehydes,<br>
-converting them into alcohols while the oxygen combines with the zinc<br>
-electrode.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alignment.</span><br>
-The placing in or occupying of the same straight line. The bearings of a<br>
-shaft in dynamos, engines, and other machinery have to be in accurate<br>
-alignment.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Allotropy.</span><br>
-The power of existing in several modifications possessed by some<br>
-substances, notably by chemical elements. Instances of the allotropic<br>
-state are found in carbon which exists as charcoal, as graphite<br>
-(plumbago or black lead), and as the diamond. All three are the same<br>
-elemental substance, although differing in every physical and electrical<br>
-property.<br>
-<br>
-<br>
-19&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alloy.</span><br>
-A mixture, produced almost universally by fusion, of two or more metals.<br>
-Sometimes alloys seem to be chemical compounds, as shown by their having<br>
-generally a melting point lower than the average of those of their<br>
-constituents. An alloy of a metal with mercury is termed an amalgam. An<br>
-important application in electricity is the use of fusible alloys for<br>
-fire alarms or for safety fuses. German silver is also of importance for<br>
-resistance coils, and palladium alloys are used for unmagnetizable<br>
-watches. An alloy of wrought iron with manganese is almost<br>
-unmagnetizable, and has been proposed for use in ship building to avoid<br>
-errors of the compass.<br>
-<br>
-Alloys or what are practically such can be deposited by electrolysis in<br>
-the electro- plater's bath. We give the composition of some alloys<br>
-interesting to the electrician.<br>
-<small><br>
-&nbsp; <span style="font-family: monospace;">Solder:&nbsp;&nbsp;
-Lead&nbsp;&nbsp; 1 part&nbsp;&nbsp;
-Tin&nbsp;&nbsp; 2 parts</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp; 1&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp; 2&nbsp; "</span></small>
-<br>
-<br>
-German Silver: Copper, 2 parts; Nickel, 1 part;<br>
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Zinc, 1 part (used for resistances).<br>
-<br>
-Platinum, Silver Alloys: Platinum, 1 part;<br>
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-silver, 2 parts (used for resistances.)<br>
-<br>
-Palladium alloys for watch springs. (See Palladium.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alphabet, Telegraphic.</span><br>
-The combinations of sounds, of dots and dashes marked on paper, of<br>
-right-hand and left-hand deflections of a needle, of bells of different<br>
-notes, or of other symbols by which a fixed combination is expressed for<br>
-each character of the alphabet, for numerals, and for punctuation. While<br>
-the code is designed for telegraphic uses it can be used not only for<br>
-the conveyance of signals and messages by the electrical telegraphs, but<br>
-also by any semaphoric or visual system, as by flashes of light,<br>
-movements of a flag or even of the arms of the person signalling.<br>
-<br>
-In the English and continental needle telegraphy in which the message is<br>
-transmitted by the movements of an index normally vertical, but<br>
-oscillating to one side or the other under the influence of the current,<br>
-the latter being controlled by the transmitter of the message, the left<br>
-hand swings of the needle are interpreted as dots, the right hand as<br>
-dashes.<br>
-<br>
-This system enables one alphabet to be translated into the other, or<br>
-virtually one alphabet answers for both Morse and needle transmitters.<br>
-<br>
-There are two principal telegraphic alphabets, the American Morse and<br>
-the International codes. They are very similar, their essential<br>
-distinction being that spaces are used in the American code, while they<br>
-are excluded from the International code.<br>
-<br>
-In the American Morse system the message is now universally received by<br>
-sound. (See Sounder--Sound Reading.)<br>
-<br>
-<br>
-20&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The two codes or telegraphic alphabets are given here.<br>
-<br>
-THE INTERNATIONAL ALPHABET.<br>
-&nbsp;&nbsp;&nbsp;&nbsp;
-<span style="font-family: monospace;">Parenthesis,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-- . - - . -</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Understand,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-... - .</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; I don't
-understand,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; ..-- ....--..</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Wait,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.-. . .</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Erase,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-...&nbsp;&nbsp; ...&nbsp;&nbsp; ...</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Call
-signal,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
--.-.-.-</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; End of
-message,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .-.-.-.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Cleared out all
-right,&nbsp;&nbsp; .-..-..-.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; A&nbsp;
-.-&nbsp;&nbsp;&nbsp; L&nbsp; .-..&nbsp; W&nbsp; .--</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; B&nbsp; -...&nbsp; M&nbsp;
---&nbsp;&nbsp;&nbsp; X&nbsp; -..-</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; C&nbsp; -.-.&nbsp; N&nbsp;
--.&nbsp;&nbsp;&nbsp; Y&nbsp; -.--</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; D&nbsp; -..&nbsp;&nbsp;
-O&nbsp; ---&nbsp;&nbsp; Z&nbsp; --..</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; E&nbsp;
-.&nbsp;&nbsp;&nbsp;&nbsp; P&nbsp; .--.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; F&nbsp; ..-.&nbsp; Q&nbsp;
---.-&nbsp; Ch ----</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; G&nbsp; --.&nbsp;&nbsp;
-R&nbsp; .-.&nbsp;&nbsp; &Auml;&nbsp; .-.-</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; H&nbsp; ....&nbsp; S&nbsp;
-...&nbsp;&nbsp; &Ouml;&nbsp; ---.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; I&nbsp;
-..&nbsp;&nbsp;&nbsp; T&nbsp; -&nbsp;&nbsp;&nbsp;&nbsp;
-&Uuml;&nbsp; ..--</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; J&nbsp; .---&nbsp; U&nbsp;
-..-&nbsp;&nbsp; &Eacute;&nbsp; ..-..</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; K&nbsp; -.-&nbsp;&nbsp;
-V&nbsp; ...-&nbsp; &Ntilde;&nbsp; --.--</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">NUMERALS</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 1&nbsp; .----&nbsp;
-4&nbsp; ....-&nbsp; 8&nbsp; ---..</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 2&nbsp; ..---&nbsp;
-5&nbsp; .....&nbsp; 9&nbsp; ----.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 3&nbsp; ...--&nbsp;
-6&nbsp; -....&nbsp; 0&nbsp; -----</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7&nbsp; --...</span><br>
-<br>
-<br>
-[Transcriber's note: The original image of the dot/dash pattern is
-somewhat<br>
-ambiguous. Since there may be differences from contemporary
-specifications,<br>
-the original image is included.]<br>
-<br>
-<img style="width: 640px; height: 1019px;" alt=""
- src="images/020Pic.jpg"><br>
-[Image of page 20: THE INTERNATIONAL ALPHABET.]<br>
-<br>
-<br>
-21&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-family: monospace;">PUNCTUATION, ETC.,</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Period
-(.)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-...&nbsp;&nbsp; ...</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Comma
-(,)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.-.-.-</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Query(?)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-..--..</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Exclamation
-(!)&nbsp;&nbsp;&nbsp; --..--</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Apostrophe
-(')&nbsp;&nbsp;&nbsp;&nbsp; .----.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Hyphen
-(-)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; -....-</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Fresh
-paragraph,&nbsp;&nbsp; .-.-..</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Inverted
-commas,&nbsp;&nbsp; -..-.</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">THE AMERICAN ALPHABET.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; A&nbsp;
-.-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; L&nbsp;
-----(Continuous)&nbsp; W&nbsp; .--</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; B&nbsp;
--...&nbsp;&nbsp;&nbsp;&nbsp; M&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-X&nbsp; .-..</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; C&nbsp;
-..s.&nbsp;&nbsp;&nbsp;&nbsp; N&nbsp;
--.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Y&nbsp; ..s..</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; D&nbsp;
--..&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; O&nbsp;
-.s.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Z&nbsp; &#8230;.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; E&nbsp;
-.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; P&nbsp; .....</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; F&nbsp;
-.-.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Q&nbsp;
-..-.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Ch ----</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; G&nbsp;
---.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; R&nbsp;
-.s..&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&Auml;&nbsp; .-.-</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; H&nbsp;
-....&nbsp;&nbsp;&nbsp;&nbsp; S&nbsp;
-...&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&Ouml;&nbsp; ---.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; I&nbsp;
-..&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; T&nbsp;
--&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&Uuml;&nbsp; ..--</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; J&nbsp; - . - .&nbsp;
-U&nbsp;
-..-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&Eacute;&nbsp; ..-..</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; K&nbsp;
--.-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; V&nbsp;
-...-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&Ntilde;&nbsp; --.--</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">NUMERALS</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 1&nbsp;
-.--.&nbsp;&nbsp;&nbsp; 4&nbsp;
-....-&nbsp;&nbsp;&nbsp;&nbsp; 8&nbsp; -....</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 2&nbsp; ..-..&nbsp;&nbsp;
-5&nbsp;
----&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 9&nbsp; -..-</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 3&nbsp; ...-.&nbsp;&nbsp;
-6&nbsp; ... ...&nbsp;&nbsp; 0&nbsp;
------(Continuous)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7&nbsp; --..</span><br>
-<br>
-[Transcriber's Note: The "s" in the American Code indicates a "space".
-I <br>
-leave the following to the reader's imagination. See the original <br>
-image.]<br>
-<br>
-<span style="font-family: monospace;">Comma (,)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Semicolon (;)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Colon (:)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Colon Dash (:~)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Period (.)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Interrogation (?)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Exclamation (!)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Dash (-)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Hyphen (-)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Pound Sterling (&pound;)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Shilling Mark ( )</span><br>
-<br>
-<br>
-<img style="width: 624px; height: 1052px;" alt=""
- src="images/021Pic.jpg"><br>
-[Image of page 21: THE AMERICAN ALPHABET.]<br>
-<br>
-<br>
-22&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-[Transcriber's Note: I leave these to the reader's imagination. See the
-<br>
-following original image.]<br>
-<br>
-Dollars ($)<br>
-Decimal Point (.)<br>
-Cents (c)<br>
-Paragraph ()<br>
-Pence (d.)<br>
-Fractional Mark (--)<br>
-Capitalized Letter<br>
-Italics or Underline<br>
-Colon followed by Quotation :"<br>
-Parenthesis (&nbsp;&nbsp; )<br>
-Brackets [&nbsp;&nbsp; ]<br>
-Quotation Marks " "<br>
-Quotation within a Quotation " ' ' "<br>
-<br>
-<br>
-<img style="width: 677px; height: 341px;" alt="" src="images/022Pic.jpg"><br>
-[Image of page 22: THE AMERICAN ALPHABET.]<br>
-<br>
-<br>
-The principal differences in the two codes are the use of spaces in the<br>
-American code, such being excluded from the International code. This<br>
-affects the letters C, R, Y, &amp; Z.<br>
-<br>
-The following diagram, due to Commandant Perian, enables the letter<br>
-corresponding to an International code sign to be rapidly found with the<br>
-exception of R.<br>
-<small><br>
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-<span style="font-family: monospace;">&lt;-
-dot&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-start&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; dash&nbsp;&nbsp;
--&gt;</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-/&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-\</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-E&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-T</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-/&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-\&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-/&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-\</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-I&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-A&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-N&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-M</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-/&nbsp;&nbsp;&nbsp;
-\&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-/&nbsp;&nbsp;&nbsp; \&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-/&nbsp;&nbsp;&nbsp; \&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-/&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; \</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;
-S&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-U&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-R&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; W&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-D&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; K&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-G&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; O</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;/&nbsp; \&nbsp;&nbsp;&nbsp;
-/ \&nbsp;&nbsp;&nbsp;&nbsp; /
-\&nbsp; &nbsp; /&nbsp; \&nbsp;&nbsp;&nbsp; /&nbsp;
-\&nbsp;&nbsp;&nbsp;&nbsp; /&nbsp; \&nbsp;&nbsp;&nbsp; /&nbsp;
-\&nbsp;&nbsp;&nbsp; /&nbsp; \</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">H&nbsp;&nbsp; V&nbsp;&nbsp;
-F&nbsp;&nbsp; U&nbsp;&nbsp; L&nbsp;&nbsp;
-A&nbsp;&nbsp; P&nbsp;&nbsp; J&nbsp;&nbsp; B&nbsp;&nbsp; X&nbsp;&nbsp;
-C&nbsp;&nbsp; Y&nbsp;&nbsp; Z&nbsp; &nbsp; Q&nbsp; &Ocirc;&nbsp;&nbsp;
-CH</span><br>
-</small>
-<br>
-Fig. 10. Diagram for translating the Morse Alphabet.<br>
-<br>
-In order to find what letter corresponds to a given sign, starting from<br>
-the top of the diagram, each line is traced down to a bifurcation,<br>
-taking the right hand line of each bifurcation for a dash, and the left<br>
-hand line for a dot, and stopping when the dots and dashes are used up.<br>
-Thus, for example,<br>
-<br>
-the signal -.- -&nbsp;&nbsp; leads us to the letter d,<br>
-<br>
-the signal - - - - to the letter j and so on.<br>
-<br>
-<br>
-23&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alternating. adj. </span><br>
-Term descriptive of a current changing periodically in<br>
-direction. (See Current, Alternating.)<br>
-<br>
-Synonyms--Oscillatory--periodic--undulatory--harmonic.<br>
-<br>
-<span style="font-weight: bold;">Alternating Current Arc.</span><br>
-The arc produced by the alternating current. It presents several<br>
-peculiarities. With an insufficient number of alternations per second it<br>
-goes out. As the carbons wear away equally it is adopted for such lamps<br>
-as the Jablochkoff candle, (see Candle, Jablochkoff). As no crater is<br>
-formed the light is disseminated equally both up and down. For this<br>
-reason to get full downward illumination a reflector is recommended.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alternating Current System.</span><br>
-A system of electric distribution employing the alternating current. For<br>
-transmission in the open air or in conduits a high potential circuit is<br>
-used, from 1,000 to 10,000 volts being maintained at the central<br>
-station. Two leads unconnected at the end lead from the station. Where<br>
-current is desired a converter or transformer (see Converter) is placed,<br>
-whose primary is connected to the two leads bridging the interval<br>
-between them. From the secondary the house leads are taken with an<br>
-initial potential in some cases of 50 volts. The converters are thus all<br>
-placed in parallel. By law or insurance rules the converters are<br>
-generally kept outside of buildings. Where no secondary current is taken<br>
-from the converters very little primary current passes them on account<br>
-of their counter-electromotive force. As more secondary current is taken<br>
-the primary increases and this accommodation of one to the other is one<br>
-of the interesting and valuable features. Street lamps are sometimes<br>
-connected in series. Each lamp in such case is in parallel with a small<br>
-coil with iron core. While the lamp is intact little current passes<br>
-through the coil. If the lamp is broken, then the converter impedes the<br>
-current by its spurious resistance, q. v., just enough to represent and<br>
-replace the resistance of the extinguished and broken lamp filament.<br>
-(See Meter, Alternating Current; Motor, Alternating Current.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alternation.</span><br>
-The change in direction of a current. The number of such changes is<br>
-expressed as number of alternations; thus a current may have a frequency<br>
-of 500 or 20,000 alternations per second.<br>
-<br>
-[Transcriber's note: One alternation per second is now called one
-hertz.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alternation, Complete. </span><br>
-A double alternation; a change from one direction<br>
-to the other and back again to the original phase. A symbol derived from<br>
-its graphic representation by a sine curve is used to indicate it. The<br>
-symbol is&nbsp; ~<br>
-<br>
-<br>
-24&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Alternative Path.</span> <br>
-A second path for a current appearing as a disruptive<br>
-discharge. Where two paths are offered the discharge, as it is of<br>
-alternating or oscillatory type, selects the path of least<br>
-self-induction. Thus a thick bar of copper, with no air gap, may be<br>
-abandoned by the current in favor of a small iron wire with an air gap,<br>
-but which has less self-induction.<br>
-<br>
-The lightning arresters, q. v., for the protection of telegraph offices<br>
-are sometimes based on these principles. A path of very high resistance<br>
-but of small self-induction is offered between the line and the earth.<br>
-This the lightning discharge selects in preference to the instruments<br>
-with their iron cores, as the latter are of very high self-induction.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Alternator. </span><br>
-A dynamo electric generator supplying an alternating current. (See<br>
-Dynamo, Alternating Current.)<br>
-<br>
-Synonym--Alternating current generator or dynamo.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Alternator, Constant Current.</span><br>
-An alternating current dynamo supplying a current of unvarying virtual<br>
-amperage. Alternators of this type are constructed with an armature of<br>
-high self-induction. Sometimes fine winding contained in deep peripheral<br>
-notches in the core-discs is employed to magnify the self-induction.<br>
-Such generators are employed for series lighting, especially<br>
-arc-lighting.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Aluminum.</span><br>
-A metal; one of the elements; symbol: Al.<br>
-Atomic weight: 27.4. Equivalent: 9.13. Valency: 3.<br>
-Specific gravity: 2.6. It is a conductor of electricity.<br>
-Relative resistance annealed, (Silver = 1)&nbsp; 1.935<br>
-Specific resistance at 0&ordm;C (32&deg;F.)&nbsp;&nbsp;&nbsp; 2.912
-microhms<br>
-<br>
-<small><span style="font-family: monospace;">Resistance of a wire at
-0&ordm;C&nbsp; (32&deg;F.)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">a) 1 foot long, weighing 1
-grain,&nbsp;&nbsp;&nbsp;&nbsp; 0.1074 ohms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">b) 1 foot long, 1/1000 inch
-thick,&nbsp;&nbsp;
-17.53&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">c) 1 meter long, weighing 1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;
-0.0749&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">d) 1 meter long, 1 millimeter
-thick&nbsp;&nbsp; 0.03710&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a 1-inch cube at
-0&ordm;C (32&deg;F.) 1.147 microhms</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Electro-chemical
-equivalent.&nbsp;&nbsp;&nbsp; .0958 (hydrogen == .0105)</span></small><br>
-<br>
-<br>
-25&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Amalgam.</span><br>
-(a) A combination or alloy in which one of the constituents is mercury.<br>
-Usually the term is applied to an alloy of a single metal with mercury.<br>
-Some metals readily form amalgams; such metals are: Gold, zinc, silver,<br>
-lead and others; some, such as platinum and iron, form amalgams only<br>
-under exceptional circumstances.<br>
-<br>
-(b) The word is also applied to compositions for application to the<br>
-cushions of frictional electric machine in which cases it is often a<br>
-misnomer. True amalgams used for this purpose are made as follows:<br>
-<br>
-(a) Tin, 1 part;&nbsp; Zinc, 1 part;&nbsp; Mercury, 2 parts (Kienmayer).<br>
-(b) Tin, 2 parts; Zinc, 3 parts.<br>
-(c) Tin, 3 parts; Zinc, 5 parts; Mercury, 4 parts.<br>
-(d) Zinc, 1 part: Mercury, 4 parts; Mercury, 9 parts.&nbsp; [sic]<br>
-<br>
-The tin, if such is used, (formula a, b and c) is first melted, the zinc<br>
-is added in successive portions. The mercury, which must be heated, is<br>
-slowly poured into the melted alloy after removal of the latter from the<br>
-fire, and the mixture, while making, is constantly stirred. It is kept<br>
-stirred or rubbed in a mortar until cold. Sometimes it is poured into<br>
-water and kept in constant agitation until cold. It is thus obtained in<br>
-a granular condition, and is pounded in a mortar until reduced to<br>
-powder. It must be dried and kept in tightly stopped bottles and is<br>
-applied to the cushions after they have been greased. It is to be<br>
-noticed that it is said that alloy (d) requires no pulverization beyond<br>
-constant rubbing in a mortar as it cools. Sometimes the amalgam is<br>
-shaken about in a wooden tray with chalk while cooling. The action of<br>
-amalgams is not very clearly understood. Some claim that there is a<br>
-chemical action, others that they simply act as conductors, others that<br>
-they are more highly negative to the glass than the leather of the<br>
-cushions.<br>
-<br>
-Graphite or sulphide of tin (mosaic gold) are sometimes used to coat the<br>
-cushions; it is these that are sometimes incorrectly called amalgams.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Amalgamation.</span><br>
-The application of mercury to a metal with which it forms an amalgam, or<br>
-with which it amalgamates. Battery zincs are amalgamated in two ways. In<br>
-the immersion method, the plate is dipped into an acid solution of<br>
-mercuric chloride or nitrate. The latter is best. In the direct<br>
-application method the plate is first wet all over with dilute acid and<br>
-a little mercury is dropped upon it and is rubbed over the surface with<br>
-a rag or, what is better, with a piece of galvanized iron. A very little<br>
-mercury answers the purpose. The whole surface of the plate should be<br>
-left as bright as silver. (See Action, Local.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Amber.</span><br>
-Amber is a fossil resin, supposed to be a product of the extinct Pinites<br>
-Succinifer and other coniferous trees. Most of it is gathered on the<br>
-shores of the Baltic between Koenigsberg and Memel. It is also found in<br>
-small pieces at Gay Head, Mass., and in New Jersey green sand. It is<br>
-found among the prehistoric remains of the Swiss Lake dwellers. When<br>
-rubbed with a cloth it becomes excited with negative electricity. The<br>
-Greek word for it is electron, which gave the name electricity to the<br>
-modern science. Thales of Miletus, 600 B. C., and Theophrastus, about<br>
-300 B. C., both mention its electric properties or power of attracting<br>
-small objects when rubbed.<br>
-<br>
-<br>
-26&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter.</span> <br>
-The commercial name for an ampere-meter, an instrument designed<br>
-to show by direct reading the number of amperes of current which are<br>
-passing through a circuit.<br>
-<br>
-A great variety of ammeters have been invented, based on different<br>
-principles. The definitions following this one give some idea of the<br>
-lines of construction followed.<br>
-<br>
-Synonym--Ampere meter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Ayrton's.</span><br>
-A direct reading instrument for measuring current intensity.<br>
-<br>
-A solenoid receives the current. In the axis of the solenoid an iron<br>
-tube is suspended by a long spiral spring that passes down within it,<br>
-and the upper end of which spring is fastened to the glass top of the<br>
-instrument. The tube is provided with proper guides so as to maintain a<br>
-vertical position, and is free to rotate. Its upper end carries an<br>
-index.<br>
-<br>
-The whole operates as a magnifying device. A slight longitudinal<br>
-displacement of the tube causes it to rotate through a considerable<br>
-angle by the action of the spring. By properly proportioning the parts,<br>
-the angle of displacement of the index is directly proportional to the<br>
-current between 15&ordm; and 270&ordm; angular displacement.<br>
-<br>
-The same instrument is wound for use as a volt-meter.<br>
-<br>
-Its principal fault is its restricted range.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Commutator.</span><br>
-A commutator ammeter is one whose windings consist of separate strands,<br>
-each of any desired number of turns, and provided with a commutating<br>
-attachment for throwing them into series or into parallel as desired.<br>
-The essential condition is that all the wires shall be of equal<br>
-resistance and of equal number of turns. Such an instrument can be used<br>
-for heavy or light currents. Two sets of graduations are marked on its<br>
-scale if it is a calibrated instrument. (See Calibration.) Commutator<br>
-volt-meters are constructed on the same principle.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Cunynghame's.</span><br>
-A modification of the Siemens' electro-dynamometer. (See<br>
-Electro-dynamometer, Siemens'.) An electro-magnet with very massive core<br>
-is excited by the current. As the core is of small reluctance the<br>
-strength of the magnet is nearly proportional to the current strength.<br>
-Between the poles of the magnet a soft iron armature or induced magnet<br>
-is pivoted. It carries a pointer so adjusted that when the axis of the<br>
-soft iron magnet is at an angle of about 30&ordm; with the line joining
-the<br>
-poles of the electro-magnet the pointer will indicate zero.<br>
-<br>
-The soft iron armature is so massive that the magnetism induced in it is<br>
-proportional to the strength of the electro-magnet. Hence the couple<br>
-exerted by the electro-magnet on the pivoted armature will be<br>
-proportional to the square of the current.<br>
-<br>
-The armature is retained in place by a spiral spring lying in line with<br>
-its axis of rotation. The instrument is operated as a zero reading<br>
-instrument. The current is passed through it. The needle is deflected;<br>
-it is brought back to zero by turning a milled head which twists the<br>
-spring. The current will be proportional to the square root of the angle<br>
-of displacement of the milled head. A scale with index is provided,<br>
-giving directly the square roots of the angle over which the pointer is<br>
-moved.<br>
-<br>
-The same instrument is wound for use as a volt-meter.<br>
-<br>
-<br>
-27&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Eccentric Iron Disc.</span><br>
-This ammeter comprises a cylindrical electro-magnet excited by the<br>
-current to be measured. A disc of iron free to rotate is suspended on<br>
-pivots below it. A piece is cut off the disc at one part of its<br>
-periphery so as to give more metal to one side than to the other. In its<br>
-zero position this portion of the disc swings towards the magnet. As the<br>
-latter is more and more excited the other or more projecting portion of<br>
-the disc turns towards it, being attracted like an armature, and moves<br>
-against the force of gravity, the disc rotating. An index attached to<br>
-the disc swings over the face of a graduated scale. The disc is so<br>
-counterpoised that in its natural position the index points to zero.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Electro-magnetic.</span><br>
-An ammeter depending for its working upon the action of an<br>
-electro-magnet, which is excited by the current to be measured.<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Gravity.</span><br>
-An ammeter whose hand or index is drawn into the zero position by<br>
-gravity, and whose displacement therefrom is produced by the action of<br>
-the current to be measured.<br>
-<br>
-<br>
-<img style="width: 517px; height: 810px;" alt="" src="images/027F11.jpg"><br>
-Fig. 11. GRAVITY SOLENOID AMMETER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Magnetic Vane.</span><br>
-A fixed plate of soft iron is placed within a coil. Facing it is a<br>
-second disc free to move or swing on an axis. When the field is excited<br>
-the two repel each other because like polarity is induced in each, and<br>
-the motion of the movable disc indicates the strength of the current.<br>
-The same instrument is wound for high resistance and constitutes a<br>
-Magnetic Vane Voltmeter.<br>
-<br>
-<br>
-28&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Magnifying Spring.</span><br>
-A solenoid ammeter in which a spiral spring is used to convert the<br>
-longitudinal motion of the armature or movable core into a rotary motion<br>
-(see Ammeter, Ayrton's) and magnify the apparent range of motion.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ammeter, Permanent Magnet.</span><br>
-An ammeter with a magnetic field produced by a permanent magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Solenoid.</span><br>
-An ammeter in which the attraction, when a current is passing through<br>
-it, exerted by a hollow coil of wire upon an iron bar or tube in line<br>
-with its axis, is utilized to indicate the strength of current. The bar<br>
-is drawn into the coil to different extents proportional to the<br>
-attraction. As an example see Ammeter, Ayrton's, and cut of Gravity<br>
-Ammeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Spring.</span><br>
-An ammeter in which the part moved by the current is controlled or<br>
-brought to the zero position by a spring.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammeter, Steel Yard.</span><br>
-A solenoid ammeter in which the solenoid core is suspended vertically<br>
-from the short end of a steel yard fitted with a sliding weight. The<br>
-current passes through the solenoid coil and attracts or draws downwards<br>
-the coil. A sliding weight is moved in and out on the long steel-yard<br>
-arm which is graduated for amperes. In use the weight is slid out until<br>
-the arm is in equipose; the divisions give the amperes.<br>
-<br>
-<br>
-<img style="width: 638px; height: 387px;" alt="" src="images/028F12.jpg"><br>
-Fig. 12. STEEL YARD AMMETER.<br>
-<br>
-<br>
-29&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ammunition Hoist, Electric.</span><br>
-An apparatus for use on ships for hoisting ammunition to the guns by an<br>
-electric elevator. The characteristic feature of it is that a constant<br>
-motion of the switch or handle is required to keep it in action. If the<br>
-operator is shot so as to be incapacitated from taking charge of the<br>
-switch, the hoist stops until another is assigned to it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Amperage.</span><br>
-Current intensity expressed in amperes, as an amperage of ten amperes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere.</span><br>
-The practical unit of electric current strength. It is the measure of<br>
-the current produced by an electro-motive force of one volt through a<br>
-resistance of one ohm. In electric quantity it is the rate of one<br>
-coulomb per second. It is one-tenth the absolute C. G. S. unit of<br>
-current strength. Its best analogy is derived from water. Assuming the<br>
-electric current to be represented by a current of water, the pressure,<br>
-head, or descent producing such current would be the electro-motive<br>
-force. The current might be measured in gallons (or other unit) passed<br>
-per second. In the analogy these gallons would be coulombs. But it might<br>
-be measured by reference to a standard stream, as for instance, the<br>
-stream which would pass through a hole an inch square under a given<br>
-head, say six inches of water. This unit is the miner's inch, and is the<br>
-exact analogy of the ampere. A current of water may flow at the rate of<br>
-so many miner's inches, just as a current of electricity may flow at the<br>
-rate of so many amperes. In neither case it will be noted is there any<br>
-reference to time. "An ampere per second" is a redundant expression, and<br>
-means no more than "an ampere"; an "ampere-second," on the other hand,<br>
-is a coulomb. The number of coulombs passed per second gives the amperes<br>
-of current.<br>
-<br>
-For value of ampere, see Coulomb.<br>
-<br>
-[Transcriber's note: The SI definition of an ampere: A current in two<br>
-straight parallel conductors of infinite length and negligible<br>
-cross-section, 1 metre apart in vacuum, would produce a force equal to<br>
-2E-7 newton per metre of length.]<br>
-<br>
-<br>
-<img style="width: 644px; height: 450px;" alt="" src="images/029F13.jpg"><br>
-Fig. 13. THE MINER'S INCH AS AN ANALOGY FOR THE AMPERE.<br>
-<br>
-<br>
-30&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere, Arc.</span><br>
-A conductor bent into the arc of a circle, and employed in measuring the<br>
-electric current by the electric balance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-currents.</span><br>
-The currents assumed to be the cause of magnetism. (See Magnetism,<br>
-Ampere's Theory of.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-feet.</span><br>
-The product of amperes of current by the length, in feet, of a conductor<br>
-passing such current. It may be in empiric calculations of dynamo or<br>
-motor construction, but is little used. One ampere-foot is a current of<br>
-one ampere passing through one foot length of a conductor, or one-tenth<br>
-ampere through ten feet, and so on.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-hour.</span><br>
-The quantity of electricity passed by a current of one ampere in one<br>
-hour. It is used by electric power and lighting companies as the unit of<br>
-energy supplied by them, because they maintain a constant potential<br>
-difference in their leads, so that only the amperes and hours need<br>
-measuring or recording to give the energy, viz. : volt-ampere-hours.<br>
-The same unit is applied to batteries to indicate their potential<br>
-energy, because they also are assumed to be of constant voltage or<br>
-electro-motive force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-meters.</span><br>
-The product of amperes of current by the length, in meters, of a<br>
-conductor carrying such current. One ampere-meter is a current of one<br>
-ampere passing through one meter of a conductor.<br>
-<br>
-The term must not be confused with the identically spelled Ampere-meter,<br>
-a synonym for Ammeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-minute.</span><br>
-The quantity of electricity passed by a current of one ampere in one<br>
-minute; sixty coulombs.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere Ring.</span><br>
-A conductor forming a ring or circle used in electric balances for<br>
-measuring currents. (See Balance, Ampere.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-second.</span><br>
-The quantity of electricity passed by a current of one ampere in one<br>
-second; the coulomb, q. v.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Amperes, Lost.</span><br>
-In a shunt or compound-wound dynamo, part of the total amperes of<br>
-current produced in the armature coils go through the shunt, and hence,<br>
-do not appear in the outer circuit. S. P. Thompson has proposed the term<br>
-"lost amperes" for this portion of the current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere's Memoria Technica.</span><br>
-An expression of the effect of a current on a magnetic needle. If we<br>
-imagine the observer in the line of the current and facing the magnetic<br>
-needle, the current entering by his feet and leaving by his head, the<br>
-north pole is deflected to his left.<br>
-<br>
-<br>
-31&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-turns.</span><br>
-The amperes of current supplied to a magnet coil multiplied by the<br>
-number of turns the current makes in the coil. If the coil is wound two<br>
-or three in parallel, the virtual turns by which the amperes are<br>
-multiplied are one-half or one-third the actual turns of wire.<br>
-<br>
-Synonym--Ampere Windings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-turns, Primary.</span><br>
-The ampere-turns in the primary coil of an induction coil or<br>
-transformer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ampere-turns, Secondary.</span><br>
-The ampere-turns in the secondary coil of an induction coil or<br>
-transformer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Amplitude of Waves.</span><br>
-Waves are distinguished by length and amplitude. The latter, in the case<br>
-of transverse waves, such as those of water and of the ether, correspond<br>
-with and measure the height from lowest to highest point, or from valley<br>
-to summit of the waves in question. In the case of longitudinal waves,<br>
-such as those of the air, due to sounding bodies, the ratio of degree of<br>
-rarefaction to degree of condensation existing in the system is the<br>
-amplitude. The latter can be graphically represented by a sinuous line,<br>
-such as would represent the section of a transverse wave. Ether waves<br>
-are produced by heated bodies and by electro-magnetic impulses, as in<br>
-the discharge of the Leyden jar.<br>
-<br>
-The amplitude of a wave, other things being equal, is the measure of its<br>
-intensity. Thus, the louder a sound the greater is the amplitude of the<br>
-system of waves to which it is due. The same applies to ether waves,<br>
-whether they are perceived in the electro-magnetic, light, or<br>
-heat-giving modification. As the amplitude of ether waves cannot be<br>
-accurately known, amplitude is a relative term and is not stated<br>
-generally in any absolute unit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Analogous Pole.</span><br>
-One of the elements of a pyro-electric crystalline substance, such as<br>
-tourmaline. When heated, such bodies acquire electrical properties. If<br>
-of such crystalline form that they are differently modified at the ends<br>
-of their crystalline axis, by hemihedral modifications, the ends may be<br>
-differently affected. One end may show positive electricity when the<br>
-temperature is rising, and negative when falling. Such end is then<br>
-called the analogous pole. The opposite end presents, in such cases, the<br>
-opposite phenomena; becoming negative when the temperature is rising,<br>
-and becoming positive when it is falling; such end is called the<br>
-antilogous pole.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Analysis.</span><br>
-The determination of the elements of a case. It may be chemical, and<br>
-consist in finding what a substance consists of; it may be mathematical,<br>
-and consist in determining the unknown quantities in a problem; or it<br>
-may belong to other branches of science. The term has a very extended<br>
-application. Where the constituents are only determined in kind it is<br>
-called qualitative analysis; where their quantity or percentage is<br>
-ascertained it is called quantitative analysis.<br>
-<br>
-<br>
-32&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Analysis, Electric.</span><br>
-Chemical analysis by electrolytic methods. (See Electrolytic&nbsp;
-Analysis.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Analyzer, Electric.</span><br>
-An apparatus used in investigations on electric ether waves. It consists<br>
-of a series of parallel metallic wires. When the electric waves have<br>
-been polarized, the analyzer will only permit them to go through it<br>
-intact, when the plane of vibration of the waves is parallel to its<br>
-wires.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anelectrics.</span><br>
-(a) Bodies which do not become electrified by friction; a term<br>
-introduced by Gilbert, now little used, as all bodies develop<br>
-electricity under proper conditions by contact action; the reverse of<br>
-idioelectrtics.<br>
-<br>
-(b) Also a conductor of electricity, the reverse of a dielectric, q. v.<br>
-(See Conductor.)<br>
-<br>
-It will be seen that Gilbert's anelectrics were, after all, the same as<br>
-the modern anelectrics, i.e., conductors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anelectrotonus.</span><br>
-A term used in medical electricity or electro-therapeutics to indicate<br>
-the deceased functional activity induced in a nerve by the proximity of<br>
-the anode of an active electric circuit completed through the nerve. The<br>
-converse of Kathelectrotonus.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Angle of Declination.</span><br>
-The angle of error of the magnetic needle or compass, measuring the<br>
-extent of its deviation from the meridian in any locality. It is the<br>
-angle between the plane of the magnetic axis of a magnetic needle free<br>
-to take its natural position, and the geographical meridian, the needle<br>
-being counterpoised if necessary, so as to hold an absolutely horizontal<br>
-position. The deviation is expressed as being east or west, referring<br>
-always to the north pole. (See Magnetic Elements.)<br>
-<br>
-Synonym--Variation of the Compass.<br>
-<br>
-[Transcriber's note:&nbsp; See Agonic Line.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Angle of the Polar Span.</span><br>
-In a dynamo or motor the angle subtended by the portion of a pole piece<br>
-facing the armature, such angle being referred to the centre of the<br>
-cross-section of the armature as its centre.<br>
-<br>
-<br>
-33&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Angular Velocity.</span><br>
-The velocity of a body moving in a circular path, measured with<br>
-reference to the angle it passes over in one second multiplied by the<br>
-radius and divided by the time. A unit angle is taken (57&deg;.29578 =<br>
-57&deg; 17' 44".8 nearly) such that it is subtended by a portion of the<br>
-circumference equal in length to the radius. Hence, the circumference,<br>
-which is 360&deg;, is equal to 2*PI*unit angle, PI being equal to
-3.1416--.<br>
-"Unit angular velocity" is such as would in a circle of radius = 1<br>
-represent a path = 1, traversed in unit time = 1 second. If the radius<br>
-is r and the angle passed over is theta, the distance is proportional to<br>
-r*theta; if this distance is traversed in t seconds the angular velocity<br>
-is theta / t. The angular velocity, if it is multiplied by r, theta<br>
-expressing a distance, will give the linear velocity. The dimensions of<br>
-angular velocity are an angle (= arc / radius) / a Time = (L/L)/T =<br>
-(T^-1).<br>
-<br>
-The velocity expressed by the rate of an arc of a circle of unit radius,<br>
-which arc subtends an angle of 57&deg; 17' 44".8, such arc being
-traversed<br>
-in unit time, is unit angular velocity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Animal Electricity.</span><br>
-Electricity, notably of high tension, generated in the animal system, in<br>
-the Torpedo, Gymnotus and Silurus. The shocks given by these fish are<br>
-sometimes very severe. The gymnotus, or electric eel, was elaborately<br>
-investigated by Faraday. It has the power of voluntarily effecting this<br>
-discharge. There is undoubtedly some electricity in all animals. The<br>
-contact of the spinal column of a recently killed frog with the lumbar<br>
-muscles produces contraction, showing electric excitement. Currents can<br>
-be obtained from nerve and muscle, or from muscle sides and muscle cut<br>
-transversely, in each case one thing representing positive and the other<br>
-negative elements of a couple.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Angle of Inclination or Dip.</span><br>
-The angle which the magnetic axis of a magnet, which magnet is free to<br>
-move in the vertical plane of the magnetic meridian, makes with a<br>
-horizontal line intersecting such axis. To observe it a special<br>
-instrument, the dipping compass, inclination compass, dipping needle, or<br>
-dipping circle, as it is called, is used. (See Elements, Magnetic,<br>
---Dipping Needle,--Compass, Inclination.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Angle of Lag.</span><br>
-The angle expressing the displacement of the magnetic axis of the<br>
-armature core of a dynamo in the direction of its rotation. (See Lag.)<br>
-Lag is due to the motion of the armature core.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Angle of Lead.</span><br>
-The angle expressing the displacement in the direction of rotation of<br>
-the armature of a dynamo which has to be given the brushes to compensate<br>
-for the lag. (See Lag.) This is positive lead. In a motor the brushes<br>
-are set the other way, giving a negative angle of lead or angle of<br>
-negative lead.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anion.</span><br>
-The electro-negative element or radical of a molecule, such as oxygen,<br>
-chlorine or the radical sulphion. (See Ions.) It is the portion which<br>
-goes to the anode, q.v., in electrolytic decomposition.<br>
-<br>
-<br>
-34&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anisotropic. (adj.)</span><br>
-Unequal in physical properties, as in conduction and specific inductive<br>
-capacity, along various axes or directions. An anisotropic conductor is<br>
-one whose conductivity varies according to the direction of the current,<br>
-each axis of crystallization in a crystalline body marking a direction<br>
-of different conductivity. An anisotropic medium is one varying in like<br>
-manner with regard to its specific inductive capacity. In magnetism an<br>
-anisotropic substance is one having different susceptibilities to<br>
-magnetism in different directions. The term is applicable to other than<br>
-electric or magnetic subjects.<br>
-<br>
-Synonym--AEolotropic.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Annealing, Electric.</span><br>
-Annealing by the heat produced by the passage of the electric current<br>
-through the body to be annealed. The object is clamped or otherwise<br>
-brought into a circuit, and a current strong enough to heat it to<br>
-redness, or to the desired temperature is passed through it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Annunciator.</span><br>
-An apparatus for announcing a call from any place to another, as from a<br>
-living-room to an office in a hotel, or for announcing the entering of<br>
-any given room or window in a building protected by a burglar alarm.<br>
-<br>
-A usual system comprises for each annunciator an electro-magnet. Its<br>
-armature is normally held away from its poles by a spring, and when in<br>
-that position a latch connected to the armature holds a little shutter.<br>
-When by a push-button or other device a current is sent through a<br>
-circuit which includes the electro-magnet the armature is attracted,<br>
-this releases the latch and the shutter drops. In dropping it displays a<br>
-number, letter or inscription which indicates the locality of the<br>
-push-button or other circuit-closing device. Often annunciators are<br>
-connected in circuit with a bell.<br>
-<br>
-<br>
-<img style="width: 581px; height: 617px;" alt="" src="images/034F14.jpg"><br>
-Fig. 14. ANNUNCIATOR.<br>
-<br>
-<br>
-35&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Annunciator Clock.</span><br>
-A clock operating an annunciator by making contact at determined times.<br>
-<br>
-<span style="font-weight: bold;">Annunciator Drop.</span><br>
-The little shutter which is dropped by some forms of annunciators, and<br>
-whose fall discloses a number, character or inscription, indicating<br>
-whence the call was sent.<br>
-<br>
-<br>
-<img style="width: 576px; height: 702px;" alt="" src="images/035F15.jpg"><br>
-Fig. 15. DROP ANNUNCIATOR.<br>
-<br>
-<br>
-<img style="width: 665px; height: 418px;" alt="" src="images/035F16.jpg"><br>
-Fig. 16. ANNUNCIATOR DETACHING MECHANISM.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Annunciator, Gravity Drop.</span><br>
-An annunciator whose operations release shutters which fall by gravity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Annunciator, Needle.</span><br>
-A needle annunciator is one whose indications are given by the movements<br>
-of needles, of which there is usually a separate one for each place of<br>
-calling.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Annunciator, Swinging or Pendulum.</span><br>
-An annunciator which gives its indications by displacing from its<br>
-vertical position a pendulum or vertically suspended arm.<br>
-<br>
-<br>
-36&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anodal Diffusion.</span><br>
-A term in electro-therapeutics; the introduction of a medicine into the<br>
-animal system by using a sponge-anode saturated with the solution of the<br>
-drug in question. On passing a current the desired result is secured by<br>
-cataphoresis, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anode.</span><br>
-The positive terminal in a broken metallic or true conducting circuit;<br>
-the terminal connected to the carbon plate of a galvanic battery or to<br>
-its equivalent in case of any other generator. In general practice it is<br>
-restricted to the positive terminal in a decomposition or electrolytic<br>
-cell, such as the nickel anode in a nickel-plating bath or the anode of<br>
-platinum in a gas voltameter. It is the terminal out of or from which<br>
-the current is supposed to flow through the decomposition cell. In<br>
-electro-therapeutics the term is used simply to indicate the positive<br>
-terminal. In an electrolytic cell the electro-negative substance or<br>
-anion goes to the anode. Hence, it is the one dissolved, if either are<br>
-attacked. The nickel, copper or silver anodes of the electroplater<br>
-dissolve in use and keep up the strength of the bath. The platinum anode<br>
-in a gas voltameter is unattacked because the anion cannot act upon it<br>
-chemically.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anodic Closure Contraction.</span><br>
-A physiological change in a living subject produced by the closing of<br>
-the electric current; the muscular contraction which takes place beneath<br>
-the anode applied to the surface of the body when the circuit is closed,<br>
-the kathode being applied elsewhere; it is due, presumably, to direct<br>
-action on the motor nerve. It is a term in electro-therapeutics. It is<br>
-the converse of anodic opening contraction, q. v. An abbreviation A. C.<br>
-C. is often used to designate it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anodic Duration Contraction.</span><br>
-A term in electro-therapeutics. On the opening or closing of an electric<br>
-circuit, the anode of which is placed over a muscle, a contraction is<br>
-observed (see Anodic Closure Contraction--Anodic Opening Contraction).<br>
-The above term is used to designate the duration of such contraction. An<br>
-abbreviation A. D. C. is often used to designate it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anodic Opening Contraction.</span><br>
-The converse of Anodic Closure Contraction, q. v.; it is the contraction<br>
-of living muscle beneath or near the anode where the circuit, including<br>
-such anode and the body in its course, is closed; a physiological<br>
-phenomenon observed in electro-therapeutics to which branch of science<br>
-the term belongs. An abbreviation A. O. C. is often used to designate<br>
-it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anodic Reactions.</span><br>
-A term in electro-therapeutics; the diagnosis of disease by the actions<br>
-of the tissue near the anode of a circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anti-Induction Conductor.</span><br>
-A conductor constructed to avoid induction effects in the conducting<br>
-element. Many kinds have been made. A tubular metal shield or envelope<br>
-which may be grounded will protect an enclosed conductor to some extent.<br>
-Or the conductor may be a double wire twisted around itself, one branch<br>
-being used for the regular and the other for the return circuit, thus<br>
-constituting a closed metallic circuit. The inductive effects are due to<br>
-interrupted or varying currents in neighboring wires and circuits. Many<br>
-anti-induction conductors have been invented and patented.<br>
-<br>
-<br>
-37&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Anti-magnetic Shield.</span><br>
-In general terms a hollow screen of soft iron designed to protect any<br>
-mass of steel behind or enclosed by it from magnetization by any magnet<br>
-near it, such as a dynamo field magnet. This it does by concentrating<br>
-the lines of force within its own mass, so that the space within it or<br>
-enclosed by it is comparatively free from lines of force. It is often<br>
-applied to watches, and is virtually an iron case in which they are<br>
-enclosed.<br>
-<br>
-<span style="font-weight: bold;">Antimony.</span><br>
-A metal, one of the elements, atomic weight, 122:<br>
-equivalent, 40.6 and 24.4; valency, 3 and 5;<br>
-specific gravity, 6.8.<br>
-It is a conductor of electricity.<br>
-<small><span style="font-family: monospace;">Relative resistance,
-compressed (silver = 1), 23.60</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Specific resistance,&nbsp;&nbsp;
-35.50 microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a wire,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(a) 1 foot long, weighing 1
-grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.418 ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">(b) 1 foot long, 1/1000 inch
-thick,&nbsp;&nbsp;&nbsp;
-213.6&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(c) 1 meter long, weighing 1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.384&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">(d) 1 meter long. 1 millimeter
-thick,&nbsp;&nbsp;&nbsp; 0.4521&nbsp; "</span></small><br>
-<br>
-Resistance of a 1-inch cube,&nbsp;&nbsp; 13.98 microhms.<br>
-<br>
-Approximate percentage resistance per degree C.<br>
-(1.8&ordm; F. at 20&ordm; C. 88&ordm; F.)&nbsp;&nbsp; 0.389 per cent.<br>
-<br>
-Elcctro-chemical equivalent (hydrogen = .0105)&nbsp; .2560<br>
-(See Thermo-Electric Series.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Anvil.</span><br>
-An intermittent contact, or "make and break" of the current is sometimes<br>
-produced by directly pressing a key down upon a metallic surface, the<br>
-two being terminals of the circuit. The surface or stud on which such<br>
-pressure is produced is called the anvil. The ordinary telegraph key,<br>
-which makes a contact by the pressure of the operator's fingers does it<br>
-by making a contact between a contact piece upon the front end of the<br>
-key and the anvil. In the induction coil the anvil is also found. Thus<br>
-in the cut representing the end of an induction coil and its circuit<br>
-breaker in which O and O' and P and P' represent the secondary circuit<br>
-terminal connections A is the core of soft iron wires, h is the anvil;<br>
-the hammer when resting upon it so as to be in contact closes the<br>
-circuit. When the current coming from the primary to the post i, passes<br>
-through the hammer and anvil h, and emerges by m, it magnetizes the<br>
-core; this attracts the hammer, which is made of or is armed with a mass<br>
-of iron. This breaks the circuit. The hammer falls at once on the anvil,<br>
-again making the circuit, and the action is repeated with great<br>
-rapidity. Hammer and anvil or key and anvil connections should be made<br>
-of platinum.<br>
-<br>
-<br>
-<img style="width: 619px; height: 507px;" alt="" src="images/038F17.jpg"><br>
-Fig. 17. INDUCTION COIL CIRCUIT BREAKER.<br>
-<br>
-<br>
-38&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">A. O. C.</span><br>
-Abbreviation for Anodic Opening Contraction, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Aperiodic. adj.</span><br>
-In an oscillating apparatus, or in the oscillating member of apparatus,<br>
-the fact of having no reference to time of vibration; dead-beat.<br>
-<br>
-Synonym. Dead-beat.<br>
-<br>
-<br>
-39&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 627px; height: 429px;" alt="" src="images/038F18.jpg"><br>
-Fig. 18. ARAGO'S DISC.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Arago's Disc.</span><br>
-An apparatus consisting of a disc of copper mounted horizontally, or on<br>
-a vertical spindle, and so arranged as to be susceptible of rapid<br>
-rotation. Immediately over it, and best with a pane of glass<br>
-intervening, a magnetic needle is mounted on a pivot directly over the<br>
-axis of the disc. If the disc is rotated the lines of force of the<br>
-magnet are cut by it, and consequently currents are produced in the<br>
-copper. These currents act upon the needle and cause it to rotate,<br>
-although quite disconnected. It is advisable for the needle to be strong<br>
-and close to the disc, which should rotate rapidly.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Arc v.</span><br>
-To form a voltaic arc.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Arc, Compound.</span><br>
-A voltaic arc springing across between more than two electrodes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Arc, Metallic.</span><br>
-The voltaic arc produced between terminals or electrodes of metal. The<br>
-characteristics of such arc as contrasted with the more usual arc<br>
-between carbon electrodes are its greater length for the same<br>
-expenditure of energy, its flaming character and characteristic colors<br>
-due to the metals employed. It is sometimes, for the latter reason, used<br>
-in spectroscopic investigations.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Arc Micrometer.</span><br>
-A micrometer for measuring the distance between the electrodes of a<br>
-voltaic arc.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Arc, Simple.</span><br>
-A voltaic arc produced, as usual, between only two electrodes.<br>
-<br>
-<br>
-40&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Arc, Voltaic.</span><br>
-The voltaic arc is the arc between two carbon electrodes slightly<br>
-separated, which is produced by a current of sufficient strength and<br>
-involving sufficient potential difference. The pencils of carbon are<br>
-made terminals in a circuit. They are first placed in contact and after<br>
-the current is established they are separated a little. The current now<br>
-seems to jump across the interval in what sometimes appears an arch of<br>
-light. At the same time the carbon ends become incandescent. As regards<br>
-the distance of separation with a strong current and high electro-motive<br>
-force, the arc may be several inches long.<br>
-<br>
-The voltaic arc is the source of the most intense heat and brightest<br>
-light producible by man. The light is due principally to the<br>
-incandescence of the ends of the carbon pencils. These are differently<br>
-affected. The positive carbon wears away and becomes roughly cupped or<br>
-hollowed; the negative also wears away, but in some cases seems to have<br>
-additions made to it by carbon from the positive pole. All this is best<br>
-seen when the rods are slender compared to the length of the arc.<br>
-<br>
-It is undoubtedly the transferred carbon dust which has much to do with<br>
-its formation. The conductivity of the intervening air is due partly,<br>
-perhaps, to this, but undoubtedly in great measure to the intense<br>
-heating to which it is subject. But the coefficient of resistance of the<br>
-intervening air is so much higher than that of any other part of the<br>
-circuit that an intense localization of resistance occurs with<br>
-corresponding localization of heating effect. This is the cause of the<br>
-intense light. Thus if the carbons are but 1/32 of an inch apart as in a<br>
-commercial lamp the resistance may be 1.5 ohms. The poor thermal<br>
-conductivity of the carbon favors the concentration of heat also. The<br>
-apparent resistance is too great to be accounted for by the ohmic<br>
-resistance of the interposed air. A kind of thermoelectric effect is<br>
-produced. The positive carbon has a temperature of about 4,000&deg; C.<br>
-(7,232&deg; F.), the negative from 3,000&deg; C. (5,432&deg; F.) to
-3,500&deg; C.<br>
-(6,322&deg; F.). This difference of temperature produces a<br>
-counter-electro-motive force which acts to virtually increase the<br>
-resistance of the arc. The carbon ends of an arc can be projected with<br>
-the lantern. Globules are seen upon them due to melted silica from the<br>
-arc of the carbon.<br>
-<br>
-<br>
-</big></big><big><big><img style="width: 708px; height: 655px;" alt=""
- src="images/040F19.jpg"></big></big><br>
-<big><big>Fig. 19. EXPERIMENTAL APPARATUS FOR PRODUCING THE VOLTAIC ARC.<br>
-<br>
-<br>
-41&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Areometer.</span><br>
-An instrument for determining the specific gravity of a fluid. It<br>
-consists of an elongated body ballasted so as to float vertically and<br>
-provided with a mark or a scale. It floats deeper in a light than in a<br>
-heavy liquid. If it carries but one mark weights are added until that<br>
-mark is reached, when the weights required give the specific gravity. Or<br>
-the scale may give the reading directly based upon the depth to which it<br>
-sinks. Areometers are often made of glass, ballasted with shot or<br>
-mercury enclosed in their bottom bulb as shown. They are used in<br>
-regulating battery solutions, and in watching the charging and<br>
-discharging of storage batteries.<br>
-<br>
-<br>
-<img style="width: 103px; height: 629px;" alt="" src="images/041F20.jpg"><br>
-Fig. 20. AREOMETER<br>
-<br>
-<br>
-<img style="width: 86px; height: 621px;" alt="" src="images/041F21.jpg"><br>
-Fig. 21. BEAD AREOMETER<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Areometer, Bead.</span><br>
-A tube of glass containing beads of different specific gravities. It has<br>
-apertures at top and bottom. When immersed in a liquid, the same fills<br>
-it, and the specific gravity within certain limits, depending on the<br>
-factors of the beads, is shown by the beads which float and those which<br>
-sink. It is used for storage batteries and other purposes where acids<br>
-and solutions have to be tested.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Argyrometry.</span><br>
-The method of ascertaining the weight and inferentially the thickness of<br>
-an electroplater's deposit of silver. It is done by weighing the article<br>
-before and after plating.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Arm.</span><br>
-The four members of a Wheatstone bridge, q. v., are termed its arms.<br>
-Referring to the diagram of a bridge, P, Q, R, S, are the arms.<br>
-<br>
-<br>
-<img style="width: 454px; height: 594px;" alt="" src="images/041F22.jpg"><br>
-Fig. 22. DIAGRAM OF WHEATSTONE'S BRIDGE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature.</span><br>
-(a.) A mass or piece of iron or steel, or a collection of pieces of iron<br>
-designed to be acted on by a magnet. While nickel or cobalt might be<br>
-used, they rarely or never are except in experimental apparatus. The<br>
-armature of a permanent horse shoe magnet is simply a little bar of soft<br>
-iron. When the magnet is not in use it is kept in contact with the poles<br>
-with the idea of retaining its magnetism. It is then said to be used as<br>
-a keeper. A bar magnet does not generally have an armature. The armature<br>
-is also used to exhibit the attraction of the magnet.<br>
-<br>
-Sometimes an armature is made of steel and is permanently magnetized.<br>
-Such an armature, termed a polarized armature, is repelled when its like<br>
-poles are opposed to like poles of the magnet and otherwise is attracted<br>
-with force due to the sums of the magnetism. If the magnet is<br>
-sufficiently powerful depolarization of the armature may ensue when like<br>
-poles are opposed to like poles. Polarized armatures are used in various<br>
-appliances, magneto generators, telegraphic instruments and others.<br>
-<br>
-(b) In a dynamo or Motor the mass of laminated iron or of wire which<br>
-carries the coils of insulated wires which are caused to rotate in the<br>
-field of force of the field magnets in order to establish and maintain<br>
-potential difference with its accompanying current, or which rotates<br>
-under the effects of a current in a motor. (See Dynamo Electric<br>
-Generator.)<br>
-<br>
-The work of the armature core is twofold. It acts as a portion of the<br>
-magnetic circuit, conducting the lines of force, and by virtue of its<br>
-high permeability or multiplying power concentrating a number of the<br>
-lines of force through its own substance. To enable it to act with<br>
-efficiency in this direction it should be made of iron of the highest<br>
-permeability, and should approach as closely as possible to the armature<br>
-cores consistent with leaving space for the wire winding. It next acts<br>
-as a support for the wires which are to be swept through the field of<br>
-force. Thus it acts both to establish a strong field and then acts as a<br>
-carrier for the wires which are to be cut by the wires in question. In<br>
-connection with this subject the different definitions under Armature,<br>
-Dynamo, Commutator, Induction and similar topics may be consulted.<br>
-<br>
-(c) See Armature of Influence Machine.<br>
-<br>
-(d) See Armature of Leyden Jar or Static Condenser.<br>
-<br>
-<br>
-42&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Bar.</span><br>
-An armature in a dynamo or motor whose winding is made up of conductors<br>
-in the form of bars, round, rectangular and of other sections. This type<br>
-of armature conductor is objectionable as Foucault currents are produced<br>
-in it. It is found best to laminate or subdivide low resistance armature<br>
-windings.<br>
-<br>
-[Transcriber's Note: Foucault currents are also called eddy currents.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Bipolar.</span><br>
-An armature in which two poles are induced by the field. A bipolar field<br>
-magnet produces a bipolar armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature Bore.</span><br>
-The cylindrical space defined by the pole pieces of a dynamo or motor<br>
-within which the armature rotates.<br>
-<br>
-Synonym--Armature Chamber.<br>
-<br>
-<br>
-43&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Armature, Closed Coil.</span><br>
-An armature for a motor or dynamo, the ends of all of whose coils are<br>
-united, so as to be in one closed circuit all the way around.<br>
-<br>
-<br>
-<img style="width: 607px; height: 377px;" alt="" src="images/043F23.jpg"><br>
-Fig. 23. CLOSED COIL GRAMME RING ARMATURE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature Coil, or Coils.</span><br>
-The insulated wire wound around the core of the armature of an electric<br>
-current generator or motor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature Core.</span><br>
-The central mass of iron on which the insulated wire, to be rotated in<br>
-the field of an electric current generator or motor, is wound. (See<br>
-Dynamo-electric Machine and Motor, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Cylinder.</span><br>
-An armature of the Gramme ring type, but longer in the axial direction,<br>
-so that its core resembles a long hollow cylinder, the wire being wound<br>
-inside and outside as in the Gramme ring. (See Gramme Ring.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Disc.</span><br>
-(a) An armature of a dynamo electric machine or motor in which the coils<br>
-are wound so as to be flat and are carried on the face of a disc forming<br>
-the core or part of the core of the armature. S. P. Thompson treats it<br>
-as a modified drum armature extended radially, the outer periphery<br>
-corresponding to the back end of the drum. The poles of the field are<br>
-generally placed to face the side or sides of the disc.<br>
-<br>
-(b) Another type of disc armature has its wire wound on bobbins arranged<br>
-around the periphery of a disc.<br>
-<br>
-In disc armatures there is often no iron core, their thinness enabling<br>
-this to be dispensed with.<br>
-<br>
-<br>
-44&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 676px; height: 746px;" alt="" src="images/044F24.jpg"><br>
-Fig. 24. DISC ARMATURE OF FRITSCHE MACHINE.<br>
-<br>
-<br>
-<img style="width: 772px; height: 728px;" alt="" src="images/044F25.jpg"><br>
-Fig. 25. PLAN OF WINDING PACINOTTI'S DISC ARMATURE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Discoidal Ring.</span><br>
-In a dynamo an armature of the shape of a ring of considerable radial<br>
-depth of section as compared to its axial depth. It is generally made of<br>
-iron ribbon or thin band wound to the proper size.<br>
-<br>
-Synonym--Flat Ring Armature.<br>
-<br>
-<br>
-45 STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Drum.</span><br>
-An armature for a dynamo or motor, consisting of a cylinder of iron<br>
-preferably made up of discs insulated from each other by thin shellacked<br>
-paper, or simply by their oxidized surfaces, and wound with wire<br>
-parallel to the axis where it lies on the cylindrical periphery and<br>
-crossing the heads approximately parallel to the diameter. It operates<br>
-practically on the same principle as a Gramme Ring Armature. (See Gramme<br>
-Ring.)<br>
-<br>
-Synonym--Cylindrical Armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature Factor.</span><br>
-The number of conductors on an armature, counted or enumerated all<br>
-around its external periphery.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Armature, Hinged.</span><br>
-An armature pivoted to the end of one of the legs of an electro-magnet<br>
-so as to be free to swing and bring its other end down upon the other<br>
-pole.<br>
-<br>
-<br>
-<img style="width: 664px; height: 383px;" alt="" src="images/045F26.jpg"><br>
-Fig. 26. HINGED ARMATURES OF CLUB-FOOT ELECTRO MAGNETS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Hole.</span><br>
-An armature whose core is perforated to secure cooling.<br>
-<br>
-Synonym--perforated Armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Intensity.</span><br>
-An armature wound for high electro-motive force. A term little used at<br>
-the present time.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature Interference.</span><br>
-A limit to the ampere turns permissible on a given armature is found in<br>
-the increase of cross magnetizing effect, q. v., the increased lead<br>
-necessitated, and the growth of the demagnetizing power. All such<br>
-perturbing effects are sometimes expressed as armature interference.<br>
-<br>
-<br>
-46&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Load of.</span><br>
-The circumflux, q. v., of the armature, or the ampere turns of the same.<br>
-The maximum load which can be carried by an armature without sparking is<br>
-directly proportional to the radial depth of core and to the length of<br>
-the gap, and inversely proportional to the breadth of the polar span.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Multipolar.</span><br>
-An armature in which a number of poles greater than two is determined by<br>
-the field. A multipolar field is employed for its production.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Neutral.</span><br>
-An armature of a magnet or telegraph relay which is not polarized or<br>
-magnetized.<br>
-<br>
-Synonym--Non-polarized Armature--Neutral Relay Armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature of Influence Machine.</span><br>
-Pieces of paper pasted on the stationary plate of an electric machine of<br>
-the Holtz type.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature of Leyden Jar or Static
-Condenser.</span><br>
-The inner and outer tin-foil coatings of a Leyden jar or other<br>
-condenser.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Armature, Open Coil.</span><br>
-An armature of a dynamo or motor on which the coils are not joined in<br>
-one closed circuit, but have their ends or some of them separated, and<br>
-connected each to its own commutator bar or each set to their own bar.<br>
-<br>
-<br>
-<img style="width: 517px; height: 401px;" alt="" src="images/046F27.jpg"><br>
-Fig. 27. OPEN COIL RING ARMATURE.<br>
-<br>
-<br>
-47&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Pivoted.</span><br>
-An armature for an electro-magnet mounted on a pivot, which is at right<br>
-angles to the yoke or parallel with the legs of the magnet, so as to be<br>
-free to rotate. When the magnet is excited the armature is drawn into<br>
-line or approximately so with its base or yoke. The system is used in<br>
-some telegraph apparatus.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Armature Pockets.</span><br>
-Spaces or recesses in armatures provided for the reception of the coils.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Polarized.</span><br>
-An armature made of steel or having a steel core to which permanent<br>
-magnetism has been imparted. Such are used in some forms of magneto<br>
-current generators, and in telegraphic instruments. (See Relay,<br>
-Polarized.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Pole.</span><br>
-An armature having coils wound on separate poles projecting radially all<br>
-around the periphery of its central hub or disc, or projecting<br>
-internally from a ring-like frame, their ends facing the field magnet.<br>
-<br>
-Synonym--Radial Armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Quantity.</span><br>
-An armature of a dynamo or motor wound for current of large quantity.<br>
-The term is now but little used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature-Reactions.</span><br>
-When an armature is running in an active dynamo a series of<br>
-reactions is established, the more important of which are:<br>
-I. A tendency to cross-magnetize the armature.<br>
-II. A tendency to spark at the brushes.<br>
-III. A tendency for the armature current to demagnetize on account of<br>
-the lead which has to be given to the brushes.<br>
-IV. Variations in the neutral points as more or less current is taken<br>
-from the machine.<br>
-V. Heating of armature, both core and conductors, and of pole pieces,<br>
-which heating is due to Foucault currents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Revolving, Page's.</span><br>
-An early form of motor. The field is produced by a permanent magnet.<br>
-Above its poles is a soft iron armature wound with a coil of insulated<br>
-wire. A two-part commutator with contact springs conveys the current to<br>
-the coil. The whole is so arranged that the polarity of the armature, as<br>
-induced by the coil, through which a current is passed, is reversed as<br>
-its ends sweep by the poles of the magnet. Then it is repelled from the<br>
-poles and swings through 180&deg; to have its polarity reversed and to
-go<br>
-through the next 180&deg;, and so on. Thus it rotates at a very high
-rate of<br>
-speed.<br>
-<br>
-In the cut showing the elevation A, B, is the armature;&nbsp; f, g, the<br>
-springs or brushes; h, the commutator with its sections o, i. In the<br>
-section of the commutator W, W, designate the springs or brushes, A, the<br>
-vertical spindle carrying the armature and commutator, and S, S, the<br>
-commutator sections.<br>
-<br>
-<br>
-48&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 516px; height: 718px;" alt=""
- src="images/048F28_29.jpg"><br>
-Fig. 28. PAGE'S REVOLVING ARMATURE.<br>
-<br>
-Fig. 29. SECTION OF COMMUTATOR OF PAGE'S REVOLVING ARMATURE.<br>
-W, W, Brushes; A, Spindle; S, S, Armature Segments.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Ring.</span><br>
-An armature whose core is in the shape of a ring, as the Gramme Ring<br>
-Armature. (See Figs. 23 &amp; 27.)<br>
-<br>
-<br>
-49&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Rolling.</span><br>
-(a) An armature for a permanent horseshoe magnet consisting of a<br>
-straight cylinder of soft iron on which a heavy wheel is mounted. When<br>
-the legs of the magnet are inclined downward and the bar is laid across<br>
-them it rolls down to the poles, across their ends, and back up the<br>
-under side. It is merely a magnetic toy or illustrative experiment.<br>
-<br>
-Synonym--Wheel Armature.<br>
-<br>
-(b) Another form consists of little bars of iron with brass discs<br>
-attached to the ends. On placing two of these together and bringing the<br>
-poles of a magnet near them, as shown, they become magnetized with like<br>
-polarity by induction and repel each other, rolling away in opposite<br>
-directions.<br>
-<br>
-<br>
-<img style="width: 328px; height: 756px;" alt="" src="images/049F30.jpg"><br>
-Fig. 30. ROLLING OR WHEEL ARMATURE.<br>
-<br>
-<br>
-<img style="width: 358px; height: 582px;" alt="" src="images/049F31.jpg"><br>
-Fig. 31. ROLLING ARMATURES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Shuttle.</span><br>
-The original Siemens' armature, now discarded. The core was long and<br>
-narrow, and its cross section was nearly of the section of an H. The<br>
-grooves were wound full of wire, so that the whole formed almost a<br>
-perfect cylinder, long and narrow comparatively. (See Winding Shuttle.)<br>
-<br>
-Synonym--Siemens' Old Armature--Girder Armature--H Armature.<br>
-<br>
-<br>
-<img style="width: 679px; height: 171px;" alt="" src="images/049F32.jpg"><br>
-Fig. 32. SHUTTLE OR H ARMATURE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Spherical.</span><br>
-An armature of a dynamo which is wound on a spherical core, so as to be<br>
-almost a sphere. It is employed in the Thomson-Houston dynamo, being<br>
-enclosed in a cavity nearly fitting it, formed by the pole pieces.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Stranded Conductor.</span><br>
-A substitute for bar-armatures in which stranded copper wire conductors<br>
-are substituted for the solid bar conductors, to avoid Foucault<br>
-currents. (See Armature, Bar.)<br>
-<br>
-<br>
-50&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armature, Unipolar.</span><br>
-An armature of a unipolar dynamo. (See Dynamo Unipolar.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Armor of Cable.</span><br>
-The metal covering, often of heavy wire, surrounding a telegraph or<br>
-electric cable subjected to severe usage, as in submarine cables.<br>
-<br>
-Synonym--Armature of Cable.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Arm, Rocker.</span><br>
-An arm extending from a rocker of a dynamo or motor, to which arm one of<br>
-the brushes is attached. (See Rocker.) Ordinarily there are two arms,<br>
-one for each brush.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Articulate Speech.</span><br>
-Speech involving the sounds of words. It is a definition which has<br>
-acquired importance in the Bell telephone litigations, one contention,<br>
-concerning the Bell telephone patent, holding that the patentee did not<br>
-intend his telephone to transmit articulations, but only sound and<br>
-music.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Astatic. adj.</span><br>
-Having no magnetic directive tendency due to the earth's magnetism.<br>
-Examples are given under Astatic Needle; Circuit, Astatic; and<br>
-Galvanometer Astatic.<br>
-<br>
-<br>
-<img style="width: 579px; height: 515px;" alt="" src="images/050F33.jpg"><br>
-Fig. 33. NOBILI'S PAIR.<br>
-<br>
-<br>
-<img style="width: 407px; height: 390px;" alt="" src="images/051F34.jpg"><br>
-FIG. 34. VERTICAL PAIR ASTATIC COMBINATION.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Astatic Needle. </span><br>
-A combination of two magnetic needles so adjusted as to<br>
-have as slight directive tendency as possible. Such a pair of needles<br>
-when poised or suspended will hardly tend to turn more to one point of<br>
-the compass than another. The combination is generally made up of two<br>
-needles arranged one above the other, with their poles in opposite<br>
-directions. This combination is usually called Nobili's pair. If of<br>
-equal strength and with parallel magnetic axes of equal length they<br>
-would be astatic. In practice this is very rarely the case. A resultant<br>
-axis is generally to be found which may even be at right angles to the<br>
-long axis of the magnets, causing them to point east and west. Such a<br>
-compound needle requires very little force to turn it one way or the<br>
-other. If one of the needles is placed within a coil of insulated wire a<br>
-feeble current will act almost as strongly to deflect the system as if<br>
-the other was absent, and the deflection will only be resisted by the<br>
-slight directive tendency of the pair of needles. This is the basis of<br>
-construction of the astatic galvanometer. Sometimes coils wound in<br>
-opposite directions and connected in series, or one following the other,<br>
-surround both needles, thus producing a still greater effect of<br>
-deflection.<br>
-<br>
-Other astatic needles are shown in the cuts below. [Figures 33 to 35.]<br>
-<br>
-<br>
-51&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 314px; height: 519px;" alt="" src="images/051F35.jpg"><br>
-FIG. 35. SIMPLE ASTATIC NEEDLE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Asymptote</span>.<br>
-A line continuously approached by a curve, but which the curve, owing to<br>
-its construction or nature of curvature, can never touch, be tangent to,<br>
-or intersect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atmosphere.</span><br>
-(a) A term applied to the atmospheric pressure as a practical unit of<br>
-pressure equal to 15 lbs. to the square inch as generally taken. It is<br>
-really about 14.7 lbs. per square inch, or 1,033 grams per square<br>
-centimeter.<br>
-<br>
-(b) Air, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atmosphere Residual.</span><br>
-The atmosphere left in a vessel after exhaustion. The term may be<br>
-applied to any gas. In an incandescent lamp after flashing the residual<br>
-atmosphere consists of hydro-carbons.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atmospheric Electricity.</span><br>
-The electricity of the atmosphere, rarely absent, but often changing in<br>
-amount and sign. Benjamin Franklin, in a memoir published in 1749,<br>
-indicated the method of drawing electricity from the clouds by pointed<br>
-conductors. In June, 1752, he flew a kite and by its moistened cord drew<br>
-an electric spark from the clouds, confirming his hypothesis that<br>
-lightning was identical with the disruptive discharge of electricity. To<br>
-observe electricity in fine weather a gold-leaf or other electroscope<br>
-may be connected to the end of a long pointed insulated conductor. The<br>
-electricity during thunderstorms can be shown by a similar arrangement,<br>
-or burning alcohol or tinder gives an ascending current of warm air that<br>
-acts as a conductor. Quite elaborate apparatus for observing and<br>
-recording it have been devised. Atmospheric electricity is usually<br>
-positive, but occasionally negative. When the sky is cloudless it is<br>
-always positive, increasing with the elevation and isolation of the<br>
-place. In houses, streets, and under trees no positive electricity can<br>
-be found. In the Isle of Arran, Scotland, a rise of 24 to 48 volts per<br>
-foot of increase in elevation was found by Sir William Thomson. At<br>
-sunrise the electrification of the air is feeble, it increases towards<br>
-noon and decreases again to reach a second maximum a few hours after<br>
-sunset. It increases with the barometric pressure generally. In cloudy<br>
-weather it is sometimes negative and the sign often changes several<br>
-times in the same day. In a thunderstorm the changes in sign and<br>
-potential are very rapid. The cause of atmospheric electricity is far<br>
-from clear. Tait attributes it to a contact effect between air and water<br>
-vapor, Solmeke to friction of water vesicles against ice particles in<br>
-the upper atmosphere, he first showing that the two may coexist. The<br>
-cause of the enormous increase of potential producing lightning is<br>
-attributed to the decreased capacity due to the change of water from<br>
-cloud vesicles to drops, thus diminishing the electrostatic capacity of<br>
-the water in question. (See Lightning.)<br>
-<br>
-<br>
-52&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atom.</span><br>
-The ultimate particle or division of an elementary substance; the<br>
-smallest part that can exist in combination, and one which cannot exist<br>
-alone. An elementary substance is composed of molecules just as truly as<br>
-a compound one, but the atoms in the molecule of an elementary substance<br>
-are all precisely alike. Hence atoms are the units of chemistry, they<br>
-have to do with combinations, but the physical unit, the smallest<br>
-particle of matter that can have an independent existence, is the<br>
-molecule. The two are often confounded, especially by writers of a few<br>
-years ago, so that by "atom" the molecule is often meant. There is<br>
-nothing to be said of their size or mass. All such calculations refer to<br>
-the molecule, q. v., often spoken of and called the atom.<br>
-<br>
-[Transcriber's note: Yet to be discovered: electron--1897 (5 years),<br>
-proton--1920 (28 years), neutron--1932 (30 years), quark--1961 (69
-years).]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atomic Attraction.</span><br>
-The attraction of atoms for each other, in virtue of which they combine<br>
-into molecules; chemical affinity, q. v., treats principally of this,<br>
-although molecular attraction also plays a part in it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atomic Heat.</span><br>
-The product of the atomic weight of a substance by its specific heat.<br>
-This product is approximately the same, 6.4; this approximation is so<br>
-close that it is of use in determining the valency and atomic weights of<br>
-substances. The atomic weight of a substance therefore represents the<br>
-approximate number of gram-calories required to raise one gram-atom, q.<br>
-v., of such substance through 1&deg; C. (1.8&deg; F.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atomicity.</span><br>
-The quantivalence or valency of the atoms; the number of combination<br>
-bonds, or bonds of affinity, possessed by the atoms of any substance.<br>
-Thus two atoms of hydrogen combine with one atom of oxygen, and three of<br>
-oxygen with one of sulphur, forming saturated compounds. Therefore,<br>
-taking hydrogen as of single atomicity or a monad, oxygen is of double<br>
-atomicity or a dyad, and sulphur is of six-fold atomicity, or a hexad.<br>
-The elements are thus classified into seven orders of atomicities, thus:<br>
-<br>
-&nbsp; <span style="font-family: monospace;">1, Monads or Univalent
-elements,&nbsp;&nbsp; Hydrogen, etc.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;2, Dyads or
-Bivalent&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Oxygen, etc.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;3, Triads or
-Trivalent&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Nitrogen, etc.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;4, Tetrads or
-Quadrivalent&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Lead, etc.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;5, Pentads or Quinquivalent
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Phosphorous, etc.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;6, Hexads or
-Sexivalent&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Chromium, etc.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;7, Heptads or
-Septivalent&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Chromium, etc.</span><br>
-<br>
-The same element often possesses several atomicities. Barium is<br>
-generally a dyad, sometimes a tetrad; nitrogen acts as a monad, dyad,<br>
-triad, tetrad and pentad. The familiar electrolysis of water, giving two<br>
-volumes of hydrogen to one of oxygen, is one of the illustrations of the<br>
-theory indicating that two atoms of hydrogen are combined with one of<br>
-oxygen.<br>
-<br>
-<br>
-53&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Atomic Weight.</span><br>
-The number expressing the relative weight of the atom of any substance,<br>
-that of hydrogen being generally taken as unity. This is the universal<br>
-system, although any other element might be taken as the basis of the<br>
-system. The whole theory of atomic weights is based on the<br>
-indivisibility of the atom and on the theory of atomicity, q. v. (See<br>
-Equivalents.)<br>
-<br>
-[Transcriber's note: The standard is now the isotope carbon-12 as<br>
-exactly 12.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Attraction.</span><br>
-The tendency to approach and adhere or cohere, shown by all forms of<br>
-matter. It includes gravitation, cohesion, adhesion, chemical affinity<br>
-and other forms, and is opposed by repulsion, and is sometimes overcome<br>
-by it, although it may be assumed to be always present. See the<br>
-different kinds of attractions under their titles: Atomic Attraction,<br>
-Electro-magnetic Attraction and Repulsion, Electro Static Attraction and<br>
-Repulsion, Electro-dynamic Attraction and Repulsion; Magnetic Attraction<br>
-and Repulsion; Molar Attraction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Audiometer.</span><br>
-An apparatus for obtaining a balance of induction from two coils acting<br>
-upon a third. The third is placed between the other two and is free to<br>
-move towards either. A scale is provided to show the extent of its<br>
-movement. A varying or interrupted current being passed through the two<br>
-outer coils, the preponderating current will produce the most induction<br>
-if the central coil is equidistant. It can always be moved to such a<br>
-point that there will be no inductive effect, one counteracting the<br>
-other. Thus its position measures the relative induction. A telephone is<br>
-in circuit with the intermediate coil and is used to determine when its<br>
-position is such that no current is induced in it. It is sometimes used<br>
-as a direct test of hearing. (See Hughes' Induction Balance.)<br>
-<br>
-Synonym--Acoutemeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Aura, Electrical.</span><br>
-The blast of air produced at highly electrified points.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Aurora.</span><br>
-A luminous display seen in the northern heavens in the northern<br>
-hemisphere, where it is the Aurora Borealis, and seen in the southern<br>
-heavens in the southern hemisphere, where it is called Aurora Australis,<br>
-or indifferently for either, the Aurora Polaris. It takes the form of<br>
-pale luminous bands, rays and curtains varying in color. Near the poles<br>
-they are very numerous. A French commission observed 150 auroras in 200<br>
-days. Their height is variously estimated at from 90 to 460 miles; they<br>
-are most frequent at the equinoxes and least so at the solstices. There<br>
-is a secular variation also, they attain a maximum of occurrence every<br>
-11 years together with sun spots, with a minimum 5 or 6 years after the<br>
-maximum. There is also a period of 60 years, coincident with<br>
-disturbances in the earth's magnetism. Various attempts have been made<br>
-to account for them. They have a constant direction of arc with<br>
-reference to the magnetic meridian (q. v.) and act upon the magnetic<br>
-needle; in high latitudes they affect telegraph circuits violently.<br>
-There is a strong probability that they represent electric currents or<br>
-discharges. De la Rive considers them due to electric discharges between<br>
-the earth and atmosphere, which electricities are separated by the<br>
-action of the sun in equatorial regions. According to Balfour Stewart,<br>
-auroras and earth currents.(q. v.) may be regarded as secondary currents<br>
-due to small but rapid changes in the earth's magnetism. The subject is<br>
-very obscure. Stewart treats the earth as representing the magnetic core<br>
-of an induction coil, the lower air is the dielectric, and the upper<br>
-rarefied and therefore conducting atmosphere is the secondary coil. This<br>
-makes the aurora a phenomenon of induced currents. Then the sun may be<br>
-regarded as the instigator of the primary changes in the earth's lines<br>
-of force representing the primary of an induction coil.<br>
-<br>
-[Transcriber's note: Solar wind, streams of electrons and protons,<br>
-interacting with the earth's magnetic field causes aurora. Neither<br>
-electrons (1897) nor protons (1920) were known in 1892. The Soviet<br>
-satellite Luna first measured the solar wind in 1959. Even today<br>
-increased understanding of solar and auroral phenomenon continues.]<br>
-<br>
-<br>
-54&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Austral Pole.</span><br>
-The north pole of the magnet is thus called sometimes in France; the<br>
-austral pole of a magnet is the one which points towards the north polar<br>
-regions As unlike magnetic poles attract each other, it is but rational<br>
-to call the north-seeking pole of the magnet the south or Austral Pole.<br>
-In the same nomenclature the south pole of a magnet, or the<br>
-south-seeking pole, is called the Boreal Pole.<br>
-<br>
-<br>
-<span style="font-weight: bold;">A. W. G.</span><br>
-Abbreviation for American Wire Gauge, q. v.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Axis, Electric.</span><br>
-The electric axis of a pyroelectric crystal, such as a tourmaline<br>
-crystal; the line connecting the points of greatest pyroelectric<br>
-excitability.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Axis of Abscissa.</span><br>
-In a system of rectilinear, or right angle co-ordinates, the horizontal<br>
-axis. (See Co-ordinates.)<br>
-<br>
-Synonym--Axis of X.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Axis of Ordinates.</span><br>
-In a system of rectilinear right angle co-ordinates, the vertical axis.<br>
-(See Co-ordinates.)<br>
-<br>
-Synonym--Axis of Y.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Azimuth.</span><br>
-The angle between the plane of the meridian and the plane of an azimuth<br>
-circle, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Azimuth Circle.</span><br>
-A great circle, whose plane passes through the zenith or point of the<br>
-heavens directly overhead; any great circle in whose plane the vertical<br>
-at the point of observation is included.<br>
-<br>
-Each celestial body has or determines an azimuth circle.<br>
-<span style="text-decoration: underline;"><br>
-</span></big></big><big><big><br>
-55&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">B.</span><br>
-(a) Abbreviation for Baum&eacute;, a hydrometer scale. (See
-Baum&eacute;.) Thus 10&ordm; B.<br>
-means "ten degrees Baum&eacute;."<br>
-<br>
-(b) Symbol for the coefficient of induced magnetization, or the number<br>
-of lines per square centimeter induced in a magnetic circuit or in any<br>
-specified part of it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">B. A.</span><br>
-Abbreviation for British Association. It is prefixed to standards fixed<br>
-by the committee of the British Association for the Advancement of<br>
-Science. Thus the B. A. ohm means the British Association ohm, a measure<br>
-of resistance which is equal to the resistance of a column of mercury<br>
-104.9 centimeters long and one square millimeter area of cross-section.<br>
-(See Ohm.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Back Induction.</span><br>
-A demagnetizing force produced in a dynamo armature when a lead is given<br>
-the brushes. The windings by such setting of the brushes are virtually<br>
-divided into two sets, one a direct magnetizing set, the other a cross<br>
-magnetizing set. The latter have a component due to the obliqueness of<br>
-the neutral line, which component is demagnetizing in its action.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Back Shock or Stroke of Lightning.</span><br>
-A lightning stroke received after the main discharge of the lightning,<br>
-and caused by a charge induced in neighboring surfaces by the main<br>
-discharge. The discharge affects the evenness of distribution of<br>
-surrounding surfaces so that a species of secondary discharge is<br>
-required to make even the distribution, or to supply charge where needed<br>
-to bind an opposite one. The effects are much lese severe as a rule than<br>
-those of the main charge, although the back stroke has caused death. The<br>
-back stroke is sometimes felt a considerable distance from the place of<br>
-the original lightning stroke.<br>
-<br>
-Synonym--Return Stroke.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Back Stroke.</span><br>
-(a) In telegraphy the return stroke of the lever in a telegraph sounder,<br>
-striking the end of the regulating screw with a sound distinct from that<br>
-which it produces on the forward stroke as it approaches the magnet<br>
-poles. It is an important factor in receiving by ear or sound reading.<br>
-<br>
-(b) See Back Shock or Stroke of Lightning.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Balance.</span><br>
-(a) Wheatstone's Bridge, q. v., is sometimes termed the Electric<br>
-Balance.<br>
-<br>
-(b) A suspension or torsion balance is one which includes a filament or<br>
-pair of filaments to whose lower end or ends are attached a horizontal<br>
-indicator often called a needle, or a magnetic needle. (See Torsion<br>
-Balance.)<br>
-<br>
-(c) See Induction Balance, Hughes'.<br>
-<br>
-(d) For Thermic Balance, see Bolometer.<br>
-<br>
-(e) See Balance, Ampere.<br>
-<br>
-<br>
-56&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Balance, Ampere.</span><br>
-A class of electrical measuring instruments due to Sir William Thomson<br>
-may be grouped under this head.<br>
-<br>
-The instrument is a true balance or scales such as used for weighing. It<br>
-is supported by a torsional wire support in place of knife edges. At<br>
-each end it carries a circle of wire through which the current to be<br>
-tested is passed. The torsional wire support enables the current to be<br>
-carried to these wire rings. Above and below each of these rings are two<br>
-similar rings, also connected so as to receive the current. They are so<br>
-connected that the current shall go through them in opposite senses.<br>
-When a current passes, therefore, one of these rings repels and one<br>
-attracts the balanced ring.<br>
-<br>
-The extent of this action measures the intensity of the current. A<br>
-sliding weight moving along a graduated scale on the balance is used to<br>
-bring the balance beam into equilibrium when the current is passing. The<br>
-degree of displacement of this weight gives the strength of the current<br>
-in amperes.<br>
-<br>
-These balances are made for different currents. Thus there is a<br>
-centi-ampere balance, deka-ampere balance and others, as well as an<br>
-ampere balance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Balata.</span><br>
-A gum used as an insulating material. It is the inspissated juice of a<br>
-sapotaceous tree, the bullet tree, Mimusops globosa, of tropical<br>
-America, from the Antilles to Guiana. It is intermediate in character<br>
-between caoutchouc and gutta percha. It is superior to gutta percha in<br>
-some respects, being very slightly acted on by light.<br>
-<br>
-Synonym--Chicle.<br>
-<br>
-<br>
-B. &amp; S.. W. G.<br>
-Abbreviation for Brown &amp; Sharpe Wire Gauge; the regular American
-Wire<br>
-Gauge. (See Wire Gauge, American.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Barad.</span><br>
-An absolute or fundamental unit of pressure, equal to one dyne per<br>
-square centimeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Barometer.</span><br>
-An apparatus for measuring the pressure exerted by the atmosphere. It<br>
-consists, in the mercurial form, of a glass tube, over 31 inches long,<br>
-closed at one end, filled with mercury and inverted, with its open end<br>
-immersed in a cistern of mercury. The column falls to a height<br>
-proportional to the pressure of the atmosphere from 30 to 31 inches at<br>
-the sea level. The "standard barometer" is a height of the mercury or of<br>
-the "barometric column" of 30 inches or 760 centimeters, measured from<br>
-the surface of the mercury in the cistern.<br>
-<br>
-The column of mercury is termed the barometric column. Above it in the<br>
-tube is the Torricellian vacuum.<br>
-<br>
-[Transcriber's note: More accurately, 29.92 inches of mercury or 14.696<br>
-PSI.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bars of Commutators.</span><br>
-The metal segments of a commutator of a dynamo or motor. They are made<br>
-of bars of copper, brass or bronze insulated from one another. (See<br>
-Commutator.)<br>
-<br>
-Synonyms--Segments, Commutator Segments, Commutator Bars.<br>
-<br>
-<br>
-57 STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bath.</span><br>
-(a) In electro-plating the solution used for depositing metal as<br>
-contained in a vat or tank; as a silver, copper, or nickel bath used for<br>
-plating articles with silver, copper, or nickel respectively.<br>
-<br>
-(b) In electro-therapeutics a bath with suitable arrangements,<br>
-electrodes and connections for treating patients with electricity. It is<br>
-termed an electric bath or electro-therapeutic bath.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bath, Bipolar Electric.</span><br>
-In electro-therapeutics a bath in which the electrodes are both immersed<br>
-in the water. The patient placed between them receives part of the<br>
-discharge. The electrodes are large copper plates, termed shovel<br>
-electrodes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bath, Electric Shower.</span><br>
-An electro-medical shower bath. The patient is placed on a metallic<br>
-stove or support connected to one of the electric terminals. Water<br>
-slightly alkaline is showered upon him. The other electrode is in<br>
-connection with the water. The rain of drops and streamlets is the<br>
-conductor of the current or discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bath, Multipolar Electric.</span><br>
-An electro-medical bath with a number of electrodes instead of two.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bath, Stripping.</span><br>
-In electro-plating a solution used for dissolving and thus removing the<br>
-plating from any object. The stripping bath is of the same general type<br>
-as the plating bath for the same metal as the one to be dissolved. The<br>
-object to be "stripped" is made the anode of a plating circuit, and as<br>
-the current acts the old plating is attacked and dissolves, leaving the<br>
-body of the article bare. It is simply the operation of plating<br>
-reversed. The same term is applied to baths acting by simple solution.<br>
-Stripping baths are described under the different metals as Silver Bath,<br>
-Stripping--Gold Bath, Stripping.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bath, Unipolar Electric.</span><br>
-An electro-medical bath, in which only one electrode connects with the<br>
-water of the bath. The second electrode is supported above the bath. The<br>
-patient touches this while in the water whenever electric action is<br>
-desired.<br>
-<br>
-<br>
-<img style="width: 509px; height: 327px;" alt="" src="images/057F36.jpg"><br>
-FIG. 36. THREE WIRE MOULDING OR BATTEN.<br>
-<br>
-<br>
-<img style="width: 486px; height: 302px;" alt="" src="images/057F37.jpg"><br>
-FIG. 37. TWO WIRE MOULDING OR BATTEN.<br>
-<br>
-<br>
-58&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Batten.</span><br>
-A strip of wood grooved longitudinally for holding wires in wiring<br>
-apartments for electric light or power. In use they are fastened to the<br>
-wall, grooves inward, or else grooves outward, with the wires lying in<br>
-the grooves and covered with the covering strip. For two wire work each<br>
-batten contains two grooves; for the three wire system it contains three<br>
-grooves.<br>
-<br>
-Synonym--Moulding.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery.</span><br>
-A combination of parts or elements for the production of electrical<br>
-action. The term is principally applied to voltaic batteries, but there<br>
-are also magnetic batteries, batteries of Leyden jars, and other<br>
-combinations, described in their places, which come under this category.<br>
-<br>
-[Transcriber's note: A group of similar items such as questions,<br>
-machines, parts, guns, or electric cells.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Acetic Acid.</span><br>
-A battery whose active solution or excitant is acetic acid or vinegar.<br>
-This acid has been used by Pulvermacher in his medical battery, as being<br>
-a substance found in every household in the form of vinegar. It is now<br>
-but little used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Alum.</span><br>
-A battery using as excitant a solution of alum. This battery has had<br>
-some application for electric clocks, but only to a limited extent.<br>
-<br>
-<br>
-<img style="width: 421px; height: 513px;" alt="" src="images/058F38.jpg"><br>
-Fig. 38. BALLOON OR FLASK BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Aluminum.</span><br>
-A battery in which aluminum is the negative plate and aluminum sulphate<br>
-the excitant. It is mounted like the gravity battery. Its electro-motive<br>
-force is 0.2 volt.<br>
-<br>
-<br>
-59&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Bagration.</span><br>
-A battery with zinc and carbon electrodes immersed in earth sprinkled<br>
-with sal ammoniac (ammonium chloride). The copper is preferably first<br>
-immersed in sal ammoniac solution and dried, until a green layer is<br>
-formed on its surface.<br>
-<br>
-The battery is highly praised for its constancy by De la Rive, but may<br>
-be regarded as obsolete.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Balloon.</span><br>
-A form of gravity battery into whose centre a globular flask, B, is<br>
-inverted, which is filled before inversion with copper sulphate, of<br>
-which 2 lbs. are used, and water, so as to remain full. This acts as a<br>
-reservoir of copper sulphate, which it constantly supplies. The glass<br>
-jar is closed with a perforated wooden cover.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Banked.</span><br>
-(a) A battery arranged to feed a number of separate circuits.<br>
-<br>
-(b) A battery connected in parallel or in multiple arc.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Bichromate.</span><br>
-A battery with amalgamated zinc and carbon plates, with an exciting<br>
-fluid composed of sulphuric acid, water, and potassium bichromate. For<br>
-formula of such solutions see Electropoion Fluid--Kookogey's<br>
-Solution--Poggendorff's Solution--Trouv&eacute;'s Solution--Delaurier's<br>
-Solution, and others. (See Index.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Bunsen.</span><br>
-A two fluid porous cell battery. The negative plate is carbon, the<br>
-positive plate, amalgamated zinc. The depolarizer is nitric acid or<br>
-electropoion fluid, q.v., in which the carbon is immersed. The last<br>
-named depolarizer or some equivalent chromic acid depolarizing mixture<br>
-is now universally used.&nbsp; The excitant is a dilute solution of
-sulphuric<br>
-acid. Originally the carbon was made cylindrical in shape and surrounded<br>
-the porous cups, in which the zinc was placed. This disposition is now<br>
-generally reversed. The electro-motive force is 1.9 volts. The<br>
-depolarizing solution is placed in the compartment with the carbon. The<br>
-excitant surrounds the zinc.<br>
-<br>
-<br>
-<img style="width: 576px; height: 600px;" alt="" src="images/059F39.jpg"><br>
-Fig. 39. BUNSEN'S BATTERY.<br>
-<br>
-<br>
-60&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Cadmium.</span><br>
-A battery in which cadmium is the negative plate, sulphate of cadmium<br>
-solution the excitant and depolarizer, and zinc the positive plate.<br>
-Electro-motive force, .31 volt or about one third of a Daniell cell. It<br>
-is mounted like a gravity battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Callan.</span><br>
-A modification of Grove's battery. Platinized lead is used for the<br>
-negative plate, and as a depolarizer a mixture of 4 parts concentrated<br>
-sulphuric acid, 2 parts of nitric acid, and 2 parts of a saturated<br>
-solution of potassium nitrate. (See Battery, Grove's.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Battery, Camacho's.</span><br>
-A battery with carbon negative and amalgamated zinc positive electrodes.<br>
-The carbon is contained in a porous cup, packed with loose carbon.<br>
-Electropoion or other fluid of that type serves as excitant and<br>
-depolarizer, and is delivered as shown from cell to cell by syphons.<br>
-<br>
-<br>
-<img style="width: 628px; height: 444px;" alt="" src="images/060F40.jpg"><br>
-Fig. 40. CAMACHO'S BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Carr&eacute;'s.</span><br>
-A Daniell battery for whose porous cup a vessel or species of sack made<br>
-of parchment paper is substituted. The battery has been used for<br>
-electric light, and has been run for 200 successive hours, by replacing<br>
-every 24 hours part of the zinc sulphate solution by water.<br>
-<br>
-<br>
-61&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Cautery.</span><br>
-A battery used for heating a platinum wire or other conductor used for<br>
-cauterization in electro-therapeutics. The term is descriptive, not<br>
-generic.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Chloric Acid.</span><br>
-A battery of the Bunsen type in which an acidulated solution of<br>
-potassium chlorate is used as depolarizer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Chloride of Lime.</span><br>
-A battery in which bleaching powder is the excitant. The zinc electrode<br>
-is immersed in a strong solution of salt, the carbon in a porous vessel<br>
-is surrounded with fragments of carbon and is packed with chloride of<br>
-lime (bleaching powder). There is no action on open circuit. It has to<br>
-be hermetically sealed on account of the odor. Its electro-motive force<br>
-is--initial, 1.65 volts; regular, 1.5 volts.<br>
-<br>
-Synonym--Niaudet's Battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Chromic Acid.</span><br>
-Properly a battery in which chromic acid is used as a depolarizer. It<br>
-includes the bichromate battery. (See Battery, Bichromate.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Closed Circuit.</span><br>
-A battery adapted by its construction to maintain a current on a closed<br>
-circuit for a long time without sensible polarization. The term is<br>
-merely one of degree, for any battery becomes exhausted sooner or later.<br>
-As examples the Grove, Bunsen or Daniell batteries may be cited.<br>
-<br>
-<br>
-62&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 591px; height: 485px;" alt="" src="images/061F41.jpg"><br>
-Fig. 41. COLUMN BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Column.</span><br>
-The original Volta's pile. It consists of a series of compound circular<br>
-plates, the upper or lower half, A, copper; the other, Z, of zinc.<br>
-Between each pair of plates some flannel or cloth, u, u, is laid, which<br>
-is saturated with dilute acid. As shown in the cut, the parts are laid<br>
-up in two piles, connected at the top with a bar, c, c, and with vessels<br>
-of acidulated water, b, b, as electrodes. The great point in setting it<br>
-up is to be sure that no acid runs from one disc of flannel to the next<br>
-over the outside of the plates, as this would create a short circuit.<br>
-The plates are best compound, being made up of a zinc and a copper plate<br>
-soldered together. They may, however, be separate, and merely laid one<br>
-on the other. In such case great care must be taken to admit no acid<br>
-between them.<br>
-<br>
-Volta's pile is no longer used, except occasionally. Trouv&eacute;'s
-blotting<br>
-paper battery (see Battery, Trouv&eacute;'s) is a relic of it, and the
-same is<br>
-to be said for Zamboni's dry pile.<br>
-<br>
-It rapidly polarizes, the flannel retains but little acid, so that it is<br>
-soon spent, and it is very troublesome to set up. Great care must be<br>
-taken to have the cloth discs thoroughly saturated, and wrung out to<br>
-avoid short circuiting by squeezing out of the acid.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, D'Arsonval's.</span><br>
-A battery of the Bunsen type, differing therefrom in the solutions. As<br>
-excitant in which the zinc electrode is immersed, the following solution<br>
-is used:<br>
-<br>
-Water, 20 volumes;<br>
-Sulphuric Acid (purified by shaking with a little olive or similar oil),<br>
-1 volume;<br>
-hydrochloric acid, 1 volume.<br>
-<br>
-As polarizer in which the carbon is immersed the following is used:<br>
-<br>
-Nitric acid, 1 volume;<br>
-hydrochloric acid, 1 volume;<br>
-water acidulated with 1/20th sulphuric acid, 2 volumes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, de la Rue.</span><br>
-A battery with zinc positive and silver negative electrode; the<br>
-depolarizer is silver chloride; the excitant common salt or ammonium<br>
-chloride. The cut shows one of its forms of construction.<br>
-<br>
-The right hand portion of the cut, Fig. 42, shows the zinc perforated at<br>
-C for the connection from the next silver plate. The next to it is the<br>
-negative electrode of silver around which a mass of silver chloride is<br>
-cast in cylindrical form. A is a parchment paper cylinder with two holes<br>
-near its top, through which the silver wire of the negative electrode is<br>
-threaded, as shown in B. A solution of 23 parts ammonium chloride in<br>
-1,000 parts of water is the approved excitant. Its electro-motive force<br>
-is 1.03 volts.<br>
-<br>
-The jars are closed with paraffin.<br>
-<br>
-<br>
-<img style="width: 598px; height: 382px;" alt="" src="images/062F42.jpg"><br>
-Fig. 42. DE LA RUE'S BATTERY.<br>
-<br>
-<br>
-63&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Dry.</span><br>
-(a) A form of open circuit battery in which the solutions by a mass of<br>
-zinc oxychloride, gypsum, or by a gelatinous mass such as gelatinous<br>
-silica, or glue jelly, are made practically solid. Numbers of such have<br>
-been patented, and have met with considerable success.<br>
-<br>
-(b) Zamboni's dry pile, q. v., is sometimes termed a dry battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Element of.</span><br>
-A term applied sometimes to a single plate, sometimes to the pair of<br>
-plates, positive and negative, of the single couple.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Faradic.</span><br>
-A term applied, not very correctly however, to apparatus for producing<br>
-medical faradic currents. It may be an induction coil with battery, or a<br>
-magneto-generator worked by hand.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Ferric Chloride.</span><br>
-A battery of the Bunsen type, in which a solution of perchloride of iron<br>
-(ferric chloride) is used for the depolarizing agent. A little bromine<br>
-is added with advantage. The depolarizing agent recuperates on standing,<br>
-by oxidation from the oxygen of the air.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Fuller's.</span><br>
-A battery of the Bunsen type. The zinc plate is short and conical, and<br>
-rests in the porous jar into which some mercury is poured. An insulated<br>
-copper wire connects with the zinc. A plate of carbon is in the outer<br>
-jar. The solutions are used as in the Bunsen battery.<br>
-<br>
-Synonym--Mercury Bichromate Battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Gas.</span><br>
-(a) A battery whose action depends on the oxidation of hydrogen as its<br>
-generating factor. It was invented by Grove. Plates of platinum are<br>
-immersed in cups of dilute acid, arranged as if they were plates of zinc<br>
-and carbon, in an ordinary battery. Each plate is surrounded by a glass<br>
-tube sealed at the top. The plates are filled with acid to the tops.<br>
-Through the top the connection is made. A current from another battery<br>
-is then passed through it, decomposing the water and surrounding the<br>
-upper part of one set of plates with an atmosphere of oxygen and of the<br>
-other with hydrogen. Considerable quantities of these gasses are also<br>
-occluded by the plates. On now connecting the terminals of the battery,<br>
-it gives a current in the reverse direction of that of the charging<br>
-current.<br>
-<br>
-This battery, which is experimental only, is interesting as being the<br>
-first of the storage batteries.<br>
-<br>
-(b) Upward's Chlorine Battery and any battery of that type (see Battery,<br>
-Upward's,) is sometimes termed a gas battery.<br>
-<br>
-<br>
-64&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery Gauge.</span><br>
-A pocket or portable galvanometer for use in testing batteries and<br>
-connections.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Gravity.</span><br>
-A battery of the Daniell type, in which the porous cup is suppressed and<br>
-the separation of the fluids is secured by their difference in specific<br>
-gravity. A great many forms have been devised, varying only in details.<br>
-The copper plate, which is sometimes disc shaped, but in any case of<br>
-inconsiderable height, rests at the bottom of the jar. Near the top the<br>
-zinc plate, also flat or of slight depth, is supported. As exciting<br>
-liquid a strong solution of copper sulphate lies at the bottom of the<br>
-jar. This is overlaid by a solution of zinc sulphate, or sodium<br>
-sulphate, which must be of considerably less specific gravity than that<br>
-of the copper sulphate solution. In charging the jar one-tenth of a<br>
-saturated solution of zinc sulphate mixed with water is sometimes used<br>
-as the upper fluid. This may be first added so as to half fill the jar.<br>
-The strong solution of copper sulphate may then be added with a syphon<br>
-or syringe underneath the other so as to raise it up. From time to time<br>
-copper sulphate in crystals are dropped into the jar. They sink to the<br>
-bottom and maintain the copper sulphate solution in a state of<br>
-saturation.<br>
-<br>
-<br>
-<img style="width: 651px; height: 347px;" alt="" src="images/064F43.jpg"><br>
-Fig. 43. GRAVITY BATTERY OF THE TROUV&Eacute;-CALLAUD TYPE.<br>
-<br>
-<br>
-If the battery is left on open circuit the liquids diffuse, and metallic<br>
-copper precipitates upon the zincs. This impairs its efficiency and<br>
-creates local action. As long as the battery is kept at work on closed<br>
-circuit work but little deposition, comparatively speaking, occurs.<br>
-<br>
-From time to time, in any case, the zinc plates are removed and scraped,<br>
-so as to remove the copper which inevitably forms on their surface. Care<br>
-must be taken that the zinc sulphate solution, which is constantly<br>
-increasing in strength, does not get so strong as to become of as high<br>
-specific gravity as the copper sulphate solution. From time to time some<br>
-of the upper solution is therefore removed with a syphon or syringe and<br>
-replaced with water. An areometer is useful in running this battery.<br>
-<br>
-<br>
-65&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Grenet.</span><br>
-A plunge battery with zinc positive and carbon negative electrodes.<br>
-Electropoion or other chromic acid or bichromate solution is used as<br>
-depolarizer and excitant. The zinc plate alone is plunged into and<br>
-withdrawn from the solution.<br>
-<br>
-<br>
-<img style="width: 390px; height: 608px;" alt="" src="images/065F44.jpg"><br>
-Fig. 44. GRENET'S BATTERY.<br>
-<br>
-<br>
-<img style="width: 462px; height: 583px;" alt="" src="images/065F45.jpg"><br>
-Fig. 45. GROVE'S BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Grove's.</span><br>
-A two fluid galvanic battery. A porous cup has within it a riband of<br>
-platinum, which is the negative plate; amalgamated zinc in the outer jar<br>
-is the positive plate. Dilute sulphuric acid (10 per cent. solution) is<br>
-placed in the outer jar, and strong nitric acid (40&deg; B.) as a<br>
-depolarizer in the porous cups. Its E. M. F. is 1.96 volts.<br>
-<br>
-It is objectionable, as it gives off corrosive nitrous fumes. These are<br>
-produced by the oxidation of the nascent hydrogen by the nitric acid, by<br>
-the following reaction:<br>
-<br>
-3 H + H N O3 = 2 H2 O + N O. There are other reactions, one of which<br>
-results in the formation of ammonia by the reduction of the nitric acid<br>
-radical by the hydrogen. Ammonium can be detected in the spent liquids.<br>
-<br>
-<br>
-66&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Hydrochloric Acid.</span><br>
-A battery in which hydrochloric acid is used as the excitant. Many<br>
-attempts have been made to use this acid in batteries, but the volatile<br>
-nature of the acid causes the production of so much odor with corrosive<br>
-fumes that it has never come into use.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Lead Chloride.</span><br>
-A battery of the lead sulphate type in which lead chloride is the<br>
-depolarizer. It has had no extended use.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Lead Sulphate.</span><br>
-A battery similar to Mari&eacute; Davy's battery or the gravity
-battery, but<br>
-using lead sulphate as depolarizer and excitant. Lead, copper or tin is<br>
-the material of the negative plate. Becquerel used the lead sulphate as<br>
-a solid cylindrical mass surrounding a lead rod 1/5 to 1/4 inch in<br>
-diameter. One part of common salt may be mixed with 5 parts of the lead<br>
-sulphate. The electro-motive force is about 0.5 volt. The resistance is<br>
-very high.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Battery, Leclanch&eacute;.</span><br>
-An open circuit battery with porous cup. In the outer jar is a zinc rod;<br>
-a carbon plate is placed in the porous cup. The latter is packed with a<br>
-mixture of clean powdered manganese binoxide as depolarizer, and<br>
-graphite in equal volumes. A strong solution of ammonium chloride (sal<br>
-ammoniac) is placed in the outer jar. It is only used on open circuit<br>
-work. Its electromotive force is 1.48 volts, when not polarized.<br>
-<br>
-The reaction is supposed to be about the following:<br>
-<br>
-2 N H4 Cl + 2 Mn O2 + Zn = Zn Cl2 + 2 N H3 + H2 0 + M2 O3<br>
-<br>
-The battery rapidly weakens on open circuit, but quickly recuperates.<br>
-There is another form of this battery, termed the agglomerate battery.<br>
-(See Battery, Leclanch&eacute; Agglomerate.)<br>
-<br>
-<br>
-<img style="width: 380px; height: 583px;" alt="" src="images/067F46.jpg"><br>
-Fig. 46. LECLANCH&Eacute; BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Leclanch&eacute; Agglomerate.</span><br>
-A form of the Leclanch&eacute; in which the porous jar is suppressed.
-Cakes<br>
-made of a mixture of carbon, 52 parts; manganese binoxide, 40 parts; gum<br>
-lac, 5 parts; potassium bisulphate, 3 parts, compressed at 300<br>
-atmospheres, at a temperature of 100&deg; C. (212&deg; F.), are
-fastened by<br>
-India rubber bands or otherwise against the carbon plate. These<br>
-constitute the depolarizer. Various shapes are given the carbon and<br>
-depolarizing agglomerates.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Local.</span><br>
-A battery supplying a local circuit (see Circuit. Local). The current is<br>
-governed by the relay situated on the main line and operated by its<br>
-current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Main.</span><br>
-The battery used in operating the main line. It is usually applied to<br>
-telegraphy. Its function is then to supply current for working relays,<br>
-which in turn actuate the local circuits.<br>
-<br>
-Main and local circuits and batteries are also used in the automatic<br>
-block system of railroad signalling.<br>
-<br>
-<br>
-67&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Mari&eacute; Davy's.</span><br>
-A two fluid porous cup battery with carbon negative plate, zinc positive<br>
-plate, and mercury sulphate, a nearly insoluble salt, as depolarizer and<br>
-excitant. Mercurous or mercuric sulphates have been used in it. Its<br>
-electromotive force is 1.5 volts. The local action and waste, owing to<br>
-the slight solubility of the mercury compounds, is very slight. If used<br>
-on close circuit it becomes polarized. It is also subject under extreme<br>
-circumstances to reversal of polarity, zinc becoming deposited upon the<br>
-carbon, and there forming a positive electrode.<br>
-<br>
-In using the cells in series the level of liquid in all must be the<br>
-same, otherwise the cell in which it is lowest will become polarized and<br>
-exhausted.<br>
-<br>
-Modifications of this battery on the lines of the gravity battery have<br>
-been constructed.<br>
-<br>
-Synonym--Sulphate of Mercury Battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Maynooth's.</span><br>
-A battery of the Bunsen type, with cast iron negative plate. The iron<br>
-takes the passive form and is not attacked.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Medical.</span><br>
-A term applied very indiscriminately to medical current generators, and<br>
-to medical induction coils, or to any source of electricity, static or<br>
-current, for medical application.<br>
-<br>
-<br>
-68&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Meidinger's.</span><br>
-A variety of Daniell cell of the gravity type. The plates are<br>
-cylindrical. The zinc plate lies against the upper walls of the vessel.<br>
-The copper plate of smaller diameter rests on the bottom. A large tube,<br>
-with an aperture in its bottom, is supported in the centre and is<br>
-charged with copper sulphate crystals. The cup is filled with a dilute<br>
-solution of Epsom salts (magnesium sulphate) or with dilute sulphuric<br>
-acid.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery Mud.</span><br>
-A deposit of mud-like character which forms in gravity batteries and<br>
-which consists of metallic copper precipitated by the zinc. It indicates<br>
-wasteful action.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Battery, Multiple-connected.</span><br>
-A battery connected in parallel, all the positive plates being connected<br>
-to one electrode, and all the negative to another.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Battery, Nitric Acid.</span><br>
-A battery in which nitric acid is used as the excitant. Owing to its<br>
-cost and volatility this acid has been but little used in batteries,<br>
-other than as a depolarizer. In Grove's battery (see Battery, Grove's)<br>
-it has been thus used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery of Dynamos.</span><br>
-A number of dynamos may be arranged to supply the same circuit. They are<br>
-then sometimes termed as above, a Dynamo Battery. They may be arranged<br>
-in series or in parallel or otherwise combined.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery of Leyden Jars.</span><br>
-To produce the quantity effect of a single large Leyden jar with a<br>
-number of small ones they are often connected in parallel and termed a<br>
-battery. In such case the inner coatings are all connected by regular<br>
-bar conductors, and the outside coatings are also all in connection.<br>
-They are conveniently placed in a box or deep tray whose inner surface<br>
-is lined with tinfoil, with an outside connection for grounding, etc.<br>
-The cascade, q. v., arrangement is not so generally termed a battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Open Circuit.</span><br>
-A battery adapted for use in open circuit work. Its main requirement is<br>
-that it shall not run down, or exhaust itself when left on open circuit.<br>
-The Leclanch&eacute; battery is very extensively used for this work.
-Its action<br>
-is typical of that of most open circuit batteries. It is without any<br>
-action on open circuit. It is very quickly exhausted on closed circuit,<br>
-but recuperates or depolarizes quite soon when on open circuit. It is<br>
-always in condition for a momentary connection, but useless for steady<br>
-work.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Oxide of Copper.</span><br>
-A battery with zinc positive and iron negative electrodes. The excitant<br>
-is a 30 or 40 per cent. solution of sodium or potassium hydrate (caustic<br>
-soda or caustic potash). The depolarizer is copper oxide. In action the<br>
-copper is gradually reduced to the metallic state. The iron element is<br>
-often the containing vessel. The battery is practically inactive on open<br>
-circuit.<br>
-<br>
-Its electro-motive force varies from .75 to .90 volt. To prevent the<br>
-formation of sodium or potassium carbonate the cell should be closed, or<br>
-else the liquid should be covered with mineral oil.<br>
-<br>
-Synonyms--Lalande &amp; Chaperon Battery--Lalande-Edison Battery.<br>
-<br>
-<br>
-69&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Peroxide of Lead.</span><br>
-A battery in which peroxide of lead (lead binoxide) is the depolarizer.<br>
-It is a sort of predecessor of the present secondary battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Platinized Carbon.</span><br>
-A modification of Smee's battery, in which platinized carbon is used for<br>
-the negative plates. Before polarization the E. M. F. is equal to that<br>
-of Smee's battery. Polarization reduces its electro-motive force<br>
-one-half.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Plunge.</span><br>
-A battery whose plates are mounted so as to be immersed in the battery<br>
-cups or cells, when the battery is to be used, and withdrawn and<br>
-supported out of the cups when not in use. The object is to prevent<br>
-wasting of the plates by standing in the solution. It is a construction<br>
-generally used with sulphuric acid--chromic acid solution and<br>
-amalgamated zinc and carbon plates.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Pneumatic.</span><br>
-A battery arranged to have air blown through the solution to assist<br>
-diffusion and depolarization. It is a construction applied to chromic<br>
-acid or bichromate batteries.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Primary.</span><br>
-A battery in which the current is supplied by the solution of one of the<br>
-plates by the solution. The term distinguishes it from a secondary or<br>
-storage battery.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Battery, Pulvermacher's
-Electro-Medical.</span><br>
-In this battery, the electrodes were zinc and copper wires wound upon<br>
-small pieces of wood. Dilute vinegar was used as the excitant, because<br>
-it could be found in every household. Formerly the battery had great<br>
-success. It is now little used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Sal Ammoniac.</span><br>
-Batteries in which a solution of ammonium chloride is the excitant; they<br>
-are very extensively used on open circuit work. (See Battery,<br>
-Leclanch&eacute;.)<br>
-<br>
-The crystals formed in these batteries have been analyzed and found to<br>
-consist of ammonium zinc chloride, 3 Zn Cl2, 8 N H3, 4 H20.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Salt, or Sea Salt.</span><br>
-Batteries in which a solution of sodium chloride or common salt is the<br>
-excitant, have been largely used, especially for telegraphic purposes.<br>
-The Swiss telegraphs use a carbon-zinc combination with salt and water<br>
-as the excitant. The batteries are sometimes mounted as plunge<br>
-batteries. They are exhausted by short circuiting after some hours, but<br>
-recuperate on standing. The zinc is not amalgamated.<br>
-<br>
-<br>
-70&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Sand.</span><br>
-A battery whose cells are charged with sand saturated with dilute acid.<br>
-It prevents spilling of acid. It is now practically obsolete.<br>
-<br>
-<br>
-<img style="width: 530px; height: 709px;" alt="" src="images/070F47.jpg"><br>
-Fig. 47. SECONDARY BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Secondary.</span><br>
-A voltaic battery whose positive and negative electrodes are formed or<br>
-deposited by a current from a separate source of electricity by<br>
-electrolysis. On disconnection the battery is ready to yield a current,<br>
-in the reverse direction of that of the charging current. The usual type<br>
-has lead plates on one of which lead binoxide and on the other of which<br>
-spongy lead is formed. The lead binoxide seems to be the negative<br>
-element, and it also acts as the depolarizer. The spongy lead is the<br>
-positive electrode. The solution is dilute sulphuric acid of specific<br>
-gravity 1.17. The action consists first in the oxidation of the spongy<br>
-lead. The hydrogen set free by the reaction, and which by electrolytic<br>
-transfer goes to the other plate, reduces the lead binoxide to<br>
-protoxide. The sulphuric acid then attacks the oxides and converts the<br>
-oxides into sulphates.<br>
-<br>
-The charging process consists in sending a current in the reverse <br>
-direction through the battery. If there are several cells they are <br>
-arranged in series, so that each one receives the same intensity of <br>
-current. An electrolytic decomposition takes place, the lead sulphate
-on <br>
-one plate is reduced to metallic lead, and that on the other plate is <br>
-oxidized to lead binoxide. It is then ready for use.<br>
-<br>
-<br>
-71&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The plates in a lead plate battery are of very large area per cell, and<br>
-are placed close together. Sometimes, as in Plant&eacute;'s battery,
-large flat<br>
-plates are laid together with a separating insulator between them, and<br>
-are then rolled into a spiral. Sometimes, the most usual arrangement,<br>
-the plates are in sets, the positive and negative ones alternating, and<br>
-each cell containing a number of plates.<br>
-<br>
-To secure a good quantity of active material, the plates are sometimes<br>
-perforated, and the perforations are filled with oxide of lead. This<br>
-gives a good depth of material for the charging current to act on, and<br>
-avoids the necessity for a tedious "forming," q. v.<br>
-<br>
-The electro-motive force of such a battery per cell is 2 volts. Its<br>
-resistance may only be one or two-hundredths of an ohm. An intense<br>
-current of many amperes can be supplied by it, but to avoid injuring the<br>
-cell a current far less than the maximum is taken from it.<br>
-<br>
-To charge it, a slightly greater electro-motive force, the excess being<br>
-termed spurious voltage, is required.<br>
-<br>
-<br>
-<img style="width: 573px; height: 703px;" alt="" src="images/071F48.jpg"><br>
-Fig. 48. SIEMENS' AND HALSKE'S PAPER PULP BATTERY.<br>
-<br>
-<br>
-72&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<span style="font-weight: bold;">Battery, Secondary, Plante's.</span><br>
-Plante's secondary battery is one of the earlier forms of storage<br>
-battery, but has had much success. Two lead plates, large in area and<br>
-close together but not touching, are "formed," by exposure to an<br>
-electrolyzing current of electricity in one direction, while they are<br>
-immersed in dilute sulphuric acid. This converts the surface of one<br>
-plate into binoxide. The cell is then allowed to discharge itself almost<br>
-completely, when the charging current is again turned on. This process<br>
-is repeated over and over again, until the surfaces of the plates are<br>
-considerably attacked, one plate, however, being maintained in a state<br>
-of oxidation. After a few days of this operation a period of rest is<br>
-allowed between the reversals, which sets up a local action on the<br>
-oxidized plate, between the metallic lead of the plate, and its coating<br>
-of binoxide. This causes the lead to be attacked, under the influence of<br>
-the local couple, and sulphate of lead is formed, which, ultimately, by<br>
-the charging current is converted into peroxide. These operations<br>
-produce an exceedingly good battery. The process described is termed<br>
-forming.<br>
-<br>
-The plates separated by strips of insulating material are generally<br>
-wound into a double spiral.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Siemens' and Halske's.</span><br>
-A Daniell battery of peculiar shape. The copper, C, is at the bottom of<br>
-the glass jar, A. The inner jar, K, has the form of a bell, and supports<br>
-a mass of paper pulp, which is dampened with sulphuric acid. The zinc,<br>
-Z, rests on top of the mass of pulp. The battery is very durable, but of<br>
-high resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Sir William Thomson's.</span><br>
-A form of Daniell battery, of the gravity type. The receptacles are<br>
-shallow wooden trays lined with lead. A thin plate of copper rests on<br>
-the bottom. The zinc plate is of gridiron shape, and rests on wooden<br>
-blocks which support it in a horizontal position above the copper. One<br>
-tray is placed on top of the other, the upper tray resting on the<br>
-corners of the zinc plate which rise above the level of the top of the<br>
-flat vessel. Thus connection is assured without wires or binding posts.<br>
-It is charged like a gravity battery. The density of the zinc sulphate<br>
-solution should be between 1.10 and 1.30. The circuit must be kept<br>
-closed to prevent deposition of metallic copper on the zinc. The entire<br>
-disposition of the battery is designed to reduce resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Skrivanow.</span><br>
-A pocket battery of the De la Rue type, with a solution of 75 parts<br>
-caustic potash in 100 parts of water as the excitant. The silver<br>
-chloride is contained in a parchment paper receptacle. Its<br>
-electro-motive force is 1.45 to 1.5 volts.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Smee's.</span><br>
-A single fluid combination, with zinc positive plate, and a plate of<br>
-silver, coated with platinum black, for the negative plate. The finely<br>
-divided platinum affords a surface from which the hydrogen bubbles<br>
-instantly detach themselves, thus preventing polarization. The liquid is<br>
-a mixture of one part sulphuric acid to seven parts of water. For the<br>
-negative plate silver-plated copper, coated with platinum black, is<br>
-used. Electromotive force, .47 volt.<br>
-<br>
-<br>
-<img style="width: 349px; height: 608px;" alt="" src="images/072F49.jpg"><br>
-Fig. 49. SMEE'S BATTERY.<br>
-<br>
-<br>
-73&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 493px; height: 712px;" alt="" src="images/073F50.jpg"><br>
-Fig. 50. SPIRAL BATTERY, OR HARE'S DEFLAGRATOR.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Spiral.</span><br>
-A battery whose plates of thin zinc and copper are wound into a spiral<br>
-so as to be very close, but not touching. Dilute sulphuric acid is the<br>
-excitant. It is now practically obsolete.<br>
-<br>
-Synonyms--Calorimeter--Hare's Deflagrator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Split.</span><br>
-A battery of a number of voltaic cells, connected in series, with their<br>
-central portion grounded or connected to earth. This gives the ends of<br>
-opposite potentials from the earth, and of difference therefrom equal to<br>
-the product of one-half of the number of cells employed, multiplied by<br>
-their individual voltage.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery Solutions, Chromic Acid.</span><br>
-A number of formulae have been proposed for these solutions. (See<br>
-Electropoion Fluid--Kookogey's Solution--Poggendorff's Solution--<br>
-Trouv&eacute;'s Solution--Delaurier's Solution--Chutaux's
-Solution--Dronier's<br>
-Salt--Tissandier's Solution.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Trough.</span><br>
-A battery whose elements are contained in a trough, which is divided by<br>
-cross-partitions so as to represent cups. A favorite wood for the trough<br>
-is teak, which is divided by glass or slate partitions. Marine glue or<br>
-other form of cement is used to make the joints tight. For porous cup<br>
-divisions plates of porous porcelain or pottery are placed across,<br>
-alternating with the impervious slate partitions.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Trouv&eacute;'s Blotting
-Paper.</span><br>
-A battery of the Daniell type in which the solutions are retained by<br>
-blotting paper. A considerable thickness of blotting paper lies between<br>
-the two plates. The upper half of the thickness of the blotting paper is<br>
-saturated with a solution of zinc sulphate, on which the zinc plate<br>
-rests.<br>
-<br>
-The lower half of the paper is saturated with copper sulphate solution,<br>
-and this rests upon the copper plate.<br>
-<br>
-<br>
-<img style="width: 696px; height: 512px;" alt="" src="images/074F51.jpg"><br>
-Fig. 51. TROUV&Eacute;'S BLOTTING PAPER BATTERY.<br>
-<br>
-<br>
-74&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Tyer's.</span><br>
-A modification, as regards the positive element, of Smee's battery, q.<br>
-v. The bottom of the battery jar contains a quantity of mercury in which<br>
-pieces of zinc are thrown, and this constitutes the positive element.<br>
-<br>
-A ball of zinc at the end of an insulated copper wire affords the<br>
-connection with the zinc and mercury. Its great advantage is that the<br>
-smallest scraps of zinc can be used in it, by being dropped into the<br>
-mercury. The negative plate is platinized silver; the exciting liquid,<br>
-dilute sulphuric acid.<br>
-<br>
-<br>
-<img style="width: 642px; height: 585px;" alt="" src="images/074F52.jpg"><br>
-Fig. 52. TYER'S BATTERY.<br>
-<br>
-<br>
-75&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 452px; height: 702px;" alt="" src="images/075F53.jpg"><br>
-Fig. 53. SECTION OF UPWARD'S BATTERY.<br>
-<br>
-<br>
-<img style="width: 566px; height: 676px;" alt="" src="images/075F54.jpg"><br>
-Fig. 54. ELEVATION OF UPWARD'S BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Upward's.</span><br>
-A primary voltaic cell, the invention of A. Ren&eacute;e Upward.
-Referring to<br>
-the cuts, the positive plate. Z, is of cast zinc; it is immersed in<br>
-water, in a porous cup, B. Outside of the porous cup and contained in<br>
-the battery jar are two carbon plates, C, C, connected together. The<br>
-rest of the space between the porous cup and battery jar is packed with<br>
-crushed carbon, and the top is cemented. Chlorine gas is led by a pipe,<br>
-D, into the outer cell. It diffuses through the fine carbon, dissolves<br>
-in the water, and so finds its way to the zinc, which it attacks,<br>
-directly combining therewith, and forming zinc chloride (Zn + 2 Cl = Zn<br>
-Cl 2). Such of the chlorine as is not absorbed finds its way by an
-outlet<br>
-tube, E, to the next cell. Arrangements are provided for generating<br>
-chlorine gas as required. The high specific gravity of the gas is<br>
-utilized in regulating its distribution through the cells. The<br>
-electro-motive force of the cell is 2.1 volts. A cell 11.5 by 5.5 inches<br>
-and 12.5 inches deep has a resistance of 0.2 ohm.<br>
-<br>
-An overflow pipe, F, with faucet, T, is supplied to withdraw the<br>
-solution of zinc chloride as it accumulates.<br>
-<br>
-<br>
-76&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Varley's.</span><br>
-A Daniell battery of the Siemens' and Halske's type (see Battery,<br>
-Siemens' and Halske's), in which zinc oxide is substituted for the paper<br>
-pulp of the other battery. It has been very little used.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Battery, Volta's.</span><br>
-The original acid battery. It has a negative electrode of copper, a<br>
-positive electrode of zinc; the excitant is sulphuric acid diluted with<br>
-sixteen times its volume of water. It rapidly polarizes, and is very<br>
-little used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Voltaic or Galvanic.</span><br>
-An apparatus for converting chemical energy directly into electric<br>
-energy. This is as broad a definition as can well be given. The general<br>
-conception of a battery includes the action of electrolysis, a solution<br>
-in the battery acting upon one of two conducting electrodes immersed in<br>
-such fluid, which dissolves one of them only, or one more than the<br>
-other. The best way to obtain a fundamental idea of a battery is to<br>
-start with the simplest. Dilute sulphuric acid dissolves neither pure<br>
-zinc nor copper. But it has a far stronger affinity for the first named<br>
-metal. If now we immerse in dilute acid two plates, one of pure zinc,<br>
-and one of copper, no action will be discernible. But if the plates are<br>
-brought in contact with each other a stream of bubbles of hydrogen gas<br>
-will escape from the surface of the copper and the zinc will dissolve.<br>
-By applying proper tests and deductions it will be found that the copper<br>
-and zinc are being constantly charged with opposite electricities, and<br>
-that these are constantly recombining. This recombination produces what<br>
-is known as an electric current.<br>
-<br>
-To constitute a battery the zinc and copper plates must be connected<br>
-outside of the solution. This connection need not be immediate. Any<br>
-conductor which touches both plates will bring about the action, and the<br>
-current will pass through it.<br>
-<br>
-The easiest way to picture the action of a battery is to accept the<br>
-doctrine of contact action. In the battery the molecules of water are<br>
-pulled apart. The hydrogen molecules go to the copper, the oxygen<br>
-molecules go to the zinc, each one, leaving its contact with the other,<br>
-comes off charged with opposite electricity. This charges the plates,<br>
-and the continuous supply of charge and its continuous discharge<br>
-establishes the current.<br>
-<br>
-The accumulation of hydrogen acts to stop the action by polarization.<br>
-Its own affinity for oxygen acts against or in opposition to the<br>
-affinity of the zinc for the same element, and so cuts down the action.<br>
-A depolarizer of some kind is used in acid batteries for this reason. As<br>
-such depolarizer has only to act upon one plate, in most batteries it is<br>
-usual to surround such plate only, as far as it is possible, with the<br>
-depolarizer. The solution which dissolves the zinc is termed the<br>
-excitant or exciting solution.<br>
-<br>
-To this concrete notion of a voltaic battery the different modifications<br>
-described here may be referred. Zinc, it will be seen, forms the almost<br>
-universally used dissolved plate; carbon or copper forms the most usual<br>
-undissolved plate; sulphuric acid in one form or another is the most<br>
-usual excitant.<br>
-<br>
-The solution in a voltaic battery is electrolyzed (see Electrolysis).<br>
-Hence the solutions must be electrolytes. The sulphuric acid and other<br>
-ingredients play a secondary role as imparting to the battery fluids<br>
-this characteristic.<br>
-<br>
-It is not necessary to have electrodes of different substances, the same<br>
-metal maybe used for both if they are immersed in different solutions<br>
-which act differentially upon them, or which act with more energy on one<br>
-than on the other. Such are only of theoretical interest.<br>
-<br>
-<br>
-77&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Water.</span><br>
-A voltaic battery, whose exciting fluid is water. They are used for<br>
-charging quadrant electrometer needles and similar purposes. They<br>
-polarize very quickly and are of high resistance. Hence very small<br>
-plates in large number can be used without impairing their advantage.<br>
-<br>
-Rowland's water battery dispenses with cups and uses capillarity<br>
-instead. The zinc and platinum or copper plates of a couple are placed<br>
-very close together, while the couples are more distant. On dipping into<br>
-water each couple picks up and retains by capillarity a little water<br>
-between its plates, which forms the exciting fluid. Many hundred couples<br>
-can be mounted on a board, and the whole is charged by dipping into<br>
-water and at once removing therefrom. It then develops its full<br>
-potential difference.<br>
-<br>
-<br>
-<img style="width: 583px; height: 622px;" alt="" src="images/077F55.jpg"><br>
-Fig. 55. SECTION OF WOLLASTON BATTERY.<br>
-<br>
-<br>
-<img style="width: 370px; height: 623px;" alt="" src="images/077F56.jpg"><br>
-Fig. 56. PLATES OF WOLLASTON'S BATTERY.<br>
-<br>
-<br>
-78&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Battery, Wollaston.</span><br>
-The original plunge battery is attributed to Wollaston. He also invented<br>
-the battery known by his name, having the disposition shown in the cut,<br>
-of zinc Z, surrounded by a thin sheet of copper C; o, o', o", are the<br>
-terminals and B, B, the battery jars. Dilute sulphuric acid is used for<br>
-exciting fluid.<br>
-<br>
-<br>
-<span style="font-weight: bold;">B. A. U.</span><br>
-Abbreviation for British Association unit, referring generally to the B.<br>
-A. unit of resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">B. A. Unit of Resistance.</span><br>
-The original ohm used under that name previous to 1884. The Paris<br>
-committee of that year recommended as a practical unit what is known as<br>
-the legal ohm. (See Ohm, Legal.)<br>
-&nbsp; 1&nbsp; Legal
-Ohm&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-=&nbsp; 1.0112&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; B. A. Units of Resistance.<br>
-&nbsp; 1&nbsp; B. A. Unit of Resistance&nbsp; =&nbsp;&nbsp;
-.9889&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Legal Ohms.<br>
-&nbsp; 1&nbsp; B. A. Unit of Resistance&nbsp; =&nbsp;&nbsp;
-.98651E9&nbsp;&nbsp; C. G. S. units.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">B. E. adj.</span><br>
-British Engineering, a qualification of a set of units, the B. E. units,<br>
-having for base the foot and pound. The term is but little used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Beaum&eacute; Hydrometer.</span><br>
-A hydrometer graduated on the following principle:<br>
-<br>
-The zero point corresponds to the specific gravity of water for liquids<br>
-heavier than water. A solution of 15 parts of salt in 85 parts of water<br>
-corresponds in specific gravity to 15&deg; B., and between that and zero<br>
-fifteen equal degrees are laid out. The degrees are carried down below<br>
-this point.<br>
-<br>
-The zero points for liquids lighter than water correspond to the<br>
-specific gravity of a solution of 10 parts of salt in 90 parts of water.<br>
-The specific gravity of water is taken as 10&deg; B. This gives ten
-degrees<br>
-which are continued up the scale.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Becquerel's Laws of Thermoelectricity.</span><br>
-These are stated under the heads, Law of Intermediate Metals and Law of<br>
-Successive Temperatures, q. v.<br>
-<br>
-<br>
-Bed Piece.<br>
-In a dynamo or motor the frame carrying it, including often the<br>
-standards in which the armature shaft is journaled, and often the yoke<br>
-or even entire field magnet core.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell, Automatic Electric.</span><br>
-A bell which rings as long as the circuit is closed, having a circuit<br>
-breaker operated by its own motion. (See Bell, Electric.)<br>
-<br>
-Synonyms--Trembling Bell--Vibrating Bell.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell, Call.</span><br>
-A bell operated by electricity, designed to call attention, as to a<br>
-telephone or telegraphic receiver. (See Bell, Electric.)<br>
-<br>
-<br>
-79&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell Call.</span><br>
-A calling device for attracting the attention of any one, consisting of<br>
-some type of electric bell.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell, Circular.</span><br>
-A gong-shaped bell, whose clapper and general mechanism is within its<br>
-cavity or behind it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell, Differentially Wound.</span><br>
-An electric bell, whose magnet is wound differentially so as to prevent<br>
-sparking.<br>
-<br>
-<br>
-<img style="width: 308px; height: 598px;" alt="" src="images/079F57.jpg"><br>
-Fig. 57. AUTOMATIC ELECTRIC BELL.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Bell, Electric.</span><br>
-A bell rung by electricity. Generally it is worked by a current exciting<br>
-an electro-magnet, attracting or releasing an armature which is attached<br>
-to the vibrating or pivoted tongue of the bell. It may be worked by a<br>
-distant switch or press-button, q. v., ringing once for each movement of<br>
-the distant switch, etc., or it may be of the vibrating bell type as<br>
-shown in the cut. When the current is turned on in this case it attracts<br>
-the armature. As this moves towards the poles of the magnet it breaks<br>
-the circuit by drawing the contact spring, q. v., away from the contact<br>
-point, q. v. This opens the circuit, to whose continuity the contact of<br>
-these two parts is essential. The hammer, however, by its momentum<br>
-strikes the bell and at once springs back. This again makes the contact<br>
-and the hammer is reattracted. This action continues as long as the<br>
-circuit is closed at any distant point to which it may be carried. The<br>
-ordinary vibrating bell is a typical automatic circuit breaker, q. v.,<br>
-this type keeping up the ringing as long as the circuit is closed. Other<br>
-bells have no electric contact and simply ring once every time the<br>
-circuit is closed. Others worked by an alternating current ring once for<br>
-each change of direction of current.<br>
-<br>
-<br>
-80&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Bell, Electro-mechanical.</span><br>
-A bell which has its striking train operated by a spring or descending<br>
-weight, and which train is thrown into action by the release of a detent<br>
-or equivalent action by the closing of an electric circuit. It rings for<br>
-any given time after being started.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell, Indicating.</span><br>
-A bell which by drop-shutter or other indicator connected in circuit<br>
-with it, indicates its number or other designation of its call.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell, Magneto.</span><br>
-An electric bell operated by the alternating current from a magneto<br>
-generator. It has a polarized armature and no circuit breaker. The<br>
-armature is attracted first in one direction and then in the other, as<br>
-the current alternates and reverses the polarity of the electro-magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bell, Relay.</span><br>
-A bell operated by a relay circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bias.</span><br>
-In polarized relay the adjustment of the tongue to lie normally against<br>
-one or the other contact. (See Relay, Polarized.)<br>
-<br>
-<br>
-81&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 661px; height: 374px;" alt="" src="images/080F58.jpg"><br>
-Fig. 58. RESISTANCE COILS SHOWING BIFILAR WINDING.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bifilar Winding.</span><br>
-The method followed in winding resistance coils to prevent them from<br>
-creating fields of force. The wire is doubled, and the doubled wire<br>
-starting with the bend or bight is wound into a coil. The current going<br>
-in opposite senses in the two lays of the winding produces no field of<br>
-force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Binary Compound.</span><br>
-A chemical compound whose molecule contains only two elements, such as<br>
-water (H2 0), lead oxide (Pb 0), and many others.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Binding.</span><br>
-In a dynamo or motor armature the wire wound around the coils to secure<br>
-them in place and prevent their disturbance by centrifugal action.<br>
-<br>
-<br>
-<img style="width: 458px; height: 565px;" alt="" src="images/081F59.jpg"><br>
-Fig. 59. DOUBLE BINDING POST.<br>
-<br>
-<br>
-<img style="width: 298px; height: 586px;" alt="" src="images/081F60.jpg"><br>
-Fig. 60. BINDING POST, ENGLISH PATTERN.<br>
-<br>
-<br>
-<img style="width: 227px; height: 622px;" alt="" src="images/081F61.jpg"><br>
-FIG. 61. WOOD SCREW BINDING POST.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Binding Posts or Screws.</span><br>
-Arrangements for receiving the loose end of a wire of an electric<br>
-circuit, and securing such end by a screw. Several constructions are<br>
-used, as shown here. Sometimes the wire is passed through a hole, and a<br>
-screw tapped in at right angles to the hole is screwed down upon the<br>
-wire. Sometimes the wire is clamped between two shoulders, one on the<br>
-screw, the other on the post. The screw is often a flat-headed thumb<br>
-screw or has a milled edge. Sometimes the screw has a slot and is turned<br>
-by a screw-driver.<br>
-<br>
-Several openings are often provided in the same post for different<br>
-wires.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Binnacle.</span><br>
-The case containing a mariner's compass on shipboard. It is enclosed<br>
-completely; it has a glass side or window through which the compass can<br>
-be seen, and is provided with one or two lamps arranged to light the<br>
-card, while showing as little light as possible outside.<br>
-<br>
-<br>
-82&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bioscopy, Electric.</span><br>
-The diagnosis of life and death by the action of the animal system when<br>
-subjected to an electric current or electrification.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bismuth.</span><br>
-A metal, one of the elements, atomic weight, 210 ; equivalent, 70;<br>
-valency, 3; specific gravity, 9.9. It is a conductor of electricity.<br>
-Relative Resistance, compressed, (silver = 1)&nbsp;&nbsp; 87.23<br>
-Specific Resistance,&nbsp;&nbsp; 131.2 microhms<br>
-Resistance of a wire<br>
-&nbsp; (a) 1 foot long,&nbsp; weighing 1 grain,&nbsp;&nbsp;&nbsp;&nbsp;
-18.44&nbsp;&nbsp; ohms<br>
-&nbsp; (b) 1 foot long,&nbsp; 1/1000 inch thick,&nbsp;&nbsp;
-789.3&nbsp; "<br>
-&nbsp; (c) 1 meter long, weighing 1 gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-12.88&nbsp;&nbsp; "<br>
-&nbsp; (d) 1 meter long, 1 millimeter thick,&nbsp;&nbsp;&nbsp;
-1.670&nbsp;&nbsp; "<br>
-Resistance of a 1-inch cube&nbsp;&nbsp; 51.65&nbsp;&nbsp; microhms<br>
-Electro chemical equivalent,&nbsp;&nbsp; .7350&nbsp; (Hydrogen = .0105)<br>
-(See Thermo-electric Series.)<br>
-<br>
-<br>
-<img style="width: 470px; height: 646px;" alt=""
- src="images/082F62_63.jpg"><br>
-Figs. 62, 63. INCANDESCENT WIRE FUSE.&nbsp; ABEL'S PATENT.<br>
-<br>
-<br>
-<img style="width: 560px; height: 742px;" alt="" src="images/082F64.jpg"><br>
-Fig. 64.&nbsp; VON EBNER'S FRICTIONAL ELECTRIC MACHINE FOR<br>
-EXPLODING ELECTRIC FUSES OR DETONATORS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bi-telephone.</span><br>
-A pair of telephones arranged with a curved connecting arm or spring, so<br>
-that they can be simultaneously applied to both ears. They are<br>
-self-retaining, staying in position without the use of the hands.<br>
-<br>
-<br>
-83&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Blasting, Electric.</span><br>
-The ignition of blasting charges of powder or high explosives by the<br>
-electric spark, or by the ignition to incandescence (red or white heat)<br>
-of a thin wire immersed in or surrounded by powder. Special influence or<br>
-frictional electric machines or induction coils are used to produce<br>
-sparks, if that method of ignition is employed. For the incandescent<br>
-wire a hand magneto is very generally employed. (See Fuse, Electric.)<br>
-<br>
-The cuts, Figs. 62 and 63, show one form of incandescent wire fuse. The<br>
-large wires are secured to the capsule, so that no strand can come upon<br>
-the small wire within the cavity.<br>
-<br>
-The cut, Fig. 64, shows a frictional electric machine for igniting spark<br>
-fuses.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bleaching, Electric.</span><br>
-Bleaching by agents produced or made available by the direct action of<br>
-electricity. Thus if a current under proper conditions is sent through a<br>
-solution of common salt (sodium chloride), the electrodes being close<br>
-together, the salt is decomposed, chlorine going to one pole and sodium<br>
-hydrate to the other. The two substances react upon each other and<br>
-combine, forming sodium hypochlorite, which bleaches the tissue immersed<br>
-in its solution.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Block System.</span><br>
-A system of signalling on railroads. The essence of the system consists<br>
-in having signal posts or stations all along the road at distances<br>
-depending on the traffic. The space between each two signal posts is<br>
-termed a block. From the signal posts the trains in day time are<br>
-signalled by wooden arms termed semaphores, and at night by lanterns.<br>
-The arms may be moved by hand or by automatic mechanism depending in<br>
-part on electricity for carrying out its functions. Thus in the<br>
-Westinghouse system the semaphores are moved by pneumatic cylinders and<br>
-pistons, whose air valves are opened and shut by the action of solenoid<br>
-magnets, q. v. The current of these magnets is short circuited by<br>
-passing trains, so as to let the valves close as the train passes the<br>
-signal post. The block system causes the semaphore to be set at "danger"<br>
-or "caution," as the train enters the next block. Then the following<br>
-train is not allowed to enter the block until the safety signal is<br>
-shown. The Westinghouse system provides for two semaphores on a post,<br>
-one indicating "danger" as long as the train is on the next block; the<br>
-other indicating "caution" as long as the train is on the next two<br>
-blocks. The rails form part of the circuit, their joints being bridged<br>
-by copper wire throughout the block, and being insulated where the<br>
-blocks meet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Block Wire.</span><br>
-In the block system a wire connecting adjacent block-signal towers or<br>
-semaphore poles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Blow-pipe.</span><br>
-A name sometimes given to an electric experiment illustrating the<br>
-repulsion of electrified air particles from a point held at high<br>
-relative potential. A metallic point, placed on the prime conductor of<br>
-an electric friction or influence machine, becomes highly electrified,<br>
-and the air becoming excited is repelled and acts upon the candle flame.<br>
-If the candle is placed on the conductor and a point held towards it the<br>
-repulsion is still away from the point.<br>
-<br>
-<br>
-84&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Blow-pipe, Electric Arc.</span><br>
-A name sometimes given to devices for using the voltaic arc to produce<br>
-local heating effects. The directive action of the magnet may be used to<br>
-force out the arc like a blow-pipe flame, or a blast of air may be<br>
-directly applied for the same purpose.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Blue-stone.</span><br>
-A trade name for crystallized copper sulphate, used in Daniell's and<br>
-gravity batteries.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Boat, Electric.</span><br>
-A boat propelled by electricity. The electricity drives a motor which<br>
-actuates a screw propeller. The current is generally supplied by a<br>
-storage battery. When used on rivers charging stations are established<br>
-at proper places. When the boat is used as a tender or launch for a<br>
-steam ship, such as a war-vessel, the battery is charged by a plant on<br>
-board the ship. From their noiselessness electric boats are peculiarly<br>
-available for nocturnal torpedo operations, and the universal equipment<br>
-of modern war-ships with electric lightning and power plants makes their<br>
-use possible at all points. This type is often termed an electric<br>
-launch, and most or all electric boats fall under this category.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bobbins.</span><br>
-A spool of wood or other material wound with insulated wire. In a<br>
-tangent galvanometer the bobbin becomes a ring, with a channel to<br>
-receive the winding. As the ring is not infinitely large compared to the<br>
-needle the tangent law is not absolutely fulfilled. It is most<br>
-accurately fulfilled (S. P. Thomson) when the depth of the groove or<br>
-channel in the radial direction bears to the breadth in the axial<br>
-direction the ratio of square root of 3 to the square root of 2 or<br>
-approximately 11 : 9<br>
-<br>
-<br>
-<span style="font-weight: bold;">Body Protector.</span><br>
-A metallic short circuit connected with the wrists and lower legs of the<br>
-human body, so that if by accident an active circuit is grounded by the<br>
-hands and body of the workman wearing it, most of the current will pass<br>
-through the wire conductors, thus avoiding the vital organs of the body.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Boiler Feed, Electric.</span><br>
-An apparatus by which an electric current acting on an electro-magnet,<br>
-or other equivalent device, opens the water supply when the water level<br>
-in a boiler sinks too low, and cuts off the water supply as the water<br>
-level rises.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Boiling.</span><br>
-In secondary batteries the escape of hydrogen and oxygen gas when the<br>
-battery is charged. The bubbling of the escaping gases produces the<br>
-effect of boiling.<br>
-<br>
-<br>
-85&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Boll.</span><br>
-An absolute, or c. g. s., unit of momentum; a gram moving at the rate of<br>
-one centimeter per second; a gram-kine (see Kine); a unit proposed by<br>
-the British Association.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bolometer.</span><br>
-An apparatus for detecting small amounts of radiant energy (radiant<br>
-heat, so called). A coil suspended by a fine wire or filament so as to<br>
-be free to rotate under the effect of force is made up of two parallel<br>
-and equal wires, insulated from each other, but connected so that<br>
-parallel currents sent through them go in opposite direction through<br>
-each. This coil is hung in a strong electro-magnetic field produced by a<br>
-large coil surrounding it. When a current passes through the suspended<br>
-coil no effect will follow, because the oppositely wound portions<br>
-counteract each other exactly. In the circuit with one half of the<br>
-suspended coil is an exceedingly thin strip of platinum wire. The other<br>
-half of the coil has no strips. Both halves unite after leaving the<br>
-coil. If now the strip of platinum is heated its conductivity is<br>
-affected and its half of the coil receives less current than the other<br>
-half. This disturbs the balance and the coil swings through a small arc.<br>
-This apparatus may be made very sensitive, so that an increase of<br>
-temperature of 1/1400&ordm; F., 9/70000&deg;C. (1/14000&ordm; F.) will
-be perceptible.<br>
-Another construction takes the form of a Wheatstone Bridge, q. v., in<br>
-whose arms are introduced resistances consisting of bands of iron, .5<br>
-Millimeter wide (.02 inches), .004 millimeter (.00016 inch) thick, and<br>
-folded on themselves 14 times so as to make a rectangular grating, 17 x<br>
-12 millimeters (.68 x .48 inch). The least difference of heat applied to<br>
-the grating affects the galvanometer.<br>
-<br>
-Synonym-Thermic Balance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Boreal Pole.</span><br>
-The south pointing pole of the magnet. (See Austral Pole.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bot.</span><br>
-A colloquial expression for the English Board of Trade unit of<br>
-Electrical Supply. It is formed of the initials of the words "Board of<br>
-Trade." (See Unit, Board of Trade.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Box Bridge.</span><br>
-A constriction of Wheatstone's Bridge in which the necessary resistance<br>
-coils are contained in a single box with plugs for throwing the coils in<br>
-and out of circuit, and connections to bring the coils into the<br>
-different arms of the system. The cut shows a box bridge. Connections<br>
-for the galvanometer, battery wires, and terminals of the unknown<br>
-resistance are provided, by which its resistances and the connections<br>
-are brought into the exact relations indicated in the conventional<br>
-diagram of Wheatstone's bridge. (See Wheatstone's Bridge.)<br>
-<br>
-Referring to the cut, the battery wire, say from the zinc plate,<br>
-connects at A1, thereby reaching A, its true connecting point. To B1 one<br>
-end of the galvanometer circuit or lead is attached, thereby reaching B,<br>
-its true connecting point. To C are connected the other end from the<br>
-galvanometer and one end of the unknown resistance. The other end of the<br>
-unknown resistance, and the other end of the battery wire, in this case<br>
-from the carbon plate, connect to D. At G is an infinity plug, as it is<br>
-called. When out it breaks the circuit.<br>
-<br>
-In use after the connections are made the key is depressed and the<br>
-galvanometer observed. The resistance is changed until no action of the<br>
-galvanometer is produced by closing the circuit when the ratio of the<br>
-resistances of the arms gives the proportion for calculating the unknown<br>
-resistances.<br>
-<br>
-Synonym--Commercial Wheatstone Bridge, or commercial form of same.<br>
-<br>
-<br>
-<img style="width: 592px; height: 443px;" alt="" src="images/086F65.jpg"><br>
-Fig. 65. TOP OF BOX BRIDGE.<br>
-<br>
-<br>
-86&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Boxing the Compass.</span><br>
-Naming the thirty-two points of the compass in order, and in sequence to<br>
-any point called out at random. There are many exercises in the relative<br>
-sailing points and bearings that come under the same head. Thus the<br>
-direction of two given points being given by names of the compass<br>
-points, it may be required to state the number of points intervening.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Brake, Electro-magnetic.</span><br>
-A brake to stop a wheel from rotating. It comprises a shoe, or sometimes<br>
-a ring, which by electro-magnetic attraction is drawn against the<br>
-rotating wheel, thus preventing it from turning, or tending to bring it<br>
-to rest. (See Electro-magnet, Annular.)<br>
-<br>
-<br>
-<img style="width: 625px; height: 449px;" alt="" src="images/087F66.jpg"><br>
-Fig. 66. ELECTRIC BRAKE.<br>
-<br>
-<br>
-87&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Branch.</span><br>
-A conductor branching from a main line. Sometimes the term is restricted<br>
-to a principal conductor, from which current is distributed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Branch Block.</span><br>
-In electric wiring of buildings, a block of porcelain or other material<br>
-with grooves, holes and screws for the connection of branch wires to a<br>
-main wire. Its functions are not only to afford a basis for connecting<br>
-the wires, but also to contain safety fuses. As when a branch wire is<br>
-taken off, fuses have to be put in its line, the branch block carries<br>
-these also. One end of each fuse connects with a main wire, the other<br>
-end connects with one of the wires of the branch leader or wire.<br>
-<br>
-Porcelain is a favorite material for them, as the fusing or "blowing<br>
-out" of the safety fuses cannot set it on fire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Branch Conductor.</span><br>
-A parallel or shunt conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brazing, Electric.</span><br>
-Brazing in which the spelter is melted by means of electricity; either<br>
-current incandescence or the voltaic arc may be used. It is identical in<br>
-general with electric welding. (See Welding, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Branding, Electric.</span><br>
-A system of branding in which the heat of electrically ignited or<br>
-incandescent conductors is used to produce or burn in the marks upon the<br>
-surface. For the alternating current a small transformer is connected to<br>
-or forms part of the tool.<br>
-<br>
-<br>
-88&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brassing.</span><br>
-The deposition of a coating of brass by electrolysis. The plating bath<br>
-contains both copper and zinc. As anode a plate of brass is used. The<br>
-operation must be constantly watched. The deposition of both metals goes<br>
-on simultaneously, so&nbsp; that a virtual alloy is deposited. By
-changing<br>
-the depth of immersion of the anode the color of the deposit is varied.<br>
-<br>
-As a formula for a brassing bath the following are typical. They are<br>
-expressed in parts by weight.<br>
-<br>
-(a) For iron and steel.<br>
-<span style="font-family: monospace;">I.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Sodium
-Bisulphate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-200</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Potassium Cyanide, 70 per
-cent.,&nbsp;&nbsp; 500</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Sodium
-Carbonate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1,000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-8,000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">II.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Copper
-Acetate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-125</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Zinc
-Chloride,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-100</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2,000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Add the second solution to the
-first.</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">(b) For zinc.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">I.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Sodium
-Bisulphate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-700</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Potassium Cyanide, 70 per
-cent., 1,000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-20,000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">II.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Copper
-Acetate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-350</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Zinc
-Chloride,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-350</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Aqua
-Ammoniae,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-400</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5,000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Add the second solution to the
-first.</span><br>
-<br>
-Use a brass anode; add more zinc to produce a greenish color; more<br>
-copper for a red color. A weak current gives a red color; a strong<br>
-current lightens the color. The battery power can be altered, a larger<br>
-or smaller anode can be used, or a copper or zinc anode can be used to<br>
-change the color of the deposit. The bath may vary from 1.036 to 1.100<br>
-sp. gr., without harm.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Break.</span><br>
-A point where an electric conductor is cut, broken, or opened by a<br>
-switch or other device, or simply by discontinuity of the wires.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Break-down Switch.</span><br>
-A switch used in the three-wire system to provide for the discontinuance<br>
-of the running of one of the dynamos.<br>
-<br>
-By connecting the positive and negative bus wires to one terminal of the<br>
-active dynamo, and the neutral bus wire to the other terminal, one<br>
-dynamo will supply the current and the system operates like a two-wire<br>
-system, but can only be used for half its normal capacity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Breaking Weight.</span><br>
-The weight which, applied in tension, will break a prism or cylinder, as<br>
-an electric current conductor.<br>
-<br>
-<br>
-89&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Breath Figures, Electric.</span><br>
-If a conductor is electrified and placed upon a piece of glass, it will<br>
-electrify the glass in contact with it by conduction or discharge. On<br>
-removing the conductor the glass remains electrified. The localized<br>
-electrification is shown by breathing gently on the glass, when a<br>
-species of image of the conductor is produced by the condensed moisture.<br>
-A coin is often used for conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Breeze, Electric.</span><br>
-A term in medical electricity, used to designate the silent or brush<br>
-discharge of high tension electricity. As an instance of its employment,<br>
-the electric head bath (see Bath, Electric Head,) may be cited. The<br>
-patient forming one electrode, being insulated and connected to one of<br>
-the conductors, the other conductor, on being brought near his person,<br>
-discharges into his body.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bridge.</span><br>
-(a) A special bar of copper connecting the dynamos to the bus wire, q.
-v.,<br>
-in electric lighting or power stations.<br>
-<br>
-(b) Wheatstone's bridge, q. v., and its many modifications, all of which<br>
-may be consulted throughout these pages.<br>
-<br>
-<br>
-<span style="font-weight: bold;">British Association Bridge.</span><br>
-The type of Wheatstone bridge used by the committee of the association<br>
-in determining the B. A. ohm; the meter bridge, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Broadside Method.</span><br>
-A method of determining the magnetic moment of a magnet. The magnet, n,<br>
-s, under examination is fixed so that it is at right angles to the<br>
-magnetic meridian, M, R, which passes through its own center and that of<br>
-a compass needle. From the deflection of the latter the moment is<br>
-calculated.<br>
-<br>
-<br>
-<img style="width: 229px; height: 646px;" alt="" src="images/089F67.jpg"><br>
-Fig. 67. BROADSIDE METHOD.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bronzing.</span><br>
-In electro-plating the deposition of a mixture or virtual alloy of<br>
-copper and tin. In general manipulation it resembles the operation of<br>
-depositing gold and silver alloy, or of brassing.<br>
-<br>
-For bronzing the following bath is recommended:<br>
-<br>
-Prepare each by itself (a) a solution of copper phosphate and (b) a<br>
-solution of stannous chloride in a solution of sodium pyrophosphate. For<br>
-a, dissolve recently precipitated copper phosphate in concentrated<br>
-solution of sodium pyrophosphate. For b, add to a saturated solution of<br>
-sodium pyrophosphate solution of stannous chloride as long as the<br>
-precipitate which is formed dissolves. Of these two solutions add to a<br>
-solution of sodium pyrophosphate which contains about 1.75 oz. of the<br>
-salt to the quart, until the precipitate appears quickly and of the<br>
-desired color. For anodes use cast bronze plates. Sodium phosphate must<br>
-be added from time to time; if the deposit is too light add copper<br>
-solution, if too dark add tin solution. (W. T. Brannt.)<br>
-<br>
-<br>
-90&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brush.</span><br>
-In electric current generators and motors, the pieces of copper or other<br>
-material that bear against the cylindrical surface of the commutator are<br>
-thus termed. Many different constructions have been employed. Some have<br>
-employed little wheels or discs bearing against and rotating on the<br>
-surface of the commutator. A bundle of copper strips is often employed,<br>
-placed flatwise. Sometimes the same are used, but are placed edgewise.<br>
-Wire in bundles, soldered together at their distant ends have been<br>
-employed. Carbon brushes, which are simply rods or slabs of carbon, are<br>
-used with much success.<br>
-<br>
-Synonym--Collecting Brush.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brush, Carbon.</span><br>
-A brush for a dynamo or motor, which consists of a plate or rod of<br>
-carbon, held in a brush holder and pressed against the commutator<br>
-surface.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brushes, Adjustment of.</span><br>
-In electric current generators and motors, the brushes which bear upon<br>
-the commutator when the machine is in action need occasional adjustment.<br>
-This is effected by shifting them until sparking between them and the<br>
-commutator is nearly or quite suppressed.<br>
-<br>
-<br>
-<img src="images/090F68.jpg" alt="" style="width: 629px; height: 532px;"><br>
-Fig. 68. BRUSH HOLDER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brushes, Lead of.</span><br>
-In a dynamo electric generator, the lead or displacement in advance of<br>
-or beyond the position at right angles to the line connecting the poles<br>
-of the field magnet, which is given the brushes. In a motor the brushes<br>
-are set back of the right angle position, or are given a negative lead.<br>
-(See Lag.)<br>
-<br>
-<br>
-91&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brush Holders.</span><br>
-The adjustable (generally) clutch or clamps for holding the commutator<br>
-brushes of a dynamo, which keep them in contact with the commutator, and<br>
-admit of adjustment by shifting backward and forward of the brushes to<br>
-compensate for wear. They are connected to and form part of the rocker,<br>
-q. v. By rotating the latter the brush-holders and brushes are carried<br>
-in one direction or other around the commutator, so as to vary the lead<br>
-as required.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brush, Pilot.</span><br>
-A third brush, used for application to different parts of a revolving<br>
-armature commutator to determine the distribution of potential<br>
-difference between its different members. (See Curve of Distribution of<br>
-Potential in Armature.) One terminal of a volt-meter is connected to one<br>
-of the regular brushes, A, of a dynamo; the other to a third brush, p,<br>
-which is pressed against different portions of the commutator of the<br>
-dynamo. The readings of the volt-meter are plotted in a curve of<br>
-distribution of potential.<br>
-<br>
-<br>
-<img style="width: 637px; height: 536px;" alt="" src="images/091F69.jpg"><br>
-Fig. 69. PILOT BRUSH.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brush, Rotating.</span><br>
-Brushes for taking off the current from dynamo commutators, or giving<br>
-current connection to motors, whose ends are in the form of rollers<br>
-which rotate like little wheels, and press against the commutator<br>
-surface.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Brush, Third.</span><br>
-A third brush is sometimes provided in a dynamo for regulating purposes.<br>
-Applied to a series machine it adjoins one of the regular brushes and<br>
-delivers its current to a resistance, to whose further end the regular<br>
-circuit is connected. By a sliding connection the resistance is divided<br>
-between the third brush circuit and the regular circuit, and by varying<br>
-the position of this contact regulation is obtained.<br>
-<br>
-It is to be distinguished from the pilot brush used for determining the<br>
-characteristic of the commutator, although based on the same general<br>
-principles.<br>
-<br>
-<br>
-<img style="width: 641px; height: 622px;" alt="" src="images/092F70.jpg"><br>
-Fig. 70. THIRD BRUSH REGULATION.<br>
-<br>
-<br>
-92&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Brush, Wire Gauze.</span><br>
-A collecting or commutator brush for a dynamo or motor, which brush is<br>
-made of wire gauze rolled up and compressed into shape.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Buckling.</span><br>
-The bending up and distortion of secondary battery plates. It is largely<br>
-due to over-exhausting the batteries. Where the E. M. F. is never<br>
-allowed to fall below 1.90 volt it is far less liable to occur.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bug.</span><br>
-Any fault or trouble in the connections or working of electric<br>
-apparatus.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bug Trap.</span><br>
-A connection or arrangement for overcoming a "bug." It is said that the<br>
-terms "bug" and "bug trap" originated in quadruplex telegraphy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bunsen Disc.</span><br>
-In photometry, the Bunsen Disc is a piece of paper upon whose centre a<br>
-spot is saturated with melted paraffin, or a ring of paraffined surface<br>
-surrounds an untouched central spot. If placed in such a position that<br>
-it receives an equal illumination on each side, the spot almost<br>
-disappears. It is used on the bar photometer. (See Photometer, Bar.)<br>
-<br>
-Synonym--Grease Spot.<br>
-<br>
-<br>
-93&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Buoy, Electric.</span><br>
-A buoy for use to indicate channels or dangers in harbors and elsewhere,<br>
-which carries an electric light, whose current is supplied by cable from<br>
-shore. It has been proposed to use glass tubes exhausted of air and<br>
-containing mercury, which, as moved by the waves, would produce a<br>
-luminous effect. A fifty-candle power incandescent lamp is an approved<br>
-source of light.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Burner, Electric Gas.</span><br>
-A gas burner arranged for the flame to be lighted by electricity. It<br>
-takes a great variety of forms. In some cases a pair of terminals are<br>
-arranged near the flame or a single terminal is placed near the metal<br>
-tip, the latter forming one of the terminals. The spark is generally<br>
-produced by an induction coil, or a spark coil. The gas may first be<br>
-turned on and the spark then passed. Sometimes the turning of the gas<br>
-cock of an individual burner makes and breaks a contact as it turns, and<br>
-thereby produces simultaneously with the turning on of the gas a spark<br>
-which lights it.<br>
-<br>
-Another form is wholly automatic. A pair of electro-magnets are attached<br>
-below the base of the burner, one of which, when excited, turns on the<br>
-gas, and the other one when it is excited turns it off. At the same time<br>
-a spark is produced with the turning on of the gas so that it is<br>
-lighted. Thus, by use of a automatic burner, a distant gas burner can be<br>
-lighted by turning an electric switch. An out-door lamp may be lighted<br>
-from within a house.<br>
-<br>
-The increasing use of electric incandescent lamps, lighted by the<br>
-turning of a switch, tends to displace electric gas burners. The latter<br>
-have been classified into a number of types depending on their<br>
-construction.<br>
-<br>
-Burners are sometimes connected in series with leads from an induction<br>
-coil. Then the gas is turned on all at once, and a succession of sparks<br>
-passed until the gas is all lighted. The ignition is practically<br>
-instantaneous.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Button, Push.</span><br>
-A species of switch which is actuated by the pressure of a button. In<br>
-its normal position the button is pressed outwards by a spring, and the<br>
-circuit is open. When pressed inwards, it closes the circuit. When<br>
-released it springs backward and opens the circuit again.<br>
-<br>
-They are principally used for ringing bells. If the latter are of the<br>
-automatic type, they ring as long as the button is pressed.<br>
-<br>
-For door-bells and room-bells, the button often occupies the center of a<br>
-rosette of wood or bronze or other ornamental piece. Sometimes, as shown<br>
-in the cut, they are constructed for use on floors to be pressed by the<br>
-foot. The general principle of their construction is shown, although the<br>
-method of making the contact varies.<br>
-<br>
-Synonym--Press Button.<br>
-<br>
-<br>
-<img style="width: 388px; height: 479px;" alt="" src="images/093F71.jpg"><br>
-Fig. 71. FLOOR PUSH BUTTON.<br>
-<br>
-<br>
-94&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Burning.</span><br>
-(a) In a dynamo, the production of shifting and temporary arcs between<br>
-the commutator and brushes, which arcs produce heat enough to injure the<br>
-parts in question.<br>
-<br>
-(b) In electro-plating, a defect due to too strong a current in<br>
-proportion to the strength of solution and area of electrodes. This<br>
-gives a black or badly-colored deposit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Bus Rod.</span><br>
-A copper conductor used in electric lighting or power stations, to<br>
-receive the current from all the dynamos. The distributing leads are<br>
-connected to the bus wires.<br>
-<br>
-In the three-wire system there are three; in the two-wire system there<br>
-are two bus wires.<br>
-<br>
-The name is undoubtedly derived from "omnibus."<br>
-<br>
-The bus wires may be divided into positive, negative, and, in the<br>
-three-wire system, neutral bus wires.<br>
-<br>
-Synonyms--Omnibus Rod, Wire, or Bar--Bus Bar, or Wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Buzzer.</span><br>
-An electric alarm or call produced by a rapid vibration of electric make<br>
-and break mechanism, which is often magnified by enclosure in a<br>
-resonating chamber, resembling a bell, but which is not struck or<br>
-touched by the vibrating parts. Sometimes a square wooden box is used as<br>
-resonator.<br>
-<br>
-<br>
-<img style="width: 716px; height: 592px;" alt="" src="images/094F72.jpg"><br>
-Fig. 72. BUZZER.<br>
-<br>
-<br>
-95&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">B. W. G.</span><br>
-Abbreviation for Birmingham Wire Gauge. (See Wire Gauge, Birmingham.)<br>
-</big></big><br>
-<big><big><span style="text-decoration: underline;"></span></big></big><big><big><span
- style="font-weight: bold;"><br>
-<br>
-C.</span><br>
-(a) Abbreviation for Centigrade, as 100 C., meaning 100 Centigrade. (See<br>
-Centigrade Scale.)<br>
-<br>
-(b) A symbol of current or of current strength. Thus in the expression<br>
-of Ohm's law C = E/R. C indicates current strength or intensity, not in<br>
-any fixed unit, but only in a unit of the same order in which E and R<br>
-are expressed; E Indicating electro-motive force and R resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable.</span><br>
-(a) Abbreviation for Cablegram, q. v.<br>
-<br>
-(b) v. It is also used as a verb, meaning to transmit a message by<br>
-submarine cable.<br>
-<br>
-(c). An insulated electric conductor, of large diameter. It often is<br>
-protected by armor or metallic sheathing and may be designed for use as<br>
-an aerial, submarine, subterranean or conduit cable. A cable often<br>
-contains a large number of separately insulated conductors, so as to<br>
-supply a large number of circuits.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable, Aerial.</span><br>
-A cable usually containing a large number of separately insulated wires,<br>
-and itself insulated. It is suspended in the air. As its weight is<br>
-sometimes so great that it could not well sustain it, a suspending wire<br>
-is in such cases carried along with it, to which it is suspended by<br>
-cable hangers, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable Box.</span><br>
-A box for receiving underground cable ends and connecting the separate<br>
-wires of the cable to air-line wires. It is often mounted on a pole,<br>
-which forms the starting point of the air-line portion of the system.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable, Bunched.</span><br>
-A cable containing a number of separate and individual conductors. In<br>
-some forms it consists virtually of two or more small cables laid<br>
-tangent to each other and there secured. Thus each in section represents<br>
-two or more tangent circles with the interstice solidly filled with the<br>
-metal sheathing.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cable, Capacity of.</span><br>
-The electrostatic capacity of a cable. A cable represents a Leyden jar<br>
-or static condenser. The outer sheathing or armor, or even the more or<br>
-less moist coating, if it is unarmored, represents one coating. The wire<br>
-conductors represent the other coating, and the insulator is the<br>
-dielectric.<br>
-<br>
-The capacity of a cable interferes with its efficiency as a conductor of<br>
-broken or interrupted currents, such as are used in telegraphy or<br>
-telephoning. As each impulse or momentary current is sent into the line,<br>
-it has to charge the cable to at least a certain extent before the<br>
-effects of the current are perceptible at the other end. Then the cable<br>
-has to discharge itself. All this creates a drag or retardation.<br>
-<br>
-The capacity of a cable is used to determine the locality of breaks in<br>
-the continuity of the conductors. The capacity per unit of length being<br>
-accurately known, it is obvious that, if the conductor breaks without<br>
-disturbance of the insulator, the distance of the break from the end can<br>
-be ascertained by determining the capacity of the cable from one end.<br>
-This capacity will be in proportion to the capacity of a mile, a knot or<br>
-any fixed unit, as the distance to the break is to the length used as<br>
-standard.<br>
-<br>
-<br>
-96&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable Core.</span><br>
-The conductors of a cable. They are generally copper wire. In a<br>
-telephone cable they may be very numerous and insulated from each other.<br>
-In ocean cables they may be a group of bare wires twisted or laid<br>
-together. Sometimes the conductors are arranged for metallic circuits,<br>
-each pair being distinguished by special colored windings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable, Duplex.</span><br>
-A cable containing two wires, each with separate insulation, so as to be<br>
-virtually two cables, laid and secured parallel and side by side.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable, Flat.</span><br>
-A cable, flat in shape, so as to lie closely against a wall or ceiling.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cablegram.</span><br>
-A message which has been transmitted or is to be transmitted by a<br>
-submarine cable. It is sometimes called a cable.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable Grip.</span><br>
-A grip for holding the end of a cable, when the cable is to be drawn<br>
-into a conduit in a subway. It is an attachment to provide the cable<br>
-with an eye or loop. Its end is a split socket and embraces the end of<br>
-the cable, and is secured thereto by bolts driven through the cable end.<br>
-In drawing a cable into a conduit a capstan and rope are often used, and<br>
-the rope is secured to the cable end by the grip.<br>
-<br>
-<br>
-<img style="width: 589px; height: 425px;" alt="" src="images/096F73.jpg"><br>
-Fig. 73. CABLE HANGER, CABLE, AND SUSPENDING WIRE.<br>
-<br>
-<br>
-<img style="width: 339px; height: 510px;" alt="" src="images/096F74.jpg"><br>
-Fig. 74. CABLE HANGER, OPEN.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable Hanger.</span><br>
-When a heavy electric cable is suspended from poles it often would be<br>
-unsafe to trust to its longitudinal strength to support or sustain its<br>
-own weight unless the poles were very near together. In such case an<br>
-auxiliary or sustaining wire is run along with it, and by clips or<br>
-hangers the cable is connected thereto at as frequent intervals as seem<br>
-desirable. The contrivance may take the form of a strip of metal<br>
-surrounding the cable and carrying a hook or eye through which the<br>
-supporting wire passes.<br>
-<br>
-Synonym--Cable Clip.<br>
-<br>
-<br>
-97&nbsp; STANDARD ELECTRICAL DICTIONARY<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable Hanger Tongs.</span><br>
-Tongs for attaching cable hangers, q.v. They have long handles so as to<br>
-be worked from the ground at the middle of a span.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable, Suspending Wire of.</span><br>
-A wire by which an aerial cable is in part or entirely suspended. The<br>
-cable, being incapable of sustaining its own weight, is secured by clips<br>
-or hangers to a wire, strong from pole to pole immediately above it.<br>
-(See Cable Hanger.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cable Tank.</span><br>
-A tank in which a submarine cable is coiled away on board a cable-laying<br>
-ship, or in the factory on shore for the purpose of testing or<br>
-watching its insulation. Sometimes, in order to test it under pressures<br>
-approximating to those it will be subjected to in practice, the tank is<br>
-closed and the portion of cable within it is subjected to hydraulic<br>
-pressure. This represents the pressure it will be exposed to in deep<br>
-water.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Calamine.</span><br>
-A mineral; zinc silicate; formula Zn2 Si 03, crystalline system,<br>
-Orthorhombic; specific gravity, 3.16-3.9.<br>
-<br>
-The crystals often show strong pyroelectric properties.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Calibration.</span><br>
-The determination by experiment or calculation of the value of the<br>
-readings of an instrument, such as a galvanometer or eudiometer. Thus if<br>
-a tangent galvanometer has its circle graduated in degrees, a table of<br>
-the value of tangents corresponding to every reading occurring in<br>
-practice would represent a calibration by calculation. A determination<br>
-of the current required to produce each deflection would be a<br>
-calibration in the more usual sense. Calibration is generally absolute,<br>
-as referring to some fixed unit, but it may be relative, as between two<br>
-things both of unknown absolute value.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Calibration, Absolute.</span><br>
-The determination of the absolute value of currents producing given<br>
-deflections in a galvanometer, or in other instruments the determination<br>
-of corresponding values, as the instrument may be a magnetometer,<br>
-quadrant electrometer, or other apparatus.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Calibration, Invariable.</span><br>
-Calibration applicable to specially constructed galvanometers, which is<br>
-unaffected by the proximity of masses of iron or field magnets. Such<br>
-galvanometers must have a constant controlling field. Such is given by a<br>
-powerful permanent magnet, whose field is practically unaffected by the<br>
-causes named. Or else, in place of a controlling field, a spring maybe<br>
-used to which the needle is attached, and which tends to hold it in one<br>
-position.<br>
-<br>
-<br>
-98&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Calibration, Relative.</span><br>
-The determination of the law connecting the various indications of an<br>
-instrument, such as the deflections of the needle of a galvanometer,<br>
-with the relative causes; in the case of a galvanometer, the strength of<br>
-the currents or the electro-motive forces producing them directly or<br>
-indirectly.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Call Bell.</span><br>
-A bell rung by pressing a button or otherwise to call the attention of a<br>
-person in a distant place. They can be classified into a great variety<br>
-of types according to their uses or construction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Call Button.</span><br>
-A push button used for ringing a call bell, sounding a buzzer, working<br>
-an annunciator and for similar purposes. (See Push Button.)<br>
-<br>
-Synonym--Push Button.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Calling Drop.</span><br>
-In a telephone exchange or telegraph office a drop shutter annunciator,<br>
-which falls to call the attention of the operator, notifying him that<br>
-the line connected to such drop is to be connected to some other<br>
-circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Calorie or Calory.</span><br>
-A practical unit of heat. There are two calories, respectively called<br>
-the great and the small calorie, or the kilogram and the gram calorie.<br>
-The first is the quantity of heat required to raise the temperature of<br>
-one kilogram of water one degree centigrade. The second is the quantity<br>
-of heat required to raise the temperature of one gram of water one<br>
-degree centigrade.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Calorimeter.</span><br>
-An apparatus for measuring the quantity of heat evolved or produced by<br>
-or under different conditions. Dulong's water calorimeter consists of a<br>
-water jacket, and by the increase of temperature of the water and<br>
-enclosing vessels the amount of heat produced by anything in the inner<br>
-vessels is determined. The amount of ice a heated body will melt is<br>
-sometimes made the basis of a calorimeter. The expansion of a fluid, as<br>
-water, may be used. In the calorimeter shown in the cut the heat<br>
-produced in a conductor by the passage of an electric current is caused<br>
-to heat water whose temperature is shown by a thermometer immersed<br>
-therein. The increase of temperature and the weight of the water give<br>
-the basis for a determination of the heat produced by the current.<br>
-Knowing the resistance of the conductor immersed, the watts can be<br>
-calculated. This gives the bases for the determination of the<br>
-heat-equivalent of electric energy. This is but an imperfect<br>
-calorimeter, as it constantly would lose heat by the surrounding<br>
-atmosphere, and would cease to operate as a calorimeter when the water<br>
-was as hot as the wire normally would be, for then it would not absorb<br>
-all the heat.<br>
-<br>
-<br>
-<img style="width: 451px; height: 621px;" alt="" src="images/098F75.jpg"><br>
-Fig. 75. CALORIMETER.<br>
-<br>
-<br>
-99 STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle</span>. <br>
-The generally accepted unit of illuminating power; there are<br>
-three kinds in use as standards. (See Candle, Decimal--Candle, German<br>
-Standard--Candle, Standard.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, Concentric.</span><br>
-An electric candle of the Jablochkoff type, having a small solid carbon<br>
-inside of an outside tubular carbon, the space between being filled with<br>
-refractory material corresponding to the colombin, q. v., of the<br>
-ordinary type. The arc springs across from one carbon to the other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, Debrun.</span><br>
-An arc lamp with approximately parallel carbons. A transverse priming<br>
-connects their bases, and the arc starting there at once flies out to<br>
-the end.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, Decimal.</span><br>
-A standard of illuminating power, proposed to the Congress of<br>
-Electricians of 1889 by Picou. It is one-twentieth of a Viole, or almost<br>
-exactly one standard candle. (See Viole's Standard of Illuminating<br>
-Power.)<br>
-<br>
-<span style="font-weight: bold;">Candle, Electric.</span><br>
-An arc lamp regulated by simple gravity, or without any feed of the<br>
-carbons or special feeding apparatus, generally for the production of an<br>
-arc light of low intensity. This definition may be considered too<br>
-elastic, and the word may be restricted to parallel carbon lamps in<br>
-which the arc springs across from carbon to carbon. For the latter class<br>
-an alternating current is used to keep the carbons of equal length. They<br>
-are but little used now. Various kinds have been invented, some of which<br>
-are given here.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, German Standard.</span><br>
-A standard of illuminating power used in Germany. It is a paraffin<br>
-candle, 6 to the pound, 20 millimeters diameter; flame, 56 millimeters<br>
-high; rate of consumption, 7.7 grams per hour. Its value is about two<br>
-per cent. lower than the English standard candle.<br>
-<br>
-<br>
-100&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle Holder.</span><br>
-A clamp for holding electric candles of the Jablochkoff type. The ones<br>
-shown in the cut designed for Jablochkoff&nbsp; candles comprise a pair
-of<br>
-metallic clamps, each member insulated from the other, and connected as<br>
-terminals of the circuit. When the candle is placed in position the<br>
-metal pieces press against the carbons of the candle and thus convey the<br>
-current. Below each member of the clamps is a binding screw for the line<br>
-wire terminals.<br>
-<br>
-<br>
-<img style="width: 546px; height: 520px;" alt="" src="images/100F76.jpg"><br>
-Fig. 76. JABLOCHKOFF CANDLE HOLDERS.<br>
-<br>
-<br>
-<img style="width: 417px; height: 526px;" alt="" src="images/100F77.jpg"><br>
-Fig. 77. JABLOCHKOFF CANDLE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, Jablochkoff.</span><br>
-An arc lamp without regulating mechanism, producing an arc between the<br>
-ends of parallel carbons. It consists of two parallel rods of carbon,<br>
-between which is an insulating layer of non-combustible material called<br>
-the colombin. Kaolin was originally employed for this part; later, as<br>
-the fusion of this material was found to short- circuit the arc, a<br>
-mixture of two parts of calcium sulphate and one of barium sulphate was<br>
-used. The carbons are 4 millimeters (.16 inch) thick, and the colombin<br>
-is 3 millimeters (.12 inch) wide and two-thirds as thick. A little slip<br>
-of carbon is placed across the top, touching both carbons to start the<br>
-arc. Once started the candle burns to the end, and cannot be restarted<br>
-after ignition, except by placing a short conductor across the ends, as<br>
-at first. The Jablochkoff candle may now be considered as virtually<br>
-extinct in this country. In France at one time a great number were in<br>
-use.<br>
-<br>
-To keep the carbons of equal length an alternating current must always<br>
-be used with them. Special alternating combinations were employed in<br>
-some cases where a direct current had to be drawn upon.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, Jamin.</span><br>
-An arc lamp with approximately parallel carbons, one of which oscillates<br>
-and is controlled by an electro-magnet and armature. A coil of wire is<br>
-carried around the carbons to keep the arc steady and in place. The<br>
-frame and wire coils have been found unsatisfactory, as causing a<br>
-shadow.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle Power.</span><br>
-The amount of light given by the standard candle. The legal English and<br>
-standard American candle is a sperm candle burning two grains a minute.<br>
-It should have burned some ten minutes before use, and the wick should<br>
-be bent over and have a red tip. Otherwise its readings or indications<br>
-are useless. A sixteen candle power lamp means a lamp giving the light<br>
-of sixteen candles. The candle power is a universal unit of illuminating<br>
-power.<br>
-<br>
-<br>
-101&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle Power, Rated.</span><br>
-The candle power of arc lamps is always stated in excess of the truth,<br>
-and this may be termed as above. A 2000 candle power lamp really gives<br>
-about 800 candles illumination.<br>
-<br>
-Synonym--Nominal Candle Power.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle Power, Spherical.</span><br>
-The average candle power of a source of light in all directions. An arc<br>
-lamp and an incandescent lamp vary greatly in the intensity of light<br>
-emitted by them in different directions. The average of a number of<br>
-determinations at various angles, the lamp being moved about into<br>
-different positions, is taken for the spherical candle power.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, Standard.</span><br>
-A standard of illuminating power. Unless otherwise expressed the English<br>
-standard sperm candle is indicated by this term. (See Candle Power.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Candle, Wilde.</span><br>
-An arc lamp with approximately parallel carbons. One of the carbons can<br>
-rotate through a small arc being pivoted at its base. This oscillation<br>
-is regulated by an electro-magnet at its base, and the carbons touch<br>
-when no current is passing. They separate a little when the current<br>
-passes, establishing an arc. The regulation is comparable to that of a<br>
-regular arc lamp.<br>
-<br>
-<br>
-<img style="width: 410px; height: 562px;" alt="" src="images/101F78.jpg"><br>
-Fig. 78. WILDE CANDLE.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Caoutchouc.</span><br>
-India rubber; a substance existing in an emulsion or solution in the<br>
-juice of certain trees and vines of the tropics, whence it is obtained<br>
-by coagulation and drying. The name "rubber" is due to the fact that one<br>
-of its earliest uses was for erasing pencil marks by rubbing. It has a<br>
-very high value as an insulator. The unworked crude rubber is called<br>
-virgin gum; after working over by kneading, it is termed masticated or<br>
-pure gum rubber; after mixture with sulphur and heating, it is termed<br>
-vulcanized rubber. If enough sulphur is added it becomes hard, and if<br>
-black, is termed ebonite; if vermilion or other pigment is also added to<br>
-produce a reddish color, it is termed vulcanite. The masticated gum<br>
-dissolves more or less completely in naphtha (sp. gr., .850) benzole,<br>
-turpentine, chloroform, ether and other similar liquids.. The resistance<br>
-per centimeter cube of "Hooper's" vulcanized India rubber, such as is<br>
-used in submarine cables is 1.5E16 ohms. The specific inductive capacity<br>
-of pure India rubber is 2.34--of vulcanized 2.94 (Schiller).<br>
-<br>
-Synonyms--India Rubber--Rubber.<br>
-<br>
-<br>
-102&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity, Dielectric.</span><br>
-The capacity of a dielectric in retaining an electrostatic charge; the<br>
-same as Specific Inductive Capacity. 'The number expressing it is<br>
-sometimes called the dielectric constant. (See Capacity, Specific<br>
-Inductive.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity, Electric, or Electrostatic.</span><br>
-The relative capacity of a conductor or system to retain a charge of<br>
-electricity with the production of a given difference of potential. The<br>
-greater the charge for a given change of potential, or the less the<br>
-change of potential for a given charge the greater the capacity. The<br>
-measure of its capacity is the amount of electricity required to raise<br>
-the potential to a stated amount. The unit of capacity is the farad, q.<br>
-v. Electric capacity is comparable to the capacity of a bottle for air.<br>
-A given amount of air will raise the pressure more or less, and the<br>
-amount required to raise its pressure a stated amount might be taken as<br>
-the measure of capacity, and would be strictly comparable to<br>
-electrostatic charge and potential change. The capacity, K, is obviously<br>
-proportional to the quantity, Q, of the charge at a given potential, E,<br>
-and inversely proportional to the potential, E, for a given quantity, Q,<br>
-or,<br>
-&nbsp; (1) K == Q/E<br>
-&nbsp; and<br>
-&nbsp; (2) Q = K * E,<br>
-or, the quantity required to raise a conductor by a given potential is<br>
-equal to the capacity of the conductor or system multiplied by the rise<br>
-of potential. The capacity of a conductor depends upon its environments,<br>
-such as the nature of the dielectric surrounding it, the proximity of<br>
-oppositely charged bodies and other similar factors. (See<br>
-Dielectric-Condenser-Leyden jar.)<br>
-<br>
-The dimensions of capacity are found by dividing a quantity of<br>
-electricity by the potential produced in the conductor by such<br>
-quantity.<br>
-<br>
-Quantity ( ((M^.5)*(L^1.5)) / T ) / potential ( ((M^.5)*(L^.5)) / T ) =
-L.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity, Instantaneous.</span><br>
-The capacity of a condenser when connected only for an instant to a<br>
-source of electricity. This is in contrast to electric absorption (see<br>
-Absorption, Electric), and is capacity without such absorption taking<br>
-part in the action.<br>
-<br>
-<br>
-103&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity of a Telegraph Conductor.</span><br>
-The electric capacity of a telegraphic conductor is identical in quality<br>
-with that of any other conductor. It varies in quantity, not only for<br>
-different wires, but for the same wire under different environments, as<br>
-the wire reacting through the surrounding air or other dielectric upon<br>
-the earth, represents one element of a condenser, the earth, in general,<br>
-representing the other. Hence, a wire placed near the earth has greater<br>
-capacity than one strung upon high poles, although the wires may be<br>
-identical in length, material and diameter. The effect of high capacity<br>
-is to retard the transmission of intermitting signals. Thus, when--as in<br>
-the Morse system--a key is depressed, closing a long telegraph current<br>
-and sending a signal into a line, it is at least very probable that a<br>
-portion of the electricity travels to the end of the wire with the<br>
-velocity of light. But as the wire has to be charged, enough current to<br>
-move the relay may not reach the end for some seconds.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity of Polarization of a Voltaic
-Cell.</span><br>
-The relative resistance to polarization of a voltaic cell, measured by<br>
-the quantity of electricity it can supply before polarization. A<br>
-counter-electromotive force may be developed, or the acid or other<br>
-solution may become exhausted. The quantity of electricity delivered<br>
-before this happens depends on the size and type of cell and other<br>
-factors.<br>
-<br>
-<br>
-C<span style="font-weight: bold;">apacity, Residual.</span><br>
-When two insulated conductors are separated by a dielectric, and are<br>
-discharged disruptively by being connected or nearly connected<br>
-electrically, on removing the discharger it is found that a slight<br>
-charge is present after a short interval. This is the residual charge.<br>
-(See Charge, Residual.) Shaking or jarring the dielectric facilitates<br>
-the complete discharge. This retaining of a charge is a phenomenon of<br>
-the dielectric, and as such, is termed residual capacity. It varies<br>
-greatly in different substances. In quartz it is one-ninth what it is in<br>
-air. Iceland spar (crystalline calcite) seems to have no residual<br>
-capacity. The action of shaking and jarring in facilitating a discharge<br>
-indicates a mechanical stress into which the electrostatic polarization<br>
-of the conductor has thrown the intervening dielectric.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity, Specific Inductive.</span><br>
-The ratio of the capacity of a condenser when its plates are separated<br>
-by any substance to the capacity of the same condenser when its plates<br>
-are separated by air.<br>
-<br>
-A static accumulator consists of two conducting surfaces separated by an<br>
-insulator. It is found that the capacity of an accumulator for an<br>
-electric charge, which varies with or may be rated by the potential<br>
-difference to which its conductors will be brought by the given charge,<br>
-varies with the nature of the interposed dielectric, and is proportional<br>
-to a constant special to each substance. This constant is the specific<br>
-inductive capacity of the dielectric.<br>
-<br>
-The same condenser will have a higher capacity as the dielectric is<br>
-thinner, other things being equal. But different dielectrics having<br>
-different specific inductive capacities, the constant may be determined<br>
-by ascertaining the relative thicknesses of layers having the same total<br>
-inductive capacity. The thicker the layer, the higher is its specific<br>
-inductive capacity.<br>
-<br>
-Thus it is found that 3.2 units thickness of sulphur have the same total<br>
-inductive capacity as 1 unit thickness of air. In other words, if<br>
-sulphur is interposed between two conducting plates, they may be<br>
-separated to over three times the distance that would be requisite to<br>
-retain the same capacity in air. Hence, sulphur is the better<br>
-dielectric, and air being taken as unity, the specific inductive<br>
-capacity of sulphur is 3.2.<br>
-<br>
-<br>
-104&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The specific inductive capacity of a dielectric varies with the time and<br>
-temperature. That of glass rises 2.5 per cent. between 12&deg; C.
-(53.6&deg; F.)<br>
-and 83&deg; C. (181.4&deg; F.). If a condenser is discharged
-disruptively, it<br>
-retains a small residual charge which it can part with later. If a<br>
-metallic connection is made between the plates, the discharge is not<br>
-instantaneous. Vibration shaking and jarring facilitate the complete<br>
-discharge. All this shows that the charge is a phase of the dielectric<br>
-itself, and indicates a strained state into which it is brought.<br>
-<br>
-The following table gives the specific inductive capacity of various<br>
-substances:<br>
-<br>
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;<span
- style="font-family: monospace;">
-<small>Specific Inductive Capacity.</small></span><small><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Substance&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Specific</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Inductive&nbsp;&nbsp; Authority</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Capacity.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Vacuum, air at about 0.001
-millimeters pressure&nbsp;&nbsp; 0.94
-about&nbsp; Ayrton</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Vacuum, air at about 5
-millimeters&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-0.9985&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Ayrton</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-0.99941&nbsp;&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Hydrogen at about 760 millimeters
-pressure&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-0.9997&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-0.9998&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Ayrton</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Air at about 760 millimeters
-pressure&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Taken as the</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-standard</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Carbon Dioxide at about 760
-millimeters pressure&nbsp;
-1.000356&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.0008&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Ayrton</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Olefiant Gas at about 760
-millimeters pressure&nbsp;&nbsp;&nbsp;
-1.000722&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Sulphur Dioxide at about 760
-millimeters pressure
-1.0037&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Ayrton</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Paraffin Wax,
-Clear&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.92&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Schiller</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.96&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; W&uuml;llner</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.977&nbsp;&nbsp; Gibson and Barclay</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.32&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Paraffin Wax,
-Milky&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.47&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Schiller</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">India Rubber,
-Pure&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.34&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Schiller</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">India Rubber,
-Vulcanized&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.94&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Schiller</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Resin&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.55&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Ebonite&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.56&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; W&uuml;llner</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.76&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Schiller</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.15&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Sulphur&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.88 to 3.21&nbsp; W&uuml;llner</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.84&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Boltzmann</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Shellac&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.95 to 3.73&nbsp; W&uuml;llner</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Gutta
-percha&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-4.2</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Mica&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Flint Glass, Very
-light&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-6.57&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; J. Hopkinson</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Flint Glass,
-Light&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-6.85&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; J. Hopkinson</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Flint Glass,
-Dense&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7.4&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; J. Hopkinson</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Flint Glass, Double extra
-dense&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-10.1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; J. Hopkinson</span></small><br>
-<br>
-<br>
-105&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity, Unit of.</span><br>
-The unit of capacity is the capacity of a surface which a unit quantity<br>
-will raise to a unit potential. The practical unit is the surface which<br>
-a coulomb will raise to one volt, and is called the farad, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capacity, Storage.</span><br>
-In secondary batteries the quantity of electrical current which they can<br>
-supply when charged, without undue exhaustion. It is expressed in<br>
-ampere-hours. The potential varies so little during the discharge that<br>
-it is assumed to be constant.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Capillarity.</span><br>
-The reaction between liquid surfaces of different kinds or between<br>
-liquid and solid surfaces due to surface tension. Its phenomena are<br>
-greatly modified by electric charging, which alters the surface tension.<br>
-Capillarity is the cause of solutions "creeping," as it is termed. Thus<br>
-in gravity batteries a crust of zinc sulphate often formed over the edge<br>
-of the jar due to the solution creeping and evaporating. As a liquid<br>
-withdraws from a surface which it does not wet, creeping as above is<br>
-prevented by coating the edge with paraffin wax, something which water<br>
-does not moisten. It also causes the liquids of a battery cell to reach<br>
-the connections and injure them by oxidation. The solutions creep up in<br>
-the pores of the carbons of a battery and oxidize the clamps. To give<br>
-good connections a disc of platinum or of lead is used for the contact<br>
-as not being attacked. Another way is to dip the upper ends of the dry<br>
-and warm carbons into melted paraffin wax, or to apply the wax to the<br>
-hot carbons at the top, and melt it in with a hot iron.<br>
-<br>
-<br>
-106&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Carbon.</span><br>
-(a) One of the elements; atomic weight, 12. It exists in three<br>
-allotropic modifications, charcoal, graphite and diamond. In the<br>
-graphitic form it is used as an electric current conductor, as in<br>
-batteries and for arc lamp, electrodes and incandescent lamp filaments.<br>
-It is the only substance which conducts electricity and which cannot be<br>
-melted with comparative ease by increase of current. (See Resistance.)<br>
-<br>
-(b) The carbon plate of a battery or rod of an arc lamp. To secure<br>
-greater conductivity in lamp carbons, they are sometimes plated with<br>
-nickel or with copper.<br>
-<br>
-(c) v. To place carbons in arc lamps. This has generally to be done once<br>
-in twenty-four hours, unless the period of burning is very short.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Carbon, Artificial.</span><br>
-For lamps, carbons and battery plates carbons are made by igniting,<br>
-while protected from the action of the air, a mixture of carbon dust and<br>
-a cementing and carbonizable substance. Lamp black may be added also.<br>
-Powdered coke or gas carbon is mixed with molasses, coal tar, syrup, or<br>
-some similar carbonaceous liquid. It is moulded into shape. For lamp<br>
-carbons the mixture is forced from a vessel through a round aperture or<br>
-die, by heavy pressure, and is cut into suitable lengths. For battery<br>
-plates it may be simply pressed into moulds. The carbons are ignited in<br>
-covered vessels and also covered with charcoal dust, lamp black or its<br>
-equivalent. They are heated to full redness for some hours. After<br>
-removal and cooling they are sometimes dipped again into the liquid used<br>
-for cementing and reignited. Great care in securing pure carbon is<br>
-sometimes necessary, especially for lamps. Fine bituminous coal is<br>
-sometimes used, originally by Robert Bunsen, in 1838 or 1840;<br>
-purification by different processes has since been applied; carbon from<br>
-destructive distillation of coal tar has been used. The famous
-Carr&eacute;<br>
-carbons are made, it is said, from 15 parts very pure coke dust, five<br>
-parts calcined lamp-black, and seven or eight parts sugar--syrup mixed<br>
-with a little gum. Five hours heating, with subsequent treatment with<br>
-boiling caramel and reignition are applied. The latter treatment is<br>
-termed "nourishing." Napoli used three parts of coke to one of tar.<br>
-Sometimes a core of different carbon than the surrounding tube is<br>
-employed.<br>
-<br>
-<br>
-107&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The following are the resistances of Carr&eacute;'s carbons per meter
-(39.37<br>
-inches):<br>
-<br>
-<span style="font-family: monospace;">Diameter
-in&nbsp;&nbsp;&nbsp;&nbsp; Diameter in&nbsp; Resistance in
-Ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Millimeters.&nbsp;&nbsp;&nbsp;
-Inches.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; @
-20&deg; C. (98&deg; F.)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.039&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 50.000</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.078&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 12.5</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-3&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.117&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5.55</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-4&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.156&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.125</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-5&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.195&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-6&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.234&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.390</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-8&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.312&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.781</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;
-10&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.390&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.5</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;
-12&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.468&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.348</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;
-15&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.585&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.222</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;
-18&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.702&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.154</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;
-20&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.780&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.125</span><br>
-<br>
-At high temperatures the resistance is about one-third these amounts. A<br>
-layer of copper may increase the conductivity one hundred times and<br>
-prolong the duration 14 per cent. Thus a layer of copper 1/695<br>
-millimeter (1/17300 inch) thick increases the conductivity 4.5 times; a<br>
-coating 1/60 millimeter (1/1500 inch) thick increases the conductivity<br>
-one hundred and eleven times.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Carbon, Cored.</span><br>
-A carbon for arc lamps with a central core of softer carbon than the<br>
-exterior zone. It fixes the position of the arc, and is supposed to give<br>
-a steadier light.<br>
-<br>
-Synonym--Concentric Carbon.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Carbon Holders.</span><br>
-In arc lamps, the fixed clamps for holding the ends of the carbons.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Carbonization.</span><br>
-The igniting in a closed vessel, protected from air, of an organic<br>
-substance so as to expel from it all the constituents except part of<br>
-the carbon; destructive distillation. (See Carbonized Cloth.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Carbonized Cloth.</span><br>
-Cloth cut in discs and heated in vessels protected from the air, until<br>
-reduced to carbon. The heating is sometimes conducted in vacuo. They are<br>
-placed in a pile in a glass or other insulating tube, and offer a<br>
-resistance which can be varied by pressure. The greater the pressure the<br>
-less will be the resistance, and vice versa.<br>
-<br>
-Carbon Dioxide.<br>
-A compound gas, CO2. It is composed of<br>
-&nbsp; Carbon, 12 parts by weight.<br>
-&nbsp; Oxygen. 32&nbsp; "<br>
-&nbsp; Specific gravity, 1.524 (Dulong and Berzelins).<br>
-&nbsp; Molecular weight, 44.<br>
-<br>
-It is a dielectric of about the resistance of air. Its specific<br>
-inductive capacity at atmospheric pressures is<br>
-&nbsp; 1.000356 (Boltzmann).<br>
-&nbsp; 1.0008 (Ayrton).<br>
-<br>
-Synonyms--Carbonic Acid--Carbonic Acid Gas.<br>
-<br>
-<br>
-108&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Carbon, Volatilization of.</span><br>
-In arc lamps the heat is so intense that it is believed that part of the<br>
-carbon is volatilized as vapor before being burned or oxidized by the<br>
-oxygen of the air. The same volatilization may take place in<br>
-incandescent lamps which are overheated.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Carcel.</span><br>
-The standard of artificial illumination used in France. It is the light<br>
-yielded by a standard lamp burning 42 grams (648 grains) of colza oil<br>
-per hour, with a flame 40 millimeters (1.57 inch) in height. One carcel<br>
-is equal to 9.5 to 9.6 candles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Carcel Lamp.</span><br>
-The lamp giving the standard of illuminating power. The wick is<br>
-cylindrical, giving an Argand or central draft flame. It is woven with<br>
-75 strands, and weighs 3.6 grams (55.5 grains) per decimeter (3.9<br>
-inches) of length. The chimney is 29 centimeters (11.3 inches) high, 47<br>
-millimeters (1.88 inch) in diameter at the bottom, contracting just<br>
-above the wick to 34 millimeters (1.36 inch).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Carcel Gas Jet.</span><br>
-A standard Argand gas burner, made with proper rating to give the light<br>
-of a definite number of carcels illuminating power. Cognizance must be<br>
-taken of the quality of the gas as well as of the burner used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Carrying Capacity.</span><br>
-In a current conductor, its capacity for carrying a current without<br>
-becoming unduly heated. It is expressed in amperes. (See Wire Gauge,<br>
-American.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cascade.</span><br>
-The arrangement of Leyden jars in series on insulating supports, as<br>
-described below.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cascade, Charging and Discharging
-Leyden Jars In.</span><br>
-An arrangement of Leyden jars in series for the purpose of charging and<br>
-discharging. They are placed on insulating supports, the inner coating<br>
-of one connected with the outer coating of the next one all through the<br>
-series. The actual charge received by such a series, the outer coating<br>
-of one end jar being grounded, and the inner coating of the other being<br>
-connected to a source of high potential, or else the same being<br>
-connected to electrodes of opposite potentials is no greater than that<br>
-of a single jar, but a much higher potential difference can be developed<br>
-without risk of perforating the glass of a jar. The difference of<br>
-potential in each jar of the series is equal to the total potential<br>
-difference divided by the number of jars. The energy of discharge is<br>
-equal to the same fraction of the energy of a single jar charged with<br>
-the same quantity.<br>
-<br>
-[Transcriber's note: The equal distribution of potential assumes all the<br>
-jars have the same capacity. The charge on all jars is the same since<br>
-they are in series.]<br>
-<br>
-<br>
-109&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Case-hardening, Electric.</span><br>
-The conversion of the surface of iron into steel by applying a proper<br>
-carbonaceous material to it while it is heated by an electric current.<br>
-It is a superficial cementation process.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cataphoresis.</span><br>
-Electric osmore; the transfer of substances in solution through porous<br>
-membranes under the influence probably of electrolysis, but without<br>
-themselves being decomposed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cautery, Electric.</span><br>
-An electro-surgical appliance for removing diseased parts, or arresting<br>
-hemorrhages, taking the place of the knife or other cutting instrument.<br>
-The cautery is a platinum wire heated to whiteness by an electric<br>
-current, and when in that condition used to cut off tumors, stop the<br>
-flow of blood and parallel operations. The application is painful, but<br>
-by the use of anaesthetics pain is avoided, and the healing after the<br>
-operation is greatly accelerated.<br>
-<br>
-The heated wire of the cautery can be used for cutting operations in<br>
-many cases where excision by a knife would be almost impracticable.<br>
-<br>
-Synonyms--Galvano-cautery--Galvano-caustry--Galvano-electric,<br>
-do.--Galvano-thermal, do.<br>
-<br>
-<br>
-<span style="font-weight: bold;">C. C.</span><br>
-A contraction of cubic centimeter. It is often written in small letters,<br>
-as 100 c.c., meaning 100 cubic centimeters.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cell, Constant.</span><br>
-A cell which yields a constant and uniform current under unvarying<br>
-conditions. This implies that neither the electro-motive force or the<br>
-resistance of the cell shall vary, or else that as the electro-motive<br>
-forces run down the resistance shall diminish in proper proportion to<br>
-maintain a constant current. There is really no constant cell. The<br>
-constancy is greatest when the external resistance is high in proportion<br>
-to the internal resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cell, Electrolytic.</span><br>
-A vessel containing the electrolyte, a liquid decomposable by the<br>
-current, and electrodes, arranged for the passage of a decomposing<br>
-current. The voltameter, q. v., is an example.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cell, Standard Voltaic.</span><br>
-A cell designed to be a standard of electro-motive force; one in which<br>
-the same elements shall always be present under the same conditions, so<br>
-as to develop the same electro-motive force. In use the circuit is<br>
-closed only for a very short time, so that it shall not become altered<br>
-by polarization or exhaustion.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cell, Standard Voltaic, Daniell's. </span><br>
-A zinc-copper-copper sulphate couple.<br>
-Many forms are used. Sometimes a number of pieces of blotting paper are<br>
-interposed between two plates, one of copper--the other of zinc. The<br>
-paper next the copper is soaked in copper sulphate solution, and those<br>
-next the zinc in zinc sulphate solution, of course before being put<br>
-together. Sometimes the ordinary porous cup combination is employed. The<br>
-cut shows a modification due to Dr. Fleming (Phil. Mag. S. 5, vol. xx,<br>
-p. 126), which explains itself. The U tube is 3/4-inch diameter, and 8<br>
-inches long. Starting with it empty the tap A is opened, and the whole U<br>
-tube filled with zinc sulphate solution, and the tap A is closed. The<br>
-zinc rod usually kept in the tube L is put in place, tightly corking up<br>
-its end of the U tube. The cock C is opened, which lowers the level of<br>
-the solution in the right-hand limb of the U tube only. The tap B is<br>
-opened and the copper sulphate solution is run in, preserving the line<br>
-of separation of the two solutions. The copper rod is taken out of its<br>
-tube M, and is put in place. India rubber corks are used for both rods.<br>
-As the liquids begin to mix the mixture can be drawn off at C and the<br>
-sharp line of demarcation re-established. In Dr. Sloane's standard cell<br>
-two test tubes are employed for the solutions and a syphon is used to<br>
-connect them.<br>
-<br>
-Oxidation of the zinc lowers the E. M. F.; oxidation of the copper<br>
-raises it. With solutions of equal sp. gr. the E. M. F. is 1.104 volts.<br>
-If the copper sulphate solution is 1.100 sp. gr. and the zinc sulphate<br>
-solution 1.400 sp. gr., both at 15&deg; C. (59&deg;F.), the E. M. F.
-will be<br>
-1.074 volt. Clean pure zinc and freshly electrolyzed copper should be<br>
-used.<br>
-<br>
-<br>
-<img style="width: 308px; height: 598px;" alt="" src="images/079F57.jpg"><br>
-Fig. 79 STANDARD DANIELL CELL--FLEMING'S FORM.<br>
-<br>
-<br>
-110&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cell, Standard Voltaic, Latimer
-Clark's. </span><br>
-A mercury and zinc electrode couple with <br>
-mercurous sulphate as excitant and depolarizer. The positive<br>
-element is an amalgam of zinc, the negative is pure mercury. Each<br>
-element, in a representative form, the H form, is contained in a<br>
-separate vessel which communicate by a tube. Over the pure mercury some<br>
-mercurous sulphate is placed. Both vessels are filled to above the level<br>
-of the connecting tube with zinc sulphate solution, and kept saturated.<br>
-It is tightly closed or corked. The E. M. F. at 15&deg; C (59&deg; F.)
-is 1.438.<br>
-Temperature correction<br>
-<br>
-(1 -&nbsp; (.00077 *(t - 15&deg; C) ) )<br>
-<br>
-t being expressed in degrees centigrade (Rayleigh). A diminution in<br>
-specific gravity of the zinc solution increases the E. M. F. The cell<br>
-polarizes rapidly and the temperature coefficient is considered too<br>
-high.<br>
-<br>
-<br>
-<img style="width: 580px; height: 690px;" alt="" src="images/111F80.jpg"><br>
-Fig. 80. LATIMER CLARK'S STANDARD CELL.<br>
-<br>
-<br>
-111&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cements, Electrical.</span><br>
-A few cements find their use in electrical work. Marine glue,<br>
-Chatterton's compound, and sealing wax may be cited.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centi-.</span><br>
-Employed as a prefix to indicate one-hundredth, as centimeter, the<br>
-one-hundredth of a meter; centi-ampere, the one-hundredth of an ampere.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centigrade-scale.</span><br>
-A thermometer scale in use by scientists of all countries and in general<br>
-use in many. The temperature of melting ice is 0&ordm;; the temperature
-of<br>
-condensing steam is 100&deg; ; the degrees are all of equal length. To<br>
-reduce to Fahrenheit degrees multiply by 9 and divide by 5, and add 32<br>
-algebraically, treating all readings below 0&ordm; as minus quantities.
-For<br>
-its relations to the Reamur scale, see Reamur Scale. Its abbreviation is<br>
-C., as 10&ordm; C., meaning ten degrees centigrade.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centimeter.</span><br>
-A metric system unit of length; one-hundredth of a meter; 0.3937 inch.<br>
-The absolute or c. g. s. unit of length.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centimeter-gram-second System.</span><br>
-The accepted fundamental or absolute system of units, called the C. G.<br>
-S. system. It embraces units of size, weight, time, in mechanics,<br>
-physics, electricity and other branches. It is also called the absolute<br>
-system of units. It admits of the formation of new units as required by<br>
-increased scope or classification. The following are basic units of the<br>
-system :<br>
-<br>
-Of length, centimeter;<br>
-of mass, gram;<br>
-of time, second:<br>
-of force, dyne:<br>
-of work or energy, erg.<br>
-<br>
-See Dyne, Erg., and other units in general.<br>
-<br>
-<br>
-112&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Central Station Distribution or Supply.</span><br>
-The system of supplying electric energy in current form from a main<br>
-generating plant to a district of a number of houses, factories, etc. It<br>
-is in contrast with the isolated plant system in which each house or<br>
-factory has its own separate generating installment, batteries or<br>
-dynamos.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Centre of Gravity. </span><br>
-A point so situated with respect to any particular body, that the <br>
-resultant of the parallel attracting forces between the earth and the <br>
-several molecules of the body always passes through it. These are <br>
-resultants of the relative moments of the molecules. If a body is <br>
-suspended, as by a string, the centre of gravity always lies vertically
-<br>
-under its point of suspension. By two trials the point of intersection <br>
-of plumb lines from the point of suspension being determined the centre
-<br>
-of gravity is known. The vertical from the point of support coincides <br>
-with the line of direction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centre of Gyration.</span><br>
-The centre of gyration with respect to the axis of a rotating body is a<br>
-point at which if the entire mass of the body were concentrated its<br>
-moment of inertia would remain unchanged. The distance of this point<br>
-from the axis is the radius of gyration.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centre of Oscillation.</span><br>
-The point referred to in a body, suspended or mounted to swing like a<br>
-pendulum, at which if all the mass were concentrated, 1t would complete<br>
-its oscillations in the same time. The distance from the axis of support<br>
-to this point gives the virtual length of the pendulum which the body<br>
-represents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centre of Percussion.</span><br>
-The point in a suspended body, one free to swing like a pendulum, at<br>
-which an impulse may be applied, perpendicular to the plane through the<br>
-axis of the body and through the axis of support without shock to the<br>
-axis. It is identical with the centre of oscillation, q. v., when such<br>
-lies within the body.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centrifugal Force.</span><br>
-The force which draws a body constrained to move in a curved path away<br>
-from the centre of rotation. It is really due to a tangential impulse<br>
-and by some physicists is called the centrifugal component of tangential<br>
-velocity. It has to be provided against in generator and motor<br>
-armatures, by winding them with wire or bands to prevent the coils of<br>
-wire from spreading or leaving their bed upon the core.<br>
-<br>
-<br>
-113&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Centrifugal Governor.</span><br>
-The usual type of steam-engine governor. The motion of the engine<br>
-rotates a system of weights, which are forced outward by centrifugal<br>
-force, and are drawn inwards by gravity or by springs. Moving outwards<br>
-they shut off steam, and moving inwards they admit it, thus keeping the<br>
-engine at approximately a constant speed. The connections between them<br>
-and the steam supply and the general construction vary widely in<br>
-different governors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">C. G. S.</span><br>
-Abbreviation or symbol for Centimeter-gram-second, as the C. G. S.<br>
-system. (See Centimeter-gram-second System.) It is sometimes expressed<br>
-in capitals, as above, and sometimes in small letters, as the c. g. s.<br>
-unit of resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chamber of Incandescent Lamp.</span><br>
-The interior of the bulb of an incandescent lamp. (See Lamp,<br>
-Incandescent.)<br>
-<br>
-<br>
-<img style="width: 487px; height: 676px;" alt="" src="images/113F81.jpg"><br>
-Fig. 81. CHARACTERISTIC CURVE OF A DYNAMO.<br>
-<br>
-<br>
-<img style="width: 442px; height: 641px;" alt="" src="images/113F82.jpg"><br>
-FIG. 82. DROOPING CHARACTERISTIC.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Characteristic Curve.</span><br>
-A curve indicating the variations in electro-motive force developed<br>
-during the rotations of the armature of a dynamo or other generator of<br>
-E. M. F. The term as used in the electrical sense is thus applied,<br>
-although the indicator diagram of a steam engine may be termed its<br>
-characteristic curve, and so in many other cases. As the amperes taken<br>
-from a series generator are increased in number, the E. M. F. rises, it<br>
-may be very rapidly up to a certain point, and thereafter more slowly.<br>
-To construct the curve coordinates, q. v., are employed. The resistance<br>
-of the dynamo and of the outer circuit being known, the current<br>
-intensity is measured. To obtain variations in electro-motive force the<br>
-external resistance is changed. Thus a number of ampere readings with<br>
-varying known resistance are obtained, and for each one an<br>
-electro-motive force is calculated by Ohm's law. From these data a curve<br>
-is plotted, usually with volts laid off on the ordinate and amperes on<br>
-the abscissa.<br>
-<br>
-By other methods other characteristic curves may be obtained, for which<br>
-the titles under Curve may be consulted.<br>
-<br>
-<br>
-114&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Characteristic, Drooping.</span><br>
-A characteristic curve of a dynamo which indicates a fall in voltage<br>
-when an excessive current is taken from the dynamo in question. It is<br>
-shown strongly in some Brush machines, and is partly due to the<br>
-arrangements for cutting out two of the coils as they approach the<br>
-neutral line. It is an advantage, as it protects from overheating on<br>
-short circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Characteristic, External.</span><br>
-In a dynamo the characteristic curve in which the relations of volts<br>
-between terminals to amperes in the outer circuit are plotted. (See<br>
-Curve, External Characteristic.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Characteristic, Internal.</span><br>
-A characteristic curve of a shunt dynamo, in which the relations of<br>
-volts to amperes in the shunt circuit is plotted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Characteristics of Sound. </span><br>
-Of interest, electrically, as affecting the telephone, they comprise:<br>
-<br>
-(1) Pitch, due to frequency of vibrations.<br>
-<br>
-(2) Intensity or loudness, due to amplitude of waves of sound.<br>
-<br>
-(3) Quality or timbre, the distinguishing characteristics of any<br>
-specific sound due to overtones, discords, etc., by which the sound is<br>
-recognizable from others. The telephone is held by the U. S. courts to<br>
-be capable of reproducing the voice by means of the undulatory current.<br>
-(See Current, Undulatory.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Charge.</span><br>
-The quantity of electricity that is present on the surface of a body or<br>
-conductor. If no electricity is supplied, and the conductor is connected<br>
-to the earth, it is quickly discharged. A charge is measured by the<br>
-units of quantity, such as the coulomb. The charge that a conductor can<br>
-retain at a given rise of potential gives its capacity, expressible in<br>
-units of capacity, such as the farad. A charge implies the stretching or<br>
-straining between the surface of the charged body, and some<br>
-complimentary charged surface or surfaces, near or far, of large or<br>
-small area, of even or uneven distribution.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Charge. v.</span><br>
-(a) To introduce an electrostatic charge, as to charge a condenser.<br>
-<br>
-(b) To decompose the elements of a secondary battery, q. v., so as to<br>
-render it capable of producing a current. Thus, a spent battery is<br>
-charged or recharged to enable it to do more work.<br>
-<br>
-Synonyms--Renovate--Revivify--Recharge.<br>
-<br>
-<br>
-115&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Charge, Bound.</span><br>
-A charge of electricity borne by the surface of a body so situated with<br>
-reference to another oppositely charged body, that the charge is<br>
-imperceptible to ordinary test, will not affect an electroscope nor<br>
-leave the surface if the latter is connected to the earth. To discharge<br>
-such a body it must be connected to its complimentarily charged body.<br>
-The bound charge was formerly called dissimulated or latent electricity.<br>
-(See Charge, Free.)<br>
-<br>
-The charge or portion of a charge of a surface which is neutralized<br>
-inductively by a neighboring charge of opposite kind. The degree of<br>
-neutralization or of binding will depend on the distance of the two<br>
-charged surfaces from one another and on the electro-static nature of<br>
-the medium intervening, which must of necessity be a dielectric. A<br>
-charge not so held or neutralized is termed a free charge. Thus a<br>
-surface may be charged and by the approach of a surface less highly<br>
-charged may have part of its charge bound. Then if connected to earth.<br>
-it will part with its unbound or free charge, but will retain the other<br>
-until the binding surface is removed, or until the electricity of such<br>
-surface is itself bound, or discharged, or until connection is made<br>
-between the two surfaces. Thus a body may have both a bound and a free<br>
-charge at the same time.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Charge, Density of.</span><br>
-The relative quantity of electricity upon a given surface. Thus a<br>
-charged surface may have an evenly distributed charge or one of even<br>
-density, or an unevenly distributed charge or one of uneven density. In<br>
-a thunderstorm the earth has a denser charge under the clouds than<br>
-elsewhere.<br>
-<br>
-Synonym--Electrical Density.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Charge, Dissipation of.</span><br>
-As every body known conducts electricity, it is impossible so to<br>
-insulate a surface that it will not lose its charge by leakage. An<br>
-absolute vacuum might answer, and Crookes in a high vacuum has retained<br>
-a charge against dissipation for years. The gradual loss is termed as<br>
-above.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Charge, Distribution of.</span><br>
-The relation of densities of charge on different parts of a charged<br>
-body. On a spherical conductor the charge is normally of even<br>
-distribution; on other conductors it is unevenly distributed, being of<br>
-greatest density at points, edges, and parts of smallest radius of<br>
-curvature. Even distribution can also be disturbed by local induction,<br>
-due to the presence of oppositely charged bodies.<br>
-<br>
-<br>
-116&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Charge, Free.</span><br>
-The charge borne by an insulated body, independent of surrounding<br>
-objects. Theoretically it is an impossibility. A charge always has its<br>
-compliment somewhere in surrounding objects. As a matter of convenience<br>
-and convention, where the complimentary charge is so distributed that<br>
-its influence is not perceptible the charge is called a free charge. If<br>
-connected to earth the free charge will leave the body. If the body is<br>
-connected with an electroscope the free charge will affect the same.<br>
-(See Charge, Bound.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Charge, Residual.</span><br>
-When a Leyden jar or other condenser is discharged by the ordinary<br>
-method, after a few minutes standing a second discharge of less amount<br>
-can be obtained from it. This is due to what is known as the residual<br>
-charge. It seems to be connected in some way with the mechanical or<br>
-molecular distortion of the dielectric. The jarring of the dielectric<br>
-after discharge favors the rapidity of the action, diminishing the time<br>
-required for the appearance of the residual charge. The phenomenon, it<br>
-will be seen, is analogous to residual magnetism. This charge is the<br>
-reciprocal of electric absorption and depends for its amount upon the<br>
-nature of the dielectric. (See Absorption, Electric, and Capacity,<br>
-Residual.)<br>
-<br>
-Synonym--Electric Residue.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chatterton's Compound.</span><br>
-A cement used for cementing together layers or sheets of gutta percha,<br>
-and for similar purposes in splicing telegraph cables. Its formula is:<br>
-&nbsp; Stockholm Tar,&nbsp;&nbsp; 1 part.<br>
-&nbsp;
-Resin,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1
-part.<br>
-&nbsp; Gutta Percha,&nbsp;&nbsp;&nbsp; 3 parts.<br>
-All parts by weight.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chemical Change.</span><br>
-When bodies unite in the ratio of their chemical equivalents, so as to<br>
-represent the satisfying of affinity or the setting free of thermal or<br>
-other energy, which uniting is generally accompanied by sensible heat<br>
-and often by light, as in the ignition of a match, burning of a candle,<br>
-and, when the new compound exhibits new properties distinct from those<br>
-of its components, a chemical combination is indicated. More definitely<br>
-it is a change of relation of the atoms. Another form of chemical change<br>
-is decomposition, the reverse of combination, and requiring or absorbing<br>
-energy and producing several bodies of properties distinct from those of<br>
-the original compound. Thus in a voltaic battery chemical combination<br>
-and decomposition take place, with evolution of electric instead of<br>
-thermal energy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chemical Equivalent.</span><br>
-The quotient obtained by dividing the atomic weight, q. v., of an<br>
-element by its valency, q. v. Thus the atomic weight of oxygen is 16,<br>
-its valency is 2. its chemical equivalent is 8. It is the weight of the<br>
-element corresponding to a unit weight of hydrogen, either as replacing<br>
-it, or combining with it. In electro-chemical calculations the chemical<br>
-equivalent is often conveniently used to avoid the necessity of dividing<br>
-by the valency when atomic weights are used. The latter is really the<br>
-better practice. The atomic weights in the old system of chemical<br>
-nomenclature were chemical equivalents.<br>
-<br>
-<br>
-117&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chemical Recorder.</span><br>
-A form of telegraphic recorder in which the characters, often of the<br>
-Morse alphabet or some similar one, are inscribed on chemically prepared<br>
-paper by decomposition affecting the compound with which the paper is<br>
-charged. In the original chemical recorder of Bain, the instrument was<br>
-somewhat similar to the Morse recorder, except that the motionless<br>
-stylus, S, always pressing against the paper was incapable of making any<br>
-mark, but being of iron, and the paper strip being impregnated with<br>
-potassium ferrocyanide, on the passage of a current a stain of Prussian<br>
-blue was produced where the stylus touched the paper. The current passes<br>
-from the line by way of the iron stylus, through the paper, and by way<br>
-of a brass surface, M, against which the paper is held and is pressed by<br>
-the stylus, to the earth. This recorder is extremely simple and has no<br>
-part to be moved by the current. The solution in which the paper is<br>
-dipped contains a mixture of potassium ferrocyanide and ammonium<br>
-nitrate. The object of the latter is to keep the paper moist. In recent<br>
-recorders a solution of potassium iodide has been used, which gives a<br>
-brown stain of free iodine, when the current passes. This stain<br>
-disappears in a few days.<br>
-<br>
-<br>
-<img style="width: 744px; height: 458px;" alt="" src="images/117F83.jpg"><br>
-Fig. 83. BAIN'S TELEGRAPH EMPLOYING CHEMICAL RECORDER.<br>
-<br>
-<br>
-In the cut, R is the roll of paper, B is a tank of solution with roll,<br>
-W1, for moistening the paper; M is the brass surface against which the<br>
-stylus, S, presses the paper, P P; W, W are feed rollers; T is the<br>
-transmitting key, and zk the battery; Pl, Pl are earth plates. The<br>
-apparatus is shown duplicated for each end.<br>
-<br>
-<br>
-118&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Chemistry.</span><br>
-The science treating of atomic and molecular relations of the elements<br>
-and of chemical compounds of the same.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chimes, Electric.</span><br>
-An apparatus employed to illustrate the principles of the electrostatic<br>
-charge, involving the ringing of bells by electrostatic attraction and<br>
-repulsion. It is used in connection with a frictional, or influence<br>
-electric machine. Two bells are employed with a button or clapper<br>
-suspended between them. One bell is connected to one of the prime<br>
-conductors, q. v., of the machine. The other insulated therefrom is<br>
-connected to earth, or if an influence machine is used, to the other<br>
-prime conductor. The clappers are hung by a silk thread, so as to be<br>
-entirely insulated. On working the machine the bells become oppositely<br>
-excited. A clapper is attracted to one, then when charged is repelled<br>
-and attracted to the other, it gives up its charge and becoming charged<br>
-with similar electricity to that of the bell it touches, is repelled and<br>
-attracted to the other, and this action is kept up as long as the<br>
-excitement continues, the bells ringing continuously.<br>
-<br>
-<br>
-<img style="width: 563px; height: 504px;" alt="" src="images/118F84.jpg"><br>
-Fig. 84. ELECTRIC CHIMES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chronograph, Electric.</span><br>
-An apparatus for indicating electrically, and thereby measuring, the<br>
-lapse of time. The periods measured may be exceedingly short, such as<br>
-the time a photographic shutter takes to close, the time required by a<br>
-projectile to go a certain distance, and similar periods.<br>
-<br>
-A drum rotated with even and known velocity may be marked by a stylus<br>
-pressed upon it by the action of an electro-magnet when a key is<br>
-touched, or other disturbance. Then the space between two marks would<br>
-give the period elapsing between the two disturbances of the circuit. As<br>
-it is practically impossible to secure even rotation of a drum, it is<br>
-necessary to constantly measure its rate of rotation. This is effected<br>
-by causing a tuning-fork of known rate of vibration to be maintained in<br>
-vibration electrically. A fine point or bristle attached to one of its<br>
-arms, marks a sinuous line upon the smoked surface of the cylinder. This<br>
-gives the basis for most accurately determining the smallest intervals.<br>
-Each wave drawn by the fork corresponds to a known fraction of a second.<br>
-<br>
-For projectiles, the cutting of a wire opens a circuit, and the opening<br>
-is recorded instead of the closing. By firing so as to cut two wires at<br>
-a known distance apart the rate is obtained by the chronograph.<br>
-<br>
-Synonym--Chronoscope.<br>
-<br>
-<br>
-119&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Chutaux's Solution.</span><br>
-A solution for bichromate batteries. It is composed as follows:<br>
-<span style="font-family: monospace;">&nbsp;
-Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1,500 parts</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Potassium
-bichromate,&nbsp;&nbsp; 100 parts</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; mercury
-bisulphate,&nbsp;&nbsp;&nbsp;&nbsp; 100 parts</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 66&deg; sulphuric
-acid,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 50 parts.</span><br>
-<br>
-Circle, Galvanic or Voltaic.<br>
-A term for the voltaic circuit; obsolete.<br>
-<br>
-<br>
-<img style="width: 546px; height: 779px;" alt="" src="images/119F85.jpg"><br>
-Fig. 85. MAGIC CIRCLE.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circle, Magic.</span><br>
-A form of electro-magnet. It is a thick circle of round iron and is used<br>
-in connection with a magnetizing coil, as shown, to illustrate<br>
-electro-magnetic attraction.<br>
-<br>
-<br>
-120&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit.</span><br>
-A conducting path for electric currents properly forming a complete path<br>
-with ends joined and including generally a generating device of some<br>
-kind. Part of the conduction may be true and part electrolytic. (See<br>
-Electrolytic Conduction.) The term has become extended, so that the term<br>
-is often applied to any portion of a circuit conveniently considered by<br>
-itself. The simplest example of a complete circuit would be a circular<br>
-conductor. If rotated in the earth's field so as to cut its lines of<br>
-force a current would go through it, and it would be an electric<br>
-circuit. Another example is a galvanic battery with its ends connected<br>
-by a wire. Here the battery generates the current which, by electrolytic<br>
-conduction, goes through the battery and by true conduction through the<br>
-wire. For an example of a portion of a circuit spoken of as "a circuit"<br>
-see Circuit, Astatic.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Astatic.</span><br>
-A circuit so wound with reference to the direction of the currents<br>
-passing through it that the terrestrial or other lines of force have no<br>
-directive effect upon it, one member counteracting the other. It may be<br>
-produced by making the wire lie in two closed curves, A and B, each<br>
-enclosing an equal area, one of identical shape and disposition with the<br>
-other, and with the current circulating in opposite directions in each<br>
-one. Thus each circuit represents a magnetizing turn of opposite<br>
-polarity and counteracting each other's directive tendency exhibited in<br>
-a field of force with reference to an axis a c. Another form of astatic<br>
-circuit is shown in Fig. 86. The portions C, D, lying on opposite sides<br>
-of the axis of rotation a c, are oppositely acted on by the earth's<br>
-directive force as regards the direction of their rotation.<br>
-<br>
-<br>
-<img style="width: 638px; height: 401px;" alt=""
- src="images/120F86_87.jpg"><br>
-Figs. 86 and 87. ASTATIC CIRCUITS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Branch.</span><br>
-A circuit dividing into two or more parts in parallel with each other.<br>
-<br>
-<br>
-121&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit Breaker.</span><br>
-Any apparatus for opening and closing a circuit is thus termed, but it<br>
-is generally applied to automatic apparatus. A typical circuit breaker<br>
-is the hammer and anvil of the induction coil. (See Induction Coil;<br>
-Anvil.) Again a pendulum connected to one terminal of a circuit may<br>
-swing so as to carry a point on its lower end through a globule of<br>
-mercury as it swings, which globule is connected to the other terminal.<br>
-A great many arrangements of this character have been devised.<br>
-<br>
-Synonym.--Contact Breaker.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit Breaker, Automatic.</span><br>
-A circuit breaker worked by the apparatus to which it is attached, or<br>
-otherwise automatically. (See Induction Coil; Anvil; Bell, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit Breaker, File.</span><br>
-A coarsely cut file, forms one terminal of an electric circuit, with a<br>
-straight piece of copper or steel for the other terminal. The latter<br>
-terminal drawn along the teeth makes and breaks the contact once for<br>
-every tooth. The movable piece should have an insulated handle.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit Breaker, Mercury.</span><br>
-A circuit breaker which may be identical in principle, with the<br>
-automatic circuit breaker of an induction coil, but in which in place of<br>
-the anvil, q. v., a mercury cup is used, into which the end of a wire<br>
-dips and emerges as it is actuated by the impulses of the current. Each<br>
-dip makes the contact, which is broken as the wire springs back. The<br>
-mercury should be covered with alcohol to protect it from oxidation.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit Breaker, Pendulum.</span><br>
-A circuit breaker in which a pendulum in its swing makes and breaks a<br>
-contact. It may be kept in motion by clockwork, or by an electro-magnet,<br>
-attracting intermittently an armature attached to its rod, the<br>
-magnet circuit being opened and closed by the pendulum or circuit<br>
-breaker itself. A mercury contact may be used with it.<br>
-<br>
-<br>
-<img style="width: 302px; height: 764px;" alt="" src="images/121F88.jpg"><br>
-Fig. 88. PENDULUM CIRCUIT BREAKER.<br>
-<br>
-<br>
-122&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit Breaker, Tuning Fork.</span><br>
-A circuit breaker in which a tuning fork makes and breaks the circuit.<br>
-Each vibration of one of the prongs in one direction makes a contact,<br>
-and the reverse vibration breaks a contact. The adjustment is<br>
-necessarily delicate, owing to the limited amplitude of the motion of<br>
-the fork. The fork is kept in vibration sometimes by an electro-magnet,<br>
-which is excited as the circuit is closed by the fork. One leg of the<br>
-fork acts as the armature of the magnet, and is attracted according to<br>
-its own natural period.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit Breaker, Wheel.</span><br>
-A toothed wheel with a spring bearing against its teeth. One terminal of<br>
-a circuit connects with the wheel through its axle, the other connects<br>
-with the spring. When the wheel is turned the circuit is opened and<br>
-closed once for each tooth. The interstices between teeth on such a<br>
-wheel may be filled with insulating material, giving a cylindrical<br>
-surface for the contact spring to rub on.<br>
-<br>
-<br>
-<img style="width: 608px; height: 514px;" alt="" src="images/122F89.jpg"><br>
-Fig. 89--TOOTHED WHEEL CIRCUIT BREAKER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, Closed.</span><br>
-A circuit whose electric continuity is complete; to make an open circuit<br>
-complete by closing a switch or otherwise is to close, complete, or make<br>
-a circuit.<br>
-<br>
-Synonyms--Completed Circuit--Made Circuit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, Compound.</span><br>
-A circuit characterized by compounding of generating or receiving<br>
-devices, as including several separate batteries, or several motors, or<br>
-other receiving devices. It is sometimes used to indicate a circuit<br>
-having its battery arranged in series. It should be restricted to the<br>
-first definition.<br>
-<br>
-<br>
-123&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Derived.</span><br>
-A partial circuit connected to two points of another circuit, so as to<br>
-be in parallel with the portion thereof between such two points; a shunt<br>
-circuit.<br>
-<br>
-Synonyms--Shunt Circuit--Derivative Circuit--Parallel Circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Electric, Active.</span><br>
-A circuit through which a current passes. The circuit itself need only<br>
-be a conducting ring, or endless wire. Generally it includes, as part of<br>
-the circuit, a generator of electro-motive force, and through which<br>
-generator by conduction, ordinary or electrolytic, the same current goes<br>
-that passes through the rest of the circuit. One and the same current<br>
-passes through all parts of a series circuit when such current is<br>
-constant.<br>
-<br>
-A current being produced by electro-motive force, and electromotive<br>
-force disappearing in its production in an active circuit, there must be<br>
-some source of energy which will maintain electromotive force against<br>
-the drain made upon it by the current.<br>
-<br>
-The simplest conception of an active electric circuit is a ring or<br>
-endless conductor swept through a field of force so as to cut lines of<br>
-force. A simple ring dropped over a magnet pole represents the<br>
-simplification of this process. In such a ring a current, exceedingly<br>
-slight, of course, will be produced. In this case there is no generator<br>
-in the circuit. An earth coil (see Coil, Earth,) represents such a<br>
-circuit, with the addition, when experimented with, of a galvanometer in<br>
-the circuit.<br>
-<br>
-In practice, a circuit includes a generator such as a battery or dynamo,<br>
-and by conductors is led through a continuous path. Electric lamps,<br>
-electrolytic cells, motors and the like may be included in it.<br>
-<br>
-The term "circuit" is also applied to portions of a true circuit, as the<br>
-internal circuit, or external circuit. A certain amount of elasticity is<br>
-allowed in its use. It by no means necessarily indicates a complete<br>
-through circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Electrostatic.</span><br>
-(a) A circuit through which an electrostatic or high tension discharge<br>
-takes place. It is virtually an electric circuit.<br>
-<br>
-(b) The term is applied also to the closed paths of electrostatic lines<br>
-of force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, External.</span><br>
-The portion of a circuit not included within the generator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Grounded.</span><br>
-A circuit, one of whose members, the return circuit, is represented by<br>
-the earth, so that the earth completes the circuit. In telegraphy each<br>
-end of the line is grounded or connected to an earth-plate, q. v., or to<br>
-the water or gas-pipes, and the current is assumed to go through the<br>
-earth on its return. It really amounts to a discharging at one end, and<br>
-charging at the other end of the line. The resistance of the earth is<br>
-zero, but the resistance of the grounding or connection with the earth<br>
-may be considerable.<br>
-<br>
-Synonyms--Ground Circuit--Earth Circuit--Single Wire Circuit.<br>
-<br>
-[Transcriber's note: The resistance of the earth is high enough that<br>
-large power system return currents may produce dangerous voltage<br>
-gradients when a power line is shorted to the ground. Don't walk near<br>
-downed lines!]<br>
-<br>
-<br>
-124&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit Indicator.</span><br>
-A pocket compass, decomposition apparatus, galvanometer or other device<br>
-for indicating the condition of a wire, whether carrying a current or<br>
-not, and, if carrying one, its direction, and sometimes roughly<br>
-indicating its strength.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Internal.</span><br>
-The portion of an electric circuit included within the generator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Line.</span><br>
-The portion of a circuit embracing the main line or conductor, as in a<br>
-telegraph circuit the line carried on the poles; distinguished from the<br>
-local circuit (see Circuit, Local,) in telegraphy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Local.</span><br>
-In telegraphy, a short circuit with local generator or battery included,<br>
-contained within the limits of the office or station and operated by a<br>
-relay, q. v. This was the original local circuit; the term is applicable<br>
-to any similar arrangement in other systems. Referring to the cut, the<br>
-main line circuit includes the main battery, E, Key, P, Relay, R, ground<br>
-plates, G, G1. The relay magnet opens and closes the local circuit with<br>
-its local battery, L, and sounder magnet, H, with its armature, B. The<br>
-minor parts, such as switches, are omitted.<br>
-<br>
-<br>
-<img style="width: 656px; height: 446px;" alt="" src="images/124F90.jpg"><br>
-Fig. 90. LOCAL CIRCUIT OF TELEGRAPH SYSTEM.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, Local Battery.</span><br>
-A local circuit worked by and including a local battery in its course.<br>
-<br>
-<br>
-125&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, Loop.</span><br>
-A minor circuit introduced in series into another circuit by a cut-out,<br>
-or other device, so as to become a portion of the main circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit Loop Break.</span><br>
-A supporter or bracket with two arms for carrying insulators. Its use is<br>
-to enable a loop connection to be introduced into a line which is cut,<br>
-so as to enable the connection of the ends of the loop to be made, one<br>
-to each end of the through wire, which ends are attached, one to each of<br>
-the two insulators.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Main.</span><br>
-The circuit including the main line and apparatus supplied by the main<br>
-battery, as distinguished from the local circuit. (See Circuit, Local.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Main Battery.</span><br>
-The main circuit, including the main or principal battery in its course.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Metallic.</span><br>
-A circuit in which the current outside the generator, or similar parts,<br>
-is carried on a metallic conductor; a circuit without any ground<br>
-circuit. The including of a galvanic battery or electro plating bath<br>
-would not prevent the application of the term; its essential meaning is<br>
-the omission of the earth as the return circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Negative Side of.</span><br>
-The side of a circuit opposite to the positive side. (See Circuit,<br>
-Positive Side of) It is defined as the half of a circuit leading to the<br>
-positive terminal of the generator.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, Open.</span><br>
-A circuit with its continuity broken, as by disconnecting a wire from<br>
-the battery, or opening a switch; a broken circuit is its synonym. To<br>
-open a switch or disconnect or cut the wire is termed opening or<br>
-breaking the circuit.<br>
-<br>
-Synonyms--Incomplete Circuit--Broken Circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Positive Side of.</span><br>
-This side is such that an observer standing girdled by the current with<br>
-his head in the positive side or region, would see the current pass<br>
-around him from his right toward his left hand. It is also defined as<br>
-the half of the circuit leading to the negative terminal of the<br>
-generator.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, Recoil.</span><br>
-The portion of a parallel circuit presenting an alternative path, q. v.,<br>
-for a disruptive discharge.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuit, Return.</span><br>
-(a) The part of a circuit extending from the generator to the extreme<br>
-point in general, upon which no apparatus is placed. In telegraph<br>
-systems the ground generally forms the return circuit. The distinction<br>
-of return and working circuit cannot always be made.<br>
-<br>
-(b) It may also be defined as the portion of a circuit leading to the<br>
-negative terminal of the generator.<br>
-<br>
-<br>
-126&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circuits, Forked.</span><br>
-Circuits starting in different paths or directions from one and the same<br>
-point.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Simple.</span><br>
-A circuit containing a single generator, and single receiver of any<br>
-kind, such as a motor or sounder, with a single connecting conductor. It<br>
-is also used to indicate arrangement in multiple arc, but not generally,<br>
-or with approval.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuits, Parallel.</span><br>
-Two or more conductors starting from a common point and ending at<br>
-another common point are termed, parallel circuits, although really but<br>
-parts of circuits. If of equal resistance their joint resistance is<br>
-obtained by dividing the resistance of one by the number of parallel<br>
-circuits. If of unequal resistance r, r', r" , etc., the formula for<br>
-joint resistance, R, of two is<br>
-<br>
-R = ( r * r' ) / ( r + r' )<br>
-<br>
-This resistance may then be combined with a third one by the same<br>
-formula, and thus any number may be calculated.<br>
-<br>
-Synonym--Shunt Circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circuit, Voltaic.</span><br>
-Properly a circuit including a conductor and voltaic couple.<br>
-<br>
-It is also applied to the electric circuit, q. v., or to any circuit<br>
-considered as a bearer of current electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Circular Units</span>.<br>
-Units of area, usually applied to cross sectional area of conductors, by<br>
-whose use area is expressed in terms of&nbsp; circle of unit diameter,<br>
-usually a circular mil, which is the area of a circle of one-thousandth<br>
-of an inch diameter, or a circular millimeter, which is the area of a<br>
-circle of one millimeter diameter. Thus a wire one-quarter of an inch<br>
-in diameter has an area of 250 circular mils; a bar one centimeter in<br>
-diameter has an area of ten circular millimeters.<br>
-<br>
-[Transcriber's Note: Area is the diameter squared. A 1/4 inch wire has<br>
-62500 circular mils of area. A one centimeter (10 millimeter) wire has<br>
-100 circular millimeters of area. Actual area = circular mils * (PI/4).]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Circumflux.</span><br>
-The product of the total number of conductor turns on the armature of a<br>
-dynamo or motor, into the current carried thereby. For two pole machines<br>
-it is equal to twice the armature ampere-turns; for four pole machines<br>
-to four times such quantity, and so on.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clamp.</span><br>
-The appliance for grasping and retaining the end of the rod that holds a<br>
-carbon in the arc lamp.<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Clark's Compound.</span><br>
-A cement used for the outside of the sheath of telegraph cables.<br>
-Its formula is:<br>
-&nbsp; Mineral Pitch,&nbsp;&nbsp; 65 parts.<br>
-&nbsp; Silica,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 30
-parts.<br>
-&nbsp;
-Tar,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5 parts.<br>
-All parts by weight.<br>
-<br>
-<br>
-127&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Cleats.<br>
-A support; a short block of wood, grooved transversely, for holding<br>
-electric wires against a wall. For the three wire system three grooves<br>
-are used. The entire wiring of apartments is sometimes done by the<br>
-"cleat system," using cleats instead of battens, q. v., or mouldings.<br>
-The cleats are secured against the wall with the grooves facing it, and<br>
-the wires are introduced therein.<br>
-<br>
-<br>
-<img style="width: 584px; height: 237px;" alt="" src="images/127F91.jpg"><br>
-Fig. 91. TWO WIRE CLEAT.<br>
-<br>
-<br>
-<img style="width: 553px; height: 121px;" alt="" src="images/127F92.jpg"><br>
-Fig. 92. THREE WIRE CLEAT.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cleat, Crossing.</span><br>
-A cleat with grooves or apertures to support wires which cross each<br>
-other. Two or three grooves are transverse, and on the under side, as<br>
-above; one groove is longitudinal and on the upper side.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cleavage, Electrification by.</span><br>
-If a mass of mica is rapidly split in the dark a slight flash is<br>
-perceived. Becquerel found that in such separation the two pieces came<br>
-away oppositely charged with electricity. The splitting of mica is its<br>
-cleavage.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clock, Controlled.</span><br>
-In a system of electric clocks, the clocks whose movements are<br>
-controlled by the current, regulated by the master or controlling clock.<br>
-<br>
-Synonym--Secondary Clock.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clock, Controlling.</span><br>
-In a system of electric clocks the master clock which controls the<br>
-movements of the others, by regulating the current.<br>
-<br>
-Synonym--Master Clock.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clock, Electric Annunciator.</span><br>
-A clock operating any form of electric annunciator, as dropping<br>
-shutters, ringing bells, and the like. It operates by the machinery<br>
-closing circuits as required at any desired hour or intervals.<br>
-<br>
-<br>
-128&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clock, Electrolytic.</span><br>
-A clock worked by the electrolytic deposition and resolution of a<br>
-deposit of metal upon a disc. It is the invention of Nikola Tesla. A<br>
-metallic disc is mounted on a transverse axis, so as to readily rotate.<br>
-It is immersed in a vessel of copper sulphate. A current is passed<br>
-through the bath, the terminals or electrodes being near to and facing<br>
-the opposite edges of the disc, so that the line connecting the<br>
-electrodes lies in the plane of the disc. If a current is passed through<br>
-the solution by the electrodes, copper is deposited on one side of the<br>
-disc, and as it rotates under the influence of the weight thus<br>
-accumulated on one side, the same metal as it is brought to the other<br>
-side of the disc is redissolved. Thus a continuous rotation is<br>
-maintained. The cause of the deposition and solution is the position of<br>
-the disc; one-half becomes negative and the other positive in their<br>
-mutual relations.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clock, Self-winding Electric.</span><br>
-A clock which is wound periodically by an electric motor and battery.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Clockwork, Feed.</span><br>
-In arc-lamps the system of feeding the carbon or carbons by clockwork<br>
-whose movements are controlled by the resistance of the arc. This system<br>
-is employed in the Serrin, and in the Gramme regulators, among others.<br>
-The carbons, if they approach, move clockwork. The movement of this is<br>
-stopped or freed by an electro-magnet placed in shunt around the arc<br>
-and carbons.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cloisons.</span><br>
-Partitions or divisions; applied to the winding of electro-magnets and<br>
-coils where the winding is put on to the full depth, over single<br>
-sections of the core, one section at a time, until the whole core is<br>
-filled up.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Closure.</span><br>
-The closing or completion of a circuit by depressing a key or moving a<br>
-switch.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clutch.</span><br>
-In arc lamps a device for the feed of the upper carbons. In its simplest<br>
-form it is simply a plate or bar pierced with a hole through which the<br>
-carbon passes loosely. The action of the mechanism raises or lowers one<br>
-end of the plate or bar. As it rises it binds and clutches the carbon,<br>
-and if the action continues it lifts it a little. When the same end is<br>
-lowered the carbon and clutch descend together until the opposite end of<br>
-the clutch being prevented from further descent, the clutch approaches<br>
-the horizontal position and the rod drops bodily through the aperture.<br>
-The cut shows the clutches of the Brush double carbon lamp. In practice<br>
-the lifting and releasing as regulated by an electro-magnet are so very<br>
-slight that practically an almost absolutely steady feed is secured. A<br>
-similar clutch is used in the Weston lamp.<br>
-<br>
-<br>
-129&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Clutch, Electro-magnetic.</span><br>
-A clutch or appliance for connecting a shaft to a source of rotary<br>
-motion while the latter is in action. In one form a disc, in whose face<br>
-a groove has been formed, which groove is filled with a coil of wire, is<br>
-attached to the loose wheel, while the shaft carries a flat plate to act<br>
-as armature. On turning on the current the flat plate is attached,<br>
-adheres, and causes its wheel to partake of the motion of the shaft.<br>
-Contact is made by brushes and collecting rings.<br>
-<br>
-In the cut, A A is the attracted disc; the brushes, B B, take current to<br>
-the collecting rings, C. The magnetizing coil is embedded in the body of<br>
-the pulley, as shown.<br>
-<br>
-<br>
-<img style="width: 535px; height: 336px;" alt="" src="images/129F93.jpg"><br>
-Fig. 93. CLUTCH OF BRUSH LAMP.<br>
-<br>
-<br>
-<img style="width: 536px; height: 709px;" alt="" src="images/129F94.jpg"><br>
-Fig. 94. ELECTRO-MAGNETIC CLUTCH.<br>
-<br>
-<br>
-130&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coatings of a Condenser or Prime
-Conductor.</span><br>
-The thin conducting coatings of tinfoil, gold leaf or other conducting<br>
-substance, enabling the surface to receive and part with the electric<br>
-charge readily. Without such a coating the charge and discharge would be<br>
-very slow, and would operate by degrees only, as one part of a<br>
-non-conducting surface might be densely charged and another part be<br>
-quite devoid of sensible charge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Code, Cipher.</span><br>
-A code of arbitrary words to designate prearranged or predetermined<br>
-words, figures or sentences. The systems used in commerce have single<br>
-words to represent whole sentences or a number of words of a sentence.<br>
-This not only imparts a degree of secrecy, but makes the messages much<br>
-shorter. Codes are used a great deal in cable transmission.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Code, Telegraphic.</span><br>
-A telegraphic alphabet. (See Alphabets, Telegraphic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coefficient.</span><br>
-In algebra, the numerical multiplier of a symbol, as in the expression<br>
-"5x," 5 is the coefficient. In physics, generally a number expressing<br>
-the ratio or relation between quantities, one of which is often unity,<br>
-as a standard or base of the set of coefficients. Thus the coefficient<br>
-of expansion by heat of any substance is obtained by dividing its volume<br>
-for a given degree of temperature by its volume at the standard<br>
-temperature as 0&ordm; C., or 32&ordm; F. This gives a fraction by
-which if any<br>
-volume of a substance, taken at 0&ordm; C., or at whatever may be taken
-as<br>
-the basic temperature, is multiplied, the expanded volume for the given<br>
-change of temperature will be obtained as the product. A coefficient<br>
-always in some form implies the idea of a multiplier. Thus the<br>
-coefficient of an inch referred to a foot would be 1/12 or .833+,<br>
-because any number of inches multiplied by that fraction would give the<br>
-corresponding number of feet.<br>
-<br>
-[Transcriber's note: 1/12 is 0.0833+]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coefficient, Economic.</span><br>
-In machinery, electric generators, prime motors and similar structures,<br>
-the number expressing the ratio between energy absorbed by the device,<br>
-and useful, not necessarily available, work obtained from it. It is<br>
-equal to work obtained divided by energy absorbed, and is necessarily a<br>
-fraction. If it exceeded unity the doctrine of the conservation of<br>
-energy would not be true. The economic coefficient expresses the<br>
-efficiency, q. v., of any machine, and of efficiencies there are several<br>
-kinds, to express any one of which the economic coefficient may be used.<br>
-Thus, let W--energy absorbed, and w = work produced ; then w/W is the<br>
-economic coefficient, and for each case would be expressed numerically.<br>
-(See Efficiency, Commercial--Efficiency, Electrical--Efficiency of<br>
-Conversion.)<br>
-<br>
-The distinction between useful and available work in a dynamo is as<br>
-follows: The useful work would include the work expended by the field,<br>
-and the work taken from the armature by the belt or other mechanical<br>
-connection. Only the latter would be the available work.<br>
-<br>
-<br>
-131&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coercive or Coercitive Force.</span><br>
-The property of steel or hard iron, in virtue of which it slowly takes<br>
-up or parts with magnetic force, is thus termed ("traditionally";<br>
-Daniell). It seems to have to do with the positions of the molecules, as<br>
-jarring a bar of steel facilitates its magnetization or accelerates its<br>
-parting, when not in a magnetic field, with its permanent or residual<br>
-magnetism. For this reason a permanent magnet should never be jarred,<br>
-and permitting the armature to be suddenly attracted and to strike<br>
-against it with a jar injures its attracting power.<br>
-<br>
-Coercive force is defined also as the amount of negative magnetizing<br>
-force required to reduce remnant magnetism to zero.<br>
-<br>
-By some authorities the term is entirely rejected, as the phenomenon<br>
-does not seem directly a manifestation of force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coil and Coil Plunger.</span><br>
-A device resembling the coil and plunge, q. v., except that for the<br>
-plunger of iron there is substituted a coil of wire of such diameter as<br>
-to enter the axial aperture of the other, and wound or excited in the<br>
-same or in the opposite sense, according to whether attraction or<br>
-repulsion is desired.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil and Plunger.</span><br>
-A coil provided with a core which is free to enter or leave the central<br>
-aperture. When the coil is excited, the core is drawn into it. Various<br>
-forms of this device have been used in arc lamp regulators.<br>
-<br>
-Synonym--Sucking coil.<br>
-<br>
-<br>
-<img style="width: 190px; height: 632px;" alt="" src="images/131F95.jpg"><br>
-Fig. 95. COIL AND COIL PLUNGER OF MENGIES ARC LAMP.<br>
-<br>
-<br>
-<img style="width: 228px; height: 660px;" alt="" src="images/131F96.jpg"><br>
-Fig. 96. COIL AND PLUNGER EXPERIMENT.<br>
-<br>
-<br>
-132&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil and Plunger, Differential.</span><br>
-An arrangement of coil and plunger in which two plungers or one plunger<br>
-are acted on by two coils, wound so as to act oppositely or<br>
-differentially on the plunger or plungers. Thus one coil may be in<br>
-parallel with the other, and the action on the plunger will then depend<br>
-on the relative currents passing through the coils.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Choking.</span><br>
-A coil of high self-induction, used to resist the intensity of or<br>
-"choke" alternating currents. Any coil of insulated wire wound around<br>
-upon a laminated or divided iron core forms a choking coil. The iron<br>
-coil is usually so shaped as to afford a closed magnetic circuit.<br>
-<br>
-A converter or transformer acts as a choking coil as long as its<br>
-secondary is left open. In alternating current work special choking<br>
-coils are used. Thus for theatrical work, a choking coil with a movable<br>
-iron core is used to change the intensity of the lights. It is in<br>
-circuit with the lamp leads. By thrusting in the core the self-induction<br>
-is increased and the current diminishes, lowering the lamps; by<br>
-withdrawing it the self-induction diminishes, and the current increases.<br>
-Thus the lamps can be made to gradually vary in illuminating power like<br>
-gas lights, when turned up or down.<br>
-<br>
-Synonyms--Kicking Coil--Reaction Coil.<br>
-<br>
-<br>
-<img style="width: 392px; height: 766px;" alt="" src="images/132F97.jpg"><br>
-Fig. 97. DIFFERENTIAL COILS AND PLUNGERS.<br>
-<br>
-<br>
-<img style="width: 531px; height: 300px;" alt="" src="images/132F98.jpg"><br>
-Fig. 98. BISECTED COILS.<br>
-<br>
-<br>
-133&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coils, Bisected.</span><br>
-Resistance coils with connections at their centers, as shown in the<br>
-diagram. They are used for comparing the resistances of two conductors.<br>
-The connections are arranged as shown in the coil, each coil being<br>
-bisected. For the wires, movable knife-edge contacts are employed. The<br>
-principle of the Wheatstone bridge is used in the method and<br>
-calculations.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coil, Earth.</span><br>
-A coil of wire mounted with commutator to be rotated so as to cut the<br>
-lines of force of the earth's magnetic field, thereby generating<br>
-potential difference. The axis of rotation may be horizontal, when the<br>
-potential will be due to the vertical component of the earth's field, or<br>
-the axis may be horizontal, when the potential will be due to the<br>
-vertical component, or it may be set at an intermediate angle.<br>
-<br>
-Synonym--Delezenne's Circle.<br>
-<br>
-<br>
-<img style="width: 610px; height: 430px;" alt="" src="images/133F99.jpg"><br>
-Fig. 99. DELEZENNE'S CIRCLE OR EARTH COIL.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Electric.</span><br>
-A coil of wire used to establish a magnetic field by passing a current<br>
-through it. The wire is either insulated, or so spaced that its<br>
-convolutions do not touch.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Flat.</span><br>
-A coil whose windings all lie in one plane, making a sort of disc, or an<br>
-incomplete or perforated disc.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Induction.</span><br>
-A coil in which by mutual induction the electromotive force of a portion<br>
-of a circuit is made to produce higher or lower electro-motive force, in<br>
-an adjoining circuit, or in a circuit, part of which adjoins the<br>
-original circuit, or adjoins part of it.<br>
-<br>
-An induction coil comprises three principal parts, the core, the primary<br>
-coil and the secondary coil. If it is to be operated by a steady<br>
-current, means must be provided for varying it or opening and closing<br>
-the primary circuit. A typical coil will be described.<br>
-<br>
-<br>
-134&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The core is a mass of soft iron preferably divided to prevent extensive<br>
-Foucault currents. A cylindrical bundle of soft iron wires is generally<br>
-used. Upon this the primary coil of reasonably heavy wire, and of one or<br>
-two layers in depth, is wrapped, all being carefully insulated with<br>
-shellac and paper where necessary. The secondary coil is wrapped upon or<br>
-over the primary. It consists of very fine wire; No. 30 to 36 is about<br>
-the ordinary range. A great many turns of this are made. In general<br>
-terms the electro-motive force developed by the secondary stands to that<br>
-of the primary terminals in the ratio of the windings. This is only<br>
-approximate.<br>
-<br>
-The greatest care is required in the insulating. The secondary is<br>
-sometimes wound in sections so as to keep those parts differing greatly<br>
-in potential far from each other. This prevents sparking, which would<br>
-destroy the insulation.<br>
-<br>
-A make and break, often of the hammer and anvil type, is operated by the<br>
-coil. (See Circuit Breaker, Automatic.) As the current passes through<br>
-the primary it magnetizes the core. This attracts a little hammer which<br>
-normally resting on an anvil completes the circuit. The hammer as<br>
-attracted is lifted from the anvil and breaks the circuit. The soft iron<br>
-core at once parts with its magnetism and the hammer falls upon the<br>
-anvil again completing the circuit. This operation goes on rapidly, the<br>
-circuit being opened and closed in quick succession.<br>
-<br>
-Every closing of the primary circuit tends to produce a reverse current<br>
-in the secondary, and every opening of the primary circuit tends to<br>
-produce a direct current in the secondary. Both are of extremely short<br>
-duration, and the potential difference of the two terminals of the<br>
-secondary may be very high if there are many times more turns in the<br>
-secondary than in the primary.<br>
-<br>
-The extra currents interfere with the action of an induction coil. To<br>
-avoid their interference a condenser is used. This consists of two<br>
-series of sheets of tin foil. Leaves of paper alternate with the sheets<br>
-of tin-foil, the whole being built up into a little book. Each sheet of<br>
-tin-foil connects electrically with the sheet next but one to it. Thus<br>
-each leaf of a set is in connection with all others of the same set, but<br>
-is insulated from the others. One set of leaves of tin-foil connects<br>
-with the hammer, the other with the anvil. In large coils there may be<br>
-75 square feet of tin-foil in the condenser.<br>
-<br>
-The action of the condenser is to dispose of the direct extra current.<br>
-When the primary circuit is opened this current passes into the<br>
-condenser, which at once discharges itself in the other direction<br>
-through the coil. This demagnetizes the core, and the action intensifies<br>
-and shortens the induced current. The condenser prevents sparking, and<br>
-in general improves the action of the coil.<br>
-<br>
-Many details enter into the construction of coils, and many variations<br>
-in their construction obtain. Thus a mercury cup into which a plunger<br>
-dips often replaces the anvil and hammer.<br>
-<br>
-<br>
-135&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The induction coil produces a rapid succession of sparks, which may<br>
-spring across an interval of forty inches. The secondary generally ends<br>
-in special terminals or electrodes between which the sparking takes<br>
-place. A plate of glass, two inches in thickness, can be pierced by<br>
-them. In the great Spottiswoode coil there are 280 miles of wire in the<br>
-secondary, and the wire is about No. 36 A.W.G.<br>
-<br>
-<br>
-<img style="width: 542px; height: 407px;" alt=""
- src="images/135F100.jpg"><br>
-Fig. 100. VERTICAL SECTION OF INDUCTION COIL.<br>
-<br>
-<br>
-<img style="width: 534px; height: 290px;" alt=""
- src="images/135F101.jpg"><br>
-Fig. l01. PLAN OF INDUCTION COIL CONNECTIONS.<br>
-<br>
-<br>
-Induction coils have quite extended use in electrical work. They are<br>
-used in telephone transmitters, their primary being in circuit with the<br>
-microphone, and their secondary with the line and receiving telephone.<br>
-In electric welding, and in the alternating current system they have<br>
-extended application. In all these cases they have no automatic circuit<br>
-breaker, the actuating current being of intermittent or alternating<br>
-type.<br>
-<br>
-<br>
-136&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-In the cuts the general construction of an induction coil is shown. In<br>
-the sectional elevation, Fig. 100, A, is the iron core; B is the primary<br>
-of coarse wire; C is a separating tube, which may be of pasteboard; D is<br>
-the secondary of fine wire; E, E are the binding posts connected to the<br>
-secondary; H, H are the heads or standards; K, K are the terminals of<br>
-the primary; F is the vibrating contact spring; G, a standard carrying<br>
-the contact screw; J is the condenser with wires, L, M, leading to it.<br>
-<br>
-Referring to the plan, Fig. 101, H represents the primary coil; B and A<br>
-are two of the separate sheets of the condenser, each sheet with<br>
-projecting ears; G, G are the heads of the coil; the dark lines are<br>
-connections to the condenser. One set of sheets connects with the<br>
-primary coil at C, and also with the vibrating spring shown in plan and<br>
-in the elevation at F. The other set of sheets connects with the post,<br>
-carrying the contact screw. The other terminal of the primary runs to a<br>
-binding post E. F, in the plan is a binding post in connection with the<br>
-standard and contact screw.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coil, Induction, Inverted.</span><br>
-An induction coil arranged to have a lower electro-motive force in the<br>
-secondary than in the primary. This is effected by having more<br>
-convolutions in the primary wire than in the secondary. Such coils in<br>
-practice are used with the alternating current and then do not include a<br>
-circuit breaker or condenser. They are employed in alternating current<br>
-system and in electric welding. (See Welding, Electric--Converter.)<br>
-<br>
-In the cut an inverted coil, as constructed for electric welding is<br>
-shown. In it the primary coil is marked P; the secondary, merely a bar<br>
-of metal, is marked E, with terminals S, S; the heavy coils, I, of iron<br>
-wire are the core; K is a screw for regulating the clamps; J, Z is a<br>
-second one for the same purpose, while between D and D' the heat is<br>
-produced for welding the bars, B, B', held in the clamps, C, C'. It will<br>
-be seen how great may be the difference in turns between the single<br>
-circle of heavy copper rod or bar which is the secondary of the coil,<br>
-and the long coil of wire forming the primary.<br>
-<br>
-<br>
-<img style="width: 420px; height: 715px;" alt=""
- src="images/136F102.jpg"><br>
-Fig. 102. INVERTED INDUCTION COIL FOR ELECTRIC WELDING.<br>
-<br>
-<br>
-137&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Induction, Telephone.</span><br>
-An induction coil used in telephone circuits. It is placed in the box or<br>
-case near the transmitter. The primary is in circuit with the<br>
-microphone. The secondary is in circuit with the line and receiving<br>
-telephone. In the Bell telephone apparatus the primary of the induction<br>
-coil is wound with No. 18 to 24 A. W. G. wire to a resistance of 1/2<br>
-ohm; the secondary, with No. 36 wire to a resistance of 80 ohms. The<br>
-Edison telephone induction coil was wound with similar wires to a<br>
-resistance of 3 to 4 ohms and of 250 ohms respectively.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Magnetizing.</span><br>
-A coil of insulated wire for making magnets; and for experimental uses;<br>
-it has a short axis and central aperture of as small size as consistent<br>
-with the diameter of the bar to be magnetized, which has to pass through<br>
-it readily. The wire may be quite heavy, 2 or 3 millimeters (.08--.12<br>
-inch) thick, and is cemented together with carpenter's glue, or with<br>
-shellac or ethereal solution of gum copal. In use it is passed over the<br>
-bar a few times while a heavy current is going through it. It is used<br>
-for magic circles also. (See Circle, Magic.)<br>
-<br>
-<br>
-<img style="width: 642px; height: 215px;" alt=""
- src="images/137F103.jpg"><br>
-Fig. 103. MAGNETIZING COIL.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Resistance.</span><br>
-A coil constructed for the purpose of offering a certain resistance to a<br>
-steady current. This resistance may be for the purpose of carrying out<br>
-quantitative tests, as in Wheatstone bridge work (see Wheatstone's<br>
-Bridge), or simply to reduce the intensity of a current. For the first<br>
-class of work the coils are wound so as to prevent the creation of a<br>
-magnetic field. This is effected by first doubling the wire without<br>
-breaking it, and then starting at the bend the doubled wire, which is<br>
-insulated, is wound on a bobbin or otherwise until a proper resistance<br>
-is shown by actual measurement. The coils are generally contained or set<br>
-in closed boxes with ebonite tops. Blocks of brass are placed on the<br>
-top, and one end from one coil and one end from the next connect with<br>
-the same block. By inserting a plug, P, so as to connect any two blocks,<br>
-which have grooves reamed out for the purpose, the coil beneath will be<br>
-short circuited. German silver, platinoid or other alloy, q. v., is<br>
-generally the material of the wire. A great object is to have a wire<br>
-whose resistance will be unaffected by heat.<br>
-<br>
-<br>
-138&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 682px; height: 336px;" alt=""
- src="images/138F104.jpg"><br>
-Fig. 104. RESISTANCE COILS AND CONNECTIONS, SHOWING PLUG.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Coil, Rhumkorff.</span><br>
-The ordinary induction coil with circuit breaker, for use with original<br>
-direct and constant current, is thus termed. (See Coil, Induction.)<br>
-<br>
-Synonym--Inductorium.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coil, Ribbon.</span><br>
-A coil made of copper ribbon wound flatwise, often into a disc-like<br>
-shape, and insulated by tape or strips of other material intervening<br>
-between the successive turns.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coils, Compensating.</span><br>
-Extra coils on the field magnets of dynamos or motors, which coils are<br>
-in series with the armature windings for the purpose of keeping the<br>
-voltage constant. In compound wound machines the regular series-wound<br>
-coil is thus termed. In a separately excited dynamo a coil of the same<br>
-kind in circuit with the armature may be used as a compensator.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coils, Henry's.</span><br>
-An apparatus used in repeating a classic experiment in electro-magnetic<br>
-induction, due to Prof. Henry. It consists in a number of coils, the<br>
-first and last ones single, the intermediate ones connected in pairs,<br>
-and one of one pair placed on the top of one of the next pair. On<br>
-opening or closing the circuit of an end coil the induced effect goes<br>
-through the series and is felt in the circuit of the other end coil.<br>
-Prof. Henry extended the series so as to include seven successive<br>
-inductions, sometimes called inductions of the first, second, third and<br>
-other orders. Frequently ribbon coils (see Coil, Ribbon,) are used in<br>
-these experiments.<br>
-<br style="font-weight: bold;">
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coils, Sectioned.</span><br>
-A device for prolonging the range of magnetic attraction. It consists of<br>
-a series of magnetizing coils traversed by an iron plunger. As it passes<br>
-through them, the current is turned off the one in the rear or passing<br>
-to the rear and turned into the next one in advance. The principle was<br>
-utilized in one of Page's electric motors about 1850, and later by<br>
-others. The port-electric railroad, q. v., utilizes the same principle.<br>
-<br>
-<br>
-139&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Collecting Ring.</span><br>
-In some kinds of generators instead of the commutator a pair of<br>
-collecting rings of metal, insulated from the machine and from each<br>
-other, are carried on the armature shaft. A brush, q. v., presses on<br>
-each, and the circuit terminals connect to these two brushes. Such rings<br>
-are employed often on alternating current generators, where the current<br>
-does not have to be changed or commuted. Collecting rings with their<br>
-brushes are used also where a current has to be communicated to a<br>
-revolving coil or circuit as in the magnetic car wheel, the cut of which<br>
-is repeated here. The coil of wire surrounding the wheel and rotating<br>
-with it has to receive current. This it receives through the two<br>
-stationary brushes which press upon two insulated metallic rings,<br>
-surrounding the shaft. The terminals of the coil connect one to each<br>
-ring. Thus while the coil rotates it constantly receives current, the<br>
-brushes being connected to the actuating circuit.<br>
-<br>
-<br>
-<img style="width: 393px; height: 590px;" alt=""
- src="images/139F105.jpg"><br>
-Fig. 105. MAGNETIC CAR WHEEL SHOWING <br>
-COLLECTING RINGS AND BRUSHES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Collector.</span><br>
-(a) A name for the brush, q. v., in mechanical electric generators, such<br>
-as dynamos, a pair of which collectors or brushes press on the<br>
-commutator or collecting rings, and take off the current.<br>
-<br>
-(b) The pointed connections leading to the prime conductor on a static<br>
-machine for collecting the electricity; often called combs. The points<br>
-of the combs or collectors face the statically charged rotating glass<br>
-plate or cylinder of the machine.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Colombin.</span><br>
-The insulating material between the carbons in a Jablochkoff candle or<br>
-other candle of that type. Kaolin was originally used. Later a mixture<br>
-of two parts calcium sulphate (plaster of Paris) and one part barium<br>
-sulphate (barytes) was substituted.<br>
-<br>
-The colombin was three millimeters (.12 inch) wide, and two millimeters<br>
-(.08 inch) thick. (See Candle, Jablochkoff.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Column, Electric.</span><br>
-An old name for the voltaic pile, made up of a pile of discs of copper<br>
-and zinc, with flannel discs, wet with salt solution or dilute acid,<br>
-between each pair of plates.<br>
-<br>
-<br>
-140&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Comb.</span><br>
-A bar from which a number of teeth project, like the teeth of a comb. It<br>
-is used as a collector of electricity from the plate of a frictional or<br>
-influence electric machine; it is also used in a lightning arrester to<br>
-define a path of very high resistance but of low self-induction, for the<br>
-lightning to follow to earth.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Communicator.</span><br>
-The instrument by which telegraph signals are transmitted is sometimes<br>
-thus termed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Commutator.</span><br>
-In general an apparatus for changing. It is used on electric current<br>
-generators, and motors, and on induction coils, and elsewhere, for<br>
-changing the direction of currents, and is of a great variety of types.<br>
-<br>
-Synonym--Commuter (but little used).<br>
-<br>
-<br>
-<img style="width: 603px; height: 371px;" alt=""
- src="images/140F106.jpg"><br>
-Fig. 106. DYNAMO OR MOTOR COMMUTATOR.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Commutator Bars.</span><br>
-The metallic segments of a dynamo or motor commutator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Commutator, Flats in.</span><br>
-A wearing away or lowering in level of one or more metallic segments of<br>
-a commutator. They are probably due in many cases to sparking, set up by<br>
-periodic springing in the armature mounting, or by defective commutator<br>
-connections.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Commutator of Current Generators and
-Motors.</span><br>
-In general a cylinder, formed of alternate sections of conducting and<br>
-non-conducting material, running longitudinally or parallel with the<br>
-axis. Its place is on the shaft of the machine, so that it rotates<br>
-therewith. Two brushes, q. v., or pieces of conducting material, press<br>
-upon its surface.<br>
-<br>
-<br>
-141&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-As a part of electric motors and generators, its function is to collect<br>
-the currents produced by the cutting of lines of force so as to cause<br>
-them all to concur to a desired result. The cut shows the simplest form<br>
-of commutator, one with but two divisions. Its object may be to enable a<br>
-current of constant direction to be taken from a rotating armature, in<br>
-which the currents alternate or change direction once in each rotation.<br>
-It is carried by the shaft A of the armature and rotates with it. It<br>
-consists of two leaves, S S, to which the terminals of the armature are<br>
-connected. Two springs, W W, the terminals of the outer circuit, press<br>
-against the leaves. The springs which do this take off the current. It<br>
-is so placed, with reference to the springs and armature, that just as<br>
-the current changes in direction, each leaf changes from one spring to<br>
-the other. Thus the springs receive constant direction currents. The<br>
-changing action of this commutator appears in its changing the character<br>
-of the current from alternating to constant. Were two insulated<br>
-collecting rings used instead of a commutator, the current in the outer<br>
-circuit would be an alternating one. On some dynamos the commutator has<br>
-a very large number of leaves.<br>
-<br>
-Taking the Gramme ring armature, there must be as many divisions of the<br>
-commutator as there are connections to the coils. In this case the<br>
-function of the commutator is simply to lessen friction, for the brushes<br>
-could be made to take current from the coils directly outside of the<br>
-periphery of the ring.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Commutator, Split Ring.</span><br>
-A two-division commutator for a motor; it consists of two segments of<br>
-brass or copper plate, bent to arcs of a circle, and attached to an<br>
-insulating cylinder. They are mounted on the revolving spindle, which<br>
-carries the armature, and acts as a two part commutator. For an example<br>
-of its application, see Armature, Revolving, Page's. (See also Fig.<br>
-107.)<br>
-<br>
-<br>
-<img style="width: 526px; height: 338px;" alt=""
- src="images/141F107.jpg"><br>
-Fig. 107. SECTION OF SPLIT RING COMMUTATOR, WITH BRUSHES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass.</span><br>
-An apparatus for utilizing the directive force of the earth upon the<br>
-magnetic needle. It consists of a circular case, within which is poised<br>
-a magnetized bar of steel. This points approximately to the north, and<br>
-is used on ships and elsewhere to constantly show the direction of the<br>
-magnetic meridian. Two general types are used. In one the needle is<br>
-mounted above a fixed "card" or dial, on which degrees or points of the<br>
-compass, q. v., are inscribed. In the other the card is attached to the<br>
-needle and rotates with it. The latter represents especially the type<br>
-known as the mariner's compass. (See Compass, Mariner's--Compass,<br>
-Spirit, and other titles under compass, also Magnetic Axis--Magnetic<br>
-Elements.) The needle in good compasses carries for a bearing at its<br>
-centre, a little agate cup, and a sharp brass pin is the point of<br>
-support.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass, Azimuth.</span><br>
-A compass with sights on one of its diameters; used in determining the<br>
-magnetic bearing of objects.<br>
-<br>
-<br>
-142&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass Card.</span><br>
-The card in a compass; it is circular in shape, and its centre coincides<br>
-with the axis of rotation of the magnetic needle; on it are marked the<br>
-points of the compass, at the ends generally of star points. (See<br>
-Compass, Points of the.) It may be fixed, and the needle may be poised<br>
-above it, or it may be attached to the needle and rotate with it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass, Declination.</span><br>
-An instrument by which the magnetic declination of any place may be<br>
-determined. It is virtually a transit instrument and compass combined,<br>
-the telescope surmounting the latter. In the instrument shown in the<br>
-cut, L is a telescope mounted by its axis, X, in raised journals with<br>
-vernier, K, and arc x, for reading its vertical angle, with level n. The<br>
-azimuth circle, Q, R, is fixed. A vernier, V is carried by the box, A,<br>
-E, and both turn with the telescope. A very light lozenge-shaped<br>
-magnetic needle, a, b, is pivoted in the exact centre of the graduated<br>
-circles, Q R, and M. The true meridian is determined by any convenient<br>
-astronomical method, and the telescope is used for the purpose. The<br>
-variation of the needle from the meridian thus determined gives the<br>
-magnetic declination.<br>
-<br>
-<br>
-<img style="width: 491px; height: 737px;" alt=""
- src="images/142F108.jpg"><br>
-FIG. 108. DECLINATION COMPASS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass, Inclination.</span><br>
-A magnetic needle mounted on a horizontal axis at its centre of gravity,<br>
-so as to be free to assume the dip, or magnetic inclination, when placed<br>
-in the magnetic meridian. It moves over the face of a vertical graduated<br>
-circle, and the frame also carries a spirit level and graduated<br>
-horizontal circle. In use the frame is turned until the needle is<br>
-vertical. Then the axis of suspension of the needle is in the magnetic<br>
-meridian. The vertical circle is then turned through 90&deg; of the
-horizon,<br>
-which brings the plane of rotation of the needle into the magnetic<br>
-meridian, when it assumes the inclination of the place.<br>
-<br>
-<br>
-143&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass, Mariner's.</span><br>
-A compass distinguished by the card being attached to and rotating with<br>
-the needle. A mark, the "lubber's mark" of the sailors is made upon the<br>
-case. This is placed so that the line connecting it, and the axis of<br>
-rotation of the card is exactly in a plane, passing through the keel of<br>
-the ship. Thus however the ship may be going, the point of the card<br>
-under or in line with the "lubber's mark," shows how the ship is<br>
-pointing. The case of the mariner's compass is often bowl-shaped and<br>
-mounted in gimbals, a species of universal joint, so as to bc always<br>
-horizontal. (See Compass, Spirit-Gimbals.)<br>
-<br>
-<br>
-<img style="width: 699px; height: 488px;" alt=""
- src="images/143F109.jpg"><br>
-FIG. 109. MARINER'S COMPASS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass, Points of the.</span><br>
-The circle of the horizon may bc and is best referred to angular<br>
-degrees. It has also been divided into thirty-two equiangular and named<br>
-points. A point is 11.25&deg;. The names of the points are as follows:<br>
-North, North by East, North North-east, North-east by North, North-east,<br>
-North-east by East, East North-east, East by North, East, East by South,<br>
-East South-east, South-east by East, South-east, South-east by South,<br>
-South South-east, South by East, South, South by West, South South-west,<br>
-South-west by South, South-west, South-west by West, West South-west,<br>
-West by South, West, West by North, West North-west, North-west by West,<br>
-North-west, North West by North, North North-west, North by West. They<br>
-are indicated by their initials as N. N. W., North North-west, N. by W.,<br>
-North by West.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Compass, Spirit.</span><br>
-A form of mariner's compass. The bowl or case is hermetically sealed and<br>
-filled with alcohol or other nonfreezing liquid. The compass card is<br>
-made with hollow compartments so as nearly to float. In this way the<br>
-friction of the pivot or point of support is greatly diminished, and the<br>
-compass is far more sensitive.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compass, Surveyor's.</span><br>
-A species of theodolite; a telescope with collimation lines, mounted<br>
-above a compass, so as to be applicable for magnetic surveys. Its use is<br>
-to be discouraged on account of the inaccuracy and changes in<br>
-declination of the magnetic needle.<br>
-<br>
-<br>
-144&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Compensating Resistances.</span><br>
-In using a galvanometer shunt the total resistance of the circuit is<br>
-diminished so that in some cases too much current flows through it; in<br>
-such case additional resistance, termed as above, is sometimes<br>
-introduced in series. The shunt in parallel with the galvanometer is<br>
-thus compensated for, and the experimental or trial circuit does not<br>
-take too much current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Complementary Distribution.</span><br>
-Every distribution of electricity has somewhere a corresponding<br>
-distribution, exactly equal to it of opposite electricity; the latter is<br>
-the complimentary distribution to the first, and the first distribution<br>
-is also complimentary to it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Component.</span><br>
-A force may always be represented diagrammatically by a straight line,<br>
-terminating in an arrow-head to indicate the direction, and of length to<br>
-represent the intensity of the force. The line may always be assumed to<br>
-represent the diagonal of a parallelogram, two of whose sides are<br>
-represented by lines starting from the base of the arrow, and of length<br>
-fixed by the condition that the original force shall be the diagonal of<br>
-the parallelogram of which they are two contiguous sides; such lines are<br>
-called components, and actually represent forces into which the original<br>
-force may always be resolved. The components can have any direction.<br>
-Thus the vertical component of a horizontal force is zero; its<br>
-horizontal component is equal to itself. Its 450 component is equal to<br>
-the square root of one-half of its square.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Condenser.</span><br>
-An appliance for storing up electrostatic charges: it is also called a<br>
-static accumulator. The telegraphic condenser consists of a box packed<br>
-full of sheets of tinfoil. Between every two sheets is a sheet of<br>
-paraffined paper, or of mica. The alternate sheets of tinfoil are<br>
-connected together, and each set has its own binding post. (See<br>
-Accumulator, Electrostatic.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Condenser, Sliding.</span><br>
-An apparatus representing a Leyden jar whose coatings can be slid past<br>
-each other. This diminishes or increases the facing area, and<br>
-consequently in almost exactly similar ratio diminishes or increases the<br>
-capacity of the condenser.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conductance.</span><br>
-The conducting power of a given mass of specified material of specified<br>
-shape and connections. Conductance varies in cylindrical or prismatic<br>
-conductors, inversely as the length, directly as the cross-section, and<br>
-with the conductivity of the material. Conductance is an attribute of<br>
-any specified conductor, and refers to its shape, length and other<br>
-factors. Conductivity is an attribute of any specified material without<br>
-direct reference to its shape, or other factors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conduction.</span><br>
-The process or act of conducting a current.<br>
-<br>
-<br>
-145&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conductivity.</span><br>
-The relative power of conducting the electric current possessed by<br>
-different substances. A path for the current through the ether is opened<br>
-by the presence of a body of proper quality, and this quality, probably<br>
-correlated to opacity, is termed conductivity. There is no perfect<br>
-conductor, all offer some resistance, q. v., and there is hardly any<br>
-perfect non-conductor. It is the reverse and reciprocal of resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conductivity, Specific.</span><br>
-The reciprocal of specific resistance. (See Resistance--Specific.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Conductivity, Unit of.</span><br>
-The reciprocal of the ohm; it is a more logical unit, but has never been<br>
-generally adopted; as a name the title mho (or ohm written backwards)<br>
-has been suggested by Sir William Thomson, and provisionally adopted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conductivity, Variable.</span><br>
-The conductivity for electric currents of conductors varies with their<br>
-temperature, with varying magnetization, tension, torsion and<br>
-compression.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conductor.</span><br>
-In electricity, anything that permits the passage of an electric<br>
-current. Any disturbance in the ether takes the form of waves because<br>
-the ether has restitutive force or elasticity. In a conductor, on the<br>
-other hand, this force is wanting; it opens a path through the ether and<br>
-a disturbance advances through it from end to end with a wave front, but<br>
-with no succession of waves. This advance is the beginning of what is<br>
-termed a current. It is, by some theorists, attributed to impulses given<br>
-at all points along the conductor through the surrounding ether, so that<br>
-a current is not merely due to an end thrust. If ether waves preclude a<br>
-current on account of their restitutive force, ether waves cannot be<br>
-maintained in a conductor, hence conductors should be opaque to light,<br>
-for the latter is due to ether waves. This is one of the more practical<br>
-every day facts brought out in Clerk Maxwell's electromagnetic theory of<br>
-light. The term conductor is a relative one, as except a vacuum there is<br>
-probably no substance that has not some conducting power. For relative<br>
-conducting power, tables of conductivity, q. v., should be consulted.<br>
-The metals beginning with silver are the best conductors, glass is one<br>
-of the worst.<br>
-<br>
-[Transcriber's note: See "ether" for contemporary comments on this now<br>
-discarded concept.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Conductor, Anti-Induction.</span><br>
-A current conductor arranged to avoid induction from other lines. Many<br>
-kinds have been invented and made the subject of patents. A fair<br>
-approximation may be attained by using a through metallic circuit and<br>
-twisting the wires composing it around each other. Sometimes concentric<br>
-conductors, one a wire and the other a tube, are used, insulated, one<br>
-acting as return circuit for the other.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Conductor, Conical.</span><br>
-A prime conductor of approximately conical shape, but rounded on all<br>
-points and angles. Its potential is highest at the point.<br>
-<br>
-<br>
-146&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Conductor, Imbricated.</span><br>
-A conductor used in dynamo armatures for avoiding eddy currents, made by<br>
-twisting together two or more strips of copper.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Conductor, Prime.</span><br>
-A body often cylindrical or spherical in shape, in any case with no<br>
-points or angles, but rounded everywhere, whose surface, if the<br>
-conductor itself is not metallic, is made conducting by tinfoil or gold<br>
-leaf pasted over it. It is supported on an insulating stand and is used<br>
-to collect or receive and retain static charges of electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conductors, Equivalent.</span><br>
-Conductors of identical resistance. The quotient of the length divided<br>
-by the product of the conductivity and cross-section must be the same in<br>
-each, if each is of uniform diameter.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Conjugate. adj.</span><br>
-Conjugate coils or conductors are coils placed in such relation that the<br>
-lines of force established by one do not pass through the coils of the<br>
-other. Hence variations of current in one produce no induced currents in<br>
-the other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Connect. v.</span><br>
-To bring two ends of a conductor together, or to bring one end of a<br>
-conductor in connection with another, or in any way to bring about an<br>
-electrical connection.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Connector.</span><br>
-A sleeve with screws or other equivalent device for securing the ends of<br>
-wires in electrical contact. A binding-post, q. v., is an example.<br>
-Sometimes wire spring-catches are used, the general idea being a device<br>
-that enables wires to be connected or released at will without breaking<br>
-off or marring their ends. The latter troubles result from twisting<br>
-wires together.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Consequent Poles.</span><br>
-A bar magnet is often purposely or accidentally magnetized so as to have<br>
-both ends of the same polarity, and the center of opposite polarity. The<br>
-center is said to comprise two consequent poles. (See Magnet,<br>
-Anomalous.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Conservation of Electricity.</span><br>
-As every charge of electricity has its equal and opposite charge<br>
-somewhere, near or far, more or less distributed, the sum of negative is<br>
-equal always to the sum of positive electrical charges. For this<br>
-doctrine the above title was proposed by Lippman.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contact Breaker.</span><br>
-Any contrivance for closing a circuit, and generally for opening and<br>
-closing in quick succession. An old and primitive form consisted of a<br>
-very coarsely cut file. This was connected to one terminal, and the<br>
-other terminal was drawn over its face, making and breaking contact as<br>
-it jumped from tooth to tooth. (See Circuit Breaker--do. Automatic,<br>
-etc.--do. Wheel-do. Pendulum.)<br>
-<br>
-<br>
-147&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Contact, Electric.</span><br>
-A contact between two conductors, such that a current can flow through<br>
-it. It may be brought about by simple touch or impact between the ends<br>
-or terminals of a circuit, sometimes called a dotting contact, or by a<br>
-sliding or rubbing of one terminal on another, or by a wheel rolling on<br>
-a surface, the wheel and surface representing the two terminals.<br>
-<br>
-There are various descriptions of contact, whose names are<br>
-self-explanatory. The term is applied to telegraph line faults also, and<br>
-under this, includes different descriptions of contact with neighboring<br>
-lines, or with the earth.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contact Electricity.</span><br>
-When two dissimilar substances are touched they assume different<br>
-electric potentials. If conductors, their entire surfaces are affected;<br>
-if dielectrics, only the surfaces which touch each other. (See Contact<br>
-Theory.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contact Faults.</span><br>
-A class of faults often called contacts, due to contact of the conductor<br>
-of a circuit with another conductor. A full or metallic contact is where<br>
-practically perfect contact is established; a partial contact and<br>
-intermittent contact are self-explanatory.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Contact Point.</span><br>
-A point, pin or stud, often of platinum, arranged to come in contact<br>
-with a contact spring, q. v., or another contact point or surface, under<br>
-any determined conditions.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contact Potential Difference.</span><br>
-The potential difference established by the contact of two dissimilar<br>
-substances according to the contact theory, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contact Series.</span><br>
-An arrangement or tabulation of substances in pairs, each intermediate<br>
-substance appearing in two pairs, as the last member of the first, and<br>
-first member of the succeeding pair, with the statement of the potential<br>
-difference due to their contact, the positively electrified substance<br>
-coming first. The following table of some contact potentials is due to<br>
-Ayrton and Perry:<br>
-<small><span style="font-family: monospace;">CONTACT SERIES.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Difference of Potential in Volts.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Zinc--Lead&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.210</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Lead--Tin&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.069</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Tin--Iron&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.313</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Iron--Copper&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.146</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Copper--Platinum&nbsp; .238</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Platinum-Carbon&nbsp;&nbsp; .113</span></small>
-<br>
-<br>
-The sum of these differences is 1.089, which is the contact potential<br>
-between zinc and carbon.<br>
-<br>
-Volta's Law refers to this and states that--<br>
-&nbsp; The difference of potential produced by the contact of any two<br>
-&nbsp; substances is equal to the sum of the differences of potentials<br>
-&nbsp; between the intervening substances in the contact series.<br>
-<br>
-It is to be remarked that the law should no longer be restricted to or<br>
-stated only for metals.<br>
-<br>
-<br>
-148&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contact-spring.</span><br>
-A spring connected to one lead of an electric circuit, arranged to press<br>
-against another spring, or contact point, q. v., under any conditions<br>
-determined by the construction of the apparatus. (See Bell,<br>
-Electric--Coil, Induction.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contact Theory.</span><br>
-A theory devised to explain electrification, the charging of bodies by<br>
-friction, or rubbing, and the production of current by the voltaic<br>
-battery. It holds that two bodies, by mere contact become oppositely<br>
-electrified. If such contact is increased in extent by rubbing together,<br>
-the intensity of their electrification is increased. This<br>
-electrification is accounted for by the assumption of different kinetic<br>
-energy, or energy of molecular motion, possessed by the two bodies;<br>
-there being a loss and gain of energy, on the two sides respectively,<br>
-the opposite electrifications are the result. Then when separated, the<br>
-two bodies come apart oppositely electrified.<br>
-<br>
-The above accounts for the frictional production of electricity. In the<br>
-voltaic battery, a separation of the atoms of hydrogen and oxygen, and<br>
-their consolidation into molecules occurs, and to such separation and<br>
-the opposite electrification of the electrodes by the oxygen and<br>
-hydrogen, the current is attributed, because the hydrogen goes to one<br>
-electrode, and the oxygen to the other, each giving up or sharing its<br>
-own charge with the electrodes to which it goes. If zinc is touched to<br>
-copper, the zinc is positively and the copper negatively electrified. In<br>
-the separation of hydrogen and oxygen, the hydrogen is positively and<br>
-the oxygen negatively electrified. In the battery, the current is due to<br>
-the higher contact difference of oxygen and hydrogen compared to that<br>
-between zinc and copper. It will be seen that the two contact actions in<br>
-a battery work against each other, and that the current is due to a<br>
-differential contact action. The zinc in a battery is electrified<br>
-negatively because the negative electrification of the oxygen is greater<br>
-in amount than its own positive electrification due to contact with the<br>
-copper.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Contractures.</span><br>
-A muscular spasm or tetanus due to the passage of a current of<br>
-electricity; a term in electro-therapeutics.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Controlling Field.</span><br>
-The magnetic or electro-magnetic field, which is used in galvanometers<br>
-to control the magnetic needle, tending to restore it to a definite<br>
-position whenever it is turned therefrom. It may be the earth's field or<br>
-one artificially produced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Controlling Force.</span><br>
-In galvanometers and similar instruments, the force used to bring the<br>
-needle or indicator back to zero. (See Controlling<br>
-Field--Electro-Magnetic Control--Gravity Control--Magnetic<br>
-Control--Spring Control.)<br>
-<br>
-<br>
-149&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Convection, Electric.</span><br>
-The production of blasts or currents of air (convection streams) from<br>
-points connected to statically charged conductors. The term is sometimes<br>
-applied to electric convection of heat. (See Convection of Heat,<br>
-Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Convection, Electrolytic.</span><br>
-The resistance of acidulated water as a true conductor is known to be<br>
-very, almost immeasurably, high. As an electrolytic, its resistance is<br>
-very much lower. Hence the current produced between immersed electrodes<br>
-is theoretically almost null, unless the difference of potential between<br>
-them is high enough to decompose the liquid. Yet a feeble current too<br>
-great for a true conduction current is sometimes observed when two<br>
-electrodes with potential difference too low to cause decomposition are<br>
-immersed in it. Such a current is termed an electrolytic convection<br>
-current. It is supposed to be due to various causes. Some attribute it<br>
-to the presence of free oxygen from the air, dissolved in the water with<br>
-which the hydrogen combines. Others attribute it to the diffusion of the<br>
-gases of decomposition in the solution; others assume a partial<br>
-polarization of the molecules without decomposition. Other theories are<br>
-given, all of which are unsatisfactory. The term is due to Helmholtz.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Convection of Heat, Electric.</span><br>
-The effect of a current upon the distribution of heat in an unevenly<br>
-heated conductor. In some, such as copper, the current tends to equalize<br>
-the varying temperatures; the convection is then said to be positive, as<br>
-comparable to that of water flowing through an unequally heated tube. In<br>
-others, such as platinum or iron, it is negative, making the heated<br>
-parts hotter, and the cooler parts relatively cooler.<br>
-<br>
-The effect of the electric current in affecting the distribution of heat<br>
-in unequally heated metal (Thomson's effect. q. v.), is sometimes so<br>
-termed. If a current passes through unequally heated iron it tends to<br>
-increase the difference of temperature, and the convection is negative;<br>
-in copper it tends to equalize the temperature, and the convection is<br>
-positive.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Converter.</span><br>
-An induction coil used with the alternating current for changing<br>
-potential difference and inversely therewith the available current. They<br>
-generally lower the potential, and increase the current, and are placed<br>
-between the primary high potential system that connects the houses with<br>
-the central station, and the secondary low potential system within the<br>
-houses. A converter consists of a core of thin iron sheets, wound with a<br>
-fine primary coil of many convolutions, and a coarse secondary coil of<br>
-few convolutions. The ratio of convolutions gives the ratio of maximum<br>
-potential differences of their terminals between the primary and<br>
-secondary coils. The coil may be jacketed with iron to increase the<br>
-permeance. (See Alternating Current System.)<br>
-<br>
-<br>
-<img style="width: 664px; height: 710px;" alt=""
- src="images/150F110.jpg"><br>
-Fig. 110. FERRANTI'S CONVERTER OR TRANSFORMER.<br>
-<br>
-<br>
-<img style="width: 672px; height: 340px;" alt=""
- src="images/150F111.jpg"><br>
-Fig. 111.&nbsp;&nbsp; SWINBURNE'S HEDGEHOG TRANSFORMER.<br>
-<br>
-<br>
-150&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Co-ordinates, System of.</span><br>
-A system for indicating the position of points in space by reference to<br>
-fixed lines, intersecting at a determined and arbitrary point 0, termed<br>
-the origin of co-ordinates. In plane rectangular co-ordinates two lines<br>
-are drawn through the origin, one horizontal, termed the axis of<br>
-abscissas, or axis of X. All distances measured parallel to it, if<br>
-unknown, are indicated by x, and are termed abscissas. The other axis is<br>
-vertical, and is termed the axis of ordinates, or axis of Y. All<br>
-distances measured parallel to it, if unknown, are indicated by y and<br>
-are termed ordinates. Thus by naming its abscissa and ordinate a point<br>
-has its position with reference to the axes determined, and by<br>
-indicating the relation between a point, line or curve, and a system of<br>
-abscissas and ordinates, the properties of a line or curve can be<br>
-expressed algebraically. Co-ordinates may also be inclined to each other<br>
-at any other angles, forming oblique co-ordinates; relations may be<br>
-expressed partly in angles referred to the origin as a centre, giving<br>
-polar co-ordinates. For solid geometry or calculations in three<br>
-dimensions, a third axis, or axis of Z, is used, distances parallel to<br>
-which if unknown are indicated by z.<br>
-<br>
-<br>
-<img style="width: 532px; height: 401px;" alt=""
- src="images/151F112.jpg"><br>
-Fig. 112. AXES OF CO-ORDINATES.<br>
-<br>
-<br>
-151&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cooling Box.</span><br>
-In a hydroelectric machine, q. v., a conduit or chest through which the<br>
-steam passes on its way to the nozzles. Its object is to partially<br>
-condense the steam so as to charge it with water vesicles whose friction<br>
-against the sides of the nozzles produces the electrification .<br>
-<br>
-<br>
-152&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Copper.</span><br>
-A metal; one of the elements. Symbol, Cu; atomic weight, 63.5;<br>
-equivalent, 63.5 and 31.75; valency, 1 and 2; specific gravity, 8.96.<br>
-It is a conductor of electricity, whose conductivity is liable to<br>
-vary greatly on account of impurities.<br>
-<br>
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;
-&nbsp; &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;&nbsp;
-<span style="font-family: monospace;"><small>Annealed.&nbsp;&nbsp; Hard
-drawn.</small></span><small><br style="font-family: monospace;">
-<span style="font-family: monospace;">Relative resistance (Silver =
-1),&nbsp;&nbsp;&nbsp;&nbsp;
-1.063&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1.086</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Specific
-resistance,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.598&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1.634 microhms.</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a wire at 0&deg; C.
-(32&deg; F.),</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Annealed.&nbsp;&nbsp;&nbsp;&nbsp; Hard Drawn.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(a) 1 foot long, weighing 1
-grain,&nbsp;&nbsp;&nbsp;&nbsp; .2041&nbsp;
-ohms&nbsp;&nbsp; .2083&nbsp; ohms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(b) 1 foot long, 1/1000 inch
-thick,&nbsp;&nbsp; 9.612&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp; 9.831&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(c) 1 meter long, weighing 1
-gram,&nbsp;&nbsp;&nbsp;&nbsp; .1424&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .1453&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(d) 1 meter long, 1 millimeter
-thick,&nbsp; .02034
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .02081&nbsp; "</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-microhm.&nbsp;&nbsp; microhm.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of 1 inch cube at
-0&deg;C. (32&deg; F.)&nbsp;&nbsp;
-.6292&nbsp;&nbsp;&nbsp;&nbsp; .6433</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">Percentage of resistance change,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">per 1&deg; C. (1.8&deg; F.) at
-about 20&deg; C. (68&deg; F.) = 0.388
-per cent.</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">Electro-chemical Equivalent
-(Hydrogen = .0105)&nbsp;&nbsp;
-Cuprous&nbsp; .6667</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Cupric&nbsp;&nbsp; .3334</span></small>
-<br>
-<br>
-In electricity it has been very extensively used as the negative plate<br>
-of voltaic batteries. It has its most extensive application as<br>
-conductors for all classes of electrical leads.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Copper Bath.</span><br>
-A solution of copper used for depositing the metal in the electroplating<br>
-process. For some metals, such as zinc or iron, which decompose copper<br>
-sulphate solution, special baths have to be used.<br>
-<br>
-The regular bath for copper plating is the following:<br>
-<br>
-To water acidulated with 8 to 10 percent. of sulphuric acid as much<br>
-copper sulphate is added as it will take up at the ordinary temperature.<br>
-The saturated bath should have a density of 1.21. It is used cold and is<br>
-kept in condition by the use of copper anodes, or fresh crystals may be<br>
-added from time to time.<br>
-<br>
-For deposition on zinc, iron, tin and other metals more electropositive<br>
-than copper, the following baths may be used, expressed in parts by<br>
-weight:<br>
-<br style="font-family: monospace;">
-<small><span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Tin</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Iron and Steel.&nbsp;&nbsp; Cast Iron</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Cold&nbsp;&nbsp;&nbsp;&nbsp; Hot.&nbsp;&nbsp;&nbsp;&nbsp; and
-Zinc.&nbsp;&nbsp; Zinc.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Sodium
-Bisulphate,&nbsp;&nbsp;&nbsp; 500&nbsp;&nbsp;&nbsp;&nbsp;
-200&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-300&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 100</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Potassium
-Cyanide,&nbsp;&nbsp;&nbsp; 500&nbsp;&nbsp;&nbsp;&nbsp;
-700&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-500&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 700</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Sodium
-Carbonate,&nbsp;&nbsp;&nbsp; 1000&nbsp;&nbsp;&nbsp;&nbsp;
-500&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
----&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; ---</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Copper
-Acetate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-475&nbsp;&nbsp;&nbsp;&nbsp;
-500&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-350&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 450</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Aqua
-Ammoniae,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-350&nbsp;&nbsp;&nbsp;&nbsp;
-300&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-200&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 150</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2500&nbsp;&nbsp;&nbsp; 2500&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2500&nbsp;&nbsp;&nbsp;&nbsp; 2500</span></small>
-<br>
-<br>
-These are due to Roseleur.<br>
-<br>
-<br>
-153&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Copper Stripping Bath.</span><br>
-There is generally no object in stripping copper from objects. It can be<br>
-done with any of the regular copper baths using the objects to be<br>
-stripped as anode. The danger of dissolving the base itself and thereby<br>
-injuring the article and spoiling the bath is obvious.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cord Adjuster.</span><br>
-A device for shortening or lengthening the flexible cord, or flexible<br>
-wire supplying the current, and by which an incandescent lamp is<br>
-suspended. It often is merely a little block of wood perforated with two<br>
-holes through which the wires pass, and in which they are retained in<br>
-any desired position by friction and their own stiffness.<br>
-<br>
-<br>
-<img style="width: 604px; height: 334px;" alt=""
- src="images/153F113.jpg"><br>
-Fig. 113. FLEXIBLE CORD ADJUSTER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cord, Flexible.</span><br>
-A pair of flexible wire conductors, insulated lightly, twisted together<br>
-and forming apparently a cord. They are used for minor services, such as<br>
-single lamps and the like, and are designated according to the service<br>
-they perform, such as battery cords, dental cords (for supplying dental<br>
-apparatus) and other titles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Core.</span><br>
-(a) The conductor or conductors of an electric cable. (See Cable Core.)<br>
-<br>
-(b) The iron mass, generally central in an electro-magnet or armature,<br>
-around which the wire is coiled. It acts by its high permeance to<br>
-concentrate or multiply the lines of force, thus maintaining a more<br>
-intense field. (See Armature--Magnet, Electro--Magnet, Field--Core,<br>
-Laminated). In converters or transformers (See Converter) it often<br>
-surrounds the wire coils.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Core-discs.</span><br>
-Discs of thin wire, for building up armature cores. (See Laminated<br>
-Core.) The usual form of core is a cylinder. A number of thin discs of<br>
-iron are strung upon the central shaft and pressed firmly together by<br>
-end nuts or keys. This arrangement, it will be seen, gives a cylinder as<br>
-basis for winding the wire on.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Core-discs, Pierced.</span><br>
-Core-discs for an armature of dynamo or motor, which are pierced around<br>
-the periphery. Tubes of insulating material pass through the peripheral<br>
-holes, and through these the conductors or windings are carried. The<br>
-conductors are thus embedded in a mass of iron and are protected from<br>
-eddy currents, and they act to reduce the reluctance of the air gaps.<br>
-From a mechanical point of view they are very good. For voltages over<br>
-100 they are not advised.<br>
-<br>
-Synonym--Perforated Core-discs.<br>
-<br>
-<br>
-154&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Core-discs, Segmental.</span><br>
-Core-discs made in segments, which are bolted together to form a<br>
-complete disc or section of the core. The plan is adopted principally on<br>
-large cores. The discs thus made up are placed together to form the core<br>
-exactly as in the case of ordinary one piece discs.<br>
-<br>
-<br>
-<img style="width: 622px; height: 549px;" alt=""
- src="images/154F114.jpg"><br>
-Fig. 114. PIERCED OR PERFORATED CORE-DISC.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Core-discs, Toothed.</span><br>
-Core-discs of an armature of a dynamo or motor, which discs are cut into<br>
-notches on the periphery. These are put together to form the armature<br>
-core, with the notches corresponding so as to form a series of grooves<br>
-in which the wire winding is laid. This construction reduces the actual<br>
-air-gaps, and keeps the wires evenly spaced. Distance-pieces of<br>
-box-wood, m, m, are sometimes used to lead the wires at the ends of the<br>
-armature.<br>
-<br>
-<br>
-<img style="width: 540px; height: 534px;" alt=""
- src="images/154F115.jpg"><br>
-Fig. 115. TOOTHED CORE-DISC.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Core, Laminated.</span><br>
-A core of an armature, induction coil or converter or other similar<br>
-construction, which is made up of plates insulated more or less<br>
-perfectly from each other. The object of lamination is to prevent the<br>
-formation of Foucault currents. (See Currents, Foucault.) As insulation,<br>
-thin shellacked paper may be used, or sometimes the superficial<br>
-oxidation of the plates alone is relied on. The plates, in general, are<br>
-laid perpendicular to the principal convolutions of the wire, or<br>
-parallel to the lines of force. The object is to break up currents, and<br>
-such currents are induced by the variation in intensity of the field of<br>
-force, and their direction is perpendicular to the lines of force, or<br>
-parallel to the inducing conductors.<br>
-<br>
-A core built up of core discs is sometimes termed a tangentially<br>
-laminated core. Made up of ribbon or wire wound coil fashion, it is<br>
-termed a radially laminated core.<br>
-<br>
-<br>
-155&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Core Ratio.</span><br>
-In a telegraph cable the ratio existing between the diameter of the<br>
-conducting core and the insulator. To get a ratio approximately accurate<br>
-in practical calculations, the diameter of the core is taken at 5 per<br>
-cent. less than its actual diameter. The calculations are those<br>
-referring to the electric constants of the cable, such as its static<br>
-capacity and insulation resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Core, Ribbon.</span><br>
-For discoidal ring-shaped cores of armatures, iron ribbon is often used<br>
-to secure lamination and prevent Foucault currents.<br>
-<br>
-Synonym--Tangentially Laminated Core.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Core, Ring.</span><br>
-A core for a dynamo or motor armature, which core forms a complete ring.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Core, Stranded.</span><br>
-In an electric light cable, a conducting core made up of a group of<br>
-wires laid or twisted together.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Core, Tubular.</span><br>
-Tubes used as cores for electro-magnets. For very small magnetizing<br>
-power, tubular cores are nearly as efficient as solid ones in straight<br>
-magnets, because the principal reluctance is due to the air-path. On<br>
-increasing the magnetization the tubular core becomes less efficient<br>
-than the solid core, as the reluctance of the air-path becomes<br>
-proportionately of less importance in the circuit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Corpusants.</span><br>
-The sailors' name for St. Elmo's Fire, q. v.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coulomb.</span><br>
-The practical unit of quantity of electricity. It is the quantity passed<br>
-by a current of one ampere intensity in one second. It is equal to 1/10<br>
-the C. G. S. electro-magnetic unit of quantity, and to 3,000,000,000 C.<br>
-G. S. electrostatic units of quantity. It corresponds to the<br>
-decomposition of .0935 milligrams of water, or to the deposition of<br>
-1.11815 milligrams of silver.<br>
-<br>
-[Transcriber's note: A coulomb is approximately 6.241E18 electrons. Two<br>
-point charges of one coulomb each, one meter apart, exerts a force of<br>
-900,000 metric tons.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coulomb's Laws of Electrostatic
-Attraction and Repulsion.</span><br>
-1. The repulsions or attractions between two electrified bodies are in<br>
-the inverse ratio of the squares of their distance.<br>
-<br>
-2. The distance remaining the same, the force of attraction or repulsion<br>
-between two electrified bodies is directly as the product of the<br>
-quantities of electricity with which they are charged.<br>
-<br>
-<br>
-156&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Counter, Electric.</span><br>
-A device for registering electrically, or by electro-magnetic machinery,<br>
-the revolutions of shafts, or any other data or factors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Counter-electro-motive Force.</span><br>
-A potential difference in a circuit opposed to the main potential<br>
-difference, and hence, resisting the operation of the latter, and<br>
-diminishing the current which would be produced without it. It appears<br>
-in electric motors, which, to a certain extent, operate as dynamos and<br>
-reduce the effective electro-motive force that operates them. It<br>
-appears in the primary coils of induction coils, and when the secondary<br>
-circuit is open, is almost equal to the main electro-motive force, so<br>
-that hardly any current can go through them under such conditions. It<br>
-appears in galvanic batteries, when hydrogen accumulates on the copper<br>
-plate, and in other chemical reactions. A secondary battery is charged<br>
-by a current in the reverse direction to that which it would normally<br>
-produce. Its own potential difference then appears as a<br>
-counter-electro-motive force.<br>
-<br>
-Synonym--Back Electro-motive Force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Counter-electro-motive Force of
-Polarization.</span><br>
-To decompose a solution by electrolysis, enough electro-motive force is<br>
-required to overcome the energy of composition of the molecule<br>
-decomposed. A part of this takes the form of a counter-electromotive<br>
-force, one which, for a greater or less time would maintain a current in<br>
-the opposite direction if the original source of current were removed.<br>
-Thus in the decomposition of water, the electrodes become covered, one<br>
-with bubbles of oxygen, the others with bubbles of hydrogen; this<br>
-creates a counter E. M. F. of polarization. In a secondary battery, the<br>
-working current may be defined as due to this cause.<br>
-<br>
-Synonym--Back Electro-motive Force of Polarization.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Couple.</span><br>
-Two forces applied to different points of a straight line, when opposed<br>
-in direction or unequal in amount, tend to cause rotation about a point<br>
-intermediate between their points of application and lying on the<br>
-straight line. Such a pair constitute a couple.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Couple, Voltaic or Galvanic.</span><br>
-The combination of two electrodes, and a liquid or liquids, the<br>
-electrodes being immersed therein, and being acted on differentially by<br>
-the liquid or liquids. The combination constitutes a source of<br>
-electro-motive force and consequently of current. It is the galvanic or<br>
-voltaic cell or battery. (See Battery, Voltaic--Contact<br>
-Theory--Electro-motive Force--Electro-motive Series.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Coupling.</span><br>
-The joining of cells of a galvanic battery, of dynamos or of other<br>
-devices, so as to produce different effects as desired.<br>
-<br>
-<br>
-157&nbsp; STANDARD ELECTRICAL DICTIONARY<br>
-<br>
-<br>
-<span style="font-weight: bold;">Couple, Astatic.</span><br>
-An astatic couple is a term sometimes applied to astatic needles, q.v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">C. P.</span><br>
-(a) An abbreviation of or symbol for candle power, q. v.<br>
-<br>
-(b) An abbreviation of chemically pure. It is used to indicate a high<br>
-degree of purity of chemicals. Thus, in a standard Daniell battery, the<br>
-use of C. P. chemicals may be prescribed or advised.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Crater.</span><br>
-The depression that forms in the positive carbon of a voltaic arc. (See<br>
-Arc, Voltaic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Creeping.</span><br>
-A phenomenon of capillarity, often annoying in battery jars. The<br>
-solution, by capillarity, rises a little distance up the sides,<br>
-evaporates, and as it dries more creeps up through it, and to a point a<br>
-little above it. This action is repeated until a layer of the salts may<br>
-form over the top of the vessel. To avoid it, paraffine is often applied<br>
-to the edges of the cup, or a layer of oil, often linseed oil, is poured<br>
-on the battery solution,<br>
-<br>
-<br>
-<span style="font-weight: bold;">Crith.</span><br>
-The weight of a litre of hydrogen at 0&ordm; C. (32&ordm; F.), and 760
-mm. (30<br>
-inches) barometric pressure. It is .0896 grams. The molecular weight of<br>
-any gas divided by 2 and multiplied by the value of the crith, gives the<br>
-weight of a litre of the gas in question. Thus a litre of electrolytic<br>
-gas, a mixture of two molecules of hydrogen for one of oxygen, with a<br>
-mean molecular weight of 12, weighs (12/2) * .0896 or .5376 gram.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Critical Speed.</span><br>
-(a) The speed of rotation at which a series dynamo begins to excite its<br>
-own field.<br>
-<br>
-(b) In a compound wound dynamo, the speed at which the same potential is<br>
-generated with the full load being taken from the machine, as would be<br>
-generated on open circuit, in which case the shunt coil is the only<br>
-exciter. The speed at which the dynamo is self-regulating.<br>
-<br>
-(c) In a dynamo the rate of speed when a small change in the speed of<br>
-rotation produces a comparatively great change in the electro-motive<br>
-force. It corresponds to the same current (the critical current) in any<br>
-given series dynamo.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cross.</span><br>
-(a) A contact between two electric conductors; qualified to express<br>
-conditions as a weather cross, due to rain, a swinging cross when a wire<br>
-swings against another, etc.<br>
-<br>
-(b) vb. To make such contact.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cross-Connecting Board.</span><br>
-A special switch board used in telephone exchanges and central telegraph<br>
-offices. Its function is, by plugs and wires, to connect the line wires<br>
-with any desired section of the main switchboard. The terminals of the<br>
-lines as they enter the building are connected directly to the<br>
-cross-connecting board.<br>
-<br>
-<br>
-158&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cross Connection.</span><br>
-A method of disposing of the effects of induction from neighboring<br>
-circuits by alternately crossing the two wires of a metallic telephone<br>
-circuit, so that for equal intervals they lie to right and left, or one<br>
-above, and one below.<br>
-<br>
-[Transcriber's note: Also used to cancel the effect of variations in the<br>
-ambient magnetic field, such as solar activity.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Crossing Wires.</span><br>
-The cutting out of a defective section in a telegraph line, by carrying<br>
-two wires from each side of the defective section across to a<br>
-neighboring conductor, pressing it for the time into service and cutting<br>
-the other wire if necessary.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cross-magnetizing Effect.</span><br>
-A phase of armature interference. The current in an armature of a dynamo<br>
-or motor is such as to develop lines of force approximately at right<br>
-angles to those of the field. The net cross-magnetizing effect is such<br>
-component of these lines, as is at right angles to the lines produced by<br>
-the field alone.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cross-over Block.</span><br>
-A piece of porcelain or other material shaped to receive two wires which<br>
-are to cross each other, and hold them so that they cannot come in<br>
-contact. It is used in wiring buildings, and similar purposes. (See<br>
-Cleat, Crossing.)<br>
-<br>
-<span style="font-weight: bold;">Cross Talk.</span><br>
-On telephone circuits by induction or by contact with other wires sound<br>
-effects of talking are sometimes received from other circuits; such<br>
-effects are termed cross talk.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Crucible, Electric.</span><br>
-A crucible for melting difficultly fusible substances, or for reducing<br>
-ores, etc., by the electric arc produced within it. Sometimes the<br>
-heating is due more to current incandescence than to the action of an<br>
-arc.<br>
-<br>
-<br>
-<img style="width: 652px; height: 250px;" alt=""
- src="images/158F116.jpg"><br>
-Fig. 116. ELECTRIC FURNACE OR CRUCIBLE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Crystallization, Electric.</span><br>
-Many substances under proper conditions take a crystalline form. The<br>
-great condition is the passage from the fluid into the solid state. When<br>
-such is brought about by electricity in any way, the term electric<br>
-crystallization may be applied to the phenomenon. A solution of silver<br>
-nitrate for instance, decomposed by a current, may give crystals of<br>
-metallic silver.<br>
-<br>
-<br>
-159&nbsp;&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cup, Porous.</span><br>
-A cup used in two-fluid voltaic batteries to keep the solutions separate<br>
-to some extent. It forms a diaphragm through which diffusion inevitably<br>
-takes place, but which is considerably retarded, while electrolysis and<br>
-electrolytic convection take place freely through its walls. As<br>
-material, unglazed pottery is very generally used.<br>
-<br>
-In some batteries the cup is merely a receptacle for the solid<br>
-depolarizer. Thus, in the Leclanch&eacute; battery, the cup contains the<br>
-manganese dioxide and graphite in which the carbon electrode is<br>
-embedded, but does not separate two solutions, as the battery only uses<br>
-one. Nevertheless, the composition of the solution outside and inside<br>
-may vary, but such variation is incidental only, and not an essential of<br>
-the operation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current.</span><br>
-The adjustment, or effects of a continuous attempt at readjustment of<br>
-potential difference by a conductor, q. v., connecting two points of<br>
-different potential. A charged particle or body placed in a field of<br>
-force tends to move toward the oppositely charged end or portion of the<br>
-field. If a series of conducting particles or a conducting body are held<br>
-so as to be unable to move, then the charge of the field tends, as it<br>
-were, to move through it, and a current results. It is really a<br>
-redistribution of the field and as long as such redistribution continues<br>
-a current exists. A current is assumed to flow from a positive to a<br>
-negative terminal; as in the case of a battery, the current in the outer<br>
-circuit is assumed to flow from the carbon to the zinc plate, and in the<br>
-solution to continue from zinc to carbon. As a memoria technica the zinc<br>
-may be thought of as generating the current delivering it through the<br>
-solution to the carbon, whence it flows through the wire connecting<br>
-them. (See Ohm's Law--Maxwell's Theory of Light--Conductor-Intensity.)<br>
-<br>
-[Transcriber's note: Supposing electric current to be the motion of <br>
-positive charge causes no practical difficulty, but the current is <br>
-actually the (slight) motion of negative electrons.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, After.</span><br>
-A current produced by the animal tissue after it has been subjected to a<br>
-current in the opposite direction for some time. The tissue acts like a<br>
-secondary battery. The term is used in electro-therapeutics.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Alternating.</span><br>
-Usually defined and spoken of as a current flowing alternately in<br>
-opposite directions. It may be considered as a succession of currents,<br>
-each of short duration and of direction opposite to that of its<br>
-predecessor. It is graphically represented by such a curve as shown in<br>
-the cut. The horizontal line may denote a zero current, that is no<br>
-current at all, or may be taken to indicate zero electro-motive force.<br>
-The curve represents the current, or the corresponding electro-motive<br>
-forces. The further from the horizontal line the greater is either, and<br>
-if above the line the direction is opposite to that corresponding to the<br>
-positions below the line. Thus the current is alternately in opposite<br>
-directions, has periods of maximum intensity, first in one and then in<br>
-the opposite sense, and between these, passing from one direction to the<br>
-other, is of zero intensity. It is obvious that the current may rise<br>
-quickly in intensity and fall slowly, or the reverse, or may rise and<br>
-fall irregularly. All such phases may be shown by the curve, and a curve<br>
-drawn to correctly represent these variations is called the<br>
-characteristic curve of such current. It is immaterial whether the<br>
-ordinates of the curve be taken as representing current strength or<br>
-electromotive force. If interpreted as representing electro-motive<br>
-force, the usual interpretation and best, the ordinates above the line<br>
-are taken as positive and those below as negative.<br>
-<br>
-Synonyms--Reversed Current--Periodic Currents.<br>
-<br>
-<br>
-<img style="width: 684px; height: 284px;" alt=""
- src="images/160F117.JPG"><br>
-Fig. 117. CHARACTERISTIC CURVE OF ALTERNATING CURRENT.<br>
-<br>
-<br>
-160&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Atomic.</span><br>
-A unit of current strength used in Germany; the strength of a current<br>
-which will liberate in 24 hours (86,400 seconds) one gram of hydrogen<br>
-gas, in a water voltameter. The atomic current is equal to 1.111<br>
-amperes. In telegraphic work the milliatom is used as a unit, comparable<br>
-to the milliampere. The latter is now displacing it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Charge.</span><br>
-If the external coatings of a charged and uncharged jar are placed in<br>
-connection, and if the inner coatings are now connected, after<br>
-separating them they are both found to be charged in the same manner. In<br>
-this process a current has been produced between the outside coatings<br>
-and one between the inner ones, to which Dove has given the name Charge<br>
-Current, and which has all the properties of the ordinary discharge<br>
-current. (Ganot.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Circular.</span><br>
-A current passing through a circular conductor; a current whose path is<br>
-in the shape of a circle.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Commuted.</span><br>
-A current changed, as regards direction or directions, by a commutator,<br>
-q. v., or its equivalent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Constant.</span><br>
-An unvarying current. A constant current system is one maintaining such<br>
-a current. In electric series, incandescent lighting, a constant current<br>
-is employed, and the system is termed as above. In arc lighting systems,<br>
-the constant current series arrangement is almost universal.<br>
-<br>
-<br>
-161&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Continuous.</span><br>
-A current of one direction only; the reverse of an alternating current.<br>
-(See Current, Alternating.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Critical.</span><br>
-The current produced by a dynamo at its critical speed; at that speed<br>
-when a slight difference in speed produces a great difference in<br>
-electro-motive force. On the characteristic curve it corresponds to the<br>
-point where the curve bends sharply, and where the electro-motive force<br>
-is about two-thirds its maximum.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Daniell/U.S. ,
-Daniell/Siemens' Unit.</span><br>
-A unit of current strength used in Germany. It is the strength of a<br>
-current produced by one Daniell cell in a circuit of the resistance of<br>
-one Siemens' unit. The current deposits 1.38 grams of copper per hour.<br>
-It is equal to 1.16 amperes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Demarcation.</span><br>
-In electro-therapeutics, a current which can be taken from an injured<br>
-muscle, the injured portion acting electro-negatively toward the<br>
-uninjured portion.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current Density.</span><br>
-The current intensity per unit of cross-sectional area of the conductor.<br>
-The expression is more generally used for electrolytic conduction, where<br>
-the current-density is referred to the mean facing areas of the<br>
-electrodes, or else to the facing area of the cathode only.<br>
-<br>
-The quality of the deposited metal is intimately related to the current<br>
-density. (See Burning.)<br>
-<small><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Proper Current Density for Electroplating</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Amperes
-Per Square Foot of Cathode.--(Urquhart.)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Copper, Acid
-Bath.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5.0&nbsp; to 10.0</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Cyanide
-Bath,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.0&nbsp; "&nbsp;&nbsp; 5.0</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Silver, Double
-Cyanide,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.0&nbsp; "&nbsp;&nbsp; 5.0</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Gold, Chloride dissolved in
-Potassium Cyanide,&nbsp;&nbsp; 1.0&nbsp;
-"&nbsp;&nbsp; 2.0</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Nickel, Double
-Sulphate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-6.6&nbsp; "&nbsp;&nbsp; 8.0</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Brass,
-Cyanide,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.0&nbsp; "&nbsp;&nbsp; 3.0</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Diacritical.</span><br>
-A current, which, passing through a helix surrounding an iron core,<br>
-brings it to one-half its magnetic saturation, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Diaphragm.</span><br>
-If a liquid is forced through a diaphragm, a potential difference<br>
-between the liquid on opposite sides of the diaphragm is maintained.<br>
-Electrodes or terminals of platinum may be immersed in the liquid, and a<br>
-continuous current, termed a diaphragm current, may be taken as long as<br>
-the liquid is forced through the diaphragm. The potential difference is<br>
-proportional to the pressure, and also depends on the nature of the<br>
-diaphragm and on the liquid.<br>
-<br>
-<br>
-162&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Direct.</span><br>
-A current of unvarying direction, as distinguished from an alternating<br>
-current. It may be pulsatory or intermittent in character, but must be<br>
-of constant direction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Direct Induced.</span><br>
-On breaking a circuit, if it is susceptible of exercising<br>
-self-induction, q. v., an extra current, in the direction of the<br>
-original is induced, which is called "direct" because in the same<br>
-direction as the original. The same is produced by a current in one<br>
-circuit upon a parallel one altogether separated from it. (See<br>
-Induction, Electro-Magnetic-Current, Extra.)<br>
-<br>
-Synonym--Break Induced Current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Direction of.</span><br>
-The assumed direction of a current is from positively charged electrode<br>
-to negatively charged one; in a galvanic battery from the carbon or<br>
-copper plate through the outer circuit to the zinc plate and back<br>
-through the electrolyte to the carbon or copper plate. (See Current.)<br>
-<br>
-[Transcriber's note: Current is caused by the motion of negative<br>
-electrons, from the negative pole to the positive. The electron was<br>
-discovered five years after this publication.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Displacement.</span><br>
-The movement or current of electricity taking place in a dielectric<br>
-during displacement. It is theoretical only and can only be assumed to<br>
-be of infinitely short duration. (See Displacement, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Eddy Displacement.</span><br>
-The analogues of Foucault currents, hypothetically produced in the mass<br>
-of a dielectric by the separation of the electricity or by its<br>
-electrification. (See Displacement.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Extra.</span><br>
-When a circuit is suddenly opened or closed a current of very brief<br>
-duration, in the first case in the same direction, in the other case in<br>
-the opposite direction, is produced, which exceeds the ordinary current<br>
-in intensity. A high potential difference is produced for an instant<br>
-only. These are called extra currents. As they are produced by<br>
-electro-magnetic induction, anything which strengthens the field of<br>
-force increases the potential difference to which they are due. Thus the<br>
-wire may be wound in a coil around an iron core, in which case the extra<br>
-currents may be very strong. (See Induction, Self-Coil, Spark.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Faradic.</span><br>
-A term in medical electricity for the induced or secondary alternating<br>
-current, produced by comparatively high electro-motive force, such as<br>
-given by an induction coil or magneto-generator, as distinguished from<br>
-the regular battery current.<br>
-<br>
-<br>
-163&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Foucault.</span><br>
-A current produced in solid conductors, and which is converted into heat<br>
-(Ganot). These currents are produced by moving the conductors through a<br>
-field, or by altering the strength of a field in which they are<br>
-contained. They are the source of much loss of energy and other<br>
-derangement in dynamos and motors, and to avoid them the armature cores<br>
-are laminated, the plane of the laminations being parallel to the lines<br>
-of force. (See Core, Laminated.)<br>
-<br>
-The presence of Foucault currents, if of long duration, is shown by the<br>
-heating of the metal in which they are produced. In dynamo armatures<br>
-they are produced sometimes in the metal of the windings, especially if<br>
-the latter are of large diameter.<br>
-<br>
-Synonyms--Eddy Currents--Local Currents--Parasitical Currents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Franklinic.</span><br>
-In electro-therapeutics the current produced by a frictional electric<br>
-machine.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Induced.</span><br>
-The current produced in a conductor by varying the conditions of a field<br>
-of force in which it is placed; a current produced by induction.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current Induction.</span><br>
-Induction by one current on another or by a portion of a current on<br>
-another portion of itself. (See Induction.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current Intensity.</span><br>
-Current strength, dependent on or defined by the quantity of electricity<br>
-passed by such current in a given time. The practical unit of current<br>
-intensity is the ampere, equal to one coulomb of quantity per second of<br>
-time.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Inverse Induced.</span><br>
-The current induced in a conductor, when in a parallel conductor or in<br>
-one having a parallel component a current is started, or is increased in<br>
-strength. It is opposite in direction to the inducing current and hence<br>
-is termed inverse. (See Induction, Electro-magnetic.) The parallel<br>
-conductors may be in one circuit or in two separate circuits.<br>
-<br>
-Synonyms--Make-induced Current--Reverse-induced Current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Jacobi's Unit of.</span><br>
-A current which will liberate one cubic centimeter of mixed gases<br>
-(hydrogen and oxygen) in a water voltameter per minute, the gases being<br>
-measured at 0&ordm; C. (32&ordm; F.) and 760 mm. (29.92 inches)
-barometric<br>
-pressure. It is equal to .0961 ampere.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Joint.</span><br>
-The current given by several sources acting together. Properly, it<br>
-should be restricted to sources connected in series, thus if two battery<br>
-cells are connected in series the current they maintain is their joint<br>
-current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Linear.</span><br>
-A current passing through a straight conductor; a current whose path<br>
-follows a straight line.<br>
-<br>
-<br>
-164&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Make and Break.</span><br>
-A succession of currents of short duration, separated by absolute<br>
-cessation of current. Such current is produced by a telegraph key, or by<br>
-a microphone badly adjusted, so that the circuit is broken at intervals.<br>
-The U. S. Courts have virtually decided that the telephone operates by<br>
-the undulatory currents, and not by a make and break current. Many<br>
-attempts have been made to produce a telephone operating by a<br>
-demonstrable make and break current, on account of the above<br>
-distinction, in hopes of producing a telephone outside of the scope of<br>
-the Bell telephone patent.<br>
-<br>
-[Transcriber's note: Contemporary long distance telephone service is<br>
-digital, as this item describes.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current-meter.</span><br>
-An apparatus for indicating the strength of current. (See Ammeter.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Negative.</span><br>
-In the single needle telegraph system the current which deflects the<br>
-needle to the left.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Nerve and Muscle.</span><br>
-A current of electricity yielded by nerves or muscles. Under proper<br>
-conditions feeble currents can be taken from nerves, as the same can be<br>
-taken from muscles.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Opposed.</span><br>
-The current given by two or more sources connected in opposition to each<br>
-other. Thus a two volt and a one volt battery may be connected in<br>
-opposition, giving a net voltage of only one volt, and a current due to<br>
-such net voltage.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Partial.</span><br>
-A divided or branch current. A current which goes through a single<br>
-conductor to a point where one or more other conductors join it in<br>
-parallel, and then divides itself between the several conductors, which<br>
-must join further on, produces partial currents. It produces as many<br>
-partial currents as the conductors among which it divides. The point of<br>
-division is termed the point of derivation.<br>
-<br>
-Synonym--Derived Current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Polarizing.</span><br>
-In electro-therapeutics, a constant current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Positive.</span><br>
-In the single needle telegraph system the current which deflects the<br>
-needle to the right.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Pulsatory.</span><br>
-A current of constant direction, but whose strength is constantly<br>
-varying, so that it is a series of pulsations of current instead of a<br>
-steady flow.<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Rectified.</span><br>
-A typical alternating current is represented by a sine curve, whose<br>
-undulations extend above and below the zero line. If by a simple two<br>
-member commutator the currents are caused to go in one direction, in<br>
-place of the sine curve a series of short convex curves following one<br>
-another and all the same side of the zero line results. The currents all<br>
-in the same direction, become what is known as a pulsating current.<br>
-<br>
-Synonym--Redressed Current.<br>
-<br>
-<br>
-165&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Rectilinear.</span><br>
-A current flowing through a rectilinear conductor. The action of<br>
-currents depending on their distance from the points where they act,<br>
-their contour is a controlling factor. This contour is determined by the<br>
-conductors through which they flow.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current Reverser.</span><br>
-A switch or other contrivance for reversing the direction of a<br>
-current in a conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Amp&eacute;rian.</span><br>
-The currents of electricity assumed by Ampere's theory to circulate<br>
-around a magnet. As they represent the maintenance of a current or of<br>
-currents without the expenditure of energy they are often assumed to be<br>
-of molecular dimensions. As they all go in the same sense of rotation<br>
-and are parallel to each other the result is the same as if a single set<br>
-of currents circulated around the body of the magnet. More will be found<br>
-on this subject under Magnetism. The Amp&eacute;rian currents are purely<br>
-hypothetical and are predicated on the existence of a field of force<br>
-about a permanent magnet. (See Magnetism, Amp&eacute;re's Theory of.)<br>
-<br>
-If the observer faces the north pole of a magnet the Amp&eacute;rian
-currents<br>
-are assumed to go in the direction opposite to that of a watch, and the<br>
-reverse for the south pole.<br>
-<br>
-<br>
-<img style="width: 684px; height: 296px;" alt=""
- src="images/165F118_119.jpg"><br>
-Figs. 118-119 DIRECTION OF AMP&Eacute;RIAN CURRENTS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Angular.</span><br>
-Currents passing through conductors which form an angle with each other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Angular, Laws of.</span><br>
-1. Two rectilinear currents, the directions of which form an angle with<br>
-each other, attract one another when both approach to or recede from the<br>
-apex of the angle.<br>
-<br>
-2. They repel one another, if one approaches and the other recedes from<br>
-the apex of the angle.<br>
-<br>
-<br>
-166&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Earth.</span><br>
-In long telegraph lines having terminal grounds or connected to earth<br>
-only at their ends, potential differences are sometimes observed that<br>
-are sufficient to interfere with their working and which, of course, can<br>
-produce currents. These are termed earth-currents. It will be noted that<br>
-they exist in the wire, not in the earth. They may be of 40 milliamperes<br>
-strength, quite enough to work a telegraph line without any battery.<br>
-Lines running N. E. and S. W. are most affected; those running N.W. and<br>
-S. E. very much less so. These currents only exist in lines grounded at<br>
-both ends, and appear in underground wires. Hence they are not<br>
-attributable to atmospheric electricity. According to Wilde they are the<br>
-primary cause of magnetic storms, q. v., but not of the periodical<br>
-changes in the magnetic elements. (See Magnetic Elements.)<br>
-<br>
-Synonym--Natural Currents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Secondary.</span><br>
-(a) A current induced in one conductor by a variation in the current in<br>
-a neighboring one; the current produced in the secondary circuit of an<br>
-induction coil or alternating current converter.<br>
-<br>
-(b) The current given by a secondary battery. This terminology is not to<br>
-be recommended.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Secretion.</span><br>
-In electro-therapeutics, a current due to stimulation of the secretory<br>
-nerves.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current Sheet.</span><br>
-(a) If two terminals of an active circuit are connected to two points of<br>
-a thin metallic plate the current spreads over or occupies practically a<br>
-considerable area of such plate, and this portion of the current is a<br>
-current sheet.<br>
-<br>
-The general contour of the current sheet can be laid out in lines of<br>
-flux. Such lines resemble lines of force. Like the latter, they are<br>
-purely an assumption, as the current is not in any sense composed&nbsp;
-of<br>
-lines.<br>
-<br>
-(b) A condition of current theoretically brought about by the
-Amp&eacute;rian<br>
-currents in a magnet. Each molecule having its own current, the<br>
-contiguous portions of the molecules counteract each other and give a<br>
-resultant zero current. All that remains is the outer sheet of electric<br>
-current that surrounds the whole.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Sinuous.</span><br>
-A current passing through a sinuous conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Multiphase.</span><br>
-A term applied to groups of currents of alternating type which<br>
-constantly differ from each other by a constant proportion of periods of<br>
-alternation. They are produced on a single dynamo, the winding being so<br>
-contrived that two, three or more currents differing a constant amount<br>
-in phase are collected from corresponding contact rings. There are<br>
-virtually as many windings on the armature as there are currents to be<br>
-produced. Separate conductors for the currents must be used throughout.<br>
-<br>
-Synonyms--Polyphase Currents--Rotatory Currents.<br>
-<br>
-<br>
-167&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents of Motion.</span><br>
-In electro-therapeutics, the currents produced in living muscle or<br>
-nerves after sudden contraction or relaxation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents of Rest.</span><br>
-In electro-therapeutics, the currents traversing muscular or nervous<br>
-tissue when at rest. Their existence is disputed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Orders of.</span><br>
-An intermittent current passing through a conductor will induce<br>
-secondary alternating currents in a closed circuit near it. This<br>
-secondary current will induce a tertiary current in a third closed<br>
-circuit near it, and so on. The induced currents are termed as of the<br>
-first, second, third and other orders. The experiment is carried out by<br>
-Henry's coils. (See Coils, Henry's.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Currents, Thermo-electric.</span><br>
-These currents, as produced from existing thermo-electric batteries,<br>
-are generated by low potential, and are of great constancy. The opposite<br>
-junctions of the plates can be kept at constant temperatures, as by<br>
-melting ice and condensing steam, so that an identical current can be<br>
-reproduced at will from a thermopile.<br>
-<br>
-Thermo-electric currents were used by Ohm in establishing his law. (See<br>
-Ohm's Law.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Swelling.</span><br>
-In electro-therapeutics, a current gradually increasing in strength.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Undulatory.</span><br>
-A current varying in strength without any abrupt transition from action<br>
-to inaction, as in the make and break current. The current may be<br>
-continually changing in direction (see Current, Alternating), and hence,<br>
-of necessity, may pass through stages of zero intensity, but such<br>
-transition must be by a graduation, not by an abrupt transition. Such<br>
-current may be represented by a curve, such as the curve of sines. It is<br>
-evident that the current may pass through the zero point as it crosses<br>
-the line or changes direction without being a make and break current.<br>
-When such a current does alternate in direction it is sometimes called a<br>
-"shuttle current." The ordinary commercial telephone current and the<br>
-alternating current is of this type. (See Current, Make and Break.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Current, Unit.</span><br>
-Unit current is one which in a wire of unit length, bent so as to form<br>
-an arc of a circle of unit length of radius, would act upon a unit pole<br>
-(see Magnetic Pole, Unit,) at the center of the circle with unit force.<br>
-Unit length is the centimeter; unit force is the dyne.<br>
-<br>
-[Transcriber's note: The SI definition of an ampere: A current in two<br>
-straight parallel conductors of infinite length and negligible<br>
-cross-section, 1 metre apart in vacuum, would produce a force equal to<br>
-2E-7 newton per metre of length.]<br>
-<br>
-<br>
-168&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Current, Wattless.</span><br>
-Whenever there is a great difference in phase in an alternating current<br>
-dynamo between volts and current, the true watts are much less than the<br>
-product of the virtual volts and amperes, because the the watts are<br>
-obtained by multiplying the product of the virtual volts and amperes by<br>
-the cosine of the angle of lag (or lead). Any alternating current may be<br>
-resolved into two components in quadrature with each other, one in phase<br>
-with the volts, the other in quadrature therewith, the former is termed<br>
-by S. P. Thompson the Working Current, the latter the Wattless Current.<br>
-The greater the angle of lag the greater will be the wattless current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Arrival.</span><br>
-A curve representing the rate of rise of intensity of current at the end<br>
-of a long conductor when the circuit has been closed at the other end.<br>
-In the Atlantic cable, for instance, it would require about 108 seconds<br>
-for the current at the distant end to attain 9/10 of its full value. The<br>
-curve is drawn with its abscissa representing time and its ordinates<br>
-current strength.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Characteristic.</span><br>
-A curve indicating, graphically, the relations between any two factors,<br>
-which are interdependent, or which vary simultaneously. Thus in a<br>
-dynamo, the voltage increases with the speed of rotation, and a<br>
-characteristic curve may be based on the relations between the speed of<br>
-rotation and voltage developed. The current produced by a dynamo varies<br>
-with the electro-motive force, and a curve can express the relations<br>
-between the electro-motive force and the current produced.<br>
-<br>
-A characteristic curve is usually laid out by rectangular co-ordinates<br>
-(see Co-ordinates). Two lines are drawn at right angles to each other,<br>
-one vertical, and the other horizontal. One set of data are marked off<br>
-on the horizontal line, say one ampere, two amperes, and so on, in the<br>
-case of a dynamo's characteristic curve.<br>
-<br>
-For each amperage of current there is a corresponding voltage in the<br>
-circuit. Therefore on each ampere mark a vertical is erected, and on<br>
-that the voltage corresponding to such amperage is laid off. This gives<br>
-a series of points, and these points may be connected by a curve. Such<br>
-curve will be a characteristic curve.<br>
-<br>
-The more usual way of laying out a curve is to work directly upon the<br>
-two axes. On one is laid off the series of values of one set of data; on<br>
-the other the corresponding series of values of the other dependent<br>
-data. Vertical lines or ordinates, q. v., are erected on the horizontal<br>
-line or axis of abscissas at the points laid off; horizontal lines or<br>
-abscissas, q. v., are drawn from the points laid off on the vertical<br>
-line or axis of ordinates. The characteristic curve is determined by the<br>
-intersections of each corresponding pair of abscissa and ordinate.<br>
-<br>
-<br>
-169&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Variations exist in characteristic curve methods. Thus to get the<br>
-characteristic of a commutator, radial lines may be drawn from a circle<br>
-representing its perimeter. Such lines may be of length proportional to<br>
-the voltage developed on the commutator at the points whence the lines<br>
-start. A cut giving an example of such a curve is given in Fig. 125.<br>
-(See Curve of Distribution of Potential in Armature.)<br>
-<br>
-There is nothing absolute in the use of ordinates or abscissas. They may<br>
-be interchanged. Ordinarily voltages are laid off as ordinates, but the<br>
-practise may be reversed. The same liberty holds good for all<br>
-characteristic curves. Custom, however, should be followed.<br>
-<br>
-Synonym--Characteristic.<br>
-<br>
-<br>
-<img style="width: 593px; height: 381px;" alt=""
- src="images/169F120.jpg"><br>
-Fig. 120. CHARACTERISTIC CURVE OF A DYNAMO <br>
-WITH HORSE POWER CURVES.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Curve, Characteristic, of Converter.</span><br>
-The characteristic curve of the secondary circuit of an alternating<br>
-current converter. It gives by the usual methods (see Curve,<br>
-Characteristic,) the relations between the electro-motive force and the<br>
-current in the secondary circuit at a fixed resistance. If connected in<br>
-parallel a constant electro-motive force is maintained, and the curve is<br>
-virtually a straight line. If connected in series an elliptical curve is<br>
-produced.<br>
-<br>
-<br>
-170&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Charging.</span><br>
-In secondary battery manipulation, a curve indicating the increase of<br>
-voltage as the charging is prolonged. The rise in voltage with the<br>
-duration of the charging current is not uniform. In one case, shown in<br>
-the cut, there was a brief rapid rise of about 0.1 volt; then a long<br>
-slow rise for 0.15 volt; then a more rapid rise for nearly 0.40 volt,<br>
-and then the curve became a horizontal line indicating a cessation of<br>
-increase of voltage. The charging rate should be constant.<br>
-<br>
-The horizontal line is laid off in hours, the vertical in volts, so that<br>
-the time is represented by abscissas and the voltage by ordinates of the<br>
-curve.<br>
-<br>
-<br>
-<img style="width: 643px; height: 388px;" alt=""
- src="images/170F121.jpg"><br>
-Fig. 121. CHARGING CURVE OF A SECONDARY BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Discharging.</span><br>
-A characteristic curve of a storage battery, indicating the fall in<br>
-voltage with hours of discharge. The volts may be laid off on the axis<br>
-of ordinates, and the hours of discharging on the axis of abscissas. To<br>
-give it meaning the rate of discharge must be constant.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Electro-motive Force.</span><br>
-A characteristic curve of a dynamo. It expresses the relation between<br>
-its entire electromotive force, as calculated by Ohm's Law, and the<br>
-current intensities corresponding thereto. To obtain the data the dynamo<br>
-is driven with different resistances in the external circuit and the<br>
-current is measured for each resistance. This gives the amperes. The<br>
-total resistance of the circuit, including that of the dynamo, is known.<br>
-By Ohm's Law the electro-motive force in volts is obtained for each case<br>
-by multiplying the total resistance of the circuit in ohms by the<br>
-amperes of current forced through such resistance. Taking the voltages<br>
-thus calculated for ordinates and the corresponding amperages for<br>
-abscissas the curve is plotted. An example is shown in the cut.<br>
-<br>
-<br>
-171&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, External Characteristic.</span><br>
-A characteristic curve of a dynamo, corresponding to the electro-motive<br>
-force curve, except that the ordinates represent the voltages of the<br>
-external circuit, the voltages as taken directly from the terminals of<br>
-the machine, instead of the total electro-motive force of the circuit.<br>
-The dynamo is run at constant speed. The resistance of the external<br>
-circuit is varied. The voltages at the terminals of the machine and the<br>
-amperages of current corresponding thereto are determined. Using the<br>
-voltages thus determined as ordinates and the corresponding amperages as<br>
-abscissas the external characteristic curve is plotted.<br>
-<br>
-This curve can be mechanically produced. A pencil may be moved against a<br>
-constant force by two electro-magnets pulling at right angles to each<br>
-other. One must be excited by the main current of the machine, the other<br>
-by a shunt current from the terminals of the machine. The point of the<br>
-pencil will describe the curve.<br>
-<br>
-<br>
-<img style="width: 644px; height: 649px;" alt=""
- src="images/171F122.jpg"><br>
-Fig. 122. CHARACTERISTIC CURVE OF A DYNAMO.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Curve, Horse Power.</span><br>
-Curves indicating electric horse power. They are laid out with<br>
-co-ordinates, volts being laid off on the axis of ordinates, and amperes<br>
-on the axis of abscissas generally. The curves are drawn through points<br>
-where the product of amperes by volts equals 746. On the same diagram 1,<br>
-2, 3 .... and any other horse powers can be plotted if within the<br>
-limits. See Fig. 120.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Isochasmen.</span><br>
-A line drawn on the map of the earth's surface indicating the locus of<br>
-equal frequency of auroras.<br>
-<br>
-<br>
-172&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Life.</span><br>
-A characteristic curve showing the relations between the durability and<br>
-conditions affecting the same in any appliance. It is used most for<br>
-incandescent lamps. The hours of burning before failure give ordinates,<br>
-and the rates of burning, expressed indirectly in volts or in<br>
-candle-power, give abscissas. For each voltage or for each candle-power<br>
-an average duration is deducible from experience, so that two dependent<br>
-sets of data are obtained for the construction of the curve.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Load.</span><br>
-A characteristic curve of a dynamo, expressing the relation between its<br>
-voltage and the amount of excitation under a definite condition of<br>
-ampere load, at a constant speed. The ordinates represent voltage, the<br>
-abscissas ampere turns in the field, and the curves may be constructed<br>
-for a flow of 0, 50, 100, or .. , or any other number of amperes.<br>
-<br>
-<br>
-<img style="width: 643px; height: 433px;" alt=""
- src="images/172F123.jpg"><br>
-Fig. 123. LOAD CURVES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve, Magnetization.</span><br>
-A characteristic curve of an electromagnet, indicating the relation of<br>
-magnetization to exciting current. Laying off on the axis of ordinates<br>
-the quantities of magnetism evoked, and the corresponding strengths of<br>
-the exciting current on the axis of abscissas, the curve can be plotted.<br>
-It first rises rapidly, indicating a rapid increase of magnetization,<br>
-but grows nearly horizontal as the iron becomes more saturated. The<br>
-effect due to the coils alone, or the effect produced in the absence of<br>
-iron is a straight line, because air does not change in permeability.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve of Distribution of Potential in
-Armature.</span><br>
-A characteristic curve indicating the distribution of potential<br>
-difference between adjoining sections of the commutator of an armature<br>
-in different positions all around it. The potential differences are<br>
-taken by a volt-meter or potential galvanometer, connection with the<br>
-armature being made by two small metal brushes, held at a distance apart<br>
-equal to the distance from centre to centre of two adjoining commutator<br>
-bars. The curve is laid out as if by polar co-ordinates extending around<br>
-the cross-section of the commutator, with the distances from the<br>
-commutator surface to the curve proportional to the potential<br>
-differences as determined by shifting the pair of brushes all around the<br>
-commutator.<br>
-<br>
-The above is S. P. Thompson's method. Another method of W. M. Mordey<br>
-involves the use of a pilot brush. (See Brush, Pilot.) Otherwise the<br>
-method is in general terms identical with the above.<br>
-<br>
-<br>
-173&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 587px; height: 514px;" alt=""
- src="images/173F124.jpg"><br>
-Fig. 124. MAGNETIZATION CURVE.<br>
-<br>
-<br>
-<img style="width: 726px; height: 272px;" alt=""
- src="images/173F125_126.jpg"><br>
-Fig. 125. ARMATURE: CURVE.<br>
-<br>
-Fig. 126. DEVELOPMENT OF ARMATURE CURVE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve of Dynamo.</span><br>
-The characteristic curve of a dynamo. (See Curve, Characteristic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve of Sines.</span><br>
-An undulating curve representing wave motion. It is produced by<br>
-compounding a simple harmonic motion, or a two and fro motion like that<br>
-of an infinitely long pendulum with a rectilinear motion. Along a<br>
-horizontal line points may be laid off to represent equal periods of<br>
-time. Then on each point a perpendicular must be erected. The length of<br>
-each must be equal to the length of path traversed by the point up to<br>
-the expiration of each one of the given intervals of time. The abscissas<br>
-are proportional to the times and the ordinates to the sines of angles<br>
-proportional to the times. Thus if a circle be drawn upon the line and<br>
-divided into thirty-two parts of equal angular value, the sines of these<br>
-angles may be taken as the ordinates and the absolute distance or length<br>
-of arc of the angle will give the abscissas.<br>
-<br>
-Synonyms--Sine Curve--Sinusoidal Curve--Harmonic Curve.<br>
-<br>
-<br>
-<img style="width: 636px; height: 263px;" alt=""
- src="images/174F127.jpg"><br>
-Fig. 127. CURVE OF SINES.<br>
-<br>
-<br>
-174&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Curve of Saturation of the Magnetic
-Circuit.</span><br>
-A characteristic curve whose ordinates may represent the number of<br>
-magnetic lines of force induced in a magnetic circuit, and whose<br>
-abscissas may represent the ampere turns of excitation or other<br>
-representative of the inducing force.<br>
-<br>
-<span style="font-weight: bold;">Curve of Torque.</span><br>
-A characteristic curve showing the relations between torque, q. v., and<br>
-current in a dynamo or motor.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Curve, Permeability Temperature.</span><br>
-A characteristic curve expressing the changes in permeability of a<br>
-paramagnetic substance as the temperature changes. The degrees of<br>
-temperature may be abscissas, and the permeabilities corresponding<br>
-thereto ordinates of the curve.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cut In. v.</span><br>
-To connect any electric appliance, mechanism or conductor, into a<br>
-circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cut Out. v.</span><br>
-The reverse of to cut in; to remove from a circuit any conducting<br>
-device, and sometimes so arranged as to leave the circuit completed in<br>
-some other way.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cut Out.</span><br>
-An appliance for removing any apparatus from an electric circuit, so<br>
-that no more current shall pass through such apparatus, and sometimes<br>
-providing means for closing the circuit so as to leave it complete after<br>
-the removal of the apparatus.<br>
-<br>
-<br>
-175&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cut Out, Automatic.</span><br>
-(a) A mechanism for automatically shunting an arc or other lamp when it<br>
-ceases to work properly. It is generally worked by an electro-magnet of<br>
-high resistance placed in parallel with the arc. If the arc grows too<br>
-long the magnet attracts its armature, thereby completing a shunt of<br>
-approximately the resistance of the arc, and which replaces it until the<br>
-carbons approach again to within a proper distance. Sometimes a strip or<br>
-wire of fusible metal is arranged in shunt with the arc. When the arc<br>
-lengthens the current through the wire increases, melts it and a spring<br>
-is released which acts to complete or close a shunt circuit of<br>
-approximately arc-resistance.<br>
-<br>
-(b) See Safety Device--Safety Fuse.<br>
-<br>
-(c) See below.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cut-out, Magnetic.</span><br>
-A magnetic cut-out is essentially a coil of wire with attracted core or<br>
-armature. When the coil is not excited the core, by pressing down a<br>
-strip of metal or by some analogous arrangement, completes the circuit.<br>
-When the current exceeds a certain strength the core rises as it is<br>
-attracted and the circuit is opened.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cut-out, Safety.</span><br>
-A block of porcelain or other base carrying a safety fuse, which melts<br>
-and breaks the circuit before the wire connected to it is dangerously<br>
-heated.<br>
-<br>
-Synonyms--Fuse Block--Safety Catch--Safety Fuse.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cut Out, Wedge.</span><br>
-A cut out operated by a wedge. The line terminals consist of a spring<br>
-bearing against a plate, the circuit being completed through their point<br>
-of contact. A plug or wedge composed of two metallic faces insulated<br>
-from each other is adapted to wedge the contact open. Terminals of a<br>
-loop circuit are connected to the faces of the wedge. Thus on sliding it<br>
-into place, the loop circuit is brought into series in the main circuit.<br>
-<br>
-Synonym--Plug Cut Out--Spring Jack.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Cutting of Lines of Force.</span><br>
-A field of force is pictured as made up of lines of force; a conductor<br>
-swept through the field is pictured as cutting these lines. By so doing<br>
-it produces potential difference or electro-motive force in itself with<br>
-a current, if the conductor is part of a closed circuit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cycle of Alternation.</span><br>
-A full period of alternation of an alternating current. It begins<br>
-properly at the zero line, goes to a maximum value in one sense and<br>
-returns to zero, goes to maximum in the other sense and returns to zero.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Cystoscopy.</span><br>
-Examination of the human bladder by the introduction of a special<br>
-incandescent electric lamp. The method is due to Hitze.<br>
-</big></big><big><big><br>
-</big></big><big><big><br>
-176&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Damper.</span><br>
-(a) A copper frame on which the wire in a galvanometer is sometimes<br>
-coiled, which acts to damp the oscillations of the needle.<br>
-<br>
-(b) A tube of brass or copper placed between the primary and secondary<br>
-coils of an induction coil. It cuts off induction and diminishes the<br>
-current and potential of the secondary circuit. On pulling it out, the<br>
-latter increases. It is used on medical coils to adjust their strength<br>
-of action.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Damping.</span><br>
-Preventing the indicator of an instrument from oscillating in virtue of<br>
-its own inertia or elasticity. In a galvanometer it is defined as<br>
-resistance to quick vibrations of the needle, in consequence of which it<br>
-is rapidly brought to rest when deflected (Ayrton). In dead-beat<br>
-galvanometers (see Galvanometer, Dead-Beat,) damping is desirable in<br>
-order to bring the needle to rest quickly; in ballistic galvanometers<br>
-(see Galvanometer, Ballistic,) damping is avoided in order to maintain<br>
-the principle of the instrument. Damping may be mechanical, the<br>
-frictional resistance of air to an air-vane, or of a liquid to an<br>
-immersed diaphragm or loosely fitting piston, being employed. A<br>
-dash-pot, q. v., is an example of the latter. It may be<br>
-electro-magnetic. A mass of metal near a swinging magnetic needle tends<br>
-by induced currents to arrest the oscillations thereof, and is used for<br>
-this purpose in dead-beat galvanometers. This is termed, sometimes,<br>
-magnetic friction. The essence of damping is to develop resistance to<br>
-movement in some ratio proportional to velocity, so that no resistance<br>
-is offered to the indicator slowly taking its true position. (See<br>
-Galvanometer, Dead-Beat.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dash-Pot.</span><br>
-A cylinder and piston, the latter loosely fitting or perforated, or some<br>
-equivalent means being provided to permit movement. The cylinder may<br>
-contain a liquid such as glycerine, or air only. Thus the piston is<br>
-perfectly free to move, but any oscillations are damped (see Damping).<br>
-In some arc lamps the carbon holder is connected to a dash-pot to check<br>
-too sudden movements of the carbon. The attachment may be either to the<br>
-piston or to the cylinder. In the Brush lamp the top of the carbon<br>
-holder forms a cylinder containing glycerine, and in it a loosely<br>
-fitting piston works. This acts as a dash-pot.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dead Beat. adj.</span><br>
-Reaching its reading quickly; applied to instruments having a moving<br>
-indicator, which normally would oscillate back and forth a number of<br>
-times before reaching its reading were it not prevented by damping. (See<br>
-Galvanometer, Aperiodic--Damping.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dead Earth.</span><br>
-A fault in a telegraph line which consists in the wire being thoroughly<br>
-grounded or connected to the earth.<br>
-<br>
-<br>
-177&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dead Point of an Alternator.</span><br>
-A two-phase alternator of the ordinary type connected as a motor to<br>
-another alternator cannot start itself, as it has dead points where the<br>
-relations and polarity of field and armature are such that there is no<br>
-torque or turning power.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dead-Turns.</span><br>
-In the winding of an armature, a given percentage of the turns, it may<br>
-be 80 per cent., more or less, is assumed to be active; the other 20 per<br>
-cent. or thereabouts, is called dead-turns. This portion represents the<br>
-wire on such portions of the armature as comes virtually outside of the<br>
-magnetic field. They are termed dead, as not concurring to the<br>
-production of electro-motive force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dead Wire.</span><br>
-(a) The percentage or portion of wire on a dynamo or motor armature that<br>
-does not concur in the production of electromotive force. The<br>
-dead-turns, q. v., of a drum armature or the inside wire in a Gramme<br>
-ring armature are dead wire.<br>
-<br>
-(b) A disused and abandoned electric conductor, such as a telegraph<br>
-wire.<br>
-<br>
-(c) A wire in use, but through which, at the time of speaking, no<br>
-current is passing.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Death, Electrical.</span><br>
-Death resulting from electricity discharged through the animal system.<br>
-The exact conditions requisite for fatal results have not been<br>
-determined. High electro-motive force is absolutely essential; a<br>
-changing current, pulsatory or alternating, is most fatal, possibly<br>
-because of the high electro-motive force of a portion of each period.<br>
-Amperage probably has something to do with it, although the total<br>
-quantity in coulombs may be very small. As applied to the execution of<br>
-criminals, the victim is seated in a chair and strapped thereto. One<br>
-electrode with wet padded surface is placed against his head or some<br>
-adjacent part. Another electrode is placed against some of the lower<br>
-parts, and a current from an alternating dynamo passed for 15 seconds or<br>
-more. The potential difference of the electrodes is given at 1,500 to<br>
-2,000 volts, but of course the maximum may be two or three times the<br>
-measured amount, owing to the character of the current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Decalescence.</span><br>
-The converse of recalescence, q. v. When a mass of steel is being heated<br>
-as it reaches the temperature of recalescence it suddenly absorbs a<br>
-large amount of heat, apparently growing cooler.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deci.</span><br>
-Prefix originally used in the metric system to signify one-tenth of, now<br>
-extended to general scientific units. Thus decimeter means one-tenth of<br>
-a meter; decigram, one-tenth of a gram.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Declination, Angle of.</span><br>
-The angle intercepted between the true meridian and the axis of a<br>
-magnetic needle at any place. The angle is measured to east or west,<br>
-starting from the true meridian as zero.<br>
-<br>
-<br>
-178&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Declination of the Magnetic Needle.</span><br>
-The deviation of the magnetic needle from the plane of the earth's<br>
-meridian. It is also called the variation of the compass. (See Magnetic<br>
-Elements.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Decomposition.</span><br>
-The reduction of a compound substance into its constituents, as in<br>
-chemical analysis. The constituents may themselves be compounds or<br>
-proximate constituents, or may be elemental or ultimate constituents.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Decomposition, Electrolytic.</span><br>
-The decomposition or separation of a compound liquid into its<br>
-constituents by electrolysis. The liquid must be an electrolyte, q. v.,<br>
-and the decomposition proceeds subject to the laws of electrolysis, q.<br>
-v. See also Electrolytic Analysis.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Decrement.</span><br>
-When a suspension needle which has been disturbed is oscillating the<br>
-swings gradually decrease in amplitude if there is any damping, as there<br>
-always is. The decrement is the ratio of the amplitude of one<br>
-oscillation to the succeeding one. This ratio is the same for any<br>
-successive swings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">De-energize.</span><br>
-To cut off its supply of electric energy from an electric motor, or any<br>
-device absorbing and worked by electric energy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deflagration.</span><br>
-The explosive or violent volatilizing and dissipating of a substance by<br>
-heat, violent oxidation and similar means. It may be applied among other<br>
-things to the destroying of a conductor by an intense current, or the<br>
-volatilization of any material by the electric arc.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deflecting Field.</span><br>
-The field produced in a galvanometer by the current which is being<br>
-tested, and which field deflects the needle, such deflection being the<br>
-measure of the current strength.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deflection.</span><br>
-In magnetism the movement out of the plane of the magnetic meridian of a<br>
-magnetic needle, due to disturbance by or attraction towards a mass of<br>
-iron or another magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deflection Method.</span><br>
-The method of electrical measurements in which the deflection of the<br>
-index of the measuring instrument is used as the measure of the current<br>
-or other element under examination. It is the opposite of and is to be<br>
-distinguished from the zero or null method, q. v. In the latter<br>
-conditions are established which make the index point to zero and from<br>
-the conditions necessary for this the measurement is deduced. The<br>
-Wheatstone Bridge, q. v., illustrates a zero method, the sine or the<br>
-tangent compass, illustrates a deflection method. The use of deflection<br>
-methods involves calibration, q. v., and the commercial measuring<br>
-instruments, such as ammeters and volt meters, which are frequently<br>
-calibrated galvanometers, are also examples of deflection instruments.<br>
-<br>
-<br>
-179&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Degeneration, Reaction of.</span><br>
-The diminished sensibility to electro-therapeutic treatment exhibited by<br>
-the human system with continuance of the treatment in question. The<br>
-general lines of variation are stated in works on the subject.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deka.</span><br>
-Prefix originally used in the metric system to signify multiplying by<br>
-ten, as dekameter, ten meters, dekagram, ten grams; now extended to many<br>
-scientific terms.<br>
-<br>
-<br>
-<span style="font-weight: bold;">De la Rive's Floating Battery.</span><br>
-A small galvanic couple, immersed in a little floating cell and<br>
-connected through a coil of wire immediately above them. When the<br>
-exciting battery solution is placed in the cell the whole, as it floats<br>
-in a larger vessel, turns until the coil lies at right angles to the<br>
-magnetic needle. Sometimes the two plates are thrust through a cork and<br>
-floated thus in a vessel of dilute sulphuric acid.<br>
-<br>
-A magnet acts to attract or repel the coil in obedience to
-Amp&eacute;re's<br>
-Theory, (See Magnetism, Ampere's Theory of.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Delaurier's Solution.</span><br>
-A solution for batteries of the Bunsen and Grenet type. It is of the<br>
-following composition:<br>
-&nbsp;&nbsp;&nbsp;&nbsp; <span style="font-family: monospace;">Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2,000 parts;</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; potassium
-bichromate,&nbsp;&nbsp; 184 parts;</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; sulphuric
-acid,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 428 parts.</span><br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Demagnetization.</span><br>
-Removal of magnetism from a paramagnetic substance. It is principally<br>
-used for watches which have become magnetized by exposure to the<br>
-magnetic field surrounding dynamos or motors.<br>
-<br>
-The general principles of most methods are to rotate the object, as a<br>
-watch, in a strong field, and while it is rotating to gradually remove<br>
-it from the field, or to gradually reduce the intensity of the field<br>
-itself to zero. A conical coil of wire within which the field is<br>
-produced in which the watch is placed is sometimes used, the idea being<br>
-that the field within such a coil is strongest at its base. Such a coil<br>
-supplied by an alternating current is found effectual (J. J. Wright).<br>
-<br>
-If a magnetized watch is made to turn rapidly at the end of a twisted<br>
-string and is gradually brought near to and withdrawn from the poles of<br>
-a powerful dynamo it may be considerably improved.<br>
-<br>
-A hollow coil of wire connected with a pole changer and dip-battery has<br>
-been used. The battery creates a strong field within the coil. The watch<br>
-is placed there and the pole changer is worked so as to reverse the<br>
-polarity of the field very frequently. By the same action of the pole<br>
-changer the plates of the battery are gradually withdrawn from the<br>
-solution so as to gradually reduce the magnetic field to zero while<br>
-constantly reversing its polarity. (G. M. Hopkins.)<br>
-<br>
-Steel may be demagnetized by jarring when held out of the magnetic<br>
-meridian, or by heating to redness.<br>
-<br>
-<br>
-180&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Density, Electric Superficial.</span><br>
-The relative quantity of electricity residing as an electric charge upon<br>
-a unit area of surface. It may be positive or negative.<br>
-<br>
-Synonyms--Density of Charge--Surface Density.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dental Mallet, Electric.</span><br>
-A dentist's instrument for hammering the fillings as inserted into<br>
-teeth. It is a little hammer held in a suitable handle, and which is<br>
-made to strike a rapid succession of blows by electro-magnetic motor<br>
-mechanism.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Depolarization.</span><br>
-(a) The removal of permanent magnetism. (See Demagnetization.)<br>
-<br>
-(b) The prevention of the polarization of a galvanic cell. It is<br>
-effected in the Grove battery by the reduction of nitric acid; in the<br>
-Bunsen, by the reduction of chromic acid; in the Smee battery,<br>
-mechanically, by the platinum coated or rather platinized negative<br>
-plate. Other examples will be found under the description of various<br>
-cells and batteries. A fluid which depolarizes is termed a depolarizer<br>
-or depolarizing fluid or solution. (See Electropoion Fluid.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deposit, Electrolytic.</span><br>
-The metal or other substance precipitated by the action of a battery or<br>
-other current generator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Derivation, Point of.</span><br>
-A point where a circuit branches or divides into two or more leads. The<br>
-separate branches then receive derived or partial currents.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Desk Push.</span><br>
-A press or push button, with small flush rim, for setting into the<br>
-woodwork of a desk.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Detector.</span><br>
-A portable galvanometer, often of simple construction, used for rough or<br>
-approximate work.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Detector, Lineman's.</span><br>
-A portable galvanometer with a high and a low resistance actuating coil,<br>
-constructed for the use of linemen and telegraph constructors when in<br>
-the field, and actually putting up, repairing or testing lines.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deviation, Quadrantal.</span><br>
-Deviation of the compass in iron or steel ships due to the magnetization<br>
-of horizontal beams by the earth's induction. The effect of this<br>
-deviation disappears when the ship is in the plane of the electric<br>
-meridian, or at right angles thereto; its name is taken from the fact<br>
-that a swing of the ship through a quadrant brings the needle from zero<br>
-deviation to a maximum and back to zero.<br>
-<br>
-<br>
-181&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Deviation, Semicircular.</span><br>
-Deviation of the compass in iron or steel ships due to vertical<br>
-induction. (See Induction, Vertical.) The effect of this induction<br>
-disappears when the ship is in the electric meridian. Its name is<br>
-derived from the fact that a swing of the ship through half the circle<br>
-brings the needle from zero deviation to a maximum and back to zero.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dextrotorsal. adj.</span><br>
-Wound in the direction or sense of a right-handed screw; the reverse of<br>
-sinistrotorsal, q. v.<br>
-<br>
-<br>
-<img style="width: 660px; height: 112px;" alt=""
- src="images/181F128.jpg"><br>
-Fig. 128. DEXTROTORSAL HELIX.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Diacritical. adj.</span><br>
-(a) The number of ampere turns, q. v., required to bring an iron core to<br>
-one half its magnetic saturation, q. v., is termed the diacritical<br>
-number.<br>
-<br>
-(b) The diacritical point of magnetic saturation is proposed by Sylvanus<br>
-P. Thompson as a term for the coefficient of magnetic saturation which<br>
-gives a magnet core one-half its maximum magnetization.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Diagnosis, Electro.</span><br>
-A medical diagnosis of a patient's condition based on the action of<br>
-different parts of the body under electric excitement.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Diamagnetic. adj.</span><br>
-Possessing a negative coefficient of magnetic susceptibility; having<br>
-permeability inferior to that of air. Such substances placed between the<br>
-poles of a magnet are repelled; if in the form of bars, they tend to<br>
-turn so as to have their long axis at right angles to the line joining<br>
-the poles. The reason is that the lines of force always seek the easiest<br>
-path, and these bodies having higher reluctance than air, impede the<br>
-lines of force, and hence are as far as possible pushed out of the way.<br>
-The above is the simplest explanation of a not well understood set of<br>
-phenomena. According to Tyndall, "the diamagnetic force is a polar<br>
-force, the polarity of diamagnetic bodies being opposed to that of<br>
-paramagnetic ones under the same conditions of excitement." Bismuth is<br>
-the most strongly diamagnetic body known; phosphorus, antimony, zinc,<br>
-and many others are diamagnetic. (See Paramagnetic.)<br>
-<br>
-<br>
-182&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Diagometer.</span><br>
-An apparatus for use in chemical analysis for testing the purity of<br>
-substances by the time required for a charged surface to be discharged<br>
-through them to earth. It is the invention of Rousseau.<br>
-<br>
-An electrometer is charged with a dry pile. One of its terminals is<br>
-connected with one surface of the solution or substance to be tested,<br>
-and the other with the other surface. The time of discharge gives the<br>
-index of the purity of the substance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Diamagnetic Polarity.</span><br>
-Treating diamagnetism as due to a polar force, the polarity of a<br>
-diamagnetic body is the reverse of the polarity of iron or other<br>
-paramagnetic bodies. A bar-shaped diamagnetic body in a field of force<br>
-tends to place itself at right angles to the lines of force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Diamagnetism.</span><br>
-(a) The science or study of diamagnetic substances and phenomena.<br>
-<br>
-(b) The magnetic property of a diamagnetic substance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Diameter of Commutation.</span><br>
-The points on the commutator of a closed circuit ring--or<br>
-drum--armature, which the brushes touch, and whence they take the<br>
-current, mark the extremities of the diameter of commutation. Were it<br>
-not for the lag this would be the diameter at right angles to the line<br>
-connecting the centers of the opposite faces of the field. It is always<br>
-a little to one side of this position, being displaced in the direction<br>
-of rotation. In open circuit armatures the brushes are placed on the<br>
-diameter at right angles to this one, and sometimes the term diameter of<br>
-commutation is applied to it. All that has been said is on the<br>
-supposition that the armature divisions correspond not only in<br>
-connection but in position with those of the armature coils. Of course,<br>
-the commutator could be twisted so as to bring the diameter of<br>
-commutation into any position desired.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Diapason, Electric.</span><br>
-A tuning-fork or diapason kept in vibration by electricity. In general<br>
-principle the ends of the fork act as armatures for an electro-magnet,<br>
-and in their motion by a mercury cup or other form of contact they make<br>
-and break the circuit as they vibrate. Thus the magnet alternately<br>
-attracts and releases the leg, in exact harmony with its natural period<br>
-of vibration.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Diaphragm.</span><br>
-(a) In telephones and microphones a disc of iron thrown into motion by<br>
-sound waves or by electric impulses, according to whether it acts as the<br>
-diaphragm of a transmitter or receiver. It is generally a plate of<br>
-japanned iron such as used in making ferrotype photographs. (See<br>
-Telephone and Microphone.)<br>
-<br>
-(b) A porous diaphragm is often used in electric decomposition cells and<br>
-in batteries. The porous cup represents the latter use.<br>
-<br>
-[Transcriber's note: Japanned--covered with heavy black lacquer, like<br>
-enamel paint.]<br>
-<br>
-<br>
-183&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dielectric.</span><br>
-A non-conductor; a substance, the different parts of which may, after an<br>
-electric disturbance, remain, without any process of readjustment, and<br>
-for an indefinite period of time, at potentials differing to any extent<br>
-(Daniell). There is no perfect dielectric. The term dielectric is<br>
-generally only used when an insulator acts to permit induction to take<br>
-place through it, like the glass of a Leyden jar.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dielectric Constant.</span><br>
-The number or coefficient expressing the relative dielectric capacity of<br>
-a medium or substance. (See Capacity, Specific Inductive.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dielectric, Energy of.</span><br>
-In a condenser, the conducting coatings are merely to conduct the<br>
-current all over the surface they cover; the keeping the electricities<br>
-separated is the work of the dielectric, and represents potential energy<br>
-which appears in the discharge. The amount of energy is proportional to<br>
-the charge, and to the potential difference. As any electrified body<br>
-implies an opposite electrification somewhere, and a separating<br>
-dielectric, the existence of a condenser is always implied.<br>
-<br>
-[Transcriber's note: The energy stored in a capacitor (condenser) is<br>
-(Q*Q)/2C = (Q*V)/2 = (C*V*V)/2<br>
-The energy is proportional to the voltage SQUARED or the charge
-SQUARED.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dielectric Polarization.</span><br>
-A term due to Faraday. It expresses what he conceived to be the<br>
-condition of a dielectric when its opposite faces are oppositely<br>
-electrified. The molecules are supposed to be arranged by the<br>
-electrification in a series of polar chains, possibly being originally<br>
-in themselves seats of opposite polarities, or having such imparted to<br>
-them by the electricities. The action is analogous to that of a magnet<br>
-pole on a mass of soft iron, or on a pile of iron filings.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dielectric Strain.</span><br>
-The strain a solid dielectric is subjected to, when its opposite<br>
-surfaces are electrified. A Leyden jar dilates under the strain, and<br>
-when discharged gives a dull sound. The original condition is not<br>
-immediately recovered. Jarring, shaking, etc., assist the recovery from<br>
-strain. The cause of the strain is termed Electric Stress. (See Stress,<br>
-Electric.) This is identical with the phenomenon of residual charge.<br>
-(See Charge, Residual.) Each loss of charge is accompanied with a<br>
-proportional return of the dielectric towards its normal condition.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dielectric Resistance.</span><br>
-The mechanical resistance a body offers to perforation or destruction by<br>
-the electric discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dielectric Strength.</span><br>
-The resistance to the disruptive discharge and depending on its<br>
-mechanical resistance largely or entirely. It is expressible in volts<br>
-per centimeter thickness. Dry air requires 40,000 volts per centimeter<br>
-for a discharge.<br>
-<br>
-<br>
-184&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Differential Winding Working.</span><br>
-A method of working an electro-magnet intermittently, so as to avoid<br>
-sparking. The magnet is wound with two coils. One is connected straight<br>
-into the circuit, the other is connected in parallel therewith with a<br>
-switch inserted. The coils are so connected that when the switch is<br>
-closed the two are in opposition, the current going through them in<br>
-opposite senses. Thus one overcomes the effect of the other and the<br>
-magnet core shows no magnetism, provided the two coils are of equal<br>
-resistance and equal number of convolutions or turns.<br>
-<br>
-<br>
-<img style="width: 642px; height: 211px;" alt=""
- src="images/184F129.jpg"><br>
-Fig. 129. DIFFERENTIAL WINDING WORKING <br>
-OF ELECTRO-MAGNETIC APPARATUS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Diffusion.</span><br>
-A term properly applied to the varying current density found in<br>
-conductors of unequal cross sectional area. In electro-therapeutics it<br>
-is applied to the distribution of current as it passes through the human<br>
-body. Its density per cross-sectional area varies with the area and<br>
-with the other factors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Diffusion Creep.</span><br>
-When electrodes of an active circuit are immersed in a solution of an<br>
-electrolyte, a current passes electrolytically if there is a sufficient<br>
-potential difference. The current passes through all parts of the<br>
-solution, spreading out of the direct prism connecting or defined by the<br>
-electrodes. To this portion of the current the above term is applied. If<br>
-the electrodes are small enough in proportion to the distance between<br>
-them the current transmission or creep outside of the line becomes the<br>
-principal conveyor of the current so that the resistance remains the<br>
-same for all distances.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dimensions and Theory of Dimensions.</span><br>
-The expression of the unitary value of a physical quantity in one or<br>
-more of the units of length (L), time (T) and mass (M) is termed the<br>
-dimensions of such quantity. Thus the dimension or dimensions of a<br>
-distance is simply L; of an angle, expressible by dividing the arc by<br>
-the radius is L/L; of a velocity, expressible by distance divided by<br>
-time--L/T; of acceleration, which is velocity acquired in a unit of<br>
-time, and is therefore expressible by velocity divided by time--L/T/T or<br>
-L/T2; of momentum, which is the product of mass into velocity--M*L/T; of<br>
-kinetic energy taken as the product of mass into the square of<br>
-velocity--M*(L2/T2); of potential energy taken as the product of mass<br>
-into acceleration into space-M*(L/T2)*L reducing to M*(L2/T2). The<br>
-theory is based on three fundamental units and embraces all electric<br>
-quantities. The simple units generally taken are the gram, centimeter<br>
-and second and the dimensions of the fundamental compound units are<br>
-expressed in terms of these three, forming the centimeter-gram-second or<br>
-C. G. S. system of units. Unless otherwise expressed or implied the<br>
-letters L, M and T, may be taken to indicate centimeter, gram and second<br>
-respectively. It is obvious that very complicated expressions of<br>
-dimensions may be built up, and that a mathematical expression of<br>
-unnamed quantities may be arrived at. Dimensions in their application by<br>
-these symbols are subject to the laws of algebra. They were invented by<br>
-Fourier and were brought into prominence by J. Clerk Maxwell. Another<br>
-excellent definition reads as follows: "By the dimensions of a physical<br>
-quantity we mean the quantities and powers of quantities, involved in<br>
-the measurement of it." (W. T. A. Emtage.)<br>
-<br>
-<br>
-185&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dimmer.</span><br>
-An adjustable choking coil used for regulating the intensity of electric<br>
-incandescent lights. Some operate by the introduction and withdrawal of<br>
-an iron core as described for the choking coil (see Coil, Choking),<br>
-others by a damper of copper, often a copper ring surrounding the coil<br>
-and which by moving on or off the coil changes the potential of the<br>
-secondary circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dip of Magnetic Needle.</span><br>
-The inclination of the magnetic needle. (See Elements, Magnetic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dipping.</span><br>
-(a) Acid or other cleaning processes applied by dipping metals in<br>
-cleaning or pickling solutions before plating in the electroplater's<br>
-bath.<br>
-<br>
-(b) Plating by dipping applies to electroplating without a battery by<br>
-simple immersion. Copper is deposited on iron from a solution of copper<br>
-sulphate in this way.<br>
-<br>
-Synonym--Simple Immersion.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dipping Needle.</span><br>
-A magnet mounted in horizontal bearings at its centre of gravity. Placed<br>
-in the magnetic meridian it takes the direction of the magnetic lines of<br>
-force of the earth at that point. It is acted on by the vertical<br>
-component of the earth's magnetism, as it has no freedom of horizontal<br>
-movement. (See Magnetic Elements, and Compass, Inclination.)<br>
-<br>
-<span style="font-weight: bold;">Directing Magnet.</span><br>
-In a reflecting galvanometer the magnet used for controlling the<br>
-magnetic needle by establishing a field. It is mounted on the spindle of<br>
-the instrument above the coil and needle.<br>
-<br>
-Synonym--Controlling Magnet.<br>
-<br>
-<br>
-186&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Direction.</span><br>
-(a) The direction of an electric current is assumed to be from a<br>
-positively charged electrode or terminal to a negatively charged one in<br>
-the outer circuit. (See Current.)<br>
-<br>
-(b) The direction of magnetic and electro-magnetic lines of force is<br>
-assumed to be from north to south pole of a magnet in the outer circuit.<br>
-It is sometimes called the positive direction. Their general course is<br>
-shown in the cuts diagrammatically. The circles indicate a compass used<br>
-in tracing their course. The magnetic needle tends to place itself in<br>
-the direction of or tangential to the lines of force passing nearest it.<br>
-<br>
-(c) The direction of electrostatic lines of force is assumed to be out<br>
-of a positively charged and to a negatively charged surface.<br>
-<br>
-<br>
-<img style="width: 469px; height: 705px;" alt=""
- src="images/186F130_131.jpg"><br>
-Fig. 130. DIRECTION OF LINES OF FORCE OF A PERMANENT MAGNET.<br>
-<br>
-Fig. 131, DIRECTION OF LINES OF FORCE OF AN ELECTRO-MAGNET.<br>
-<br>
-<br>
-187&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Directive Power.</span><br>
-In magnetism the power of maintaining itself in the plane of the<br>
-magnetic meridian, possessed by the magnetic needle.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Brush.</span><br>
-The static discharge of electricity into or through the air may be of<br>
-the brush or spark form. The brush indicates the escape of electricity<br>
-in continuous flow; the spark indicates discontinuity. The conditions<br>
-necessary to the production of one or the other refer to the nature of<br>
-the conductor, and of other conductors in its vicinity and to the<br>
-electro-motive force or potential difference; small alterations may<br>
-transform one into the other. The brush resembles a luminous core whose<br>
-apex touches the conductor. It is accompanied by a slight hissing noise.<br>
-Its luminosity is very feeble. The negative conductor gives a smaller<br>
-brush than that of the positive conductor and discharges it more<br>
-readily. When electricity issues from a conductor, remote from an<br>
-oppositely excited one, it gives an absolutely silent discharge, showing<br>
-at the point of escape a pale blue luminosity called electric glow, or<br>
-if it escapes from points it shows a star-like centre of light. It can<br>
-be seen in the dark by placing a point on the excited conductor of a<br>
-static-electric machine.<br>
-<br>
-Synonyms--Silent Discharge--Glow Discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Conductive.</span><br>
-A discharge of a static charge by conduction through a conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Convective.</span><br>
-The discharge of static electricity from an excited conductor through<br>
-air or rarefied gas; it is also called the quiet or silent discharge.<br>
-The luminous effect in air or gas at atmospheric pressures takes the<br>
-form of a little brush from a small positive electrode; the negative<br>
-shows a star. The phenomena of Gassiot's cascade, the philosopher's egg<br>
-and Geissler tubes, all of which may be referred to, are instances of<br>
-convective discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Dead Beat.</span><br>
-A discharge that is not oscillatory in character.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Disruptive.</span><br>
-A discharge of a static charge through a dielectric. It involves<br>
-mechanical perforation of the dielectric, and hence the mere mechanical<br>
-strength of the latter has much to do with preventing it. A disruptive<br>
-discharge is often oscillatory in character; this is always the case<br>
-with the discharge of a Leyden jar.<br>
-<br>
-<br>
-188&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Duration of.</span><br>
-The problem of determining this factor has been attacked by various<br>
-observers. Wheatstone with his revolving mirror found it to be 1/24000<br>
-second. Fedderson, by interposing resistance, prolonged it to 14/10000<br>
-and again to 138/10000 second. Lucas &amp; Cazin made it from 26 to 47<br>
-millionths of a second. All these experiments were performed with Leyden<br>
-jars.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Impulsive.</span><br>
-A disruptive discharge produced between conductors by suddenly produced<br>
-potential differences. The self-induction of the conductor plays an<br>
-especially important part in discharges thus produced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Lateral.</span><br>
-(a) A lightning discharge, which sometimes takes place between a<br>
-lightning rod and the building on which it is.<br>
-<br>
-(b) In the discharge of a Leyden jar or condenser the discharge which<br>
-takes the alternative path, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Oscillatory</span>.<br>
-The sudden or disruptive discharge of a static condenser, such as a<br>
-Leyden jar, or of many other charged conductors, is oscillatory in<br>
-character. The direction of the currents rapidly changes, so that the<br>
-discharge is really an alternating current of excessively short total<br>
-duration. The discharge sends electro-magnetic waves through the ether,<br>
-which are exactly analogous to those of light but of too long period to<br>
-affect the eye.<br>
-<br>
-Synonym--Surging Discharge.<br>
-<br>
-[Transcriber's note: Marconi's transmission across the English channel<br>
-occurs in 1897, five years after the publication of this book.]<br>
-<br>
-<br>
-<img style="width: 627px; height: 541px;" alt=""
- src="images/188F132.jpg"><br>
-Fig. 132. DISCHARGER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharger.</span><br>
-An apparatus for discharging Leyden jars. It consists of a conductor<br>
-terminating in balls, and either jointed like a tongs or bent with a<br>
-spring-action, so that the balls can be set at distances adapted to<br>
-different sized jars. It has an insulating handle or a pair of such. In<br>
-use one ball is brought near to the coating and the other to the spindle<br>
-ball of the jar. When nearly or quite in contact the jar discharges.<br>
-<br>
-Synonyms--Discharging Rod--Discharging Tongs.<br>
-<br>
-<br>
-189&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharger, Universal.</span><br>
-An apparatus for exposing substances to the static discharge spark. It<br>
-consists of a base with three insulating posts. The central post carries<br>
-an ivory table to support the object. The two side posts carry<br>
-conducting rods, terminating in metal balls, and mounted with universal<br>
-joints. A violent shock can be given to any object placed on the table.<br>
-<br>
-Synonym--Henley's Universal Discharger.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Silent.</span><br>
-This term is sometimes applied to the glow or brush discharge and<br>
-sometimes to the condition of electric effluvium. (See Discharge,<br>
-Brush--Effluvium, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Discharge, Spark.</span><br>
-The discontinuous discharge of high tension electricity through a<br>
-dielectric or into the air produces electric sparks. These are quite<br>
-strongly luminous, of branching sinuous shape, and in long sparks the<br>
-luminosity varies in different parts of the same spark. A sharp noise<br>
-accompanies each spark. High density of charge is requisite for the<br>
-formation of long sparks.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Disconnection.</span><br>
-The separation of two parts of, or opening a circuit, as by turning a<br>
-switch, unscrewing a binding screw, or the like. The term is sometimes<br>
-used to indicate a class of faults in telegraph circuits. Disconnections<br>
-may be total, partial or intermittent, and due to many causes, such as<br>
-open or partially replaced switches, oxidized or dirty contact points,<br>
-or loose joints.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Displacement, Electric.</span><br>
-A conception of the action of charging a dielectric. The charge is all<br>
-on the surface. This fact being granted, the theory of displacement<br>
-holds that charging a body is the displacing of electricity, forcing it<br>
-from the interior on to the surface, or vice versa, producing a positive<br>
-or negative charge by displacement of electricity. While displacement is<br>
-taking place in a dielectric there is assumed to be a movement or<br>
-current of electricity called a displacement current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Disruptive Tension.</span><br>
-When the surface of a body is electrified, it tends to expand, all<br>
-portions of the surface repelling each other. The film of air<br>
-surrounding such a body is electrified too, and is subjected to a<br>
-disruptive tension, varying in intensity with the square of the density.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dissimulated Electricity.</span><br>
-The electricity of a bound charge. (See Charge, Bound.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dissociation.</span><br>
-The separation of a chemical compound into its elements by a<br>
-sufficiently high degree of heat. All compounds are susceptible of<br>
-dissociation, so that it follows that combustion is impossible at high<br>
-temperatures.<br>
-<br>
-<br>
-190&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Distance, Critical, of Alternative
-Path.</span><br>
-The length of air gap in an alternative path whose resistance joined to<br>
-the impedance of the rest of the conductors of the path just balances<br>
-the impedance of the other path.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Distance, Sparking.</span><br>
-The distance between electrodes, which a spark from a given Leyden jar<br>
-or other source will pass across.<br>
-<br>
-Synonym--Explosive Distance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Distillation.</span><br>
-The evaporation of a liquid by heat, and sometimes in a vacuum, followed<br>
-by condensation of the vapors, which distil or drop from the end of the<br>
-condenser. It is claimed that the process is accelerated by the liquid<br>
-being electrified.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Distributing Box.</span><br>
-In an electric conduit system, a small iron box provided for giving<br>
-access to the cable for the purpose of making house and minor<br>
-connections.<br>
-<br>
-Synonym--Hand Hole.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Distributing Switches.</span><br>
-Switch systems for enabling different dynamos to supply different lines<br>
-of a system as required. Spring jacks, q. v., are used for the lines,<br>
-and plug switches for the dynamo leads. Thus, dynamos can be thrown in<br>
-or out as desired, without putting out the lights.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Distribution of Electric Energy,
-Systems of.</span><br>
-The systems of electric current distribution from central stations or<br>
-from private generating plants, mechanical or battery, the latter<br>
-primary or secondary. They include in general the alternating current<br>
-system and direct current systems. Again, these may be subdivided into<br>
-series and multiple arc, multiple-series and series-multiple<br>
-distribution, and the three, four, or five wire system may be applied to<br>
-multiple arc or multiple series systems. (See Alternating<br>
-Current--Current System--Multiple Arc--Multiple Series--Series<br>
-Multiple--Three Wire System.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Door Opener, Electric.</span><br>
-An apparatus for opening a door by pushing back the latch. A spring then<br>
-draws the door open, and it is closed against the force of the spring by<br>
-the person entering. Electro-magnetic mechanism actuates the latch, and<br>
-is operated by a switch or press-button. Thus a person on the upper<br>
-floor can open the hall door without descending.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dosage, Galvanic.</span><br>
-In electro-therapeutics the amount of electric current or discharge, and<br>
-duration of treatment given to patients.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Double Carbon Arc Lamp.</span><br>
-An arc lamp designed to burn all night, usually constructed with two<br>
-parallel sets of carbons, one set replacing the other automatically, the<br>
-current being switched from the burnt out pair to the other by the<br>
-action of the mechanism of the lamp.<br>
-<br>
-<br>
-191&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Double Fluid Theory.</span><br>
-A theory of electricity. Electricity is conveniently treated as a fluid<br>
-or fluids. According to the double fluid hypothesis negative electricity<br>
-is due to a preponderance of negative fluid and vice versa. Like fluid<br>
-repels like, and unlike attracts unlike; either fluid is attracted by<br>
-matter; the presence in a body of one or the other induces<br>
-electrification; united in equal proportions they neutralize each other,<br>
-and friction, chemical decomposition and other causes effect their<br>
-separation. The hypothesis, while convenient, is overshadowed by the<br>
-certainty that electricity is not really a fluid at all. (See Single<br>
-Fluid Theory--Fluid, Electric.)<br>
-<br>
-Synonym--Symmer's Theory.<br>
-<br>
-[Transcriber's note: Current is the motion of negative electrons in a<br>
-conductor or plasma. Unequal distribution of electrons is static<br>
-electricity. The relatively immobile nuclei of atoms are positive when<br>
-one or more of its electrons is absent and accounts for part of the<br>
-current in electrolysis and plasmas.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Double Fluid Voltaic Cell.</span><br>
-A cell in which two fluids are used, one generally as depolarizer<br>
-surrounding the negative plate, the other as excitant surrounding the<br>
-positive plate. A porous diaphragm or difference in specific gravities<br>
-is used to keep the solutions separate and yet permit the essential<br>
-electrolytic diffusion. Grove's Cell, Bunsen's Cell, and Daniell's Cell,<br>
-all of which may be referred to, are of this type, as are many others.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Double Wedge.</span><br>
-A plug for use with a spring-jack. It has connection strips at its end<br>
-and another pair a little distance back therefrom, so that it can make<br>
-two loop connections at once.<br>
-<br>
-Synonym--Double Plug.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Doubler.</span><br>
-A continuously acting electrophorous, q.v.; an early predecessor of the<br>
-modern electric machines. It is now no longer used.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">D. P.</span><br>
-Abbreviation for Potential Difference.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Drag.</span><br>
-The pull exercised by a magnetic field upon a conductor moving through<br>
-it or upon the motion of an armature in it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dreh-strom. (German)</span><br>
-Rotatory currents; a system of currents alternating in periodic<br>
-succession of phases and producing a rotatory field. (See Field,<br>
-Rotatory--Multiphase Currents.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Drill Electric.</span><br>
-A drill for metals or rock worked by an electro-magnetic motor. For<br>
-metals a rotary motion, for rocks a reciprocating or percussion action<br>
-is imparted. It is used by shipbuilders for drilling holes in plates<br>
-which are in place in ships, as its flexible conductors enable it to be<br>
-placed anywhere. For rock-drilling a solenoid type of construction is<br>
-adopted, producing rapid percussion.<br>
-<br>
-<br>
-192&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Drip Loop.</span><br>
-A looping downward of wires entering a building, so that rain water, as<br>
-it runs along the wire, will drip from the lowest part of the loop<br>
-instead of following the wire into or against the side of the building.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Driving Horns.</span><br>
-Projections on the periphery of an armature of a dynamo for holding the<br>
-winding in place and preventing its displacement. Various arrangements<br>
-have been adopted. They are sometimes wedges or pins and are sometimes<br>
-driven into spaces left in the drum core. The toothed disc armature<br>
-cores make up an armature in which the ridges formed by the teeth form<br>
-practically driving horns.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dronier's Salt.</span><br>
-A substance for solution for use in bichromate batteries. It is a<br>
-mixture of one-third potassium bichromate and two-thirds potassium<br>
-bisulphate. It is dissolved in water to make the exciting fluid.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Drop, Automatic.</span><br>
-A switch or circuit breaker, operating to close a circuit by dropping<br>
-under the influence of gravity. It is held up by a latch, the circuit<br>
-remaining open, until the latch is released by a current passing through<br>
-an electro-magnet. This attracting an armature lets the drop fall. As it<br>
-falls it closes a local or second circuit, and thus may keep a bell<br>
-ringing until it is replaced by hand. It is used in burglar alarms, its<br>
-function being to keep a bell ringing even though the windows or door by<br>
-which entrance was made is reclosed.<br>
-<br>
-<br>
-193&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 597px; height: 714px;" alt=""
- src="images/192F133.jpg"><br>
-Fig. 133. THE MAGIC DRUM.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Drum, Electric.</span><br>
-A drum with a mechanism within for striking the head with a hammer or<br>
-some equivalent method so as to be used as a piece of magical apparatus.<br>
-In the one shown in the cut a sort of telephone action is used to<br>
-produce the sound, the electro-magnet D and armature being quite<br>
-screened from observation through the hole. (See Fig. 133) A ring, C,<br>
-shown in Fig. 133, with two terminals, the latter shown by the unshaded<br>
-portions a a, and a suspending hook E, also with two terminals, and two<br>
-suspending conductors A, B, carry the current to the magnet. A sudden<br>
-opening or closing of the circuit produces a sound.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dub's Laws.</span><br>
-1. The magnetism excited at any transverse section of a magnet is<br>
-proportional to the square root of the distance between the given<br>
-section and the end.<br>
-<br>
-2. The free magnetism at any given transverse section of a magnet is<br>
-proportional to the difference between the square root of half the<br>
-length of the magnet and the square root of the distance between the<br>
-given section and the nearest end.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Duct.</span><br>
-The tube or compartment in an electric subway for the reception of a<br>
-cable. (See Conduit, Electric Subway.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dyad.</span><br>
-A chemical term; an element which in combination replaces two monovalent<br>
-elements; one which has two bonds or is bivalent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dyeing, Electric.</span><br>
-The producing mordanting or other dyeing effects on goods in dyeing by<br>
-the passage of an electric current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamic Electricity.</span><br>
-Electricity of relatively low potential and large quantity; current<br>
-electricity as distinguished from static electricity; electricity in<br>
-motion.<br>
-<br>
-<br>
-194&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Alternating Current.</span><br>
-A dynamo-electric machine for producing an alternating current; an<br>
-alternator. They are classified by S. P. Thompson into three classes--I.<br>
-Those with stationary field-magnet and rotating armature. II. Those with<br>
-rotating field magnet and stationary armature. III. Those with both<br>
-field magnet part and armature part stationary, the amount of magnetic<br>
-induction from the latter through the former being caused to vary or<br>
-alternate in direction by the revolution of appropriate pieces of iron,<br>
-called inductors. Another division rests on whether they give one simple<br>
-alternating current, a two phase current, or whether they give multi<br>
-phase currents. (See Current, Alternating--Currents, Multiphase.)<br>
-<br>
-A great many kinds of alternators have been constructed. Only an outline<br>
-of the general theory can be given here. They are generally multipolar,<br>
-with north and south poles alternating around the field. The armature<br>
-coils, equal in number in simple current machines, to the poles, are<br>
-wound in opposite senses, so that the current shall be in one direction,<br>
-though in opposite senses, in all of them at anyone time. As the<br>
-armature rotates the coils are all approaching their poles at one time<br>
-and a current in one sense is induced in every second coil, and one in<br>
-the other sense in the other coils. They are all in continuous circuit<br>
-with two open terminals, each connected to its own insulated connecting<br>
-ring on the shaft. As the coils pass the poles and begin to recede from<br>
-them the direction changes, and the current goes in the other direction<br>
-until the next poles are reached and passed. Thus there are as many<br>
-changes of direction of current per rotation as there are coils in the<br>
-armature or poles in the field.<br>
-<br>
-<br>
-<img style="width: 579px; height: 542px;" alt=""
- src="images/194F134.jpg"><br>
-Fig. 134. ALTERNATING CURRENT DYNAMO WITH<br>
-SEPARATE EXCITER MOUNTED ON MAIN SHAFT.<br>
-<br>
-<br>
-195&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The field-magnets whose windings may be in series are often excited by a<br>
-separate direct current generation. Some are self-exciting, one or more<br>
-of the armature coils being separated from the rest, and connected to a<br>
-special commutator, which rectifies its current.<br>
-<br>
-By properly spacing the coils with respect to the poles of the field,<br>
-and connecting each set of coils by itself to separate connecting rings,<br>
-several currents can be taken from the same machine, which currents<br>
-shall have a constant difference in phase. It would seem at first sight<br>
-that the same result could be attained by using as many separate<br>
-alternators as there were currents to be produced. But it would be<br>
-almost impossible to preserve the exact relation of currents and current<br>
-phase where each was produced by its own machine. The currents would<br>
-overrun each other or would lag behind. In a single machine with<br>
-separate sets of coils the relation is fixed and invariable.<br>
-<br>
-<img style="width: 753px; height: 427px;" alt=""
- src="images/195F135.jpg"><br>
-<br>
-Fig. I35. DIAGRAM OF ARRANGEMENT OF ARMATURE COILS AND<br>
-COLLECTING RINGS IN AN ALTERNATING CURRENT DYNAMO.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Alternating Current,
-Regulation of.</span><br>
-Transformers, converters, or induction coils are used to regulate<br>
-alternating current dynamos, somewhat as compound winding is applied in<br>
-the case of direct-current dynamos. The arrangement consists in<br>
-connecting the primary of an induction coil or transformer into the<br>
-external circuit with its secondary connected to the field circuit. Thus<br>
-the transformer conveys current to the field picked up from the main<br>
-circuit, and represents to some extent the shunt of a direct-current<br>
-machine.<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Commercial Efficiency of.</span><br>
-The coefficient, q. v., obtained by dividing the mechanically useful or<br>
-available work of a dynamo by the mechanical energy absorbed by it. This<br>
-only includes the energy available in the outer circuit, for doing<br>
-useful work.<br>
-<br>
-<br>
-196&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 426px; height: 590px;" alt=""
- src="images/196F136.jpg"><br>
-Fig. 136. COMPOUND WOUND DYNAMO.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo. Compound.</span><br>
-A compound wound dynamo; one which has two coils on its field magnet;<br>
-one winding is in series with the external circuit and armature; the<br>
-other winding is in parallel with the armature winding, or else with the<br>
-armature winding and field winding, both in series. (See Winding, Long<br>
-Shunt--Winding, Short Shunt.)<br>
-<br>
-Such a dynamo is, to a certain extent, self-regulating, the two coils<br>
-counteracting each other, and bringing about a more regular action for<br>
-varying currents than that of the ordinary shunt or series dynamo.<br>
-<br>
-The extent of the regulation of such a machine depends on the<br>
-proportions given its different parts. However good the self-regulating<br>
-may be in a compound wound machine, it can only be perfect at one<br>
-particular speed.<br>
-<br>
-To illustrate the principle on which the approximate regulation is<br>
-obtained the characteristic curve diagram may be consulted.<br>
-<br>
-<br>
-<img style="width: 629px; height: 387px;" alt=""
- src="images/196F137.jpg"><br>
-Fig. 137. CURVES OF SERIES AND SHUNT WINDINGS SUPERIMPOSED.<br>
-<br>
-<br>
-One curve is the curve of a series winding, the other that of a shunt<br>
-winding, and shows the variation of voltage in each with resistance in<br>
-the external or working circuit. The variation is opposite in each case.<br>
-It is evident that the two windings could be so proportioned on a<br>
-compound machine that the resultant of the two curves would be a<br>
-straight line. This regulation would then be perfect and automatic, but<br>
-only for the one speed.<br>
-<br>
-<br>
-197&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Direct Current.</span><br>
-A dynamo giving a current of unvarying direction, as distinguished from<br>
-an alternator or alternating current dynamo.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Disc.</span><br>
-A dynamo with a disc armature, such as Pacinotti's disc, q. v. (See also<br>
-Disc, Armature.) The field magnets are disposed so that the disc rotates<br>
-close to their poles, and the poles face or are opposite to the side or<br>
-sides of the disc. The active leads of wire are those situated on the<br>
-face or faces of the disc.<br>
-<br>
-<br>
-<img style="width: 633px; height: 616px;" alt=""
- src="images/197F138.jpg"><br>
-Fig. 138. POLECHKO'S DISC DYNAMO.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dynamo-electric Machine.</span><br>
-A machine driven by power, generally steam power, and converting the<br>
-mechanical energy expended on driving it into electrical energy of the<br>
-current form. The parts of the ordinary dynamo may be summarized as<br>
-follows: First, A circuit as complete as possible of iron. Such circuit<br>
-is composed partly of the cores of an electro-magnet or of several<br>
-electro-magnets, and partly of the cylindrical or ring-shaped core of an<br>
-armature which fits as closely as practicable between the magnet ends or<br>
-poles which are shaped so as to partly embrace it. Second, of coils of<br>
-insulated wire wound upon the field-magnet cores. When these coils are<br>
-excited the field-magnets develop polarity and the circuit just spoken<br>
-of becomes a magnetic circuit, interrupted only by the air gaps between<br>
-the poles and armatures. Thirdly, of coils of insulated wire upon the<br>
-armature core. These coils when rotated in the magnetic field cut<br>
-magnetic lines of force and develop electro-motive force.<br>
-<br>
-<br>
-198&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Fourthly, of collecting mechanism, the commutator in direct current<br>
-dynamos, attached to the armature shaft and rotating with it. This<br>
-consists of insulated rings, or segments of rings to which the wire<br>
-coils of the armature are connected, and on which two springs of copper<br>
-or plates of carbon or some other conductor presses. The electro-motive<br>
-force developed by the cutting of lines of force, by the wires of the<br>
-armature, shows itself as potential difference between the two springs.<br>
-If the ends of a conductor are attached, one to each of these brushes,<br>
-the potential difference will establish a current through the wire. By<br>
-using properly divided and connected segments on the commutator the<br>
-potential difference and consequent direction of the current may be kept<br>
-always in the same sense or direction. It is now clear that the external<br>
-wire may be connected with the windings of the field-magnet. In such<br>
-case the excitement of the field-magnets is derived from the armature<br>
-and the machine is self-excited and entirely self-contained.<br>
-<br>
-The above is a general description of a dynamo. Sometimes the coils of<br>
-the field-magnets are not connected with the armature, but derive their<br>
-current from an outside source. Such are termed separately excited<br>
-dynamos.<br>
-<br>
-Some general features of dynamo generators may be seen in the<br>
-definitions under this head and elsewhere. The general conception is to<br>
-cut lines of force with a conductor and thus generate electromotive<br>
-force, or in some way to change the number of lines of force within a<br>
-loop or circuit with the same effect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Electroplating.</span><br>
-A dynamo designed for low potential and high current intensity. They are<br>
-wound for low resistance, frequently several wires being used in<br>
-parallel, or ribbon, bar or rectangular conductors being employed. They<br>
-are of the direct current type. They should be shunt wound or they are<br>
-liable to reverse. They are sometimes provided with resistance in the<br>
-shunt, which is changed as desired to alter the electro-motive force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dynamo, Equalizing.</span><br>
-A combination for three and five-wire systems. A number of armatures or<br>
-of windings on the same shaft are connected across the leads. If the<br>
-potential drops at any pair of mains, the armature will begin to be<br>
-driven by the other mains, acting to an extent as an element of a motor,<br>
-and will raise the potential in the first pair.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Far Leading.</span><br>
-A motor dynamo, used to compensate the drop of potential in long mains.<br>
-Into the mains at a distant point a series motor is connected, driving a<br>
-dynamo placed in shunt across the mains. The dynamo thus driven raises<br>
-the potential difference between the two mains.<br>
-<br>
-<br>
-199&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamograph.</span><br>
-A printing telegraph in which the message is printed at both<br>
-transmitting and receiving ends.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Inductor.</span><br>
-A generator in which the armature or current-generating windings are all<br>
-comprised upon the poles of the field magnets. Masses of iron, which<br>
-should be laminated and are the inductors, are carried past the field<br>
-magnet poles concentrating in their passage the lines of force, thus<br>
-inducing currents in the coils. In one construction shown in the cut the<br>
-field magnets a, a .. are U shaped and are arranged in a circle, their<br>
-poles pointing inwards. A single exciting coil c, c ... is wound around<br>
-the circle in the bend of the V-shaped segments. The poles carry the<br>
-armature coils e, e ... The laminated inductors i, i ... are mounted on<br>
-a shaft S, by spiders h, to be rotated inside the circle of magnets,<br>
-thus generating an alternating current.<br>
-<br>
-Synonym--Inductor Generator.<br>
-<br>
-<br>
-<img style="width: 622px; height: 538px;" alt=""
- src="images/199F139.jpg"><br>
-Fig. 139. INDUCTOR DYNAMO.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Interior Pole.</span><br>
-A dynamo with a ring armature, with field magnet pole pieces which<br>
-extend within the ring.<br>
-<br>
-<br>
-200&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Iron Clad.</span><br>
-A dynamo in which the iron of the field magnet is of such shape as to<br>
-enclose the field magnet coils as well as the armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamometer.</span><br>
-A device or apparatus for measuring force applied, or rate of<br>
-expenditure of energy by, or work done in a given time by a machine. A<br>
-common spring balance can be used as a force dynamometer, viz: to<br>
-determine how hard a man is pulling and the like. The steam engine<br>
-indicator represents an energy-dynamometer of the graphic type, the<br>
-instrument marking an area whence, with the aid of the fixed factors of<br>
-the engine, the work done may be determined. Prony's Brake, q. v., is a<br>
-type of the friction dynamometer, also of the energy type. In the latter<br>
-type during the experiment the whole power must be turned on or be<br>
-expended on the dynamometer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Motor.</span><br>
-A motor dynamo is a machine for (a) converting a continuous current at<br>
-any voltage to a continuous current of different strength at a different<br>
-voltage or for (b) transforming a continuous current into an alternating<br>
-one, and vice versa.<br>
-<br>
-For the first type see Transformer, Continuous Current; for the second<br>
-type see Transformer, Alternating Current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Multipolar.</span><br>
-A dynamo having a number of field magnet poles, not merely a single<br>
-north and a single south pole. The field magnet is sometimes of a<br>
-generally circular shape with the poles arranged radially within it, the<br>
-armature revolving between the ends.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dynamo, Non-polar.</span><br>
-A name given by Prof. George Forbes to a dynamo invented by him. In it a<br>
-cylinder of iron rotates within a perfectly self-contained iron-clad<br>
-field magnet. The current is taken off by brushes bearing near the<br>
-periphery, at two extremities of a diameter. A machine with a disc 18<br>
-inches in diameter was said to give 3,117 amperes, with 5.8 volts E. M.<br>
-F. running at 1,500 revolutions per second. The E. M. F. of such<br>
-machines varies with the square of the diameter of the disc or cylinder.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Open Coil.</span><br>
-A dynamo the windings of whose armatures may be grouped in coils, which<br>
-are not connected in series, but which have independent terminals. These<br>
-terminals are separate divisions of the commutator and so spaced that<br>
-the collecting brushes touch each pair belonging to the same coil<br>
-simultaneously. As the brushes come in contact with the sections forming<br>
-the terminals they take current from the coil in question. This coil is<br>
-next succeeded by another one, and so on according to the number of<br>
-coils employed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Ring.</span><br>
-A dynamo the base of whose field magnets is a ring in general shape, or<br>
-perhaps an octagon, and with poles projecting inwardly therefrom.<br>
-<br>
-<br>
-201&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Coupling of.</span><br>
-Dynamos can be coupled exactly like batteries and with about the same<br>
-general results. An instance of series coupling would be given by the<br>
-dynamos in the three wire system when no current is passing through the<br>
-neutral wire, and when the lamps on each side of it are lighted in equal<br>
-number.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dynamo, Self-exciting.</span><br>
-A dynamo which excites its own field. The majority of dynamos are of<br>
-this construction. Others, especially alternating current machines, are<br>
-separately excited, the field magnets being supplied with current from a<br>
-separate dynamo or current generator.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dynamo, Separate Circuit.</span><br>
-A dynamo in which the field magnet coils are entirely disconnected from<br>
-the main circuit, and in which current for the field is supplied by<br>
-special coils carried for the purpose by the same armature, or by a<br>
-special one, in either case a special commutator being provided to<br>
-collect the current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dynamo, Separately Excited.</span><br>
-A dynamo whose field magnets are excited by a separate current<br>
-generator, such as a dynamo or even a battery. Alternating current<br>
-dynamos are often of this construction. Direct current dynamos are not<br>
-generally so. The term is the opposite of self-exciting.<br>
-<br>
-<br>
-<img style="width: 570px; height: 725px;" alt=""
- src="images/201F140.jpg"><br>
-Fig. 140. SERIES DYNAMO.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Series.</span><br>
-A dynamo whose armature, field winding, and external circuit are all in<br>
-series.<br>
-<br>
-In such a dynamo short circuiting or lowering the resistance of the<br>
-external circuit strengthens the field, increases the electro-motive<br>
-force and current strength and may injure the winding by heating the<br>
-wire, and melting the insulation.<br>
-<br>
-<br>
-202&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Shunt.</span><br>
-A dynamo whose field is wound in shunt with the external circuit. Two<br>
-leads are taken from the brushes; one goes around the field magnets to<br>
-excite them; the other is the external circuit.<br>
-<br>
-In such a dynamo the lowering of resistance on the outer circuit takes<br>
-current from the field and lowers the electro-motive force of the<br>
-machine. Short circuiting has no heating effect.<br>
-<br>
-<br>
-<img style="width: 604px; height: 698px;" alt=""
- src="images/202F141.jpg"><br>
-Fig. 141.&nbsp;&nbsp; SHUNT DYNAMO.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Single Coil.</span><br>
-A dynamo whose field magnet is excited by a single coil. Several such<br>
-have been constructed, with different shapes of field magnet cores, in<br>
-order to obtain a proper distribution of poles.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Dynamo, Tuning Fork.</span><br>
-A dynamo in which the inductive or armature coils were carried at the<br>
-ends of the prongs of a gigantic tuning fork, and were there maintained<br>
-in vibration opposite the field magnets. It was invented by T. A.<br>
-Edison, but never was used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dynamo, Uni-polar.</span><br>
-A dynamo in which the rotation of a conductor effects a continuous<br>
-increase in the number of lines cut, by the device of arranging one part<br>
-of the conductor to slide on or around the magnet. (S. P. Thomson.)<br>
-Faraday's disc is the earliest machine of this type.<br>
-<br>
-<br>
-203&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Dyne.</span><br>
-The C. G. S. or fundamental unit of force. It is the force which can<br>
-impart an acceleration of one centimeter per second to a mass of one<br>
-gram in one second. It is equal to about 1/981 the weight of a gram,<br>
-this weight varying with the latitude.</big></big><big><big><br>
-<br>
-<br>
-<span style="font-weight: bold;">Earth.</span><br>
-(a) The earth is arbitrarily taken as of zero electrostatic potential.<br>
-Surfaces in such condition that their potential is unchanged when<br>
-connected to the earth are said to be of zero potential. All other<br>
-surfaces are discharged when connected to the earth, whose potential,<br>
-for the purposes of man at least, never changes.<br>
-<br>
-(b) As a magnetic field of force the intensity of the earth's field is<br>
-about one-half a line of force per square centimeter.<br>
-<br>
-(c) The accidental grounding of a telegraph line is termed an earth, as<br>
-a dead, total, partial, or intermittent earth, describing the extent and<br>
-character of the trouble.<br>
-<br>
-[Transcriber's note: Fallen power lines can produce voltage gradients on<br>
-the earth's surface that make walking in the area dangerous, as in<br>
-hundreds of volts per foot. Lightning may be associated with substantial<br>
-changes in the static ground potential.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Earth, Dead.</span><br>
-A fault, when a telegraph or other conductor is fully connected to earth<br>
-or grounded at some intermediate point.<br>
-<br>
-Synonyms--Solid Earth--Total Earth.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Earth, Partial.</span><br>
-A fault, when a telegraph or other conductor is imperfectly connected to<br>
-earth or grounded at some intermediate point.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Earth Plate.</span><br>
-A plate buried in the earth to receive the ends of telegraph lines or<br>
-other circuits to give a ground, q. v. A copper plate is often used. A<br>
-connection to a water or gas main gives an excellent ground, far better<br>
-than any plate. When the plate oxidizes it is apt to introduce<br>
-resistance.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Earth Return.</span><br>
-The grounding of a wire of a circuit at both ends gives the circuit an<br>
-earth return.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Earth, Swinging.</span><br>
-A fault, when a telegraph or other conductor makes intermittent<br>
-connection with the earth. It is generally attributable to wind action<br>
-swinging the wire, whence the name.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ebonite.</span><br>
-Hard vulcanized India rubber, black in color. Specific resistance in<br>
-ohms per cubic centimeter at 46&ordm; C. (115&ordm; F.): 34E15
-(Ayrton); specific<br>
-inductive capacity, (air = 1): 2.56 (W&uuml;llner); 2.76 (Schiller);
-3.15<br>
-(Boltzmann). It is used in electrical apparatus for supporting members<br>
-such as pillars, and is an excellent material for frictional generation<br>
-of potential. Its black color gives it its name, and is sometimes made a<br>
-point of distinction from Vulcanite, q. v.<br>
-<br>
-<br>
-204&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Economic Coefficient.</span><br>
-The coefficient of electric efficiency. (See Efficiency, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Edison Effect.</span><br>
-A continuous discharge resulting in a true current which takes place<br>
-between a terminal of an incandescent lamp filament and a plate placed<br>
-near it. The lamp must be run at a definitely high voltage to obtain it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ediswan.</span><br>
-An abbreviation for Edison-Swan; the trade name of the incandescent lamp<br>
-used in Great Britain, and of other incandescent system apparatus.<br>
-<br>
-<br>
-<img style="width: 422px; height: 511px;" alt=""
- src="images/204F142.jpg"><br>
-Fig. 142. GYMNOTUS ELECTRICUS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Eel, Electric (Gymnotus Electricus).</span><br>
-An eel capable of effecting the discharge of very high potential<br>
-electricity, giving painful or dangerous shocks. Its habitat is the<br>
-fresh water, in South America. Faraday investigated it and estimated its<br>
-shock as equal to that from fifteen Leyden jars, each of 1.66 square<br>
-feet of coating. (See Animal Electricity and Ray, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Effect, Counter-inductive.</span><br>
-A counter-electro-motive force due to induction, and opposing a current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Efficiency.</span><br>
-The relation of work done to energy absorbed. A theoretically perfect<br>
-machine would have the maximum efficiency in which the two qualities<br>
-named would be equal to each other. Expressed by a coefficient, q. v.,<br>
-the efficiency in such case would be equal to 1. If a machine produced<br>
-but half the work represented by the energy it absorbed, the rest<br>
-disappearing in wasteful expenditure, in heating the bearings, in<br>
-overcoming the resistance of the air and in other ways, its efficiency<br>
-would be expressed by the coefficient 1/2 or .5, or if one hundred was<br>
-the basis, by fifty per centum. There are a number of kinds of<br>
-efficiencies of an electric generator which are given below.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Efficiency, Commercial.</span><br>
-Practical efficiency of a machine, obtained by dividing the available<br>
-output of work or energy of a machine by the energy absorbed by the same<br>
-machine. Thus in a dynamo part of the energy is usefully expended in<br>
-exciting the field magnet, but this energy is not available for use in<br>
-the outer circuit, is not a part of the output, and is not part of the<br>
-dividend.<br>
-<br>
-If M represents the energy absorbed, and W the useful or available<br>
-energy, the coefficient of commercial efficiency is equal to W/M. M is<br>
-made up of available, unavailable and wasted (by Foucault currents,<br>
-etc.,) energy. Calling available energy W, unavailable but utilized<br>
-energy w, and wasted energy m, the expression for the coefficient of<br>
-commercial efficiency becomes<br>
-<br>
-&nbsp; W / ( W + w + m )<br>
-&nbsp; when M = W + w + m<br>
-<br>
-Synonym--Net efficiency.<br>
-<br>
-<br>
-205&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Efficiency, Electrical.</span><br>
-In a dynamo or generator the relation of total electric energy produced,<br>
-both wasted and useful or available to the useful or available<br>
-electrical energy. If we call W the useful electric and w the wasted<br>
-electric energy, the coefficient of electrical efficiency is equal to<br>
-<br>
-&nbsp; W / ( W + w )<br>
-<br>
-Synonyms--Intrinsic Efficiency--Economic Coefficient--Coefficient of<br>
-Electrical Efficiency.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Efficiency of Conversion.</span><br>
-In a dynamo or generator the relation of energy absorbed to total<br>
-electric energy produced. Part of the electric energy is expended in<br>
-producing the field and in other ways. Thus a generator with high<br>
-efficiency of conversion may be a very poor one, owing to the<br>
-unavailable electric energy which it produces. The coefficient of<br>
-Efficiency of Conversion is obtained by dividing the total electric<br>
-energy produced by the energy absorbed in working the dynamo. If M<br>
-represents the energy absorbed, or work done in driving the dynamo or<br>
-generator, W the useful electric, and w the wasted electrical energy,<br>
-then the coefficient of efficiency of conversion is equal to<br>
-<br>
-(W + w ) / M<br>
-<br>
-In the quantity M are included besides available (W) and unavailable (w)<br>
-electric energy, the totally wasted energy due to Foucault currents,<br>
-etc., calling the latter m, the above formula may be given<br>
-<br>
-( W+ w ) / (W + w + m )<br>
-<br>
-This coefficient may refer to the action of a converter, q. v., in the<br>
-alternating system. Synonym--Gross Efficiency.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Efficiency of Secondary Battery,
-Quantity.</span><br>
-The coefficient obtained by dividing the ampere-hours obtainable from a<br>
-secondary battery by the ampere hours required to charge it.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Efficiency of Secondary Battery, Real.</span><br>
-The coefficient obtained by dividing the energy obtainable from a<br>
-secondary battery by the energy absorbed in charging it. The energy is<br>
-conveniently taken in watt-hours and includes the consideration of the<br>
-spurious voltage. (See Battery, Secondary.)<br>
-<br>
-<br>
-206&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Efflorescence.</span><br>
-The appearance of a dry salt upon the walls of a vessel containing a<br>
-solution above the normal water-line from evaporation of a liquid. It<br>
-appears in battery jars and in battery carbons, in the latter<br>
-interfering with the electrical connections, and oxidizing or rusting<br>
-them. (See Creeping.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Effluvium, Electric.</span><br>
-When a gas is made to occupy the position of dielectric between two<br>
-oppositely electrified surfaces a peculiar strain or condition of the<br>
-dielectric is produced, which promotes chemical change. The condition is<br>
-termed electrical effluvium or the silent discharge. By an apparatus<br>
-specially constructed to utilize the condition large amounts of ozone<br>
-are produced.<br>
-<br>
-Synonym--Silent Discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Elastic Curve.</span><br>
-A crude expression for a curve without projections or sudden<br>
-sinuosities; such a curve as can be obtained by bending an elastic strip<br>
-of wood.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrepeter.</span><br>
-An obsolete name for a key, switch or pole changer of any kind.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Elasticity, Electric.</span><br>
-The phenomenon of the dielectric is described under this term. When a<br>
-potential difference is established between two parts of the dielectric,<br>
-a flow of electricity displacement current starts through the<br>
-dielectric, which current is due to the electric stress, but is<br>
-instantly arrested by what has been termed the electric elasticity of<br>
-the dielectric. This is expressed by<br>
-&nbsp; ( electric stress ) / ( electric strain )<br>
-and in any substance is inversely proportional to the specific inductive<br>
-capacity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electricity.</span><br>
-It is impossible in the existing state of human knowledge to give a<br>
-satisfactory definition of electricity. The views of various authorities<br>
-are given here to afford a basis for arriving at the general consensus<br>
-of electricians.<br>
-<br>
-We have as yet no conception of electricity apart from the electrified<br>
-body; we have no experience of its independent existence. (J. E. H.<br>
-Gordon.)<br>
-<br>
-What is Electricity? We do not know, and for practical purposes it is<br>
-not necessary that we should know. (Sydney F. Walker.)<br>
-<br>
-Electricity &#8230; is one of those hidden and mysterious powers of nature<br>
-which has thus become known to us through the medium of effects.<br>
-(Weale's Dictionary of Terms.)<br>
-<br>
-This word Electricity is used to express more particularly the cause,<br>
-which even today remains unknown, of the phenomena that we are about to<br>
-explain. (Am&eacute;d&eacute;e Guillemin.)<br>
-<br>
-207&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-Electricity is a powerful physical agent which manifests itself mainly<br>
-by attractions and repulsions, but also by luminous and heating effects,<br>
-by violent commotions, by chemical decompositions, and many other<br>
-phenomena. Unlike gravity, it is not inherent in bodies, but it is<br>
-evoked in them by a variety of causes &#8230; (Ganot's Physics.)<br>
-<br>
-Electricity and magnetism are not forms of energy; neither are they<br>
-forms of matter. They may, perhaps, be provisionally defined as<br>
-properties or conditions of matter; but whether this matter be the<br>
-ordinary matter, or whether it be, on the other hand, that<br>
-all-pervading ether by which ordinary matter is surrounded, is a question<br>
-which has been under discussion, and which now may be fairly held to be<br>
-settled in favor of the latter view. (Daniell's Physics.)<br>
-<br>
-The name used in connection with an extensive and important class of<br>
-phenomena, and usually denoting the unknown cause of the phenomena or<br>
-the science that treats of them. (Imperial Dictionary.)<br>
-<br>
-Electricity. . . is the imponderable physical agent, cause, force or the<br>
-molecular movement, by which, under certain conditions, certain<br>
-phenomena, chiefly those of attraction and repulsion, . . . are<br>
-produced. (John Angell.)<br>
-<br>
-It has been suggested that if anything can rightly be called<br>
-"electricity," this must be the ether itself; and that all electrical<br>
-and magnetic phenomena are simply due to changes, strains and motions in<br>
-the ether. Perhaps negative electrification. . .means an excess of<br>
-ether, and positive electrification a defect of ether, as compared with<br>
-the normal density. (W. Larden.)<br>
-<br>
-Electricity is the name given to the supposed agent producing the<br>
-described condition (i. e. electrification) of bodies. (Fleeming<br>
-Jenkin.)<br>
-<br>
-There are certain bodies which, when warm and dry, acquire by friction,<br>
-the property of attracting feathers, filaments of silk or indeed any<br>
-light body towards them. This property is called Electricity, and bodies<br>
-which possess it are said to be electrified. (Linnaeus Cumming.)<br>
-<br>
-What electricity is it is impossible to say, but for the present it is<br>
-convenient to look upon it as a kind of invisible something which<br>
-pervades all bodies. (W. Perren Maycock.)<br>
-<br>
-What is electricity? No one knows. It seems to be one manifestation of<br>
-the energy which fills the universe and which appears in a variety of<br>
-other forms, such as heat, light, magnetism, chemical affinity,<br>
-mechanical motion, etc. (Park Benjamin.)<br>
-<br>
-<br>
-208&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The theory of electricity adopted throughout these lessons is, that<br>
-electricity, whatever its true nature, is one, not two; that this<br>
-Electricity, whatever it may prove to be, is not matter, and is not<br>
-energy; that it resembles both matter and energy in one respect,<br>
-however, in that it can neither be created nor destroyed. (Sylvanus P.<br>
-Thomson.)<br>
-<br>
-In Physics a name denoting the cause of an important class of phenomena<br>
-of attraction and repulsion, chemical decomposition, etc., or,<br>
-collectively, these phenomena themselves. (Century Dictionary.)<br>
-<br>
-A power in nature, often styled the electric fluid, exhibiting itself,<br>
-when in disturbed equilibrium or in activity, by a circuit movement, the<br>
-fact of direction in which involves polarity, or opposition of<br>
-properties in opposite directions; also, by attraction for many<br>
-substances, by a law involving attraction between substances of unlike<br>
-polarity, and repulsion between those of like; by exhibiting accumulated<br>
-polar tension when the circuit is broken; and by producing heat, light,<br>
-concussion, and often chemical changes when the circuit passes between<br>
-the poles, or through any imperfectly conducting substance or space. It<br>
-is evolved in any disturbance of molecular equilibrium, whether from a<br>
-chemical, physical, or mechanical cause. (Webster's Dictionary.)<br>
-<br>
-In point of fact electricity is not a fluid at all, and only in a few of<br>
-its attributes is it at all comparable to a fluid. Let us rather<br>
-consider electricity to be a condition into which material substances<br>
-are thrown. . .(Slingo &amp; Brooker.)<br>
-<br>
-[Transcriber's note: 2008 Dictionary: Phenomena arising from the<br>
-behavior of electrons and protons caused by the attraction of particles<br>
-with opposite charges and the repulsion of particles with the same<br>
-charge.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electricity, Cal.</span><br>
-The electricity produced in the secondary of a transformer by changes of<br>
-temperature in the core. This is in addition to the regularly induced<br>
-current.<br>
-<br>
-Synonym--Acheson Effect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrics.</span><br>
-Substances developing electrification by rubbing or friction; as<br>
-Gilbert, the originator of the term, applied it, it would indicate<br>
-dielectrics. He did not know that, if insulated, any substance was one<br>
-of his "electrics." A piece of copper held by a glass handle becomes<br>
-electrified by friction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrification.</span><br>
-The receiving or imparting an electric charge to a surface; a term<br>
-usually applied to electrostatic phenomena.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrization.</span><br>
-A term in electro-therapeutics; the subjection of the human system to<br>
-electric treatment for curative, tonic or diagnostic purposes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-biology.</span><br>
-The science of electricity in its relation to the living organism,<br>
-whether as electricity is developed by the organism, or as it affects<br>
-the same when applied from an external source.<br>
-<br>
-<br>
-209&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-capillarity.</span><br>
-The relations between surface tension, the potential difference and the<br>
-electrostatic capacity of fluids in contact. Although nominally in<br>
-contact such surfaces are separated by about one-twenty-millionth of a<br>
-centimeter (1/50000000 inch) ; thus a globule of mercury and water in<br>
-which it is immersed constitute an electrostatic accumulator of definite<br>
-electrostatic capacity. Again the mercury and water being in electric<br>
-connection differ in potential by contact (see Contact Theory). A<br>
-definite surface tension is also established. Any change in one of these<br>
-factors changes the other also. A current passed through the contact<br>
-surfaces will change the surface tension and hence the shape of the<br>
-mercury globule. Shaking the globule will change its shape and capacity<br>
-and produce a current. Heating will do the same. (See Electrometer,<br>
-Capillary; and Telephone, Capillary.) Mercury and water are named as<br>
-liquids in which the phenomena are most conveniently observed. They are<br>
-observable in other parallel cases.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-chemical Equivalent.</span><br>
-The quantity of an element or compound liberated from or brought into<br>
-combination, electrolytically, by one coulomb of electricity. The<br>
-electro-chemical equivalent of hydrogen is found by experiment to be<br>
-.0000105 gram. That of any other substance is found by multiplying this<br>
-weight by its chemical equivalent referred to hydrogen, which is its<br>
-atomic or molecular weight divided by its valency. Thus the atomic<br>
-weight of oxygen is 16, its valency is 2, its equivalent is 16/2 = 8;<br>
-its electro-chemical equivalent is equal to .0000105 X 8 = .000840 gram.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-chemical Series.</span><br>
-An arrangement of the elements in the order of their relative electrical<br>
-affinities so that each element is electro-negative to all the elements<br>
-following it, and electro-positive to the elements preceding it. The<br>
-usual series begins with oxygen as the most electro-negative and ends<br>
-with potassium as the most electro-positive element. There is, of<br>
-course, no reason why other series of compound radicals, such as<br>
-sulphion (SO4), etc., should not also be constructed. For each liquid<br>
-acting on substances a separate series of the substances acted on may be<br>
-constructed. Thus for dilute sulphuric acid the series beginning with<br>
-the negatively charged or most attacked one is zinc, amalgamated or<br>
-pure, cadmium, iron, tin, lead, aluminum, nickel, antimony, bismuth,<br>
-copper, silver, platinum. In other liquids the series is altogether<br>
-different.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro--chemistry.</span><br>
-The branch of electricity or of chemistry treating of the relations<br>
-between electric and chemical force in different compounds and<br>
-reactions. (See Electrolysis--Electrochemical series--Electro-chemical<br>
-Equivalent .)<br>
-<br>
-<br>
-210&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-culture.</span><br>
-The application of electricity to the cultivation of plants. In one<br>
-system wires are stretched or carried across the bed under the surface,<br>
-and some are connected to one pole and others to the other pole of a<br>
-galvanic battery of two or more elements. In some experiments improved<br>
-results have thus been obtained.<br>
-<br>
-Another branch refers to the action of the electric arc light on<br>
-vegetation. This has an effect on vegetation varying in results.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrode.</span><br>
-(a) The terminal of an open electric circuit.<br>
-<br>
-(b) The terminals of the metallic or solid conductors of an electric<br>
-circuit, immersed in an electrolytic solution.<br>
-<br>
-(c) The terminals between which a voltaic arc is formed, always in<br>
-practice made of carbon, are termed electrodes.<br>
-<br>
-(d) In electro-therapeutics many different electrodes are used whose<br>
-names are generally descriptive of their shape, character, or uses to<br>
-which they are to be applied. Such are aural electrodes for the ears,<br>
-and many others.<br>
-<br>
-(e) The plates of a voltaic battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrode, Indifferent.</span><br>
-A term in electro-therapeutics. An electrode to which no therapeutic<br>
-action is attributed but which merely provides a second contact with the<br>
-body to complete the circuit through the same. The other electrode is<br>
-termed the therapeutic electrode.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrodes, Erb's Standards of.</span><br>
-Proposed standard sizes for medical electrodes as follows:<br>
-&nbsp;<small><span style="font-family: monospace;">
-Name.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Diameter.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Fine&nbsp;&nbsp;&nbsp;&nbsp; Electrode,&nbsp;&nbsp; 1/2&nbsp;
-centimeter&nbsp;&nbsp; .2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; inch</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Small&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.8&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Medium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7.5&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Large&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-6X2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2.4 X .8&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Very large&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-16x8&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 6.4 x 3.2&nbsp; "</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrodes, Non-polarizable.</span><br>
-In electro-therapeutics electrodes whose contact surface is virtually<br>
-porous clay saturated with zinc chloride solution. The series terminate<br>
-in amalgamated zinc ends, enclosed each in a glass tube, and closed with<br>
-clay. Contact of metal with the tissues is thus avoided.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrode, Therapeutic.</span><br>
-A term in electro-therapeutics. An electrode applied to the body for the<br>
-purpose of inducing therapeutic action, or for giving the basis for an<br>
-electric diagnosis of the case. The other electrode is applied to<br>
-complete the circuit only; it is termed the indifferent electrode.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-diagnosis.</span><br>
-The study of the condition of a patient by the reactions which occur at<br>
-the terminals or kathode and anode of an electric circuit applied to the<br>
-person. The reactions are divided into kathodic and anodic reactions.<br>
-<br>
-<br>
-211&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-dynamic. adj.</span><br>
-The opposite of electrostatic; a qualification of phenomena due to<br>
-current electricity.<br>
-<br>
-Synonym--Electro-kinetic.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-dynamic Attraction and
-Repulsion.</span><br>
-The mutual attraction and repulsion exercised by currents of electricity<br>
-upon each other. The theory of the cause is based upon stress of the<br>
-luminiferous ether and upon the reaction of lines of force upon each<br>
-other. For a resum&eacute; of the theory see Induction,
-Electro-magnetic.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-dynamics.</span><br>
-The laws of electricity in a state of motion; the inter-reaction of<br>
-electric currents. It is distinguished from electro-magnetic induction<br>
-as the latter refers to the production of currents by induction. The<br>
-general laws of electro-dynamics are stated under Induction,<br>
-Electro-magnetic, q. v.<br>
-<br>
-Synonym--Electro-kinetics.<br>
-<br>
-<br>
-<img style="width: 537px; height: 530px;" alt=""
- src="images/211F143.jpg"><br>
-Fig. 143. DIAGRAM OF CONNECTIONS OF <br>
-SIEMENS' ELECTRO-DYNAMOMETER.<br>
-<br>
-<br>
-212&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-dynamometer, Siemens'.</span><br>
-An apparatus for measuring currents by the reaction between two coils,<br>
-one fixed and one movable, through which the current to be measured<br>
-passes. It is one of the oldest commercial ammeters or current<br>
-measurers. It comprises a fixed coil of a number of convolutions and a<br>
-movable coil often of only one convolution surrounding the other. The<br>
-movable coil is suspended by a filament or thread from a spiral spring.<br>
-The spring is the controlling factor. Connection is established through<br>
-mercury cups so as to bring the two coils in series. In use the spring<br>
-and filament are adjusted by turning a milled head to which they are<br>
-connected until the coils are at right angles. Then the current is<br>
-turned on and deflects the movable coil. The milled head is turned until<br>
-the deflection is overcome. The angle through which the head is turned<br>
-is proportional to the square of the current. The movable coil must in<br>
-its position at right angles to the fixed one lie at right angles to the<br>
-magnetic meridian.<br>
-<br>
-Thus in the diagram, Fig. 143 A B C D is the fixed coil; E F G H is the<br>
-movable coil; S is the spiral spring attached at K to the movable coil.<br>
-The arrows show the course of the current as it goes through the coils.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrolier.</span><br>
-A fixture for supporting electric lamps; the analogue in electric<br>
-lighting of the gasolier or gas chandelier. Often both are combined, the<br>
-same fixture being piped and carrying gas burners, as well as being<br>
-wired and carrying electric lamps.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrolysis.</span><br>
-The separation of a chemical compound into its constituent parts or<br>
-elements by the action of the electric current. The compound may be<br>
-decomposed into its elements, as water into hydrogen and oxygen, or into<br>
-constituent radicals, as sodium sulphate into sodium and sulphion, which<br>
-by secondary reactions at once give sodium hydrate and sulphuric acid.<br>
-The decomposition proceeds subject to the laws of electrolysis. (See<br>
-Electrolysis, Laws of.) For decomposition to be produced there is for<br>
-each compound a minimum electro-motive force or potential difference<br>
-required. The current passes through the electrolyte or substance<br>
-undergoing decomposition entirely by Electrolytic Conduction, q. v. in<br>
-accordance with Groth&uuml;ss' Hypothesis, q. v. The electrolyte
-therefore<br>
-must be susceptible of diffusion and must be a fluid.<br>
-<br>
-The general theory holds that under the influence of a potential<br>
-difference between electrodes immersed in an electrolyte, the molecules<br>
-touching the electrodes are polarized, in the opposite sense for each<br>
-electrode. If the potential difference is sufficient the molecules will<br>
-give up one of their binary constituents to the electrode, and the other<br>
-constituent will decompose the adjoining molecule, and that one being<br>
-separated into the same two constituents will decompose its neighbor,<br>
-and so on through the mass until the other electrode is reached. This<br>
-one separates definitely the second binary constituent from the<br>
-molecules touching it.<br>
-<br>
-<br>
-213&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Thus there is an exact balance preserved. Just as many molecules are<br>
-decomposed at one electrode as at the other, and the exact chain of<br>
-decomposition runs through the mass. Each compound electrolyzed develops<br>
-a binary or two-fold composition, and gives up one constituent to one<br>
-electrode and the other to the other.<br>
-<br>
-<br>
-<img style="width: 653px; height: 504px;" alt=""
- src="images/213F144.jpg"><br>
-Fig. 144. ACTION OF MOLECULES IN A SOLUTION<br>
-BEFORE AND DURING ELECTROLYSIS.<br>
-<br>
-<br>
-The cut shows the assumed polarization of an electrolyte. The upper row<br>
-shows the molecules in irregular order before any potential difference<br>
-has been produced, in other words, before the circuit is closed. The<br>
-next row shows the first effects of closing the circuit, and also<br>
-indicates the polarization of the mass, when the potential difference is<br>
-insufficient for decomposition. The third row indicates the<br>
-decomposition of a chain of molecules, one constituent separating at<br>
-each pole.<br>
-<br>
-<br>
-214&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrolysis, Laws of.</span><br>
-The following are the principal laws, originally discovered by<br>
-Faraday, and sometimes called Faraday's Laws of Electrolysis:<br>
-<br>
-1. Electrolysis cannot take place unless the electrolyte is a conductor.<br>
-Conductor here means an electrolytic conductor, one that conducts by its<br>
-own molecules traveling, and being decomposed. (See Groth&uuml;ss'<br>
-Hypothesis.)<br>
-<br>
-II. The energy of the electrolytic action of the current is the same<br>
-wherever exercised in different parts of the circuit.<br>
-<br>
-III. The same quantity of electricity--that is the same current for the<br>
-same period----- decomposes chemically equivalent quantities of the<br>
-bodies it decomposes, or the weights of elements separated in<br>
-electrolytes by the same quantity of electricity (in coulombs or some<br>
-equivalent unit) are to each other as their chemical equivalent.<br>
-<br>
-IV. The quantity of a body decomposed in a given time is proportional to<br>
-the strength of the current.<br>
-<br>
-To these may be added the following:<br>
-<br>
-V. A definite and fixed electro-motive force is required for the<br>
-decomposition of each compound, greater for some and less for others.<br>
-Without sufficient electro-motive force expended on the molecule no<br>
-decomposition will take place. (See Current, Convective.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrolyte.</span><br>
-A body susceptible of decomposition by the electric current, and capable<br>
-of electrolytic conduction. It must be a fluid body and therefore<br>
-capable of diffusion, and composite in composition. An elemental body<br>
-cannot be an electrolyte.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrolytic Analysis.</span><br>
-Chemical analysis by electrolysis. The quantitative separation of a<br>
-number of metals can be very effectively executed. Thus, suppose that a<br>
-solution of copper sulphate was to be analyzed. A measured portion of<br>
-the solution would be introduced into a weighed platinum vessel. The<br>
-vessel would be connected to the zinc plate terminal of a battery. From<br>
-the other terminal of the battery a wire would be brought and would<br>
-terminate in a plate of platinum. This would be immersed in the solution<br>
-in the vessel. As the current would pass the copper sulphate would be<br>
-decomposed and eventually all the copper would be deposited in a firm<br>
-coating on the platinum. The next operations would be to wash the metal<br>
-with distilled water, and eventually with alcohol, to dry and to weigh<br>
-the dish with the adherent copper. On subtracting the weight of the dish<br>
-alone from the weight of the dish and copper, the weight of the metallic<br>
-copper in the solution would be obtained.<br>
-<br>
-In similar ways many other determinations are effected. The processes of<br>
-analysis include solution of the ores or other substances to be analyzed<br>
-and their conversion into proper form for electrolysis. Copper as just<br>
-described can be precipitated from the solution of its sulphate. For<br>
-iron and many other metals solutions of their double alkaline oxalates<br>
-are especially available forms for analysis.<br>
-<br>
-The entire subject has been worked out in considerable detail by<br>
-Classen, to whose works reference should be made for details of<br>
-processes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrolytic Convection.</span><br>
-It is sometimes observed that a single cell of Daniell battery, for<br>
-instance, or other source of electric current establishing too low a<br>
-potential difference for the decomposition of water seems to produce a<br>
-feeble but continuous decomposition. This is very unsatisfactorily<br>
-accounted for by the hydrogen as liberated combining with dissolved<br>
-oxygen. (Ganot.) The whole matter is obscure. (See Current, Convection.)<br>
-<br>
-<br>
-215&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrolytic Conduction.</span><br>
-Conduction by the travel of atoms or radicals from molecule to molecule<br>
-of a substance with eventual setting free at the electrodes of the atoms<br>
-or radicals as elementary molecules or constituent radicals. A substance<br>
-to be capable of acting as an electrolytic conductor must be capable of<br>
-diffusion, and must also have electrolytic conductivity. Such a body is<br>
-called an electrolyte. (See Groth&uuml;ss' Hypothesis--Electrolysis--<br>
-Electrolysis, Laws of--Electro-chemical Equivalent.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet.</span><br>
-A mass, in practice always of iron, around which an electric circuit is<br>
-carried, insulated from the iron. When a current is passed through the<br>
-circuit the iron presents the characteristics of a magnet. (See<br>
-Magnetism, Amp&eacute;re's Theory of--Solenoid--Lines of Force.) In
-general<br>
-terms the action of a circular current is to establish lines of force<br>
-that run through the axis of the circuit approximately parallel thereto,<br>
-and curving out of and over the circuit, return into themselves outside<br>
-of the circuit. If a mass of iron is inserted in the axis or elsewhere<br>
-near such current, it multiplies within itself the lines of force, q. v.<br>
-(See also Magnetic Permeability--Permeance--Magnetic Induction,<br>
-Coefficient of Magnetic Susceptibility--Magnetization, Coefficient of<br>
-Induced.) These lines of force make it a magnet. On their direction,<br>
-which again depends on the direction of the magnetizing current, depends<br>
-the polarity of the iron. The strength of an electro-magnet, below<br>
-saturation of the core (see Magnetic Saturation), is proportional nearly<br>
-to the ampere-turns, q. v. More turns for the same current or more<br>
-current for the same turns increase its strength.<br>
-<br>
-In the cut is shown the general relation of current, coils, core and<br>
-line of force. Assume that the magnet is looked at endwise, the observer<br>
-facing one of the poles; then if the current goes around the core in the<br>
-direction opposite to that of the hands of a clock, such pole will be<br>
-the north pole. If the current is in the direction of the hands of a<br>
-clock the pole facing the observer will be the south pole. The whole<br>
-relation is exactly that of the theoretical Amp&eacute;rian currents,
-already<br>
-explained. The direction and course of the lines of force created are<br>
-shown in the cut.<br>
-<br>
-The shapes of electro-magnets vary greatly. The cuts show several forms<br>
-of electro- magnets. A more usual form is the horseshoe or double limb<br>
-magnet, consisting generally of two straight cores, wound with wire and<br>
-connected and held parallel to each other by a bar across one end, which<br>
-bar is called the yoke.<br>
-<br>
-In winding such a magnet the wire coils must conform, as regards<br>
-direction of the current in them to the rule for polarity already cited.<br>
-If both poles are north or both are south poles, then the magnet cannot<br>
-be termed a horseshoe magnet, but is merely an anomalous magnet. In the<br>
-field magnets of dynamos the most varied types of electro-magnets have<br>
-been used. Consequent poles are often produced in them by the direction<br>
-of the windings and connections.<br>
-<br>
-To obtain the most powerful magnet the iron core should be as short and<br>
-thick as possible in order to diminish the reluctance of the magnetic<br>
-circuit. To obtain a greater range of action a long thin shape is<br>
-better, although it involves waste of energy in its excitation.<br>
-<br>
-<br>
-216&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 743px; height: 384px;" alt=""
- src="images/216F145.jpg"><br>
-Fig. 145 DIAGRAM OF AN ELECTRO-MAGNET SHOWING RELATION OF<br>
-CURRENT AND WINDING TO ITS POLARITY AND LINES OF FORCE.<br>
-<br>
-<br>
-<img style="width: 373px; height: 710px;" alt=""
- src="images/216F146.jpg"><br>
-Fig. 146. ANNULAR ELECTRO-MAGNET<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Annular.</span><br>
-An electro-magnet consisting of a cylinder with a circular groove cut in<br>
-its face, in which groove a coil of insulated wire is placed. On the<br>
-passage of a current the iron becomes polarized and attracts an armature<br>
-towards or against its grooved face. The cut shows the construction of<br>
-an experimental one. It is in practice applied to brakes and clutches.<br>
-In the cut of the electro-magnetic brake (see Brake, Electro-magnetic),<br>
-C is the annular magnet receiving its current through the brushes, and<br>
-pressed when braking action is required against the face of the moving<br>
-wheel. The same arrangement, it can be seen, may apply to a clutch.<br>
-<br>
-<br>
-217&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 551px; height: 358px;" alt=""
- src="images/217F147.jpg"><br>
-Fig. 147. BAR ELECTRO-MAGNET.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-magnet, Bar.</span><br>
-A straight bar of iron surrounded with a magnetizing coil of wire. Bar<br>
-electromagnets are not much used, the horseshoe type being by far the<br>
-more usual.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Club-foot.</span><br>
-An electro-magnet, one of whose legs only is wound with wire, the other<br>
-being bare.<br>
-<br>
-<br>
-<img style="width: 707px; height: 364px;" alt=""
- src="images/217F148.jpg"><br>
-Fig. 148. CLUB-FOOT ELECTRO-MAGNETS WITH HINGED ARMATURES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Hinged.</span><br>
-An electro-magnet whose limbs are hinged at the yoke. On excitation by a<br>
-current the poles tend to approach each other.<br>
-<br>
-<br>
-<img style="width: 521px; height: 330px;" alt=""
- src="images/217F149.jpg"><br>
-Fig. 149. ELECTRO-MAGNET, HINGED<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnetic Attraction and
-Repulsion.</span><br>
-The attraction and repulsion due to electromagnetic lines of force,<br>
-which lines always tend to take as short a course as possible and also<br>
-seek the medium of the highest permeance. This causes them to<br>
-concentrate in iron and steel or other paramagnetic substance and to<br>
-draw them towards a magnet by shortening the lines of force connecting<br>
-the two. It is exactly the same attraction as that of the permanent<br>
-magnet for its armature, Amp&eacute;re's theory bringing the latter
-under the<br>
-same title. In the case of two magnets like poles repel and unlike<br>
-attract. In the case of simple currents, those in the same direction<br>
-attract and those in opposite directions repel each other. This refers<br>
-to constant current reactions. Thus the attraction of unlike poles of<br>
-two magnets is, by the Amp&eacute;rian theory, the attraction of two
-sets of<br>
-currents of similar direction, as is evident from the diagram. The<br>
-repulsion of like poles is the repulsion of unlike currents and the same<br>
-applies to solenoids, q. v. (See Magnetism and do. Amp&eacute;re's
-Theory<br>
-of--Induction, Electro-dynamic--Electro-magnetic Induction.)<br>
-<br>
-<br>
-218&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnetic Control.</span><br>
-Control of a magnet, iron armature, or magnetic needle in a<br>
-galvanometer, ammeter, voltmeter or similar instrument by an<br>
-electro-magnetic field, the restitutive force being derived from an<br>
-electro-magnet. The restitutive force is the force tending to bring the<br>
-index to zero.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnetic Field of Force.</span><br>
-A field of electro-magnetic lines of force, q. v., established through<br>
-the agency of an electric current. A wire carrying a current is<br>
-surrounded by circular concentric lines of force which have the axis of<br>
-the wire as the locus of their centres. Electro-magnets produce lines of<br>
-force identical with those produced by permanent magnets. (See Field of<br>
-Force--Magnetic Field of Force--Controlling Field--Deflecting Field.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnetic Induction.</span><br>
-When two currents of unlike direction are brought towards each other,<br>
-against their natural repulsive tendency work is done, and the<br>
-consequent energy takes the form of a temporary increase in both<br>
-currents. When withdrawn, in compliance with the natural tendency of<br>
-repulsion, the currents are diminished in intensity, because energy is<br>
-not expended on the withdrawal, but the withdrawal is at the expense of<br>
-the energy of the system. The variations thus temporarily produced in<br>
-the currents are examples of electro-magnetic induction. The currents<br>
-have only the duration in each case of the motion of the circuits. One<br>
-circuit is considered as carrying the inducer current and is termed the<br>
-primary circuit and its current the primary current, the others are<br>
-termed the secondary circuit and current respectively. We may assume a<br>
-secondary circuit in which there is no current. It is probable that<br>
-there is always an infinitely small current at least, in every closed<br>
-circuit. Then an approach of the circuits will induce in the secondary<br>
-an instantaneous current in the reverse direction. On separating the two<br>
-circuits a temporary current in the same direction is produced in the<br>
-secondary.<br>
-<br>
-<br>
-219&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-A current is surrounded by lines of force. The approach of two circuits,<br>
-one active, involves a change in the lines of force about the secondary<br>
-circuit. Lines of force and current are so intimately connected that a<br>
-change in one compels a change in the other. Therefore the induced<br>
-current in the secondary may be attributed to the change in the field of<br>
-force in which it lies, a field maintained by the primary circuit and<br>
-current. Any change in a field of force induces a current or change of<br>
-current in any closed circuit in such field, lasting as long as the<br>
-change is taking place. The new current will be of such direction as to<br>
-oppose the change. (See Lenz's Law.)<br>
-<br>
-The action as referred to lines of force may be figured as the cutting<br>
-of such lines by the secondary circuit, and such cutting may be brought<br>
-about by moving the secondary in the field. (See Lines of Force--Field<br>
-of Force.) The cutting of 1E8 lines of force per second by a closed<br>
-circuit induces an electro-motive force of one volt. (See Induction,<br>
-Mutual, Coefficient of.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Iron Clad.</span><br>
-A magnet whose coil and core are encased in a iron jacket, generally<br>
-connected to one end of the core. This gives at one end two poles, one<br>
-tubular, the other solid, and concentric with each other. It is<br>
-sometimes called a tubular magnet.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-magnet, One Coil.</span><br>
-An electro-magnet excited by one coil. In some dynamos the field magnets<br>
-are of this construction, a single coil, situated about midway between<br>
-the poles, producing the excitation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnetic Leakage.</span><br>
-The leakage of lines of force in an electro-magnet; the same as magnetic<br>
-leakage. (See Magnetic Leakage.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-magnetic Lines of Force.</span><br>
-The lines of force produced in an electro-magnetic field. They are<br>
-identical with Magnetic Lines of Force, q. v. (See also Field of<br>
-Force-Line of Force.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnetic Stress.</span><br>
-The stress in an electro-magnetic field of force, showing itself in the<br>
-polarization of light passing through a transparent medium in such a<br>
-field. (See Magnetic Rotary Polarization.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-magnetic Theory of Light.</span><br>
-This theory is due to J. Clark Maxwell, and the recent Hertz experiments<br>
-have gone far to prove it. It holds that the phenomena of light are due<br>
-to ether waves, identical in general factors with those produced by<br>
-electro-magnetic induction of alternating currents acting on the ether.<br>
-In a non-conductor any disturbance sets an ether wave in motion owing to<br>
-its restitutive force; electricity does not travel through such a<br>
-medium, but can create ether waves in it. Therefore a non-conductor of<br>
-electricity is permeable to waves of ether or should transmit light, or<br>
-should be transparent. A conductor on the other hand transmits<br>
-electrical disturbances because it has no restitutive force and cannot<br>
-support an ether wave. Hence a conductor should not transmit light, or<br>
-should be opaque. With few exceptions dielectrics or non-conductors are<br>
-transparent, and conductors are opaque.<br>
-<br>
-<br>
-220&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Again, the relation between the electrostatic and electro-magnet units<br>
-of quantity is expressed by 1 : 30,000,000,000; the latter figure in<br>
-centimeters gives approximately the velocity of light. The<br>
-electro-magnetic unit depending on electricity in motion should have<br>
-this precise relation if an electro-magnetic disturbance was propagated<br>
-with the velocity of light. If an electrically charged body were whirled<br>
-around a magnetic needle with the velocity of light, it should act in<br>
-the same way as a current circulating around it. This effect to some<br>
-extent has been shown experimentally by Rowland.<br>
-<br>
-A consequence of these conclusions is (Maxwell) that the specific<br>
-inductive capacity of a non-conductor or dielectric should be equal to<br>
-the square of its index of refraction for waves of infinite length. This<br>
-is true for some substances--sulphur, turpentine, petroleum and benzole.<br>
-In others the specific inductive capacity is too high, e. g., vegetable<br>
-and animal oils, glass, Iceland spar, fluor spar, and quartz.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-magnetic Unit of Energy.</span><br>
-A rate of transference of energy equal to ten meg-ergs per second.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnetism.</span><br>
-The branch of electrical science treating of the magnetic relations of a<br>
-field of force produced by a current, of the reactions of<br>
-electro-magnetic lines of force, of the electromagnetic field of force,<br>
-of the susceptibility, permeability, and reluctance of diamagnetic and<br>
-paramagnetic substances, and of electro-magnets in general.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Long Range.</span><br>
-An electro-magnet so constructed with extended pole pieces or otherwise,<br>
-as to attract its armature with reasonably constant force over a<br>
-considerable distance. The coil and plunger, q. v., mechanisms<br>
-illustrate one method of getting an extended range of action. When a<br>
-true electro-magnet is used, one with an iron core, only a very limited<br>
-range is attainable at the best. (See Electro-magnet, Stopped Coil--do.<br>
-Plunger.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Plunger.</span><br>
-An electro-magnet with hollow coils, into which the armature enters as a<br>
-plunger. To make it a true electro-magnet it must have either a yoke,<br>
-incomplete core, or some polarized mass of iron.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-magnet, Polarized.</span><br>
-An electro-magnet consisting of a polarized or permanently magnetized<br>
-core wound with magnetizing coils, or with such coils on soft iron cores<br>
-mounted on its ends. The coils may be wound and connected so as to<br>
-cooperate with or work against the permanent magnet on which it is<br>
-mounted. In Hughes' magnet shown in the cut it is mounted in opposition,<br>
-so that an exceedingly feeble current will act to displace the armature,<br>
-a, which is pulled away from the magnet by a spring, s.<br>
-<br>
-<br>
-221&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 473px; height: 576px;" alt=""
- src="images/221F150.jpg"><br>
-Fig. 150 HUGHES' POLARIZED ELECTRO-MAGNET<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electro-magnets, Interlocking.</span><br>
-Electro-magnets so arranged that their armatures interlock. Thus two<br>
-magnets, A A and B B, may be placed with their armatures, M and N, at<br>
-right angles and both normally pulled away from the poles. When the<br>
-armature M is attracted a catch on its end is retained by a hole in the<br>
-end of the other armature N, and when the latter armature N is attracted<br>
-by its magnet the armature M is released. In the mechanism shown in the<br>
-cut the movements of the wheel R are controlled. Normally it is held<br>
-motionless by the catch upon the bottom of the armature M, coming<br>
-against the tooth projecting from its periphery. A momentary current<br>
-through the coils of the magnet A A releases it, by attracting M, which<br>
-is caught and retained by N, and leaves it free to rotate. A momentary<br>
-current through the coils of the magnet B B again releases M, which<br>
-drops down and engages the tooth upon R and arrests its motion.<br>
-<br>
-<br>
-<img style="width: 613px; height: 519px;" alt=""
- src="images/221F151.jpg"><br>
-Fig. 151. INTERLOCKING ELECTRO-MAGNETS.<br>
-<br>
-<br>
-222&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Stopped Coil.</span><br>
-An electro-magnet consisting of a tubular coil, in which a short fixed<br>
-core is contained, stopping up the aperture to a certain distance, while<br>
-the armature is a plunger entering the aperture. This gives a longer<br>
-range of action than usual.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-magnet, Surgical.</span><br>
-An electro-magnet, generally of straight or bar form, fitted with<br>
-different shaped pole pieces, used for the extraction of fragments of<br>
-iron or steel from the eyes. Some very curious cases of successful<br>
-operations on the eyes of workmen, into whose eyes fragments of steel or<br>
-iron had penetrated, are on record.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-medical Baths.</span><br>
-A bath for the person provided with connections and electrodes for<br>
-causing a current of electricity of any desired type to pass through the<br>
-body of the bather. Like all electro-therapeutical treatment, it should<br>
-be administered under the direction of a physician only.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-metallurgy.</span><br>
-(a) In the reduction of ores the electric current has been proposed but<br>
-never extensively used, except in the reduction of aluminum and its<br>
-alloys. (See Reduction of Ores, Electric.)<br>
-<br>
-(b) Electro-plating and deposition of metal from solutions is another<br>
-branch. (See Electroplating and Electrotyping.)<br>
-<br>
-(c) The concentration of iron ores by magnetic attraction may come under<br>
-this head. (See Magnetic Concentration of Ores.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrometer.</span><br>
-An instrument for use in the measurement of potential difference, by the<br>
-attraction or repulsion of statically charged bodies. They are<br>
-distinguished from galvanometers as the latter are really current<br>
-measurers, even if wound for use as voltmeters, depending for their<br>
-action upon the action of the current circulating in their coils.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrometer, Absolute.</span><br>
-An electrometer designed to give directly the value of a charge in<br>
-absolute units. In one form a plate, a b, of conducting surface is<br>
-supported or poised horizontally below a second larger plate C, also of<br>
-conducting surface. The poised plate is surrounded by a detached guard<br>
-ring--an annular or perforated plate, r g r' g'--exactly level and even<br>
-with it as regards the upper surface. The inner plate is carried by a<br>
-delicate balance. In use it is connected to one of the conductors and<br>
-the lower plate to earth or to the other. The attraction between them is<br>
-determined by weighing. By calculation the results can be made absolute,<br>
-as they depend on actual size of the plates and their distance, outside<br>
-of the potential difference of which of course nothing can be said. If S<br>
-is the area of the disc, d the distance of the plates, V-V1 the<br>
-difference of their potential, which is to be measured, and F the force<br>
-required to balance their attraction, we have:<br>
-<br>
-F = ( ( V - V1 )^2 * S )&nbsp; / ( 8 * PI * d^2 )<br>
-<br>
-<br>
-223&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-If&nbsp; V = 0 this reduces to<br>
-<br>
-&nbsp;&nbsp; F =&nbsp; ( V^2 * S ) / ( 8 * PI * d^2 )&nbsp; (2)<br>
-&nbsp; or<br>
-&nbsp; V =&nbsp; d * SquareRoot( (8 * PI * F ) / S )&nbsp;&nbsp; (3)<br>
-<br>
-As F is expressed as a weight, and S and a as measures of area and<br>
-length, this gives a means of directly obtaining potential values in<br>
-absolute measure. (See Idiostatic Method--Heterostatic Method.)<br>
-<br>
-Synonyms--Attracted Disc Electrometer--Weight Electrometer.<br>
-<br>
-<br>
-<img style="width: 664px; height: 252px;" alt=""
- src="images/223F152.jpg"><br>
-Fig. 152. SECTION OF BASE OF PORTABLE ELECTROMETER.<br>
-<br>
-<br>
-In some forms the movable disc is above the other, and supported at the<br>
-end of a balance beam. In others a spring support, arranged so as to<br>
-enable the attraction to be determined in weight units, is adopted. The<br>
-cuts, Figs. 152 and 154, show one of the latter type, the portable<br>
-electrometer. The disc portion is contained within a cylindrical vessel.<br>
-<br>
-<br>
-<img style="width: 660px; height: 279px;" alt=""
- src="images/223F153.jpg"><br>
-Fig. 153. DIAGRAM ILLUSTRATING <br>
-THEORY OF ABSOLUTE ELECTROMETER.<br>
-<br>
-<br>
-Referring to Fig. 152&nbsp; g is the stationary disc, charged through
-the<br>
-wire connection r; f is the movable disc, carried by a balance beam<br>
-poised at i on a horizontal and transverse stretched platinum wire,<br>
-acting as a torsional spring. The position of the end k of the balance<br>
-beam shows when the disc f is in the plane of the guard ring h h. The<br>
-end k is forked horizontally and a horizontal sighting wire or hair is<br>
-fastened across the opening of the fork. When the hair is midway between<br>
-two dots on a vertical scale the lever is in the sighted position, as it<br>
-is called, and the disc is in the plane of the guard ring.<br>
-<br>
-<br>
-224&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 425px; height: 604px;" alt=""
- src="images/224F154.jpg"><br>
-Fig. 154. PORTABLE ELECTROMETER.<br>
-<br>
-<br>
-The general construction is seen in Fig. 154. There the fixed disc D is<br>
-carried by insulating stem g1. The charging electrode is supported by an<br>
-insulating stem g2, and without contact with the box passes out of its<br>
-cover through a guard tube E, with cover, sometimes called umbrella, V.<br>
-The umbrella is to protect the apparatus from air currents. At m is the<br>
-sighting lens. H is a lead box packed with pumice stone, moistened with<br>
-oil of vitriol or concentrated sulphuric acid, to preserve the<br>
-atmosphere dry. Before use the acid is boiled with some ammonium<br>
-sulphate to expel any corrosive nitrogen oxides, which might corrode the<br>
-brass.<br>
-<br>
-In use the upper disc is charged by its insulated electrode within the<br>
-tube E; the movable disc is charged if desired directly through the case<br>
-of the instrument. The upper disc is screwed up or down by the<br>
-micrometer head M, until the sighted position is reached. The readings<br>
-of the micrometer on the top of the case give the data for calculation.<br>
-<br>
-<br>
-225&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 642px; height: 668px;" alt=""
- src="images/225F155.jpg"><br>
-Fig. 155. LIPPMAN'S CAPILLARY ELECTROMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electrometer, Capillary.</span><br>
-An electrometer for measuring potential difference by capillary action,<br>
-which latter is affected by electrostatic excitement. A tube A contains<br>
-mercury; its end drawn out to a fine aperture dips into a vessel B which<br>
-contains dilute sulphuric acid with mercury under it, as shown. Wires<br>
-running from the binding-posts a and b connect one with the mercury in<br>
-A, the other with that in B. The upper end of the tube A connects with a<br>
-thick rubber mercury reservoir T, and manometer H. The surface tension<br>
-of the mercury-acid film at the lower end of the tube A keeps all in<br>
-equilibrium. If now a potential difference is established between a and<br>
-b, as by connecting a battery thereto, the surface tension is increased<br>
-and the mercury rises in the tube B. By screwing down the compressing<br>
-clamp E, the mercury is brought back to its original position. The<br>
-microscope M is used to determine this position with accuracy. The<br>
-change in reading of the manometer gives the relation of change of<br>
-surface tension and therefore of potential. Each electrometer needs<br>
-special graduation or calibration, but is exceedingly sensitive and<br>
-accurate. It cannot be used for greater potential differences than .6<br>
-volt, but can measure .0006 volt. Its electrostatic capacity is so small<br>
-that it can indicate rapid changes. Another form indicates potential<br>
-difference by the movement of a drop of sulphuric acid in a horizontal<br>
-glass tube, otherwise filled with mercury, and whose ends lead into two<br>
-mercury cups or reservoirs. The pair of electrodes to be tested are<br>
-connected to the mercury vessels. The drop moves towards the negative<br>
-pole, and its movement for small potential differences (less than one<br>
-volt) is proportional to the electro-motive force or potential<br>
-difference.<br>
-<br>
-<br>
-226&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrometer Gauge.</span><br>
-An absolute electrometer (see Electrometer, Absolute) forming an<br>
-attachment to a Thomson quadrant electrometer. It is used to test the<br>
-potential of the flat needle connected with the inner surface of the<br>
-Leyden jar condenser of the apparatus. This it does by measuring the<br>
-attraction between itself and an attracting disc, the latter connected<br>
-by a conductor with the interior of the jar.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrometer, Lane's.</span><br>
-A Leyden jar with mounted discharger, so that when charged to a certain<br>
-point it discharges itself. It is connected with one coating of any jar<br>
-whose charge is to be measured, which jar is then charged by the other<br>
-coating. As the jar under trial becomes charged to a certain point the<br>
-electrometer jar discharges itself, and the number of discharges is the<br>
-measure of the charge of the other jar. It is really a unit jar, q. v.<br>
-<br>
-<br>
-<img style="width: 433px; height: 612px;" alt=""
- src="images/226F156.jpg"><br>
-Fig. 156. THOMSON'S QUADRANT ELECTROMETER.<br>
-<br>
-<br>
-<img style="width: 508px; height: 522px;" alt=""
- src="images/226F157.jpg"><br>
-Fig. 157. HENLEY'S QUADRANT ELECTROSCOPE.<br>
-<br>
-<br>
-227&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrometer, Quadrant.</span><br>
-(a) Sir William Thomson's electrometer, a simple form of which is shown<br>
-in the cut, consists of four quadrants of metal placed horizontally;<br>
-above these a broad flat aluminum needle hangs by a very fine wire,<br>
-acting as torsional suspension. The quadrants are insulated from each<br>
-other, but the opposite ones connect with each other by wires. The<br>
-apparatus is adjusted so that, when the quadrants are in an unexcited<br>
-condition the needle is at rest over one of the diametrical divisions<br>
-between quadrants. The needle by its suspension wire is in communication<br>
-with the interior of a Leyden jar which is charged. The whole is covered<br>
-with a glass shade, and the air within is kept dry by a dish of<br>
-concentrated sulphuric acid so that the jar retains its charge for a<br>
-long time and keeps the needle at approximately a constant potential. If<br>
-now two pairs of quadrants are excited with opposite electricities, as<br>
-when connected with the opposite poles of an insulated galvanic cell,<br>
-the needle is repelled by one pair and attracted by the other, and<br>
-therefore rotates through an arc of greater or less extent. A small<br>
-concave mirror is attached above the needle and its image is reflected<br>
-on a graduated screen. This makes the smallest movement visible.<br>
-Sometimes the quadrants are double, forming almost a complete box,<br>
-within which the needle moves.<br>
-<br>
-(b) Henley's quadrant electrometer is for use on the prime conductor of<br>
-an electric machine, for roughly indicating the relative potential<br>
-thereof. It consists of a wooden standard attached perpendicularly to<br>
-the conductor. Near one end is attached a semi-circular or quadrant arc<br>
-of a circle graduated into degrees or angular divisions. An index,<br>
-consisting of a straw with a pith-bell attached to its end hangs from<br>
-the center of curvature of the arc. When the prime conductor is charged<br>
-the index moves up over the scale and its extent of motion indicates the<br>
-potential relatively.<br>
-<br>
-When the "quadrant electrometer" is spoken of it may always be assumed<br>
-that Sir William Thomson's instrument is alluded to. Henley's instrument<br>
-is properly termed a quadrant electroscope. (See Electroscope.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-motive Force.</span><br>
-The cause which produces currents of electricity. In general it can be<br>
-expressed in difference of potentials, although the term electro-motive<br>
-force should be restricted to potential difference causing a current. It<br>
-is often a sustained charging of the generator terminals whence the<br>
-current is taken. Its dimensions are<br>
-<br>
-(work done/the quantity of electricity involved),<br>
-<br>
-or ( M * (L^2) /(T^2 ) ) / ((M^.5) * (L^.5)) = ( (M^.5) * (L^1.5) )
-/(T^2)<br>
-<br>
-The practical unit of electro-motive force is the volt, q. v. It is<br>
-often expressed in abbreviated form, as E. M. D. P., or simply as D. P.,<br>
-i. e., potential difference.<br>
-<br>
-Electro-motive force and potential difference are in many cases<br>
-virtually identical, and distinctions drawn between them vary with<br>
-different authors. If we consider a closed electric circuit carrying a<br>
-current, a definite electro-motive force determined by Ohm's law from<br>
-the resistance and current obtains in it. But if we attempt to define<br>
-potential difference as proper to the circuit we may quite fail.<br>
-Potential difference in a circuit is the difference in potential between<br>
-defined points of such circuit. But no points in a closed circuit can be<br>
-found which differ in potential by an amount equal to the entire<br>
-electro-motive force of the circuit. Potential difference is properly<br>
-the measure of electro-motive force expended on the portion of a circuit<br>
-between any given points. Electro-motive force of an entire circuit, as<br>
-it is measured, as it were, between two consecutive points but around<br>
-the long portion of the circuit, is not conceivable as merely potential<br>
-difference. Taking the circle divided in to degrees as an analogy, the<br>
-electro-motive force of the entire circuit might be expressed as
-360&ordm;,<br>
-which are the degrees intervening between two consecutive points,<br>
-measured the long way around the circle. But the potential difference<br>
-between the same two points would be only 1&ordm;, for it would be
-measured<br>
-by the nearest path.<br>
-<br>
-[Transcriber's notes: If 360&ordm; is the "long" way, 0&ordm; is the
-"short". A<br>
-formal restatement of the above definition of EMF: "If a charge Q passes<br>
-through a device and gains energy U, the net EMF for that device is the<br>
-energy gained per unit charge, or U/Q. The unit of EMF is a volt, or<br>
-newton-meter per coulomb."]<br>
-<br>
-<br>
-228&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-motive Force, Counter.</span><br>
-A current going through a circuit often has not only true or ohmic<br>
-resistance to overcome, but meets an opposing E. M. F. This is termed<br>
-counter-electro-motive force. It is often treated in calculations as<br>
-resistance, and is termed spurious resistance. It may be a part of the<br>
-impedance of a circuit.<br>
-<br>
-In a primary battery hydrogen accumulating on the negative plate<br>
-develops counter E. M. F. In the voltaic arc the differential heating of<br>
-the two carbons does the same. The storage battery is changed by a<br>
-current passing in the opposite direction to its own natural current;<br>
-the polarity of such a battery is counter E. M. F.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-motive Force, Unit.</span><br>
-Unit electro-motive force is that which is created in a conductor moving<br>
-through a magnetic field at such a rate as to cut one unit line of force<br>
-per second. It is that which must be maintained in a circuit of unit<br>
-resistance to maintain a current of unit quantity therein. It is that<br>
-which must be maintained between the ends of a conductor in order that<br>
-unit current may do unit work in a second.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-motive Intensity.</span><br>
-The force acting upon a unit charge of electricity. The mean force is<br>
-equal to the difference of potential between two points within the field<br>
-situated one centimeter apart, such distance being measured along the<br>
-lines of force. The term is due to J. Clerk Maxwell.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-motive Series.</span><br>
-Arrangement of the metals and carbon in series with the most<br>
-electro-positive at one end, and electronegative at the other end. The<br>
-following are examples for different exciting liquids:<br>
-<br>
-<small><span style="font-family: monospace;">Dilute
-Sulphuric&nbsp;&nbsp; Dilute Hydrochloric&nbsp;&nbsp;
-Caustic&nbsp;&nbsp; Potassium</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Acid&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Acid.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Potash.&nbsp;&nbsp; Sulphide.</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">Zinc&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Zinc&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Zinc&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Zinc</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Cadmium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Cadmium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Tin&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Copper</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Tin&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Tin&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Cadmium&nbsp;&nbsp; Cadmium</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Lead&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Lead&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Antimony&nbsp; Tin</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Iron&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Iron&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Lead&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Silver</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Nickel&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Copper&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Bismuth&nbsp;&nbsp; Antimony</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Bismuth&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Bismuth&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Iron&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Lead</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Antimony&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Nickel&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Copper&nbsp;&nbsp;&nbsp; Bismuth</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Copper&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Silver&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Nickel&nbsp;&nbsp;&nbsp; Nickel</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Silver&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Antimony&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Silver&nbsp;&nbsp;&nbsp; Iron</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Gold</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Platinum</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Carbon</span></small>
-<br>
-<br>
-In each series the upper metal is the positive, dissolved or attacked<br>
-element.<br>
-<br>
-<br>
-229&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-motograph.</span><br>
-An invention of Thomas A. Edison. A cylinder of chalk, moistened with<br>
-solution of caustic soda, is mounted so as to be rotated by a handle. A<br>
-diaphragm has an arm connected to its center. This arm is pressed<br>
-against the surface of the cylinder by a spring. When the cylinder is<br>
-rotated, a constant tension is exerted on the diaphragm. If a current is<br>
-passed through the junction of arm and cylinder the electrolytic action<br>
-alters the friction so as to change the stress upon the diaphragm.<br>
-<br>
-If the current producing this effect is of the type produced by the<br>
-human voice through a microphone the successive variations in strain<br>
-upon the diaphragm will cause it to emit articulate sounds. These are<br>
-produced directly by the movement of the cylinder, the electrolytic<br>
-action being rather the regulating portion of the operation. Hence very<br>
-loud sounds can be produced by it. This has given it the name of the<br>
-loud- speaking telephone.<br>
-<br>
-The same principle may be applied in other ways. But the practical<br>
-application of the motograph is in the telephone described.<br>
-<br>
-<br>
-<img style="width: 432px; height: 680px;" alt=""
- src="images/229F158.jpg"><br>
-Fig. 158. ELECTRO-MOTOGRAPH TELEPHONE<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-motor.</span><br>
-This term is sometimes applied to a current generator, such as a voltaic<br>
-battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-muscular Excitation.</span><br>
-A term in medical electricity indicating the excitation of muscle as the<br>
-effect of electric currents of any kind.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-negative. adj.</span><br>
-Appertaining to negative electrification; thus of the elements oxygen is<br>
-the most electro-negative, because if separated by electrolytic action<br>
-from any combination, it will be charged with negative electricity.<br>
-<br>
-<br>
-230&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-optics.</span><br>
-The branch of natural science treating of the relations between light<br>
-and electricity. Both are supposed to be phenomena of or due to the<br>
-luminiferous ether. To it may be referred the following:<br>
-<br>
-(a) Electro-magnetic Stress and Magnetic Rotary Polarization;<br>
-<br>
-(b) Dielectric Strain; all of which may be referred to in this book;<br>
-<br>
-(c) Change in the resistance of a conductor by changes in light to which<br>
-it is exposed (see Selenium);<br>
-<br>
-(d) The relation of the index of refraction of a dielectric to the<br>
-dielectric constant (see Electro-magnetic Theory of Light);<br>
-<br>
-(e) The identity (approximate) of the velocity of light in centimeters<br>
-and the relative values of the electrostatic and electro-magnet units<br>
-of intensity, the latter being 30,000,000,000 times greater than the<br>
-former, while the velocity of light is 30,000,000,000 centimeters per<br>
-second.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electrophoric Action.</span><br>
-The action of an electrophorous; utilized in influence machines. (See<br>
-Electrophorous.)<br>
-<br>
-<br>
-<img style="width: 631px; height: 500px;" alt=""
- src="images/230F159.jpg"><br>
-Fig. 159. ELECTROPHOROUS.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electrophorous.</span><br>
-An apparatus for the production of electric charges of high potential by<br>
-electrostatic induction, q. v. It consists of a disc of insulating<br>
-material B, such as resin or gutta percha, which is held in a shallow<br>
-metal-lined box or form. The disc may be half an inch thick and a foot<br>
-or more in diameter, or may be much smaller and thinner. A metal disc A,<br>
-smaller in diameter is provided with an insulating handle which may be<br>
-of glass, or simply silk suspension strings. To use it the disc B is<br>
-excited by friction with a cat-skin or other suitable substance. The<br>
-metallic disc is then placed on the cake of resin exactly in its centre,<br>
-so that the latter disc or cake projects on all sides. Owing to<br>
-roughness there is little real electric contact between the metal and<br>
-dielectric. On touching the metal disc a quantity of negative<br>
-electricity escapes to the earth. On raising it from the cake it comes<br>
-off excited positively, and gives a spark and is discharged. It can be<br>
-replaced, touched, removed and another spark can be taken from it, and<br>
-so on as long as the cake stays charged.<br>
-<br>
-The successive discharges represent electrical energy expended. This is<br>
-derived from the muscular energy expended by the operator in separating<br>
-the two discs when oppositely excited. As generally used it is therefore<br>
-an apparatus for converting muscular or mechanical energy into electric<br>
-energy.<br>
-<br>
-<br>
-231&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-physiology.</span><br>
-The science of the electric phenomena of the animal system. It may also<br>
-be extended to include plants. The great discovery of Galvani with the<br>
-frog's body fell into this branch of science. The electric fishes,<br>
-gymnotus, etc., present intense phenomena in the same.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electroplating.</span><br>
-The deposition by electrolysis of a coating of metal upon a conducting<br>
-surface. The simplest system makes the object to be plated the negative<br>
-electrode or plate in a galvanic couple. Thus a spoon or other object<br>
-may be connected by a wire to a plate of zinc. A porous cup is placed<br>
-inside a battery jar. The spoon is placed in the porous cup and the zinc<br>
-outside it. A solution of copper sulphate is placed in the porous cup,<br>
-and water with a little sodium or zinc sulphate dissolved in it,<br>
-outside. A current starts through the couple, and copper is deposited on<br>
-the spoon.<br>
-<br>
-A less primitive way is to use a separate battery as the source of<br>
-current; to connect to the positive plate by a wire the object to be<br>
-plated, and a plate of copper, silver, nickel or other metal to the<br>
-other pole of the battery. On immersing both object and plate (anode) in<br>
-a bath of proper solution the object will become plated.<br>
-<br>
-In general the anode is of the same material as the metal to be<br>
-deposited, and dissolving keeps up the strength of the bath. There are a<br>
-great many points of technicality involved which cannot be given here.<br>
-The surface of the immersed object must be conductive. If not a fine<br>
-wire network stretched over it will gradually fill up in the bath and<br>
-give a matrix. More generally the surface is made conductive by being<br>
-brushed over with plumbago. This may be followed by a dusting of iron<br>
-dust, followed by immersion in solution ot copper sulphate. This has the<br>
-effect of depositing metallic copper over the surface as a starter for<br>
-the final coat.<br>
-<br>
-Attention must be paid to the perfect cleanliness of the objects, to the<br>
-condition of the bath, purity of anodes and current density.<br>
-<br>
-Voltaic batteries are largely used for the current as well as special<br>
-low resistance dynamos. Thermo-electric batteries are also used to some<br>
-extent but not generally.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-pneumatic Signals.</span><br>
-Signals, such as railroad signals or semaphores, moved by compressed<br>
-air, which is controlled by valves operated by electricity. The House<br>
-telegraph, which was worked by air controlled by electricity, might come<br>
-under this term, but it is always understood as applied to railroad<br>
-signals, or their equivalent.<br>
-<br>
-<br>
-232&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electropoion Fluid.</span><br>
-An acid depolarizing solution for use in zinc-carbon couples, such as<br>
-the Grenet battery. The following are formulae for its preparation:<br>
-<br>
-(a) Dissolve one pound of potassium bichromate in ten pounds of water,<br>
-to which two and one-half pounds of concentrated sulphuric acid have<br>
-been gradually added. The better way is to use powdered potassium<br>
-bichromate, add it to the water first, and then gradually add the<br>
-sulphuric acid with constant stirring.<br>
-<br>
-(b) To three pints of water add five fluid ounces of concentrated<br>
-sulphuric acid; add six ounces pulverized potassium bichromate.<br>
-<br>
-(c) Mix one gallon concentrated sulphuric acid and three gallons of<br>
-water. In a separate vessel dissolve six pounds potassium bichromate in<br>
-two gallons of boiling water. Mix the two.<br>
-<br>
-The last is the best formula. Always use electropoion fluid cold. (See<br>
-Trouv&eacute;'s Solution--Poggendorff's Solution--Kakogey's Solution--<br>
-Tissandrier's Solution--Chutaux's Solution.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-positive. adj.</span><br>
-Appertaining to positive electrification; thus potassium is the most<br>
-electro-positive of the elements. (See Electro-negative.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-puncture.</span><br>
-The introduction into the system of a platinum point or needle,<br>
-insulated with vulcanite, except near its point, and connected as the<br>
-anode of a galvanic battery. The kathode is a metal one, covered with a<br>
-wet sponge and applied on the surface near the place of puncture. It is<br>
-used for treatment of aneurisms or diseased growths, and also for<br>
-removal of hair by electrolysis. (See Hair, Removal of by Electrolysis.)<br>
-<br>
-Synonym--Galvano-puncture.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-receptive. adj.</span><br>
-A term applied to any device or apparatus designed to receive and absorb<br>
-electric energy. A motor is an example of an electro-receptive<br>
-mechanism.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electroscope.</span><br>
-An apparatus for indicating the presence of an electric charge, and also<br>
-for determining the sign, or whether the charge is positive or negative.<br>
-The simplest form consists of a thread doubled at its centre and hung<br>
-therefrom. On being charged, or on being connected to a charged body the<br>
-threads diverge. A pair of pith balls may be suspended in a similar way,<br>
-or a couple of strips of gold leaf within a flask (the gold leaf<br>
-electroscope). To use an electroscope to determine the sign of the<br>
-charge it is first slightly charged. The body to be tested is then<br>
-applied to the point of suspension, or other charging point. If at once<br>
-further repelled the charge of the body is of the same sign as the<br>
-slight charge first imparted to the electroscope leaves; the leaves as<br>
-they become more excited will at once diverge more. If of different sign<br>
-they will at first approach as their charge is neutralized and will<br>
-afterwards diverge.<br>
-<br>
-The gold-leaf electroscope is generally enclosed in a glass bell jar or<br>
-flask. Sometimes a pair of posts rise, one on each side, to supply<br>
-points of induction from the earth to intensify the action. (See<br>
-Electrometer, Quadrant--Electroscope, Gold leaf, and others.)<br>
-<br>
-<br>
-233&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electroscope, Bennett's.</span><br>
-A gold-leaf electroscope, the suspended leaves of which are contained in<br>
-a glass shade or vessel of dry air. On the inside of the glass shade are<br>
-two strips of gold leaf, which rise from the lower edge a short<br>
-distance, being pasted to the glass, and connected to the ground. These<br>
-act by induction to increase the sensitiveness of the instruments.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electroscope, Bohenberger's.</span><br>
-A condensing electroscope (see Electroscope, Condensing) with a single<br>
-strip of gold leaf suspended within the glass bell. This is at an equal<br>
-distance from the opposite poles of two dry piles (see Zamboni's Dry<br>
-Pile) standing on end, one on each side of it. As soon as the leaf is<br>
-excited it moves toward one and away from the other pile, and the sign<br>
-of its electrification is shown by the direction of its motion.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electroscope, Condensing.</span><br>
-A gold leaf electroscope, the glass bell of which is surmounted by an<br>
-electrophorous or static condenser, to the lower plate of which the<br>
-leaves of gold are suspended or connected.<br>
-<br>
-In use the object to be tested is touched to the lower plate, and the<br>
-upper plate at the same time is touched by the finger. The plates are<br>
-now separated. This reduces the capacity of the lower plate greatly and<br>
-its charge acquires sufficient potential to affect the leaves, although<br>
-the simple touching may not have affected them at all.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electroscope, Gold Leaf.</span><br>
-An electroscope consisting of two leaves of gold leaf hung in contact<br>
-with each other from the end of a conductor. When excited they diverge.<br>
-The leaves are enclosed in a glass vessel.<br>
-<br>
-<br>
-<img style="width: 350px; height: 718px;" alt=""
- src="images/233F160.jpg"><br>
-Fig. 160. GOLD LEAF ELECTROSCOPE.<br>
-<br>
-<br>
-234&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electroscope, Pith Ball.</span><br>
-Two pith balls suspended at opposite ends of a silk thread doubled in<br>
-the middle. When charged with like electricity they repel each other.<br>
-The extent of their repulsion indicates the potential of their charge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrostatic Attraction and Repulsion.</span><br>
-The attraction and repulsion of electrostatically charged bodies for<br>
-each other, shown when charged with electricity. If charged with<br>
-electricity of the same sign they repel each other. If with opposite<br>
-they attract each other. The classic attraction and subsequent repulsion<br>
-of bits of straw and chaff by the excited piece of amber is a case of<br>
-electrostatic attraction and repulsion. (See Electricity,<br>
-Static--Electrostatics--Coulomb's Laws of Electrostatic Attraction and<br>
-Repulsion.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electrostatic Induction, Coefficient
-of.</span><br>
-The coefficient expressing the ratio of the charge or change of charge<br>
-developed in one body to the potential of the inducing body.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Electrostatic Lines of Force.</span><br>
-Lines of force assumed to exist in an electrostatic field of force, and<br>
-to constitute the same. In general they correspond in action and<br>
-attributes with elcctro-magnetic lines of force. They involve in almost<br>
-all cases either a continuous circuit, or a termination at both ends in<br>
-oppositely charged surfaces.<br>
-<br>
-<br>
-<img style="width: 624px; height: 124px;" alt=""
- src="images/234F161.jpg"><br>
-Fig. 161. ELECTROSTATIC LINES OF FORCE <br>
-BETWEEN NEAR SURFACES.<br>
-<br>
-<br>
-<img style="width: 650px; height: 399px;" alt=""
- src="images/234F162.jpg"><br>
-Fig. 162. ELECTROSTATIC LINKS OF FORCE <br>
-BETWEEN DISTANT SURFACES.<br>
-<br>
-<br>
-235&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The cut, Fig. 161, shows the general course taken by lines of force<br>
-between two excited surfaces when near together. Here most of them are<br>
-straight lines reaching straight across from surface to surface, while a<br>
-few of them arch across from near the edges, tending to spread. If the<br>
-bodies are drawn apart the spreading tendency increases and the<br>
-condition of things shown in the next cut, Fig. 162, obtains. There is<br>
-an axial line whose prolongations may be supposed to extend<br>
-indefinitely, as occupying a position of unstable equilibrium. Here the<br>
-existence of a straight and unterminated line of force may be assumed.<br>
-<br>
-A direction is predicated to lines of force corresponding with the<br>
-direction of an electric current. They are assumed to start from a<br>
-positively charged and to go towards a negatively charged surface. A<br>
-positively charged body placed in an electrostatic field of force will<br>
-be repelled from the region of positive into or towards the region of<br>
-negative potential following the direction of the lines of force, not<br>
-moving transversely to them, and having no transverse component in its<br>
-motion.<br>
-<br>
-[Transcriber's note: More precisely, "A positively charged body placed<br>
-in an electrostatic field of force will be repelled from the region of<br>
-positive into or towards the region of negative potential ACCELERATING<br>
-in the direction of the lines of force, not ACCELERATING transversely to<br>
-them, and having no transverse component in its ACCELERATION."<br>
-Previously acquired momentum can produce a transverse component of<br>
-VELOCITY.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrostatics.</span><br>
-The division of electric science treating of the phenomena of electric<br>
-charge, or of electricity in repose, as contrasted with electro-dynamics<br>
-or electricity in motion or in current form. Charges of like sign repel,<br>
-and of unlike sign attract each other. The general inductive action is<br>
-explained by the use of the electrostatic field of force and<br>
-electrostatic lines of force, q. v. The force of attraction and<br>
-repulsion of small bodies or virtual points, which are near enough to<br>
-each other, vary as the square of the distance nearly, and with the<br>
-product of the quantities of the charges of the two bodies.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrostatic Refraction.</span><br>
-Dr. Kerr found that certain dielectrics exposed to electric strain by<br>
-being placed between two oppositely excited poles of a Holtz machine or<br>
-other source of very high tension possess double refracting powers, in<br>
-other words can rotate a beam of polarized light, or can develop two<br>
-complimentary beams from common light. Bisulphide of carbon shows the<br>
-phenomenon well, acting as glass would if the glass were stretched in<br>
-the direction of the electrostatic lines of force. To try it with glass,<br>
-holes are drilled in a plate and wires from an influence machine are<br>
-inserted therein. The discharge being maintained through the glass it<br>
-polarizes light.<br>
-<br>
-Synonym--Kerr Effect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrostatic Series.</span><br>
-A table of substances arranged in the order in which they are<br>
-electrostatically charged by contact, generally by rubbing against each<br>
-other. The following series is due to Faraday. The first members become<br>
-positively excited when rubbed with any of the following members, and<br>
-vice versa. The first elements correspond to the carbon plate in a<br>
-galvanic battery, the succeeding elements to the zinc plate.<br>
-<br>
-Cat, and Bear-skin--Flannel--Ivory--Feathers--Rock Crystal--Flint<br>
-Glass--Cotton--Linen--Canvas--White Silk--the Hand--Wood--Shellac--the<br>
-Metals (Iron-Copper-Brass-Tin-Silver-Platinum)--Sulphur. There are some<br>
-irregularities. A feather lightly drawn over canvas is negatively<br>
-electrified; if drawn through folds pressed against it it is positively<br>
-excited. Many other exceptions exist, so that the table is of little<br>
-value.<br>
-<br>
-<br>
-236&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrostatic Stress.</span><br>
-The stress produced upon a transparent medium in an electrostatic field<br>
-of force by which it acquires double refracting or polarizing properties<br>
-as regards the action of such medium upon light. (See Electrostatic<br>
-Refraction.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electro-therapeutics or Therapy.</span><br>
-The science treating of the effects of electricity upon the animal<br>
-system in the treatment and diagnosis of disease.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrotonus.</span><br>
-An altered condition of functional activity occurring in a nerve<br>
-subjected to the passage of an electric current. If the activity is<br>
-decreased, which occurs near the anode, the state is one of<br>
-anelectrotonus, if the activity is increased which occurs near the<br>
-kathode the condition is one of kathelectrotonus.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Electrotype.</span><br>
-The reproduction of a form of type or of an engraving or of the like by<br>
-electroplating, for printing purposes. The form of type is pressed upon<br>
-a surface of wax contained in a shallow box. The wax is mixed with<br>
-plumbago, and if necessary some more is dusted and brushed over its<br>
-surface and some iron dust is sprinkled over it also. A matrix or<br>
-impression of the type is thus obtained, on which copper is deposited by<br>
-electroplating, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Element, Chemical.</span><br>
-The original forms of matter that cannot be separated into constituents<br>
-by any known process. They are about seventy in number. Some of the<br>
-rarer ones are being added to or cancelled with the progress of chemical<br>
-discovery. For their electric relations see Electro-chemical<br>
-Equivalents--Electro-chemical Series.<br>
-<br>
-The elements in entering into combination satisfy chemical affinity and<br>
-liberate energy, which may take the form of electric energy as in the<br>
-galvanic battery, or of heat energy, as in the combustion of carbon or<br>
-magnesium. Therefore an uncombined element is the seat of potential<br>
-energy. (See Energy, Potential.) In combining the elements always<br>
-combine in definite proportions. A series of numbers, one being proper<br>
-to each element which denote the smallest common multipliers of these<br>
-proportions, are called equivalents. Taking the theory of valency into<br>
-consideration the product of the equivalents by the valencies gives the<br>
-atomic weights.<br>
-<br>
-<br>
-237&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Element, Mathematical.</span><br>
-A very small part of anything, corresponding in a general way to a<br>
-differential, as the element of a current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Element of a Battery Cell.</span><br>
-The plates in a galvanic couple are termed elements, as the carbon and<br>
-zinc plates in a Bunsen cell. The plate unattacked by the solution, as<br>
-the carbon plate in the above battery, is termed the negative plate or<br>
-element; the one attacked, as the zinc plate, is termed the positive<br>
-plate or element.<br>
-<br>
-Synonym--Voltaic Element.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Elements, Electrical Classification of.</span><br>
-This may refer to Electro-chemical Series, Electrostatic Series, or<br>
-Thermo-electric Series, all of which may be referred to.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Element, Thermo-electric.</span><br>
-One of the metals or other conductors making a thermo-electric couple,<br>
-the heating of whose junction produces electro-motive force and a<br>
-current, if on closed circuit. The elements of a couple are respectively<br>
-positive and negative, and most conductors can be arranged in a series<br>
-according to their relative polarity. (See Thermo-electric Series.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Elongation.</span><br>
-The throw of the magnetic needle. (See Throw.)<br>
-<br>
-Synonym--Throw.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Embosser, Telegraph.</span><br>
-A telegraphic receiver giving raised characters on a piece of paper. It<br>
-generally refers to an apparatus of the old Morse receiver type, one<br>
-using a dry point stylus, which pressing the paper into a groove in the<br>
-roller above the paper, gave raised characters in dots and lines.<br>
-<br>
-<br>
-<img style="width: 690px; height: 495px;" alt=""
- src="images/237F163.jpg"><br>
-Fig. 163. MORSE RECEIVER.<br>
-<br>
-<br>
-238&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">E. M. D. P.</span><br>
-Abbreviation for "electro-motive difference of potential" or for<br>
-electro-motive force producing a current as distinguished from mere<br>
-inert potential difference.<br>
-<br>
-<span style="font-weight: bold;">E. M. F.</span><br>
-Abbreviation for "electro-motive force."<br>
-<br>
-<br>
-<img style="width: 638px; height: 433px;" alt=""
- src="images/238F164.jpg"><br>
-Fig. 164. END-ON METHOD.<br>
-<br>
-<br>
-<span style="font-weight: bold;">End-on Method.</span><br>
-A method of determining the magnetic moment of a magnet. The magnet<br>
-under examination, N S, is placed at right angles to the magnetic<br>
-meridian, M O R, and pointing directly at or "end on" to the centre of a<br>
-compass needle, n s. From the deflection a of the latter the moment is<br>
-calculated.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Endosmose, Electric.</span><br>
-The inflowing current of electric osmose. (See Osmose, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">End Play.</span><br>
-The power to move horizontally in its bearings sometimes given to<br>
-armature shafts. This secures a more even wearing of the commutator<br>
-faces. End play is not permissible in disc armatures, as the attraction<br>
-of the field upon the face of the armature core would displace it<br>
-endwise. For such armatures thrust-bearings preventing end play have to<br>
-be provided.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy.</span><br>
-The capacity for doing work. It is measured by work units which involve<br>
-the exercise of force along a path of some length. A foot-pound,<br>
-centimeter-gram, and centimeter-dyne are units of energy and work.<br>
-<br>
-The absolute unit of energy is the erg, a force of one dyne exercised<br>
-over one centimeter of space. (See Dyne.)<br>
-<br>
-The dimensions of energy are<br>
-&nbsp; force (M * L / T^2) * space (L) = M * (L^2 / T^2).<br>
-Energy may be chemical (atomic or molecular), mechanical,<br>
-electrical, thermal, physical, potential, kinetic, or actual, and other<br>
-divisions could be formulated.<br>
-<br>
-<br>
-239&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Atomic.</span><br>
-The potential energy due to atomic relations set free by atomic change;<br>
-a form of chemical energy, because chemistry refers to molecular as well<br>
-as to atomic changes. When atomic energy loses the potential form it<br>
-immediately manifests itself in some other form, such as heat or<br>
-electric energy. It may be considered as always being potential energy.<br>
-(See Energy, Chemical.)<br>
-<br>
-[Transcriber's note: This item refers to chemical energy, that is<br>
-manifest in work done by electric forces during re-arrangement of<br>
-electrons. Atomic energy now refers to re-arrangement of&nbsp; nucleons<br>
-(protons and neutrons) and the resulting conversion of mass into<br>
-energy.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Energy, Chemical.</span><br>
-A form of potential energy (see Energy, Potential) possessed by elements<br>
-in virtue of their power of combining with liberation of energy, as in<br>
-the combination of carbon with oxygen in a furnace; or by compounds in<br>
-virtue of their power of entering into other combinations more<br>
-satisfying to the affinities of their respective elements or to their<br>
-own molecular affinity. Thus in a galvanic couple water is decomposed<br>
-with absorption of energy, but its oxygen combines with zinc with<br>
-evolution of greater amount of energy, so that in a voltaic couple the<br>
-net result is the setting free of chemical energy, which is at once<br>
-converted into electrical energy in current form, if the battery is on a<br>
-closed circuit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Energy, Conservation of.</span><br>
-A doctrine accepted as true that the sum of energy in the universe is<br>
-fixed and invariable. This precludes the possibility of perpetual<br>
-motion. Energy may be unavailable to man, and in the universe the<br>
-available energy is continually decreasing, but the total energy is the<br>
-same and never changes.<br>
-<br>
-[Transcriber's note: If mass is counted a energy (E=m*(c^2)) then energy<br>
-is strictly conserved.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Energy, Degradation of.</span><br>
-The reduction of energy to forms in which it cannot be utilized by man.<br>
-It involves the reduction of potential energy to kinetic energy, and the<br>
-reduction of kinetic energy of different degrees to energy of the same<br>
-degree. Thus when the whole universe shall have attained the same<br>
-temperature its energy will have become degraded or non-available. At<br>
-present in the sun we have a source of kinetic energy of high degree, in<br>
-coal a source of potential energy. The burning of all the coal will be<br>
-an example of the reduction of potential to kinetic energy, and the<br>
-cooling of the sun will illustrate the lowering in degree of kinetic<br>
-energy. (See Energy, Conservation of--Energy, Potential--Energy,<br>
-Kinetic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Electric.</span> <br>
-The capacity for doing work possessed by electricity<br>
-under proper conditions. Electric energy may be either kinetic or<br>
-potential. As ordinary mechanical energy is a product of force and<br>
-space, so electric energy is a product of potential difference and<br>
-quantity. Thus a given number of coulombs of electricity in falling a<br>
-given number of volts develop electric energy. The dimensions are found<br>
-therefore by multiplying electric current intensity quantity<br>
-&nbsp; ((M^.5) * (L^.5)),<br>
-by electric potential<br>
-&nbsp; ((M^.5)*(L^1.5) / (T^2)),<br>
-giving (M * (L^2)/(T^2)),<br>
-the dimensions of energy in general as it should be.<br>
-<br>
-The absolute unit of electric energy in electro-magnetic measure is<br>
-(1E-7) volt coulombs.<br>
-<br>
-<br>
-240&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The practical unit is the volt-coulomb. As the volt is equal to 1E8<br>
-absolute units of potential and the coulomb to 0.1 absolute units of<br>
-quantity, the volt-coulomb is equal to 1E7 absolute units of energy.<br>
-<br>
-The volt-coulomb is very seldom used, and the unit of Electric Activity<br>
-or Power (see Power, Electric), the volt-ampere, is universally used.<br>
-This unit is sometimes called the Watt, q. v., and it indicates the rate<br>
-of expenditure or of production of electric energy.<br>
-<br>
-The storing up in a static accumulator or condenser of a given charge of<br>
-electricity, available for use with a given change of potential<br>
-represents potential electric energy.<br>
-<br>
-The passing of a given quantity through a conductor with a given fall of<br>
-potential represents kinetic electric energy.<br>
-<br>
-In a secondary battery there is no storage of energy, but the charging<br>
-current simply accumulates potential chemical energy in the battery,<br>
-which chemical energy is converted into electric energy in the discharge<br>
-or delivery of the battery.<br>
-<br>
-It is customary to discuss Ohm's law in this connection; it is properly<br>
-treated under Electric Power, to which the reader is referred. (See<br>
-Power, Electric.)<br>
-<br>
-[Transcriber's note: A volt-ampere or watt is a unit of power. A<br>
-volt-coulomb-second or watt-second is a unit of energy. Power
-multiplied by<br>
-time yields energy.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Electric Transmission of.</span><br>
-If an electric current passes through a conductor all its energy is<br>
-expended in the full circuit. Part of the circuit may be an electrical<br>
-generator that supplies energy as fast as expended. Part of the circuit<br>
-may be a motor which absorbs part of the energy, the rest being expended<br>
-in forcing a current through the connecting wires and through the<br>
-generator. The electric energy in the generator and connecting wires is<br>
-uselessly expended by conversion into heat. That in the motor in great<br>
-part is utilized by conversion into mechanical energy which can do<br>
-useful work. This represents the transmission of energy. Every electric<br>
-current system represents this operation, but the term is usually<br>
-restricted to the transmission of comparatively large quantities of<br>
-energy.<br>
-<br>
-A typical installation might be represented thus. At a waterfall a<br>
-turbine water wheel is established which drives a dynamo. From the<br>
-dynamo wires are carried to a distant factory, where a motor or several<br>
-motors are established, which receive current from the dynamo and drive<br>
-the machinery. The same current, if there is enough energy, may be used<br>
-for running lamps or electroplating. As electric energy (see Energy,<br>
-Electric,) is measured by the product of potential difference by<br>
-quantity, a very small wire will suffice for the transmission of a small<br>
-current at a high potential, giving a comparatively large quantity of<br>
-energy. It is calculated that the energy of Niagara Falls could be<br>
-transmitted through a circuit of iron telegraph wire a distance of over<br>
-1,000 miles, but a potential difference of 135,000,000 volts would be<br>
-required, something quite impossible to obtain or manage.<br>
-<br>
-[Transcriber's note: Contemporary long distance power transmission lines<br>
-use 115,000 to 1,200,000 volts. At higher voltages corona discharges<br>
-(arcing) create unacceptable losses.]<br>
-<br>
-<br>
-241&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Kinetic.</span><br>
-Energy due to matter being actually in motion. It is sometimes called<br>
-actual energy. The energy varies directly with the mass and with the<br>
-square of the velocity. It is represented in formula by .5 *M * (v^2).<br>
-<br>
-Synonyms--Actual Energy--Energy of Motion--Dynamic Energy.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Energy, Mechanical.</span><br>
-The energy due to mechanical change or motion, virtually the same as<br>
-molar energy. (See Energy, Molar.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Molar.</span><br>
-The energy of masses of matter due to movements of or positions of<br>
-matter in masses; such as the kinetic energy of a pound or of a ton in<br>
-motion, or the potential energy of a pound at an elevation of one<br>
-hundred feet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Molecular.</span><br>
-The potential energy due to the relations of molecules and set free by<br>
-their change in the way of combination. It is potential for the same<br>
-reason that applies to atomic and chemical energy, of which latter it is<br>
-often a form, although it is often physical energy. The potential energy<br>
-stored up in vaporization is physical and molecular energy; the<br>
-potential energy stored up in uncombined potassium oxide and water, or<br>
-calcium oxide (quicklime) and water is molecular, and when either two<br>
-substances are brought together kinetic, thermal or heat energy is set<br>
-free, as in slaking lime for mortar.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Energy of an Electrified Body.</span><br>
-An electrified body implies the other two elements of a condenser. It is<br>
-the seat of energy set free when discharged. (See Dielectric, Energy<br>
-of.) The two oppositely charged bodies tend to approach. This tendency,<br>
-together with the distances separating them, represents a potential<br>
-energy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy of Stress.</span><br>
-Potential energy due to stress, as the stretching of a spring. This is<br>
-hardly a form of potential energy. A stressed spring is merely in a<br>
-position to do work at the expense of its own thermal or kinetic energy<br>
-because it is cooled in doing work. If it possessed true potential<br>
-energy of stress it would not be so cooled.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy of Position.</span><br>
-Potential energy due to position, as the potential energy of a pound<br>
-weight raised ten feet (ten foot lbs.). (See Energy, Potential.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Physical.</span><br>
-The potential energy stored up in physical position or set free in<br>
-physical change. Thus a vapor or gas absorbs energy in its vaporization,<br>
-which is potential energy, and appears as heat energy when the vapor<br>
-liquefies.<br>
-<br>
-<br>
-242&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Potential, or Static Energy.</span><br>
-The capacity for doing work in a system due to advantage of position or<br>
-other cause, such as the stress of a spring. A pound weight supported<br>
-ten feet above a plane has ten foot lbs. of potential energy of position<br>
-referred to that plane. A given weight of an elementary substance<br>
-represents potential chemical energy, which will be liberated as actual<br>
-energy in its combination with some other element for which it has an<br>
-affinity. Thus a ton of coal represents a quantity of potential chemical<br>
-energy which appears in the kinetic form of thermal energy when the coal<br>
-is burning in a furnace. A charged Leyden jar represents a source of<br>
-potential electric energy, which becomes kinetic heat energy as the same<br>
-is discharged.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Energy, Thermal.</span><br>
-A form of kinetic molecular energy due to the molecular motion of bodies<br>
-caused by heat.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Entropy.</span><br>
-Non-available energy. As energy may in some way or other be generally<br>
-reduced to heat, it will be found that the equalizing of temperature,<br>
-actual and potential, in a system, while it leaves the total energy<br>
-unchanged, makes it all unavailable, because all work represents a fall<br>
-in degree of energy or a fall in temperature. But in a system such as<br>
-described no such fall could occur, therefore no work could be done. The<br>
-universe is obviously tending in that direction. On the earth the<br>
-exhaustion of coal is in the direction of degradation of its high<br>
-potential energy, so that the entropy of the universe tends to zero.<br>
-(See Energy, Degradation of.)<br>
-<br>
-[Transcriber's note: Entropy (disorder) INCREASES, while AVAILABLE<br>
-ENERGY tends to zero.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Entropy, Electric.</span><br>
-Clerk Maxwell thought it possible to recognize in the Peltier effect, q.<br>
-v., a change in entropy, a gain or loss according to whether the<br>
-thermo-electric junction was heated or cooled. This is termed Electric<br>
-Entropy. (See Energy, Degradation of.)<br>
-<br>
-<br>
-243&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 683px; height: 503px;" alt=""
- src="images/242F165.jpg"><br>
-Fig. 165. EPINUS' CONDENSER,<br>
-<br>
-<br>
-<span style="font-weight: bold;">Epinus' Condenser.</span><br>
-Two circular brass plates, A and B, are mounted on insulating supports,<br>
-and arranged to be moved towards or away from each other as desired.<br>
-Between them is a plate of glass, C, or other dielectric. Pith balls may<br>
-be suspended back of each brass plate as shown. The apparatus is charged<br>
-by connecting one plate to an electric machine and the other to the<br>
-earth. The capacity of the plate connected to the machine is increased<br>
-by bringing near to it the grounded plate, by virtue of the principle of<br>
-bound charges. This apparatus is used to illustrate the principles of<br>
-the electric condenser. It was invented after the Leyden jar was<br>
-invented.<br>
-<br>
-<br>
-<img style="width: 693px; height: 445px;" alt=""
- src="images/243F166.jpg"><br>
-Fig. 166. EPINUS' CONDENSER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">E. P. S.</span><br>
-Initials of Electrical Power Storage; applied to a type of secondary<br>
-battery made by a company bearing that title.<br>
-<br>
-<br>
-<img style="width: 686px; height: 678px;" alt=""
- src="images/243F167.jpg"><br>
-Fig. 167. CAM EQUALIZER.<br>
-<br>
-<br>
-244&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<span style="font-weight: bold;">Equalizer.</span><br>
-In electro-magnetic mechanism an arrangement for converting the pull of<br>
-the electro-magnet varying in intensity greatly over its range of<br>
-action, into a pull of sensibly equal strength throughout. The use of a<br>
-rocking lever acting as a cam, with leverage varying as the armature<br>
-approaches or recedes from the magnet core is one method of effecting<br>
-the result. Such is shown in the cut. E is an electro-magnet, with<br>
-armature a. A and B are the equalizer cams. The pull on the short end of<br>
-the cam B is sensibly equal for its whole length.<br>
-<br>
-Many other methods have been devised, involving different shapes of pole<br>
-pieces, armatures or mechanical devices other than the one just shown.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Equipotential. adj.</span><br>
-Equal in potential; generally applied to surfaces. Thus every magnetic<br>
-field is assumed to be made up of lines of force and intersecting those<br>
-lines, surfaces, plane, or more or less curved in contour, can be<br>
-determined, over all parts of each one of which the magnetic intensity<br>
-will be identical. Each surface is the locus of equal intensity. The<br>
-same type of surface can be constructed for any field of force, such as<br>
-an electrostatic field, and is termed an equipotential surface.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Equipotential Surface, Electrostatic.</span><br>
-A surface in an electrostatic field of force, which is the locus of all<br>
-points of a given potential in such field; a surface cutting all the<br>
-lines of force at a point of identical potential. Lines of force are cut<br>
-perpendicularly by an equipotential surface, or are normal thereto.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Equipotential Surface, Magnetic and
-Electro-magnetic.</span><br>
-A surface bearing the same relation to a magnetic or electro-magnetic<br>
-field of force that an electrostatic equipotential surface (see<br>
-Equipotential Surface, Electrostatic,) does to an electrostatic field of<br>
-force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Equivalent, Chemical.</span><br>
-The quotient obtained by dividing the atomic weight of an element by its<br>
-valency.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Equivalents, Electro-chemical.</span><br>
-The weight of any substance set free by one coulomb of electricity. The<br>
-following give some equivalents expressed in milligrams:<br>
-<br>
-<small><span style="font-family: monospace;">Hydrogen&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.0105&nbsp;&nbsp;&nbsp; Mercury (mercurous)&nbsp;&nbsp; 2.10</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Gold&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.6877&nbsp;&nbsp;&nbsp; Iron
-(ferric)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .1964</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Silver&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.134&nbsp;&nbsp;&nbsp;&nbsp; Iron
-(ferrous)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .294</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Copper
-(cupric)&nbsp;&nbsp;&nbsp;&nbsp; .3307&nbsp;&nbsp;&nbsp;
-Nickel&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.3098</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Mercury (mercuric)
-1.05&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Zinc&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.3413</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Lead&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.0868&nbsp;&nbsp;&nbsp;
-Chlorine&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.3728</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Oxygen&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.89</span></small><br>
-<br>
-<br>
-245&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Equivalent, Electro-mechanical.</span><br>
-The work or energy equivalent to unit quantities of electric energy, q.<br>
-v.; or equivalent to a unit current in a conductor whose ends differ one<br>
-unit of potential. The unit of electric energy taken is the watt-second<br>
-or volt-coulomb. One volt-coulomb is equal to<br>
-&nbsp;
-<small><span style="font-family: monospace;">Ergs&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1E7&nbsp;&nbsp; [10000000]</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Foot
-Pound&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.737337</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Gram-degree
-C.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .24068</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Horse Power
-Second&nbsp;&nbsp; .0013406</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Pound-degree
-F.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .000955</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; One horse power is equal
-to 745.943 volt coulombs per second.</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Equivalent, Electro-thermal.</span><br>
-The heat produced by a unit current passing through a conductor with<br>
-unit difference of potential at its ends; the heat equivalent of a<br>
-volt-coulomb or watt-second. It is equal to<br>
-&nbsp; Gram-degree C.&nbsp;&nbsp; .24068<br>
-&nbsp; Pound-degree F.&nbsp; .000955<br>
-<br>
-<br>
-<span style="font-weight: bold;">Equivalent, Thermo-chemical.</span><br>
-The calories evolved by the combination of one gram of any substance<br>
-with its equivalent of another substance being determined, the product<br>
-obtained by multiplying this number by the equivalent (atomic or<br>
-molecular weight / valency) of the first element or substance is the<br>
-thermo-chemical equivalent. If expressed in kilogram calories, the<br>
-product of the thermo-chemical equivalent by 0.43 gives the voltage<br>
-required to effect such decomposition.<br>
-<br>
-The following are thermo-chemical equivalents of a few combinations:<br>
-<span style="font-family: monospace;">&nbsp;
-Water&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-34.5</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Zinc
-oxide&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 43.2</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Iron
-protoxide&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 34.5</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Iron
-Sesquioxide&nbsp;&nbsp;&nbsp;&nbsp; 31.9 X 3</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Copper
-oxide&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 19.2</span><br>
-<br>
-<br>
-<span style="font-weight: bold;">Equivolt.</span><br>
-"The mechanical energy of one volt electro-motive force exerted under<br>
-unit conditions through one equivalent of chemical action in grains."<br>
-(J. T. Sprague.) This unit is not in general use as the unit of electric<br>
-energy, the volt-coulomb and (for rate of electric energy) the<br>
-volt-ampere being always used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Erg.</span><br>
-The absolute or fundamental C. G. S. unit of work or energy. The work<br>
-done or energy expended in moving a body through one centimeter against<br>
-a resistance of one dyne.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Erg-ten.</span><br>
-Ten millions of ergs, or ten meg-ergs.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Escape.</span><br>
-A term applied to leakage of current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Etching, Electric.</span><br>
-A process of producing an etched plate. The plate is coated with wax,<br>
-and the design traced through as in common etching. It is then placed in<br>
-a bath and is connected to the positive terminal from a generator, whose<br>
-negative is immersed in the same bath, so that the metal is dissolved by<br>
-electrolytic action. By attaching to the other terminal and using a<br>
-plating bath, a rough relief plate may be secured, by deposition in the<br>
-lines of metal by electroplating.<br>
-<br>
-Synonym--Electric Engraving.<br>
-<br>
-<br>
-246&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ether.</span><br>
-The ether is a hypothetical thing that was invented to explain the<br>
-phenomena of light. Light is theoretically due to transverse vibrations<br>
-of the ether. Since the days of Young the conception of the ether has<br>
-extended, and now light, "radiant heat," and electricity are all treated<br>
-as phenomena of the ether. Electrical attraction and repulsion are<br>
-explained by considering them due to local stresses in the ether;<br>
-magnetic phenomena as due to local whirlpools therein. The ether was<br>
-originally called the luminiferous ether, but the adjective should now<br>
-be dropped. Its density is put at 936E-21 that of water, or equal to<br>
-that of the atmosphere at 210 miles above the earth's surface. Its<br>
-rigidity is about 1E-9 that of steel (see Ten, Powers of); as a whole it<br>
-is comparable to an all-pervading jelly, with almost perfect elasticity.<br>
-The most complete vacuum is filled with ether.<br>
-<br>
-All this is a hypothesis, for the ether has never been proved to exist.<br>
-Whether gravitation will ever be explained by It remains to be seen.<br>
-<br>
-[Transcriber's note: The Michelson-Morley experiment in 1887 (five years<br>
-before this book) cast serious doubt on the ether. In 1905 Einstein<br>
-explained electromagnetic phenomenon with photons. In 1963 Edward M.<br>
-Purcell used special relativity to derive the existence of magnetism and<br>
-radiation.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Eudiometer.</span><br>
-A graduated glass tube for measuring the volumes of gases. In its<br>
-simplest form it is simply a cylindrical tube, with a scale etched or<br>
-engraved upon it, closed at one end and open at the other. The gas to be<br>
-measured is collected in it over a liquid, generally water, dilute<br>
-sulphuric acid in the gas voltameter, or mercury. Many different shapes<br>
-have been given them by Hoffmann, Ure, Bunsen and others.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Evaporation, Electric.</span><br>
-The superficial sublimation or evaporation of a substance under the<br>
-influence of negative electricity. It is one of the effects investigated<br>
-by Crookes in his experiments with high vacua. He found that when a<br>
-metal, even so infusible as platinum, was exposed to negative<br>
-electrification in one of his high vacuum tubes, that it was volatilized<br>
-perceptibly. A cadmium electrode heated and electrified negatively was<br>
-found to give a strong coating of metal on the walls of the tube. Even<br>
-in the open air the evaporation of water was found to be accelerated by<br>
-negative electrification.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Exchange, Telephone.</span><br>
-The office to which telephone wires lead in a general telephone system.<br>
-In the office by a multiple switch board, or other means, the different<br>
-telephones are interconnected by the office attendants, so that any<br>
-customers who desire it may be put into communication with each other.<br>
-The exchange is often termed the Central Office, although it may be only<br>
-a branch office.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Excitability, Faradic.</span><br>
-The action produced in nerve or muscle of the animal system by an<br>
-alternating or intermitting high potential discharge from an induction<br>
-coil.<br>
-<br>
-<br>
-247&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Excitability, Galvanic.</span><br>
-The same as Faradic excitability, except that it refers to the effects<br>
-of the current from a galvanic battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Excitability of Animal System,
-Electric.</span><br>
-The susceptibility of a nerve or muscle to electric current shown by the<br>
-effect produced by its application.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Exciter.</span><br>
-A generator used for exciting the field magnet of a dynamo. In<br>
-alternating current dynamos, e. g., of the Westinghouse type, a special<br>
-dynamo is used simply to excite the field magnet. In central station<br>
-distribution the same is often done for direct current dynamos.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Exosmose, Electric.</span><br>
-The outflowing current of electric osmose. (See Osmose, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Expansion, Coefficient of.</span><br>
-The number expressing the proportional increase in size, either length,<br>
-area or volume, of a substance under the influence generally of heat.<br>
-There are three sets of coefficients, (1) of linear expansion, (2) of<br>
-superficial expansion, (3) of cubic expansion or expansion of volume.<br>
-The first and third are the only ones much used. They vary for different<br>
-substances, and for the same substance at different temperatures. They<br>
-are usually expressed as decimals indicating the mixed number referred<br>
-to the length or volume of the body at the freezing point as unity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Expansion, Electric.</span><br>
-(a) The increase in volume of a condenser, when charged<br>
-electrostatically. A Leyden jar expands when charged, and contracts when<br>
-discharged.<br>
-<br>
-(b) The increase in length of a bar of iron when magnetized.<br>
-<br>
-This is more properly called magnetic expansion or magnetic elongation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Exploder.</span><br>
-(a) A small magneto-generator for producing a current for heating the<br>
-wire in an electric fuse of the Abel type (see Fuse, Electric), and<br>
-thereby determining an explosion.<br>
-<br>
-(b) The term may also be applied to a small frictional or influence<br>
-machine for producing a spark for exploding a spark fuse.<br>
-<br style="font-weight: bold;">
-<br>
-<span style="font-weight: bold;">Explorer.</span><br>
-A coil, similar to a magnetizing coil (see Coil, Magnetizing), used for<br>
-investigating the electro-magnetic circuit and for similar purposes. If<br>
-placed around an electro-magnet and connected with a galvanometer, it<br>
-will produce a deflection, owing to a momentary induced current, upon<br>
-any change in the magnet, such as removing or replacing the armature. It<br>
-is useful in determining the leakage of lines of force and for general<br>
-investigations of that nature. It is often called an exploring coil.<br>
-Hughes' Induction Balance (see Induction Balance, Hughes') is sometimes<br>
-called a Magnetic Explorer. The exploring coil may be put in circuit<br>
-with a galvanometer for quantitative measurements or with a telephone<br>
-for qualitative ones.<br>
-<br>
-<br>
-248&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Extension Bell Call.</span><br>
-A system of relay connection, q. v., by which a bell is made to continue<br>
-ringing after the current has ceased coming over the main line. It is<br>
-designed to prolong the alarm given by a magneto call bell, q. v., which<br>
-latter only rings as long as the magneto handle is turned. A vibrating<br>
-electric bell (see Bell, Electric,) is connected in circuit with a local<br>
-battery and a switch normally open, but so constructed as to close the<br>
-circuit when a current is passed and continue to do so indefinitely. The<br>
-distant circuit is connected to this switch. When the magneto is worked<br>
-it acts upon the switch, closes the local battery circuit and leaves it<br>
-closed, while the bell goes on ringing until the battery is exhausted or<br>
-the switch is opened by hand.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Eye, Electro-magnetic.</span><br>
-An apparatus used in exploring a field of electro-magnetic radiations.<br>
-It is a piece of copper wire 2 millimeters (.08 inch) in diameter, bent<br>
-into an almost complete circle 70 millimeters (.28 inch) in diameter,<br>
-with terminals separated by an air gap. This is moved about in the<br>
-region under examination, and by the production of a spark indicates the<br>
-locality of the loops or venters in systems of stationary waves.<br>
-</big></big><br>
-<big><big><br>
-</big></big><big><big><br>
-248&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">F.</span><br>
-Abbreviation for Fahrenheit, as 10&ordm; F., meaning 10&ordm;
-Fahrenheit. (See<br>
-Fahrenheit Scale.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Fahrenheit Scale.</span><br>
-A thermometer scale in use in the United States and England. On this<br>
-scale the temperature of melting ice is 32&deg;; that of condensing
-steam is<br>
-212&deg;; the degrees are all of equal length. Its use is indicated by
-the<br>
-letter F., as 180&deg; F. To convert its readings into centigrade,
-subtract<br>
-32 and multiply by 5/9. (b) To convert centigrade into F. multiply by<br>
-9/5 and add 32. Thus 180&deg; F. = ((180-32) * 5/9)&deg; C. = 82.2&deg;
-C. Again<br>
-180&deg; C. = (180 * 9/5) + 32 = 324&deg; F.<br>
-<br>
-[Transcribers note: 180&deg; C. = (180 * 9/5) + 32 = 356&deg; F. ]<br>
-<br>
-The additions and subtractions must be algebraic in all cases. Thus when<br>
-the degrees are minus or below zero the rules for conversion might be<br>
-put thus: To convert degrees F. below zero into centigrade to the number<br>
-of degrees F. add 32, multiply by 5/9 and place a minus sign (-) before<br>
-it. (b) To convert degrees centigrade below zero into Fahrenheit,<br>
-multiply the number of degrees by 9/5, subtract from 32 if smaller; if<br>
-greater than 32 subtract 32 therefrom, and prefix a minus sign, thus:<br>
--10&deg; C. = 32 - (10 * 9/5) = 14&deg;. Again, -30&deg;C. = (30 * 9/5)
-- 32 = 22 =<br>
--22&deg; F.<br>
-<br>
-<br>
-249&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Farad.</span><br>
-The practical unit of electric capacity; the capacity of a conductor<br>
-which can retain one coulomb of electricity at a potential of one volt.<br>
-<br>
-The quantity of electricity charged upon a conducting surface raises its<br>
-potential; therefore a conductor of one farad capacity can hold two<br>
-coulombs at two volts potential, and three coulombs at three volts, and<br>
-so on. The electric capacity of a conductor, therefore, is relative<br>
-compared to others as regards its charge, for the latter may be as great<br>
-as compatible with absence of sparking and disruptive discharge. In<br>
-other words, a one farad or two farad conductor may hold a great many<br>
-coulombs. Charging a conductor with electricity is comparable to pumping<br>
-air into a receiver. Such a vessel may hold one cubic foot of air at<br>
-atmospheric pressure and two at two atmospheres, and yet be of one cubic<br>
-foot capacity however much air is pumped into it.<br>
-<br>
-The farad is equal to one fundamental electrostatic unit of capacity<br>
-multiplied by 9E11 and to one electro-magnetic unit multiplied by 1E-9.<br>
-<br>
-The farad although one of the practical units is far too large, so the<br>
-micro-farad is used in its place. The capacity of a sphere the size of<br>
-the earth is only .000636 of a farad.<br>
-<br>
-[Transcriber's note: Contemporary calculations give about .000720<br>
-farad.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faraday, Effect.</span><br>
-The effect of rotation of its plane produced upon a polarized beam of<br>
-light by passage through a magnetic field. (See Magnetic Rotary<br>
-Polarization.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faraday's Cube.</span><br>
-To determine the surface action of a charge, Faraday constructed a room,<br>
-twelve feet cube, insulated, and lined with tinfoil. This room he<br>
-charged to a high potential, but within it he could detect no excitement<br>
-whatever. The reason was because the electricity induced in the bodies<br>
-within the room was exactly equal to the charge of the room-surface, and<br>
-was bound exactly by it. The room is termed Faraday's cube.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faraday's Dark Space.</span><br>
-A non-luminous space between the negative and positive glows, produced<br>
-in an incompletely exhausted tube through which a static discharge, as<br>
-from an induction coil, is produced. It is perceptible in a rarefaction<br>
-of 6 millimeters (.24 inch) and upwards. If the exhaustion is very high<br>
-a dark space appears between the negative electrode and its discharge.<br>
-This is known as Crookes' dark space.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faraday's Disc.</span><br>
-A disc of any metal, mounted so as to be susceptible of rotation in a<br>
-magnetic field of force, with its axis parallel to the general direction<br>
-of the lines of force. A spring bears against its periphery and another<br>
-spring against its axle. When rotated, if the springs are connected by a<br>
-conductor, a current is established through the circuit including the<br>
-disc and conductor. The radius of the disc between the spring contacts<br>
-represents a conductor cutting lines of force and generating a potential<br>
-difference, producing a current. If a current is sent through the<br>
-motionless wheel from centre to periphery it rotates, illustrating the<br>
-doctrine of reversibility. As a motor it is called Barlow's or<br>
-Sturgeon's Wheel. If the disc without connections is rapidly rotated it<br>
-produces Foucault currents, q. v., within its mass, which resist its<br>
-rotation and heat the disc.<br>
-<br>
-<br>
-250&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 419px; height: 657px;" alt=""
- src="images/250F168.jpg"><br>
-Fig. 168. "FARADAY'S NET."<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faraday's Net.</span><br>
-An apparatus for showing that the electric charge resides on the<br>
-surface. It consists of a net, conical in shape and rather deep, to<br>
-whose apex two threads, one on each side, are attached. Its mouth is<br>
-fastened to a vertical ring and the whole is mounted on an insulating<br>
-support.<br>
-<br>
-It is pulled out to its full extent and is electrified. No charge can be<br>
-detected inside it. By pulling one of the threads it is turned with the<br>
-other side out. Now all the charge is found on the outside just as<br>
-before, except that it is of course on the former inside surface of the<br>
-bag. The interior shows no charge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faraday's Transformer.</span><br>
-The first transformer. It was made by Michael Faraday. It was a ring of<br>
-soft iron 7/8 inch thick, and 6 inches in external diameter. It was<br>
-wound with bare wire, calico being used to prevent contact of the wire<br>
-with the ring and of the layers of wire with each other, while twine was<br>
-wound between the convolutions to prevent the wires from touching.<br>
-Seventy-two feet of copper wire, 1/20 inch diameter, were wound in three<br>
-superimposed coils, covering about one-half of the ring. On the other<br>
-half sixty feet of copper wire were wound in two superimposed coils.<br>
-Faraday connected his coils in different ways and used a galvanometer to<br>
-measure the current produced by making and breaking one of the circuits<br>
-used as a primary.<br>
-<br>
-The coil is of historic interest.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faraday's Voltameter.</span><br>
-A voltameter, in which the coulombs of current are measured by the<br>
-volume of the gas evolved from acidulated water. (See Voltameter, Gas.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faradic. adj.</span><br>
-Referring to induced currents, produced from induction coils. As Faraday<br>
-was the original investigator of the phenomena of electro-magnetic<br>
-induction, the secondary or induced electro-magnetic currents and their<br>
-phenomena and apparatus are often qualified by the adjective Faradic,<br>
-especially in electro-therapeutics. A series of alternating<br>
-electrostatic discharges, as from an influence machine (Holtz), are<br>
-sometimes called Franklinic currents. They are virtually Faradic, except<br>
-as regards their production.<br>
-<br>
-<br>
-251&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Faradic Brush.</span><br>
-A brush for application of electricity to the person. It is connected as<br>
-one of the electrodes of an induction coil or magneto generator. For<br>
-bristles wire of nickel plated copper is generally employed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faradization.</span><br>
-In medical electricity the analogue of galvanization; the effects due to<br>
-secondary or induced currents; galvanization referring to currents from<br>
-a galvanic battery; also the process of application of such currents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Faults.</span><br>
-Sources of loss of current or of increased resistance or other troubles<br>
-in electric circuits.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Feeder.</span><br>
-A lead in an electric central station distribution system, which lead<br>
-runs from the station to some point in the district to supply current.<br>
-It is not used for any side connections, but runs direct to the point<br>
-where current is required, thus "feeding" the district directly. In the<br>
-two wire system a feeder may be positive or negative; in the three wire<br>
-system there is also a neutral feeder. Often the term feeder includes<br>
-the group of two or of three parallel lines.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Feeder Equalizer.</span><br>
-An adjustable resistance connected in circuit with a feeder at the<br>
-central station. The object of the feeder being to maintain a definite<br>
-potential difference at its termination, the resistance has to be varied<br>
-according to the current it is called on to carry.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Feeder, Main or Standard.</span><br>
-The main feeder of a district. The standard regulation of pressure<br>
-(potential difference between leads) in the district is often determined<br>
-by the pressure at the end of the feeder.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Feeder, Negative.</span><br>
-The lead or wire in a set of feeders, which is connected to the negative<br>
-terminal of the generator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Feeder, Neutral.</span><br>
-In the three wire system the neutral wire in a set of feeders. It is<br>
-often made of less diameter than the positive and negative leads.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Feeder, Positive.</span><br>
-The lead or wire in a set of feeders, which wire is connected to the<br>
-positive terminal of the generator.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ferranti Effect.</span><br>
-An effect as yet not definitely explained, observed in the mains of the<br>
-Deptford, Eng., alternating current plant. It is observed that the<br>
-potential difference between the members of a pair of mains rises or<br>
-increases with the distance the place of trial is from the station.<br>
-<br>
-[Transcriber's note: This effect is due to the voltage drop across the<br>
-line inductance (due to charging current) being in phase with the<br>
-sending end voltages. Both capacitance and inductance are responsible<br>
-for producing this phenomenon.&nbsp; The effect is more pronounced in<br>
-underground cables and with very light loads.]<br>
-<br>
-<br>
-252&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ferro-magnetic. adj.</span><br>
-Paramagnetic; possessing the magnetic polarity of iron.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fibre and Spring Suspension.</span><br>
-A suspension of the galvanometer needle used in marine galvanometers.<br>
-The needle is supported at its centre of gravity by a vertically<br>
-stretched fibre attached at both its ends, but with a spring<br>
-intercalated between the needle and one section of the fibre.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fibre Suspension.</span><br>
-Suspension, as of a galvanometer needle, by a vertical or hanging fibre<br>
-of silk or cocoon fibre, or a quartz fibre. (See Quartz.)<br>
-<br>
-This suspension, while the most delicate and reliable known, is very<br>
-subject to disturbance and exacts accurate levelling of the instrument.<br>
-<br>
-Fibre suspension is always characterized by a restitutive force. Pivot<br>
-suspension, q. v., on the other hand, has no such force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Air.</span><br>
-A field the lines of force of which pass through air; the position of a<br>
-field comprised within a volume of air.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Alternating.</span><br>
-Polarity or direction being attributed to lines of force, if such<br>
-polarity is rapidly reversed, an alternating field results. Such field<br>
-may be of any kind, electro-magnetic or electrostatic. In one instance<br>
-the latter is of interest. It is supposed to be produced by high<br>
-frequency discharges of the secondary of an induction coil, existing in<br>
-the vicinity of the discharging terminals.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field Density.</span><br>
-Field density or density of field is expressed in lines of force per<br>
-unit area of cross-section perpendicular to the lines of force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Field, Distortion of.</span><br>
-The lines of force reaching from pole to pole of an excited field magnet<br>
-of a dynamo are normally symmetrical with respect to some axis and often<br>
-with respect to several. They go across from pole to pole, sometimes<br>
-bent out of their course by the armature core, but still symmetrical.<br>
-The presence of a mass of iron in the space between the pole pieces<br>
-concentrates the lines of force, but does not destroy the symmetry of<br>
-the field.<br>
-<br>
-When the armature of the dynamo is rotated the field becomes distorted,<br>
-and the lines of force are bent out of their natural shape. The new<br>
-directions of the lines of force are a resultant of the lines of force<br>
-of the armature proper and of the field magnet. For when the dynamo is<br>
-started the armature itself becomes a magnet, and plays its part in<br>
-forming the field. Owing to the lead of the brushes the polarity of the<br>
-armature is not symmetrical with that of the field magnets. Hence the<br>
-compound field shows distortion. In the cut is shown diagrammatically<br>
-the distortion of field in a dynamo with a ring armature. The arrow<br>
-denotes the direction of rotation, and n n * * * and s s * * * indicate<br>
-points of north and south polarity respectively.<br>
-<br>
-<br>
-253&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The distorted lines must be regarded as resultants of the two induced<br>
-polarities of the armature, one polarity due to the induction of the<br>
-field, the other to the induction from its own windings. The positions<br>
-of the brushes have much to do with determining the amount and degree of<br>
-distortion. In the case of the ring armature it will be seen that some<br>
-of the lines of force within the armature persist in their polarity and<br>
-direction, almost as induced by the armature windings alone, and leak<br>
-across without contributing their quota to the field. Two such lines are<br>
-shown in dotted lines.<br>
-<br>
-In motors there is a similar but a reversed distortion.<br>
-<br>
-<br>
-<img style="width: 721px; height: 345px;" alt=""
- src="images/253F169.jpg"><br>
-Fig. 169. DISTORTION OF FIELD IN A <br>
-RING ARMATURE OF AN ACTIVE DYNAMO.<br>
-<br>
-<br>
-<img style="width: 718px; height: 545px;" alt=""
- src="images/253F170.jpg"><br>
-Fig. 170. DISTORTION OF FIELD IN A <br>
-RING ARMATURE OF AN ACTIVE MOTOR.<br>
-<br>
-<br>
-254&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Drag of.</span><br>
-When a conductor is moved through a field so that a current is generated<br>
-in it, the field due to that current blends with the other field and<br>
-with its lines of force, distorting the field, thereby producing a drag<br>
-upon its own motion, because lines of force always tend to straighten<br>
-themselves, and the straightening would represent cessation of motion in<br>
-the conductor. This tendency to straightening therefore resists the<br>
-motion of the conductor and acts a drag upon it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field of Force.</span><br>
-The space in the neighborhood of an attracting or repelling mass or<br>
-system. Of electric fields of force there are two kinds, the<br>
-Electrostatic and the Magnetic Fields of Force, both of which may be<br>
-referred to. A field of force may be laid out as a collection of<br>
-elements termed Lines of Force, and this nomenclature is universally<br>
-adopted in electricity. The system of lines may be so constructed that<br>
-(a) the work done in passing from one equipotential surface to the next<br>
-is always the same; or (b) the lines of force are so laid out and<br>
-distributed that at a place in which unit force is exercised there is a<br>
-single line of force passing through the corresponding equipotential<br>
-surface in each unit of area of that surface. The latter is the<br>
-universal method in describing electric fields. It secures the following<br>
-advantages:--First: The potential at any point in the field of space<br>
-surrounding the attracting or repelling mass or masses is found by<br>
-determining on which imaginary equipotential surface that point lies.<br>
-Second: If unit length of a line of force cross n equipotential<br>
-surfaces, the mean force along that line along the course of that part<br>
-of it is equal to n units; for the difference of potential of the two<br>
-ends of that part of the line of force = n; it is also equal to F s (F<br>
-= force), because it represents numerically a certain amount of work;<br>
-but s = I, whence n = F. Third: The force at any part of the field<br>
-corresponds to the extent to which the lines of force are crowded<br>
-together; and thence it may be determined by the number of lines of<br>
-force which pass through a unit of area of the corresponding<br>
-equipotential surface, that area being so chosen as to comprise the<br>
-point in question. (Daniell.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field of Force, Electrostatic.</span><br>
-The field established by the attracting, repelling and stressing<br>
-influence of an electrostatically charged body. It is often termed an<br>
-Electrostatic Field. (See Field of Force.)<br>
-<br>
-<br>
-255&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field of Force of a Current.</span><br>
-A current establishes a field of force around itself, whose lines of<br>
-force form circles with their centres on the axis of the current. The<br>
-cut, Fig. 172, shows the relation of lines of force to current.<br>
-<br>
-<br>
-<img style="width: 564px; height: 476px;" alt=""
- src="images/255F171.jpg"><br>
-Fig. 171. EXPERIMENT SHOWING LINES OF FORCE <br>
-SURROUNDING AN ACTIVE CONDUCTOR.<br>
-<br>
-<br>
-<img style="width: 300px; height: 539px;" alt=""
- src="images/255F172.jpg"><br>
-Fig. 172. DIAGRAM OF FIELD OF FORCE <br>
-SURROUNDING AN ACTIVE CONDUCTOR.<br>
-<br>
-<br>
-<img style="width: 702px; height: 236px;" alt=""
- src="images/255F173.jpg"><br>
-Fig. 173. LINK OF FORCE INDUCED BY A <br>
-CURRENT SHOWING THE MAGNETIC
-WHIRLS.<br>
-<br>
-<br>
-The existence of the field is easily shown by passing a conductor<br>
-vertically through a horizontal card. On causing a current to go through<br>
-the wire the field is formed, and iron filings dropped upon the card,<br>
-tend, when the latter is gently tapped, to take the form of circles. The<br>
-experiment gives a version of the well-known magnetic figures, q. v. See<br>
-Fig. 171.<br>
-<br>
-The cut shows by the arrows the relation of directions of current to the<br>
-direction of the lines of force, both being assumptions, and merely<br>
-indicating certain fixed relations, corresponding exactly to the<br>
-relations expressed by the directions of electro-magnetic or magnetic<br>
-lines of force<br>
-<br>
-<br>
-256&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Pulsatory.</span><br>
-A field produced by pulsatory currents. By induction such field can<br>
-produce an alternating current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Rotating.</span><br>
-In a dynamo the field magnets are sometimes rotated instead of the<br>
-armature, the latter being stationary. In Mordey's alternator the<br>
-armature, nearly cylindrical, surrounds the field, and the latter<br>
-rotates within it, the arrangement being nearly the exact reverse of the<br>
-ordinary one. This produces a rotating field.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Rotatory.</span><br>
-A magnetic field whose virtual poles keep rotating around its centre of<br>
-figure. If two alternating currents differing one quarter period in<br>
-phase are carried around four magnetizing coils placed and connected in<br>
-sets of two on the same diameter and at right angles to each other, the<br>
-polarity of the system will be a resultant of the combination of their<br>
-polarity, and the resultant poles will travel round and round in a<br>
-circle. In such a field, owing to eddy currents, masses of metal,<br>
-journaled like an armature, will rotate, with the speed of rotation of<br>
-the field.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Stray.</span><br>
-The portion of a field of force outside of the regular circuit;<br>
-especially applied to the magnetic field of force of dynamos expressing<br>
-the portion which contributes nothing to the current generation.<br>
-<br>
-Synonym--Waste Field.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Field, Uniform.</span><br>
-A field of force of uniform density. (See Field Density.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Figure of Merit.</span><br>
-In the case of a galvanometer, a coefficient expressing its delicacy. It<br>
-is the reciprocal of the current required to deflect the needle through<br>
-one degree. By using the reciprocal the smaller the current required the<br>
-larger is the figure of merit. The same term may be applied to other<br>
-instruments.<br>
-<br>
-It is often defined as the resistance of a circuit through which one<br>
-Daniell's element will produce a deflection of one degree on the scale<br>
-of the instrument. The circuit includes a Daniell's cell of resistance<br>
-r, a rheostat R, galvanometer G and shunt S. Assume that with the shunt<br>
-in parallel a deflection of a divisions is obtained. The resistance of<br>
-the shunted galvanometer is (GS/G+S ; the multiplying power m of the<br>
-shunt is S+G/S; the formula or figure of merit is m d (r+R +G S/G+S).<br>
-<br>
-The figure of merit is larger as the instrument is more sensitive.<br>
-Synonym--Formula of Merit.<br>
-<br>
-<br>
-257&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Filament.</span><br>
-A thin long piece of a solid substance. In general it is so thin as to<br>
-act almost like a thread, to be capable of standing considerable<br>
-flexure. The distinction between filament and rod has been of much<br>
-importance in some patent cases concerning incandescent lamps. As used<br>
-by electricians the term generally applies to the carbon filament of<br>
-incandescent lamps. This as now made has not necessarily any fibres, but<br>
-is entitled to the name of filament, partly by convention, partly by its<br>
-relative thinness and want of stiffness. (See Incandescent<br>
-Lamps--Magnetic Filament.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fire Alarm, Electric, Automatic.</span><br>
-A system of telegraph circuits, at intervals supplied with thermostats<br>
-or other apparatus affected by a change of temperature, which on being<br>
-heated closes the circuit and causes a bell to ring. (See Thermostat.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Fire Alarm Telegraph System.</span><br>
-A system of telegraphic lines for communicating the approximate location<br>
-of a fire to a central station and thence to the separate fire-engine<br>
-houses in a city or district. It includes alarm boxes, distributed at<br>
-frequent intervals, locked, with the place where the key is kept<br>
-designated, or in some systems left unlocked. On opening the door of the<br>
-box and pulling the handle or otherwise operating the alarm, a<br>
-designated signal is sent to the central station. From this it is<br>
-telegraphed by apparatus worked by the central station operator to the<br>
-engine houses. The engines respond according to the discipline of the<br>
-service.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fire Cleansing.</span><br>
-Freeing the surface of an article to be plated from grease by heating.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fire Extinguisher, Electric, Automatic.</span><br>
-A modification of the electric fire alarm (see Fire Alarm, Electric,<br>
-Automatic), in which the thermostats completing the circuits turn on<br>
-water which, escaping through the building, is supposed to reach and<br>
-extinguish a fire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Flashing in a Dynamo or
-Magneto-electric Generator.</span><br>
-Bad adjustment of the brushes at the commutator, or other fault of<br>
-construction causes the production of voltaic arcs at the commutator of<br>
-a generator, to which the term flashing is applied.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Flashing of Incandescent Lamp Carbons.</span><br>
-A process of treatment for the filaments of incandescent lamps. The<br>
-chamber before sealing up is filled with a hydro-carbon vapor or gas,<br>
-such as the vapor of a very light naphtha (rhigolene). A current is then<br>
-passed through the filament heating it to redness. The more attenuated<br>
-parts or those of highest resistance are heated the highest, and<br>
-decompose most rapidly the hydro-carbon vapor, graphitic carbon being<br>
-deposited upon these parts, while hydrogen is set free. This goes on<br>
-until the filament is of uniform resistance throughout. It gives also a<br>
-way of making the resistance of the filament equal to any desired number<br>
-of ohms, provided it is originally of high enough resistance. The<br>
-process increases the conductivity of the filament.<br>
-<br>
-After flashing the chambers are pumped out and sealed up.<br>
-<br>
-<br>
-258&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Flashing Over.</span><br>
-A phenomenon observed in high potential dynamos. On a sudden alteration<br>
-of the resistance of the circuit a long blue spark will be drawn out<br>
-around the surface of the commutator from brush to brush. The spark is<br>
-somewhat of the nature of an arc, and may seriously injure commutators<br>
-whose sections are only separated by mica, or other thin insulation. In<br>
-the case of commutators whose sections are separated by air spaces it is<br>
-not so injurious.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Flats.</span><br>
-In a commutator of a dynamo, the burning or wearing away of a commutator<br>
-segment to a lower level than the rest. Sometimes two adjacent bars will<br>
-be thus affected, causing a flat place on the commutator. It is not<br>
-always easy to account for the formation of flats. They may have their<br>
-origin in periodic vibrations due to bad mounting, or to sparking at the<br>
-particular point.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Floor Push.</span><br>
-A press or push button constructed to be set into the floor to be<br>
-operated by pressing with the foot. It is used to ring an alarm bell,<br>
-sound a buzzer or for similar service.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fluid, Depolarizing.</span><br>
-A fluid used in voltaic batteries to dispose of the hydrogen, which goes<br>
-to the negative plate. This it does by oxidizing it. Chromic acid,<br>
-nitric acid, and chloric acids are among the constituents of liquid<br>
-depolarizers. (See Electropoion Fluid.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Fluid, Electric.</span><br>
-The electric current and charge have sometimes been attributed to a<br>
-fluid. The theory, which never was much more than hypothetical, survives<br>
-to some extent in the single and double fluid theory. (See Single Fluid<br>
-Theory-Double Fluid Theory.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fluorescence.</span><br>
-The property of converting ether waves of one length, sometimes of<br>
-invisible length, into waves of another length (visible). AEsculin,<br>
-quinine salts, uranium glass and other substances exhibit this<br>
-phenomenon. The phenomenon is utilized in the production of Geissler<br>
-tubes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Flush Boxes.</span><br>
-A heavy iron box covered with a heavy hand plate and laid flush (whence<br>
-the name), or even with the surface of a roadway. Into it conductors of<br>
-an underground system lead, and it is used to make connections therewith<br>
-and for examining the leakage of the conductors and for similar<br>
-purposes. It is a "man-hole" (q. v.) in miniature.<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Fluviograph.</span><br>
-An electric registering tide gauge or water level gauge.<br>
-<br>
-<br>
-259&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fly or Flyer, Electric.</span><br>
-A little wheel, ordinarily poised on a point, like a compass needle. It<br>
-carries several tangentially directed points, all pointing in the same<br>
-sense. When connected with a source of electricity of high potential it<br>
-revolves by reaction. The tension of its charge is highest at the<br>
-points, the air there is highly electrified and repelled, the reaction<br>
-pushing the wheel around like a Barker's mill or Hero's steam engine.<br>
-Sometimes the flyer is mounted with its axis horizontal and across the<br>
-rails on a railroad along which it travels.<br>
-<br>
-Synonym--Reaction Wheel.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Foci Magnetic.</span><br>
-The two points on the earth's surface where the magnetic intensity is<br>
-greatest. They nearly coincide in position with the magnetic poles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fog, Electric.</span><br>
-Fogs occurring when the atmosphere is at unusually high potential and<br>
-accompanied by frequent change of such polarity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Following Horns.</span><br>
-In dynamo-electric machines the projecting ends of the pole pieces<br>
-towards which the outer uncovered perimeter of the armature turns in its<br>
-regular operations. The leading horns are those away from which the<br>
-armature rotates. In considering rotation the exposed portion of the<br>
-superficies of the armature is considered. The definition would have to<br>
-be reversed if the part facing the pole pieces were considered.<br>
-<br>
-Synonym--Trailing Horns.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Foot-candle.</span><br>
-A unit of illuminating power; the light given by one standard candle at<br>
-a distance of one foot. The ordinary units of illuminating power are<br>
-entirely relative; this is definite. It is due to Carl Herring.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Foot-pound.</span><br>
-A practical unit of work or energy. The quantity of work required to<br>
-raise a pound one foot, or one hundred pounds one-hundredth of a foot,<br>
-and so on; or the potential energy represented by a weight at an<br>
-elevation under these conditions.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Foot-step.</span><br>
-In a dynamo with armature at the lower end of its field magnets, the<br>
-plate generally of zinc, interposed between it and the iron base plate<br>
-to prevent the leakage of lines of force outside of the circuit. Any<br>
-diamagnetic material which is mechanically suitable may be used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Force.</span><br>
-Force may be variously defined.<br>
-(a) Any cause of change of the condition of matter with respect to<br>
-motion or rest.<br>
-<br>
-(b) A measurable action upon a body under which the state of rest of<br>
-that body, or its state of uniform motion in a straight line, suffers<br>
-change.<br>
-<br>
-(c) It may be defined by its measurement as the rate of change of<br>
-momentum, or<br>
-<br>
-(d) as the rate at which work is done per unit of space traversed.<br>
-<br>
-Force is measured by the acceleration or change of motion it can impart
-<br>
-to a body of unit mass in a unit of time, or, calling<br>
-force, F,<br>
-mass, m<br>
-acceleration per second a<br>
-we have F = m a.<br>
-<br>
-The dimensions of force are <br>
-mass (M) * acceleration (L/(T^2)) = (M*L)/(T^2).<br>
-<br>
-<br>
-260&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Force de Cheval. Horse power (French).
-</span><br>
-It is the French or metric horse power.<br>
-It is equal to:<br>
-&nbsp; <span style="font-family: monospace;">542.496&nbsp;&nbsp;&nbsp;
-Foot lbs. per second.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;
-.9864&nbsp;&nbsp; English Horse Power.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;
-75.0&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Kilogram-meters per
-second.</span><br>
-<br>
-<br>
-<span style="font-weight: bold;">Force, Electro-magnetic.</span><br>
-The mechanical force of attraction or repulsion acting on the<br>
-electro-magnetic unit of quantity. Its intensity varies with the square<br>
-of the distance. It may also be defined as electric force in the<br>
-electro-magnetic system.<br>
-<br>
-Its dimensions are equal to <br>
-mechanical force ((M*L)/(T^2)) divided by quantity ((M^.5)*(L^.5)) <br>
-= ((M^.5)*(L^.5))/(T^2).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Force, Electrostatic.</span><br>
-The force by which electric matter or electrified surfaces attract or<br>
-repel each other. It is also termed electric force (not good) and<br>
-electro-motive intensity. It is the mechanical force acting upon a unit<br>
-quantity of electricity. Its intensity varies with the square of the<br>
-distance.<br>
-<br>
-Its dimensions are therefore equal to<br>
-(quantity * unity / (square of distance) Q. * 1 / (L^2)<br>
-&nbsp;= ((M^.5) * (L^1.5) )/ T*1 / (L^2)<br>
-&nbsp;= ((M^.5) * (L^.5)) / T<br>
-These dimensions are also those of potential difference.<br>
-<br>
-<img style="width: 675px; height: 71px;" alt="" src="images/260T.jpg"><br>
-[Transcriber's Note: The image of the preceding paragraph is included<br>
-for "clarity".]<br>
-<br>
-The objection to the term electric force is that it may be applied also<br>
-to electro-magnetic force, and hence be a source of confusion.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Forces, Parallelogram of.</span><br>
-The usual method of composing forces or resolving a force. The sides of<br>
-a parallelogram of forces represent component forces and the diagonal<br>
-represents the resultant. See Component--Resultant--Forces, Composition<br>
-of--Forces, Resolution of.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Forces, Composition of.</span><br>
-When several forces act in a different direction upon a point they may<br>
-be drawn or graphically represented as arrows or lines emanating from<br>
-the point in the proper direction and of lengths proportional to the<br>
-force they exercise. Any two can be treated as contiguous sides of a<br>
-parallelogram and the parallelogram can be completed. Then its diagonal,<br>
-called the resultant, will represent the combined action of the two<br>
-forces, both as regards direction and intensity. This is the composition<br>
-of two forces.<br>
-<br>
-If more than two forces act upon the given point the resultant can be<br>
-composed with any of the others and a new force developed. The new<br>
-resultant can be combined with another force, and the process kept up,<br>
-eliminating the components one by one until a final resultant of all is<br>
-obtained. This will give the exact direction and intensity of the<br>
-forces, however many or varied.<br>
-<br>
-<br>
-261&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Forces, Resolution of.</span><br>
-The developing from a single force treated as a resultant, two other<br>
-forces in any desired direction. The reverse of composition of forces.<br>
-(See Forces, Composition of--Forces, Parallelogram<br>
-of--Components--Resultant.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Force, Tubes of.</span><br>
-Aggregations of lines of force, either electrostatic or magnetic. They<br>
-generally have a truncated, conical or pyramidal shape and are not<br>
-hollow. Every cross-section contains the same number of lines. The name<br>
-it will seem is not very expressive.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Force, Unit of.</span><br>
-The fundamental or C. G. S. unit or force is the dyne, q. v.<br>
-<br>
-The British unit of force is the poundal (the force which will produce<br>
-an acceleration of one foot per second in a mass of one pound). It is<br>
-equal to about 10/322 pound. A force cannot be expressed accurately in<br>
-weight units, because weight varies with the latitude.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Forming.</span><br>
-The process of producing secondary battery plates from lead plates by<br>
-alternately passing a charging current through the cell and then<br>
-allowing it to discharge itself and repeating the operation. (See<br>
-Battery, Secondary, Plant&eacute;'s.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Foundation Ring.</span><br>
-In a dynamo armature the ring-shaped core on which Gramme ring armatures<br>
-and other ring armatures are wound.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fourth State of Matter.</span><br>
-Gas so rarefied that its molecules do not collide, or rarely do so;<br>
-radiant matter, q. v.<br>
-<br>
-[Transcriber's note: This term now refers to plasma, an ionized gas,<br>
-which contains free electrons. The ions and electrons move somewhat<br>
-independently making plasma electrically conductive. It responds<br>
-strongly to electromagnetic fields.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Frame.</span><br>
-In a dynamo the bed-piece is sometimes called the frame.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Franklin's Experiment.</span><br>
-Franklin proved the identity of lightning and electricity by flying a<br>
-kite in a thunder storm. The kite was of silk so as to endure the<br>
-wetting. When the string became wet sparks could be taken from a key<br>
-attached to its end. The main string was of hemp; at the lower end was a<br>
-length of silk to insulate it. The key was attached near the end of and<br>
-to the hemp string.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Franklin's Plate.</span><br>
-A simple form of condenser. It consists of a plate of glass coated on<br>
-each side with tinfoil with a margin of about an inch of clear glass.<br>
-One coating may be grounded as indicated in the cut, and the plate<br>
-charged like a Leyden jar. Or one side may be connected with one<br>
-terminal, and the other with the other terminal of an influence machine<br>
-and the pane will be thus charged.<br>
-<br>
-Synonym--Fulminating Pane.<br>
-<br>
-<br>
-262&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 525px; height: 496px;" alt=""
- src="images/262F174.jpg"><br>
-Fig. 174. FRANKLIN'S PLATE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Franklin's Theory.</span><br>
-The single fluid theory, q. v., of electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Frequency.</span><br>
-The number of double reversals or complete alternations per second in an<br>
-alternating current.<br>
-<br>
-Synonym--Periodicity.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Frictional Electricity.</span><br>
-Electricity produced by friction of dissimilar substances. (See<br>
-Electrostatic Series.) The contact theory holds that friction plays only<br>
-a secondary r&ocirc;le in this process; that it increases the
-thoroughness of<br>
-contact, and tends to dry the rubbing surfaces, but that the charges<br>
-induced are due to contact of dissimilar substances, not to friction of<br>
-one against the other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Frictional Heating.</span><br>
-The heating of a conductor by the passage of a current; the Joule<br>
-effect, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fringe.</span><br>
-The outlying edge of a magnetic field.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Frog, Galvani's Experiment With.</span><br>
-A classic experiment in electricity, leading to the discovery of current<br>
-or dynamic electricity. If a pair of legs of a recently killed frog are<br>
-prepared with the lumbar nerves exposed near the base of the spinal<br>
-column, and if a metallic conductor, one half-length zinc and the other<br>
-half-length copper, is held, one end between the lumbar nerves and the<br>
-spine, and the other end against one of the muscles of the thigh or<br>
-lower legs, the moment contact occurs and the circuit is completed<br>
-through the animal substance the muscles contract and the leg is<br>
-violently drawn upwards. Galvani, in 1786, first performed, by accident,<br>
-this famous experiment, it is said, with a scalpel with which he was<br>
-dissecting the animal. He gave his attention to the nerves and muscles.<br>
-Volta, more happily, gave his attention to the metals and invented the<br>
-voltaic battery, described by him in a letter to Sir Joseph Banks, dated<br>
-1800.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Frog, Rheoscopic.</span><br>
-If the nerve or living muscle of a frog is suddenly dropped upon another<br>
-living muscle so as to come in contact with its longitudinal and<br>
-transverse sections, the first muscle will contract on account of the<br>
-stimulation of its nerve due to the passage of a current derived from<br>
-the second muscle (Ganot). The experiment goes under the above title.<br>
-<br>
-<br>
-263&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Frying.</span><br>
-A term applied to a noise sometimes produced in a voltaic arc due to too<br>
-close approach of the carbons to each other. It has been suggested that<br>
-it may be due to volatilization of the carbon. (Elihu Thomson.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fulgurite.</span><br>
-An irregular and tubular mass of vitrified quartz, believed to be formed<br>
-by melting under the lightning stroke.<br>
-<br>
-<br>
-<img style="width: 637px; height: 241px;" alt=""
- src="images/263F175.jpg"><br>
-Fig. 175. CRUCIBLE, ELECTRIC.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Furnace, Electric.</span><br>
-A furnace in which the heat is produced by the electric current. It has<br>
-hitherto been practically used only in the extraction of aluminum and<br>
-silicium&nbsp; from their ores. The general principle involves the
-formation<br>
-of an arc between carbon electrodes. The substances to be treated are<br>
-exposed to the heat thus produced. Sometimes the substances in the arc<br>
-form imperfect conductors, and incandescence takes a part in the action.<br>
-Sometimes the substances are merely dropped through the arc.<br>
-<br>
-[Transcriber's note: Silicium is silicon.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fuse Board.</span><br>
-A tablet on which a number of safety fuses are mounted. Slate is<br>
-excellent material for the tablet, as it is incombustible, and is easily<br>
-drilled and worked.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fuse Box.</span><br>
-A box containing a safety fuse. Porcelain is an excellent material for<br>
-its base. No combustible material should enter into its composition.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fuse, Cockburn.</span><br>
-A safety fuse or cut off which consists of a wire of pure tin running<br>
-from terminal to terminal, to whose centre a leaden ball is secured by<br>
-being cast into position. The connection with the terminals is made by<br>
-rings at the ends of the wire through which the terminal screws are<br>
-passed and screwed home. When the tin softens under too heavy a current<br>
-the weight of the shot pulls it apart.<br>
-<br>
-<br>
-<img style="width: 445px; height: 318px;" alt=""
- src="images/263F176.jpg"><br>
-Fig. 176 COCKBURN SAFETY FUSE.<br>
-<br>
-<br>
-264&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 653px; height: 562px;" alt=""
- src="images/264F177.jpg"><br>
-Fig. 177. ELECTRIC FUSE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Fuse, Electric.</span><br>
-A fuse for igniting an explosive by electricity. There are two kinds. In<br>
-one a thin wire unites the ends of the two conducting wires as they<br>
-enter the case of the fuse. The larger wires are secured to the case, so<br>
-that no strain comes on the fine wire. On passing a current of<br>
-sufficient strength the small wire is heated. In use the fuse is bedded<br>
-in powder, which again may be surrounded by fulminating powder, all<br>
-contained in a copper or other metallic case. Such a detonator is used<br>
-for exploding guncotton and other high explosives.<br>
-<br>
-The other kind of fuse is similar, but has no thin connecting wire. The<br>
-ends of the conductors are brought nearer together without touching. In<br>
-use a static discharge is produced across from end to end of the<br>
-conductors, igniting a proper explosive placed there as in the other<br>
-case.<br>
-<br>
-The first kind of fuse is generally operated by a battery or small<br>
-mechanical generator--the latter by a spark coil, frictional or<br>
-influence machine or by a Leyden jar.<br>
-<br>
-</big></big><big><big><br>
-264&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanic. adj.</span><br>
-Voltaic; relating to current electricity or the electrolytic and<br>
-electro-chemical relations of metals. (For titles in general under this<br>
-head see Voltaic--or the main title.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanic Element.</span><br>
-A galvanic couple with exciting fluid and adjuncts; a galvanic cell. The<br>
-word element is sometimes applied to the electrodes of a cell, as the<br>
-carbon element or zinc element.<br>
-<br>
-<br>
-265&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanic Polarization.</span><br>
-The polarization of a voltaic couple. (See Polarization.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanism.</span><br>
-The science of voltaic or current electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanization.</span><br>
-(a) Electroplating or depositing a metal over the surface of another by<br>
-electrolysis.<br>
-<br>
-(b) In medical electricity the effects produced on any part of the<br>
-system by the current of voltaic battery. Various descriptive<br>
-qualifications are prefixed, such as "general" galvanization, indicating<br>
-its application as applied to the whole body, "local" for the reverse<br>
-case, and so on.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanization, Labile.</span><br>
-Application of the galvanic current in electro-therapeutics where one<br>
-sponge electrode is employed which is rubbed or moved over the body, the<br>
-other being in constant contact with the body.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanized Iron.</span><br>
-Iron coated with zinc by cleaning and immersion in melted zinc. The iron<br>
-is prevented from rusting by galvanic action. It forms the negative<br>
-element in a couple of which the zinc is the positive element. From this<br>
-electric protective action the name is derived.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvano-cautery, Chemical.</span><br>
-Electro-therapeutic treatment with sharp electrodes, one of which is<br>
-inserted in the tissue and a current passed by completing the circuit<br>
-through the tissue so as to electrolyze or decompose the fluids of the<br>
-tissue. It is applied in the removal of hair or extirpation of the<br>
-follicle. The process is not one of heating, and is improperly named<br>
-cautery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvano-faradization.</span><br>
-In medical electricity the application of the voltaic and induced or<br>
-secondary current simultaneously to any part of the system.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer.</span><br>
-An instrument for measuring current strength and sometimes for measuring<br>
-inferentially potential difference, depending on the action of a<br>
-magnetic field established by the current, such action being exerted on<br>
-a magnetic needle or its equivalent.<br>
-<br>
-A current passing through a conductor establishes circular lines of<br>
-force. A magnetic needle placed in their field is acted on and tends to<br>
-place itself parallel with the lines, in accordance with the principles<br>
-of current induction. (See Induction, Electro-magnetic.) A common<br>
-compass held near a conductor through which a current is passing tends<br>
-to place itself at right angles to such conductor. For a maximum effect<br>
-the conductor or the part nearest the needle should lie in the magnetic<br>
-meridian. If at right angles thereto its action will only strengthen the<br>
-directive force of the earth's induction or magnetic field, as the<br>
-needle naturally points north and south. Such combination is virtually a<br>
-galvanometer.<br>
-<br>
-<br>
-266&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-A typical galvanometer comprises a flat coil of wire placed horizontally<br>
-within which a magnetic needle is delicately poised, so as to be free to<br>
-rotate with the least possible friction. The needle may be supported on<br>
-a sharp point like a compass needle, or may be suspended by a long fine<br>
-filament. It should be covered by a glass plate and box, or by a glass<br>
-shade. Finally a graduated disc may be arranged to show the amount of<br>
-deflection of the needle.<br>
-<br>
-In use the apparatus is turned about until the needle, as acted on by<br>
-the earth's magnetic field, lies parallel to the direction of the coils<br>
-of wire. On passing a current through the coil the needle is deflected,<br>
-more or less, according to its strength.<br>
-<br>
-By using exceedingly fine wire, long enough to give high resistance, the<br>
-instrument can be used for very high potentials, or is in condition for<br>
-use in determining voltage. By using a coil of large wire and low<br>
-resistance it can be employed in determining amperage. In either case<br>
-the deflection is produced by the current.<br>
-<br>
-The needle is often placed above or below the coil so as only to receive<br>
-a portion of its effect, enough for all practical purposes in the<br>
-commoner class of instruments.<br>
-<br>
-The galvanometer was invented by Schweigger a short time after Oersted's<br>
-discovery, q. v.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Absolute.</span><br>
-A galvanometer giving absolute readings; properly one whose law of<br>
-calibration can be deduced from its construction. Thus the diameter of<br>
-the coil, and the constants and position of a magnetic needle suspended<br>
-in its field being known, the current intensity required to deflect the<br>
-needle a given number of degrees could be calculated.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Aperiodic.</span><br>
-A galvanometer whose needle is damped (see Damping) as, for instance, by<br>
-the proximity of a plate of metal, by an air vane or otherwise, so that<br>
-it reaches its reading with hardly any oscillation. A very light needle<br>
-and a strong magnetic field also conduce to vibrations of short period<br>
-dying out very quickly. Such galvanometers are termed "dead-beat." No<br>
-instrument is absolutely dead-beat, only relatively so.<br>
-<br>
-<br>
-267&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 419px; height: 557px;" alt=""
- src="images/266F178.jpg"><br>
-Fig. 178. ASTATIC GALVANOMETER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer, Astatic.</span><br>
-A galvanometer with a pair of magnetic needles connected astatically, or<br>
-parallel with their poles in opposition. (See Astatic Needle.) Each<br>
-needle has its own coil, the coils being wound in opposite directions so<br>
-as to unite in producing deflections in the same sense. As there should<br>
-be some directive tendency this is obtained by one of the magnets being<br>
-slightly stronger than the other or by the proximity of a fixed and<br>
-adjustable controlling magnet, placed nearer one needle than the other.<br>
-<br>
-For small deflections the currents producing them are proportional to<br>
-their extent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer, Ballistic.</span><br>
-A galvanometer whose deflected element has considerable moment of<br>
-inertia; the exact opposite of an aperiodic or dead beat galvanometer.<br>
-(See Galvanometer, Aperiodic.) All damping by air vanes or otherwise<br>
-must be carefully done away with.<br>
-<br>
-<br>
-<img style="width: 437px; height: 683px;" alt=""
- src="images/267F179.jpg"><br>
-Fig. 179. SIEMENS &amp; HALSKE'S GALVANOMETER.<br>
-<br>
-<br>
-Siemens &amp; Halske's galvanometer is of the reflecting or mirror type
-(see<br>
-Galvanometer, Reflecting) with suspended, bell-shaped magnet, in place<br>
-of the ordinary magnetic needle, or astatic combination of the lightest<br>
-possible weight in the regular instrument. A copper ball drilled out to<br>
-admit the magnet is used as damper in the ordinary use of the<br>
-instrument. To convert it into a ballistic galvanometer the copper ball<br>
-is removed. The heavy suspended magnet then by its inertia introduces<br>
-the desired element into the instrument.<br>
-<br>
-<br>
-268&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Referring to the cut, Fig. 179, M is the suspended magnet, with north<br>
-and south poles n and s; S is the reflecting mirror; r is the tube<br>
-containing the suspending thread; R is the damper removed for ballistic<br>
-work.<br>
-<br>
-The ballistic galvanometer is used to measure quantities of electricity<br>
-in an instantaneous discharge, which discharge should be completed<br>
-before the heavy needle begins to move. The extreme elongation or throw<br>
-of the needle is observed, and depends (1) on the number of coulombs (K)<br>
-that pass during the discharge; (2) on the moment of inertia of the<br>
-needle and attached parts; (3) on the moment of the controlling forces,<br>
-i. e., the forces tending to pull the needle back to zero; (4) on the<br>
-moment of the damping forces; (5) on the moment of the deflecting forces<br>
-due to a given constant current. The formula is thus expressed:<br>
-<br>
-K = (P / PI ) * A * sin( k&ordm; / 2 ) / tan( a&ordm; )<br>
-<br>
-in which K = coulombs discharged; P = periodic time of vibration of<br>
-needle; A = amperes producing a steady deflection equal to&nbsp;
-a&ordm;&nbsp; ; k&ordm; =<br>
-first angular deflection of needle. For accuracy k&ordm; and a&ordm;
-should both<br>
-be small and the damping so slight as to be negligible. Otherwise a<br>
-correction for the latter must be applied. For approximate work for
-k&ordm;<br>
-and a&ordm; the deflections read on the scale may be used with the
-following<br>
-formula:<br>
-<br>
-K = (P / PI ) * ( A / 2 ) * ( k&ordm; / a&ordm; )<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer Constant.</span><br>
-Assume a galvanometer with a very short needle and so placed with<br>
-respect to its coils that the magnetic field produced by a current<br>
-circulating in them is sensibly uniform in the neighborhood of the<br>
-needle, with its lines of force at right angles thereto. The field is<br>
-proportional to the current i, so that it may be denoted by G i. Then G<br>
-is the galvanometer constant. If now the angle of deflection of the<br>
-needle is ? against the earth's field H, M being the magnetic moment of<br>
-the needle we have G i M cos ? = H M sin ? or i = (H/G)* tan ?. H/G is<br>
-the reduction factor; variable as H varies for different places.<br>
-<br>
-For a tangent galvanometer the constant G is equal to&nbsp; 2*PI*(n/a),
-in<br>
-which n denotes the number of turns of wire, and a denotes the radius of<br>
-the circle.<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Differential.</span><br>
-A galvanometer in which the needle is acted on by two coils wound in<br>
-opposition, each of equal deflecting action and of equal resistance. If<br>
-a current is divided between two branches or parallel conductors, each<br>
-including one of the coils, when the needle points to zero the<br>
-resistances of the two branches will bc equal. In the cut, C C'<br>
-represent the coils, and A and B the two leads into which the circuit, P<br>
-Q, is divided.<br>
-<br>
-<br>
-269&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 612px; height: 274px;" alt=""
- src="images/269F180.jpg"><br>
-Fig. 180. THEORY OF DIFFERENTIAL GALVANOMETER.<br>
-<br>
-<br>
-<img style="width: 513px; height: 740px;" alt=""
- src="images/269F181.jpg"><br>
-Fig. 181. DIFFERENTIAL GALVANOMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Direct Reading.</span><br>
-A calibrated galvanometer, whose scale is graduated by volts or amperes,<br>
-instead of degrees.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer, Marine. (Sir William
-Thomson's.)</span><br>
-A galvanometer of the reflecting type, for use on shipboard. A fibre<br>
-suspension is adopted for the needle. The fibre is attached to a fixed<br>
-support at one end and to a spring at the other, and the needle is<br>
-suspended by its centre of gravity. This secures it to a considerable<br>
-extent from disturbance due to the rolling of the ship. A thick iron box<br>
-encloses the needle, etc., to cut off any magnetic action from the ship.<br>
-(See Galvanometer, Reflecting.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer, Potential.</span><br>
-A galvanometer wound with fine German silver wire to secure high<br>
-resistance used for determination of potential difference.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Proportional.</span><br>
-A galvanometer so constructed that the deflections of its index are<br>
-proportional to the current passing. It is made by causing the<br>
-deflecting force to increase as the needle is deflected, more and more,<br>
-or by causing the restitutive force to diminish under like conditions,<br>
-or by both. The condition is obtained in some cases by the shape and<br>
-position of the deflecting coils.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer, Quantity.</span><br>
-A galvanometer for determining quantities of electricity, by the<br>
-deflections produced by discharging the quantities through their coils.<br>
-It is a ballistic galvanometer with very little or no damping.<br>
-<br>
-<br>
-270&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 626px; height: 301px;" alt=""
- src="images/270F182.jpg"><br>
-Fig. 182. PRINCIPLE OF REFLECTING GALVANOMETER.<br>
-<br>
-<br>
-<img style="width: 647px; height: 418px;" alt=""
- src="images/270F183.jpg"><br>
-Fig. 183. REFLECTING GALVANOMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Reflecting.</span><br>
-A galvanometer the deflections of whose needle are read by an image<br>
-projected by light reflected from a mirror attached to the needle or to<br>
-a vertical wire carrying the needle. A lamp is placed in front of the<br>
-instrument facing the mirror. The light of the lamp is reflected by the<br>
-mirror upon a horizontal scale above the lamp. An image of a slit or of<br>
-a wire may be caused thus to fall upon the scale, the mirror being<br>
-slightly convex, or a lens being used to produce the projection.<br>
-<br>
-<br>
-271&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-If the mirror swings through a horizontal arc, the reflected image will<br>
-move, in virtue of a simple geometrical principle, through an arc of<br>
-twice as many degrees. The scale can be placed far from the mirror, so<br>
-that the ray of light will represent a weightless index of very great<br>
-length, and minute deflections of the needle will be shown distinctly<br>
-upon the scale.<br>
-<br>
-In the cut, Fig. 182, the ray of light from the lamp passes through the<br>
-aperture, m m, and is made parallel by the lens, L. At s is the mirror<br>
-attached to the needle and moving with it. A scale placed at t receives<br>
-the reflection from the mirror. The cut, Fig. 183, shows one form of the<br>
-instrument set up for use.<br>
-<br>
-Synonym--Mirror Galvanometer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer Shunt.</span><br>
-To prevent too much current passing through a galvanometer (for fear of<br>
-injury to its insulation) a shunt is sometimes placed in parallel with<br>
-it. The total current will be distributed between galvanometer and shunt<br>
-in the inverse ratio of their respective resistances. (See Multiplying<br>
-Power of a Shunt.)<br>
-<br>
-<br>
-272&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 555px; height: 728px;" alt=""
- src="images/271F184.jpg"><br>
-Fig. 184. SINE GALVANOMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Sine.</span><br>
-A galvanometer whose measurements depend upon the sine of the angle of<br>
-deflection produced when the coil and needle lie in the same vertical<br>
-plane.<br>
-<br>
-The needle, which may be a long one, is surrounded by a coil, which can<br>
-be rotated about a vertical axis passing through the point of suspension<br>
-of the needle. Starting with the needle at rest in the plane of the<br>
-coil, a current is passed through the coil deflecting the needle, the<br>
-coil is swung around deflecting the needle still more, until the needle<br>
-lies in the plane of the coil; the intensity of the current will then be<br>
-in proportion to the sine of the angle through which the coil and needle<br>
-move.<br>
-<br>
-In the galvanometer M is a circle carrying the coil, N is a scale over<br>
-which the needles, m and n, move, the former being a magnetic needle,<br>
-the latter an index at right angles and attached thereto; a and b are<br>
-wires carrying the current to be measured. The circles, M and N, are<br>
-carried by a base, O, around which they rotate. H is a fixed horizontal<br>
-graduated circle. In use the circle, M, is placed in the magnetic<br>
-meridian, the current is passed through the coil, M; the needle is<br>
-deflected; M is turned until its plane coincides with the direction of<br>
-the needle, m. The current strength is proportional to the sine of the<br>
-angle of deflection. This angle is measured by the vernier, C, on the<br>
-circle, H. The knob, A, is used to turn the circle, M.<br>
-<br>
-<br>
-273&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 614px; height: 754px;" alt=""
- src="images/272F185.jpg"><br>
-Fig. 185. TANGENT GALVANOMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Tangent.</span><br>
-A galvanometer in which the tangents of the angles of deflection are<br>
-proportional to the currents producing such deflections.<br>
-<br>
-For this law to apply the instrument in general must fulfill the<br>
-following conditions:<br>
-<br>
-(1) The needle must be controlled by a uniform magnetic field such as<br>
-that of the earth;<br>
-<br>
-(2) the diameter of the coil must be large compared to the length of the<br>
-needle;<br>
-<br>
-(3) the centre of suspension of the needle must be at the centre of the<br>
-coil;<br>
-<br>
-(4) the magnetic axis of the needle must lie in the plane of the coil<br>
-when no current is passing.<br>
-<br>
-If a single current strength is to be measured the best results will be<br>
-attained when the deflection is 45&deg;; in comparing two currents the
-best<br>
-results will be attained when the deflections as nearly as possible are<br>
-at equal distances on both sides of 45&deg;.<br>
-<br>
-The needle should not exceed in length one-tenth the diameter of the<br>
-coil.<br>
-<br>
-For very small deflections any galvanometer follows the law of<br>
-tangential deflection.<br>
-<br>
-As for very small deflections the tangents are practically equal to the<br>
-arcs subtended, for such deflections the currents are proportional to<br>
-the deflections they produce.<br>
-<br>
-The sensibility is directly proportional to the number of convolutions<br>
-of wire and inversely proportional to their diameter.<br>
-<br>
-The tangent law is most accurately fulfilled when the depth of the coil<br>
-in the radial direction is to the breadth in the axial direction as<br>
-squareRoot(3):squareRoot(2), or about as 11:9.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Torsion.</span><br>
-A galvanometer whose needle is suspended by a long filament or by a<br>
-thread and spiral spring against whose force of torsion the movements of<br>
-the needle are produced. The current strength is determined by bringing<br>
-the needle back to its position of rest by turning a hand-button or<br>
-other arrangement. The angle through which this is turned gives the<br>
-angle of torsion. From this the current strength is calculated on the<br>
-general basis that it is proportional to the angle of torsion.<br>
-<br>
-<br>
-<img style="width: 483px; height: 752px;" alt=""
- src="images/273F186.jpg"><br>
-Fig. 186. TORSION GALVANOMETER.<br>
-<br>
-<br>
-274&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Galvanometer, Vertical.</span><br>
-A galvanometer whose needle is mounted on a horizontal axis and is<br>
-deflected in a vertical plane. One of the poles is weighted to keep it<br>
-normally vertical, representing the control. It is not used for accurate<br>
-work.<br>
-<br>
-Synonym--Upright Galvanometer.<br>
-<br>
-<br>
-<img style="width: 513px; height: 590px;" alt=""
- src="images/274F187.jpg"><br>
-Fig. 187. VERTICAL GALVANOMETER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanometer, Volt- and Ampere-meter. </span><br>
-A galvanometer of Sir William Thomson's invention embodying the tangent
-<br>
-principle, and having its sensibility adjustable by moving the magnetic
-<br>
-needle horizontally along a scale (the "meter") towards or away from
-the <br>
-coil. A curved magnet is used to adjust the control. The leads are <br>
-twisted to prevent induction.<br>
-<br>
-The instrument is made with a high resistance coil for voltage<br>
-determinations, and with a low resistance coil for amperage<br>
-determinations.<br>
-<br>
-At one end of a long base board a vertical coil with its plane at right<br>
-angles to the axis of the board is mounted. A scale (the "meter" of the<br>
-name) runs down the centre of the board. A groove also runs down the<br>
-centre. The magnetic needle is contained in a quadrant-shaped<br>
-glass-covered box which slides up and down the groove. A number of short<br>
-parallel needles mounted together, with an aluminum pointer are used.<br>
-<br>
-<br>
-</big></big><big><big><img style="width: 647px; height: 308px;" alt=""
- src="images/274F188.jpg"></big></big><br>
-<big><big>Fig. 188. SIR WILLIAM THOMSON'S <br>
-AMPERE-METER GALVANOMETER.<br>
-<br>
-<br>
-275&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-In the cut P is the base board, M is a glass covered case containing the<br>
-magnetic needle, and sliding along the base board, being guided by the<br>
-central groove, C, is the coil. Between the coil and the needle is the<br>
-arched or bent controlling magnet. The long twisted connecting wires are<br>
-seen on the right hand.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvano-plastics.</span><br>
-The deposition of metals by electrolysis, a disused term replaced<br>
-by electro-deposition, electroplating, and electro-metallurgy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvano-puncture.</span><br>
-An operation in medical electricity. (See Electro-puncture.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Galvanoscope.</span><br>
-An instrument, generally of the galvanometer type, used for ascertaining<br>
-whether a current is flowing or not. Any galvanoscope, when calibrated,<br>
-if susceptible thereof, becomes a galvanometer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gas, Electrolytic.</span><br>
-Gas produced by the decomposition, generally of water, by electrolysis.<br>
-It may be hydrogen or oxygen, or a mixture of the two, according to how<br>
-it is collected. (See Gases, Mixed.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gases, Mixed.</span><br>
-The mixture of approximately one volume of oxygen and two volumes of<br>
-hydrogen collected in the eudiometer of a gas voltameter or other<br>
-electrolytic apparatus.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gassing.</span><br>
-The evolution of gas from the plates of a storage battery in the<br>
-charging process, due to too high voltage in the circuit of the charging<br>
-dynamo.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gastroscope.</span><br>
-An apparatus for illuminating by an incandescent lamp the interior of<br>
-the stomach, and with prisms to refract the rays of light so that the<br>
-part can be seen. The stomach is inflated with air, if desirable, to<br>
-give a better view. An incandescent platinum spiral in a water jacket<br>
-has been employed for the illumination.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gassiot's Cascade.</span><br>
-A goblet lined for half its interior surface with tinfoil. It is placed<br>
-in the receiver of an air pump from the top of whose bell a conductor<br>
-descends into it, not touching the foil. On producing a good<br>
-rarefaction, and discharging high tension electricity from between the<br>
-conductor just mentioned and the metal of the machine, a luminous effect<br>
-is produced, as if the electricity, pale blue in color, was overflowing<br>
-the goblet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gauss.</span><br>
-A name suggested for unit intensity of magnetic field. Sylvanus P.<br>
-Thomson proposed for its value the intensity of a field of 1E8 C. G. S.<br>
-electro-magnetic units. J. A. Fleming proposed the strength of field<br>
-which would develop one volt potential difference in a wire 1E6<br>
-centimeters long, moving through such field with a velocity of one<br>
-centimeter per second. This is one hundred times greater than Thomson's<br>
-standard. Sir William Thomson suggested the intensity of field produced<br>
-by a current of one ampere at a distance of one centimeter<br>
-<br>
-The gauss is not used to any extent; practical calculations are based on<br>
-electro-magnetic lines of force.<br>
-<br>
-<br>
-276&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gauss' Principle.</span><br>
-An electric circuit acts upon a magnetic pole in such a way as to make<br>
-the number of lines of force that pass through the circuit a maximum.<br>
-<br>
-<br>
-<img style="width: 643px; height: 434px;" alt=""
- src="images/276F189.jpg"><br>
-Fig. 189. GAUSS' TANGENT POSITION.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gauss, Tangent Positions of.</span><br>
-The "end on" and "broadside" methods of determining magnetization<br>
-involve positions which have been thus termed. (See Broadside Method and<br>
-End on Method.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gear, Magnetic Friction.</span><br>
-Friction gear in which the component wheels are pressed against each<br>
-other by electromagnetic action. In the cut, repeated from Adherence,<br>
-Electro-magnetic, the magnetizing coil makes the wheels, which are of<br>
-iron, press strongly together.<br>
-<br>
-<br>
-<img style="width: 507px; height: 660px;" alt=""
- src="images/276F190.jpg"><br>
-Fig. 190. MAGNETIC FRICTION GEAR.<br>
-<br>
-<br>
-277&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Geissler Tubes.</span><br>
-Sealed tubes of glass containing highly rarefied gases, and provided<br>
-with platinum electrodes extending through the glass tightly sealed as<br>
-they pass through it, and often extending a short distance beyond its<br>
-interior surface.<br>
-<br>
-On passing through them the static discharge luminous effects are<br>
-produced varying with the degree of exhaustion, the contents (gas), the<br>
-glass itself, or solutions surrounding it. The two latter conditions<br>
-involve fluorescence phenomena often of a very beautiful description.<br>
-<br>
-The pressure of the gas is less than one-half of a millimeter of<br>
-mercury. If a complete vacuum is produced the discharge will not pass.<br>
-If too high rarefaction is produced radiant matter phenomena (see<br>
-Radiant State) occur.<br>
-<br>
-Geissler tubes have been used for lighting purposes as in mines, or for<br>
-illuminating the interior cavities of the body in surgical or medical<br>
-operations.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Generating Plate.</span><br>
-The positive plate in a voltaic couple, or the plate which is dissolved;<br>
-generally a plate of zinc.<br>
-<br>
-Synonyms--Positive Plate--Positive Element.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Generator, Current.</span><br>
-Any apparatus for maintaining an electric current. It may be as regards<br>
-the form of energy it converts into electrical energy, mechanical, as a<br>
-magneto or dynamo electric machine or generator; thermal, as a<br>
-thermo-electric battery; or chemical, as a voltaic battery; all of which<br>
-may be consulted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Generator, Secondary.</span><br>
-A secondary or storage battery. (See Battery, Secondary.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">German Silver.</span><br>
-An alloy of copper, 2 parts, nickel, 1 part, and zinc, 1 part. Owing to<br>
-its high resistance and moderate cost and small variation in resistance<br>
-with change of temperature, it is much used for resistances. From Dr.<br>
-Mathiessen's experiment the following constants are deduced in legal<br>
-ohms:<br>
-&nbsp; <small><span style="font-family: monospace;">Relative
-Resistance (Silver = 1),&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-13.92</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Specific Resistance at
-0&deg; C. (32F.),&nbsp;&nbsp; 20.93
-microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a wire,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long, weighing
-1 grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.622&nbsp;&nbsp; ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 1 foot long, 1/1000 inch
-thick,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-125.91&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 1 meter long, weighing 1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.830&nbsp;&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 1 meter long, 1 millimeter
-thick,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 0.2666&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a 1 inch
-cube at 0&deg;C. (32&deg;
-F.),&nbsp;&nbsp; 8.240 microhms.</span></small><br>
-<br>
-Approximate percentage increase of resistance per 1&deg; C. (1.8&deg;
-F.) at<br>
-about 20&deg; C. (68&deg; F.), 0.044 per cent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gilding, Electro-.</span><br>
-The deposition of gold by an electric current, or electrolytically in<br>
-the electroplating bath.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gilding Metal.</span><br>
-A special kind of brass, with a high percentage of copper, used to make<br>
-objects which are to be gilded by electrolysis.<br>
-<br>
-<br>
-278&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gimbals.</span><br>
-A suspension used for ships' compasses and sometimes for other<br>
-apparatus. It consists of a ring held by two journals, so as to bc free<br>
-to swing in one plane. The compass is swung upon this ring, being placed<br>
-concentrically therewith. Its journals are at right angles to those of<br>
-the ring. This gives a universal joint by which the compass, weighted<br>
-below its line of support, is always kept horizontal.<br>
-<br>
-<br>
-<img style="width: 697px; height: 495px;" alt=""
- src="images/278F191.jpg"><br>
-Fig. 191. COMPASS SUSPENDED IN GIMBALS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Glass.</span><br>
-A fused mixture of silicates of various oxides. It is of extremely<br>
-varied composition and its electric constants vary greatly. Many<br>
-determinations of its specific resistance have been made. For flint<br>
-glass at 100&deg; C. (212&deg; F.) about (2.06E14) ohms --at 60&deg; C
-(140&deg; F.)<br>
-(1.020E15) (Thomas Gray) is given, while another observer (Beetz) gives<br>
-for glass at ordinary temperatures an immeasurably high resistance. It<br>
-is therefore a non-conductor of very high order if dry. As a dielectric<br>
-the specific inductive capacity of different samples of flint glass is<br>
-given as 6.57--6.85--7.4--10.1 (Hopkinson), thus exceeding all other<br>
-ordinary dielectrics. The densest glass, other things being equal, has<br>
-the highest specific inductive capacity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gold.</span><br>
-A metal, one of the elements; symbol Au. c .; atomic weight, 196.8;<br>
-equivalent, 65.6; valency, 3; specific gravity 19.5.<br>
-It is a conductor of electricity.<br>
-<small><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Annealed.&nbsp;&nbsp; Hard drawn.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Relative Resistance (Annealed
-Silver = 1),&nbsp;&nbsp;
-1.369&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1.393</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Specific
-Resistance,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.058&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2.094</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a wire at 0&deg; C.
-(32&deg;F.)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">(a) 1 foot long, weighing 1
-grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-57.85&nbsp;&nbsp;&nbsp;&nbsp; 58.84&nbsp;&nbsp; ohms</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(b) 1 foot long, 1/1000 inch
-thick,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-12.38&nbsp;&nbsp;&nbsp;&nbsp; 12.60&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(c) 1 meter long, weighing 1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.4035&nbsp;&nbsp;&nbsp;&nbsp; .4104&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(d) 1 meter long, 1 millimeter
-thick,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.02620&nbsp;&nbsp;&nbsp; .02668 "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a 1 inch cube at
-0&deg; C.(32&deg; F.)&nbsp;
-.8102&nbsp;&nbsp;&nbsp;&nbsp; .8247</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">Approximate increase in
-resistance per 0&deg; C., (1.8&deg; F)</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">at about 20&deg; C. (68&deg; F.),
-0.365 per cent.</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">Electro-chemical equivalent
-(Hydrogen = .0105), .6888</span></small>
-<br>
-<br>
-<br>
-279&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gold Bath.</span><br>
-A solution of gold used for depositing the metal in the electroplating<br>
-process.<br>
-<br>
-A great number of formulae have been devised, of which a few<br>
-representative ones are given here.<br>
-<small><span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-COLD
-BATHS.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-HOT BATHS.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-10,000&nbsp; 10,000&nbsp; 10,000&nbsp; 10,000&nbsp;&nbsp; 5,000&nbsp;
-3,000</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Potassium
-Cyanide,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-200&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;
-200&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-10&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp; 50</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Gold,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-100&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-15&nbsp;&nbsp;&nbsp;&nbsp;
-100&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-10&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 10&nbsp;&nbsp;&nbsp;&nbsp; 10</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Potassium Ferrocyanide,&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;
-200&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp;
-150&nbsp;&nbsp;&nbsp;&nbsp; --</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Potassium
-Carbonate,&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;
-150&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-50&nbsp;&nbsp;&nbsp;&nbsp; --</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Ammonium
-Chloride,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-30&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-20&nbsp;&nbsp;&nbsp;&nbsp; --</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Aqua
-Ammoniae,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp;
-500&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp; --</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Sodium
-Phosphate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp;
-600&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp; --</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Sodium
-Bisulphite,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
---&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp;
-100&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; --&nbsp;&nbsp;&nbsp;&nbsp; --</span></small><br>
-<br>
-(Roseleur.)<br>
-<br>
-In the baths the gold is added in the form of neutral chloride, Auric<br>
-chloride (Au Cl6).<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Gold Stripping Bath</span>.<br>
-A bath for removing gold from plated articles without dissolving the<br>
-base in order to save the precious metal. A bath of 10 parts of<br>
-potassium cyanide and 100 parts of water may be used, the articles to be<br>
-stripped being immersed therein as the anode of an active circuit. If<br>
-the gilding is on a silver or copper basis, or on an alloy of these<br>
-metals the same solution attacks the base and dissolves it, which is<br>
-objectionable. For silver articles it is enough to heat to cherry red<br>
-and throw into dilute sulphuric acid. The gold scales off in metallic<br>
-spangles. For copper articles, a mixture of 10 volumes concentrated<br>
-sulphuric acid, 1 volume nitric acid, and 2 volumes hydrochloric acid<br>
-may be used by immersion only, or with a battery. The sulphuric acid in<br>
-such large excess is supposed to protect the copper. For copper articles<br>
-concentrated sulphuric acid alone with the battery may be used. This<br>
-does not sensibly attack the copper if it is not allowed to become<br>
-diluted. Even the dampness of the air may act to dilute it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Graduator.</span><br>
-Apparatus for enabling the same line to be used for telegraph signals<br>
-and telephoning.<br>
-<br>
-One type consists in coils with iron cores or simply electromagnets.<br>
-These act to retard the current in reaching its full power and also<br>
-prolong it. This gives a graduated effect to the signals, so that the<br>
-telephone diaphragm is not audibly affected by the impulses.<br>
-<br>
-The telephoning current is so slight and so rapid in its characteristic<br>
-changes that it is without effect upon the ordinary telegraph.<br>
-<br>
-<br>
-280&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gram. </span><br>
-The unit of weight in the metric system; accepted as the unit of<br>
-mass in the absolute of C. G. S. system of units. It is the<br>
-one-thousandth part of mass of a standard weight preserved under proper<br>
-conditions in Paris, and supposed to be the mass of a cubic decimeter of<br>
-distilled water at the temperature of the maximum density of water. The<br>
-standard is the kilogram; the temperature is 3.9&ordm; C. (39&ordm;
-F.). The<br>
-standard kilogram is found to be not exactly the weight of a cubic<br>
-decimeter of water, the latter weighing 1.000013 kilogram.<br>
-<br>
-If therefore the defined gram on the water basis is taken as the unit it<br>
-varies very slightly from the accepted gram.<br>
-<br>
-1 gram is equal to 15.43234874 grains. (Prof. W. H. Miller.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Gram-atom.</span><br>
-The number of grams of an element equal numerically to the atomic<br>
-weight, as 16 grams of oxygen, 1 gram of hydrogen, 35.5 grams of<br>
-chlorine; all which might be expressed as gram-atoms of oxygen, hydrogen<br>
-and chlorine respectively.<br>
-<br>
-The gram-atom approximately expresses the number of gram-calories<br>
-required to heat one gram of the substance 1&ordm; C. (1.8&ordm; F.).
-This is in<br>
-virtue of Dulong and Petit's discovery that the atomic weight of an<br>
-element multiplied by its specific heat gives approximately a constant<br>
-for all elements.<br>
-<br>
-[Transcriber's note: A gram-atom is the mass, in grams, of one mole of<br>
-atoms in a monatomic element. A mole consists of Avogadro's number of<br>
-atoms, approximately 6.02214E23.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gram-molecule.</span><br>
-The number of grams of a substance equal numerically to its molecular<br>
-weight.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Graphite.</span><br>
-Carbon; one of three allotropic modifications of this element. It occurs<br>
-in nature as a mineral.<br>
-<br>
-It is used as a lubricant for machinery; for commutator brushes; for<br>
-making surfaces to be plated conductive, and for mixing with manganese<br>
-binoxide in Leclanch&eacute; cells.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gravitation.</span><br>
-A natural force which causes all masses of matter to attract each other.<br>
-Its cause is unknown; it is often supposed to be due to the luminiferous<br>
-ether.<br>
-<br>
-[Transcriber's note: Einstein's explanation of gravity, General<br>
-Relativity and the curvature of space-time, came 23 years later, 1915.]<br>
-<br>
-<br>
-281&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gravity, Acceleration of.</span><br>
-The velocity imparted to a body in one second by the action of<br>
-gravitation at any standard point upon the earth's surface in a vacuum.<br>
-This will vary at different places, owing principally to the variation<br>
-in centrifugal force due to the earth's rotation. For standard valuation<br>
-it must be reduced to sea level. The following are examples of its<br>
-variation:<br>
-<br>
-<small><span style="font-family: monospace;">Equator,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-978.1028&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; centimeters per second</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Paris,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-980.94&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Greenwich&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-981.I7&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Edinburgh,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-981.54&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Pole (N. or S.),&nbsp; 983.1084
-(theoretical)&nbsp;&nbsp; "</span></small><br>
-<br>
-As round numbers for approximate calculations 981 centimeters or 32.2<br>
-feet may be employed.<br>
-<br>
-[Transcriber's note: The acceleration of gravity at the equator is also<br>
-reduced by the increased distance from the center of the earth<br>
-(equatorial bulge). Increased altitude reduces gravity. Reduced air<br>
-density at altitude reduces buoyancy and increases apparent weight.<br>
-Local variations of rock density affects gravity.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gravity, Control.</span><br>
-Control by weight. In some ammeters and voltmeters gravity is the<br>
-controlling force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Grid.</span><br>
-A lead plate perforated or ridged for use in a storage battery as the<br>
-supporter of the active materials and in part as contributing thereto<br>
-from its own substance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ground.</span><br>
-The contact of a conductor of an electric circuit with the earth,<br>
-permitting the escape of current if another ground exists.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ground-wire.</span><br>
-A metaphorical term applied to the earth when used as a return circuit.<br>
-<br>
-<br>
-<img style="width: 664px; height: 487px;" alt=""
- src="images/281F192.jpg"><br>
-Fig. 192. GROVE'S GAS BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Grove's Gas Battery.</span><br>
-A voltaic battery depending for its action on the oxidation of hydrogen<br>
-instead of the oxidation of zinc. Its action is more particularly<br>
-described under Battery, Gas. In the cut B, B1 * * * are the terminals<br>
-of the positive or hydrogen electrodes, marked H, and A, Al * * * are<br>
-the terminals of the negative or oxygen electrodes marked O, while M, M1<br>
-* * * is dilute sulphuric acid.<br>
-<br>
-<br>
-282&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Guard Ring.</span><br>
-An annular horizontal surface surrounding the balanced disc in the<br>
-absolute electrometer. (See Electrometer, Absolute.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Guard Tube.</span><br>
-A metal tube surrounding a dry pile used with a quadrant electrometer,<br>
-or other electrometers of that type. It prevents the capacity of the<br>
-lower brass end of the pile (which brass end closes the glass tube<br>
-containing the discs) from momentary change by approach of some<br>
-conductor connected to the earth. There are other guard tubes also.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Gun, Electro-magnetic.</span><br>
-An electro-magnet with tubular core. If, when it is excited a piece of<br>
-an iron rod is pushed into the central aperture of the core and is<br>
-released, the magnetic circle will try to complete itself by pushing the<br>
-rod out so that it can thus be discharged, as if from a popgun.<br>
-<br>
-Synonym--Electric Popgun.<br>
-<br>
-<br>
-<img style="width: 564px; height: 454px;" alt=""
- src="images/282F193.jpg"><br>
-Fig. 193. "ELECTRIC POPGUN."<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Gutta Percha.</span><br>
-The hardened milky juice of a tree, the Isonandra gutta, growing in<br>
-Malacca and other parts of the Eastern Archipelago. It is much used as<br>
-an insulator or constituent of insulators.<br>
-<br>
-Resistance after several minutes electrification per 1 centimeter cube<br>
-at 54&ordm; C. (75&ordm; F.),&nbsp; 4.50E14 ohms.<br>
-<br>
-The specific resistance varies--from 2.5E13 to 5.0E14 ohms. A usual<br>
-specification is 2.0E14 ohms. The influence of temperature on its<br>
-resistance is given in Clark &amp; Bright's empirical formula, R = R0
-at, in<br>
-which R is the resistance at temperature t&ordm; C--Ro the resistance
-at 0&ordm; C<br>
-(32&ordm; F), a is the coefficient .8944.<br>
-<br>
-The resistance increases with the time of passage of the current, the<br>
-variation being less the higher the temperature.<br>
-<br>
-<br>
-283&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<small><span style="font-family: monospace;">Time
-of&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Relative Resistance&nbsp;&nbsp;&nbsp;&nbsp; Relative Resistance</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Electrification.&nbsp;&nbsp; at
-0&ordm; C (32&ordm;
-F.)&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; at 24&ordm; C (75&ordm;
-F.)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp; 1
-minute&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-100&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5.51</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp; 2&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-127.9&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-6.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp; 5&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-163.1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-6.66</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 10&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-190.9&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-6.94</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 20&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-230.8&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7.38</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 30&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-250.6&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7.44</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 60&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-290.4&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7.6</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 90&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-318.3&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7.66</span></small><br>
-<br>
-In cable testing one minute is generally taken as the time of<br>
-electrification.<br>
-<br>
-Pressure increases the resistance by the formula Rp=R (1+ .00327 P) in<br>
-which Rp is the resistance at pressure p--R resistance at atmospheric<br>
-pressure--p pressure in atmospheres. Thus in the ocean at a depth of<br>
-4,000 meters (2.4855 miles), the resistance is more than doubled. The<br>
-longer the pressure is applied, the greater is the resistance.<br>
-<br>
-The specific inductive capacity of gutta percha is 4.2.<br>
-<br>
-Good gutta percha should not break when struck with a hammer, should<br>
-recover its shape slowly, and it should support much more than 300 times<br>
-its own weight.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Gyrostatic Action of Armatures.</span><br>
-Owing to gyrostatic action a rotating armature resists any change of<br>
-direction of its axis. On ships and in railway motors which have to turn<br>
-curves this action occurs. A 148 lb. armature running at 1,300<br>
-revolutions per minute may press with 30 lbs. on each journal as the<br>
-ship rolls through an angle of 20&deg; in 16 seconds.<br>
-</big></big><br>
-<big><big><br>
-</big></big><big><big><br>
-283&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<small><span style="font-family: monospace;"></span></small><span
- style="font-weight: bold;">H.</span><br>
-(a) The symbol for the horizontal component of the earth's<br>
-magnetization.<br>
-<br>
-(b) The symbol for the intensity of a magnetizing force or field. The<br>
-symbol H, as it is generally used, may mean either the number of dynes<br>
-which act upon a unit pole, or the number of lines of force per<br>
-centimeter.<br>
-<br>
-(c) The symbol for the unit of self-induction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hair, Removal of, by Electrolysis.</span><br>
-A method of depilation by destruction of individual hair follicles by<br>
-electrolysis.<br>
-<br>
-A fine platinum electrode is thrust into a hair follicle. It is the<br>
-negative electrode. The positive electrode is in contact with the body<br>
-of the person under treatment; it is often a sponge electrode simply<br>
-held in his hand. A current of two to four milliamperes from an E. M. F.<br>
-of 15 to 20 volts, is passed. This destroys the follicle, the hair is<br>
-removed and never grows again. A gradual increase of current is advised<br>
-for the face. As only one hair is removed at once, but a small number<br>
-are taken out at a sitting.<br>
-<br>
-<br>
-284&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Haldat's Figures.</span><br>
-With a pole of a strong bar magnet, used like a pencil, imaginary<br>
-figures are drawn upon a hard steel plate, such as a saw-blade. The<br>
-pattern is gone over several times. By dusting iron filings on a sheet<br>
-of paper laid over the steel plate, while horizontal, very complicated<br>
-magnetic figures are produced.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Hall's Experiment.</span><br>
-A cross of thin metal, such as gold leaf, is secured upon a pane of<br>
-glass. To two opposite arms a battery is connected in circuit with them.<br>
-To the other two arms a galvanometer is connected in circuit. If the<br>
-cross is put into a field of force whose lines are perpendicular<br>
-thereto, the galvanometer will disclose a constant current. The current<br>
-is pushed, as it were, into the galvanometer circuit. Other metals have<br>
-been used with similar results. They must be thin or the experiment<br>
-fails. If the arm receiving the battery current is horizontal, and if it<br>
-flows from left to right, and if the lines of force go from downward<br>
-through the cross, the current in the galvanometer circuit will flow<br>
-from the observer through the other arms of the cross, if the cross is<br>
-of gold, silver, platinum or tin, and the reverse if of iron. The<br>
-experiment has indicated a possible way of reaching the velocity of<br>
-electricity in absolute measure.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hall Effect.</span><br>
-The effect observed in Hall's experiment, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hall Effect, Real.</span><br>
-A transverse electro-motive force in a conductor through which a current<br>
-is passing produced by a magnetic field.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hall Effect, Spurious.</span><br>
-A spurious electro-motive force produced in a conductor, through which a<br>
-current is passing by changes in conductivity of the conductor brought<br>
-about by a magnetic field.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hanger Board.</span><br>
-A board containing two terminals, a suspending hook, and a switch, so<br>
-that an arc lamp can be introduced into a circuit thereby, or can be<br>
-removed as desired.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Harmonic Receiver.</span><br>
-A receiver containing a vibrating reed, acted on by an electro-magnet.<br>
-Such a reed answers only to impulses tuned to its own pitch. If such are<br>
-received from the magnet it will vibrate. Impulses not in tune with it<br>
-will not affect it. (See Telegraph, Harmonic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Head Bath, Electric.</span><br>
-A fanciful name for an electro-medical treatment of the head. The<br>
-patient is insulated by an insulating stool or otherwise. His person is<br>
-connected with one terminal of an influence machine. An insulated<br>
-metallic circle, with points of metal projecting inward or downward, is<br>
-placed about the head. The circle is connected with the other pole of<br>
-the machine. On working it a silent or brush discharge with air<br>
-convection streams occurs between the patient's head and the circle of<br>
-points.<br>
-<br>
-<br>
-285&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Head-light, Electric.</span><br>
-An electric head-light for locomotives has been experimented with. It<br>
-includes the parabolic reflection of the regular light with an arc-lamp<br>
-in place of the oil lamp. An incandescent lamp may be used in the same<br>
-place, but has no great advantage over oil as regards illuminating<br>
-power.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat.</span><br>
-A form of kinetic energy, due to a confused oscillatory movement of the<br>
-molecules of a body. Heat is not motion, as a heated body does not<br>
-change its place; it is not momentum, but it is the energy of motion. If<br>
-the quantity of molecular motion is doubled the momentum of the<br>
-molecules is also doubled, but the molecular mechanical energy or heat<br>
-is quadrupled.<br>
-<br>
-As a form of energy it is measured by thermal units. The calorie is the<br>
-most important, and unfortunately the same term applies to two units,<br>
-the gram-degree C. and the kilogram-degree C. (See Calorie.) Calories<br>
-are determined by a calorimeter, q. v.<br>
-<br>
-Independent of quantity of heat a body may be hotter or colder.<br>
-Thermometers are used to determine its temperature.<br>
-<br>
-Heat is transmitted by conduction, a body conducting it slowly for some<br>
-distance through its own substance. Bodies vary greatly in their<br>
-conductivity for heat. It is also transmitted by convection of gases or<br>
-liquids, when the heated molecules traveling through the mass impart<br>
-their heat to other parts. Finally it is transmitted by ether waves with<br>
-probably the speed of light. This mode of transmission and the phenomena<br>
-of it were attributed to radiant heat. As a scientific term this is now<br>
-dropped by many scientists. This practice very properly restricts the<br>
-term "heat" to kinetic molecular motion.<br>
-<br>
-The mechanical equivalent of heat is the number of units of work which<br>
-the energy of one unit quantity of heat represents. (See Equivalents,<br>
-Mechanical and Physical.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Atomic.</span><br>
-The product of the specific heat of an element by its atomic weight. The<br>
-product is approximately the same for all the elements, and varies as<br>
-determined between 5.39 and 6.87. The variations are by some attributed<br>
-principally to imperfection of the work in determining them. The atomic<br>
-heat represents the number of gram calories required to raise the<br>
-temperature of a gram atom (a number of grams equal numerically to the<br>
-atomic weight) one degree centigrade.<br>
-<br>
-<br>
-286&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Electric.</span><br>
-This term has been given to the heat produced by the passage of a<br>
-current of electricity through a conductor. It is really electrically<br>
-produced heat, the above term being a misnomer.<br>
-<br>
-The rise of temperature produced in a cylindrical conductor by a current<br>
-depends upon the diameter of the conductor and on the current. The<br>
-length of the wire has only the indirect connection that the current<br>
-will depend upon the resistance and consequently upon its length.<br>
-<br>
-The quantity of heat produced in a conductor by a current is in<br>
-gram-degree C. units equal to the product of the current, by the<br>
-electro-motive force or potential difference maintained between the ends<br>
-of the wire, by .24.<br>
-<br>
-The cube of the diameter of a wire for a given rise of temperature<br>
-produced in such conductor by a current is equal approximately to the<br>
-product of the square of the current, by the specific resistance (q. v.)<br>
-of the material of the conductor, by .000391, the whole divided by the<br>
-desired temperature in centigrade units.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Electrical Convection of.</span><br>
-A term applied to the phenomena included under the Thomson effect, q.<br>
-v., the unequal or differential heating effect produced by a current of<br>
-electricity in conductors whose different parts are maintained at<br>
-different temperatures.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heater, Electric.</span><br>
-An apparatus for converting electrical energy into thermal energy.<br>
-<br>
-An incandescent lamp represents the principle, and in the Edison meter<br>
-has been used as such to maintain the temperature of the solutions.<br>
-Heaters for warming water and other purposes have been constructed,<br>
-utilizing conductors heated by the passage of the current as a source of<br>
-heat. (See also Heating Magnet.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heating Error.</span><br>
-In voltmeters the error due to alteration of resistance of the coil by<br>
-heating. If too strong a current is sent through the instrument, the<br>
-coils become heated and their resistance increased. They then do not<br>
-pass as much current as they should for the potential difference to<br>
-which they may be exposed. Their readings then will be too low. One way<br>
-of avoiding the trouble is to have a key in circuit, and to pass only an<br>
-instantaneous or very brief current through the instrument and thus get<br>
-the reading before the coils have time to heat.<br>
-<br>
-The heating error does not exist for ammeters, as they are constructed<br>
-to receive the entire current, and any heating "error" within their<br>
-range is allowed for in the dividing of the scale.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heating Magnet.</span><br>
-An electro-magnet designed to be heated by Foucault currents induced in<br>
-its core by varying currents in the windings. It has been proposed as a<br>
-source of artificial heat, a species of electric heating apparatus for<br>
-warming water, or other purposes.<br>
-<br>
-<br>
-287&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Irreversible.</span><br>
-The heat produced by an electric current in a conductor of identical<br>
-qualities and temperature throughout. Such heat is the same whatever the<br>
-direction of the current. The heating effect is irreversible because of<br>
-the absence of the Thomson effect, q. v.) or Peltier effect, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Mechanical Equivalent of.</span><br>
-The mechanical energy corresponding to a given quantity of heat energy.<br>
-Mechanical energy is generally represented by some unit of weight and<br>
-height, such as the foot-pound; and heat energy is represented by a<br>
-given weight of water heated a given amount, such as a pound-degree<br>
-centigrade. Joule's equivalent is usually accepted; it states that<br>
-772.55 foot pounds of mechanical energy are equivalent to 1 pound-degree<br>
-F. (one pound avds. of water raised in temperature one degree<br>
-Fahrenheit). Other equivalencies have also been deduced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Molecular.</span><br>
-The product of a specific heat of the compound by its molecular weight.<br>
-It is approximately equal to the sum of the atomic heats of its<br>
-constituent elements.<br>
-<br>
-The molecular heat represents the number of gram calories required to<br>
-raise the temperature of a gram-molecule (a number of grams equal<br>
-numerically to the molecular weight) one degree centigrade.<br>
-<br>
-The molecular heat is approximately equal for all substances.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Specific.</span><br>
-The capacity of a body for heat; a coefficient representing the relative<br>
-quantity of heat required to raise the temperature of an identical<br>
-weight of a given body a defined and identical amount.<br>
-<br>
-The standard of comparison is water; its specific heat is taken as<br>
-unity. The specific heats by weight of other substances are less than<br>
-unity. The specific heat varies with the temperature. Thus the specific<br>
-heat of water is more strictly 1+.00015 t&ordm; C.<br>
-<br>
-Specific heat is greater when a substance is in the liquid than when it<br>
-is in the solid state. Thus the specific heat of ice is 0.489; less<br>
-than half that of water. It differs with the allotropic modifications of<br>
-bodies; the specific heat of graphite is .202; of diamond, .147.<br>
-<br>
-The product of the specific heat by the atomic weight of elements gives<br>
-a figure approximately the same. A similar law applies in the case of<br>
-molecules. (See Heat, Atomic-Heat, Molecular.)<br>
-<br>
-The true specific heat of a substance should be separated from the heat<br>
-expended in expanding a body against molecular and atomic forces, and<br>
-against the atmospheric pressure. So far this separation has not been<br>
-possible to introduce in any calculations.<br>
-<br>
-<br>
-288&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat, Specific, of Electricity.</span><br>
-A proposed term to account for the heat absorbed or given out in<br>
-unhomogeneous conductors, by the Thomson effect, or Peltier effect (see<br>
-Effect, Thomson--Effect, Peltier.) If a current of electricity be<br>
-assumed to exist, then under the action of these effects it may be<br>
-regarded as absorbing or giving out so many coulombs of heat, and thus<br>
-establishing a basis for specific heat.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heat Units.</span><br>
-The British unit of heat is the pound degree F--the quantity of heat<br>
-required to raise the temperature of a pound of water from 32&deg; to
-33&deg; F.<br>
-<br>
-The C. G. S. unit is the gram-degree C.; another metric unit is the<br>
-kilogram-degree C. The latter is the calorie; the former is sometimes<br>
-called the small calorie or the joule; the latter is sometimes called<br>
-the large calorie. The term joule is also applied to a quantity of heat<br>
-equivalent to the energy of a watt-second or volt-coulomb. This is equal<br>
-to .24l gram degree calorie.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hecto.</span><br>
-A prefix to terms of measurement--meaning one hundred times, as<br>
-hectometer, one hundred meters.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heliograph.</span><br>
-An apparatus for reflecting flashes of light to a distant observer. By<br>
-using the Morse telegraph code messages may thus be transmitted long<br>
-distances. When possible the sun's light is used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Helix.</span><br>
-A coil of wire; properly a coil wound so as to follow the outlines of a<br>
-screw without overlaying itself.<br>
-<br>
-<br>
-<img style="width: 712px; height: 299px;" alt=""
- src="images/288F194_195.jpg"><br>
-Fig. 194. LEFT-HANDED HELIX.<br>
-<br>
-Fig. 195. RIGHT-HANDED HELIX.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Henry.</span><br>
-The practical unit of electro-magnetic or magnetic inductance. It is<br>
-equal to 1E9 C. G. S., or absolute units of inductance. As the<br>
-dimensions of inductance are a length the henry is equal to 1E9<br>
-centimeters, or approximately to one quadrant of the earth measured on<br>
-the meridian.<br>
-<br>
-Synonyms--Secohm--Quadrant--Quad.<br>
-<br>
-<br>
-289&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hermetically Sealed.</span><br>
-Closed absolutely tight. Glass vessels, such as the bulbs of<br>
-incandescent lamps, are hermetically sealed often by melting the glass<br>
-together over any opening into their interior.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Heterostatic Method.</span><br>
-A method of using the absolute or attracted disc electrometer. (See<br>
-Electrometer Absolute.) The formula for its idiostatic use, q. v.,<br>
-involves the determination of d, the distance between the suspended and<br>
-fixed discs. As this is difficult to determine the suspended disc and<br>
-guard ring may be kept at one potential and the lower fixed disc is then<br>
-connected successively with the two points whose potential difference is<br>
-to be determined. Their difference is determined by the difference<br>
-between d and d', the two distances between the discs. This difference<br>
-is the distance through which the micrometer screw is moved. The<br>
-heterostatic formula is:<br>
-<br>
-V' - V = (d' - d)* squareRoot( 8*PI*F / S )<br>
-<br>
-in which V and V' are potentials of the two points; d' and d the two<br>
-distances between the discs necessary for equilibrium; S the area of the<br>
-disc and F the force of attraction in dynes. (See Idiostatic Method.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">High Bars of Commutator.</span><br>
-Commutator bars, which in the natural wear of the commutator, project<br>
-beyond the others. The surface then requires turning down, as it should<br>
-be quite cylindrical.<br>
-<br>
-<br>
-<span style="font-weight: bold;">High Frequency.</span><br>
-A term used as a noun or as an adjective to indicate in an alternating<br>
-current, the production of a very great number of alternations per unit<br>
-of time--usually expressed as alternations per second.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hissing.</span><br>
-A term applied to a noise sometimes produced by a voltaic arc; probably<br>
-due to the same cause as frying, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hittorf's Solution.</span><br>
-A solution used as a resistance. It is a solution of cadmium iodide in<br>
-amylic alcohol. Ten per cent. of the salt is used. It is contained in a<br>
-tube with metallic cadmium electrodes. (See Resistance, Hittorf' s.)<br>
-<br>
-<br>
-<img style="width: 339px; height: 579px;" alt=""
- src="images/289F196.jpg"><br>
-Fig. 196. HITTORF'S RESISTANCE TUBE.<br>
-<br>
-<br>
-290&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Holders.</span><br>
-(a) The adjustable clamps for holding the armature brushes of dynamos<br>
-and motors.<br>
-<br>
-(b) The clamps for holding the carbons of arc lamps.<br>
-<br>
-(c) The clamps for holding safety fuses, q. v.<br>
-<br>
-(d) Holders for Jablochkoff candles and other electric candles. (See<br>
-Candle Holders.)<br>
-<br>
-(e) A box or block of porcelain for holding safety fuses.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hood.</span><br>
-A tin hood placed over an arc-lamp. Such hoods are often truncated cones<br>
-in shape, with the small end upwards. They reflect a certain amount of<br>
-light besides protecting the lamp to some extent from rain.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Horns.</span><br>
-The extensions of the pole pieces of a dynamo or motor. (See Following<br>
-Horns-Leading Horns.)<br>
-<br>
-Synonym--Pole Tips.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Horse Power.</span><br>
-A unit of rate of work or activity. There are two horse powers.<br>
-<br>
-The British horse power is equal to 33,000 pounds raised one foot per<br>
-minute, or 550 foot pounds per second, or 1.0138 metric horse power.<br>
-<br>
-The metric horse power (French) is equal to 75 kilogram-meters, or 542<br>
-foot pounds per second, or .986356 British horse power.<br>
-<br>
-H. P. is the abbreviation for horse power. (See Horse Power, Electric.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Horse Power, Actual.</span><br>
-The rate of activity of a machine, as actually developed in condition<br>
-for use. It is less than the indicated or total horse power, because<br>
-diminished by the hurtful resistances of friction, and other sources of<br>
-waste. It is the horse power that can be used in practise, and which in<br>
-the case of a motor can be taken from the fly-wheel.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Horse Power, Electric.</span><br>
-The equivalent of a mechanical horse power in electric units, generally<br>
-in volt-amperes or watts; 745.943 watts are equivalent to the activity<br>
-of one British horse power; 735.75 are equivalent to one metric horse<br>
-power. The number 746 is usually taken in practical calculations to give<br>
-the equivalency.<br>
-<br>
-[Transcriber's note: Contemporary values are: Mechanical (British)<br>
-horsepower = 745.6999 Watts; Metric horsepower = 735.49875 Watts]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Horse Power, Indicated.</span><br>
-The horse power of an engine as indicated by its steam pressure, length<br>
-of stroke, and piston area, and vacuum, without making any deduction for<br>
-friction or hurtful resistances. The steam pressure is in accurate work<br>
-deduced from indicator diagrams.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Horse Power, Hour.</span><br>
-A horse power exerted for one hour, or the equivalent thereof. As the<br>
-horse power is a unit of activity, the horse power hour is a unit of<br>
-work or of energy. It is equal to 1,980,000 foot pounds.<br>
-<br>
-<br>
-<span style="font-weight: bold;">H. P.</span><br>
-Abbreviation for "horse power."<br>
-<br>
-<br>
-291&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hughes' Electro-magnet.</span><br>
-A horseshoe electro-magnet with polarized core. It is made by mounting<br>
-two bobbins of insulated wire on the ends of a permanent horseshoe<br>
-magnet. It was devised for use in Hughes' printing telegraph, where very<br>
-quick action is required. The contact lasts only .053 second, 185<br>
-letters being transmitted per minute.<br>
-<br>
-<br>
-<img style="width: 398px; height: 479px;" alt=""
- src="images/291F197.jpg"><br>
-Fig. 197 HUGHES' ELECTRO-MAGNET.<br>
-<br>
-<br>
-<img style="width: 555px; height: 761px;" alt=""
- src="images/291F198.jpg"><br>
-Fig. 198. HUGHES' INDUCTION BALANCE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hughes' Induction Balance.</span><br>
-An apparatus for determining the presence of a concealed mass of metal.<br>
-The apparatus is variously connected. The cut shows a representative<br>
-form; a and a' are two primary coils, each consisting of 100 meters (328<br>
-feet) of No. 32 silk covered copper wire (0.009 inch diameter) wound on<br>
-a boxwood spool ten inches in depth; b and b' are secondary coils. All<br>
-coils are supposed to be alike. The primary coils are joined in series<br>
-with a battery of three or four Daniell cells. A microphone m is<br>
-included in the same circuit. The secondary coils are joined in series<br>
-with a telephone and in opposition with each other. The clock is used to<br>
-produce a sound affecting the microphone. If all is exactly balanced<br>
-there will be no sound produced in the telephone. This balance is<br>
-brought about by slightly varying the distance of one of the secondaries<br>
-from the primary, until there is no sound in the telephone. If now a<br>
-piece of metal is placed within either of the coils, it disturbs the<br>
-balance and the telephone sounds.<br>
-<br>
-<br>
-292&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-To measure the forces acting a sonometer or audiometer is used. This is<br>
-shown in the upper part of the cut. Two fixed coils, c and e are mounted<br>
-at the ends of a graduated bar. A movable coil d is connected in the<br>
-telephone circuit; c and e by a switch can be connected with the battery<br>
-and microphone circuit, leaving out the induction balance coils. The<br>
-ends of the coils c and e, facing each other are of the same polarity.<br>
-If these coils, c and e, were equal in all respects, no sound would be<br>
-produced when d was midway between them. But they are so wound that the<br>
-zero position for d is very near one of them, c.<br>
-<br>
-Assume that a balance has been obtained in the induction balance with<br>
-the coil d at zero. No sound is heard whether the switch is moved to<br>
-throw the current into one or the other circuit. A piece of metal placed<br>
-in one of the balance coils will cause the production of a sound. The<br>
-current is turned into the sonometer and d is moved until the same<br>
-sound, as tested by rapid movements of the switch, is heard in both<br>
-circuits. The displacement of d gives the value of the sound.<br>
-<br>
-A milligram of copper is enough to produce a loud sound. Two coins can<br>
-be balanced against each other, and by rubbing one of them, or by<br>
-breathing on one of them, the balance will be disturbed and a sound will<br>
-be produced.<br>
-<br>
-Prof. Hughes has also dispensed with the audiometer. He has used a strip<br>
-of zinc tapering from a width of 4 mm. (.16 inch) at one end to a sharp<br>
-edge or point at the other. The piece to be tested being in place in one<br>
-coil, the strip is moved across the face of the other until a balance is<br>
-obtained.<br>
-<br>
-As possible uses the detection of counterfeit coins, the testing of<br>
-metals for similarity of composition and the location of bullets in the<br>
-body have been suggested. Care has to be taken that no masses of metal<br>
-interfere. Thus in tests of the person of a wounded man, the presence of<br>
-an iron truss, or of metallic bed springs may invalidate all<br>
-conclusions.<br>
-<br>
-The same principle is carried out in an apparatus in which the parts are<br>
-arranged like the members of a Wheatstone bridge. One pair of coils is<br>
-used, which react on each other as primary and secondary coils. One of<br>
-the coils is in series with a telephone in the member of the bridge<br>
-corresponding to that containing the galvanometer of the Wheatstone<br>
-bridge. The latter is more properly termed an induction bridge.<br>
-<br>
-Synonyms--Inductance Bridge--Inductance Balance--Induction Bridge.<br>
-<br>
-<br>
-293&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hydro-electric. adj.</span><br>
-(a) A current produced by a voltaic couple or the couple itself is<br>
-sometimes thus characterized or designated as a "hydro-electric current"<br>
-or a "hydro-electric couple." It distinguishes them from<br>
-thermo-electric.<br>
-<br>
-(b) Armstrong's steam boiler electric machine (see Hydroelectric<br>
-Machine) is also termed a hydro-electric machine.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hydro-electric Machine.</span><br>
-An apparatus for generating high potential difference by the escape of<br>
-steam through proper nozzles.<br>
-<br>
-It consists of a boiler mounted on four glass legs or otherwise<br>
-insulated. An escape pipe terminates in a series of outlets so shaped as<br>
-to impede the escape of the steam by forcing it out of the direct<br>
-course. These jets are lined with hard wood. They are enclosed in or led<br>
-through a box which is filled with cold water.<br>
-<br>
-<br>
-<img style="width: 693px; height: 792px;" alt=""
- src="images/293F199.jpg"><br>
-Fig. 199. ARMSTRONG'S HYDRO-ELECTRIC MACHINE.<br>
-<br>
-<br>
-This is to partly condense the steam so as to get it into the vesicular<br>
-state, which is found essential to its action. Dry steam produces no<br>
-excitation. If the boiler is fired and the steam is permitted to escape<br>
-under the above conditions the vesicles presumably, or the "steam" is<br>
-found to be electrified. A collecting comb held against the jet becomes<br>
-charged and charges any connected surface.<br>
-<br>
-<br>
-294&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The boiler in the above case is negatively and the escaping "steam" is<br>
-positively charged. By changing the material of the linings of the jets,<br>
-or by adding turpentine the sign of the electricity is reversed. If the<br>
-water contains acid or salts no electricity is produced. The regular<br>
-hydro-electric machine is due to Sir William Armstrong.<br>
-<br>
-Faraday obtained similar results with moist air currents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hydrogen.</span><br>
-An element existing under all except the most extreme artificial<br>
-conditions of pressure and cold as a gas. It is the lightest of known<br>
-substances. Atomic weight, 1; molecular weight, 2; equivalent, 1;<br>
-valency, 1; specific gravity, .0691-.0695. (Dumas &amp; Boussingault.)<br>
-<br>
-It is a dielectric of about the same resistance as air. Its specific<br>
-inductive capacity at atmospheric pressure is:<br>
-&nbsp;&nbsp;&nbsp; .9997 (Baltzman)&nbsp;&nbsp; .9998 (Ayrton)<br>
-<br>
-Electro-chemical equivalent, .0105 milligram.<br>
-The above is usually taken as correct. Other values are as follows:<br>
-.010521 (Kohllrausch)&nbsp;&nbsp; .010415 (Mascart)<br>
-<br>
-The electro-chemical equivalent of any element is obtained by<br>
-multiplying its equivalent by the electro-chemical equivalent of<br>
-hydrogen. The value .0105 has been used throughout this book.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hygrometer.</span><br>
-An instrument for determining the moisture in the air. One form consists<br>
-of a pair of thermometers, one of which has its bulb wrapped in cloth<br>
-which is kept moist during the observation. The evaporation is more or<br>
-less rapid according to the dryness or moisture of the air, and as the<br>
-temperature varies with this evaporation the relative readings of the<br>
-two thermometers give the basis for calculating the hygrometric state of<br>
-the air. Another form determines the temperature at which dew is<br>
-deposited on a silver surface, whence the calculations are made.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hysteresis, Magnetic.</span><br>
-A phenomenon of magnetization of iron. It may be attributed to a sort of<br>
-internal or molecular friction, causing energy to be absorbed when iron<br>
-is magnetized. Whenever therefore the polarity or direction of<br>
-magnetization of a mass of iron is rapidly changed a considerable<br>
-expenditure of energy is required. It is attributed to the work done in<br>
-bringing the molecules into the position of polarity.<br>
-<br>
-<br>
-295&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The electric energy lost by hysteresis may be reduced by vibrations or<br>
-jarring imparted to the iron, thus virtually substituting mechanical for<br>
-electrical work.<br>
-<br>
-On account of hysteresis the induced magnetization of a piece of iron or<br>
-steel for fields of low intensity will depend on the manner in which the<br>
-material has been already magnetized. Let the intensity of field<br>
-increase, the magnetization increasing also; then lower the intensity;<br>
-the substance tends to and does retain some of its magnetism. Then on<br>
-again strengthening the field it will have something to build on, so<br>
-that when it attains its former intensity the magnetization will exceed<br>
-its former value. For a moderate value of intensity of field the<br>
-magnetization can have many values within certain limits.<br>
-<br>
-Synonym--Hysteresis--Hysteresis, Static--Magnetic Friction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Hysteresis, Viscous.</span><br>
-The gradual increase or creeping up of magnetization when a magnetic<br>
-force is applied with absolute steadiness to a piece of iron. It may<br>
-last for half an hour or more and amount to several per cent. of the<br>
-total magnetization. It is a true magnetic lag.<br>
-</big></big><br>
-<big><big><br>
-295&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">I.</span><br>
-A symbol sometimes used to indicate current intensity. Thus Ohm's law is<br>
-often expressed I = E/R, meaning current intensity is equal to<br>
-electro-motive force divided by resistance. C is the more general symbol<br>
-for current intensity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ideoelectrics or Idioelectrics.</span><br>
-Bodies which become electric by friction. This was the old definition,<br>
-the term originating with Gilbert. It was based on a misconception, as<br>
-insulation is all that is requisite for frictional electrification,<br>
-metals being thus electrified if held by insulating handles. The term is<br>
-virtually obsolete; as far as it means anything it means insulating<br>
-substances such as scaling wax, sulphur, or glass.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Idle Coils.</span><br>
-Coils in a dynamo, in which coils no electro-motive force is being<br>
-generated. This may occur when, as a coil breaks connection with the<br>
-commutator brush, it enters a region void of lines of magnetic force, or<br>
-where the lines are tangential to the circle of the armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Idiostatic Method.</span><br>
-A method of using the absolute or attracted disc electrometer. (See<br>
-Electrometer, Absolute.) The suspended disc and guard ring are kept at<br>
-the same potential, which is that of one of the points whose potential<br>
-difference is to be determined; the lower fixed disc is connected to the<br>
-other of the points whose potential difference is to be determined. Then<br>
-we have the formula<br>
-<br>
-V = d * SquareRoot( 8 * PI * F ) / S<br>
-<br>
-in which d is the distance between the discs, V is the difference of<br>
-potential of the two points, F the force of attraction between the discs<br>
-in dynes, and S the area of the suspended disc. (See Heterostatic<br>
-Method.)<br>
-<br>
-<br>
-296&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Idle Poles.</span><br>
-Poles of wire sealed into Crookes' tubes, not used for the discharge<br>
-connections, but for experimental connections to test the effect of<br>
-different excitation on the discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Idle Wire.</span><br>
-In a dynamo the wire which plays no part in generating electro-motive<br>
-force. In a Gramme ring the wire on the inside of the ring is idle wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Igniter.</span><br>
-In arc lamps with fixed parallel carbons of the Jablochkoff type (see<br>
-Candle, Jablochkoff) a strip of carbon connects the ends of the carbons<br>
-in the unused candle. This is necessary to start the current. Such strip<br>
-is called an igniter. It burns away in a very short time when an arc<br>
-forms producing the light, and lasts, if all goes well, until the candle<br>
-burns down to its end. Without the igniter the current would not start<br>
-and no arc would form.<br>
-<br>
-<br>
-<span style="font-weight: bold;">I. H. P.</span><br>
-Symbol for indicated horse-power.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Illuminating Power.</span><br>
-The relative light given by any source compared with a standard light,<br>
-and stated in terms of the same, as a burner giving an illuminating<br>
-power of sixteen candles. For standards see Candle, Carcel--Methven<br>
-Standard--Pentane Standard.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Illuminating Power, Spherical.</span><br>
-The illuminating power of a lamp or source of light may vary in<br>
-different directions, as in the case of a gas burner or incandescent<br>
-lamp. The average illuminating power determined by photometric test or<br>
-by calculation in all directions from the source of light is called the<br>
-spherical illuminating power, or if stated in candles is called the<br>
-spherical candle power.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Illumination, Unit of.</span><br>
-An absolute standard of light received by a surface. Preece proposed as<br>
-such the light received from a standard candle (see Candle, Standard) at<br>
-a distance of 12.7 inches. The object of selecting this distance was to<br>
-make it equal to the Carcel Standard (see Carcel), which is the light<br>
-given by a Carcel lamp at a distance of one meter.<br>
-<br>
-From one-tenth to one-fiftieth this degree of illumination was found in<br>
-gas-lighted streets by Preece, depending on the proximity of the gas<br>
-lamps.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Image, Electric.</span><br>
-An electrified point or system of points on one side of a surface which<br>
-would produce on the other side of that surface the same electrical<br>
-action which the actual electrification of that surface really does<br>
-produce. (Maxwell.)<br>
-<br>
-The method of investigating the distribution of electricity by electric<br>
-images is due to Sir William Thomson. The conception is purely a<br>
-theoretical one, and is of mathematical value and interest.<br>
-<br>
-<br>
-297&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Impedance.</span><br>
-The ratio of any impressed electro-motive force to the current which it<br>
-produces in a conductor. For steady currents it is only the resistance.<br>
-For variable currents it may include besides resistance inductance and<br>
-permittance. It is the sum of all factors opposing a current, both ohmic<br>
-and spurious resistances. It is often determined and expressed as ohms.<br>
-<br>
-Synonym--Apparent Resistance--Virtual Resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Impedance, Oscillatory.</span><br>
-The counter-electro-motive force offered to an oscillatory discharge, as<br>
-that of a Leyden jar. It varies with the frequency of the discharge<br>
-current.<br>
-<br>
-Synonym--Impulsive Impedance.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Impressed Electro-motive Force.</span><br>
-The electro-motive force expending itself in producing current induction<br>
-in a neighboring circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Impulse.</span><br>
-(a) An electro-magnetic impulse is the impulse produced upon the<br>
-luminiferous ether by an oscillatory discharge or other varying type of<br>
-current; the impulse is supposed to be identical, except as regards<br>
-wave-length, with a light wave.<br>
-<br>
-(b) An electro-motive impulse is the electro-motive force which rises so<br>
-high as to produce an impulsive or oscillatory discharge, such as that<br>
-of a Leyden jar.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Incandescence, Electric.</span><br>
-The heating or a conductor to red, or, more etymologically, to white<br>
-heat by the passage of an electric current. The practical conditions are<br>
-a high intensity of current and a low degree of conductance of the<br>
-conductor relatively speaking.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Inclination Map.</span><br>
-A map showing the locus of equal inclination or dips of the magnetic<br>
-needle. The map shows a series of lines, each one of which follows the<br>
-places at which the dip of the magnetic needle is identical. The map<br>
-changes from year to year. (See Magnetic Elements.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Independence of Currents in Parallel
-Circuits.</span><br>
-If a number of parallel circuits of comparatively high resistance are<br>
-supplied by a single generator of comparatively low resistance, the<br>
-current passed through each one will be almost the same whether a single<br>
-one or all are connected. Under the conditions named the currents are<br>
-practically independent of each other.<br>
-<br>
-[Transcriber's note: The current in each parallel branch depends on the<br>
-resistance/impedance of that branch. Only if they all have the same<br>
-</big></big><big><big>impedance</big></big><big><big> will the current
-be the same.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Indicating Bell.</span><br>
-An electric bell arranged to drop a shutter or disclose in some other<br>
-way a designating number or character when rung.<br>
-<br>
-<br>
-298&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Indicator.</span><br>
-(a) An apparatus for indicating the condition of a distant element, such<br>
-as the water level in a reservoir, the temperature of a drying room or<br>
-cold storage room or any other datum. They are of the most varied<br>
-constructions.<br>
-<br>
-(b) The receiving instrument in a telegraph system is sometimes thus<br>
-termed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Indicator, Circuit.</span><br>
-A galvanometer used to show when a circuit is active, and to give an<br>
-approximate measurement of its strength. It is a less accurate and<br>
-delicate form of instrument than the laboratory appliance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Inductance.</span><br>
-The property of a circuit in virtue of which it exercises induction and<br>
-develops lines of force. It is defined variously. As clear and<br>
-satisfactory a definition as any is the following, due to Sumpner and<br>
-Fleming: Inductance is the ratio between the total induction through a<br>
-circuit to the current producing it. "Thus taking a simple helix of five<br>
-turns carrying a current of two units, and assuming that 1,000 lines of<br>
-force passed through the central turn, of which owing to leakage only<br>
-900 thread the next adjacent on each side, and again only 800 through<br>
-the end turns, there would be 800 + 900 + 1000 + 900 + 800, or 4,400<br>
-linkages of lines with the wire, and this being with 2 units of current,<br>
-there would be 2,200 linkages with unit current, and consequently the<br>
-self-inductance of the helix would be 2,200 centimetres." (Kennelly.)<br>
-Inductance, as regards its dimensions is usually reduced to a length,<br>
-hence the last word of the preceding quotation.<br>
-<br>
-The practical unit of inductance is termed the henry, from Prof. Joseph<br>
-Henry; the secohm, or the quad or quadrant. The latter alludes to the<br>
-quadrant of the earth, the value in length of the unit in question.<br>
-<br>
-[Transcriber's note: (L (di/dt) = V). A current changing at the rate of<br>
-one ampere per second through a one henry inductance produces one volt.<br>
-A sinusoidal current produces a voltage 90 degrees ahead of the current,<br>
-a cosine (the derivative of sine is cosine). One volt across one henry<br>
-causes the current to increase at one ampere per second.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Coefficient of Self.</span><br>
-The coefficient of self-induction of a circuit is the quantity of<br>
-induction passing through it per unit current in it. If a given circuit<br>
-is carrying a varying current it is producing a varying quantity of<br>
-magnetic induction through itself. The quantity of induction through the<br>
-circuit due to its current is generally proportional to its current. The<br>
-quantity for unit current is the coefficient of self-induction.<br>
-(Emtage.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Cross.</span><br>
-The induction of magnetic lines of force in a dynamo armature core by<br>
-the current passing around such armature. These lines in a symmetrical<br>
-two pole machine are at right angles to the lines of force which would<br>
-normally extend across the space between the two magnet poles. The joint<br>
-magnetizing effect of the field and of the cross induction produces a<br>
-distorted field between the poles .<br>
-<br>
-Synonym--Cross-magnetizing Effect.<br>
-<br>
-<br>
-299&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Electro-magnetic.</span><br>
-The inter-reaction of electromagnetic lines of force with the production<br>
-of currents thereby.<br>
-<br>
-A current passing through a conductor establishes around it a field of<br>
-force representing a series of circular lines of force concentric with<br>
-the axis of the conductor and perpendicular thereto. These lines of<br>
-force have attributed to them, as a representative of their polarity,<br>
-direction. This is of course purely conventional. If one is supposed to<br>
-be looking at the end of a section of conductor, assuming a current be<br>
-passing through it towards the observer, the lines of force will have a<br>
-direction opposite to the motion of the hands of a watch. The idea of<br>
-direction may be referred to a magnet. In it the lines of force are<br>
-assumed to go from the north pole through the air or other surrounding<br>
-dielectric to the south pole.<br>
-<br>
-Two parallel wires having currents passing through them in the same<br>
-direction will attract each other. This is because the oppositely<br>
-directed segments of lines of force between the conductors destroy each<br>
-other, and the resultant of the two circles is an approximation to an<br>
-ellipse. As lines of force tend to be as short as possible the<br>
-conductors tend to approach each other to make the ellipse become of as<br>
-small area as possible, in other words to become a circle.<br>
-<br>
-If on the other hand the currents in the conductors are in opposite<br>
-directions the segments of the lines of force between them will have<br>
-similar directions, will, as it were, crowd the intervening ether and<br>
-the wires will be repelled.<br>
-<br>
-<br>
-<img style="width: 638px; height: 291px;" alt=""
- src="images/299F200.jpg"><br>
-Fig. 200. ATTRACTION OF CONDUCTORS CARRYING SIMILAR CURRENTS.<br>
-<br>
-<br>
-By Amp&eacute;re's theory of magnetism, (see Magnetism, Amp&eacute;re's
-Theory of,) a<br>
-magnet is assumed to be encircled by currents moving in the direction<br>
-opposite to that of the hands of a watch as the observer faces the north<br>
-pole. A magnet near a wire tends to place the Amp&eacute;rian currents
-parallel<br>
-to the wire, and so that the portion of the Amp&eacute;rian currents
-nearest<br>
-thereto will correspond in direction with the current in the wire.<br>
-<br>
-<br>
-300&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-This is the principle of the galvanometer. A number of methods of<br>
-memoria technica have been proposed to remember it by.<br>
-<br>
-Thus if we imagine a person swimming with the current and always facing<br>
-the axis of the conductor, a magnetic needle held where the person is<br>
-supposed to be will have its north pole deflected to the right hand of<br>
-the person.<br>
-<br>
-<br>
-<img style="width: 639px; height: 288px;" alt=""
- src="images/300F201.jpg"><br>
-Fig. 201. REPULSION OF CONDUCTORS <br>
-CARRYING OPPOSITE CURRENTS.<br>
-<br>
-<br>
-Again if we think of a corkscrew, which as it is turned screws itself<br>
-along with the current, the motion of the handle shows the direction of<br>
-the lines of force and the direction in which the north pole of a needle<br>
-is deflected. This much is perhaps more properly electro-dynamics, but<br>
-is necessary as a basis for the expression of induction.<br>
-<br>
-If a current is varied in intensity in one conductor it will induce a<br>
-temporary current in another conductor, part of which is parallel to the<br>
-inducing current and which conductor is closed so as to form a circuit.<br>
-If the inducing current is decreased the induced current in the near and<br>
-parallel portion of the other circuit will be of identical direction; if<br>
-increased the induced current will be of opposite direction.<br>
-<br>
-This is easiest figured by thinking of the lines of force surrounding<br>
-the inducing conductor. If the current is decreased these can be<br>
-imagined as receiving a twist or turn contrary to their normal<br>
-direction, as thereby establishing a turn or twist in the ether<br>
-surrounding the other wire corresponding in direction with the direction<br>
-of the original lines of force, or what is the same thing, opposite in<br>
-direction to the original twist. But we may assume that the<br>
-establishment of such a disturbance causes a current, which must be<br>
-governed in direction with the requirements of the new lines of force.<br>
-<br>
-The same reasoning applies to the opposite case.<br>
-<br>
-<br>
-301&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The general statement of a variable current acting on a neighboring<br>
-circuit also applies to the approach or recession of an unvarying<br>
-current, and to the cutting of lines of force by a conductor at right<br>
-angles thereto. For it is evident that the case of a varying current is<br>
-the case of a varying number of lines of force cutting or being cut by<br>
-the neighboring conductor. As lines of force always imply a current,<br>
-they always imply a direction of such current. The cutting of any lines<br>
-of force by a closed conductor always implies a change of position with<br>
-reference to all portions of such conductor and to the current and<br>
-consequently an induced current or currents in one or the other<br>
-direction in the moving conductor.<br>
-<br>
-As the inducing of a current represents energy abstracted from that of<br>
-the inducing circuit, the direction of the induced current is determined<br>
-by (Lenz's Law) the rule that the new current will increase already<br>
-existing resistances or develop new ones to the disturbance of the<br>
-inducing field.<br>
-<br>
-In saying that a conductor cutting lines of force at right angles to<br>
-itself has a current induced in it, it must be understood that if not at<br>
-right angles the right angle component of the direction of the wire acts<br>
-in generating the current. The case resolves itself into the number of<br>
-lines of force cut at any angle by the moving wire.<br>
-<br>
-The lines of force may be produced by a magnet, permanent or electro.<br>
-This introduces no new element. The magnet may be referred, as regards<br>
-direction of its lines of force, to its encircling currents, actual or<br>
-Amp&eacute;rian, and the application of the laws just cited will cover
-all<br>
-cases.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Coefficient of Mutual.</span><br>
-The coefficient of mutual induction of two circuits is the quantity of<br>
-magnetic induction passing through either of them per unit current in<br>
-the other. (Emtage.) It is also defined as the work which must be done<br>
-on either circuit, against the action of unit current in each, to take<br>
-it away from its given position to an infinite distance from the other;<br>
-and also as the work which would be done by either circuit on the other<br>
-in consequence of unit current in each, as the other moves from an<br>
-infinite distance to its given position with respect to the other<br>
-conductor. It depends on the form, size, and relative position of the<br>
-two circuits; and on the magnetic susceptibilities of neighboring<br>
-substances.<br>
-<br>
-The ether surrounding two circuits of intensity i' and i" must possess<br>
-energy, expressible (Maxwell) as 1/2 L i2 + M i i + 1/2 N i12. It can be<br>
-shown that M i i1 in any given position of the two circuits is<br>
-numerically equal (1) to the mutual potential energy of the two circuits<br>
-(2) to the number of lines of induction, which being due to A, pass from<br>
-A through B, or equally being due to B, pass from B through A, and M is<br>
-styled the coefficient of mutual induction. (Daniell.)<br>
-<br>
-<br>
-302&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Electrostatic.</span><br>
-An electrostatic charge has always an opposite and bound charge. This<br>
-may be so distributed as not to be distinguishable, in which case the<br>
-charge is termed, incorrectly but conventionally, a free charge. But<br>
-when a charge is produced an opposite and equal one always is formed,<br>
-which is the bound charge. The region between the two charges and<br>
-permeated by their lines of force, often curving out so as to embrace a<br>
-volume of cross-sectional area larger than the mean facing area of the<br>
-excited surfaces, is an electrostatic field of force. The establishing<br>
-of an electrostatic field, and the production of a bound charge are<br>
-electrostatic induction.<br>
-<br>
-An insulated conductor brought into such a field suffers a<br>
-redistribution of its electricity, or undergoes electrostatic induction.<br>
-The parts nearest respectively, the two loci of the original and the<br>
-bound charges, are excited oppositely to such charges. The conductor<br>
-presents two new bound charges, one referred to the original charge, the<br>
-other to the first bound charge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Horizontal.</span><br>
-In an iron or steel ship the induction exercised upon the compass needle<br>
-by the horizontal members of the structure, such as deck-beams, when<br>
-they are polarized by the earth's magnetic induction. This induction<br>
-disappears four times in swinging a ship through a circle; deviation due<br>
-to it is termed quadrantal deviation. (See Deviation, Quadrantal.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Lateral.</span><br>
-A term formerly used to express the phenomenon of the alternative<br>
-discharge of a Leyden jar or other oscillatory discharge of electricity.<br>
-(See Discharge, Alternative.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Induction, Magnetic.</span><br>
-The magnetization of iron or other paramagnetic substance by a magnetic<br>
-field.<br>
-<br>
-On account of its permeability or multiplying power for lines of force,<br>
-a paramagnetic body always concentrates lines of force in itself if<br>
-placed in a magnetic field, and hence becomes for the time being a<br>
-magnet, or is said to be polarized.<br>
-<br>
-As the tendency of lines of force is to follow the most permeable path,<br>
-a paramagnetic bar places itself lengthwise or parallel with the<br>
-prevailing direction of the lines of force so as to carry them as far on<br>
-their way as possible. Every other position of the bar is one of<br>
-unstable equilibrium or of no equilibrium. The end of the bar where the<br>
-lines of force enter (see Lines of Force) is a south pole and is<br>
-attracted towards the north pole of the magnet.<br>
-<br>
-The production of magnetic poles under these conditions in the bar is<br>
-shown by throwing iron filings upon it. They adhere to both ends but not<br>
-to the middle.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Induction, Mutual, Electro-magnetic.</span><br>
-The induction due to two electric currents reacting on each other.<br>
-<br>
-<br>
-303&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Mutual, Electrostatic.</span><br>
-A charged body always induces a charge upon any other body near it; and<br>
-the same charge in the second body will induce the other charge in the<br>
-first body if the latter is unexcited. In other words the second body's<br>
-induction from the first is the measure of the charge the second would<br>
-require to induce in the first its own (the second's) induced charge.<br>
-This is the law of mutual electrostatic induction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Open Circuit.</span><br>
-Inductive effects produced in open circuits. By oscillatory discharges a<br>
-discharge can be produced across a break in a circuit otherwise<br>
-complete. The requirements for its production involve a correspondence<br>
-or relation of its dimensions to the inducing discharge. The whole is<br>
-analogous to the phenomena of sound resonators and sympathetic<br>
-vibrations. Synonym--Oscillatory induction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Self-.</span><br>
-(a) A phenomenon of electric currents analogous to the inertia of<br>
-matter. Just as water which fills a pipe would resist a sudden change in<br>
-its rate of motion, whether to start from rest, to cease or decrease its<br>
-motion, so an electric current requires an appreciable time to start and<br>
-stop. It is produced most strongly in a coiled conductor, especially if<br>
-a core of iron is contained within it.<br>
-<br>
-As in the case of two parallel wires, one bearing currents which vary,<br>
-momentary currents are induced in the other wire, so in a single<br>
-conductor a species of inertia is found which retards and prolongs the<br>
-current. If a single conductor is twisted into a helix or corresponding<br>
-shape, its separate turns react one on the other in accordance with the<br>
-general principles of electromagnetic induction. (See Induction,<br>
-Electro-magnetic.) Thus when a current is suddenly formed the coils<br>
-acting upon each other retard for an instant its passage, producing the<br>
-effect of a reverse induced current or extra current opposing the<br>
-principal current. Of course no extra current is perceptible, but only<br>
-the diminution. When the current is passing regularly and the current is<br>
-broken, the corresponding action prolongs the current or rather<br>
-intensifies it for an instant, producing the true extra current. This is<br>
-current self-induction.<br>
-<br>
-[Transcriber's note: See inductance.]<br>
-<br>
-Synonyms--Electric Inertia--Electro-dynamic Capacity.<br>
-<br>
-(b) A permanent magnet is said to tend to repel its own magnetism, and<br>
-thus to weaken itself; the tendency is due to magnetic self-induction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction Sheath.</span><br>
-In the brush dynamo a thin sheet of copper surrounding the magnet cores<br>
-with edges soldered together. The winding is outside of it. Its object<br>
-is to absorb extra currents set up by variations in magnetic intensity<br>
-in the cores. These currents otherwise would circulate in the cores.<br>
-<br>
-<br>
-304&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Unit of Self-.</span><br>
-The unit of self-induction is the same as that of induction in general.<br>
-It is the henry, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Unipolar.</span><br>
-Induction produced in a conductor which continuously cuts the lines of<br>
-force issuing from one pole of a magnet. As the lines of force are<br>
-always cut in the same sense a continuous and constant direction current<br>
-is produced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Induction, Vertical.</span><br>
-In an iron or steel ship the induction or attraction exercised in the<br>
-compass by vertical elements of the structure. Such vertical masses of<br>
-iron in the northern hemisphere would have their upper ends polarized as<br>
-south poles, and would affect the magnet as soon as the vessel swung out<br>
-of the magnetic meridian. Thus this induction disappears twice in<br>
-swinging a ship through a complete circle; deviation due to it is termed<br>
-semi-circular deviation. (See Deviation, Semi-circular.)<br>
-<br>
-<br>
-<img style="width: 620px; height: 534px;" alt=""
- src="images/304F202.jpg"><br>
-Fig. 202. INDUCTOR DYNAMO.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Inductophone.</span><br>
-A method of train telegraphy. The train carries a circuit including a<br>
-coil, and messages are picked up by it from coils along the line into<br>
-which an alternating current is passed. A telephone is used as a<br>
-receiver in place of a sounder or relay. The invention, never<br>
-practically used, is due to Willoughby Smith.<br>
-<br>
-<br>
-305&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Inductor.</span><br>
-(a) In a current generator a mass of iron, generally laminated, which is<br>
-moved past a magnet pole to increase the number of lines of force<br>
-issuing therefrom. It is used in inductor dynamos. (See Dynamo<br>
-Inductor.) In the cut Fig. 202, of an inductor dynamo i, i, are the<br>
-laminated inductors.<br>
-<br>
-(b) In influence machines the paper or tinfoil armatures on which the<br>
-electrification is induced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Inertia.</span><br>
-A force in virtue of which every body persists in its state of motion or<br>
-rest except so far as it is acted on by some force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Inertia, Electro-magnetic.</span><br>
-This term is sometimes applied to the phenomena of self-induction, or<br>
-rather to the cause of these phenomena.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Infinity Plug.</span><br>
-A plug in a resistance box, which on being pulled out of its seat opens<br>
-the circuit or makes it of infinite resistance. The plug seats itself<br>
-between two brass plates which are not connected with each other in any<br>
-way. The other plates are connected by resistance coils of varying<br>
-resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Influence, Electric.</span><br>
-Electric induction, which may be either electrostatic, current, or<br>
-electro-magnetic.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Insolation, Electric.</span><br>
-Exposure to powerful arc-light produces effects resembling those of<br>
-sun-stroke. The above term or the term "electric sun-stroke" has been<br>
-applied to them.<br>
-<br>
-[Transcriber's note: Operators of arc welders are prone to skin cancer<br>
-from ultra violet rays if not properly protected.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Installation.</span><br>
-The entire apparatus, buildings and appurtenances of a technical or<br>
-manufacturing establishment. An electric light installation, for<br>
-instance, would include the generating plant, any special buildings, the<br>
-mains and lamps.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Insulating Stool.</span><br>
-A support for a person, used in experiments with static generators. It<br>
-has ordinarily a wooden top and glass legs. It separates one standing on<br>
-it from the earth and enables his surface to receive an electrostatic<br>
-charge. This tends to make his hair stand on end, and anyone on the<br>
-floor who touches him will receive a shock.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Insulating Tape.</span><br>
-Prepared tape used in covering the ends of wire where stripped for<br>
-making joints. After the stripped ends of two pieces are twisted<br>
-together, and if necessary soldered and carefully cleaned of soldering<br>
-fluid, they may be insulated by being wound with insulating tape.<br>
-<br>
-The tape is variously prepared. It may be common cotton or other tape<br>
-saturated with any insulating compound, or may be a strip of gutta<br>
-percha or of some flexible cement-like composition.<br>
-<br>
-<br>
-306&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Insulating Varnish.</span><br>
-Varnish used to coat the surface of glass electrical apparatus, to<br>
-prevent the deposition of hygrometric moisture, and also in the<br>
-construction of magnetizing and induction coils and the like. Shellac<br>
-dissolved in alcohol is much used. Gum copal dissolved in ether is<br>
-another. A solution of sealing wax in alcohol is also used. If applied<br>
-in quantities these may need baking to bring about the last drying. (See<br>
-Shellac Varnish.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Insulator.</span><br>
-(a) Any insulating substance.<br>
-<br>
-(b) A telegraph or line insulator for telegraph wires. (See Insulator,<br>
-Line or Telegraph.)<br>
-<br>
-Synonyms--Dielectric--Non-conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Insulator Cap.</span><br>
-A covering or hood, generally of iron, placed over an insulator to<br>
-protect it from injury by fracture with stones or missiles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Insulator, Fluid.</span><br>
-(a) For very high potentials, as in induction coils or alternating<br>
-circuits, fluid insulators, such as petroleum or resin oil, have been<br>
-used. Their principal merit is that if a discharge does take place<br>
-through them the opening at once closes, so that they are self-healing.<br>
-<br>
-(b) Also a form of telegraph or line insulator in which the lower rim is<br>
-turned up and inwards, so as to form an annular cup which is filled with<br>
-oil.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Insulator, Line or Telegraph.</span><br>
-A support often in the shape of a collar or cap, for a telegraph or<br>
-other wire, made of insulating material. Glass is generally used in the<br>
-United States, porcelain is adopted for special cases; pottery or stone<br>
-ware insulators have been used a great deal in other countries.<br>
-Sometimes the insulator is an iron hook set into a glass screw, which is<br>
-inserted into a hole in a telegraph bracket. Sometimes a hook is caused<br>
-to depend from the interior of an inverted cup and the space between the<br>
-shank of the hook and cup is filled with paraffine run in while melted.<br>
-<br>
-Insulators are tested by measuring their resistance while immersed in a<br>
-vessel of water.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Intensity. Strength.</span><br>
-The intensity of a current or its amperage or strength; the intensity or<br>
-strength of a magnetic field or its magnetic density; the intensity or<br>
-strength of a light are examples of its use. In the case of dynamic<br>
-electricity it must be distinguished from tension. The latter<br>
-corresponds to potential difference or voltage and is not an attribute<br>
-of current; intensity has no reference to potential and is a<br>
-characteristic of current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Intensity of a Magnetic Field.</span><br>
-The intensity of a magnetic field at any point is measured by the force<br>
-with which it acts on a unit magnet pole placed at that point. Hence<br>
-unit intensity of field is that intensity of field which acts on a unit<br>
-pole with a force of one dyne. (S. P. Thomson.) (See Magnetic Lines of<br>
-Force.)<br>
-<br>
-<br>
-307&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Intercrossing.</span><br>
-Crossing a pair of conductors of a metallic circuit from side to side to<br>
-avoid induction from outside sources.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Intermittent.</span><br>
-Acting at intervals, as an intermittent contact, earth, or grounding of<br>
-a telegraph wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Interpolar Conductor.</span><br>
-A conductor connecting the two poles of a battery or current generator;<br>
-the external circuit in a galvanic circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Interpolation.</span><br>
-A process used in getting a closer approximation to the truth from two<br>
-varying observations, as of a galvanometer. The process varies for<br>
-different cases, but amounts to determining an average or deducing a<br>
-proportional reading from the discrepant observed ones.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Interrupter.</span><br>
-A circuit breaker. It may be operated by hand or be automatic. (See<br>
-Circuit Breaker--Circuit Breaker, Automatic--and others.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Interrupter, Electro-magnetic, for a
-Tuning Fork.</span><br>
-An apparatus for interrupting a current which passes through an<br>
-electromagnet near and facing one of the limbs of a tuning fork. The<br>
-circuit is made and broken by the vibrations of another tuning fork<br>
-through which the current passes. The second one is thus made to<br>
-vibrate, although it may be very far off and may not be in exact unison<br>
-with the first. The first tuning fork has a contact point on one of its<br>
-limbs, to close the circuit; it may be one which dips into a mercury<br>
-cup.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Intrapolar Region.</span><br>
-A term in medical electricity, denoting the part of a nerve through<br>
-which a current is passing.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ions.</span><br>
-The products of decomposition produced in any given electrolysis are<br>
-termed ions, the one which appears at the anode or negative electrode is<br>
-the anion. The electrode connected to the carbon or copper plate of a<br>
-wet battery is an anode. Thus in the electrolysis of water oxygen is the<br>
-anion and hydrogen is termed the kation. In this case both anion and<br>
-kation are elements. In the decomposition of copper sulphate the anion<br>
-is properly speaking sulphion (S O4), a radical, and the kation is<br>
-copper, an element. Electro-negative elements or radicals are anions,<br>
-such as oxygen, sulphion, etc., while electro-positive ones are kations,<br>
-such as potassium. Again one substance may be an anion referred to one<br>
-below it and a kation referred to one above it, in the electro-chemical<br>
-series, q. v. Anion means the ion which goes to the anode or positive<br>
-electrode; kation, the ion which goes to the kathode or negative<br>
-electrode.<br>
-<br>
-[Transcriber's note: An ion is an atom or molecule that has lost or<br>
-gained one or more valence electrons, giving it a positive or negative<br>
-electrical charge. A negatively charged ion, with more electrons than<br>
-protons in its nuclei, is an anion. A positively charged ion, with fewer<br>
-electrons than protons, is a cation. The electron was discovered five<br>
-years after this publication.]<br>
-<br>
-<br>
-308&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Iron.</span><br>
-A metal; one of the elements; symbol, Fe; atomic weight, 56;<br>
-equivalent, 28 and 14, ; valency, 4 and 2.<br>
-It is a conductor of electricity. The following data are at<br>
-0&deg; C. 32&deg; F., with annealed metal.<br>
-<br>
-<small><span style="font-family: monospace;">&nbsp; Specific
-Resistance,&nbsp;&nbsp; 9.716 microhms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Relative
-Resistance.&nbsp;&nbsp; 6.460</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a wire,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long weighing 1
-grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.085&nbsp;&nbsp; ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (b) 1 foot long 1/1000
-inch thick,&nbsp;&nbsp;&nbsp;
-58.45&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (c) 1 meter long weighing
-1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .7570&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (d) 1 meter long, 1
-millimeter thick,&nbsp;&nbsp;
-.1237&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Percentage increase in resistance
-per degree C. (1.8&deg; F.)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; at about 20&deg; C.
-(68&deg;F.), about 0.5 per cent.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a 1 inch
-cube,&nbsp;&nbsp; 3.825 microhms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Electro-chemical equivalent
-(Hydrogen = .0105), .147 and .294</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Iron, Electrolytic.</span><br>
-Iron deposited by electrolytic action. Various baths are employed for<br>
-its formation. (See Steeling.) It has very low coercive power, only<br>
-seven to ten times that of nickel.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ironwork Fault of a Dynamo.</span><br>
-A short circuiting of a dynamo by, or any connection of its coils with,<br>
-the iron magnet cores or other iron parts.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isochronism.</span><br>
-Equality of periodic time; as of the times of successive beats of a<br>
-tuning fork, or of the times of oscillations of a pendulum.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isoclinic Lines.</span><br>
-The lines denoting the locus of sets of equal dips or inclinations of<br>
-the magnetic needle upon the earth's surface, the magnetic parallels, q.<br>
-v. These lines are very irregular. (See Magnetic Elements.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isoclinic Map.</span><br>
-A map showing the position of isoclinic lines.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isodynamic Lines.</span><br>
-Lines marking the locus of places of equal magnetic intensity on the<br>
-earth's surface. (See Magnetic Elements, Poles of Intensity.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isodynamic Map.</span><br>
-A map showing the position of isodynamic lines. (See Poles of<br>
-Intensity.)<br>
-<br>
-<span style="font-weight: bold;">Isogonic Lines.</span><br>
-Lines on a map marking the locus of or connecting those points where the<br>
-declination or variation of the magnetic needle is the same. (See<br>
-Magnetic Elements--Declination of Magnetic Needle.)<br>
-<br>
-Synonyms--Isogonal Lines--Halleyan Lines.<br>
-<br>
-<br>
-309&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isogonic Map.</span><br>
-A map showing the isogonic lines. On such a map each line is<br>
-characterized and marked with the degrees and direction of variation of<br>
-the compass upon itself.<br>
-<br>
-Synonym--Declination Map.<br>
-<br>
-<img style="width: 372px; height: 327px;" alt=""
- src="images/309_Declination_1590_1990.gif"><br>
-[Transcriber's note: The file Earth_Declination_1590_1990.gif provided<br>
-by the U.S. Geological Survey (http://www.usgs.gov) is an animation of<br>
-the declination of the entire earth.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isolated Plant, Distribution or Supply.</span><br>
-The system of supplying electric energy by independent generating<br>
-systems, dynamo or battery, for each house, factory or other place, as<br>
-contra-distinguished from Central Station Distribution or Supply.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Isotropic.<br>
-<img style="width: 633px; height: 42px;" alt="" src="images/309Pic.jpg"><br>
-</span>(Greek, equal in manner.)<br>
-<br>
-Having equal properties in all directions; the reverse of anisotropic,<br>
-q. v. Thus a homogeneous mass of copper or silver has the same specific<br>
-resistance in all directions and is an isotropic conductor. Glass has<br>
-the same specific inductive capacity in all directions and is an<br>
-isotropic medium or dielectric. The same applies to magnetism. Iron is<br>
-an isotropic paramagnetic substance. (See Anisotropic.) The term applies<br>
-to other branches of physics also.<br>
-<br>
-<br>
-<span style="font-weight: bold;">I. W. G.</span><br>
-Contraction for Indian Wire Gauge--the gauge adopted in British India.<br>
-</big></big><big><big><br>
-<span style="text-decoration: underline;"></span></big></big><big><big><br>
-309&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">J.</span><br>
-Symbol for the unit joule, the unit of electric energy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Jacobi's Law.</span><br>
-A law of electric motors. It states that the maximum work of a motor is<br>
-performed when the counter-electromotive force is equal to one-half the<br>
-electro-motive force expended on the motor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Jewelry.</span><br>
-Small incandescent lamps are sometimes mounted as articles of jewelry in<br>
-scarf-pins or in the hair. They may be supplied with current from<br>
-storage or from portable batteries carried on the person.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joint, American Twist.</span><br>
-A joint for connecting telegraph wires, especially aerial lines. Its<br>
-construction is shown in the cut. The end of each wire is closely wound<br>
-around the straight portion of the other wire for a few turns.<br>
-<br>
-<br>
-<img style="width: 672px; height: 184px;" alt=""
- src="images/309F203.jpg"><br>
-Fig. 203. AMERICAN TWIST JOINT.<br>
-<br>
-<br>
-310&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joint, Britannia.</span><br>
-A joint for uniting the ends of telegraph and electric wires. The ends<br>
-of the wires are scraped clean and laid alongside each other for two<br>
-inches, the extreme ends being bent up at about right angles to the<br>
-wire. A thin wire is wound four or five times around one of the wires,<br>
-back of the joint, the winding is then continued over the lapped<br>
-portion, and a few more turns are taken around the other single wire.<br>
-The whole is then soldered.<br>
-<br>
-<br>
-<img style="width: 680px; height: 121px;" alt=""
- src="images/310F204.jpg"><br>
-Fig. 204. BRITANNIA JOINT.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joint, Butt.</span><br>
-A joint in belting or in wire in which the ends to be joined are cut off<br>
-square across, placed in contact and secured. It ensures even running<br>
-when used in belting. Any irregularity in thickness of a belt affects<br>
-the speed of the driven pulley. As dynamos are generally driven by<br>
-belts, and it is important to drive them at an even speed to prevent<br>
-variations in the electro-motive force, butt joints should be used on<br>
-belting for them, unless a very perfect lap joint is made, which does<br>
-not affect either the thickness or the stiffness of the belt.<br>
-<br>
-When a butt joint is used in wire a sleeve may be used to receive the<br>
-abutting ends, which may be secured therein by soldering. This species<br>
-of joint has been used on lightning rods and may more properly be termed<br>
-a sleeve joint.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joint, Lap.</span><br>
-(a) In belting a joint in which the ends are overlapped, and riveted or<br>
-otherwise secured in place. If made without reducing the thickness of<br>
-the ends it is a bad joint for electrical work, as it prevents even<br>
-running of machinery to which it is applied. Hence dynamo belts should<br>
-be joined by butt joints, or if by lap joints the ends should be shaved<br>
-off so that when joined and riveted, there will be no variation in the<br>
-thickness of the belt.<br>
-<br>
-(b) In wire lap joints are made by overlapping the ends of the wire and<br>
-soldering or otherwise securing. The Britannia joint (see Joint,<br>
-Britannia,) may be considered a lap-joint.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Joint, Marriage.</span><br>
-A joint for stranded conductors used for Galende's cables. It is made<br>
-somewhat like a sailor's long splice. Each one of the strands is wound<br>
-separately into the place whence the opposite strand is unwound and the<br>
-ends are cut off so as to abutt. In this way all are smoothly laid in<br>
-place and soldering is next applied.<br>
-<br>
-<br>
-<img style="width: 685px; height: 118px;" alt=""
- src="images/310F205.jpg"><br>
-Fig. 205. MARRIAGE JOINT.<br>
-<br>
-<br>
-311&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joint, Sleeve.</span><br>
-A joint in electric conductors, in which the ends of the wires are<br>
-inserted into and secured in a metallic sleeve or tube, whose internal<br>
-diameter is just sufficient to admit them.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Joint, Splayed.</span><br>
-The method of joining the ends of stranded conductors. The insulating<br>
-covering is removed, the wires are opened out, and the center wire,<br>
-heart or core of the cable is cut off short. The two ends are brought<br>
-together, the opened out wires are interlaced or crotched like the<br>
-fingers of the two hands, and the ends are wound around the body of the<br>
-cable in opposite directions. The joint is trimmed and well soldered.<br>
-Tinned wire with rosin flux for the soldering is to be recommended.<br>
-Insulating material is finally applied by hand, with heat if necessary.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joints in Belts.</span><br>
-Belt-joints for electric plants where the belts drive dynamos should be<br>
-made with special care. The least inequality affects the electro-motive<br>
-force. Butt joints are, generally speaking, the best, where the ends of<br>
-the belt are placed in contact and laced. Lap-joints are made by<br>
-overlapping the belt, and unless the belt is carefully tapered so as to<br>
-preserve uniform strength, the speed of the dynamo will vary and also<br>
-the electromotive force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joulad.</span><br>
-A name proposed to be substituted for "joule," q. v. It has not been<br>
-adopted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joule.</span><br>
-This term has been applied to several units.<br>
-<br>
-(a) The practical C. G. S. unit of electric energy and work--the<br>
-volt-coulomb. It is equal to 1E7 ergs--0.73734 foot pound.--.00134 horse<br>
-power seconds. A volt-ampere represents one joule per second.<br>
-<br>
-(b) It has also been used as the name of the gram-degree C. thermal<br>
-unit--the small calorie.<br>
-<br>
-Synonym--Joulad.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joule Effect.</span><br>
-The heating effect of a current passing through a conductor. It varies<br>
-with the product of the resistance by the square of the current, or with<br>
-(C^2)*R.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Joule's Equivalent.</span><br>
-The mechanical equivalent of heat, which if stated in foot-pounds per<br>
-pound-degree F. units, is 772 (772.55). (See Equivalents.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Junction Box.</span><br>
-In underground distribution systems, an iron casing or box in which the<br>
-feeders and mains are joined, and where other junctions are made.<br>
-<br>
-Synonym--Fishing Box.<br>
-</big></big><br>
-<big><big><span style="text-decoration: underline;"></span></big></big><big><big><br>
-311&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">K.</span><br>
-The symbol for electrostatic capacity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kaolin.</span><br>
-A product of decomposition of feldspar, consisting approximately of<br>
-silica, 45, alumina, 40, water, 15. It was used in electric candles of<br>
-the Jablochkoff type as a constituent of the insulating layer or<br>
-colombin. Later it was abandoned for another substance, as it was found<br>
-that it melted and acted as a conductor.<br>
-<br>
-<br>
-312&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kapp Line of Force.</span><br>
-A line of force proposed by Kapp. It is equal to 6,000 C. G. S. lines of<br>
-force, and the unit of area is the square inch. Unfortunately it has<br>
-been adopted by many manufacturers, but its use should be discouraged,<br>
-as it is a departure from the uniform system of units.<br>
-<br>
-One Kapp line per square inch = 930 C. G. S. lines per square<br>
-centimeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kathelectrotonus.</span><br>
-A term used in medical electricity or electro-therapeutics to indicate<br>
-the increased functional activity induced in a nerve by the proximity of<br>
-the kathode of an active circuit which is completed through the nerve.<br>
-The converse of anelectrotonus.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kathode.</span><br>
-The terminal of an electric circuit whence an electrolyzing current<br>
-passes from a solution. It is the terminal connected to the zinc plate<br>
-of a primary battery.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Kathodic Closure Contraction.</span><br>
-A term in electro-therapeutics; the contractions near where the kathode<br>
-of an active circuit is applied to the body, which are observed at the<br>
-instant when the circuit is closed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kathodic Duration Contraction.</span><br>
-A term in electro-therapeutics; the contraction near where the kathode<br>
-of an active circuit is applied to the body for a period of time.<br>
-<br>
-<br>
-<span style="font-weight: bold;">K. C. C.</span><br>
-Abbreviation for Kathodic Closure Contraction, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">K. D. C.</span><br>
-Abbreviation for Kathodic Duration Contraction, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Keeper.</span><br>
-A bar of soft iron used to connect the opposite poles of a horseshoe<br>
-magnet or the opposite poles of two bar magnets placed side by side. It<br>
-is designed to prevent loss of magnetism. The armature of a horseshoe<br>
-magnet is generally used as its keeper. For bar magnets a keeper is used<br>
-for each end, the magnets being laid side by side, with their poles in<br>
-opposite direction but not touching, and a keeper laid across at each<br>
-end connecting the opposite poles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kerr Effect.</span><br>
-The effect of an electrostatic field upon polarized light traversing a<br>
-dielectric contained within the field. (See Electrostatic Refraction.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Kerr's Experiment.</span><br>
-Polarized light reflected from the polished face of a magnet pole has<br>
-its plane of polarization rotated; when it is reflected from the north<br>
-pole the rotation is from left to right.<br>
-<br>
-<br>
-313&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key.</span><br>
-A switch adapted for making and breaking contact easily when worked by<br>
-hand, as a Morse telegraph key.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key Board.</span><br>
-A board or tablet on which keys or switches are mounted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key-board.</span><br>
-(a) A switch board, q. v.<br>
-<br>
-(b) A set of lettered keys similar to those of a typewriter employed in<br>
-some telegraph instruments. As each key is depressed it produces the<br>
-contact or break requisite for the sending of the signal corresponding<br>
-to the letter marked upon the key. The signal in printing telegraphs, on<br>
-which such key-boards are used, is the reprinting of the letter at the<br>
-distant end of the line.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Key, Bridge.</span><br>
-A key for use with a Wheatstone Bridge, q.v. It is desirable to first<br>
-send a current through the four arms of the bridge in using it for<br>
-testing resistances and then through the galvanometer, because it takes<br>
-a definite time for the current to reach its full strength. This is<br>
-especially the case if the element being measured has high static<br>
-capacity, as a long ocean cable. If the galvanometer connections were<br>
-completed simultaneously with the bridge connections a momentary swing<br>
-would be produced even if the arms bore the proper relation to each<br>
-other. This would cause delay in the testing. A bridge key avoids this<br>
-by first connecting the battery circuit through the arms of the bridge,<br>
-and then as it is still further depressed the galvanometer circuit is<br>
-completed.<br>
-<br>
-<br>
-314&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 668px; height: 505px;" alt=""
- src="images/313F206.jpg"><br>
-Fig. 206. CHARGE AND DISCHARGE KEY<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Key, Charge and Discharge.</span><br>
-A key for use in observing the discharge of a condenser immediately<br>
-after removing the battery. In one typical form it has two contacts, one<br>
-below and one above, and being a spring in itself is pressed up against<br>
-the upper one. Connections are so made that when in its upper position<br>
-it brings the two coatings of the condenser in circuit with the<br>
-galvanometer. When depressed it does the same for a battery. In use it<br>
-is depressed and suddenly released when the galvanometer receives the<br>
-full charge, before there has been time for leakage. This is one method<br>
-of connection illustrating its principle.<br>
-<br>
-In the cut L is the spring-key proper. S2, is the upper contact screw<br>
-against which the spring normally presses. In this position the<br>
-galvanometer G is in circuit with the opposite coatings of the condenser<br>
-C. On depressing the contact S2, is broken and S1, is made. This brings<br>
-the battery B in circuit with the condenser coatings. On releasing the<br>
-key it springs up and the galvanometer receives the effect of the charge<br>
-of the condenser as derived from the battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Double Contact.</span><br>
-A key arranged to close two distinct circuits, holding the first closed<br>
-until the second is completed. It is used for Wheatstone bridge work.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Double Tapper.</span><br>
-A telegraph key giving contacts alternately for currents in opposite<br>
-directions, used in needle telegraphy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Increment.</span><br>
-A key for use in duplex and quadruplex telegraphy. Its action is to<br>
-increase the line current, not merely to suddenly turn current into it.<br>
-<br>
-<br>
-315&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 720px; height: 499px;" alt=""
- src="images/314F207.jpg"><br>
-Fig. 207. KEMPE'S DISCHARGE KEY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Kempe's Discharge.</span><br>
-A key giving a charging, discharging and insulating connection, for<br>
-static condenser work. Referring to the cut l is a lever or spring with<br>
-upper discharging contact s, and lower charging contact s'. In use it is<br>
-pressed down by the insulating handle or finger piece C, until caught by<br>
-the hook attached to the key I. This hook is lower down than that on the<br>
-key D, and holds it in contact with the charging contact piece S'. On<br>
-pressing the key I, marked or designated "Insulate," it springs up,<br>
-breaks contact at S', and catching against the hook on D, which key is<br>
-designated "Discharge," remains insulated from both contacts; next on<br>
-pressing D it is released and springs up and closes the discharge<br>
-contact S. It is a form of charge and discharge key. (See Key, Charge<br>
-and Discharge.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Key, Magneto-electric.</span><br>
-A telegraph key whose movements operate what is virtually a small<br>
-magneto-generator, so as to produce currents of alternating direction,<br>
-one impulse for each motion of the key. It is employed for telegraphing<br>
-without a line battery, a polarized relay being used. In one very simple<br>
-form a key is mounted on a base with a permanent magnet and connected to<br>
-the armature, so that when the key is pressed downwards it draws the<br>
-armature away from the poles of the magnet. If the magnet or its<br>
-armature is wound with insulated wire this action of the key will cause<br>
-instantaneous currents to go through a circuit connected to the magnet<br>
-or armature coils.<br>
-<br>
-<br>
-<img style="width: 750px; height: 368px;" alt=""
- src="images/315F208.jpg"><br>
-Fig. 208. SIEMENS' MAGNETO-ELECTRIC KEY.<br>
-<br>
-<br>
-In Siemens &amp; Halske's key an H armature E is pivoted between the
-poles N<br>
-S, of a powerful compound horseshoe magnet, G G. It is wound with fine<br>
-wire and a key handle H is provided for working it. In its normal<br>
-position the handle is drawn upward, and the end S S of the armature<br>
-core is in contact with the south pole S of the permanent magnet, and<br>
-the end D D with the north pole. This establishes the polarity of the<br>
-armature. On depressing the key the contacts are broken and in their<br>
-place the end D D comes in contact with the south pole and the end S S<br>
-with the north pole. This suddenly reverses the polarity of the armature<br>
-and sends a momentary current through the armature coil which is in<br>
-circuit with the line. The cut only shows the principle of the key,<br>
-whose construction is quite complicated.<br>
-<br>
-<br>
-316&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Make and Break.</span><br>
-An ordinary electric key, usually making a contact when depressed, and<br>
-rising by spring action when released, and in its rise breaking the<br>
-contact.<br>
-<br>
-<br>
-<img style="width: 305px; height: 258px;" alt=""
- src="images/316F209.jpg"><br>
-Fig. 209. PLUG KEY<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Plug.</span><br>
-An appliance for closing a circuit. Two brass blocks are connected to<br>
-the terminals, but are disconnected from each other. A brass plug<br>
-slightly coned or with its end split so as to give it spring action is<br>
-thrust between the blocks to complete the circuit. It is used in<br>
-Resistance coils and elsewhere. (See Coil, Resistance.) Grooves are<br>
-formed in the blocks to receive the plug.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Reversing.</span><br>
-(a) A double key, arranged so that by depressing one key a current flows<br>
-in one direction, and by depressing the other a current flows in the<br>
-opposite direction. It is used in connection with a galvanometer in<br>
-experimental, testing or measuring operations.<br>
-<br>
-(b) A key effecting the same result used in quadruplex telegraphy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Sliding-Contact.</span><br>
-A name given to the key used for making instantaneous contacts with the<br>
-metre wire of a metre bridge, q. v. The name is not strictly correct,<br>
-because it is important that there should be no sliding contact made, as<br>
-it would wear out the wire and make it of uneven resistance.<br>
-<br>
-It is a key which slides along over the wire and which, when depressed,<br>
-presses a platinum tipped knife edge upon the wire. On being released<br>
-from pressure the key handle springs up and takes the knife edge off the<br>
-wire. This removal is essential to avoid wearing the wire, whose<br>
-resistance per unit of length must be absolutely uniform.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Key, Telegraph.</span><br>
-The key used in telegraphy for sending currents as desired over the<br>
-line. It consists of a pivoted lever with finger piece, which lever when<br>
-depressed makes contact between a contact point on its end and a<br>
-stationary contact point on the base. This closes the circuit through<br>
-the line. When released it springs up and opens the line circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kilo.</span><br>
-A prefix to the names of units; it indicates one thousand times, as<br>
-kilogram, one thousand grams. A few such units are given below.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kilodyne.</span><br>
-A compound unit; one thousand dynes. (See Dyne.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kilogram.</span><br>
-A compound unit; one thousand grams; 2.2046 pounds avds.<br>
-<br>
-<br>
-317&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Kilojoule.</span><br>
-A compound unit; one thousand joules, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kilometer.</span><br>
-A compound unit; one thousand meters; 3280.899 feet; 0.621382 statute<br>
-miles. (See Meter.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Kilowatt.</span><br>
-A compound unit; one thousand watts, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kine.</span><br>
-An absolute or C. G. S. unit of velocity or rate of motion; one<br>
-centimeter per second; proposed by the British Association.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kirchoff's Laws.</span><br>
-These relate to divided circuits.<br>
-<br>
-I. When a steady current branches, the quantity of electricity arriving<br>
-by the single wire is equal to the quantity leaving the junction by the<br>
-branches. The algebraical sum of the intensities of the currents passing<br>
-towards (or passing from) the junction is equal to zero; Summation(C) =<br>
-0 (Daniell.) In the last sentence currents flowing towards the point are<br>
-considered of one sign and those flowing away from it of the other.<br>
-<br>
-II. In a metallic circuit comprising within it a source of permanent<br>
-difference of potential, E, the products of the intensity of the current<br>
-within each part of the circuit into the corresponding resistance are,<br>
-if the elements of current be all taken in cyclical order together,<br>
-equal to E; Summation(C * r) =E. In a metallic circuit in which there is<br>
-no source of permanent difference of potential E = 0, and Summation(C *<br>
-r)&nbsp; = 0.<br>
-<br>
-This law applies to each several mesh of a wire network as well as to a<br>
-single metallic loop, and it holds good even when an extraneous current<br>
-is passed through the loop. (Daniell.)<br>
-<br>
-In this statement of the two laws E stands for electro-motive force, C<br>
-for current intensity; and r for resistance of a single member of the<br>
-circuit.<br>
-<br>
-[Transcriber's note: These laws may be restated as: At any point in an<br>
-steady-state electrical circuit, the directed sum of currents flowing<br>
-towards that point is zero. The directed sum of the electrical potential<br>
-differences around any closed circuit is zero.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Knife-edge Suspension.</span><br>
-The suspension of an object on a sharp edge of steel or agate. The knife<br>
-edge should abut against a plane. The knife edge is generally carried by<br>
-the poised object. Its edge then faces downward and on the support one<br>
-or more plane or approximately plane surfaces are provided on which it<br>
-rests. In the ordinary balance this suspension can be seen. It is<br>
-sometimes used in the dipping needle.<br>
-<br>
-It is applied in cases where vertical oscillations are to be provided<br>
-for.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Knot.</span><br>
-The geographical mile; a term derived from the knots on the log line,<br>
-used by navigators. It is equal to 6,087 feet.<br>
-<br>
-Synonyms--Nautical Mile--Geographical Mile.<br>
-<br>
-[Transcriber's note: A knot is a velocity, 1 nautical mile per hour, not<br>
-a distance. The contemporary definition is: 1 international knot = 1<br>
-nautical mile per hour = 1.852 kilometres per hour = 1.1507794 miles per<br>
-hour = 0.51444444 meters per second = 6076.1152 feet per hour.]<br>
-<br>
-<br>
-318&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kohlrausch's Law.</span><br>
-A law of the rate of travel of the elements and radicals in solutions<br>
-under the effects of electrolysis. It states that each element under the<br>
-effects of electrolysis has a rate of travel for a given liquid, which<br>
-is independent of the element with which it was combined. The rates of<br>
-travel are stated for different elements in centimeters per hour for a<br>
-potential difference of one or more volts per centimeter of path.<br>
-<br>
-[Friedrich Wilhelm Georg Kohlrausch (1840-1910)]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Kookogey's Solution.</span><br>
-An acid exciting and depolarizing solution for a zinc-carbon couple,<br>
-such as a Bunsen battery. Its formula is: Potassium bichromate, 227<br>
-parts; water, boiling, 1,134 parts; while boiling add very carefully and<br>
-slowly 1,558 parts concentrated sulphuric acid. All parts are by weight.<br>
-Use cold.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Krizik's Cores.</span><br>
-Cores of iron for use with magnetizing coils, q. v. They are so shaped,<br>
-the metal increasing in quantity per unit of length, as the centre is<br>
-approached, that the pull of the excited coil upon them will as far as<br>
-possible be equal in all positions. A uniform cylinder is attracted with<br>
-varying force according to its position; the Krizik bars or cores are<br>
-attracted approximately uniformly through a considerable range.<br>
-<br>
-</big></big><br>
-<big><big><br>
-318&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">L.</span><br>
-Symbol for length and also for the unit of inductance or coefficient of<br>
-induction, because the dimensions of inductance are length.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lag, Angle of.</span><br>
-(a) The angle of displacement of the magnetic axis of an armature of a<br>
-dynamo, due to its magnetic lag. The axis of magnetism is displaced in<br>
-the direction of rotation. (See Magnetic Lag.)<br>
-<br>
-(b) The angle expressing the lag of alternating current and<br>
-electro-motive force phases.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Laminated. adj.</span><br>
-Made up of thin plates, as a laminated armature core or converter core.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamination.</span><br>
-The building up of an armature core or other thing out of plates. The<br>
-cores of dynamo armatures or of alternating current converters are often<br>
-laminated. Thus a drum armature core may consist of a quantity of thin<br>
-iron discs, strung upon a rod and rigidly secured, either with or<br>
-without paper insulation between the discs. If no paper is used the film<br>
-of oxide on the iron is relied on for insulation. The object of<br>
-lamination is to break up the electrical continuity of the core, so as<br>
-to avoid Foucault currents. (See Currents, Foucault.) The laminations<br>
-should be at right angles to the direction of the Foucault currents<br>
-which would be produced, or in most cases should be at right angles to<br>
-the active parts of the wire windings.<br>
-<br>
-<br>
-319&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamination of Armature Conductors.</span><br>
-These are sometimes laminated to prevent the formation of eddy currents.<br>
-The lamination should be radial, and the strips composing it should be<br>
-insulated from each other by superficial oxidation, oiling or<br>
-enamelling, and should be united only at their ends.<br>
-<br>
-<br>
-<img style="width: 336px; height: 633px;" alt=""
- src="images/319F210.jpg"><br>
-Fig. 210. PILSEN ARC LAMP.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Arc.</span><br>
-A lamp in which the light is produced by a voltaic arc. Carbon<br>
-electrodes are almost universally employed. Special mechanism, operating<br>
-partly by spring or gravity and partly by electricity, is employed to<br>
-regulate the distance apart of the carbons, to let them touch when no<br>
-current passes, and to separate them when current is first turned on.<br>
-<br>
-The most varied constructions have been employed, examples of which will<br>
-be found in their places. Lamps may in general be divided into classes<br>
-as follows, according to their regulating mechanism and other features:<br>
-<br>
-(a) Single light regulators or monophotes. Lamps through whose<br>
-regulating mechanism the whole current passes. These are only adapted to<br>
-work singly; if several are placed in series on the same circuit, the<br>
-action of one regulator interferes with that of the next one.<br>
-<br>
-(b) Multiple light regulators or polyphotes. In these the regulating<br>
-mechanism and the carbons with their arc are in parallel; the regulating<br>
-device may be a single magnet or solenoid constituting a derived or<br>
-shunt-circuit lamp, or it may include two magnets working differentially<br>
-against or in opposition to each other constituting a differential lamp.<br>
-<br>
-<br>
-320&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-(c) Lamps with fixed parallel carbons termed candles (q. v., of various<br>
-types).<br>
-<br>
-(d) Lamps without regulating mechanism. These include lamps with<br>
-converging carbons, whose object was to dispense with the regulating<br>
-mechanism, but which in some cases have about as much regulating<br>
-mechanism as any of the ordinary arc lamps.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Contact.</span><br>
-A lamp depending for its action on loose contact between two carbon<br>
-electrodes. At the contact a species of incandescence with incipient<br>
-arcs is produced. One of the electrodes is usually flat or nearly so,<br>
-and the other one of pencil shape rests upon it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Differential Arc.</span><br>
-An arc lamp, the regulation of the distance between whose carbons<br>
-depends on the differential action of two separate electrical coils. The<br>
-diagram illustrates the principle. The two carbons are seen in black;<br>
-the upper one is movable, The current arrives at A. It divides, and the<br>
-greater part goes through the low resistance coil M to a contact roller<br>
-r, and thence by the frame to the upper carbon, and through the arc and<br>
-lower carbon to B, where it leaves the lamp. A smaller portion of the<br>
-current goes through the coil M1 of higher resistance and leaves the<br>
-lamp also at B. A double conical iron core is seen, to which the upper<br>
-carbon holder is attached. This is attracted in opposite directions by<br>
-the two coils. If the arc grows too long its resistance increases and<br>
-the coil M1 receiving more current draws it down and thus shortens the<br>
-arc. If the arc grows too short, its resistance falls, and the coil M<br>
-receives more current and draws the core upwards, thus lengthening the<br>
-arc. This differential action of the two cores gives the lamp its name.<br>
-R is a pulley over which a cord passes, one end attached to the core and<br>
-the other to a counterpoise weight, W.<br>
-<br>
-<br>
-<img style="width: 195px; height: 700px;" alt=""
- src="images/320F211.jpg"><br>
-Fig. 211. DIAGRAM OF THE PILSEN DIFFERENTIAL ARC LAMP.<br>
-<br>
-<br>
-321&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Lamp, Holophote.</span><br>
-A lamp designed for use alone upon its own circuit. These have the<br>
-regulating mechanism in series with the carbon and arc, so that the<br>
-whole current goes through both. (See Lamp, Arc.)<br>
-<br>
-Synonym--Monophote Lamp.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp-hour.</span><br>
-A unit of commercial supply of electric energy; the volt-coulombs<br>
-required to maintain an electric lamp for one hour. A sixteen-candle<br>
-power incandescent lamp is practically the lamp alluded to, and requires<br>
-about half an ampere current at 110 volts, making a lamp-hour equal to<br>
-about 198,000 volt-coulombs.<br>
-<br>
-[Transcriber's note: 0.55 KW hours.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Incandescent.</span><br>
-An electric lamp in which the light is produced by heating to whiteness<br>
-a refractory conductor by the passage of a current of electricity. It is<br>
-distinguished from an arc lamp (which etymologically is also an<br>
-incandescent lamp) by the absence of any break in the continuity of its<br>
-refractory conductor. Many different forms and methods of construction<br>
-have been tried, but now all have settled into approximately the same<br>
-type.<br>
-<br>
-The incandescent lamp consists of a small glass bulb, called the<br>
-lamp-chamber, which is exhausted of air and hermetically sealed. It<br>
-contains a filament of carbon, bent into a loop of more or less simple<br>
-shape. This shape prevents any tensile strain upon the loop and also<br>
-approximates to the outline of a regular flame.<br>
-<br>
-<br>
-<img style="width: 245px; height: 652px;" alt=""
- src="images/321F212.jpg"><br>
-Fig. 212. INCANDESCENT ELECTRIC LAMP.<br>
-<br>
-<br>
-322&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The loop is attached at its ends to two short pieces of platinum wire,<br>
-which pass through the glass of the bulb and around which the glass is<br>
-fused. As platinum has almost exactly the same coefficient of<br>
-heat-expansion as glass, the wires do not cause the glass to crack.<br>
-<br>
-The process of manufacture includes the preparation of the filament.<br>
-This is made from paper, silk, bamboo fibre, tamidine, q. v., or other<br>
-material. After shaping into the form of the filament the material is<br>
-carbonized at a high heat, while embedded in charcoal, or otherwise<br>
-protected from the air. The flashing process (see Flashing of<br>
-incandescent Lamp Carbons) may also be applied. The attachment to the<br>
-platinum wires is effected by a minute clamp or by electric soldering.<br>
-The loop is inserted and secured within the open globe, which the glass<br>
-blower nearly closes, leaving one opening for exhaustion.<br>
-<br>
-The air is pumped out, perhaps first by a piston pump, but always at the<br>
-end by a mercurial air pump. (See Pump, Geissler--and others.) As the<br>
-exhaustion becomes high a current is passed through the carbons heating<br>
-them eventually to white heat so as to expel occluded gas. The occluded<br>
-gases are exhausted by the pump and the lamp is sealed by melting the<br>
-glass with a blowpipe or blast-lamp flame. For the exhaustion several<br>
-lamps are usually fastened together by branching glass tubes, and are<br>
-sealed off one by one.<br>
-<br>
-The incandescent lamps require about 3.5 watts to the candle power, or<br>
-give about 12 sixteen-candle lamps to the horse power expended on them.<br>
-<br>
-Generally incandescent lamps are run in parallel or on multiple arc<br>
-circuits. All that is necessary in such distribution systems is to<br>
-maintain a proper potential difference between the two leads across<br>
-which the lamps are connected. In the manufacture of lamps they are<br>
-brought to an even resistance and the proper voltage at which they<br>
-should be run is often marked upon them. This may be fifty volts and<br>
-upward. One hundred and ten volts is a very usual figure. As current one<br>
-ampere for a fifty-volt, or about one-half an ampere for a one hundred<br>
-and ten volt lamp is employed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Incandescent, Three Filament.</span><br>
-A three filament lamp is used for three phase currents. It has three<br>
-filaments whose inner ends are connected, and each of which has one<br>
-leading-in wire. The three wires are connected to the three wires of the<br>
-circuit. Each filament receives a current varying in intensity, so that<br>
-there is always one filament passing a current equal to the sum of the<br>
-currents in the other two filaments.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Lighthouse.</span><br>
-A special type of arc light. It is adapted for use in a lighthouse<br>
-dioptric lantern, and hence its arc has to be maintained in the same<br>
-position, in the focus of the lenses. The lamps are so constructed as to<br>
-feed both carbons instead of only one, thereby securing the above<br>
-object.<br>
-<br>
-<br>
-323&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Pilot.</span><br>
-A lamp connected to a dynamo, and used by its degree of illumination to<br>
-show when the dynamo on starting becomes excited, or builds itself up.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Polyphote.</span><br>
-An arc lamp adapted to be used, a number in series, upon the same<br>
-circuit. The electric regulating mechanism is placed in shunt or in<br>
-parallel with the carbons and arc. (See Lamp, Arc.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamps, Bank of.</span><br>
-A number of lamps mounted on a board or other base, and connected to<br>
-serve as voltage indicator or to show the existence of grounds, or for<br>
-other purposes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp, Semi-incandescent.</span><br>
-A lamp partaking of the characteristics of both arc and incandescence; a<br>
-lamp in which the imperfect contact of two carbon electrodes produces a<br>
-part of or all of the resistance to the current which causes<br>
-incandescence.<br>
-<br>
-The usual type of these lamps includes a thin carbon rod which rests<br>
-against a block of carbon. The species of arc formed at the junction of<br>
-the two heats the carbons. Sometimes the upper carbon or at least its<br>
-end is heated also by true incandescence, the current being conveyed<br>
-near to its end before entering it.<br>
-<br>
-Semi-incandescent lamps are not used to any extent now.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lamp Socket.</span><br>
-A receptacle for an incandescent lamp; the lamp being inserted the<br>
-necessary connections with the two leads are automatically made in most<br>
-sockets. The lamps may be screwed or simply thrust into the socket and<br>
-different ones are constructed for different types of lamps. A key for<br>
-turning the current on and off is often a part of the socket.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Latent Electricity.</span><br>
-The bound charge of static electricity. (See Charge, Bound.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Law of Intermediate Metals.</span><br>
-A law of thermo-electricity. The electro-motive force between any two<br>
-metals is equal to the sum of electro-motive forces between each of the<br>
-two metals and any intermediate metal in the thermo-electric series, or<br>
-the electro-motive force between any two metals is equal to the sum of<br>
-the electromotive forces between all the intermediate ones and the<br>
-original two metals; it is the analogue of Volta's Law, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Law of Inverse Squares.</span><br>
-When force is exercised through space from a point, its intensity varies<br>
-inversely with the square of the distance. Thus the intensity of light<br>
-radiated by a luminous point at twice a given distance therefrom is of<br>
-one-fourth the intensity it had at the distance in question.<br>
-Gravitation, electric and magnetic attraction and repulsion and other<br>
-radiant forces are subject to the same law.<br>
-<br>
-<br>
-324&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Law of Successive Temperatures.</span><br>
-A law of thermo-electricity. The electro-motive force due to a given<br>
-difference of temperature between the opposite junctions of the metals<br>
-is equal to the sum of the electro-motive forces produced by fractional<br>
-differences of temperature, whose sum is equal to the given difference<br>
-and whose sum exactly fills the given range of temperature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Law, Right-handed Screw.</span><br>
-This rather crude name is given by Emtage to a law expressing the<br>
-relation of direction of current in a circuit to the positive direction<br>
-of the axis of a magnet acted on by such current. It is thus expressed:<br>
-A right-handed screw placed along the axis of the magnet and turned in<br>
-the direction of the current will move in the positive direction, i. e.,<br>
-towards the north pole of the axis of the magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lead.</span><br>
-A metal; one of the elements; symbol Pb. Atomic weight, 207;<br>
-equivalent, 103-1/2; valency, 2.<br>
-Lead may also be a tetrad, when its equivalent is 51.75.<br>
-The following data are at 0&ordm; C. (32&ordm; F.) with compressed
-metal:<br>
-<small><span style="font-family: monospace;">Relative Resistance,
-(Silver = l)&nbsp;&nbsp;&nbsp;&nbsp; 13.05</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Specific
-Resistance,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-19.63&nbsp;&nbsp; microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a wire,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">(a) 1 ft. long, weighing 1
-grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.200&nbsp;&nbsp; ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">(b) 1 meter long, weighing 1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.232&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">(c) 1 meter long, 1 millimeter
-thick,&nbsp;&nbsp;&nbsp; .2498&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of 1 inch
-cube,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-7.728&nbsp;&nbsp; microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Electro-Chemical Equivalent
-(Hydrogen = .0105)&nbsp;&nbsp;
-1.086&nbsp;&nbsp; mgs.</span></small><br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Leading Horns.</span><br>
-The tips of pole pieces in a dynamo, which extend in the direction of<br>
-movement of the armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Leading-in Wires.</span><br>
-The platinum wires passing through the glass of an incandescent<br>
-lamp-chamber, to effect the connection of the carbon filament with the<br>
-wires of the circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lead of Brushes, Negative.</span><br>
-In a motor the brushes are set backwards from their normal position, or<br>
-in a position towards the direction of armature rotation or given a<br>
-negative lead instead of a positive one, such as is given to dynamo<br>
-brushes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Leak.</span><br>
-A loss or escape of electricity by accidental connection either with the<br>
-ground or with some conductor. There are various kinds of leak to which<br>
-descriptive terms are applied.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Leakage.</span><br>
-The loss of current from conductors; due to grounding at least at two<br>
-places, or to very slight grounding at a great many places, or all along<br>
-a line owing to poor insulation. In aerial or pole telegraph lines in<br>
-wet weather there is often a very large leakage down the wet poles from<br>
-the wire. (See Surface Leakage--Magnetic Leakage.)<br>
-<br>
-<br>
-325&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Leakage Conductor.</span><br>
-A conductor placed on telegraph poles to conduct directly to earth any<br>
-leakage from a wire and thus prevent any but a very small portion<br>
-finding its way into the other wires on the same pole. It presents a<br>
-choice of evils, as it increases the electrostatic capacity of the line,<br>
-and thus does harm as well as good. It consists simply of a wire<br>
-grounded and secured to the pole.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Leg of Circuit.</span><br>
-One lead or side of a complete metallic circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lenz's Law.</span><br>
-A law expressing the relations of direction of an inducing current or<br>
-field of force to the current induced by any disturbance in the<br>
-relations between such field and any closed conductor within its<br>
-influence. It may be variously expressed.<br>
-<br>
-(a) If the relative position of two conductors, A and B, be changed, of<br>
-which A is traversed by a current, a current is induced in B in such a<br>
-direction that, by its electro-dynamic action on the current in A, it<br>
-would have imparted to the conductors a motion of the contrary kind to<br>
-that by which the inducing action was produced. (Ganot.)<br>
-<br>
-(b) The new (induced) current will increase the already existing<br>
-resistances, or develop new resistance to that disturbance of the field<br>
-which is the cause of induction. (Daniell.)<br>
-<br>
-(c) When a conductor is moving in a magnetic field a current is induced<br>
-in the conductor in such a direction as by its mechanical action to<br>
-oppose the motion. (Emtage.)<br>
-<br>
-(d) The induced currents are such as to develop resistance to the change<br>
-brought about.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Letter Boxes, Electric.</span><br>
-Letter boxes with electrical connections to a bell or indicator of some<br>
-sort, which is caused to act by putting a letter into the box.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Leyden Jar.</span><br>
-A form of static condenser.<br>
-<br>
-In its usual form it consists of a glass jar. Tinfoil is pasted around<br>
-the lower portions of its exterior and interior surfaces, covering from<br>
-one-quarter to three-quarters of the walls in ordinary examples. The<br>
-rest of the glass is preferably shellacked or painted over with<br>
-insulating varnish, q. v. The mouth is closed with a wooden or cork<br>
-stopper and through its centre a brass rod passes which by a short chain<br>
-or wire is in connection with the interior coating of the jar. The top<br>
-of the rod carries a brass knob or ball.<br>
-<br>
-If such a jar is held by the tinfoil-covered surface in one hand and its<br>
-knob is held against the excited prime conductor of a static machine its<br>
-interior becomes charged; an equivalent quantity of the same electricity<br>
-is repelled through the person of the experimenter to the earth and when<br>
-removed from the conductor it will be found to hold a bound charge. If<br>
-the outer coating and knob are both touched or nearly touched by a<br>
-conductor a disruptive discharge through it takes place.<br>
-<br>
-<br>
-326&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 612px; height: 530px;" alt=""
- src="images/326F213.jpg"><br>
-Fig. 213. LEYDEN JAR WITH DISCHARGER.<br>
-<br>
-<br>
-If one or more persons act as discharging conductors they will receive a<br>
-shock. This is done by their joining hands, a person at one end touching<br>
-the outer coating and another person at the other end touching the knob.<br>
-<br>
-From an influence machine a charge can be taken by connecting the<br>
-coating to one electrode and the knob to the other.<br>
-<br>
-<br>
-<img style="width: 574px; height: 622px;" alt=""
- src="images/326F214.jpg"><br>
-Fig. 214. SULPHURIC ACID LEYDEN JAR.<br>
-<br>
-<br>
-327&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Leyden Jar, Sir William Thomson's.</span><br>
-An especially efficient form of Leyden jar. It consists of a jar with<br>
-outer tinfoil coating only. For the interior coating is substituted a<br>
-quantity of concentrated sulphuric acid. The central rod is of lead with<br>
-a foot, which is immersed in the acid and from which the rod rises. A<br>
-wooden cover partly closes the jar, as the central tube through which<br>
-the rod passes is so large as not to allow the wood to touch it. Thus<br>
-any leakage from inner to outer coating has to pass over the inside and<br>
-outside glass surfaces. In the common form of jar the wooden cover may<br>
-short circuit the uncoated portion of the inner glass surface. In the<br>
-cut a simplified form of Thomson's Leyden jar is shown, adapted for<br>
-scientific work.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lichtenberg's Figures.</span><br>
-If the knob of a Leyden jar or other exited electrode is rubbed over the<br>
-surface of ebonite, shellac, resin or other non-conducting surface it<br>
-leaves it electrified in the path of the knob. If fine powder such as<br>
-flowers of sulphur or lycopodium is dusted over the surface and the<br>
-excess is blown away, the powder will adhere where the surface was<br>
-electrified, forming what are called Lichtenberg's Figures, Lycopodium<br>
-and sulphur show both positive and negative figures, that is to say,<br>
-figures produced by a positively or negatively charged conductor. Red<br>
-lead adheres only to negative figures. If both positive and negative<br>
-figures are made and the surface is sprinkled with both red lead and<br>
-flowers of sulphur each picks out its own figure, the sulphur going<br>
-principally to the positive one.<br>
-<br>
-The red lead takes the form of small circular heaps, the sulphur<br>
-arranges itself in tufts with numerous diverging branches. This<br>
-indicates the difference in the two electricities. The figures have been<br>
-described as "a very sensitive electrosope for investigating the<br>
-distribution of electricity on an insulating surface." (Ganot.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Life of Incandescent Lamps.</span><br>
-The period of time a lamp remains in action before the carbon filament<br>
-is destroyed. The cause of a lamp failing may be the volatilization of<br>
-the carbon of the filament, causing it to become thin and to break; or<br>
-the chamber may leak. The life of the lamp varies; 600 hours is a fair<br>
-estimate. Sometimes they last several times this period.<br>
-<br>
-The higher the intensity at which they are used the shorter is their<br>
-life. From their prime cost and the cost of current the most economical<br>
-way to run them can be approximately calculated.<br>
-<br>
-[Transcriber's note: Contemporary incandecent buls are rated for 1000<br>
-hours; flourescent bulbs up to 24000 hours; LED lamps up to 100000
-hours.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Lightning.</span><br>
-The electrostatic discharge to the earth or among themselves of clouds<br>
-floating in the atmosphere. The discharge is accompanied by a spark or<br>
-other luminous effect, which may be very bright and the effects, thermal<br>
-and mechanical, are often of enormous intensity.<br>
-<br>
-The lightning flash is white near the earth, but in the upper regions<br>
-where the air is rarefied it is of a blue tint, like the spark of the<br>
-electric machine. The flashes are often over a mile in length, and<br>
-sometimes are four or five miles long. They have sometimes a curious<br>
-sinuous and often a branching shape, which has been determined by<br>
-photography only recently. To the eye the shape seems zigzag.<br>
-<br>
-<br>
-328&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-In the case of a mile-long flash it has been estimated that 3,516,480 De<br>
-la Rue cells, q. v., would be required for the development of the<br>
-potential, giving the flash over three and one-half millions of volts.<br>
-But as it is uncertain how far the discharge is helped on its course by<br>
-the rain drops this estimate may be too high.<br>
-<br>
-There are two general types of flash. The so-called zigzag flash<br>
-resembles the spark of an electric machine, and is undoubtedly due to<br>
-the disruptive discharge from cloud to earth. Sheet lightning has no<br>
-shape, simply is a sudden glow, and from examination of the spectrum<br>
-appears to be brush discharges (see Discharge, Brush) between clouds.<br>
-Heat lightning is attributed to flashes below the horizon whose light<br>
-only is seen by us. Globe or ball lightning takes the form of globes of<br>
-fire, sometimes visible for ten seconds, descending from the clouds. On<br>
-reaching the earth they sometimes rebound, and sometimes explode with a<br>
-loud detonation. No adequate explanation has been found for them.<br>
-<br>
-The flash does not exceed one-millionth of a second in duration; its<br>
-absolute light is believed to be comparable to that of the sun, but its<br>
-brief duration makes its total light far less than that of the sun for<br>
-any period of time.<br>
-<br>
-If the disruptive discharge passes through a living animal it is often<br>
-fatal. As it reaches the earth it often has power enough to fuse sand,<br>
-producing fulgurites, q. v. (See also Back Shock or Stroke of<br>
-Lightning.)<br>
-<br>
-Volcanic lightning, which accompanies the eruptions of volcanoes, is<br>
-attributed to friction of the volcanic dust and to vapor condensation.<br>
-<br>
-[Transcriber's note: The origin of lightning is still (2008) not fully<br>
-understood, but is thought to relate to charge separation in the<br>
-vertical motion of water droplets and ice crystals in cloud updrafts. A<br>
-lightning bolt carries a current of 40,000 to 120,000 amperes, and<br>
-transfers a charge of about five coulombs. Nearby air is heated to about<br>
-10,000 &deg;C (18,000 &deg;F), almost twice the temperature of the Sun&#8217;s<br>
-surface.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lightning Arrester.</span><br>
-An apparatus for use with electric lines to carry off to earth any<br>
-lightning discharge such lines may pick up. Such discharge would imperil<br>
-life as well as property in telegraph offices and the like.<br>
-<br>
-Arresters are generally constructed on the following lines. The line<br>
-wires have connected to them a plate with teeth; a second similar plate<br>
-is placed near this with its teeth opposite to those of the first plate<br>
-and nearly touching it. The second plate is connected by a low<br>
-resistance conductor to ground. Any lightning discharge is apt to jump<br>
-across the interval, of a small fraction of an inch, between the<br>
-oppositely placed points and go to earth.<br>
-<br>
-Another type consists of two plates, placed face to face, and pressing<br>
-between them a piece of paper or mica. The lightning is supposed to<br>
-perforate this and go to earth. One plate is connected to the line, the<br>
-other one is grounded.<br>
-<br>
-The lightning arrester is placed near the end of the line before it<br>
-reaches any instrument. (See Alternative Paths.)<br>
-<br>
-<br>
-329&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 721px; height: 453px;" alt=""
- src="images/329F215.jpg"><br>
-Fig. 215. COMB OR TOOTHED LIGHTNING ARRESTER.<br>
-<br>
-<br>
-<img style="width: 646px; height: 310px;" alt=""
- src="images/329F216.jpg"><br>
-Fig. 216. FILM OR PLATE LIGHTNING ARRESTER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lightning Arrester,
-Counter-electro-motive Force.</span><br>
-An invention of Prof. Elihu Thompson. A lightning arrester in which the<br>
-lightning discharge sets up a counter-electro-motive force opposed to<br>
-its own. This it does by an induction coil. If a discharge to earth<br>
-takes place it selects the primary of the coil as it has low<br>
-self-induction. In its discharge it induces in the secondary a reverse<br>
-electro-motive force which protects the line.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lightning Arrester Plates.</span><br>
-The toothed plates nearly in contact, tooth for tooth, or the flat<br>
-plates of a film lightning arrester, which constitute a lightning<br>
-arrester. Some advocate restricting the term to the plate connected to<br>
-the line.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lightning Arrester, Vacuum.</span><br>
-A glass tube, almost completely exhausted, into which the line wire is<br>
-fused, while a wire leading to an earth connection has its end fused in<br>
-also.<br>
-<br>
-A high tension discharge, such as that of lightning, goes to earth<br>
-across the partial vacuum in preference to going through the line, which<br>
-by its capacity and self-induction opposes the passage through it of a<br>
-lightning discharge.<br>
-<br>
-It is especially adapted for underground and submarine lines.<br>
-<br>
-<br>
-330&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lightning, Ascending.</span><br>
-Lightning is sometimes observed which seems to ascend. It is thought<br>
-that this may be due to positive electrification of the earth and<br>
-negative electrification of the clouds.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Lightning, Globe or Globular.</span><br>
-A very unusual form of lightning discharge, in which the flashes appear<br>
-as globes or balls of light. They are sometimes visible for ten seconds,<br>
-moving so slowly that the eye can follow them. They often rebound on<br>
-striking the ground, and sometimes explode with a noise like a cannon.<br>
-They have never been satisfactorily explained. Sometimes the phenomenon<br>
-is probably subjective and due to persistence of vision.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lightning Jar.</span><br>
-A Leyden jar whose coatings are of metallic filings dusted on to the<br>
-surface while shellacked, and before the varnish has had time to dry. In<br>
-its discharge a scintillation of sparks appears all over the surface.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Line of Contact.</span><br>
-The line joining the points of contact of the commutator brushes in a<br>
-dynamo or motor.<br>
-<br>
-Synonym--Diameter of Commutation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lines of Force.</span><br>
-Imaginary lines denoting the direction of repulsion or attraction in a<br>
-field of force, q. v. They may also be so distributed as to indicate the<br>
-relative intensity of all different parts of the field. They are normal<br>
-to equipotential surfaces. (See Electro-magnetic Lines of<br>
-Force--Electrostatic Lines of Force--Magnetic Lines of Force.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lines of Induction.</span><br>
-Imaginary lines within a body marking the direction taken within it by<br>
-magnetic induction. These are not necessarily parallel to lines of<br>
-force, but may, in bodies of uniform agglomeration, or in crystalline<br>
-bodies, take various directions.<br>
-<br>
-Synonym--Lines of Magnetic Induction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lines of Slope.</span><br>
-Lines in a field of force which mark the directions in which the<br>
-intensity of force in the field most rapidly falls away.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Links, Fuse.</span><br>
-Links made of more or less easily fusible metal, for use as safety<br>
-fuses.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Listening Cam.</span><br>
-In a telephone exchange a cam or species of switch used to connect the<br>
-operator's telephone with a subscriber's line.<br>
-<br>
-<br>
-331&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lithanode.</span><br>
-A block of compressed lead binoxide, with platinum connecting foils for<br>
-use as an electrode in a storage battery. It has considerable capacity,<br>
-over 5 ampere-hours per pound of plates, but has not met with any<br>
-extended adoption.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Load.</span><br>
-In a dynamo the amperes of current delivered by it under any given<br>
-conditions.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Local Action.</span><br>
-(a) In its most usual sense the electric currents within a battery, due<br>
-to impurities in the zinc, which currents may circulate in exceedingly<br>
-minute circuits, and which waste zinc and chemicals and contribute<br>
-nothing to the regular current of the battery. Amalgamated or chemically<br>
-pure zinc develops no local action.<br>
-<br>
-(b) The term is sometimes applied to currents set up within the armature<br>
-core or pole pieces of a dynamo. (See Currents, Foucault.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Local Battery.</span><br>
-A battery supplying a local circuit (q. v.); in telegraphy, where it is<br>
-principally used, the battery is thrown in and out of action by a relay,<br>
-and its current does the work of actuating the sounder and any other<br>
-local or station instruments. (See Relay.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Local Circuit.</span><br>
-A short circuit on which are placed local apparatus or instruments. Such<br>
-circuit is of low resistance and its current is supplied by a local<br>
-battery, q. v. Its action is determined by the current from the main<br>
-line throwing its battery in and out of circuit by a relay, q. v., or<br>
-some equivalent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Local Currents.</span><br>
-Currents within the metal parts of a dynamo. (See Currents, Foucault.)<br>
-In a galvanic battery. where there is local action, q. v., there are<br>
-also local currents, though they are not often referred to.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Localization.</span><br>
-Determining the position of anything, such as a break in a cable, or a<br>
-grounding in a telegraph line. In ocean cables two typical cases are the<br>
-localization of a break in the conductor and of a defect in the<br>
-insulation admitting water. The first is done by determining the static<br>
-capacity of the portion of the line which includes the unbroken portion<br>
-of the conductor; the other by determining the resistance of the line on<br>
-a grounded circuit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Locus.</span><br>
-A place. The word is used to designate the locality or position of, or<br>
-series of positions of definite conditions and the like. Thus an<br>
-isogonic line is the locus of equal declinations of the magnetic needle;<br>
-it is a line passing through all places on the earth's surface where the<br>
-condition of a given declination is found to exist.<br>
-<br>
-<br>
-332&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Lodestone.</span><br>
-Magnetic magnetite; magnetite is an ore of iron, Fe3 04 which is<br>
-attracted by the magnet. Some samples possess polarity and attract iron.<br>
-The latter are lodestones.<br>
-<br>
-Synonym--Hercules Stone<br>
-<br>
-<br>
-<span style="font-weight: bold;">Logarithm.</span><br>
-The exponent of the power to which it is necessary to raise a fixed<br>
-number to produce a given number. The fixed number is the base of the<br>
-system. There are two systems; one, called the ordinary system, has 10<br>
-for its base, the other, called the Naperian system, has 2.71828 for its<br>
-base. The latter are also termed hyperbolic logarithms, and are only<br>
-used in special calculations.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Log, Electric.</span><br>
-An apparatus for measuring the speed of a ship. A rotating helical vane<br>
-of known pitch is dragged behind the vessel. As the helix rotates its<br>
-movements may actuate electric machinery for registering its rotations.<br>
-The number of these in a given time, multiplied by the pitch of the<br>
-vane, gives the distance traversed in such time.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Loop.</span><br>
-A portion of a circuit introduced in series into another circuit. The<br>
-latter circuit is opened by a spring-jack, q. v. or other device, and<br>
-the loop inserted. By loops any number of connections can be inserted<br>
-into a circuit in series therewith, and in series or in parallel with<br>
-one another.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Loop Break.</span><br>
-A double bracket or similar arrangement for holding on insulators the<br>
-ends of a conductor which is cut between them, and to which are<br>
-connected the ends of a loop. The space between the insulators may be<br>
-about a foot.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Luces.</span><br>
-This may be used as the plural of lux, q. v. It is the Latin plural.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Luminous Jar.</span><br>
-A Leyden jar whose coatings are of lozenge-shaped pieces of tinfoil<br>
-between which are very short intervals. When discharged, sparks appear<br>
-all over the surface where the lozenges nearly join.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Lux.</span><br>
-A standard of illumination, q. v., as distinguished from illuminating<br>
-power.<br>
-<br>
-It is the light given by one candle at a distance of 12.7 inches--by a<br>
-carcel, q. v., at a distance of one meter---or by 10,000 candles at<br>
-105.8 feet.<br>
-<br>
-It was proposed by W. H. Preece. All the above valuations are identical.<br>
-</big></big><big><big><span style="text-decoration: underline;"><br>
-</span></big></big><big><big><br>
-332&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">M.</span><br>
-(a) Symbol of gaseous pressure equal to one-millionth of an atmosphere.<br>
-<br>
-(b) The Greek m, &micro;, is used as the symbol of magnetic
-permeability.<br>
-<br>
-<br>
-333&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Machine, Cylinder Electric.</span><br>
-A frictional electric machine whose rotating glass is in the shape of a<br>
-cylinder instead of a disc as in the more recent machines.<br>
-<br>
-<br>
-<img style="width: 589px; height: 680px;" alt=""
- src="images/333F217.jpg"><br>
-Fig. 217. PLATE FRICTIONAL ELECTRIC MACHINE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Machine, Frictional Electric.</span><br>
-An apparatus for development of high tension electricity by contact<br>
-action, brought about by friction.<br>
-<br>
-It consists of a plate or cylinder of glass mounted on insulating<br>
-standards and provided with a handle for turning it. One or more<br>
-cushions of leather are held on an insulated support, so as to rub<br>
-against the plate or cylinder as it is turned. A metal comb or combs are<br>
-held on another insulating support so as to be nearly in contact with<br>
-the surface of the glass plate at a point as far removed as possible<br>
-from the rubbers. The combs are attached to a brass ball or round-ended<br>
-cylinder, which is termed the prime conductor.<br>
-<br>
-In use either the prime conductor or cushions are connected by a chain<br>
-or otherwise with the earth. Assume it to be the cushions. As the<br>
-machine is worked by turning the plate, the glass and cushion being in<br>
-contact develop opposite electricities. The glass is charged with<br>
-positive electricity, and as it turns carries it off and as it reaches<br>
-the prime conductor by induction and conduction robs it of its negative<br>
-electricity. Meanwhile the cushions negatively excited deliver their<br>
-charge to the earth. The action thus goes on, the prime conductor being<br>
-charged with positive electricity.<br>
-<br>
-<br>
-334&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-If the prime conductor is connected to the earth and the cushions are<br>
-left insulated, negative electricity can be collected from the cushions.<br>
-<br>
-In some machines both prime conductor and cushions are kept insulated<br>
-and without ground contact. Electrodes connecting with each are brought<br>
-with their ends close enough to maintain a sparking discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Machine Influence.</span><br>
-A static electric machine working by induction to build up charges of<br>
-opposite nature on two separate prime conductors. In general they are<br>
-based on the principle of the electrophorous. Work is done by the<br>
-operator turning the handle. This rotates a disc and draws excited parts<br>
-of it away from their bound charges. This represents a resistance to<br>
-mechanical motion. The work absorbed in overcoming this mechanical<br>
-resistance appears as electric energy. There are various types of<br>
-influence machines, the Holtz, Toeppler-Holtz and Wimshurst being the<br>
-most used. The electrophorous, q. v., is a type of influence machine.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Machine, Holtz Influence.</span><br>
-A static electric machine. It includes two plates, one of which is<br>
-rapidly rotated in front of the other. Two armatures of paper are<br>
-secured to the back of the stationary plate at opposite ends of a<br>
-diameter. To start it one of these is charged with electricity. This<br>
-charge by induction acts through the two thicknesses of glass upon a<br>
-metal bar carrying combs, which lies in front of the further side of the<br>
-movable plate. The points opposite the armature repel electrified air,<br>
-which strikes the movable disc and charges it. A second rod with comb at<br>
-the opposite end of the same diameter acts in the reverse way. Thus<br>
-opposite sections of the disc are oppositely charged and the combs with<br>
-them. By induction these portions of the disc react upon the two<br>
-armatures. The opposite electricities escape from the armatures by paper<br>
-tongues which are attached thereto and press against the back of the<br>
-movable plate. As the plate rotates the opposite electricities on its<br>
-face neutralize the electricity repelled from the combs. The charges on<br>
-the back strengthen the charges of the armatures and brass combs. Thus<br>
-the machine builds up, and eventually a discharge of sparks takes place<br>
-from the poles of the brass combs.<br>
-<br>
-<br>
-335&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Machine, Toeppler-Holtz.</span><br>
-A modification of the Holtz machine. The priming charge of the armatures<br>
-is produced by friction of metallic brushes against metallic buttons on<br>
-the face of the rotating plate. (See Machine, Holtz.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Machine, Wimshurst.</span><br>
-A form of static influence machine. It consists of two plates of glass,<br>
-on which radial sectors of tinfoil are pasted. Both plates are rotated<br>
-in opposite directions. The sectors of the two plates react one upon the<br>
-other, and electric charges of opposite sign accumulate on the opposite<br>
-sides of the plates and are collected therefrom by collecting combs.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mack.</span><br>
-A name, derived from Maxwell, and suggested for the unit of inductance.<br>
-It is due to Oliver Heaviside, but has never been adopted. (See Henry.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magne-Crystallic Action.</span><br>
-The action of a supposed force of the same name, proposed by Faraday. It<br>
-relates to the different action of a magnetic field upon crystalline<br>
-bodies, according to the position of their axes of crystallization. A<br>
-needle of tourmaline, normally paramagnetic, if poised with its axis<br>
-horizontal, is diamagnetic. Bismuth illustrates the same phenomenon. The<br>
-subject is obscure. Faraday thought that he saw in it the action of a<br>
-specific force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet.</span><br>
-A body which tends when suspended by its centre of gravity to lay itself<br>
-in a definite direction, and to place a definite line within it, its<br>
-magnetic axis, q. v., in a definite direction, which, roughly speaking,<br>
-lies north and south. The same bodies have the power of attracting iron<br>
-(Daniell), also nickel and cobalt.<br>
-<br>
-Magnets are substances which possess the power of attracting iron.<br>
-(Ganot.)<br>
-<br>
-[Transcriber's note: Edward Purcell and others have explained magnetic<br>
-and electromagnetic phenomenon as relativistic effects related to<br>
-electrostatic attraction. Magnetism is caused by Lorentz contraction of<br>
-space along the direction of a current. Electromagnetic waves are caused<br>
-by charge acceleration and the resulting disturbance of the<br>
-electrostatic field. (Electricity and Magnetism: Berkeley Physics<br>
-Course Volume 2, 1960)]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Anomalous.</span><br>
-A magnet possessing more than the normal number (two) of poles. If two<br>
-straight magnets are placed end to end with their south poles in<br>
-juxtaposition the compound bar will seem to possess three poles, one at<br>
-each end and one in the middle. The apparent pole in the middle is<br>
-really made up of two consequent poles, q. v. It sometimes happens that<br>
-when a single long thin bar is magnetized consequent poles are produced,<br>
-although such magnet is in one piece. This may be accidental, as in such<br>
-case it is quite hard to avoid anomalous poles, or, as in the field<br>
-magnets of some forms of dynamos, anomalous poles may be purposely<br>
-produced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Artificial.</span><br>
-A magnet formed artificially by any method of magnetization (see<br>
-Magnetism) applicable to permanent magnets, electro-magnets and<br>
-solenoids. It expresses the distinction from the natural magnets or<br>
-lodestone, q. v. It is made of steel in practice magnetized by some of<br>
-the methods described under Magnetization.<br>
-<br>
-<br>
-336&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet, Axial.</span><br>
-A straight-solenoid with axial core.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Bar.</span><br>
-A bar magnet is one in the shape of a bar, i. c., straight with parallel<br>
-sides and considerably longer than wide or deep.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Bell-shaped.</span><br>
-A form of permanent magnet used in some galvanometers. In shape it is a<br>
-thick-sided cylindrical box with two slots cut out of opposite sides, so<br>
-as to make it represent a horseshoe magnet. Its shape enables it to be<br>
-surrounded closely by a mass of copper, for damping its motion, to<br>
-render the instrument dead-beat. Such a magnet is used in Siemens &amp;<br>
-Halske's galvanometer.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet Coil.</span><br>
-A coil to be thrust over an iron core, to make an electro-magnet. They<br>
-are often wound upon paper or wooden bobbins or spools, so as to be<br>
-removable from the core if desired.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Compensating.</span><br>
-(a) A magnet fastened near a compass on an iron or steel ship to<br>
-compensate the action of the metal of the ship upon the magnetic needle.<br>
-The ship itself always has some polarity and this is neutralized by one<br>
-or more compensating magnets.<br>
-<br>
-(b) See below.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Controlling.</span><br>
-A magnet attached to a galvanometer by which the directive tendency of<br>
-its magnetic needle is adjusted. In the reflecting galvanometer it often<br>
-is a slightly curved magnet carried by a vertical brass spindle rising<br>
-from the center of the instrument, and which magnet may be slid up and<br>
-down on the spindle to regulate or adjust its action.<br>
-<br>
-Synonym--Compensating Magnet.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet, Compound.</span><br>
-A permanent magnet, built up of a number of magnets. Small bars can be<br>
-more strongly magnetized than large. Hence a compound magnet may be made<br>
-more powerful than a simple one.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet Core.</span><br>
-The iron bar or other mass of iron around which insulated wire is wound<br>
-for the production of an electro-magnet. The shapes vary greatly,<br>
-especially for field magnets of dynamos and motors. For these they are<br>
-usually made of cast iron, although wrought iron is preferable from the<br>
-point of view of permeability.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet, Damping.</span><br>
-A damping magnet is one used for bringing an oscillating body to rest.<br>
-The body may be a metallic disc or needle, and the action of the magnet<br>
-depends on its lines of force which it establishes, so that the body has<br>
-to cut them, and hence has its motion resisted.<br>
-<br>
-<br>
-337&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet, Deflection of.</span><br>
-The change of position of a magnet from the plane of the earth's<br>
-meridian in which it normally is at rest into another position at some<br>
-angle thereto, by the effect of an artificial magnetic field, as the<br>
-deflection of a galvanometer needle.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Electro-.</span><br>
-A magnet consisting of a bar of iron, bundle of iron wires, iron tube or<br>
-some equivalent, around which a coil of insulated wire is wound. Such<br>
-combination becomes polarized when a current is passed through it and is<br>
-an active magnet. On the cessation of the current its magnetism in part<br>
-or almost completely disappears. (See Electro-magnet.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Equator of.</span><br>
-In a magnet the locus of points of no attractive power and of no<br>
-polarity. In a symmetrical, evenly polarized magnet it is the imaginary<br>
-line girdling the centre. The terms Neutral Point or Neutral Line have<br>
-displaced it.<br>
-<br>
-Synonyms--Neutral Line--Neutral Point.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Field.</span><br>
-A magnet, generally an electro-magnet, used to produce the field in a<br>
-dynamo or motor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Haarlem.</span><br>
-Celebrated magnets made in Haarlem, Holland. Logeman, Van Wetteren,<br>
-Funckler and Van der Willigen were the makers who gave the celebrity to<br>
-the magnets. They were generally horseshoe magnets, and would carry<br>
-about twenty times their own weight.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet, Horseshoe.</span><br>
-A magnet of U shape--properly one with the poles brought a little closer<br>
-together than the rest of the limbs. For direct lifting and attractive<br>
-effects it is the most generally adopted type. Its advantage as regards<br>
-lifting effect is due to small reluctance, q. v., offered by a complete<br>
-iron circuit, such as the armature and magnet together produce. As the<br>
-term is now used it is applied to any U shaped magnet.<br>
-<br>
-<br>
-<img style="width: 676px; height: 482px;" alt=""
- src="images/337F218.jpg"><br>
-Fig. 218. JOULE'S ELECTRO-MAGNET.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Joule's Electro.</span><br>
-An electro-magnet of the shape of a cylinder with a longitudinal segment<br>
-cut-off. It is wound with wire as shown. The segment cut-off is a piece<br>
-of the same shape as the armature. It is of high power.<br>
-<br>
-<br>
-338&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Adherence.</span><br>
-The tendency of a mass of iron to adhere to the poles of a magnet. It is<br>
-best figured as due to the virtual shortening of lines of force, as the<br>
-more permeable iron gives a better path for them than the air can<br>
-afford, and consequently a virtually shorter one.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Attraction and Repulsion.</span><br>
-The attraction of a magnet for iron, steel, nickel and cobalt and of<br>
-unlike poles of magnets for each other. It is identical with<br>
-electro-magnetic attraction, q.v. (Also see Electro-magnetism.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Attraction and Repulsion,
-Coulomb's Law of.</span><br>
-Magnetic attraction and repulsion are inversely as the square of the<br>
-distance. (Ganot.)<br>
-<br>
-While theoretically true in the case of isolated poles, in practise it<br>
-does not generally apply on account of the large diameter and relative<br>
-shortness of magnets.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Axis.</span><br>
-The line connecting the poles of a magnet. It does not generally<br>
-coincide exactly with any symmetrical axis of figure. In such cases an<br>
-error is introduced into the indications of the needle which must be<br>
-determined and allowed for in compasses. To determine it with a magnetic<br>
-needle the suspension cup is made removable, so that the needle can be<br>
-reversed. Readings are taken with one side of the needle and then with<br>
-the other side of the needle up, and the average corresponds with the<br>
-position of the magnetic axis in both positions of the needle.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Azimuth.</span><br>
-The angle, measured on a horizontal circle, between the magnetic<br>
-meridian and a great circle of the earth passing through the observer<br>
-and any observed body. It is the astronomical azimuth of a body referred<br>
-to the magnetic meridian and therefore subject to the variation of the<br>
-compass. The angle is the magnetic azimuth of the observed body.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Battery.</span><br>
-A name for a compound permanent magnet; one made up by bolting or<br>
-clamping together, or to single soft iron pole pieces, a number of<br>
-single permanent magnets. There are a number of forms of compound<br>
-magnets. In making them care has to be taken to have them of even<br>
-strength. It is also well to have them slightly separated. The object of<br>
-both these precautions is to prevent a stronger element or magnet from<br>
-depolarizing its neighbor.<br>
-<br>
-Synonym--Compound Magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Bridge.</span><br>
-An apparatus for testing the relative permeability of iron. It consists<br>
-of a rectangular system of iron cores. Three of the sides are wound with<br>
-wire as shown. The other side is built up of double bars, and from the<br>
-centre two curved arms rise, as shown in the cut. The arms do not touch.<br>
-Between them a short magnet is suspended by a filament, which also<br>
-carries a mirror and an index.<br>
-<br>
-<br>
-339&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 669px; height: 265px;" alt=""
- src="images/339F219.jpg"><br>
-Fig. 219. MAGNETIC BRIDGE.<br>
-<br>
-<br>
-A lamp and scale are provided as in the reflecting galvanometer. When<br>
-adjusted the magnetic needle hangs as shown in the cut, Fig. 219,<br>
-without any tendency to turn towards either curved pole piece. If all<br>
-iron parts are symmetrical and of similar metal, a current through the<br>
-coils will make no difference. It will work in magnetic opposition upon<br>
-the two arms, or, in other words, will maintain both arms at identical<br>
-potential.<br>
-<br>
-<br>
-<img style="width: 644px; height: 288px;" alt=""
- src="images/339F220.jpg"><br>
-Fig. 220. POLE PIECES, MAGNETIC NEEDLE <br>
-AND MIRROR OF MAGNETIC BRIDGE.<br>
-<br>
-<br>
-If there is the least difference in permeability, length or thickness<br>
-between any of the iron bars the magnetic potential of the two curved<br>
-arms will differ, and the magnetic needle will turn one way or the<br>
-other. In practical use different samples of iron are substituted for<br>
-the unwound members of the fourth side of the parallelogram, and the<br>
-needle by its motions indicates the permeability.<br>
-<br>
-In the cut, Fig. 220, D D are the ends of the curved pole pieces; A the<br>
-wire carrying the mirror B and magnetic needle N, and E is the index<br>
-which shows the larger deflections.<br>
-<br>
-<br>
-340&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Circuit.</span><br>
-A magnetic field of force is characterized by the presence of lines of<br>
-force, which, while approximately parallel, curve around and tend to<br>
-form closed curves. The polarity of a field of force is referred to an<br>
-imaginary direction of the lines of force from the north pole through<br>
-space to the south pole, and in the part of the field corresponding to<br>
-the body of the magnet, from the south to the north pole. The cut<br>
-indicates these features. Hence the magnetic field of force is termed<br>
-the magnetic circuit, and to it are attributed a species of resistance<br>
-termed reluctance, q. v., and the producing cause of the field or lines<br>
-of force is termed sometimes magneto-motive force, q. v.) corresponding<br>
-to the electro-motive force. The modern treatment of the magnetic<br>
-circuit is similar to the application of Ohm's law and the laws of<br>
-resistance and conductivity to the electric circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Circuit, Double.</span><br>
-A magnetic circuit which virtually represents two horseshoe magnets<br>
-placed with their like poles in contact. It is used for field magnets,<br>
-the armatures occupying a place between the consequent poles.<br>
-<br>
-<br>
-<img style="width: 606px; height: 547px;" alt=""
- src="images/340F221.jpg"><br>
-Fig. 221. ONE-HALF PORTION OF A DOUBLE MAGNETIC CIRCUIT.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Concentration of Ores.</span><br>
-The concentration of ores or the freeing them from their gangue by<br>
-magnetic attraction. It is only applicable to those cases in which<br>
-either the ore itself or the gangue is attracted by the magnet. Its<br>
-principal application is to the concentration of magnetic iron sands.<br>
-(See Magnetic Concentration.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Concentrator.</span><br>
-An apparatus similar to a magnetic separator, q. v., but used to<br>
-concentrate magnetic iron sands. By the action of electro-magnets the<br>
-magnetic iron sand (magnetite) is separated from the sand with which it<br>
-is mixed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Conductivity and Conductance.</span><br>
-The first notion of permeance and of the magnetic circuit included the<br>
-idea of magnetic conductivity, which conducted lines of force urged by<br>
-magneto-motive force through a magnetic circuit. The terms are displaced<br>
-by permeability and permeance.<br>
-<br>
-<br>
-341&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Continuity.</span><br>
-The completeness of a magnetic circuit, as when the armature of a<br>
-horseshoe magnet is in contact with both poles. It is an attribute of a<br>
-paramagnetic substance only and is identical for permanent magnets or<br>
-for electro-magnets. An air space intervening between armature and<br>
-magnet poles, or a space filled with any diamagnetic substance prevents<br>
-continuity, although the lines of force to some extent still find their<br>
-way around. The leakage is increased by discontinuity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Control.</span><br>
-Control of a magnetic needle, magnet, iron index or armature, in a<br>
-galvanometer, ammeter or voltmeter by a magnetic field; the restitutive<br>
-force being derived from a permanent magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Couple.</span><br>
-The couple of magnetic force which tends to bring the magnetic needle<br>
-into the plane of the magnetic meridian. One force is represented by the<br>
-imaginary pull upon the north pole, and the other by the opposite pull<br>
-upon the south pole of the needle. The moment of the couple varies from<br>
-a maximum when the needle is at right angles to the plane of the<br>
-magnetic meridian to zero when it is in such plane.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Creeping.</span><br>
-Viscous hysteresis; the slow increase of magnetism in a paramagnetic<br>
-body when exposed to induction.<br>
-<br>
-<br>
-<img style="width: 536px; height: 580px;" alt=""
- src="images/341F222.jpg"><br>
-Fig. 222. MAGNETIC CURVES OR FIGURES.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Curves.</span><br>
-The pictorial representation of magnetic lines of force. It is generally<br>
-produced by scattering filings on a sheet of paper or pane of glass held<br>
-over a magnet. The filings arrange themselves in characteristic curves.<br>
-Tapping the paper or pane of glass facilitates the arrangement, or<br>
-jarring the filings off a smaller magnet, so that they fall polarized<br>
-upon the paper, is thought by some to improve the effect. The group of<br>
-curves forms what are termed magnetic figures, q. v.<br>
-<br>
-<br>
-342&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Declination.</span><br>
-The angular deviation of the magnetic needle, causing it to rest at an<br>
-angle with the true meridian; the variation of the compass. (See<br>
-Magnetic Elements.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Density.</span><br>
-The intensity of magnetization expressed in lines of force per stated<br>
-area of cross-section in a plane at right angles to the lines of force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Dip.</span><br>
-The inclination from the horizontal assumed by a magnetic needle free to<br>
-move in the vertical plane. (See Magnetic Elements.) The angle of dip or<br>
-inclination is entirely a function of the earth, not of the needle.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Discontinuity.</span><br>
-A break or gap in a magnetic circuit. To make a complete circuit the<br>
-iron or other core must be continuous. If the armature of a horseshoe<br>
-magnet is in contact with both poles the continuity is complete. If the<br>
-armature is not in contact magnetic continuity gives place to<br>
-discontinuity. It is an attribute of a paramagnetic substance only, and<br>
-is identical for permanent magnets, or for electro-magnets.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Elements.</span><br>
-The qualities of the terrestrial magnetism at any place as expressed in<br>
-its action upon the magnetic needle. Three data are involved.<br>
-<br>
-I. The Declination or Variation.<br>
-II. The Inclination or Dip.<br>
-III. The Force or Intensity.<br>
-<br>
-I. The Declination is the variation expressed in angular degrees of the<br>
-magnetic needle from the true north and south, or is the angle which the<br>
-plane of the magnetic meridian makes with that of the geographical<br>
-meridian. It is expressed as east or west variation according to the<br>
-position of the north pole; east when the north pole of the needle is to<br>
-the east of the true meridian, and vice versa. Declination is different<br>
-for different places; it is at present west in Europe and Africa, and<br>
-east in Asia and the greater part of North and South America. The<br>
-declination is subject to (a) secular, (b) annual and (c) diurnal<br>
-variations. These are classed as regular; others due to magnetic storms<br>
-are transitory and are classed as irregular, (a) Secular variations. The<br>
-following table shows the secular variations during some three hundred<br>
-years at Paris. These changes are termed secular, because they require<br>
-centuries for their completion.<br>
-<br>
-<br>
-</big></big><big><big>343 &nbsp;</big></big><big><big>
-&nbsp; STANDARD ELECTRICAL DICTIONARY. <br>
-<br>
-<br>
-Table of Declination or Variation at Paris.<br>
-Year.&nbsp;&nbsp; Declination.<br>
-1580&nbsp;&nbsp; 11&ordm; 30' E.<br>
-1663&nbsp;&nbsp;&nbsp; 0&deg;<br>
-1700&nbsp;&nbsp;&nbsp; 8&deg; 10' W.<br>
-1780&nbsp;&nbsp; 19&ordm; 55' W.<br>
-1785&nbsp;&nbsp; 22&ordm; 00' W.<br>
-1805&nbsp;&nbsp; 22&ordm;&nbsp; 5' W.<br>
-1814&nbsp;&nbsp; 22&ordm; 34' W.<br>
-1825&nbsp;&nbsp; 22&deg; 22' W.<br>
-1830&nbsp;&nbsp; 22&ordm; 12' W.<br>
-1835&nbsp;&nbsp; 22&ordm;&nbsp; 4' W.<br>
-1850&nbsp;&nbsp; 20&ordm; 30' W.<br>
-1855&nbsp;&nbsp; 19&ordm; 57' W.<br>
-1860&nbsp;&nbsp; 19&ordm; 32' W.<br>
-1865&nbsp;&nbsp; 18&ordm; 44' W.<br>
-1875&nbsp;&nbsp; 17&ordm; 21' W.<br>
-1878&nbsp;&nbsp; 17&ordm; 00' W.<br>
-[Transcriber's note The value for 2008 is about&nbsp; 0&deg; 48' W,
-changing by<br>
-0&deg; 7' E/year.]<br>
-<br>
-On scrutinizing these figures it will be seen that there is part of a<br>
-cycle represented and that the declination is slowly returning to the<br>
-zero point after having reached its maximum western variation in 1814.<br>
-Upwards of 300 years would be required for its completion on the basis<br>
-of what is known. In other places, notably the coast of Newfoundland,<br>
-the Gulf of the St. Lawrence and the rest of the North American seaboard<br>
-and in the British Channel, the secular variations are much more rapid<br>
-in progress. (b) Annual variations--These were first discovered in 1780<br>
-by Cassini. They represent a cycle of annual change of small extent,<br>
-from 15' to 18' only. In Paris and London the annual variation is<br>
-greatest about the vernal equinox, or March 21st, and diminishes for the<br>
-next three months, and slowly increases again during the nine following<br>
-months. It varies during different epochs. (c) Diurnal variations were<br>
-discovered in 1722 by Graham. A long needle has to be employed, or the<br>
-reflection of a ray of light, as in the reflecting galvanometer, has to<br>
-be used to observe them. In England the north pole of the magnetic<br>
-needle moves every day from east to west from sunrise until 1 or 2 P.<br>
-M.; it then tends towards the east and recovers its original position by<br>
-10 P. M. During the night the needle is almost stationary. As regards<br>
-range the mean amplitude of diurnal variations at Paris is from April to<br>
-September 13' to 15'; for the other months from 8' to 10'. On some days<br>
-it amounts to 25' and sometimes is no more than 5'. The amplitude of<br>
-diurnal variations decreases from the poles to the equator. Irregular<br>
-variations accompany earthquakes, the aurora borealis and volcanic<br>
-eruptions. In Polar regions the auroral variations may be very great;<br>
-even at 40&deg; latitude they may be 1&deg; or 2&deg;. Simultaneous
-irregularities<br>
-sometimes extend over large areas. Such are attributed to magnetic<br>
-storms. II. The Inclination is the angle which the magnetic needle makes<br>
-with the horizon, when the vertical plane in which the needle is assumed<br>
-to be free to move coincides with the magnetic meridian. It is sometimes<br>
-called the dip of the needle. It varies as does the declination, as<br>
-shown in the following table of inclinations of London.<br>
-<br>
-<br>
-344&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Table of Inclination or Dip at London<br>
-Year.&nbsp;&nbsp; Inclination.<br>
-1576&nbsp;&nbsp; 71&deg; 50'<br>
-1600&nbsp;&nbsp; 72&deg;<br>
-1676&nbsp;&nbsp; 73&deg; 30'<br>
-1723&nbsp;&nbsp; 74&deg; 42'<br>
-1773&nbsp;&nbsp; 72&deg; 19'<br>
-1780&nbsp;&nbsp; 72&deg;&nbsp; 8'<br>
-1790&nbsp;&nbsp; 71&deg; 33'<br>
-1800&nbsp;&nbsp; 70&deg; 35'<br>
-1821&nbsp;&nbsp; 70&deg; 31'<br>
-1828&nbsp;&nbsp; 69&deg; 47'<br>
-1838&nbsp;&nbsp; 69&deg; 17'<br>
-1854&nbsp;&nbsp; 68&deg; 31'<br>
-1859&nbsp;&nbsp; 68&deg; 21'<br>
-1874&nbsp;&nbsp; 67&deg; 43'<br>
-1876&nbsp;&nbsp; 67&deg; 39'<br>
-1878&nbsp;&nbsp; 67&deg; 36'<br>
-1880&nbsp;&nbsp; 67&deg; 35'<br>
-1881&nbsp;&nbsp; 67&deg; 35'<br>
-<br>
-III. Force or Intensity is the directive force of the earth. It varies<br>
-with the squares of the number of oscillations the magnetic needle will<br>
-make if caused to oscillate from a determined initial range. The<br>
-intensity is supposed to be subject to secular change. According to<br>
-Gauss the total magnetic intensity of the earth is equal to that which<br>
-would be exerted if in each cubic yard there were eight bar magnets,<br>
-each weighing one pound. This is, of course, a rough way of expressing<br>
-the degree of intensity. Intensity is least near the magnetic equator<br>
-and greatest near the magnetic poles; the places of maximum intensity<br>
-are termed the magnetic foci. It varies with the time of day and<br>
-possibly with changes in altitude.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Elongation.</span><br>
-The elongation a bar of iron or steel undergoes when magnetized. By<br>
-magnetization it becomes a little longer and thinner, there being no<br>
-perceptible change in volume. The change is accompanied by a slight<br>
-sound--the magnetic tick. An exceedingly delicate adjustment of<br>
-apparatus is required for its observation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Equator.</span><br>
-A locus of the earth's surface where the magnet has no tendency to dip.<br>
-It is, approximately speaking, a line equally distant from the magnetic<br>
-poles, and is called also the aclinic line. It is not a great circle of<br>
-the earth.<br>
-<br>
-<br>
-345&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Field of Force.</span><br>
-The field of force established by a magnet pole. The attractions and<br>
-repulsions exercised by such a field follow the course of the electro-<br>
-magnetic lines of force. (See also Field of Force.) Thus the tendency of<br>
-a polarized needle attracted or repelled is to follow, always keeping<br>
-tangential to curved lines, the direction of the lines of force, however<br>
-sweeping they may be. The direction of magnetic lines of force is<br>
-assumed to be the direction in which a positive pole is repelled or a<br>
-negative one attracted; in other words, from the north pole of a magnet<br>
-to its south pole in the outer circuit. The direction of lines of force<br>
-at any point, and the intensity or strength of the field at that point,<br>
-express the conditions there. The intensity may bc expressed in terms of<br>
-that which a unit pole at unit distance would produce. This intensity as<br>
-unitary it has been proposed to term a Gauss. (See Weber.)<br>
-<br>
-The direction of the lines of force in a magnetic field are shown by the<br>
-time-honored experiment of sprinkling filings of iron upon a sheet of<br>
-paper held over a magnet pole or poles. They arrange themselves, if the<br>
-paper is tapped, in more or less curved lines tending to reach from one<br>
-pole of the magnet to the other. Many figures may be produced by<br>
-different conditions. Two near poles of like name produce lines of force<br>
-which repel each other. (See Magnetic Curves.)<br>
-<br>
-A magnetic and an electro-magnetic field are identical in all essential<br>
-respects; the magnetic field may be regarded as a special form of the<br>
-electro-magnetic field, but only special as regards its production and<br>
-its defined north and south polar regions.<br>
-<br>
-Synonyms--Magnetic Spin (not much used).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Field, Uniform.</span><br>
-A field of identical strength in all parts, such as the earth's magnetic<br>
-field. If artificially produced, which can only be approximately done,<br>
-it implies large cross-section of magnet pole in proportion to the<br>
-length of the magnetic needle affected by it, which is used in<br>
-determining its uniformity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Figures.</span><br>
-The figures produced by iron filings upon paper or glass held near<br>
-magnetic poles. By these figures the direction of lines of force is<br>
-approximately given, and a species of map of the field is shown. (See<br>
-Magnetic Field of Force--Magnetic Curves.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Filament.</span><br>
-The successive rows of polarized molecules assumed to exist in<br>
-magnetized iron. Each molecule represents an infinitely small magnet,<br>
-and its north pole points to the south pole of the next molecule. Such a<br>
-string or row is a theoretical conception based on the idea that the<br>
-molecules in a magnet are all swung in to parallelism in the magnetizing<br>
-process. A magnetic filament may be termed the longitudinal element of a<br>
-magnet. (See Magnetism, Hughes' Theory of.)<br>
-<br>
-[Transcriber's note: This description parallels the modern<br>
-notion of electron spin as the basis of magnetism in materials.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Fluids.</span><br>
-A two-fluid theory of magnetism has been evolved, analogous to the<br>
-two-fluid theory of electricity. It assumes north fluid or "red<br>
-magnetism" and a south fluid or "blue magnetism." Each magnetism is<br>
-supposed to predominate at its own pole and to attract its opposite.<br>
-Before magnetization the fluids are supposed to neutralize each other<br>
-about each molecule; magnetization is assumed to separate them,<br>
-accumulating quantities of them at the poles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Flux.</span><br>
-Magnetic induction; the number of lines of force that pass through a<br>
-magnetic circuit.<br>
-<br>
-Synonym--Magnetic Flow.<br>
-<br>
-<br>
-346&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Force.</span><br>
-The forces of attraction and repulsion exercised by a magnet. By<br>
-Ampere's theory it is identical with the forces of attraction and<br>
-repulsion of electric currents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Friction.</span><br>
-The damping effect produced on the movements of a mass of metal by<br>
-proximity to a magnet; the phenomenon illustrated in Arago's wheel, q.<br>
-v. When a mass of metal moves in the vicinity of a magnet it cuts the<br>
-lines of force emanating from its poles, thereby producing currents in<br>
-its mass; as the production of these currents absorbs energy a damping<br>
-effect is produced upon the movements of the mass.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Gear.</span><br>
-Friction gear in which electro-magnetic adherence is employed to draw<br>
-the wheels together. (See Adherence, Electro-magnetic--Electro-magnetic<br>
-Friction Gear.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Inclination.</span><br>
-The inclination from the horizontal of a magnetic needle placed in the<br>
-magnetic meridian. (See Magnetic Element--Inclination Map.)<br>
-<br>
-Synonym--Magnetic Dip.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Induction.</span><br>
-The force of magnetization within an induced magnet. It is in part due<br>
-to the action of the surrounding particles of polarized material; in<br>
-part to the magnetic field. (See Magnetic Induction, Coefficient of.)<br>
-<br>
-In a more general way it is the action of a magnet upon bodies in its<br>
-field of force. In some cases the magnetism induced causes the north<br>
-pole of the induced magnet to place itself as far as possible from the<br>
-north pole of the inducing magnet and the same for the south poles. Such<br>
-substances are called paramagnetic or ferromagnetic. They lie parallel<br>
-or tangential to the lines of force. In other cases the bodies lie at<br>
-right angles or normal to the lines of force. Such bodies are called<br>
-diamagnetic.<br>
-<br>
-Some bodies are crystalline or not homogeneous in structure, and in them<br>
-the lines of magnetic induction may take irregular or eccentric paths.<br>
-(See AEolotropic.)<br>
-<br>
-Synonym--Magnetic Influence.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Induction, Apparent
-Coefficient of.</span><br>
-The apparent permeability of a paramagnetic body as affected by the<br>
-presence of Foucault currents in the material itself. These currents act<br>
-exactly as do the currents in the coils surrounding the cores of<br>
-electro-magnets. They produce lines of force which may exhaust the<br>
-permeability of the iron, or may, if in an opposite direction, add to<br>
-its apparent permeability.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Induction, Coefficient of.</span><br>
-The number, obtained by dividing the magnetization of a body, expressed<br>
-in lines of force produced in it, by the magnetizing force which has<br>
-produced such magnetization, expressed in lines of force producible by<br>
-the force in question in air. It always exceeds unity for iron, nickel<br>
-and cobalt. It is also obtained by multiplying the coefficient of<br>
-induced magnetization by 4 PI (4 * 3.14159) and adding 1. (See Magnetic<br>
-Susceptibility--Magnetization, Coefficient of Induced.)<br>
-<br>
-<br>
-347&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The coefficient of magnetic induction varies with the material of the<br>
-induced mass, and varies with the intensity of the magnetizing force.<br>
-This variation is due to the fact that as the induced magnetism in a<br>
-body increases, the magnetizing force required to maintain such<br>
-induction, increases in a more rapid ratio. The coefficient of magnetic<br>
-induction is the same as magnetic permeability, and in a certain sense<br>
-is the analogue of conductivity. It is also termed the multiplying power<br>
-of the body or core magnetized. It is the coefficient of induced<br>
-magnetization (see Magnetization, Coefficient of Induced) referred to a<br>
-mass of matter. For diamagnetic bodies the coefficient has a negative<br>
-sign; for paramagnetic bodies it has a positive sign.<br>
-<br>
-Synonyms--Permeability--Multiplying Power--Magnetic Inductive Capacity.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Induction, Dynamic.</span><br>
-The induction produced by a magnetic field which moves with respect to a<br>
-body, or where the body if moving moves at a different rate, or where<br>
-the body moves and the field is stationary. In the case where both move,<br>
-part of the induction may be dynamic and part static. (See Magnetic<br>
-Induction, Static.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Induction, Static.</span><br>
-Magnetic induction produced by a stationary field acting upon a<br>
-stationary body.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Induction, Tube of.</span><br>
-An approximate cylinder or frustrum of a cone whose sides are formed of<br>
-lines of magnetic induction. (See Magnetic Induction, Lines of.) The<br>
-term tube is very curiously applied in this case, because the element or<br>
-portion of a magnetic field thus designated is in no sense hollow or<br>
-tubular.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Inertia.</span><br>
-A sensible time is required to magnetize iron, or for it to part with<br>
-its magnetism, however soft it may be. This is due to its magnetic<br>
-inertia and is termed the lag. Permanent or residual magnetism is a<br>
-phase of it. It is analogous to self-induction of an electric circuit,<br>
-or to the residual capacity of a dielectric.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Insulation.</span><br>
-Only approximate insulation of magnetism is possible. There is no<br>
-perfect insulator. The best ones are only 10,000 times less permeable<br>
-than iron. Hence lines of force find their way through air and all other<br>
-substance, being simply crowded together more in paths of iron or other<br>
-paramagnetic substance.<br>
-<br>
-<br>
-348&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Intensity.</span><br>
-The intensity of the magnetization of a body. It is measured by the<br>
-magnetic lines of force passing through a unit area of the body, such<br>
-area being at right angles to the direction of the lines of force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Lag.</span><br>
-In magnetism the tendency of hard iron or steel especially to take up<br>
-magnetism slowly, and to part with it slowly. (See Magnetic Inertia.)<br>
-The lag affects the action of a dynamo, and is a minor cause of those<br>
-necessitating the lead of the brushes.<br>
-<br>
-Synonym--Magnetic Retardation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Latitude.</span><br>
-Latitude referred to the magnetic equator and isoclinic lines.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Leakage.</span><br>
-The lines of force in a field magnet which pass through the air and not<br>
-through the armature are useless and represent a waste of field. Such<br>
-lines constitute magnetic leakage.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Limit.</span><br>
-The temperature beyond which a paramagnetic metal cannot be magnetized.<br>
-The magnetic limit of iron is from a red to a white heat; of cobalt, far<br>
-beyond a white heat; of chromium, below a red heat; of nickel at about<br>
-350&deg; C. (662&deg;F.) of manganese, from 15&deg; C. to 20&deg; C.
-(59&deg; to 68&deg; F.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Lines of Force.</span><br>
-Lines of force indicating the distribution of magnetic force, which is<br>
-due presumably to whirls of the ether. A wire or conductor through which<br>
-a current is passing is surrounded by an electro-magnetic field of<br>
-force, q. v., whose lines of force form circles surrounding the<br>
-conductor in question. A magnet marks the existence of a similar<br>
-electro-magnetic field of force whose lines form circuits comprising<br>
-part of and in some places all of the body of the magnet, and which are<br>
-completed through the air or any surrounding paramagnetic or diamagnetic<br>
-body. They may be thought of as formed by the Amp&eacute;rian sheet of
-current,<br>
-and analogous to those just mentioned as surrounding a conductor.<br>
-<br>
-<br>
-<img style="width: 723px; height: 287px;" alt=""
- src="images/348F223.jpg"><br>
-Fig. 223. MAGNETIC LINES OF FORCE, DIRECTION OF.<br>
-<br>
-<br>
-A magnetic line of force may be thought of as a set of vortices or<br>
-whirls, parallel to each other, and strung along the line of force which<br>
-is the locus of their centres.<br>
-<br>
-If as many lines are drawn per square centimeter as there are dynes (per<br>
-unit pole) of force at the point in question, each such line will be a<br>
-unitary c. g. s. line of force.<br>
-<br>
-<br>
-349&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Mass.</span><br>
-A term for a quantity of magnetism. Unit mass is the quantity which at<br>
-unit distance exercises unit force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Matter.</span><br>
-Imaginary matter assumed as a cause of magnetism. Two kinds, one<br>
-positive and one negative, may be assumed as in the two fluid theory of<br>
-electricity, or only one kind, as in the single fluid theory of<br>
-electricity. Various theories of magnetic matter have been presented<br>
-whose value is only in their convenience.<br>
-<br>
-[Transcriber's note: See "magnet" and Edward Purcell's explanation of<br>
-magnetism using general relativity.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Memory.</span><br>
-The property of retaining magnetism; coercive force; magnetic inertia;<br>
-residual magnetism.<br>
-<br>
-[Transcriber's note: Small ferrite magnetic donuts were used as computer<br>
-main memory from 1950 to 1970.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Meridian.</span><br>
-A line formed on the earth's surface by the intersection therewith of a<br>
-plane passing through the magnetic axis. It is a line determined by the<br>
-direction of the compass needle. The meridians constantly change in<br>
-direction and correspond in a general way to the geographical meridians.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Moment.</span><br>
-The statical couple with which a magnet would be acted on by a uniform<br>
-magnetic field of unit intensity if placed with its magnetic axis at<br>
-right angles to the lines of force of the field. (Emtage.) A uniformly<br>
-and longitudinally magnetized bar has a magnetic moment equal to the<br>
-product of its length by the strength of its positive pole.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Needle.</span><br>
-A magnet with a cup or small depression at its centre and poised upon a<br>
-sharp pin so as to be free to rotate or oscillate in a horizontal plane.<br>
-The cup is often made of agate. Left free to take any position, it<br>
-places its magnetic axis in the magnetic meridian.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Parallels.</span><br>
-Lines roughly parallel to the magnetic equator on all parts of each of<br>
-which the dip of the magnetic needle is the same; also called Isoclinic<br>
-Lines. These lines mark the places of the intersection of equipotential<br>
-surfaces with the earth's surface. They are not true circles, and near<br>
-the poles are irregular ellipses; the magnet there points toward their<br>
-centres of curvature. They correspond in a general way with the<br>
-Geographical Parallels of Latitude.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Permeability.</span><br>
-The specific susceptibility of any substance, existing in a mass, for<br>
-magnetic induction. (See Magnetic Induction, Coefficient of, synonym for<br>
-Magnetic Permeability and Magnetization, Coefficient of Induced.)<br>
-<br>
-Synonyms--Magnetic Inductive Capacity--Multiplying Power--Coefficient of<br>
-Magnetic Induction.<br>
-<br>
-<br>
-350&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Perturbations.</span><br>
-Irregular disturbances of the terrestrial magnetism, as by the aurora<br>
-and in electric storms.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Poles.</span><br>
-The points where the equipotential surfaces of the terrestrial field of<br>
-force graze the earth's surface; the points toward which the north or<br>
-south poles of the magnetic needle is attracted. Over a magnetic pole<br>
-the magnetic needle tends to stand in a vertical position. There are two<br>
-poles, Arctic or negative, and Antarctic or positive. Magnetic needles<br>
-surrounding them do not necessarily point toward them, as they point to<br>
-the centres of curvature of their respective magnetic parallels. The<br>
-poles constantly change in position. The line joining them does not<br>
-coincide with anything which may be termed the magnetic axis of the<br>
-earth.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Poles, False.</span><br>
-Poles on the earth's surface other than the two regular magnetic poles.<br>
-There seem by observation to be several such poles, while analogy would<br>
-limit true magnetic poles to two in number.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Potential.</span><br>
-The potential at any point of a magnetic field is the work which would<br>
-be done by the magnetic forces of the field upon a positive unit of<br>
-magnetism as it moves from that point to an infinite distance. (Emtage.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Proof Piece.</span><br>
-A piece of iron used for testing magnets and the distribution of<br>
-magnetism in bars, by suspending or supporting above or near the magnet,<br>
-by detaching after adherence, and in other ways.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Proof Plane.</span><br>
-An exploring coil used for testing the distribution of magnetism. It is<br>
-connected in circuit with a galvanometer, and exposed to alternation of<br>
-current, or to other disturbing action produced by the magnet or field<br>
-under examination. This affects the galvanometer, and from its movements<br>
-the current produced in the coil, and thence the magnetic induction to<br>
-which it was exposed, are calculated.<br>
-<br>
-Synonym--Exploring Coil.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Quantity.</span><br>
-The magnetism possessed by a body; it is proportional to the action of<br>
-similar poles upon each other, or to the field produced by the pole in<br>
-question. It is also called the strength of a pole.<br>
-<br>
-The force exercised by two similar poles upon each other varies with<br>
-their product and inversely with the square of the distance separating<br>
-them; or it may be expressed thus (m * m) / (L^2). This is a force, and<br>
-the dimensions of a force are ML/(T^2). Therefore, (m^2)/(L^2) =<br>
-ML/(T^2) or m = (M^.5)*(L^1.5)/T.<br>
-<br>
-<br>
-351&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Reluctance.</span><br>
-The reciprocal of permeance; magnetic resistance; the relative<br>
-resistance to the passage of lines of force offered by different<br>
-substances. The idea is derived from treating the magnetic circuit like<br>
-an electric one, and basing its action on magneto-motive force acting<br>
-through a circuit possessing magnetic reluctance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Reluctivity.</span><br>
-The reciprocal of magnetic permeability, q. v.<br>
-<br>
-Synonym--Magnetic Resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Retentivity.</span><br>
-The property of steel or hard iron by which it slowly takes up and<br>
-slowly parts with a magnetic condition--traditionally (Daniell) called<br>
-coercitive force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Rotary Polarization.</span><br>
-If a plane polarized beam of light is sent through a transparent medium<br>
-in a magnetic field its plane of polarization is rotated, and this<br>
-phenomenon is denoted as above. (Compare Refraction, Electric, and see<br>
-Electro-magnetic Stress.) This has been made the basis of a method for<br>
-measuring current. A field of force varies with the current; the<br>
-polarization produced by such field is therefore proportional to the<br>
-current. (Becquerel &amp; Rayleigh.)<br>
-<br>
-A plane polarized beam of light passing through the transparent medium<br>
-in the magnetic field by the retardation or acceleration of one of its<br>
-circular components has its plane of polarization rotated as described.<br>
-The direction of the lines of force and the nature of the medium<br>
-determine the sense of the rotation; the amount depends upon the<br>
-intensity of the field resolved in the direction of the ray, and on the<br>
-thickness and nature of the medium.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Saturation.</span><br>
-The maximum magnetic force which can be permanently imparted to a steel<br>
-bar. A bar may be magnetized beyond this point, but soon sinks to it.<br>
-The magnetism produced in a bar is prevented from depolarization by the<br>
-retentivity or coercive force of the bar. The higher the degree of<br>
-magnetization the greater the tendency to depolarization.<br>
-<br>
-It is also defined as the maximum intensity of magnetism produced in a<br>
-paramagnetic substance by a magnetic field as far as affected by the<br>
-permeability of the substance in question. The more lines of force<br>
-passed through such a substance the lower is its residual permeability.<br>
-It is assumed that this becomes zero after a certain point, and then the<br>
-point of saturation is reached. After this point is reached the addition<br>
-of any lines of force is referred entirely to the field and not at all<br>
-to the permeability of the substance. But such a zero is only definable<br>
-approximately.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Screen.</span><br>
-A box or case of soft iron, as thick as practicable, for protecting<br>
-bodies within it from the action of a magnetic field. The lines of force<br>
-to a great extent keep within the metal of the box on account of its<br>
-permeability, and but a comparatively few of them cross the space within<br>
-it.<br>
-<br>
-Such screens are used to prevent watches from being magnetized, and are<br>
-a part of Sir William Thomson's Marine galvanometer.<br>
-<br>
-A magnetic screen may be a sphere, an infinite or very large plane, or<br>
-of the shape of any equipotential surface.<br>
-<br>
-Synonym--Magnetic Shield.<br>
-<br>
-<br>
-352&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Self-induction.</span><br>
-The cause of a magnet weakening is on account of this quality, which is<br>
-due to the direction of the lines of force within a magnet from the<br>
-positive towards the negative pole. "A magnet thus tends to repel its<br>
-own magnetism and to weaken itself by self-induction." (Daniell.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Separator.</span><br>
-An apparatus for separating magnetic substances from mixtures. Such<br>
-separators depend on the action of electro-magnets. In one form the<br>
-material falls upon an iron drum, magnetized by coils. Any magnetic<br>
-substance adheres to the drum and is thereby separated. They are used by<br>
-porcelain makers for withdrawing iron particles from clay, by machinists<br>
-to separate iron filings and chips from brass, and for similar purposes.<br>
-<br>
-<br>
-<img style="width: 481px; height: 574px;" alt=""
- src="images/352F224.jpg"><br>
-Fig. 224. MAGNETIC SEPARATOR.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Shell.</span><br>
-A theoretical conception of a cause of a magnetic field or of a<br>
-distribution of magnetism. If we imagine a quantity of very short<br>
-magnets arranged in contact with their like poles all pointing in the<br>
-same direction so as to make a metal sheet, we have a magnetic shell.<br>
-Its magnetic moment is equal to the sum of the magnetic moment of all<br>
-its parts. If the shell is of uniform strength the magnetic moment of a<br>
-unit area gives the strength of the shell; it is equal to the magnetic<br>
-quantity per unit of area, multiplied by the thickness of the shell.<br>
-<br>
-If its strength is uniform throughout a magnetic shell is called simple;<br>
-if its strength varies it is termed complex.<br>
-<br>
-Emtage thus defines it: A magnetic shell is an indefinitely thin sheet<br>
-magnetized everywhere in the direction normal to itself.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Shell, Strength of.</span><br>
-The magnetic quantity per unit of area of the shell multiplied by the<br>
-thickness of the shell.<br>
-<br>
-<br>
-353&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Shield.</span><br>
-In general a magnetic screen, q. v. Sometimes a strong local field is<br>
-made to act as a shield, by its predominance overcoming any local or<br>
-terrestrial field to which the needle to be protected may be exposed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Shunt.</span><br>
-The conception of a magnetic circuit being formed, the shunt is a<br>
-corollary of the theory. It is any piece of iron which connects points<br>
-of a magnet differing in polarity, so as to divert part of the lines of<br>
-force from the armature or yoke. The shunt is especially applicable in<br>
-the case of horseshoe magnets. Thus a bar of iron placed across from<br>
-limb to limb a short distance back from the poles would act as a shunt<br>
-to the armature and would divert to itself part of the lines of force<br>
-which would otherwise go through the armature and would weaken the<br>
-attraction of the magnet for the latter. In dynamos a bar of iron used<br>
-as a magnetic shunt has been used to diminish the lines of force going<br>
-through the armature and hence to weaken the field and diminish the<br>
-electro-motive force. By moving the shunt nearer or further from the<br>
-poles the dynamo is regulated.<br>
-<br>
-In the cut the projections between the yoke and poles of the magnet<br>
-shown act as a shunt to the yoke, taking some lines of force therefrom.<br>
-<br>
-<br>
-<img style="width: 507px; height: 728px;" alt=""
- src="images/353F225.jpg"><br>
-Fig. 225. MAGNETIC SHUNT.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Storms.</span><br>
-Terrestrial magnetic disturbances sometimes covering very wide areas,<br>
-and affecting the magnetic declination and inclination. One such<br>
-disturbance was felt simultaneously at Toronto, Canada, the Cape of Good<br>
-Hope, Prague and Van Diemen's Land. (Sabine.)<br>
-<br>
-<br>
-354&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Strain.</span><br>
-The strain produced by magnetic lines of force in substances exposed to<br>
-their action. It is observed in substances placed between the poles of a<br>
-strong electro-magnet, and evinces itself in the alteration of the<br>
-optical properties of transparent substances.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Stress.</span><br>
-The stress produced by magnetic lines of force on substances through<br>
-which they pass, evidenced in alteration of the optical properties of<br>
-transparent bodies thus treated.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Susceptibility.</span><br>
-The specific intrinsic susceptibility of any material for magnetic<br>
-induction. It refers to the particle of matter, and not to the mass, as<br>
-in the latter its own particles react on each other and bring about what<br>
-is termed permeability, q. v. (See also Magnetization, Coefficient of<br>
-Induced, and Magnetic Induction, Coefficient of.)<br>
-<br>
-Synonym--Coefficient of Induced Magnetization.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Tick.</span><br>
-When a bar of iron is suddenly magnetized or demagnetized it emits a<br>
-slight sound, called the Page sound, or the magnetic tick. This has been<br>
-utilized in a telephone by Reiss. The telephone will receive sound, but<br>
-is very weak. It consists of a bar surrounded with a coil of insulated<br>
-wire. Variations in current produce sounds, which may be articulate if<br>
-the currents are produced by a telephonic transmitter.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetic Twist.</span><br>
-A bar of iron held in the magnetic meridian and pointing to the pole and<br>
-twisted becomes to some extent permanently magnetized. Conversely a bar<br>
-when magnetized seems to have a twist set up in it. The latter is<br>
-magnetic twist.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Variations.</span><br>
-Changes in the value of magnetic declination or inclination. (See<br>
-Magnetic Elements.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Amp&eacute;re's Theory of.</span><br>
-A theory accounting for magnetic phenomena by assuming the existence of<br>
-currents circulating around the molecules of permanent magnets. If such<br>
-currents so circulate and all in the same direction, the result is the<br>
-same as if the body of the magnet was enveloped in currents representing<br>
-those of an electro-magnet or solenoid. This is because in the interior<br>
-the current around one molecule would counteract the current around its<br>
-neighboring ones in part, so that the only virtual currents left would<br>
-be represented by those on the outer surfaces of the outer shell of<br>
-molecules, and these virtually resolve themselves into one general<br>
-current sheet, surrounding the magnet and coinciding with its surface.<br>
-<br>
-The theory assumes that such currents permanently circulate around the<br>
-molecules of paramagnetic substances. Under ordinary conditions there is<br>
-no coincidence in their direction and no resultant current is produced.<br>
-When magnetized or polarized the molecules are brought into order, so<br>
-that the direction of their current coincides and the body becomes a<br>
-magnet.<br>
-<br>
-<br>
-355&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 607px; height: 469px;" alt=""
- src="images/355F226.jpg"><br>
-Fig. 226. AMP&Eacute;RIAN CURRENTS IN MAGNETS.<br>
-<br>
-<br>
-At the north pole of the magnet the direction of the Amp&eacute;rian
-currents<br>
-is the reverse of that of a watch when the observer faces the pole; the<br>
-reverse obtains for the south pole.<br>
-<br>
-The attraction of opposite and repulsion of similar poles is explained<br>
-by the actions of the Amp&eacute;rian currents upon each other. If
-north and<br>
-south pole are placed together these currents will coincide in direction<br>
-and hence will attract each other. If two like poles are put together<br>
-the currents will have opposite directions and will repel each other.<br>
-<br>
-No energy is supposed to be required to maintain currents around or in a<br>
-single molecule.<br>
-<br>
-<br>
-<img style="width: 683px; height: 320px;" alt=""
- src="images/355F227.jpg"><br>
-Fig. 227. NORTH AND SOUTH POLES OF A MAGNET <br>
-SHOWING DIRECTION OF AMP&Eacute;RIAN CURRENTS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Blue.</span><br>
-A term arising from the two fluid theory of magnetism; the magnetism of<br>
-the south pole of a magnet. (See Magnetic Fluids.) The magnetism of the<br>
-north pole is termed red magnetism. Both terms originated presumably in<br>
-the painting of magnets, and are little used.<br>
-<br>
-Synonym--South Magnetic Fluid.<br>
-<br>
-<br>
-356&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Components of Earth's.</span><br>
-The magnetic force of the earth acts in the plane of the magnetic<br>
-meridian and in direction generally lies oblique to the plane of the<br>
-horizon. It can be resolved into two components, one vertical, which has<br>
-no directive effect upon the magnetic needle, the other horizontal,<br>
-which represents the directive element for the usual compass needle. For<br>
-the dipping needle, q. v., the vertical component is the only active<br>
-one. A magnetic needle mounted on a universal joint at its centre of<br>
-gravity would be acted on by both components.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetism, Creeping of.</span><br>
-The gradual increase of magnetism when a magnetic force is applied with<br>
-absolute steadiness to a piece of iron. It is a form of magnetic lag. It<br>
-may last for half an hour and involve an increase of several per cent.<br>
-of the total magnetism.<br>
-<br>
-Synonym--Viscous Hysteresis.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Iron Clad.</span><br>
-A magnet with a casing of iron connected at one end to the core. The<br>
-term is generally applied to electromagnets of this form.<br>
-<br>
-Synonyms--Tubular Magnet--Jacketed Magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Decay of.</span><br>
-The gradual loss of magnetism by permanent magnets, due to accidental<br>
-shocks, changes of temperature, slow spontaneous annealing of the iron<br>
-and other similar causes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Discharge of.</span><br>
-The loosing of magnetization. Thus in a shunt-wound dynamo there is a<br>
-critical resistance for the outer circuit, below which the field ceases<br>
-to be magnetized, as enough current ceases to be shunted into it to<br>
-magnetize it. The machine is said to unbuild itself, and a discharge of<br>
-magnetism occurs from the field magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Ewing's Theory of.</span><br>
-Ewing found by a model consisting of a number of pivoted magnetic<br>
-needles that the observed phenomena of magnetization could be<br>
-represented thereby. Thus there would be no need of assuming internal<br>
-frictional forces of Maxwell, nor the closed rings or chains of Hughes.<br>
-The theory retains the notion, however, of paramagnetic matter,<br>
-consisting of an assemblage of molecular magnets. The loss of energy by<br>
-hysteresis is represented in the model by the energy lost by the needles<br>
-in beating against the air.<br>
-<br>
-<br>
-357&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Free.</span><br>
-The magnetism or magnetic field outside of a magnetic circuit. It is due<br>
-to escape of lines of force and to the magnetic leakage through the air.<br>
-The lines of force are never, under the most favorable circumstances,<br>
-confined to the metallic circuit of the magnet and armature. In a simple<br>
-magnet without armature all the lines of force have to follow an air<br>
-path, and the field is at its strongest. As the magnetism is strongest<br>
-at the surface near the poles, the term is sometimes understood as<br>
-applying to the surface attraction. In such case it is defined as the<br>
-distribution, on a magnetized bar or mass, of magnetic lines of force as<br>
-they emerge from its surface.<br>
-<br>
-Synonym--Surface Magnetization.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Hughes' Theory of.</span><br>
-A theory accounting for magnetic phenomena by assuming that each<br>
-molecule is a magnet, and that in a polarized or magnetized body they<br>
-are all arranged with their poles in the same direction, while in an<br>
-unmagnetized body their poles, alternating in direction, neutralize each<br>
-other.<br>
-<br>
-Magnetization consists in a partial rotation of the molecules so as to<br>
-make them agree in position, thus, as a resultant developing north and<br>
-south poles at the ends of the bar.<br>
-<br>
-The theory is in a certain sense simpler than Ampere's theory, but is<br>
-not so generally adopted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Lamellar Distribution of.</span><br>
-The distribution of magnetism in thin and uniform or "simple magnetic<br>
-shells," q. v. A given distribution is termed lamellar if the substance<br>
-in which it exists can be divided into simple magnetic shells, which<br>
-either form closed surfaces, or have their edges in the surface of the<br>
-substance. In lamellar distribution the polar area is very large<br>
-compared with the distance between opposite poles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism of Gases.</span><br>
-Faraday experimented on this point by coloring gases with a little vapor<br>
-of iodine or other colored gas, and letting them flow between the two<br>
-poles of a powerful electromagnet. In this way he found some are<br>
-repelled, some attracted, and in the case of oxygen, it is attracted at<br>
-one temperature and repelled at another. At ordinary temperatures a<br>
-cubic yard of oxygen possesses the magnetism of 5.5 grains of iron and<br>
-when liquefied it is strongly attracted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism or Magnetization, Temporary.</span><br>
-When a mass of iron is magnetized by a current, when the current ceases<br>
-the portion of its magnetism which disappears is the temporary<br>
-magnetism; the portion retained is the residual or permanent magnetism.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Red.</span><br>
-A term arising from the two fluid theory of magnetism; the magnetism of<br>
-the north pole of a magnet. (See Magnetic Fluids.) The magnetism of the<br>
-south pole is termed blue magnetism. Both terms originated in the<br>
-painting of magnets. They are but little used.<br>
-<br>
-Synonym--North Magnetic Fluid.<br>
-<br>
-<br>
-358&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetic Remanence.</span><br>
-The residual magnetism left in a bar of steel or other paramagnetic<br>
-material after the application of a powerful magnet. It is distinguished<br>
-from coercive force, as the latter is the amount of negative magnetizing<br>
-or of demagnetizing force required to reduce the remanent magnetism to<br>
-zero.<br>
-<br>
-Synonym--Remanence--Residual Magnetism.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Solenoidal Distribution of.</span><br>
-The distribution of magnetism in such a way that the poles are very far<br>
-apart in proportion to their area. The magnetization of a long thin bar<br>
-of steel illustrates solenoidal distribution.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism Sub-permanent.</span><br>
-The magnetism of a paramagnetic substance which presents a considerable<br>
-degree of permanency, but which gradually disappears, leaving the<br>
-permanent magnetism present. It is noticeable in iron or steel ships<br>
-whose magnetism gradually reduced in quantity, eventually becomes fully<br>
-permanent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetism, Weber's Theory of.</span><br>
-The molecules of a magnetizable material by this theory are supposed to<br>
-be magnets with their poles lying in every direction, and hence<br>
-neutralizing each other. By magnetization these are supposed to be<br>
-turned with their similar poles in the same direction, and their axis<br>
-parallel, hence acting like a group of magnets. It is practically<br>
-identical with Hughes' theory.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetism, Terrestrial.</span><br>
-The magnetism of the earth. (See Magnetic Elements.)<br>
-<br>
-<br>
-<img style="width: 676px; height: 230px;" alt=""
- src="images/358F228.jpg"><br>
-Fig. 228. MAGNETIZATION BY DOUBLE TOUCH.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization by Double Touch.</span><br>
-The process of magnetizing a steel bar by simultaneously stroking it<br>
-with two poles of a horseshoe magnet or with two opposite poles of two<br>
-bar magnets. The poles must be close but not touching. A block of wood<br>
-may be placed between the ends if single magnets are used. The poles are<br>
-placed on the middle of the bar and carried back and forth to one end,<br>
-then to the other, and so on, ending at the middle of the bar in such<br>
-direction as to give each end the same number of strokes. The poles must<br>
-be close together or consequent poles will be produced. If bar magnets<br>
-are used they may be held inclined at an angle of 15&ordm; to 20&ordm;
-with the<br>
-horizontal bar to be magnetized. The ends of the latter may rest on<br>
-poles of two other magnets, each end on a pole of the same name as that<br>
-of the magnetizing magnet on its side. (See Magnetization, Hoffer's<br>
-Method.)<br>
-<br>
-<br>
-359&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization by Separate Touch.</span><br>
-A method of magnetization. Two magnets are used. Held in an inclined<br>
-position two opposite poles are touched to the bar near its centre, and<br>
-are drawn off to the two ends. They are returned through the air and the<br>
-process is repeated.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization by Single Touch.</span><br>
-A method of polarizing or magnetizing steel bars, by stroking them<br>
-always in one direction with one pole of a magnet, returning it through<br>
-the air. The stroking is best done on both sides. The stroking may begin<br>
-at one end and end at the other, or it may be commenced in the center of<br>
-the bar and be carried to one end with one pole, and the same done for<br>
-the other half with the other pole.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization by the Earth.</span><br>
-The earth imparts magnetism to iron masses. If a rod of steel is held<br>
-parallel to the inclination and in the magnetic meridian it exhibits<br>
-polarity, which by jarring or hammering, can be made to some extent<br>
-permanent. A piece of soft iron held vertically, or still better in the<br>
-line of the dip as above, and which is twisted when in that position,<br>
-becomes magnetized with some degree of permanence. Many other instances<br>
-are cited, such as fire-irons, lamp-posts, iron gates, lathe turnings,<br>
-all of which often exhibit polarity, having been magnetized by the<br>
-earth's field.<br>
-<br>
-[Transcriber's note: The earth's magnetic field is believed to originate<br>
-it electric currents in the moving molten core.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization, Coefficient of Induced.</span><br>
-The coefficient (q. v.) expressing the relation between the specific<br>
-intensity of magnetization of a particle and the magnetizing force. The<br>
-magnetizing force is measured by the lines of force it can produce in a<br>
-field of air. The coefficient of induced magnetization is the factor by<br>
-which the intensity of a magnetizing field must be multiplied to produce<br>
-the magnetization imparted by it to a particle of any substance. This<br>
-coefficient varies for different substances, and is also called magnetic<br>
-susceptibility. It is distinguished from permeability as referring only<br>
-to a particle isolated from influence of a mass of surrounding particles<br>
-of its own kind. It is definable as the intensity of the magnetization<br>
-assumed by an exceedingly long and exceedingly thin bar placed in a unit<br>
-field. If a mass of metal were placed in such a field all its particles<br>
-would become affected and within the mass no unit field could exist.<br>
-Hence magnetic susceptibility (another name for this coefficient) does<br>
-not apply to the case of large cores of electro-magnets and<br>
-dynamo-armatures, but is really a theoretical rather than a practical<br>
-figure.<br>
-<br>
-The sign of the coefficient of diamagnetic bodies is negative; of<br>
-paramagnetic bodies is positive.<br>
-<br>
-Synonym--Magnetic Susceptibility.&nbsp;&nbsp; \<br>
-<br>
-<br>
-360&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetization, Cycle of.</span><br>
-A cycle of positive or of positive and negative magnetization represents<br>
-the application of a magnetizing force beginning at a fixed value,<br>
-generally zero, rising to a maximum, or to a value of maximum distance<br>
-from the initial and then returning to the original basis. It is<br>
-virtually a full wave of magnetization and may extend on both sides of a<br>
-zero line giving positive and negative values.<br>
-<br>
-Cycles of magnetization apply especially to transformers and other<br>
-apparatus of that character used with the alternating current system.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetization, Hoffer's Method.</span><br>
-For horseshoe bars an armature is placed against the poles of the magnet<br>
-bar to be treated. The poles of a strong horseshoe magnet are stroked<br>
-over it from poles to bend and returned through the air, or vice versa.<br>
-In the first case the poles will be the same as those of the inducing<br>
-magnet; in the second case they will be opposite. A maximum effect is<br>
-produced in ten strokes. The stroking should be applied to both sides.<br>
-An electro-magnet may be used as inducer as shown, but an armature<br>
-should be used; in the cut it is omitted.<br>
-<br>
-<br>
-<img style="width: 635px; height: 293px;" alt=""
- src="images/360F229.jpg"><br>
-Fig. 229. MAGNETIZING A HORSESHOE MAGNET.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization, Intensity of.</span><br>
-The amount of magnetism induced in or present in a body. It is expressed<br>
-in Magnetic Lines of Force, q. v., per cross-sectional area.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetization, Isthmus Method of.</span><br>
-A method used by Ewing in a research on the magnetization of iron in<br>
-very strong fields. He used samples of iron turned down in the centre to<br>
-a narrow neck, and thus concentrated the lines of force greatly.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetization, Elias' Method.</span><br>
-The bar to be magnetized is surrounded by a magnetizing coil, q. v. A<br>
-strong current is passed through it, and the coil is moved back and<br>
-forth a few times.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization, Jacobi's Method.</span><br>
-For horseshoe bars. The bar is placed with its poles against those of a<br>
-horseshoe magnet. A bar of soft iron, long enough to reach from outside<br>
-to outside of the legs, is laid across near the junction and is drawn<br>
-along towards the bend of the new bar and away from it. This is repeated<br>
-a few times on both sides.<br>
-<br>
-<br>
-361&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization, Limit of.</span><br>
-As the induction of magnetizing force increases, magnetization of<br>
-paramagnetic metals tends towards a limit, the increase in magnetization<br>
-being continually less and less as the metal becomes more highly<br>
-magnetized. In diamagnetic substances no limit is discernible.<br>
-<br>
-Synonym--Maximum Magnetization.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetization, Specific.</span> <br>
-The magnetic moment per gram of a substance.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet-keeper.</span><br>
-A bar of iron connecting the two poles of a permanent magnet. Often the<br>
-same bar serves as armature and keeper.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Lamination of.</span><br>
-It is advantageous to make magnets of laminated construction, or of thin<br>
-plates of steel. The thin metal can be better tempered or hardened than<br>
-thick metal. A slight separation of the plates is advantageous from some<br>
-points of view. If in actual contact there is some danger that the<br>
-weaker members will have their polarity reversed by the stronger ones.<br>
-This is counteracted to some extent by separation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Long Coil.</span><br>
-A high resistance electro-magnet; one whose coil is of thin wire of<br>
-considerable length.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet, Natural.</span><br>
-The lodestone, q. v.; a variety of magnetite or magnetic oxide of iron,<br>
-exhibiting permanent magnetism, attracting iron, and possessing north<br>
-and south poles.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnet, Neutral Line of.</span><br>
-A line at right angles to the magnetic axis of a magnet, q.v., and<br>
-nearly or quite at the centre, so situated with reference to the poles<br>
-on either end that it marks the locus of no polarity. It has been called<br>
-the equator of the magnet. It is defined by the intersection of the<br>
-plane of no magnetism with the surface of the bar.<br>
-<br>
-Synonym--Magnetic Equator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Normal.</span><br>
-A bar or compound bar magnet, magnetized to such an extent that the<br>
-curves of the lines of force run into each other in the middle, is thus<br>
-termed by Jamin.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magneto.</span><br>
-Abbreviation for Magneto-electric Generator. (See Magneto-electric<br>
-Generator.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magneto Call Bell.</span><br>
-A call operated by current from a magneto-electric generator. It is very<br>
-generally used in telephone systems.<br>
-<br>
-<br>
-362&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magneto-electric. adj.</span><br>
-Relating to induced electric effects due to the cutting of true magnetic<br>
-lines of force by, or equivalent action of or upon a conductor. These<br>
-effects are identical with electro-magnetic effects and are only<br>
-distinguished from them by the field being due to a permanent magnet<br>
-instead of an electromagnet.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magneto-electric Brake.</span><br>
-A device for bringing to rest an oscillating galvanometer needle. It<br>
-consists essentially of a coil in circuit with a key and with the<br>
-galvanometer. On opening the circuit an inverse current is established<br>
-by induction, tending to bring the needle to rest.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magneto-electric Generator.</span><br>
-A current generator operating by maintaining a potential difference at<br>
-its terminals, by reactions in a field of force, which field is<br>
-established by a permanent magnet.<br>
-<br>
-The cut, Fig. 230, shows the general principle of construction of a<br>
-direct current generator. The armature is rotated between the poles of a<br>
-permanent magnet. Any of the regular types of dynamo armature can be<br>
-used. From its commutator the current is taken by brushes.<br>
-<br>
-<br>
-<img style="width: 685px; height: 399px;" alt=""
- src="images/362F230.jpg"><br>
-Fig. 230. MAGNETO-ELECTRIC GENERATOR.<br>
-<br>
-<br>
-<img style="width: 594px; height: 370px;" alt=""
- src="images/362F231.jpg"><br>
-Fig. 231. MAGNETO-ELECTRIC GENERATOR.<br>
-<br>
-<br>
-363&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The cut, Fig. 231, shows an alternating current machine. In it a pair of<br>
-bobbins, wound in series, and both either right-handed or left-handed,<br>
-are rotated between permanent magnet poles. The current may be taken off<br>
-by two brushes bearing on two collecting rings on the axis of the<br>
-bobbins, the ends of the wire being connected thereto. Or if a shocking<br>
-current is desired, one of the brushes or springs may strike a series of<br>
-pins forming virtually a broken or interrupted collecting ring. This<br>
-gives a current for medical purposes.<br>
-<br>
-Synonyms--Magneto-dynamo--Magneto-electric Machine.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetograph.</span><br>
-An apparatus for recording variations in magnetic elements. One type<br>
-includes a magnetic needle to which a concave mirror is attached. The<br>
-light ray from the mirror is reflected upon sensitized paper where its<br>
-movements are photographically reproduced. The movements of the spot are<br>
-due to the movements of the needle and act as the record of the same.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magneto-Inductor.</span><br>
-An instrument for use with a ballistic galvanometer to reproduce a<br>
-definite current impulse. Two magnets are fastened together in one<br>
-straight line, the north poles almost touching. This is mounted at the<br>
-end of a rod like a pendulum, the axis of the magnets transverse to the<br>
-rod. The magnets are carried by a frame and oscillate at the end of the<br>
-rod, back and forth within a fixed coil, which is one-half the length<br>
-of the double magnet. A bob is attached to the bottom of the frame by<br>
-which the whole can be swung. As the magnets are of fixed value, their<br>
-time of oscillation constant, and the coil fixed in size, the apparatus<br>
-provides a means of getting a definite instantaneous current of<br>
-identical value whenever needed.<br>
-<br>
-<br>
-<img style="width: 358px; height: 655px;" alt=""
- src="images/363F232.jpg"><br>
-Fig. 232. MAGNETO-INDUCTOR.<br>
-<br>
-<br>
-364&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetometer.</span><br>
-(a) A reflecting galvanometer, with heavy magnetic needle, dampened by a<br>
-copper frame. It was devised by Weber.<br>
-<br>
-(b) An apparatus for measuring the intensity of magnetic force. It may<br>
-consist of a magnet suspended by bifilar or by torsion suspension. A<br>
-reflecting mirror and scale as in the reflecting galvanometer may be<br>
-used to act as indicator of its motions. It is used in investigations of<br>
-the intensity of the earth's field.<br>
-<br>
-If the motions of the spot of light are received on a moving strip of<br>
-sensitized paper and are thereby reproduced photographically, the<br>
-instrument is self-recording. Such an apparatus is used in the Kew<br>
-Observatory, Eng., for recording the terrestrial magnetic elements.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetometry.</span><br>
-The determination of the magnetic moment of a magnet.<br>
-<br>
-It involves the determination by experiment of--( a) the product of the<br>
-magnetic moment, M, of the magnet by the horizontal component, H, of the<br>
-earth's magnetism; (b) the quotient of M divided by H. Knowing these two<br>
-quantities, M is given by the formula M = SquareRoot( )M * H) * (M/H) )<br>
-and if desired H is given by the formula H = SquareRoot( (M*H) / (M/H)).<br>
-<br>
-M*H is determined by the method of vibrations. A very long, thin magnet<br>
-suspended by a torsion filament is caused to oscillate, and its period<br>
-is determined. Calling such period T and the moment of inertia of the<br>
-magnet I, we have the formula T= 2* PI * SquareRoot( I / (H*M) )&nbsp;
-(a),<br>
-whence H*M is calculated, I of course being known or separately<br>
-determined.<br>
-<br>
-<br>
-<img style="width: 623px; height: 430px;" alt=""
- src="images/364F233.jpg"><br>
-Fig. 233 END-ON METHOD.<br>
-<br>
-<br>
-<img style="width: 414px; height: 619px;" alt=""
- src="images/364F234.jpg"><br>
-Fig. 234. BROADSIDE METHOD.<br>
-<br>
-<br>
-M/H is determined by the End-on deflection method, or the Broadside<br>
-deflection method. In both cases the deflection of a compass needle by<br>
-the magnet in question is the basis of the work.<br>
-<br>
-In the end-on method AB is the magnet under examination; DE the compass<br>
-needle; a the angle of deflection; d&nbsp; the distance between C and
-the<br>
-middle of AB, which should be considerable compared with the length of<br>
-DE; 2l, the length of AB. We then have the formula<br>
-&nbsp;&nbsp; tan a = (M/H) * (2d / (d^2 - l^2)^2),<br>
-which if 2l is small compared to d reduces to<br>
-&nbsp;&nbsp; tan a = M/Hd 3<br>
-<br>
-(b), which gives M/H, a and d being known.<br>
-<br>
-<br>
-365&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-In the broadside method the line d is the magnetic meridian, and the<br>
-diagram shows the relative positions. We then have the formula<br>
-&nbsp; tan a = (M/H) / (d2 + l2)^1.5;<br>
-which if 1 is relatively small reduces to<br>
-&nbsp; tan a = M/(H * d3 )(C.)<br>
-<br>
-<br>
-<img style="width: 644px; height: 226px;" alt="" src="images/365PIC.jpg"><br>
-[Transcriber's note: The image of the above paragraphs is included
-here.]<br>
-<br>
-a and c or a and b can be combined giving M and H in C.G.S. measurement.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetometer, Differential.</span><br>
-An apparatus, invented by Eickemeyer, for testing the magnetic qualities<br>
-of different samples of iron. It is very similar in construction and<br>
-principle to the magnetic bridge, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magneto-motive Force.</span><br>
-The force producing a magnetic field or forcing lines of force around a<br>
-magnetic circuit. It is usually applied only to electro-magnets and is<br>
-expressible in turns of the wire winding multiplied by amperes of<br>
-current, or in ampere-turns.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet Operation.</span><br>
-A term in surgery; the use of the electro-magnet or permanent magnet for<br>
-removing particles of iron from the eye.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnetoscope.</span><br>
-An apparatus for detecting the presence of magnetism, without measuring<br>
-its intensity. A simple magneto-scope consists of a magnetized bit of<br>
-watch-spring suspended in a vertical glass tube by a fine filament. A<br>
-bit of unmagnetized soft iron wire may be used in the same way. The<br>
-first has the advantage of indicating polarity; the latter merely shows<br>
-magnetic attraction. A cork may be used as base of the instrument.<br>
-<br>
-<br>
-<img style="width: 362px; height: 724px;" alt=""
- src="images/365F235.jpg"><br>
-Fig. 235. MAGNETOSCOPE.<br>
-<br>
-<br>
-366&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Permanent.</span><br>
-A bar of steel charged with residual magnetism. Steel possesses high<br>
-coercive force in virtue of which when once magnetized it retains part<br>
-of the magnetization.<br>
-<br>
-Permanent magnets are generally straight bars or U shaped; they are<br>
-termed bar magnets, magnetic needles, horseshoe magnets, machine magnets<br>
-and otherwise, according to their shape or uses.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet Pole.</span><br>
-The part of a magnet showing strongest polarity; the part which attracts<br>
-iron the most powerfully, and acts as the starting point for lines of<br>
-force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet Poles, Secondary.</span><br>
-Magnet poles are often not situated at the ends. Owing to inequality of<br>
-the material or other causes they may occupy intermediate positions on<br>
-the magnet. Such poles are called secondary poles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet Pole, Unit.</span><br>
-A unit magnet pole is one which exerts unit force on another unit pole<br>
-placed at unit distance from it. Unit force is the dyne; unit distance<br>
-is one centimeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Portative Power of.</span><br>
-The power of sustaining a weight by attraction of its armature possessed<br>
-by a magnet. In general terms the adherence of the armature of a magnet<br>
-to the pole varies with the square of the number of lines of force which<br>
-pass through the point of contact. Hence an increased adherence of the<br>
-armature to a horseshoe electro-magnet is sometimes obtained by<br>
-diminishing the area of contact of one pole which concentrates the lines<br>
-of force. Steel magnets were frequently made with rounded ends to<br>
-increase the portative power.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Simple.</span><br>
-A magnet made of one piece of metal, or at least magnetized as such; the<br>
-reverse of a compound magnet, which is magnetized piece by piece and<br>
-then fastened together.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Solenoidal.</span><br>
-A magnet which is so uniformly magnetized and is so long in proportion<br>
-to its other dimensions that it virtually establishes two magnetic<br>
-poles, one at either end. It is a long thin bar so magnetized that all<br>
-its molecules would, considered as magnets, be absolutely equal.<br>
-(Daniell.) It acts like a solenoid, except that it is longer in<br>
-proportion than the solenoid generally is constructed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Sucking.</span><br>
-A magnet coil with movable or loose axial bar of soft iron.<br>
-<br>
-The whole is usually mounted vertically. When a strong enough current is<br>
-passed the bar is drawn up into the coil as if by suction, whence the<br>
-name.<br>
-<br>
-<br>
-367&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnet, Unipolar.</span><br>
-No such thing as a unipolar magnet is possible. The name is given to<br>
-poised or suspended magnets, one of whose poles lies in the axis of<br>
-suspension. It is obvious that such a magnet will act, as far as its<br>
-directive tendency and rotatory movements are concerned, as if it had<br>
-only one pole. As shown in the cut, the pole s in both magnets lies in<br>
-the axis of suspension or directly under the filament by which they are<br>
-suspended, while the other pole n is the active pole in causing rotation<br>
-or directive tendency; c c are counterweights or counterpoises.<br>
-<br>
-<br>
-<img style="width: 422px; height: 373px;" alt=""
- src="images/367F236.jpg"><br>
-Fig. 236. UNIPOLAR MAGNETS.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Magnetophone.</span><br>
-An apparatus for producing a loud sound, involving the principles of the<br>
-telephone. A rapidly alternating or make and break current being<br>
-produced by any means and being transmitted through the telephone gives<br>
-a loud note of pitch dependent on the current producing it. Sometimes a<br>
-perforated metallic disc is rotated in a magnetic field, and produces<br>
-the requisite type of current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Magnus' Law.</span><br>
-A law of thermo-electricity. In a homogeneous circuit, however, the<br>
-temperature varies from point to point; there is no current.<br>
-<br>
-Whatever potential differences may be established by the variations in<br>
-temperature it is evident that they must counteract each other and<br>
-reduce to zero.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mains, Electric.</span><br>
-The larger conductors in a system of electric light or power<br>
-distribution.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Make. v.</span><br>
-To complete a circuit, as by closing a switch.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Make and Break Current.</span><br>
-A current which is continually broken or interrupted and started again.<br>
-It is applied only where the "makes" and "breaks" succeed each other<br>
-with great rapidity, as in the action of an induction coil or pole<br>
-changer, etc. It has had considerable importance in litigation affecting<br>
-the Bell telephone patents, the courts holding that the original Bell<br>
-patent (No. 174,465, of 1876,) covered the undulating current, for the<br>
-transmission of speech. Many efforts have been made by litigants to<br>
-prove that specific telephones have transmitted articulate speech by the<br>
-make and break current, but without success. If this could have been<br>
-proved the assumption is that the courts would have sustained the use of<br>
-such device as not infringing upon the claims of the Bell patent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Malapterurus.</span><br>
-A fish, sometimes called the thunder fish, an inhabitant of African<br>
-rivers, occurring in the Nile and Senegal. It possesses considerable<br>
-electric power, similar to that of the gymnotus and torpedo, although<br>
-inferior in amount.<br>
-<br>
-<br>
-368&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 563px; height: 233px;" alt=""
- src="images/368F237.jpg"><br>
-Fig. 237. MALAPTERURUS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Man-hole.</span><br>
-The cistern-like depression in the ground for giving access to the ends<br>
-of tubes in electric conduits. (See Conduit, Electric Subway.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Marked End or Pole.</span><br>
-The north pole or north seeking pole of a magnet, so called because it<br>
-is usually marked with a notch or scratch by the maker. The south pole<br>
-is called the unmarked end.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mass.</span><br>
-The quantity of matter in a body. The C. G. S. unit of mass is the<br>
-quantity of matter in a gram. While weight varies with latitude and<br>
-other circumstances, mass is invariable.<br>
-<br>
-The unit of mass is also defined as the quantity of matter which in a<br>
-balance will counterpoise a standard mass, the gram or pound. As the<br>
-gram is intended to be the mass of one cubic centimeter of water at<br>
-3.09&ordm; C. (39&ordm; F.), the C. G. S. unit of mass is really
-1.000013 gram.<br>
-<br>
-As a primary unit its dimensions are indicated by M.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Mass, Electric.</span><br>
-A term for quantity of electricity. The unit mass is such a quantity as<br>
-at unit distance will act with unit force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Matter, Electric.</span><br>
-The imaginary substance constituting electricity; a conception used<br>
-purely as a matter of convenience.<br>
-<br>
-[Transcriber's note: The electron was discovered five years after this<br>
-publication.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Matter, Radiant.</span><br>
-Matter in the ultra-gaseous or so-called fourth state. In the gaseous<br>
-state the molecules of a gas are in perpetual kinetic motion, colliding<br>
-actually or virtually with each other, rebounding from such approach,<br>
-and striking also the walls of the containing vessel. But except for<br>
-these deflections, which are of enormous frequency, the paths of the<br>
-molecules would be perfectly straight.<br>
-<br>
-In the radiant state matter exists in so high a vacuum that collisions<br>
-of the molecules rarely occur, and the molecules simply beat back and<br>
-forth in straight lines from side to side of the containing vessel.<br>
-<br>
-A layer of gas in this condition is termed a Crookes' layer, from Prof.<br>
-William Crookes, who discovered and investigated these phenomena.<br>
-<br>
-<br>
-369&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Luminous streams of the molecules are produced by electric high<br>
-potential discharges between electrodes. The course of the discharge is<br>
-normal, in general terms, to the surfaces of the electrodes, and reaches<br>
-from one to the other in a curve or straight line, as the case may be.<br>
-<br>
-These luminous streams are deflected by a magnetic field; if brought to<br>
-a focus can heat refractory material in that focus to a full white heat,<br>
-and can develop phosphorescence. The latter is termed electric<br>
-phosphorescence. A great variety of experiments have been devised to<br>
-illustrate the phenomena of radiant matter. The vacuum is generally<br>
-produced in a hermetically sealed glass vessel into which the electrodes<br>
-are sealed, and which contain the phosphorescent substances or other<br>
-essentials for the experiments. The vessels are termed Crookes' Tubes.<br>
-<br>
-[Transcriber's note: Crookes reported on "radiant matter" in 1879. It is<br>
-actually electrons, but he failed to distinguish them from ordinary<br>
-atoms. Thompson properly described electrons in 1897.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Matteueci's Experiment.</span><br>
-An experiment for showing the inductive effect of the discharge of a<br>
-Leyden jar. Two glass plates are supported on standards in a vertical<br>
-position. Flat coils of wire are wound or coiled and secured to one<br>
-surface of each plate. One plate has much finer and longer wire than the<br>
-other. Metal handles are connected to the ends of the coarser wire coil.<br>
-The plates are placed with their coils facing each other. A Leyden jar<br>
-is discharged through the coarser coil, while the handles are grasped by<br>
-a person. The shock of the discharge is felt by him.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Matting, Electric Floor.</span><br>
-Matting or floor covering underlaid with burglar alarm contacts, so<br>
-arranged as to be closed by anyone walking on the matting. The contacts<br>
-are connected to a burglar alarm system. The object is to provide an<br>
-alarm if a burglar enters a house, in case he should enter a door or<br>
-window without sounding the bell. The latter can be done by cutting out<br>
-the window or part of the door instead of opening it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Maxwell's Theory of Light.</span><br>
-A theory of light. It is due to J. Clerk Maxwell.<br>
-<br>
-It supposes the phenomena of electric induction to be due to the ether,<br>
-q. v. It supposes the condition of the ether when conveying light to be<br>
-the same as if exposed to the induction of rapidly alternating currents<br>
-or discharges (in this case synonymous). It therefore is an<br>
-electro-magnetic effect if the theory is correct.<br>
-<br>
-An electric stress such as one due to the induction of an<br>
-electrostatically charged body is not a wave-creating element or factor,<br>
-but is a simple stress. But let this stress be stopped and renewed and<br>
-at once it appears as a wave-forming agency.<br>
-<br>
-This stoppage and renewal represents evidently a discharge succeeded by<br>
-a charge, or if repeated is equivalent to an intermittent current or an<br>
-alternating one.<br>
-<br>
-<br>
-370&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Again the electrostatic stress kept constant may by being carried<br>
-through space carry with it a wave, just as a moving projectile carries<br>
-a wave of air in advance of itself.<br>
-<br>
-Admitting this much the following consequences follow:<br>
-<br>
-Since in non-conductors the displacement produces a restitution force,<br>
-which varies as the displacement which is requisite or is a criterion<br>
-for the propagation of waves, while in conductors no such force is<br>
-manifested and the electric energy appears as heat, it follows that<br>
-light vibrations are not possible in conductors, because<br>
-electro-magnetic waves do not exist in them when they are in circuit,<br>
-and conductors should be opaque, while the reverse is true for<br>
-non-conductors. (Daniell.)<br>
-<br>
-This is carried out often enough to make a striking evidence in favor of<br>
-Maxwell's theory.<br>
-<br>
-The velocity of propagation of an electro-magnetic disturbance in a<br>
-non-conductor should be equal to that of light. This constant is proved<br>
-by mathematical considerations, to be approximately the same as the<br>
-ratio of the electrostatic to the electromagnetic unit of intensity or<br>
-quantity. This ratio is 3E10 (30,000,000,000), which is almost exactly<br>
-the velocity of light.<br>
-<br>
-It also follows from what has been said that if an electrostatically<br>
-charged body were whirled around a galvanometer needle at the rate of<br>
-3E10 revolutions per second it should affect it like a circulating<br>
-current. This rate of rotation cannot be attained, but Rowland has made<br>
-manifest the effect of a rotating statically charged body upon a<br>
-magnetic needle.<br>
-<br>
-The above is the merest outline of Maxwell's theory. The full<br>
-development must be studied in his own and succeeding works.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mayer's Floating Magnets.</span><br>
-An experiment due to Prof. Mayer. A number of sewing needles are<br>
-magnetized and thrust into bits of cork, almost all the way through,<br>
-with their like poles projecting. They are floated in a basin of water<br>
-and take, under the effects of attraction and repulsion, when approached<br>
-by a magnet pole, regular geometric positions, marking out the positions<br>
-of angles of polygons.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Measurements.</span><br>
-The determination of the value of quantities; determination of the<br>
-factor by which the unitary value must be multiplied to produce the<br>
-quantity under examination. Such are the measurement of the voltage of a<br>
-galvanic battery, or of the ohms of resistance of a conductor.<br>
-Electricity has been termed the science of measurement.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meg or Mega.</span><br>
-A prefix, meaning one million times. A megohm is one million ohms; a<br>
-megerg is one million ergs; a megadyne is one million dynes.<br>
-<br>
-<br>
-371&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<img style="width: 664px; height: 574px;" alt=""
- src="images/371F238.jpg"><br>
-Fig. 238. MAYER'S FLOATING MAGNETS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mercury.</span><br>
-A metal; one of the elements; symbol, Hg; atomic weight, 200 ;<br>
-equivalent, 200 or 100; valency, 1 and 2.<br>
-It is a conductor of electricity.<br>
-The following data are 0&ordm; C. (32&ordm; F.)<br>
-&nbsp; R<small><span style="font-family: monospace;">elative
-Resistance,&nbsp;&nbsp; 62.73</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Specific
-Resistance,&nbsp;&nbsp; 94.32&nbsp;&nbsp; microhms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a wire,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long, weighing
-1 grain,&nbsp;&nbsp;&nbsp;&nbsp;
-18.51&nbsp;&nbsp; ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (b) 1 foot long, 1/1000
-inch thick,&nbsp;&nbsp;
-572.3&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (c) 1 meter long, weighing
-1 gram,&nbsp;&nbsp;&nbsp;&nbsp;
-12.91&nbsp; &nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (d) I meter long, 1
-millimeter thick&nbsp;&nbsp;&nbsp;
-1.211&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of&nbsp; a 1
-inch cube,&nbsp;&nbsp; 37.15&nbsp;&nbsp;
-microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Percentage increase of
-resistance per degree C. 1.8&deg; F.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp; at about
-20&deg; C. (68&deg; F.),&nbsp;&nbsp;
-.72&nbsp;&nbsp; per cent.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Electro-chemical
-equivalent (Hydrogen = .0105),&nbsp;&nbsp;
-2.10&nbsp;&nbsp; mgs.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.05&nbsp;&nbsp; "</span></small><br>
-<br>
-372&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mercury Cup.</span><br>
-A cup of iron, wood or some material that does not amalgamate or is<br>
-unattacked by mercury, which is filled with mercury and made an<br>
-electrode of a circuit. By dipping the other terminal of the circuit<br>
-into the mercury a very good contact is obtained. It is well to cover<br>
-the mercury with alcohol. The cup may be filled so that the mercury<br>
-rises in a meniscus or semi-globule above its edges.<br>
-<br>
-For some purposes this form is useful, as for contacts with the end of a<br>
-swinging wire or pendulum, because in such cases the contact can be made<br>
-without the contact point entering the cup. The point swings through the<br>
-projecting meniscus without touching the edges of the cup. A mercury cup<br>
-and contact constitute a mercury break.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meridian, Astronomical.</span><br>
-The great circle passing through the north and south poles of the<br>
-celestial sphere. It lies in a plane with the corresponding geographical<br>
-or terrestrial meridian.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meridian, Geographic.</span><br>
-The true north and south meridian; the approximate great circle formed<br>
-by the intersection of a plane passing through north and south poles of<br>
-the earth with the earth's surface.<br>
-<br>
-<br>
-373&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 494px; height: 671px;" alt=""
- src="images/372F239.jpg"><br>
-Fig. 239. SCHALLENBERG'S ALTERNATING CURRENT METER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter, Alternating Current.</span><br>
-A meter for measuring alternating current, as supplied to consumers,<br>
-from an alternating current system. Like most commercial meters its only<br>
-function is the measurement of quantity; the potential difference is<br>
-maintained at a constant figure by the generating plant.<br>
-<br>
-The cut shows the Schallenberg meter. It is simply an alternating<br>
-current motor (see Motor, Alternating Current), with air vanes mounted<br>
-on its spindle. A main coil passes all the current. Within this is a<br>
-second coil complete in itself, and not touching or connecting with the<br>
-other. The latter is built up of copper rings. Within the two coils, and<br>
-concentric with both is a disc of copper carried by a vertical spindle.<br>
-The same spindle carries air vanes, and is free to rotate. As it does so<br>
-it moves the indicating machinery.<br>
-<br>
-The current in the outer coil induces one in the inner coil. Owing to<br>
-lag, the current in the inner one differs in phase from that in the<br>
-outer one, and a rotatory field is produced. The copper disc acquires<br>
-induced polarity, and rotates with speed which normally would be in<br>
-proportion to the square of the current. But the object of the meter is<br>
-to register the current only. The air vanes effect this. The resistance<br>
-of the air to their motion causes the rate of rotation to vary directly<br>
-as the speed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter Bridge.</span><br>
-A form of Wheatstone's bridge in which one lateral pair of arms is<br>
-represented by a straight wire. The other pair comprise a known<br>
-resistance, and the resistance to be determined. The galvanometer is<br>
-connected on one side between the known and unknown resistance. On the<br>
-other side its connection is moved back and forth along the straight<br>
-wire until the balance is secured and the galvanometer reads zero.<br>
-<br>
-The relative lengths of wire intercepted between the two ends thereof<br>
-and the movable galvanometer connection are proportional to the<br>
-resistance of these parts and give the necessary data with the one known<br>
-resistance for determining the unknown resistance.<br>
-<br>
-<br>
-374&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-In the original meter bridge the wire was one meter long, whence its<br>
-name, and was stretched straight. In more recent examples the wire<br>
-varies in length and in one form is bent into a circle or spiral, so as<br>
-to make the instrument more compact.<br>
-<br>
-The contact is not a sliding one, but is adjusted by trial. The contact<br>
-piece is slid along, but not touching the wire, and from time to time is<br>
-pressed down against the wire. This prevents wear of the wire. The wire<br>
-may be made of platinum or of platinum-iridium alloy. The latter is<br>
-very hard and not easily worn out.<br>
-<br>
-Sometimes, as shown in the cut, three parallel wires are stretched along<br>
-the baseboard of the instrument, and arranged so that a single wire, two<br>
-wires or three wires in series can be used for the proportional sides of<br>
-the bridge, thus making it a two-meter or three-meter bridge as desired.<br>
-On the other hand some are made of restricted length, as a half or<br>
-quarter meter only.<br>
-<br>
-<br>
-<img style="width: 612px; height: 395px;" alt=""
- src="images/374F240.jpg"><br>
-Fig. 240. METER BRIDGE.<br>
-<br>
-<br>
-In the cut J K is the wire, traversed by the contact key. By moving the<br>
-contact C back and forth in the slot it can be brought over any of the<br>
-three divisions of the wire. H is the handle for depressing the key. S<br>
-is a flat spring, carrying the contact piece and holding it up from the<br>
-wires, except when pressed downwards. As shown in the cut, it is in use<br>
-for calibrating a voltmeter V, by Poggendorff's method, G being the<br>
-galvanometer and r1 and r2 being resistances.<br>
-<br>
-Synonyms--Slide Bridge--Slide Balance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter Candle.</span> <br>
-A unit of illuminating power; the light given by one standard candle at
-<br>
-a distance of one meter. The ordinary units of illuminating power are <br>
-altogether relative; this one is definite.<br>
-<br>
-<br>
-375&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter, Chemical Electric.</span><br>
-A current meter in which the current is determined by the amount of<br>
-chemical decomposition which it can effect. In the Edison meter the<br>
-solution is one of zinc sulphate. Two electrodes of zinc are immersed in<br>
-it, and a fractional part of the current is passed through it. The gain<br>
-in weight of one electrode and the loss in the other are proportional to<br>
-the current. Both electrodes are weighed periodically, one acting as<br>
-check upon the other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter, Current.</span><br>
-An instrument for measuring the quantity of electricity in current form<br>
-supplied to consumers. It may be of various types. The general principle<br>
-involved is that in commercial installations for incandescent light and<br>
-power supply a fixed potential is usually maintained, the multiple arc<br>
-system being employed. Hence all that is requisite is to measure the<br>
-coulombs or the ampere-hours to know what quantity of energy has been<br>
-supplied.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter, Electro-magnetic.</span><br>
-A current meter in which the current is measured by its electro-magnetic<br>
-effects.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter-millimeter.</span><br>
-A unit of resistance. (See Resistance, Meter-millimeter.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter, Thermal Electric.</span><br>
-A current meter in which the current is measured by the heat it imparts<br>
-to a conductor. In one meter a very light helix of mica is poised<br>
-horizontally over a conductor, and the whole is enclosed in a case. As<br>
-the wire is heated it causes an ascending current of air which rotates<br>
-the vane, and the latter moves delicate clockwork which moves indicating<br>
-hands. The hotter the wire the more rapidly the air ascends, and<br>
-consequently the speed of the vane is proportional to the current,<br>
-because the heat of the conductor is proportional thereto.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter, Time Electric.</span><br>
-An electric meter which measures the length of time during which current<br>
-is used. It assumes a constant current and potential. It is virtually a<br>
-clock, which is turned on when the current passes, and is turned off<br>
-with the current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Meter, Watt.</span><br>
-A combined current and potential meter. It is constructed on the general<br>
-lines of a Siemens' Electro Dynamometer. If in it one coil is made of<br>
-coarse wire and is placed in series with the current conductor, and if<br>
-the other is wound with fine wire and is connected as a shunt from point<br>
-to point whose potential difference is to be determined, the instrument<br>
-becomes a watt meter.<br>
-<br>
-Synonym--Energy Meter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Methven Standard or Screen.</span><br>
-A standard of illuminating power. It is the light emitted by a<br>
-three-inch Argand gas flame through a rectangular aperture in a silver<br>
-plate carried by a screen. The aperture is of such size and so far<br>
-distant from the flame as to permit the passage of exactly two candles<br>
-illuminating power.<br>
-<br>
-<br>
-<img style="width: 346px; height: 844px;" alt=""
- src="images/376F241.jpg"><br>
-</big></big><big><big>Fig. 241. METHVEN SCREEN<br>
-<br>
-<br>
-</big></big><big><big>376&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mho.</span><br>
-A unit of conductance, not in very general use. It is the reciprocal of<br>
-the ohm. Thus a resistance of ten ohms is a conductance of one-tenth<br>
-mho.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mica.</span><br>
-A natural mineral, a silicate of several oxides; muscovite. It is used<br>
-as an insulator and dielectric. Its resistance per centimeter cube after<br>
-several minutes electrification at 20&ordm; C. (68&ordm; F.) is 8.4E13
-ohms<br>
-(Ayrton). Its specific inductive capacity is 5, air being taken at 1.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mica, Moulded.</span><br>
-An insulating material, whose body is made of mica pulverized and<br>
-cemented together with heat and pressure and some suitable cement.<br>
-Shellac is often used as the cement.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Micro.</span><br>
-A prefix meaning "one-millionth of;" a micro-farad is one-millionth of a<br>
-farad.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Micrometer.</span><br>
-An instrument for measuring small distances or small differences. It<br>
-generally is based upon an accurate screw which may have a worm wheel<br>
-for head, actuated by a worm or helix with graduated head, so that<br>
-exceedingly small advances of the screw may be produced. The pitch of<br>
-the screw being known its actual advance is known.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Micrometer, Arc.</span><br>
-A micrometer for measuring the distance between voltaic arc electrodes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Micron.</span><br>
-A unit of length. It is one-millionth of a meter or four<br>
-one-hundred-thousandths of an inch.<br>
-<br>
-<br>
-377&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Microphone.</span><br>
-An apparatus which includes a contact of variable resistance; such<br>
-resistance can be varied in amount by slight vibrations, such as those<br>
-produced by sound waves. The apparatus in use forms part of a circuit<br>
-including a telephone and current generator. As the contact is varied<br>
-the resistance of the circuit and consequently the current intensity<br>
-changes and sounds are emitted by the telephone corresponding to such<br>
-changes. If the microphone is spoken to, the telephone will emit<br>
-corresponding sounds, reproducing the voice.<br>
-<br>
-It has been found in practice that carbon gives the best microphone<br>
-contact. One of the simplest and earliest forms is shown in the cut. A<br>
-short rod or pencil of carbon, A, such as used in batteries, is<br>
-sharpened at the ends and rests loosely in a vertical position between<br>
-two blocks of carbon, C C, in each of which a hole is drilled to receive<br>
-one of the points. The blocks are carried on a standard and base D. The<br>
-blocks are connected with two terminals x, y, of a circuit, including a<br>
-telephone and battery. There are two contacts to be disturbed.<br>
-<br>
-If delicately adjusted a fly walking over the base-board will disturb<br>
-the contacts enough to produce sounds in the telephone. These sounds are<br>
-possibly not due only to sound waves, but in part to absolute mechanical<br>
-disturbances.<br>
-<br>
-The various forms of telephone transmitter are generally microphones.<br>
-<br>
-<br>
-<img style="width: 805px; height: 675px;" alt=""
- src="images/377F242.jpg"><br>
-Fig. 242. MICROPHONE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Microphone Relay.</span><br>
-A combined microphone and telephone. A microphone is placed close to the<br>
-diaphragm of a telephone. The slight sound waves emitted by the<br>
-telephone affect the microphone and are repeated in its circuit. The<br>
-microphone circuit includes a local battery and telephone.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Microtasimeter.</span><br>
-An apparatus for indicating minute changes in temperature or atmospheric<br>
-moisture.<br>
-<br>
-<br>
-378&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-A button of compressed lampblack is placed in series with a battery and<br>
-galvanometer. A strip of some substance, affected in its length either<br>
-by heat or by moisture, is held pressing against the button. A slight<br>
-change in length of the strip varies the resistance of the button and<br>
-hence affects the galvanometer. In this way exceedingly slight changes<br>
-in heat or moisture may be indicated.<br>
-<br>
-For heat indications vulcanite may be used. The heat of the hand held<br>
-near it is enough to affect the galvanometer. For moisture a slip of<br>
-gelatine is used. The moisture of a damp slip of paper two or three<br>
-inches distant is sufficient to affect the galvanometer.<br>
-<br>
-In the cut, Fig. 2, shows the general distribution of the apparatus in<br>
-circuit with a battery and galvanometer. C is the base of the apparatus,<br>
-from which the standard, B, with adjusting screw, H, rises. The strip of<br>
-vulcanite is held between I and G. Within D is the carbon button (F in<br>
-Fig. 3) pressed between G and E; A is a standard to carry the parts last<br>
-described. In Fig. I it is shown as part of a Wheatstone bridge, a, b<br>
-and c being resistance coils; l the tasimeter, and g the galvanometer.<br>
-If a balance is secured, any variation in the resistance of the<br>
-tasimeter will disturb the galvanometer.<br>
-<br>
-Synonym--Tasimeter.<br>
-<br>
-<br>
-<img style="width: 482px; height: 693px;" alt=""
- src="images/378F243.jpg"><br>
-Fig. 243. MICROTASIMETER.<br>
-<br>
-<br>
-379&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mil.</span><br>
-A unit of length; one-thousandth part of a lineal inch.<br>
-<br>
-It is equal to<br>
-.025399 millimeter;<br>
-.000083 foot;<br>
-.001000 inch.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mil, Circular.</span><br>
-A unit of area; employed in designating the cross-sectional area of<br>
-wires and other circular conductors.<br>
-<br>
-It is equal to<br>
-&nbsp; .78540&nbsp; square mil;<br>
-&nbsp; .000507 square millimeter;<br>
-&nbsp; 7.8E-7 (.00000078) square inch.<br>
-<br>
-If the diameter of a wire is given in mils, the square of its diameter<br>
-gives its cross-sectional area in circular mils.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mil-foot.</span><br>
-A unit of resistance. (See Resistance, Mil-foot, Unit of).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mil, Square.</span><br>
-A unit of area; one-millionth of a square inch.<br>
-<br>
-It is equal to<br>
-&nbsp;&nbsp; .000645 square millimeter;<br>
-&nbsp; 1.2733 circular mil;<br>
-&nbsp;&nbsp; .000001 square inch.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Milli.</span><br>
-A prefix; one-thousandth. Thus a milligram is one-thousandth of a gram;<br>
-a millimeter is one thousandth of a meter.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Milligram.</span><br>
-A unit of weight ; one-thousandth of a gram, q. v.<br>
-<br>
-It is equal to<br>
-&nbsp; .015432 grain;<br>
-&nbsp; .000032 troy ounce.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Millimeter.</span><br>
-A unit of length; one-thousandth of a meter.<br>
-<br>
-It is equal to<br>
-&nbsp; 39.37079 mils;<br>
-&nbsp;&nbsp;&nbsp; .03937 inch;<br>
-&nbsp;&nbsp;&nbsp; .00109 yard.<br>
-<br>
-<br>
-380&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Milli-oerstedt.</span><br>
-A proposed but not adopted unit of current; one-thousandth of an<br>
-oerstedt. It is equal to one-thousandth of an ampere.<br>
-<br>
-[Transcriber's note: oersted: 1. CGS unit of magnetic intensity, equal<br>
-to the magnetic pole of unit strength when undergoing a force of one<br>
-dyne in a vacuum. 2. Formerly, the unit of magnetic reluctance equal to<br>
-the reluctance of a centimeter cube of vacuum between parallel<br>
-surfaces.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">mm.</span><br>
-Contraction for millimeters.<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Molar. </span><br>
-Referring to phenomena of mass as gravitation. Mechanics<br>
-generally treats of molar laws and phenomena.<br>
-<br>
-[Transcriber's note: Molar, or mole, often refers to a quantity of a<br>
-substance containing an Avagadro number (6.02E23) of molecules--a weight<br>
-equal to the atomic weight of the molecule. For example, a mole of<br>
-hydrogen (H2) is 2.015 grams; sodium chloride (NaCl) is 58.443 grams.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Molar Attraction.</span><br>
-The attraction of mass for mass; gravitation. Synonyms--Mass<br>
-Attraction--Gravitation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Molecular Affinity.</span><br>
-The attraction of molecules for each other as seen in the formation of<br>
-double salts, the combining of water of crystallization with a salt, and<br>
-in other cases; a phase of affinity belonging to chemistry, although<br>
-outside of true atomic attraction.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Molecular Attraction.</span><br>
-The attraction of molecules; physical affinity. Cohesion, the attraction<br>
-of similar molecules for each other, and adhesion, that of dissimilar<br>
-molecules, are examples. This should be distinguished from molecular<br>
-affinity, a phase of chemical force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Molecular Bombardment.</span><br>
-When a gas contained in a vessel is brought to a sufficient state of<br>
-rarefaction the molecules cease to be subject to the laws of diffusion,<br>
-but move back and forth in straight lines from side to side of the<br>
-vessel. Their courses can be affected by electric discharge, which can<br>
-cause them to all impinge upon one of the electrodes, the positive one,<br>
-producing luminous effects. The path, if referred to the negative<br>
-electrode, tends to be normal to its surface, so that the resultant path<br>
-may be curved, as the stream of molecules go to the positive electrode.<br>
-The fanciful name of molecular bombardment is given to the phenomenon,<br>
-the luminous effect being attributed to the impinging of the molecules<br>
-against the positive electrode as they are projected from the positive.<br>
-The course of the molecules is comparable to the stream of carbon<br>
-particles from the positive to the negative electrode in an arc lamp.<br>
-(See Matter, Radiant.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Molecular Chain.</span><br>
-The theoretical rows of molecules supposed to extend from anode to<br>
-cathode in an electrolytic cell (see Cell, Electric--Groth&uuml;ss'<br>
-Hypothesis) are called molecular chains.<br>
-<br>
-<br>
-381&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Molecular Rigidity.</span><br>
-The tendency of the molecules of a mass to retain their position in a<br>
-mass in resistance to polarizing or depolarizing force, the first being<br>
-the effect of a magnetic field. It is the theoretical cause of coercive<br>
-force, q. v., and of residual magnetism. (See Magnetism, Residual.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Molecule</span>.<br>
-The smallest particle of matter that can exist alone. It is made up of<br>
-atoms, but an atom can never exist alone, but only, with one or two<br>
-possible exceptions, combined with one or more other atoms as a<br>
-molecule. The molecules under present conditions are not in constant<br>
-contact with each other, but are perpetually vibrating through paths, in<br>
-solids probably in defined paths, in liquids and gases in perpetually<br>
-new paths. The molecules collide with each other and rebound. This<br>
-motion is the kinetic motion termed heat. At the absolute zero--minus<br>
-273.72&deg; C. (-460.7&deg; F.) the molecules would be in contact and
-quiescent.<br>
-In the gaseous state the molecules of most substances occupy the same<br>
-volume; those of a few elements occupy one-half and of others twice the<br>
-normal volume. The mean free path of the molecule of hydrogen is about<br>
-1/20,000 mm. (1/508,000 inch) (Maxwell) or twice this length (Crookes),<br>
-the collisions in hydrogen are about 17,750 millions per second; the<br>
-diameter is about 8/10,000,000 mm. (8/254,000,000 inch) ; A particle of<br>
-matter 1/4,000 mm. (1/102,000 inch) contains, it is supposed, about<br>
-40,000 molecules. The results of different authorities vary so widely as<br>
-to deprive the subject of much of its interest. A Sprengel pump, such as<br>
-used for exhausting Geissler tubes, or incandescent lamp bulbs, may<br>
-leave only one hundred-millionth (1/100,000,000,) of an atmosphere<br>
-present, giving the molecules a capability of an average free path of<br>
-vibration 33 feet long.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Moment.</span><br>
-When a force is applied so as to tend to produce rotation around a<br>
-point, the product of the force by the shortest distance from the point<br>
-of rotation to the extension of the line of the force. Such distance is<br>
-the perpendicular to the extension of the line through the point of<br>
-rotation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mordey Effect.</span><br>
-A phenomenon observed in dynamo armatures. At full loads the hysteresis<br>
-decreases. The effect is thus expressed by S. P. Thompson. "When an<br>
-armature core is rotated in a strong magnetic field, the magnetization<br>
-of the iron is being continually carried through a cycle, but in a<br>
-manner quite different from that in which it is carried when the<br>
-magnetizing force is periodically reversed, as in the core of a<br>
-transformer. Mordey has found the losses by hysteresis to be somewhat<br>
-smaller in the former case than in the latter."<br>
-<br>
-<br>
-<span style="font-weight: bold;">Morse Receiver.</span><br>
-The receiving instrument formerly universally used in the Morse system.<br>
-It is now but little employed, the sounder having displaced it. Several<br>
-types were invented.<br>
-<br>
-It consists of machinery which carries a reel of paper ribbon arranged<br>
-to be fed over a roller by clockwork. A pencil, inking roller, or<br>
-embossing stylus (for the latter the roller must have a groove) is<br>
-carried by an arm with restricted range of vibration just over the paper<br>
-and roller. The armature of an electro-magnet is attached to the arm.<br>
-When the magnet is excited the armature is attracted and the marking<br>
-device is pressed on the paper. If the clockwork is in operation the<br>
-marker will make a line as long as the armature is attracted. When<br>
-released no mark will be produced. In this way the dots and dashes of<br>
-the Morse code are made on a ribbon of paper.<br>
-<br>
-As an inking arrangement a small roller is carried by the end of the<br>
-vibrating arm. The embosser, or dry point stylus, was very extensively<br>
-used. The clockwork was generally driven by descending weights.<br>
-<br>
-Synonym--Morse Recorder.<br>
-<br>
-<br>
-382&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Mortar, Electric.</span><br>
-An electric toy which may have various modifications. In the cut a<br>
-wooden mortar with recess to receive a ball is shown. Two wires enter<br>
-the base but do not touch. On placing the ball in position and passing a<br>
-spark from a Leyden jar across the interval between the wires, the heat<br>
-and disturbance are enough to project the ball. Gunpowder may be used,<br>
-the discharge being passed through a wet string to prolong the spark.<br>
-<br>
-<br>
-<img style="width: 362px; height: 423px;" alt=""
- src="images/382F244.jpg"><br>
-Fig. 244. ELECTRIC MORTAR.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Motor, Compound or Compound Wound.</span><br>
-A motor which has two windings on the field magnets, one in parallel<br>
-with that on the armature, the other in series therewith, exactly as in<br>
-a compound dynamo. (See Dynamo, Compound.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor, Differential.</span><br>
-A differentially wound motor; with a compound wound field, whose series<br>
-coil and shunt coil are wound in opposition to each other. It is<br>
-virtually a compound wound dynamo. (See Dynamo, Compound Wound.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor, Electric.</span><br>
-A machine or apparatus for converting electric energy into mechanical<br>
-kinetic energy. The electric energy is generally of the dynamic or<br>
-current type, that is to say, of comparatively low potential and<br>
-continuous or virtually continuous flow. Some electrostatic motors have,<br>
-however, been made, and an influence machine can often be operated as a<br>
-static motor.<br>
-<br>
-Electric motors of the current type may be divided into two<br>
-classes--direct current and alternating current motors.<br>
-<br>
-Direct current motors are generally based on the same lines of<br>
-construction as dynamos. One of the great discoveries in modern<br>
-electricity was that if a current is passed through a dynamo, the<br>
-armature will rotate. This fact constitutes the principle of the<br>
-reversibility of the dynamo.<br>
-<br>
-<br>
-383&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Motors built on the dynamo model may be series wound, shunt wound, or<br>
-compound wound, or of the magneto type, in the latter case having a<br>
-fixed field irrespective of any current sent through them. The field may<br>
-be produced by an electro-magnet separately excited and unaffected by<br>
-the current sent through the motor.<br>
-<br>
-A current passed through a magneto or motor with separately excited<br>
-field will turn it in the direction opposite to that required to produce<br>
-the same current from it were it worked as a generator.<br>
-<br>
-A current passed through a series wound motor acts exactly as above.<br>
-<br>
-Both these facts follow from Lenz's law, q. v.<br>
-<br>
-A current passed through a shunt wound motor acts oppositely to the<br>
-above. The direction of rotation is the same as that required to produce<br>
-a current of the same direction. This is because the field being in<br>
-parallel with the armature the motor current goes through the magnet<br>
-coils in the direction the reverse of that of the current produced in<br>
-the armature when it is used as a dynamo. Hence this also carries out<br>
-Lenz's law.<br>
-<br>
-The compound wound motor acts one way or the other according as its<br>
-shunt or series winding preponderates. The two may exactly balance each<br>
-other, when there will be no motion at all. The series connections of a<br>
-compound wound dynamo should therefore be reversed, making both series<br>
-and shunt work in unison, if the dynamo is to be used as a motor.<br>
-<br>
-The general principles of the electric motor of the dynamo, or<br>
-continuous rotation type, can only be outlined here. The current passing<br>
-through the field magnets polarizes them and creates a field. Entering<br>
-the armature by the brushes and commutators it polarizes its core, but<br>
-in such a way that the north pole is away from the south pole of the<br>
-field magnet, and the same for the south pole. Hence the armature<br>
-rotates. As it does this the brushes connect with other commutator<br>
-sections, and the poles of the armature are shifted back. This action<br>
-continues indefinitely.<br>
-<br>
-Another class of motors is of the reciprocating type. These are now very<br>
-little used. (See Motor, Reciprocating.)<br>
-<br>
-One valuable feature of continuous rotation electric motors is the fact<br>
-that they absorb energy, to a great extent proportional in amount to the<br>
-work they have to do. The rotation of the armature in the field of the<br>
-motor involves the cutting of lines of force by its coils. This<br>
-generates an electro-motive force contrary in direction to that<br>
-producing the actuating current. The more rapid the rotation the greater<br>
-is this counter-electro-motive force. The motor armature naturally<br>
-revolves faster with diminished resistance to the motion of the<br>
-armature. This increases the counter-electromotive force, so that less<br>
-energy is absorbed. When the motor is called on to do work, the armature<br>
-rotates more slowly, and the counter-electro-motive force diminishes, so<br>
-that the machine absorbs more energy. (See Jacobi's Law.)<br>
-<br>
-<br>
-384&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor Electro-motive Force.</span><br>
-The counter-electro-motive force of a motor. (F. J. Sprague.)<br>
-<br>
-A motor rotates in virtue of the pull of the field magnet upon the poles<br>
-of the core of its armature. In responding to this pull the windings of<br>
-the armature cuts lines of force and hence generates a<br>
-counter-electro-motive force, for which the above term was suggested.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor-Generator.</span><br>
-A combined motor and generator used to lower the potential difference in<br>
-a portion of a circuit, e. g., that part within a building.<br>
-<br>
-A motor-generator is a dynamo whose armature carries two commutators,<br>
-with two separate windings, one of fine wire of many turns, the other of<br>
-coarse wire of few turns. If the potential of the system is to be<br>
-lowered, the main current is passed through the fine winding. This<br>
-causes the armature to turn motor-fashion, and a potential difference is<br>
-generated by the rotation of the large coils in the field. This<br>
-potential difference is comparatively low and by properly proportioning<br>
-the windings may be lowered to as great a degree as required.<br>
-<br>
-The same apparatus may be inverted so as to raise potential difference.<br>
-It acts for continuous current systems as the induction coil transformer<br>
-does for alternating current systems.<br>
-<br>
-Synonym--Continuous Current Transformer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor, Multiphase.</span><br>
-A motor driven by multiphase currents. It is arranged in general terms<br>
-for distribution of the multi phase currents in coils symmetrically<br>
-arranged around the circle of the field. These coils are wound on cores<br>
-of soft iron. A rotating field is thus produced, and a permanent magnet<br>
-or a polarized armature pivoted in such a field will rotate with the<br>
-field, its poles following the poles of the rotatory field.<br>
-<br>
-The cut, Fig. 245, illustrates the principles of action of a four phase<br>
-current motor, connected to a four phase current dynamo or generator.<br>
-The generator is shown on the left hand of the cut and the motor on the<br>
-right hand. In the generator the armature N S is supposed to be turned<br>
-by power in the direction shown by the arrow. Each one of the pair of<br>
-coils is wound in the reverse sense of the one opposite to it, and the<br>
-two are connected in series with each other, and with a corresponding<br>
-pair in the motor. The connection can be readily traced by the letters A<br>
-A', a a' for one set of coils and B B' b b' for the other set.<br>
-<br>
-<br>
-385&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-For each rotation of the armature two currents, each in opposite<br>
-direction, are produced in A A', and the same is the case for B B'.<br>
-These currents which have an absolutely constant relation of phase, and<br>
-which it will be seen alternate four times for each rotation of the<br>
-armature, regulate the polarity of the field of the motor. The resultant<br>
-of their action is to keep the poles of the field magnet of the motor<br>
-constantly traveling around its circle. Hence the armature N S of the<br>
-motor, seen on the right hand of the cut, tends to travel around also<br>
-its north and south poles, following the south and north poles of the<br>
-rotatory field respectively.<br>
-<br>
-<br>
-<img style="width: 635px; height: 398px;" alt=""
- src="images/385F245.jpg"><br>
-Fig. 245. FOUR-PHASE CURRENT GENERATOR AND MOTOR.<br>
-<br>
-<br>
-It is not essential that the armature should be a magnet or polarized.<br>
-Any mass of soft iron will by induction be polarized and will be<br>
-rotated, although not necessarily synchronously, with the rotatory<br>
-field. Any mass of copper, such as a disc or cylinder, will have<br>
-Foucault currents induced in it and will also rotate. The only<br>
-components of such currents which are useful in driving the motor are<br>
-those which are at right angles to the lines of force and to the<br>
-direction of motion. A very good type of armature based on these<br>
-considerations is a core of soft iron wound with insulated copper wire<br>
-in one or more closed coils; and so wound as to develop the currents of<br>
-proper direction.<br>
-<br>
-Such an armature is used in the Tesla alternating current motor. An<br>
-efficiency of 85 per cent. has been attained with some of the Tesla<br>
-motors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor, Prime.</span><br>
-A machine used for producing mechanical motion against resistance. It<br>
-may operate by converting heat or any other form of kinetic or potential<br>
-energy into mechanical energy of the moving type. A steam-engine and a<br>
-water-wheel are examples of prime motors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor, Reciprocating.</span><br>
-The early type of motor depending upon reciprocating motion, such as the<br>
-motion of a coil in a solenoid. These were based upon the lines of a<br>
-steam engine, and have been abandoned except for special purposes where<br>
-reciprocating motion is especially required, as in the case of rock<br>
-drills.<br>
-<br>
-<br>
-386&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 573px; height: 517px;" alt=""
- src="images/386F246.jpg"><br>
-Fig. 246. RICORDON'S RECIPROCATING MOTOR.<br>
-<br>
-<br>
-In the cut, B is an electro-magnet; A is an armature; E a pole piece.<br>
-The current enters by the springs, b b, and by commutation is supplied<br>
-and cut off alternately, thus maintaining a reciprocating movement of<br>
-the armature and rotation of the fly-wheel.<br>
-<br>
-Synonym--Pulsating Motor.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Motor, Series.</span><br>
-A motor whose winding on the armature is in series with the winding on<br>
-the field. It is similar to a series dynamo. (See Dynamo, Series.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Motor, Shunt.</span><br>
-A motor whose winding on the armature is in parallel with the winding on<br>
-the field magnets. It is similar to a shunt wound dynamo. (See Dynamo,<br>
-Shunt.)<br>
-<br>
-<br>
-<img style="width: 592px; height: 210px;" alt=""
- src="images/386F247.jpg"><br>
-Fig. 247. MULTIPLE ARC CONNECTION.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Multiple.</span><br>
-A term expressing connection of electric apparatus such as battery<br>
-couples, or lamps in parallel with each other. In the ordinary<br>
-incandescent lamp circuits the lamps are connected in multiple.<br>
-<br>
-Synonym--Multiple Arc.<br>
-<br>
-<br>
-387&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Multiple Arc Box.</span><br>
-A resistance box arranged so that the coils may be plugged in multiple<br>
-instead of in series. Such can be used as a rheostat, as the resistance<br>
-can be very gradually changed by putting the coils one by one into<br>
-parallel with each other. Thus by adding in parallel with a 10 ohm coil<br>
-a 10,000 ohm coil the resistance is decreased to 9.999001 ohms, and thus<br>
-the resistance can be very slowly changed without sudden stops or abrupt<br>
-changes.<br>
-<br>
-[Transcriber's note: The correct value is 9.99001]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Multiple Series.</span><br>
-Arrangements of electric apparatus in a circuit in a number of series,<br>
-which minor series are then arranged in parallel. The term may be used<br>
-as a noun, as "arranged in multiple-series," or as an adjective, as "a<br>
-multiple-series circuit."<br>
-<br>
-<br>
-Fig. 248. MULTIPLE SERIES CONNECTION.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Multiple Switch Board.</span><br>
-A switch board on whose face connecting spring jacks or other devices<br>
-are repeated for the same circuits, so that different operators have<br>
-each the entire set of connections repeated on the section of the board<br>
-immediately in front of and within their reach. This multiplication of<br>
-the same set of connections, giving one complete set to each operator,<br>
-gives the title "multiple" to the type of switch board in question. The<br>
-typical multiple switch board used in telephone exchanges is the best<br>
-example of this construction. The calling annunciators of the<br>
-subscribers are distributed along the bottom of the board extending its<br>
-full length. To each operator a given number is assigned, all within<br>
-reach of the right or left hand. This gives five or six feet length of<br>
-board to each, and an operator only responds to those subscribers within<br>
-his range. But anyone of his subscribers may want to connect with any of<br>
-the others in the entire central station. Accordingly in front of each<br>
-operator spring jacks are arranged, one for each of the entire set of<br>
-subscribers connected in that office. The operator connects as required<br>
-any of the calling subscribers, who are comparatively few, to any one of<br>
-the large number served by the central station. Thus the entire set of<br>
-subscribers' spring jacks are multiplied over and over again so as to<br>
-give one set to each operator.<br>
-<br>
-<br>
-388&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Multiple Wire Method for Working
-Electro-magnets.</span><br>
-A method for suppressing sparking in working electro-magnets<br>
-intermittently. The magnet core is wound with a number (from four to<br>
-twenty) of separate layers of fine wire. A separate wire is taken for<br>
-each layer and all are wound in the same direction, from one end to the<br>
-other of the space or bobbin without returning. The ends are then joined<br>
-so as to bring all the wires in parallel. The effect of this is that as<br>
-the coils vary in diameter the time constants of each is different from<br>
-that of the others, the coefficient of self-induction being less, and<br>
-the resistance being greater for the coils farthest from the central<br>
-axis. Thus the extra currents run differently in the different coils,<br>
-and only a comparatively small spark can be produced owing to the<br>
-division of forces thus brought about.<br>
-<br>
-<br>
-<img style="width: 677px; height: 207px;" alt=""
- src="images/388F249.jpg"><br>
-Fig. 249. DIAGRAM ILLUSTRATING MULTIPLE WIRE WORKING.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Multiplex Telegraphy.</span><br>
-Any system of telegraphy transmitting more than four messages<br>
-simultaneously over a single wire. Properly it should apply to all<br>
-transmitting more than one, but conventionally has the above restricted<br>
-meaning, distinguishing it from duplex and quadruplex telegraphy.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Multiplying Power of a Shunt.</span><br>
-When a resistance is placed in parallel with a galvanometer on a circuit<br>
-the following relation obtains. Let s and g equal the resistances of the<br>
-shunt and galvanometer respectively, S and G the currents in amperes<br>
-passing through them, V the potential difference between their common<br>
-terminals, and A the whole current in amperes. Then we have<br>
-&nbsp; A = ( (s + g ) / s ) * G<br>
-and ( (s + g ) / s ) is termed the multiplying power of the shunt, as it<br>
-is the factor by which the current passing through the galvanometer must<br>
-be multiplied by to produce the total current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Muscular Pile.</span><br>
-A species of voltaic battery, often termed Matteueci's pile, made up of<br>
-alternate pieces of muscle cut longitudinally and transversely<br>
-respectively. The different pieces represent the elements of a battery,<br>
-and their difference of potential is naturally possessed by the pieces.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Myria.</span><br>
-A prefix; one million times. Thus myriavolt means one million volts.<br>
-<br>
-[Transcriber's note: Contemporary usage is mega, as in megavolt.]<br>
-</big></big><br>
-<big><big><br>
-389&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">N.</span><br>
-(a) Symbol for north pole or north-seeking pole of a magnet.<br>
-<br>
-(b) Symbol for the number of lines of force in a magnetic circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Nairne's Electrical Machine.</span><br>
-The cylinder electrical machine, q.v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Napierian Logarithms.</span><br>
-A series of logarithms the base of whose system is 2.72818. They are<br>
-also called hyperbolic logarithms.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Nascent State.</span><br>
-An element just separating from a combination possesses at that time<br>
-higher affinities than after separation, and can effect more powerful<br>
-chemical changes.<br>
-<br>
-It is sometimes attributed to a differential time of existence in the<br>
-atomic modification, before the freed atoms have united to form<br>
-molecules.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Natural Currents.</span><br>
-A term for earth currents. (See Current, Earth.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Needle.</span><br>
-(a) A term applied to a bar magnet poised horizontally upon a vertical<br>
-point, or suspended in a horizontal position by a filament. Thus the<br>
-magnet in a mariner's compass, which may be a substantial bar magnet, is<br>
-called a magnetic needle.<br>
-<br>
-(b) An indicator in general shape like the hand of a clock. (Sec<br>
-Annunciator, Needle- Telegraph, Needle.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Needle of Oscillation.</span><br>
-The magnetic needle poised horizontally, and used for measuring the<br>
-intensity of the earth's magnetic field, or of an artificial magnetic<br>
-field, by the method of oscillations. The intensities of the field is<br>
-inversely as the square of the number of oscillations performed in a<br>
-given time.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Needle, Telegraphic.</span><br>
-The index in needle telegraphy (see Telegraph, Needle), whose motions<br>
-indicate the characters it is desired to transmit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Negative Charge.</span><br>
-One of the two kinds of electric charges. The other is the positive.<br>
-<br>
-By the double fluid hypothesis this is assumed to be a charge of a<br>
-particular kind of electricity--negative electricity.<br>
-<br>
-By the single fluid hypothesis it is supposed to be caused by the<br>
-absence of part of the normal electricity of a surface. The reverse is<br>
-held by some theorists.<br>
-<br>
-The subject is so purely theoretical that neither of the two hypotheses<br>
-is accepted as final.<br>
-<br>
-[Transcriber's note: Current is a wire is the motion of negative<br>
-electrons. Current in a electrolyte is the motion of positive ions and<br>
-negative ions. Current in a plasma is the motion of electrons and<br>
-positive ions.]<br>
-<br>
-<br>
-390&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Negative Electricity.</span><br>
-The kind of electricity with which a piece of amber is charged by<br>
-friction with flannel; resinous electricity. (See Electrostatic Series.)<br>
-<br>
-<br>
-In a galvanic battery the surface of the zinc plate is charged with<br>
-negative electricity.<br>
-<br>
-According to the single fluid theory negative electrification consists<br>
-in a deficiency of electricity.<br>
-<br>
-[Transcriber's note: Negative electrification is an excess of<br>
-electrons.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Negative Element.</span><br>
-In a voltaic cell the plate not dissolved by the solution; the one which<br>
-is positively charged; the copper, platinum, or carbon plate in the<br>
-usual type of battery.<br>
-<br>
-The current is assumed to flow from negative element to positive element<br>
-(the zinc plate) through the wire or other external conductor.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Nerve Currents.</span><br>
-Currents of electricity obtained from nerves. They are much more feeble<br>
-than those obtained from muscle, but are produced in the same general<br>
-ways.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Network.</span><br>
-Conductors in parallel and crossing each other, with connections at the<br>
-junctions.<br>
-<br>
-The term is sometimes so loosely applied as to include parallel<br>
-conductors.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Neutral Line of Commutator.</span><br>
-The diameter of a commutator which connects its Neutral Points, q. v.;<br>
-sometimes termed the diameter of commutation; the diameter approximately<br>
-at right angles with the lines of force. The commutator brushes are<br>
-applied at the extremities of this diameter.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Neutral Point of a Commutator.</span><br>
-The points of a commutator at which no lines of force are cut; the<br>
-points at the extremities of a diameter which, except for the lag, would<br>
-be at right angles to the lines of force; the points at which the<br>
-brushes touch the commutator.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Neutral Point, Thermo-electric.</span><br>
-A temperature marking a point of no thermo-electric difference of<br>
-potential. If the junctions of a thermo-electric couple are at<br>
-temperatures, one a little over and the other an equal amount under the<br>
-neutral point, no current will be developed. At the neutral point the<br>
-thermo-electric polarities are reversed. Differences of temperature<br>
-above it give currents of reverse direction to those given by<br>
-corresponding differences below it. For an iron-copper couple the<br>
-neutral point is 274.5&deg; C. (526&deg; F.)<br>
-<br>
-Synonym--Neutral Temperature.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Neutral Relay Armature.</span><br>
-An unpolarizable armature for use with a relay; an armature of soft iron<br>
-or iron wire; as distinguished from a polarized armature.<br>
-<br>
-<br>
-391&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Neutral Wire.</span><br>
-The central wire in the three wire system, q. v., of electric<br>
-distribution; the wire connected to a point between the two dynamos, or<br>
-otherwise to the central point of the current generator.<br>
-<br>
-<br>
-<img style="width: 713px; height: 223px;" alt=""
- src="images/391F250.jpg"><br>
-Fig. 250. DIAGRAM OF THREE WIRE SYSTEM SHOWING NEUTRAL WIRE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Neutral Wire Ampere Meter.</span><br>
-An ampere meter connected in the circuit of the neutral wire to<br>
-determine the current passing through it. Such determination is for the<br>
-purpose of ascertaining how much more work is being done by one of the<br>
-lateral leads than by the other.<br>
-<br>
-Synonym--Balance Ampere Meter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">N. H. P.</span><br>
-Symbol or contraction for "nominal horse power." This is a basis for<br>
-rating the size of an engine.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Nickel.</span><br>
-A metal; one of the elements; atomic weight, 58.8 ; equivalent, 29.4;<br>
-valency, 2; specific gravity, 8.8. It is a conductor of electricity.<br>
-&nbsp; <small><span style="font-family: monospace;">Relative
-resistance, annealed (Silver = 1),&nbsp;&nbsp; 8.285</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Specific
-Resistance,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-12.47&nbsp;&nbsp; microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a wire</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long, weighing
-1 grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 15.206&nbsp;&nbsp; ohms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (b) 1 foot long, 1/1000
-inch thick,&nbsp;&nbsp;&nbsp;&nbsp; 74.963&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (c) 1 meter long, weighing
-1 gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1.060&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (d) 1 meter long, 1
-millimeter thick,&nbsp;&nbsp;&nbsp;&nbsp; .1587&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a 1-inch
-cube,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-4.907&nbsp;&nbsp; microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Electro-chemical
-equivalent, (Hydrogen = .0105)&nbsp;&nbsp; .3087&nbsp;&nbsp; mgs.</span></small><br>
-<br>
-It is strongly paramagnetic, but loses this quality at 350&ordm; C.
-(662&ordm; F.)<br>
-<br>
-It is important as a constituent of German silver, an alloy much used<br>
-for resistance coils.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Nickel, Bath.</span> <br>
-A bath for the electro-deposition of nickel. A great many<br>
-formulae have been given. Metallic nickel is dissolved in 1 vol.<br>
-sulphuric acid mixed with 2 vols. water. Neutralize with ammonia, and<br>
-add of ammonium sulphate one-half the weight of metallic nickel<br>
-originally used; 135 parts of nickel will be enough for a bath of 10,000<br>
-parts.<br>
-<br>
-<br>
-392&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Other formulae are as follows:<br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Double nickel-ammonium
-sulphate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 4&nbsp;&nbsp; parts.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Ammonium
-carbonate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Water&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-100&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Nickel sulphate, nitrate
-or chloride,&nbsp;&nbsp; 1&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Sodium
-bisulphate,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-20&nbsp;&nbsp; "</span><br>
-<br>
-Nickel anodes are used in the bath to maintain the strength. Too much<br>
-care cannot be exercised in the absolute cleanliness of the articles to<br>
-be plated. A too alkaline bath gives a disagreeable yellow color to the<br>
-deposit; too acid a bath gives badly adhering deposits.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Night Bell.</span><br>
-An alarm bell in a telegraph office, which bell is connected at night to<br>
-give a loud signal to attract the operator's attention. It is used in<br>
-telephone exchanges and is connected so as to ring as long as a<br>
-subscriber remains unanswered after calling.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Nobili's Rings.</span><br>
-When a dilute solution of copper acetate is placed on a bright silver<br>
-plate and a strip of zinc is touched to the silver beneath the copper, a<br>
-series of rings of copper are formed by electrolysis around the zinc.<br>
-These are Nobili's rings.<br>
-<br>
-If for the copper acetate a solution of lead oxide in potassium hydrate<br>
-solution is substituted, and if the polished plate which may be German<br>
-silver is connected to the positive electrode of a battery, and a<br>
-platinum wire connected to the negative pole is immersed in the liquid,<br>
-it determines the formation of beautiful iridescent rings of lead<br>
-binoxide. The platinum wire is sometimes sealed in glass so that only<br>
-its point projects.<br>
-<br>
-The colors are due to interference of light, the layers of lead oxide<br>
-being extremely thin.<br>
-<br>
-The lead binoxide is formed by secondary reaction. Metallic lead is<br>
-first deposited on the negative pole. The oxygen which goes to the<br>
-positive pole formed by the polished plate produces lead binoxide which<br>
-is deposited there in rings. The reaction is comparable to that of a<br>
-storage battery.<br>
-<br>
-Synonyms--Metallochromes--Electric Rings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Nodular Deposit.</span><br>
-A deposit obtained in electroplating, characterized by irregular<br>
-thickness; due to too low density of current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Non-conductor.</span><br>
-A material that does not conduct electricity except with great<br>
-difficulty; a substance of very high resistance.<br>
-<br>
-Synonym--Insulator--Dielectric.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">North Pole.</span><br>
-(a) The north-seeking pole of a magnet; the pole of a magnet which tends<br>
-to point to the north, and whence lines of force are assumed to issue on<br>
-their course to the other pole of the magnet.<br>
-<br>
-(b) The North Pole of the earth. Treating the earth as a magnet, and<br>
-accepting the above nomenclature the north pole should be termed the<br>
-south pole. (See Austral Pole--Boreal Pole.)<br>
-<br>
-<br>
-393&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">North-seeking Pole.</span><br>
-The pole of a magnet which tends to point to the north; the north pole<br>
-of a magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Null Method.</span><br>
-Any method of obtaining measurements or comparisons, in which the<br>
-measurement is correct when the deflection of the galvanometer or other<br>
-indicator is zero, nought or null. The Wheatstone Bridge (see Bridge,<br>
-Wheatstone) is an example of a null method.<br>
-<br>
-Two obvious advantages attach to null methods in electric galvanometer<br>
-work. One is that an uncalibrated galvanometer can be employed. The<br>
-other is that a galvanometer of any high degree of sensitiveness can be<br>
-employed, there being no restriction as to its fineness of winding or<br>
-highness of resistance.<br>
-<br>
-</big></big><big><big><br>
-393&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 634px; height: 86px;" alt=""
- src="images/393Omega.jpg"><br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">"Upper case Omega Graphic".</span><br>
-(Greek capital" Omega") symbol for megohm.<br>
-[Transcriber's note: Now used for ohms.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">"Lower case Omega Graphic".</span><br>
-(Greek omega) symbol for ohm.<br>
-[Transcriber's note: Now used for angular velocity, 2*PI*frequency.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Occlusion.</span><br>
-An absorption of gases by metals. Palladium will, if used as the<br>
-hydrogen evolving electrode in decomposing water, absorb 980 times its<br>
-volume of hydrogen, which is said to be occluded. The metal may also be<br>
-heated in hydrogen and allowed to cool therein, when occlusion occurs.<br>
-Platinum will occlude 4 times its volume of hydrogen; iron, 4.15 times<br>
-its volume of carbon-monoxide; silver, 7 times its volume of oxygen.<br>
-Metals with occluded gases may serve as elements in a galvanic couple.<br>
-(See Gas Battery.) A metal expands in occluding a gas.<br>
-<br>
-In the storage battery it is believed that occlusion plays a part,<br>
-hydrogen and oxygen being respectively absorbed by the two sets of<br>
-plates, and acting as they do in Groves' gas battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Oerstedt.</span><br>
-Name proposed for the unit of current strength, but not adopted. The<br>
-ampere is the accepted name.<br>
-<br>
-<br>
-394&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Oerstedt's Discovery.</span><br>
-Oerstedt discovered in 1820 that a magnetic needle tended to place<br>
-itself at right angles to a current of electricity. This fundamental<br>
-experiment is the basis of the galvanometer.<br>
-<br>
-<br>
-<img style="width: 587px; height: 510px;" alt=""
- src="images/393F251.jpg"><br>
-Fig. 251. OERSTEDT'S DISCOVERY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohm.</span><br>
-The practical unit of resistance; 1E9 C. G. S. electro-magnetic units.<br>
-The legal ohm is the resistance of a mercury column 1 square millimeter<br>
-in cross-sectional area and 106 centimeters in length. There has been<br>
-considerable confusion, owing to inaccuracy in early determinations, in<br>
-the valuation of the ohm. In this work the legal ohm is used. The<br>
-different ohms will be found defined in their place. Resistance units of<br>
-various names may also be consulted.<br>
-<br>
-The following table gives the relative values of the different ohms.<br>
-<small><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Length of</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Mercury&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Board of</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Column in&nbsp;&nbsp;&nbsp; True&nbsp;&nbsp;&nbsp; B.
-A.&nbsp;&nbsp;&nbsp; Trade&nbsp;&nbsp;&nbsp;&nbsp; Legal</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Centimetre.&nbsp; Ohm.&nbsp;&nbsp;&nbsp; Ohm.&nbsp;&nbsp;&nbsp;&nbsp;
-Ohm.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Ohm.</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">True
-Ohm,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-106.24&nbsp;&nbsp;&nbsp; 1.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1.0128&nbsp;&nbsp;&nbsp; .9994&nbsp;&nbsp;&nbsp; 1.0022</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">B. A.
-Ohm,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-104.9&nbsp;&nbsp;&nbsp;&nbsp; .9874&nbsp;&nbsp;
-1.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.9868&nbsp;&nbsp;&nbsp;&nbsp; .9889</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Board of Trade Ohm&nbsp;
-106.3&nbsp;&nbsp;&nbsp; 1.00050&nbsp; 1.0133&nbsp;&nbsp;
-1.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1.0028</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Legal
-Ohm,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-106.0&nbsp;&nbsp;&nbsp;&nbsp; .9977&nbsp;&nbsp;
-1.0112&nbsp;&nbsp;&nbsp; .9971&nbsp;&nbsp;&nbsp; 1.</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Ohmage.</span><br>
-The Resistance of a circuit expressed in ohms.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohm, B. A.</span><br>
-The British Association unit of resistance; the resistance of a column<br>
-of mercury 1 square millimeter in cross sectional area and 104.9<br>
-centimeters long; the B. A. Unit of Resistance.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohm, Board of Trade.</span><br>
-The approximate ohm as recommended by the British Board of Trade on the<br>
-advice of a committee (Sir W. Thomson, Dr. J. Hopkinson, Lord Rayleigh<br>
-and others). It is the resistance of a mercury column one square<br>
-millimeter in section, and 106.3 centimeters long at 0&ordm; C.
-(32&ordm; F.)<br>
-<br>
-Synonym--New Ohm.<br>
-<br>
-<br>
-395&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohmic Resistance.</span><br>
-True resistance as distinguished from spurious resistance, or<br>
-counter-electro-motive force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohm, Legal.</span><br>
-The practical unit of resistance. The resistance of a column of mercury<br>
-one square millimeter in cross-sectional area and 106 centimetres long<br>
-at 0&ordm; C. (32&ordm; F.) The ohm used previously to 1884 is the B.
-A. Unit of<br>
-Resistance, q. v.<br>
-<br>
-One legal ohm = 1.0112 B. A. Units, and I B. A. Unit = 0.9889 legal ohm.<br>
-<br>
-The resistance of a copper wire 1 foot long and 1/1000 inch in diameter<br>
-is about 10 ohms. The resistance of 1 mile of iron wire 1/3 inch in<br>
-diameter is about 10 ohms.<br>
-<br>
-Synonym--Congress Ohm.<br>
-<br>
-<br>
-396&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 642px; height: 466px;" alt=""
- src="images/395F252.jpg"><br>
-Fig. 252. THEORY OF OHMMETER.<br>
-<br>
-<br>
-<img style="width: 595px; height: 501px;" alt=""
- src="images/395F253.jpg"><br>
-Fig. 253. OHMMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohmmeter.</span><br>
-An instrument for measuring directly the resistance of a conductor or of<br>
-any part of a circuit through which a strong current is passing.&nbsp;
-It is<br>
-the invention of Prof. W. E. Ayrton.<br>
-<br>
-It contains two fixed coils at right angles to each other acting on the<br>
-same needle of soft iron. One coil is of thick wire and is placed in<br>
-series with the resistance to be measured. The other is of very thin<br>
-wire and is placed in parallel with the same resistance. One wire acts<br>
-by the total current, the other by the potential difference between the<br>
-ends of the resistance. The action on the soft iron needle is due to the<br>
-ratio of potential difference to total currents, or to the resistance<br>
-itself. By properly designing and proportioning the coils the angular<br>
-deflections of the needle are made proportional to the resistance.<br>
-<br>
-In use the thick wire may be kept permanently in circuit. On connecting<br>
-the binding posts of the thin wire coil to any two parts of the circuit<br>
-its resistance is at once given by the deflection of the needle.<br>
-<br>
-When no current is passing the needle rests in any position. A current<br>
-in the thick coil brings it to zero. A current simultaneously passing<br>
-through the thin high resistance coil brings about the deflection.<br>
-<br>
-The instrument is a commercial rather than a scientific one.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohm's Law.</span><br>
-The fundamental law expressing the relations between current,<br>
-electro-motive force and resistance in an active electric circuit. It<br>
-may be expressed thus:<br>
-<br>
-(a) The current strength is equal to the electro-motive force divided by<br>
-the resistance.<br>
-<br>
-(b) The electro-motive force is equal to the current strength multiplied<br>
-by the resistance.<br>
-<br>
-(c) The resistance is equal to the electro-motive force divided by the<br>
-current strength. All these are different forms of the same statement.<br>
-Algebraically the law is usually expressed thus, (a) C = E/R. It may<br>
-also be expressed thus: (b) E = C*R and (c) R= E/C, in which R denotes<br>
-resistance, C denotes current strength, and E denotes electro-motive<br>
-force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ohm, True.</span><br>
-The true ohm is the resistance of a column of mercury 1 square<br>
-millimeter in cross-sectional area, and 106.24 centimeters long. (See<br>
-Ohm.)<br>
-<br>
-Synonym-Rayleigh Ohm.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Oil Insulation.</span><br>
-Oil insulation has received several applications in electrical work. It<br>
-has been proposed for use in underground conduits. These it was proposed<br>
-to fill with oil after the insertion of the conductors, the latter<br>
-properly wrapped with cotton or other covering. For induction coils it<br>
-has been very successfully used. Its principal utility depends on the<br>
-fact that it is liquid, so that if pierced by a spark it at once closes<br>
-again. A solid insulator if pierced is permanently injured. It is also<br>
-used in telegraph insulators (see Insulator, Liquid) to prevent surface<br>
-leakage.<br>
-<br>
-<br>
-397&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Olefiant Gas.</span><br>
-A compound gas; C2H4; composed of carbon, 24; hydrogen, 4; molecular<br>
-weight, 28; specific gravity, .981.<br>
-<br>
-It is a dielectric of about the resistance of air. Its specific<br>
-inductive capacity at atmospheric pressure is 1.000722 (Boltzman.)<br>
-<br>
-Synonym--Ethene; heavy carburetted hydrogen.<br>
-<br>
-[Transcriber's note: Also called ethylene. A primary use is polyethylene<br>
-plastic.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Open. adj.</span><br>
-An electric circuit is said to be open when it is cut or broken so that<br>
-no current can pass through it. The term may be recollected by thinking<br>
-of a switch; when open no current can pass through it. The same<br>
-adjective is applied to magnetic circuits, an air gap implying an open<br>
-circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Open Circuit Oscillation.</span><br>
-An oscillation of current in open circuit so that a spark discharge<br>
-accompanies it. It is produced by electric resonance in a simple circle<br>
-or loop of wire with ends placed near together but not touching, if the<br>
-circuit is of such size that its period of oscillation corresponds with<br>
-that of the inducing discharge. (See Resonance, Electric.) Its period<br>
-depends entirely on the self-induction of the circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ordinate.</span><br>
-In a system of plane co-ordinates (see Co-ordinates), the distance of<br>
-any point from the axis of abscissas measured parallel to the axis of<br>
-ordinates.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ordinates, Axis of.</span><br>
-The vertical axis in a system of co-ordinates, q. v.<br>
-<br>
-Synonym--Axis of Y.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Organ, Electric.</span><br>
-An organ in which the air blast is admitted or excluded from the<br>
-different pipes by electric mechanism.<br>
-<br>
-The outlines of the system are a series of contacts worked by the keys<br>
-and stops, which cause, when operated by the organist, a current to pass<br>
-through electro-magnets, opening the valves of the different pipes. Thus<br>
-the manual may be at any distance from the organ, and a number of organs<br>
-may be worked upon the same manual. As many as five in a single<br>
-cathedral are thus connected to a manual in the chancel.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Orientation of a Magnetic Needle.</span><br>
-The acquirement by a magnetic needle of its position of rest, with its<br>
-magnetic axis in the magnetic meridian.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Origin of Co-ordinates.</span><br>
-In a system of linear co-ordinates the point of intersection of the<br>
-axes; the point whose co-ordinates are both zero.<br>
-<br>
-<br>
-398&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Oscillating Needle.</span><br>
-A small light bar magnet suspended by a filament and employed in<br>
-determining the intensity of a magnetic field by the oscillations it<br>
-completes in a given time after a given disturbance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Oscillations, Electric.</span><br>
-In static electricity the sudden and very rapid alternations in the<br>
-discharge of a static condenser. This discharge of the disruptive order<br>
-seems a single one, but is really composed of a number of discharges<br>
-alternating in direction and producing electro-magnetic ether waves,<br>
-probably identical with light waves except that they are longer and far<br>
-less rapid.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Oscillatory Electro-motive Force.</span><br>
-Electro-motive force rapidly changing in sense or in direction, so that<br>
-it presents an oscillatory character. The alternating current and the<br>
-telephone current as used in practice are actuated by this type of<br>
-electro-motive force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Osmose, Electric.</span><br>
-When two liquids are separated by a porous diaphragm, and a strong<br>
-current of electricity is passed through from the liquid on one side,<br>
-through the diaphragm, to the liquid on the other side, the liquid on<br>
-the side towards which the current is passing rises in level. The<br>
-process is termed electric osmose. When a liquid is forced through a<br>
-diaphragm a current is produced; in other words electric osmose is<br>
-reversible. The current thus produced is termed a diaphragm current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Oscillation, Electric.</span><br>
-The phase of discharge of a static condenser in one direction. It is<br>
-usually followed by a discharge in the opposite direction constituting a<br>
-second oscillation, and so on, so that a great number of exceedingly<br>
-short oscillations are comprised. Thus, in the discharge of the Leyden<br>
-jar a large number of oscillations of current back and forth are<br>
-produced, the current alternating like the swings of a pendulum.<br>
-<br>
-These oscillations are supposed to affect the ether, producing waves in<br>
-it identical with light waves, except that we have not been able yet to<br>
-produce them short enough to affect the visual organs. The waves thus<br>
-produced can be reflected or refracted; some substances are transparent<br>
-for them and others opaque. There is a possibility that man may yet<br>
-succeed in producing electric oscillations of sufficient frequency to<br>
-bring about the direct production of light.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Oscillatory Displacement.</span><br>
-Hypothetical displacement currents of rapidly alternating direction<br>
-produced in the oscillatory discharge of a Leyden jar or static<br>
-condenser.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Oscillatory Induction.</span><br>
-Induction produced by sympathetic action of an oscillatory discharge or<br>
-by electric resonance. (See Oscillations, Electric--Resonance,<br>
-Electric--Resonator, Electric.)<br>
-<br>
-<br>
-399&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Outlet.</span><br>
-The part of an electrolier or electric light fixture out of which the<br>
-wires are led for attachment of an incandescent light socket.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Output.</span><br>
-The rate of energy delivered or of work done by a machine. In the case<br>
-of a current generator it is the volt-coulombs per given second, or<br>
-better the volt-amperes delivered at its outer circuit terminals.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Output, Magnetic.</span><br>
-The analogue in a magnetic circuit of the output of an electric circuit.<br>
-It is the product of the magnetizing force by the induced magnetism.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Output, Unit of.</span><br>
-As a unit of output of a dynamo Prof. Sylvanus P. Thompson has proposed<br>
-1,000 watts, or one kilowatt. This unit is now frequently used. To<br>
-completely define the dynamo, however, the amperage or the voltage must<br>
-also be given, as a 10 kilowatt--110 volt machine, or a 10 kilowatt--99<br>
-ampere machine.<br>
-<br>
-[Transcriber's note: 10 kilowatt at 110 volts is 91 amperes.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Over-Compounding.</span><br>
-A proportioning of the series and shunt windings of a compound dynamo,<br>
-so that the voltage of the terminals rises with the load or output<br>
-enough to allow for the drop in mains, thus maintaining the potential<br>
-for full load at distant points in a district. It is carried out by an<br>
-increase of ampere-turns in the series winding.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Overload.</span><br>
-In an electric motor a mechanical load put upon it so great as to<br>
-prevent economical working. One effect of such a load is to make the<br>
-armature run so slowly as to unduly reduce the counter-electro-motive<br>
-force and hence to permit so much current to pass through the coils as<br>
-to heat them, perhaps injuriously. In this case the production of heat<br>
-implies the waste of energy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Overtype Dynamo or Motor.</span><br>
-A dynamo or motor whose armature is placed above or in the upper part of<br>
-the field magnets, the yoke piece of the magnets being in or resting<br>
-upon the base of the machine.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ozone.</span><br>
-An allotropic form of oxygen. It possesses much more energetic chemical<br>
-properties than oxygen. It is supposed to contain three atoms of oxygen<br>
-in its molecule, represented thus:<br>
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp; O</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp; / \</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; O---O</span><br>
-<br>
-It is produced by electric discharges and it is its peculiar odor which<br>
-is noticed about an electric machine, and sometimes in a thunderstorm<br>
-near the path of a lightning flash.<br>
-<br>
-In the electrolysis of water some ozone may be produced, thus<br>
-diminishing the volume of the oxygen or of the mixed gases given off.<br>
-This is a source of inaccuracy in a gas voltameter.<br>
-<br>
-</big></big><big><big><br>
-400&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pacinotti's Inductor.</span><br>
-The Pacinotti or Gramme Ring. (See Pacinotti's Ring.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pacinotti's Ring.</span><br>
-A ring of iron wire wound with coils of insulated wire at right angles<br>
-to its circular axis, and used as the armature of a dynamo or motor. A<br>
-number of connections are taken from the coils to a central commutator.<br>
-<br>
-<br>
-<img style="width: 640px; height: 559px;" alt=""
- src="images/400F254.jpg"><br>
-Fig. 254. PACINOTTI'S MACHINE, WITH RING ARMATURE.<br>
-<br>
-<br>
-If such a ring with its coils is rotated in a field, current can be<br>
-taken from points of the commutator on a line at right angles to the<br>
-lines of force entering the ring.<br>
-<br>
-The ring was discovered in 1862 by Pacinotti, and later was<br>
-independently discovered by Gramme. It is often known as the Gramme<br>
-ring.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pacinotti Teeth.</span><br>
-Projections on a cylindrical or drum armature, between which in the<br>
-grooves formed thereby, the wire is wound. The teeth being of iron tend<br>
-to diminish the reluctance or magnetic resistance of the interpolar<br>
-space, or interval between the poles of the field magnet.<br>
-<br>
-Synonym--Pacinotti Projections.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Paillard Alloys.</span> <br>
-Non-magnetic palladium alloys, invented by Paillard, of<br>
-Switzerland, used in anti-magnetic watches. The following are given as<br>
-the compositions of several such alloys:<br>
-<small><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-I.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-II.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Palladium,&nbsp; 60 to
-75&nbsp;&nbsp; parts&nbsp;&nbsp; 50 to 75&nbsp; parts</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Copper,&nbsp;&nbsp;&nbsp;&nbsp;
-I5 to 25&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 20 to
-30&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Iron.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1 to 5&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 5 to
-20&nbsp;&nbsp; "</span></small><br>
-<br>
-<br>
-401&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The following are more complex:<small><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-I.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-II.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Palladium,&nbsp;&nbsp; 65 to
-75&nbsp;&nbsp; parts&nbsp;&nbsp; 45 to 50&nbsp;&nbsp; parts</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Copper,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-15 to 25&nbsp;&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp; 15 to
-25&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Nickel,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1 to 5&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2
-to 5&nbsp;&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Silver,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3 to 10&nbsp;&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp; 20 to
-25&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Gold,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1 to 2-1/2&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2 to
-5&nbsp;&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Platinum,&nbsp;&nbsp; 1/2 to
-2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2 to
-5&nbsp;&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Steel,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1 to 5&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2
-to 5&nbsp;&nbsp;&nbsp; "</span></small><br>
-<br>
-These alloys are used for balance springs, as well as for the balance<br>
-wheels and escapement parts of watches. The elasticity of recently<br>
-produced springs has been found to be very satisfactory.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Page Effect.</span><br>
-The sounds produced by magnetizing and demagnetizing a bar of iron or<br>
-steel; the magnetic tick. The sounds are strong enough to produce a<br>
-telephonic effect. (See Magnetic Tick.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Palladium.</span><br>
-A metal of the platinum series. It has the highest power of occlusion,<br>
-q.v., of all metals. It is the characteristic ingredient of non-magnetic<br>
-watch alloys.<br>
-<br>
-Palladium used as an electrode in the electrolysis of water will occlude<br>
-936 volumes of hydrogen, and the hydrogen-palladium alloy will exceed in<br>
-size the original electrode.<br>
-<br>
-<br>
-<img style="width: 343px; height: 686px;" alt=""
- src="images/365F235.jpg"><br>
-Fig. 255. LUMINOUS PANE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pane, Luminous.</span><br>
-A pane of glass, one side of which has pasted to it a long zigzag strip<br>
-of tinfoil. A design is made by cutting through the strip. On<br>
-discharging a Leyden jar or an electric machine through the strip sparks<br>
-appear where the tinfoil is severed, thus producing the design in a<br>
-luminous effect. Many variations can be employed in their construction.<br>
-<br>
-<br>
-402&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pantelegraphy.</span><br>
-A system of telegraphy for transmitting designs, maps, drawing, and the<br>
-like by telegraphy. (See Telegraphy, Facsimile.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Paper Filaments.</span><br>
-Filaments of carbon for incandescent lamps made from paper.<br>
-<br>
-This is one of the earliest materials practically used. The paper is cut<br>
-out of proper shape, and is carbonized in a close vessel, while embedded<br>
-in powdered charcoal or some other form of carbon to absolutely cut off<br>
-access of air. It is then placed in the lamp chamber and flashed or<br>
-subjected to the regular treatment.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Parabola.</span><br>
-A curve; one of the conic sections. It is approximately represented by a<br>
-small arc of a circle, but if extended becomes rapidly deeper than a<br>
-half circle.<br>
-<br>
-If, from a point within called the focus, lines are drawn to the curve<br>
-and then other lines are drawn from these points parallel to the axis,<br>
-the angles of incidence will he equal to the angles of reflection as<br>
-referred to tangents at the points where the lines touch the curve.<br>
-<br>
-[Transcriber's note; The general equation of a parabola is<br>
-&nbsp;&nbsp;&nbsp; A*x^2 + B*x*y + C*y^2 + D*x + E*y + F = 0<br>
-such that B^2 = 4*A*C, all of the coefficients are real, and A and C are<br>
-not zero. A parabola positioned at the origin and symmetrical on the y<br>
-axis is simplified to y = a*x^2 ]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Parabolic Reflector.</span><br>
-A reflector for a light, a paraboloid or surface of revolution whose<br>
-section is a parabola. A light placed at its focus has its rays<br>
-reflected parallel to each other.<br>
-<br>
-Examples of parabolic reflectors are seen in electric search lights and<br>
-in locomotive head-lights. They are employed in electric search lights.<br>
-The arc light must be of such construction as to maintain its ignited<br>
-points always at the same point, the focus of the paraboloid.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Paraffine. v.</span><br>
-To coat or saturate with paraffine wax. Paper may be paraffined by<br>
-dipping in the wax, or by being sprinkled with fragments of wax,<br>
-subsequently melted in with a hot iron or otherwise. The tops of battery<br>
-carbons are often paraffined to prevent the acid from rising in the<br>
-pores by capillary attraction and rusting the connections.<br>
-<br>
-<br>
-</big></big><big><big>403&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-</big></big><big><big><span style="font-weight: bold;">Paraffine Wax.</span><br>
-A hydro-carbon composed principally of mixtures of the higher members of<br>
-the paraffine series C n H2 n + 2. It is made from cannel coal, coal<br>
-tar, or petroleum by distillation. It is an insulator. Its resistance at<br>
-46&deg; C. (114.8&deg; F.) per centimeter cube is 3.4E16 ohms, or about
-the<br>
-highest resistance known.<br>
-<br>
-Its specific inductive capacity (for milky wax) is 2.47 (Schiller). For<br>
-clear wax it is given as follows by different authorities:<br>
-&nbsp; 1.92&nbsp; Ayrton.<br>
-&nbsp; 1.96&nbsp; W&uuml;llner.<br>
-&nbsp; 1.977 Gibson &amp; Barclay.<br>
-&nbsp; 2.32&nbsp; Baltzmann.<br>
-<br>
-It is extensively used in condensers and other electric apparatus as a<br>
-dielectric and insulator.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Paragr&ecirc;les.</span><br>
-Protectors against hail; lightning rods used to guard fields against<br>
-hail; of little or no real utility.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Parallax.</span><br>
-The apparent change in position of an object when looked at from two<br>
-points of view. By looking at an object a few feet distant first with<br>
-one eye and then with the other, the shifting in apparent position is<br>
-seen.<br>
-<br>
-In reading the position of an indicator or needle over a scale parallax<br>
-introduces an error unless the eye is held vertically over the needle.<br>
-By making the dial of looking- glass and holding the eye so that the<br>
-reflection of its pupil is bisected by the needle this verticality is<br>
-ensured.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Parallel.</span><br>
-(a) In the nomenclature of electric circuits two or more conductors<br>
-leading from one point to another, are said to be in parallel.<br>
-<br>
-(b) When two or more conductors connect two main leads of comparatively<br>
-large size and low resistance they are said to be in parallel or in<br>
-multiple arc. This order is easiest pictured as the rungs of a ladder in<br>
-parallel connecting its two sides representing the main leads.<br>
-<br>
-It may be used as a noun as "arranged in parallel," or as an adjective<br>
-as "a parallel circuit," the opposite of series, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Paramagnetic. adj.</span><br>
-Possessing paramagnetic properties; tending to occupy a position with<br>
-the longer axis parallel to the lines of force of a magnetic field;<br>
-having magnetism; attracted by a magnet.<br>
-<br>
-"If a homogeneous isotropic substance is placed in a magnetic field it<br>
-becomes magnetized at every point in the direction of the magnetic<br>
-intensity at that point, and with an intensity of magnetization<br>
-proportional to the magnetic intensity. When the positive direction of<br>
-the induced magnetization is the same as that of the magnetic intensity<br>
-the substance is called Magnetic or Paramagnetic; when it is opposite,<br>
-the substance is called Diamagnetic." (Emtage.)<br>
-<br>
-A paramagnetic substance has high permeability or multiplying power for<br>
-lines of force, hence in a magnetic field a bar of iron, etc., is in<br>
-unstable equilibrium unless its longer axis is parallel with the lines<br>
-of force in order to reduce as much as possible the reluctance of the<br>
-circuit.<br>
-<br>
-<br>
-404&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Iron is the most paramagnetic of all substances. Other paramagnetic<br>
-metals are: Nickel, cobalt, manganese, platinum, cerium, osmium,<br>
-palladium. Diamagnetic metals are bismuth, antimony, zinc, tin, mercury,<br>
-lead, silver, copper, gold, arsenic. Bismuth is the most diamagnetic of<br>
-all metals.<br>
-<br>
-Of gases oxygen is most paramagnetic. Becquerel calculated that a cubic<br>
-yard of oxygen condensed would act on a magnetic needle as powerfully as<br>
-5.5 grains of metallic iron. Liquefied oxygen will adhere to the poles<br>
-of a magnet.<br>
-<br>
-Changes of temperature and of other conditions may affect a body's<br>
-magnetism. Thus hot oxygen is diamagnetic, and a substance paramagnetic<br>
-in a vacuum may be diamagnetic in air.<br>
-<br>
-Of liquids, solutions of iron or cobalt are paramagnetic; water, blood,<br>
-milk, alcohol, ether, oil of turpentine and most saline solutions are<br>
-diamagnetic.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Paramagnetism.</span><br>
-(a) The science or study of paramagnetic substances and phenomena.<br>
-<br>
-(b) The magnetic property of a paramagnetic substance; that of being<br>
-attracted by a magnet, and of arranging itself with its longer axis<br>
-parallel with the lines of force of a magnetic field.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Parchmentizing.</span><br>
-If cellulose is treated with a mixture of two parts of sulphuric acid<br>
-and one part of water perfectly cold, it becomes like parchment. It<br>
-should at once be washed with water, and then with ammonia and water.<br>
-The Swan incandescent light fibres are made of parchmentized cotton<br>
-thread, which is afterward carbonized.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Partial Earth.</span><br>
-A fault in a conductor caused by imperfect connection with the earth,<br>
-where insulation from the earth is desired.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Passive State.</span><br>
-A state of a substance in virtue of which it is unattacked by a solvent<br>
-which ordinarily would dissolve or attack it. Iron in strong nitric acid<br>
-is unattacked or assumes the passive state. This particular case is<br>
-supposed to be due to a coating of magnetic oxide, so that there would<br>
-be properly speaking no question of a passive state, but only one of<br>
-superficial protection.<br>
-<br>
-The existence of a true passive state of any substance is very doubtful.<br>
-<br>
-<br>
-<span style="font-weight: bold;">P. D.</span><br>
-Abbreviation for potential difference or difference of potential, or for<br>
-electro-motive force.<br>
-<br>
-<br>
-405&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Peltier Effect.</span><br>
-The thermal effect produced by the passage of a current through the<br>
-junction of two unlike conductors. Such junction is generally the seat<br>
-of thermo-electric effects, and a current is generally produced by<br>
-heating such a junction. If an independent current is passed in the same<br>
-direction as that of the thermoelectric current, it cools the junction,<br>
-and warms it if passed in the other direction. In general terms,<br>
-referring to thermo-electric couples, if passed through them it tends to<br>
-cool the hot and heat the cool junction. The phenomenon does not occur<br>
-in zinc-copper junctions.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Peltier's Cross.</span><br>
-A bar of bismuth and a bar of antimony soldered centre to centre at<br>
-right angles, being notched or halved there to receive or to set into<br>
-each other. It is used to demonstrate the Peltier effect, q. v. To one<br>
-pair of ends are connected the terminals of a battery circuit; to the<br>
-other pair are connected the terminals of a galvanometer.<br>
-<br>
-The galvanometer by its deflections in one and then in the other<br>
-direction indicates that the junction is heated when the current passes<br>
-from antimony to bismuth and vice versa. It thus illustrates the heating<br>
-and cooling of a thermo-electric junction by a current of electricity.<br>
-The current from the battery by the Peltier effect either heats or cools<br>
-the junction, as the case may be. This heating or cooling them produces<br>
-a thermo-electric current in the galvanometer circuit. The battery has<br>
-no direct influence on the galvanometer.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pendant Cord.</span><br>
-A double conductor or pair of conductors, insulated from each other and<br>
-covered with a worsted, silk, or cotton covering and used to suspend<br>
-incandescent lamps and at the same time to conduct the current to them.<br>
-It is also used for other similar service, such as acting as conductors<br>
-for small motors. Often each conductor is composed of a number of thin<br>
-wires laid together. This gives flexibility to the cord.<br>
-<br>
-Synonym--Flexible Cord.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pendulum, Electric.</span><br>
-(a) A pendulum operated by the intermittent action of an electro-magnet,<br>
-whose circuit is opened and closed by the pendulum itself. A point at<br>
-the lower end of the pendulum swinging through a globule of mercury may<br>
-close and open the circuit. Various other methods of accomplishing the<br>
-same end are employed ..<br>
-<br>
-(b) A pith ball suspended by a thread from an insulating stand. It is<br>
-used to show the attraction exercised by a piece of sealing wax or other<br>
-substance excited by rubbing.<br>
-<br>
-<br>
-406&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pen, Electric.</span><br>
-A stylus for producing a series of perforations in paper, so that the<br>
-paper may act as a stencil for the reproduction of a great number of<br>
-copies of the original matter. Various kinds of electric pens have been<br>
-invented. One kind, invented by Edison, consists of a handle carrying an<br>
-electric motor actuating a needle, which is driven in and out of the<br>
-other end of the handle with high rapidity. It is used by being held<br>
-vertically on the paper with the needle end downward, and is moved so as<br>
-to describe perforated letters or designs. The paper is then used as a<br>
-stencil with an ink roller to reproduce the writing or design ad<br>
-libitum. A simpler kind dispenses with the motor and depends on the<br>
-perforations produced by the electric spark. As shown in the cut the<br>
-stylus is one terminal of an induction coil circuit. The support on<br>
-which the paper rests is the other terminal and must be a conductor. In<br>
-use the induction coil is started, and the stylus is moved over the<br>
-paper; a series of sparks pass through the paper from stylus to the<br>
-supporting tablet, perforating the paper and producing a stencil to be<br>
-used for reproduction.<br>
-<br>
-<br>
-<img style="width: 681px; height: 631px;" alt=""
- src="images/406F256.jpg"><br>
-Fig. 256. ELECTRIC PEN.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pentane Standard, Harcourt's.</span><br>
-A standard of illuminating power; in it the combustible substance is a<br>
-gas made by mixing one cubic foot of air with three cubic inches of<br>
-liquid pentane, measured at 60&deg; F. or, if measured as gases, 20
-volumes<br>
-of air to 7 of pentane. It is burned at the rate of 0.5 cubic foot per<br>
-hour from a cylindrical tube one inch in diameter, closed at the top by<br>
-a disc 0.5 inch thick with a hole 0.25 inch in diameter, through which<br>
-the gas issues. It gives a flame 2.5 inches high.<br>
-<br>
-The pentane used is the distillate of petroleum which boils at 50&deg;
-C.<br>
-(122&deg; F.) ; it has a specific gravity at 15&deg; C. (60&deg; F.) of
-from 0.628<br>
-to 0.631. It is almost pure pentane (C5H12).<br>
-<br>
-As long as the rate of consumption is between 0.48 and 0.52 cubic foot<br>
-per hour the flame gives practically the same light.<br>
-<br>
-<br>
-407&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Perforator.</span><br>
-An apparatus used in automatic high speed telegraphy for perforating<br>
-strips of paper. These are then used by drawing between a roller and<br>
-contact spring for making and breaking the telegraphic circuit for the<br>
-production of a record, such as the Morse record, at the distant<br>
-receiving station.<br>
-<br>
-The perforated strip has different classes of holes punched in it to<br>
-represent dots or dashes. It is fed by machinery very rapidly, so that<br>
-the message is transmitted with the highest speed. Several operators may<br>
-simultaneously prepare the paper strips, and thus in conjunction with<br>
-its rapid feeding in the transmitter, far surpass the time of ordinary<br>
-direct transmission.<br>
-<br>
-<br>
-<img style="width: 539px; height: 530px;" alt=""
- src="images/407F257.jpg"><br>
-Fig. 257. PERFORATOR FOR <br>
-WHEATSTONE'S AUTOMATIC TELEGRAPH.<br>
-<br>
-<br>
-Perforators may be entirely mechanical but are sometimes pneumatic,<br>
-compressed air being used to operate them. The holes they make are on<br>
-different levels of the paper strip, as shown in the cut.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Period.</span><br>
-The time required for the completion of one complete element of periodic<br>
-motion. This may be a complete alternation (See Alternation, Complete)<br>
-of an alternating current, or of an oscillatory discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Periodicity.</span><br>
-The rate of succession of alternations or of other fixed phases; the<br>
-rate of recurrence of phenomena.<br>
-<br>
-<br>
-408&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Permanency.</span><br>
-In electric current conductors the property of possessing conductivity<br>
-unaffected by lapse of time. Generally the permanency of conductors is<br>
-very high. In some cases a slow annealing takes place which causes a<br>
-gradual change with the lapse of time. Annealed German silver wire has<br>
-been found to increase in conductivity at about .02 per cent. in a year.<br>
-(Matthiessen.) Wire, whether annealed or not, is left in a strained<br>
-condition after the drawing operations, and such a change is consonant<br>
-with this fact. The figure only applies to the samples tested by<br>
-Matthiessen.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Permanent State.</span><br>
-In a telegraph line or other current conductor, the condition when a<br>
-uniform current strength obtains over the whole line. When a current is<br>
-started it advances through the line with a sort of wave front gradually<br>
-increasing in strength. At the further end some time may elapse before<br>
-it attains its full intensity. When its does the permanent state<br>
-prevails. Until then the variable state, q. v., exists in the line.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Permeameter.</span><br>
-An apparatus for determining the permeability of samples of iron. It<br>
-consists of a large slotted block of iron. A coil is placed within the<br>
-slot. A hole is drilled through one end, and a rod of the iron to be<br>
-tested is passed through this hole and through the coil to the bottom of<br>
-the slot. The lower end of the rod must be accurately faced off. The<br>
-current is turned on, upon which the rod adheres to the bottom of the<br>
-slot. The force required to detach it is determined with a spring<br>
-balance. The permeation through its face is proportional to the square<br>
-of the force required.<br>
-<br>
-<br>
-<img style="width: 407px; height: 659px;" alt=""
- src="images/408F258.jpg"><br>
-Fig. 258. PERMEAMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Permeance.</span><br>
-The multiplying or the conducting power for magnetic lines of force<br>
-possessed by a given mass of material. It varies with the shape and size<br>
-of the substance as well as with the inducing force. It is distinguished<br>
-from permeability, as the latter is a specific quality proper to the<br>
-material, and expressed as such; the permeance is the permeability as<br>
-affected by size and shape of the object as well as by its material.<br>
-<br>
-<br>
-409&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pfl&uuml;ger's Law.</span><br>
-A law of electro-therapeutics. It states that stimulation of a nerve is<br>
-only produced by successive appearance of the kathelectrotonic state,<br>
-and disappearance of the anelectrotonic state.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Phantom Wires.</span><br>
-The extra transmission circuits obtained in multiplex telegraph systems.<br>
-A single line arranged for four separate simultaneous transmissions by<br>
-quadruplex apparatus is said to establish three phantom wires.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Phase.</span><br>
-In wave motion, oscillating motion, simple harmonic motion, or similar<br>
-periodic phenomena, the interval of time passed from the time the moving<br>
-particle moved through the middle point of its course to the instant<br>
-when the phase is to be stated.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pherope.</span><br>
-An apparatus for the electric transmission of pictures. (See Telephote.)<br>
-<br>
-[Transcriber's note: Precursor of the contemporary Fax and scanner.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Philosopher's Egg.</span><br>
-An ellipsoidal vessel mounted with its long axis vertical and with two<br>
-vertical electrodes, the upper one sliding, and arranged to be attached<br>
-to an air pump. A discharge through it when the air is exhausted takes<br>
-the general shape of an egg.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Phonautograph.</span><br>
-An apparatus for registering the vibrations of a stylus, which is<br>
-mounted on a diaphragm and is acted on by sound waves.<br>
-<br>
-It is virtually a resonating chamber, over one of whose ends a parchment<br>
-diaphragm is stretched. To the centre of the parchment a needle or<br>
-stylus is attached. A cylinder covered with soot is rotated in contact<br>
-with the point of the stylus. As the chamber is spoken into the<br>
-diaphragm and stylus vibrate and the vibrations are marked on the<br>
-cylinder. It is of some electric interest in connection with telephony.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Phone.</span> <br>
-Colloquial abbreviation for telephone.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Phonic Wheel.</span><br>
-A form of small motor of very simple construction. It consists of a<br>
-toothed wheel of soft iron. A bar electro-magnet is fixed with one pole<br>
-facing the teeth of the wheel. By a tuning fork make and break a<br>
-succession of impulses of rapid frequency and short duration are sent<br>
-through the magnet. The teeth act as armatures and are successively<br>
-attracted by the magnet. The regulated speed is one tooth for each<br>
-impulse, but it may rotate at one-half the speed, giving two teeth for<br>
-each impulse, or at certain other sub-multiples of its regular speed. It<br>
-is the invention of Paul Lecour.<br>
-<br>
-<br>
-410&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Phonograph.</span><br>
-An apparatus for reproducing articulate speech. It is not electric,<br>
-except as it may be driven by electricity.<br>
-<br>
-It consists of a cylinder of wax-like material which is rotated and<br>
-moved slowly, longitudinally, screw fashion, at an even speed. A glass<br>
-diaphragm carrying a needle point is supported with the point barely<br>
-touching the wax. If the diaphragm is agitated, as by being spoken<br>
-against, the needle is driven back and forwards cutting a broken line or<br>
-groove following the direction of the thread of a screw in the wax, the<br>
-depth of which line or groove continually varies.<br>
-<br>
-This imprints the message. If the needle is set back and the cylinder is<br>
-rotated so as to carry the needle point over the line thus impressed,<br>
-the varying depth throws the needle and diaphragm into motion and the<br>
-sound is reproduced.<br>
-<br>
-The cylinder is rotated often by an electric motor, with a centrifugal<br>
-governor.<br>
-<br>
-[Transcriber's note; Due to T. A. Edison, 1877, fifteen years before<br>
-this book.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Phonozenograph.</span><br>
-An apparatus for indicating the direction of the point where a sound is<br>
-produced. It operates by a microphone and telephone in conjunction with<br>
-a Wheatstone bridge to determine the locality.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Phosphorescence.</span><br>
-The emission of light rays by a substance not heated, but whose<br>
-luminosity is due to the persistence of luminous vibration after light<br>
-has fallen upon it.<br>
-<br>
-A phosphorescent body, after exposure to light, is luminous itself.<br>
-Phosphorescence may be induced by rubbing or friction, by heat, by<br>
-molecular bombardment, as in Crookes' tubes, and by static discharge of<br>
-electricity, as well as by simple exposure to light.<br>
-<br>
-Another form of phosphorescence may be due to slow chemical combustion.<br>
-This is the cause of the luminosity of phosphorous.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Phosphorous, Electrical Reduction of.</span><br>
-Phosphorous is reduced from bone phosphate by the heat of the electric<br>
-arc. The phosphate mixed with charcoal is exposed to the heat of the<br>
-voltaic are, and reduction of the phosphorous with its volatilization at<br>
-once ensues. The phosphorous as it volatilizes is condensed and<br>
-collected.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Photo-electricity.</span><br>
-The development of electrical properties by exposure to light. Crystals<br>
-of fluor spar are electrified not only by heat (see Pyro-electricity)<br>
-but also by exposure to sunlight or to the light of the voltaic arc.<br>
-<br>
-[Transcribers note: Although first observed in 1839 by Becquerel, it<br>
-was not explained until 1905 by Albert Einstein with the introduction of<br>
-photons.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Photo-electric Microscope.</span><br>
-A projection, solar or magic-lantern microscope worked by the electric<br>
-light.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Photo-electro-motive Force.</span><br>
-Electro-motive force produced in a substance by the action of light.<br>
-<br>
-<br>
-411&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Photometer.</span><br>
-An apparatus for measuring the intensity of light emitted by a given<br>
-lamp or other source of illuminating power. They may be classified into<br>
-several types.<br>
-<br>
-Calorimetric or Heat Photometers act by measuring relatively the heat<br>
-produced by the ether waves (so-called radiant heat) emitted by the<br>
-source. The accuracy of the instrument is increased by passing the rays<br>
-through an alum solution. A thermopile, or an air thermometer, may be<br>
-used to receive the rays.<br>
-<br>
-Chemical Photometers. In these the light falls upon sensitized<br>
-photographic paper. The depth of coloration is used as the index of<br>
-illuminating power.<br>
-<br>
-Direct Visual Photometers. These include Rumford's Shadow Photometer,<br>
-Bunsen's Bar Photometer, and Wheatstone's Bead Photometer, in which the<br>
-light is estimated by direct visual comparison of its effects.<br>
-<br>
-Optical Photometers. These include Polarization Photometers, in which<br>
-the light is polarized; Dispersion Photometers, in which a diverging<br>
-lens is placed in the path of the rays of light so as to reduce the<br>
-illuminating power in more rapid ratio than that of the square of the<br>
-distance.<br>
-<br>
-Selenium Photometers, in which the variations in resistance of selenium<br>
-as light of varying intensity falls upon it is used as the indicator of<br>
-the intensity of the light.<br>
-<br>
-Jet Photometers, for gas only, in which the height of a flame under<br>
-given conditions, or the conditions requisite to maintain a flame of<br>
-given height, is used to indicate the illuminating power.<br>
-<br>
-The subject of photometers has acquired more importance than ever in<br>
-view of the extensive introduction of the electric light. (See Candle,<br>
-Standard--Carcel--Viol&eacute;'s Standard--and Photometers of various
-kinds.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Photometer, Actinic.</span><br>
-A photometer whose registrations are produced by the action of the light<br>
-being tested upon sensitized paper or plates, such as used in<br>
-photography. Some efforts at self-registering photometers have been<br>
-based on actinic registration of the height of a flame of the gas to be<br>
-tested.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Photometer, Bar.</span><br>
-A photometer in which the two lights to be compared are fixed at or<br>
-opposite to the ends of a bar or scale of known length, generally 60 or<br>
-100 inches. The bar is divided by the rule of the inverse square of the<br>
-distances, so that if a screen is placed on any part of the bar where it<br>
-receives an equal amount of light from both sources, the figure on the<br>
-bar will indicate the relative illuminating power of the larger lamp or<br>
-light in terms of the smaller. The divisions of the bar are laid out on<br>
-the principle that the illuminating power of the two sources of light<br>
-will vary inversely with the square of their distance from the screen.<br>
-<br>
-<br>
-412&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The screen used is sometimes the Bunsen disc. This is a disc of paper<br>
-with a spot of paraffine wax in the centre melted thoroughly into the<br>
-paper or with a ring of paraffine wax surrounding the untouched centre.<br>
-When this disc is equally illuminated on both sides the spot is nearly<br>
-invisible. Inequality of illumination brings it out more visibly.<br>
-Sometimes a Leeson disc is used. This consists of three pieces of paper,<br>
-two thin ones between which a thicker piece, out of which a star is cut,<br>
-is laid. When equally illuminated on both sides the star appears equally<br>
-bright on both sides.<br>
-<br>
-The bar photometer is the standard form. A candle or pair of candles may<br>
-be burned at one end and an incandescent lamp at the other, or a gas<br>
-flame may first be rated by candles and used as a standard.<br>
-<br>
-Synonyms--Bunsen's Photometer--Translucent Disc Photometer.<br>
-<br>
-<br>
-<img style="width: 588px; height: 261px;" alt=""
- src="images/412F259.jpg"><br>
-Fig. 259. BAR PHOTOMETER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Photometer. Calorimetric.</span><br>
-A photometer in which the radiant energy, so called radiant heat, is<br>
-used as the measurer of the light.<br>
-<br>
-In one type a differential air thermometer is used, one of whose bulbs<br>
-is blackened. On exposing this bulb to a source of light it will become<br>
-heated, and if lights of the same character are used the heating will be<br>
-in proportion to their illuminating power quite closely. The heating is<br>
-shown by the movements of the index. By careful calibration the<br>
-instrument may be made quite reliable.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Photometer, Dispersion.</span><br>
-A photometer in which the rays from one of the lights under comparison<br>
-are made more divergent by a concave lens. In this way a strong light,<br>
-such as all arc lamp can be photometered more readily than where only<br>
-the natural divergence of the beam exists. The law of the variation of<br>
-the intensity of light with the square of the distance is abrogated for<br>
-a law of more rapid variation by the use of a concave lens.<br>
-<br>
-The diagram, Fig. 260, illustrates the principle. E represents a<br>
-powerful light, an arc light, to be tested. Its distance from the screen<br>
-is e. Its light goes through the concave lens L and is dispersed as<br>
-shown over an area A1, instead of the much smaller area A, which the<br>
-same rays would otherwise cover. Calling l the distance of the lens from<br>
-the screen, f its focus, and c the distance of the standard candle from<br>
-the screen when the shadows are of equal intensity, we have the<br>
-proportion.<br>
-<br>
-</big></big><big><big>
-Illuminating power of lamps: ditto of standard candle::<br>
-&nbsp;(l (e-l) + fe)2 : (c f)2<br>
-<br>
-<br>
-</big></big><big><big>413&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="border: 2px solid ; width: 638px; height: 328px;" alt=""
- src="images/413F260.jpg"><br>
-Fig. 260. DIAGRAM OF PRINCIPLE <br>
-OF THE DISPERSION PHOTOMETER.<br>
-<br>
-<br>
-The cut, Fig. 261, gives a perspective view of Ayrton's Dispersion<br>
-Photometer. C is the standard candle, L the concave lens, R the rod for<br>
-producing the two shadows on the screen S.<br>
-<br>
-<br>
-<img style="width: 583px; height: 425px;" alt=""
- src="images/413F261.jpg"><br>
-Fig. 261. AYRTON'S DISPERSION PHOTOMETER.<br>
-<br>
-<br>
-The mirror M is fixed at an angle of 45&deg; with the stem on which it<br>
-rotates. The light of the arc lamp is received by the mirror and is<br>
-reflected through the lens. The candle holder slides along a graduated<br>
-bar C, and at D is an index plate to show the angle at which the spindle<br>
-carrying the mirror is set.<br>
-<br>
-<br>
-414&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Dr. J. Hopkinson in his dispersion photometer uses a double convex lens.<br>
-This gives a focal image of the arc-lamp between the lens and screen,<br>
-whence the rays diverge very rapidly, thus giving the desired dispersion<br>
-effect.<br>
-<br>
-It is principally for arc lamps that dispersion photometers are used.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Photometer, Shadow.</span><br>
-A photometer in which the relative intensity of the two lights is<br>
-estimated by the intensity or strength of shadows of the same object<br>
-which they respectively cast.<br>
-<br>
-<br>
-<img style="width: 686px; height: 430px;" alt=""
- src="images/414F262.jpg"><br>
-Fig. 262. RUMFORD'S SHADOW PHOTOMETER.<br>
-<br>
-<br>
-<img style="width: 634px; height: 519px;" alt=""
- src="images/414F263.jpg"><br>
-Fig. 263. RUMFORD'S SHADOW PHOTOMETER ARRANGED FOR TESTING<br>
-INCANDESCENT LAMPS.<br>
-<br>
-<br>
-415&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-A rod is supported in a vertical position. Back of it is a screen of<br>
-white paper. The two lights to be compared are arranged in front of the<br>
-rod and at a little distance from each other. They are shifted about<br>
-until the two shadows appear of equal darkness. The relative intensity<br>
-of the lights varies inversely with the square of their distances from<br>
-the shadows cast respectively by them on the screen.<br>
-<br>
-The cut, Fig. 262, shows the simplest type of the shadow photometer. In<br>
-the cut, Fig. 263, a shadow photometer for testing incandescent lamps is<br>
-shown. In it E is the lamp under trial supported by a clamp H. A is an<br>
-ampere meter in circuit with the lamp, and V is a voltmeter. A candle C<br>
-can be moved along a graduated scale G G. R is the vertical rod, and S<br>
-is the screen on which the shadows fall.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Photophore.</span><br>
-An instrument for medical examination of the cavities of the body. It<br>
-includes an incandescent lamp mounted in a tube with a concave mirror<br>
-and convex lens.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Photo-voltaic Effect.</span><br>
-The change in resistance of some substances effected by light. Selenium,<br>
-of all substances, is most susceptible to this effect. (See Selenium.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Piano, Electric.</span><br>
-A piano whose manual or key-board operates to close electric circuits,<br>
-whereby electro-magnets are caused to operate to drive the hammers<br>
-against the strings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pickle.</span><br>
-An acid solution for cleaning metal surfaces before electro-plating,<br>
-galvanizing or other deposition of metal upon them.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Picture, Electric.</span><br>
-A picture produced by passing a strong discharge through a piece of gold<br>
-leaf clamped or firmly pressed upon a sheet of paper. The gold leaf is<br>
-cut out of the desired shape, or else a stencil of paper overlays it.<br>
-The discharge dissipates the gold, and produces a purple colored<br>
-reproduction of the design upon the paper. The design is due to the<br>
-deposition of an exceedingly thin film of metallic gold.<br>
-<br>
-Synonym--Electric Portrait.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pile.</span><br>
-A galvanic or voltaic battery. It is sometimes restricted to a number of<br>
-voltaic couples connected. It should be only applied to batteries with<br>
-superimposed plates and no containing vessel such as the Dry Pile, q.<br>
-v., or Volta's Pile, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pilot Transformer.</span><br>
-In alternating current distribution a small transformer placed at any<br>
-part of the system and connected to a voltmeter in the central station,<br>
-to indicate the potential difference of the leads.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pilot Wires.</span><br>
-Wires brought from distant parts of electric light or power mains, and<br>
-leading to voltmeters at the central station, so that the potential of<br>
-distant parts of the system can be watched. The wires can be very small,<br>
-as they have but little current to transmit.<br>
-<br>
-<br>
-416&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pistol, Electric.</span><br>
-An experimental apparatus for exhibiting the power of electric<br>
-incandescence or of the electric spark. A tube is mounted with a handle<br>
-like a pistol. A plug is provided to screw in and out of its side. The<br>
-plug carries two wires connected on its inner side by a fine platinum<br>
-wire, or else disconnected but with their ends brought near together to<br>
-act as terminals for the production of a spark. To use it the tube is<br>
-filled with a mixture of air and gas, the latter either hydrogen,<br>
-hydro-carbon or other combustible gas. The tube when full is corked. The<br>
-wire is heated to incandescence by a current, or a spark is passed from<br>
-a Leyden jar or other source of electrostatic excitation. The mixture,<br>
-if properly proportioned, explodes and expels the cork violently.<br>
-<br>
-<br>
-<img style="width: 611px; height: 450px;" alt=""
- src="images/416F264.jpg"><br>
-Fig. 264. ELECTRIC PISTOL.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pith.</span><br>
-A light and soft cellular tissue forming the central core of exogenous<br>
-trees and plants. In the older parts of the tree the woody tissue often<br>
-encroaches in and partly obliterates it.<br>
-<br>
-For electrical pith-balls, the pith of the elder, of corn, or, best of<br>
-all, of sun-flower stems is used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pith-balls.</span><br>
-Ball made of pith. They are used in the construction of electroscopes<br>
-and for other experiments in static electricity.<br>
-<br>
-They are cut out with a sharp knife and their shape may be improved by<br>
-gentle rolling in the hand or between the fingers.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pivot Suspension.</span><br>
-Suspension poising or supporting of an object on a sharp pivot. This is<br>
-used for the needle in the ordinary compass. A cavity or inverted cup,<br>
-which may be made of agate, is attached to the middle of the needle<br>
-which has a hole for its reception. The centre of gravity of the needle<br>
-comes below the bottom of the cup.<br>
-<br>
-Pivot suspension is not perfect, as it has considerable friction. There<br>
-is no restitution force, as with torsion filaments.<br>
-<br>
-<br>
-417&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plant.</span><br>
-The apparatus for commercial manufacturing or technical works. An<br>
-electric lighting plant includes the boilers, engines and dynamos for<br>
-producing the current, and the electric mains and subsidiary apparatus.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Plant Electricity.</span><br>
-Electricity manifested by plant life. By means of a galvanometer<br>
-potential differences are found to exist in different parts of trees or<br>
-fruits. The roots and interior portions are negative, and the flowers,<br>
-smaller branches and fruit are positive.<br>
-<br>
-In some cases a contraction of the tissue of plants can be produced by<br>
-an electric current. The sensitive plant and others exhibit this<br>
-phenomenon, exactly analogous to the action of muscular tissue.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plate, Arrester.</span><br>
-In a lightning arrester the plate connected to the circuit. Sometimes<br>
-both plates are designated arrester plates.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plate Condenser.</span><br>
-A static condenser having a flat plate of glass for dielectric. (See<br>
-Epinus' Condenser.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plate Electrical Machine.</span><br>
-A frictional electric machine, in which a circular plate of glass is<br>
-excited by friction with the cushions. It is the most recent type of<br>
-frictional machine and has superseded the old cylinder machines. In its<br>
-turn it is superseded by influence machines, really plate machines, but<br>
-not so termed in practice.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plate, Ground.</span><br>
-In a lightning arrester, the plate connected to the earth.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plate, Negative.</span><br>
-In a voltaic battery, either primary or secondary, the plate which is<br>
-unattacked by the oxygen or negative radical or element of the fluid. It<br>
-corresponds to the carbon plate in the ordinary voltaic battery, and is<br>
-the one charged with positive electricity.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Plate, Positive.</span><br>
-In a voltaic battery, either primary or secondary, the plate which is<br>
-dissolved or attacked by the oxygen or negative radical or element of<br>
-the fluid. It is the plate corresponding to the zinc plate in the<br>
-ordinary voltaic battery, and is the one charged with negative<br>
-electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plating Balance.</span><br>
-A balance or scales to which articles in an electroplater's bath are<br>
-suspended. A weight exceeding by a known amount that of the article as<br>
-immersed overbalances the article. When the plating is being deposited<br>
-as soon as it exceeds the excess of weight of the counterpoise the<br>
-balance tips, the article descends a little, the electric circuit is<br>
-broken and the plating ceases. Thus the plating is automatically stopped<br>
-when a predetermined amount of metal is deposited.<br>
-<br>
-<br>
-418&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plating Bath.</span><br>
-A vessel of solution for the deposition of metal by electrolysis as used<br>
-in electro-plating.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plating, Electro-.</span><br>
-The deposition of metal by electrolysis so as to coat the conducting<br>
-surface of objects therewith. The full details of the many processes are<br>
-very lengthy and cannot be given here.<br>
-<br>
-The general principle includes a battery or source of electric current.<br>
-The object to be plated is connected to the negative terminal and is<br>
-immersed in the solution. Thus with a battery the object is in<br>
-electrical connection with the zinc plate. To the other terminal a<br>
-metallic plate is connected. The object and the plate termed the anode<br>
-being introduced into a suitable bath, the metal whose solution is in<br>
-the bath is deposited upon the surface of the object.<br>
-<br>
-The bath is a solution of the metal in some form that will lend itself<br>
-to the electrolytic action. The anode is often a plate of the metal of<br>
-the bath, so that it dissolves as fast as metal is deposited on the<br>
-object, thus keeping up the strength of the solution.<br>
-<br>
-The objects to be plated must be scrupulously clean, and great care must<br>
-be taken to keep the bath uncontaminated.<br>
-<br>
-When the object has a non-conducting surface, it is made conducting by<br>
-being brushed over with plumbago q.v. In addition iron dust is sometimes<br>
-dusted over it. This acts by precipitating the metal of the bath<br>
-directly and thus giving a conducting basis for the metal to deposit on.<br>
-To avoid getting iron in a bath the object may be dipped in copper<br>
-sulphate solution. This precipitates copper in place of the iron and<br>
-leaves the article in good shape for silver or other plating.<br>
-<br>
-Electro-plating, if made thick enough, gives a reverse of the article<br>
-when separated therefrom. A direct copy can be got by a second plating,<br>
-on the first plating after separation, or a wax impression can be<br>
-employed.<br>
-<br>
-Under the different metals, formulae for the baths will be found. (See<br>
-also Quicking--<br>
-Steeling--Plating Balance.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Platinoid.</span><br>
-An alloy of copper, nickel, zinc in the proportions of German silver<br>
-with 1 or 2 per cent of tungsten. It is used for resistances. It has a<br>
-specific resistance (or resistance per centimeter cube) of about 34<br>
-microhms. Its percentage variation in resistance per degree C.
-(1.8&deg; F.)<br>
-is only about .021 per cent., or less than half that of German silver.<br>
-This is its most valuable feature.<br>
-<br>
-<br>
-419&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Platinum. </span><br>
-A metal; one of the elements; symbol, Pt; atomic weight,
-197.4;<br>
-equivalent, 49.35; valency, 4; specific gravity, 21.5.<br>
-It is a conductor of electricity.<br>
-The following data refer to the annealed metal at 0&deg; C. (32&deg; F.)<br>
-<small><span style="font-family: monospace;">&nbsp; Relative Resistance
-(Silver annealed = 1),&nbsp;&nbsp; 6.022</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Specific
-Resistance,&nbsp;&nbsp; 9.057&nbsp;&nbsp; microhms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a wire,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long, weighing
-1 grain,&nbsp;&nbsp;&nbsp;&nbsp;
-2.779&nbsp;&nbsp; ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (b) 1 foot long, 1/1000
-inch thick,&nbsp;&nbsp;
-54.49&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (c) 1 meter long, weighing
-1 gram,&nbsp;&nbsp;&nbsp;&nbsp;
-1.938&nbsp;&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (d) 1 meter long, 1
-millimeter thick,&nbsp;&nbsp;
-.1153&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a 1 inch
-cube,&nbsp;&nbsp; 3.565</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Electro-chemical equivalent
-(Hydrogen = .0105),&nbsp;&nbsp; 0.5181.</span></small><br>
-<br>
-The coefficient of expansion by heat is almost the same as that of<br>
-glass. It can be passed through holes in glass and the latter can be<br>
-melted about it so as to hermetically seal its place of passage through<br>
-the glass. It is used in incandescent lamps for leading-in wires and<br>
-other similar uses.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Platinum Black.</span><br>
-Finely divided platinum. It is made by boiling a solution of platinic<br>
-chloride with excess of sodium carbonate and a quantity of sugar, until<br>
-the precipitate is perfectly black and the supernatant liquid is<br>
-colorless. It seems to possess a great power of occluding oxygen gas.<br>
-When heated to redness it becomes spongy platinum. The negative plates<br>
-of a Smee battery are coated with platinum black.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Platinum-silver Alloy.</span><br>
-An alloy of 1 part platinum and 2 parts silver, used for resistance
-coils.<br>
-<br>
-&nbsp; <small><span style="font-family: monospace;">Relative
-Resistance (silver annealed = 1 ),&nbsp;&nbsp;
-16.21&nbsp;&nbsp; microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Specific Resistance at
-0&deg;C. (32&deg; F.), &nbsp; &nbsp; &nbsp;&nbsp; 24.39</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a wire,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long, weighing
-1
-grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-4.197&nbsp;&nbsp; ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (b) 1 foot long, 1/1000
-inch diameter,&nbsp;&nbsp;
-146.70&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (c)&nbsp; 1 meter long
-weighing 1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-2.924&nbsp;&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (d) 1 meter long, 1
-millimeter diameter,&nbsp;&nbsp;
-0.3106&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a 1 inch
-cube,&nbsp;&nbsp; 9.603&nbsp;&nbsp;
-microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Percentage Variation per
-degree C. (1.8&deg; F.)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp; at about
-20&deg; C. (68&deg; F.), 0.031 per cent.</span></small><br>
-<br>
-Synonym--Platinum Alloy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Platinum Sponge.</span><br>
-Finely divided platinum obtained by igniting platinum black, q.v., and<br>
-also by igniting salts of platinum. It has considerable power of<br>
-condensing or occluding oxygen. It will, if in good condition, set fire<br>
-to a jet of hydrogen impinging upon it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plow.</span><br>
-Contact arms projecting downwards from the motors, trucks, or bodies of<br>
-electric street cars, which enter the underground conduit through the<br>
-slot and carry contact pieces or brushes, to take the current for<br>
-driving the motors from the leads within the conduit.<br>
-<br>
-<br>
-420&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pl&uuml;cker Tubes.</span><br>
-A special form of Geissler tube designed for the production of<br>
-stratification and for observing the effects produced in the space<br>
-surrounding the negative electrode.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plug.</span><br>
-(a) A piece of metal with a handle and a somewhat tapered end, used to<br>
-make connections by insertions between two plates or blocks of metal<br>
-slightly separated and with grooves to receive it.<br>
-<br>
-(b) A plug or wedge with two metallic faces, insulated from each other<br>
-with a separate wire connected to each one. It is used in spring-jacks<br>
-q. v., to introduce a loop in a circuit.<br>
-<br>
-Synonym--Wedge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plug. v.</span><br>
-To connect by inserting a plug, as in a resistance box.<br>
-<br>
-<br>
-<img style="width: 504px; height: 552px;" alt=""
- src="images/420F265.jpg"><br>
-Fig. 265. PLUGS FOR RESISTANCE COIL BOX.<br>
-<br>
-<br>
-<img style="width: 277px; height: 289px;" alt=""
- src="images/420F266.jpg"><br>
-Fig. 266. PLUG SWITCH.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Plug, Double.</span><br>
-A spring-jack plug or wedge with two pairs of insulated faces, one<br>
-behind the other, so as to simultaneously introduce two loops into a<br>
-circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plug, Grid.</span><br>
-A piece or mass of lead oxide, inserted into the holes in the lead<br>
-plates of storage batteries. The holes are often dovetailed or of uneven<br>
-section to better retain the plugs.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plug Infinity.</span><br>
-In a box-bridge or resistance box, a plug whose removal from between two<br>
-disconnected discs opens the circuit. All the other discs are connected<br>
-by resistance coils of various resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plug Switch.</span><br>
-A switch composed of two contact blocks, not touching each other and<br>
-brought into electrical connection by the insertion of a metallic plug.<br>
-The latter is usually provided with an insulating handle, and a seat is<br>
-reamed out for it in the two faces of the contact blocks.<br>
-<br>
-<br>
-421&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Plumbago.</span><br>
-Soft lustrous graphite, a native form of carbon; sometimes chemically<br>
-purified. It is used in electro-plating to give a conducting surface to<br>
-non-conducting objects, such as wax moulds. The surface, after coating<br>
-with plumbago, is sometimes dusted over with iron dust, which<br>
-precipitates the metal of the bath and starts the plating. It is<br>
-sometimes plated with copper, silver or gold, and is then termed<br>
-coppered, silvered, or gilt plumbago. It is gilded by moistening with<br>
-etherial solution of gold chloride and exposing to the air, and drying<br>
-and igniting.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Plunger.</span><br>
-A movable core which is used in connection with a so-called solenoid<br>
-coil, to be drawn in when the coil is excited. (See Coil and Plunger.)<br>
-<br>
-<br>
-<img style="width: 224px; height: 668px;" alt=""
- src="images/421F267.jpg"><br>
-Fig. 267 COIL AND PLUNGER WITH <br>
-SCALES TO SHOW ATTRACTION.<br>
-<br>
-<br>
-<span style="font-weight: bold;">P. O.</span><br>
-Abbreviation for Post Office, q.v.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Poggendorf's Solution.</span><br>
-An acid depolarizing and exciting fluid for zinc-carbon batteries. The<br>
-following is its formula: Water, 100 parts; potassium bichromate, 12<br>
-parts; concentrated sulphuric acid, 25 parts. All parts by weight. Use<br>
-cold.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Point, Neutral.</span><br>
-(a) On a commutator of a dynamo the points at the ends of the diameter<br>
-of commutation, or where the brushes rest upon the surface of the<br>
-commutator, are termed neutral points. At these points there is no<br>
-generation of potential, they marking the union of currents of opposite<br>
-direction flowing from the two sides of the armature into the brushes.<br>
-<br>
-(b) In electro-therapeutics, a place in the intra-polar region of a<br>
-nerve so situated with reference to the kathode and electrode as applied<br>
-in treatment, that its condition is unaffected.<br>
-<br>
-Synonym--Indifferent Point.<br>
-<br>
-(c) In a magnet the point of no attraction, situated between the two<br>
-poles, at about an equal distance from each, so as to mark the centre of<br>
-a magnet of even distribution of polarity.<br>
-<br>
-(d) In thermo-electricity the point of temperature where the<br>
-thermo-electric powers of two metals are zero; in a diagram the point<br>
-where the lines representing their thermo-electric relations cross each<br>
-other; if the metals are arranged in a thermo-electric couple, one end<br>
-at a temperature a given amount above, the other at a temperature the<br>
-same amount below the neutral point, no current or potential difference<br>
-will be produced.<br>
-<br>
-<br>
-422&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Point, Null.</span><br>
-A nodal point in electrical resonators; a point where in a system of<br>
-waves or oscillations, there is rest, the zero of motion being the<br>
-resultant of oppositely directed and equal forces. In electrical<br>
-resonators it is to be sought for in a point symmetrically situated,<br>
-with reference to the spark gap, or in a pair of points, which pair is<br>
-symmetrically placed.<br>
-<br>
-The null point in resonators is found by connecting a lead from one of<br>
-the secondary terminals of an induction coil to different parts of the<br>
-resonator. The null point is one where the connection does not give rise<br>
-to any sparks between the micrometer knobs or spark gap, or where the<br>
-sparks are of diminished size.<br>
-<br>
-The whole is exactly comparable to loops and nodes in a vibrating string<br>
-or in a Chladni plate as described in treatises on sound and acoustics.<br>
-(See Resonance, Electrical--Resonator, Electrical.)<br>
-<br>
-Synonym--Nodal Point.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Point Poles.</span><br>
-Magnet poles that are virtually points, or of no magnitude. A long thin<br>
-magnet with little leakage except close to the ends may be supposed to<br>
-have point poles within itself a short distance back from the ends.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Points, Consequent.</span><br>
-In a magnet with consequent poles, the points where such poles are<br>
-situated.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Points, Corresponding.</span><br>
-In bound electrostatic charges the points of equal charges of opposite<br>
-potentials; the points at opposite extremities of electrostatic lines of<br>
-force. This definition implies that the bound charges shall be on equal<br>
-facing areas of conductors, as otherwise the spread or concentration of<br>
-the lines of force would necessitate the use of areas of size<br>
-proportionate to the spreading or concentrating of the lines of force.<br>
-At the same time it may figuratively be applied to these cases, the<br>
-penetration of the surface by a single line of force including the area<br>
-fixed by its relation to the surrounding lines.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Points, Isoelectric.</span><br>
-In electro-therapeutics, points of equal potential in a circuit.<br>
-<br>
-<br>
-423&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Points of Derivation.</span><br>
-The point where a single conductor branches into two or more conductors,<br>
-operating or acting in parallel with each other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polar Angle.</span><br>
-The angle subtended by one of the faces of the pole pieces of the field-<br>
-magnet of a dynamo or motor. The centre of the circle of the angle lies<br>
-in the axis of the armature.<br>
-<br>
-Synonym--Angle of Polar Span.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polar Extension.</span><br>
-An addition made of iron to the poles of magnets. Various forms have<br>
-been experimented with. The pole pieces of dynamo field magnets are<br>
-polar extensions.<br>
-<br>
-Synonyms--Pole Piece--Polar Tips.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polarity, Diamagnetic.</span><br>
-The induced polarity of diamagnetic substances; it is the reverse of<br>
-paramagnetic polarity, or of the polarity of iron. A bar of diamagnetic<br>
-material held parallel with the lines of force in a magnetic field has a<br>
-like pole induced in the end nearest a given pole of the field magnet,<br>
-and vice versa. This theory accounts for the repulsion by a magnet of a<br>
-diamagnetic substance. The existence of this polarity is rather an<br>
-assumption. It originated with Faraday.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polarity, Paramagnetic.</span><br>
-The induced polarity of paramagnetic substances, such as iron, nickel,<br>
-or cobalt.<br>
-<br>
-When such a substance is brought into a magnetic field the part nearest<br>
-a specific pole of a magnet acquires polarity opposite to that of such<br>
-pole and is thereby attracted.<br>
-<br>
-Another way of expressing it, in which the existence of a pole in or<br>
-near to the field is not implied, is founded on the conventional<br>
-direction of lines of force. Where these enter the substance a south<br>
-pole is formed and where they emerge a north pole is formed.<br>
-<br>
-Such polarity tends always to be established in the direction of<br>
-greatest length, if the body is free to rotate.<br>
-<br>
-<br>
-424&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polarization.</span><br>
-(a) The depriving of a voltaic cell of its proper electro-motive force.<br>
-Polarization may be due to various causes. The solution may become<br>
-exhausted, as in a Smee battery, when the acid is saturated with zinc<br>
-and thus a species of polarization follows. But the best definition of<br>
-polarization restricts it to the development of counter-electro-motive<br>
-force in the battery by the accumulation of hydrogen on the negative<br>
-(carbon or copper) plate. To overcome this difficulty many methods are<br>
-employed. Oxidizing solutions or solids are used, such as solution of<br>
-chromic acid or powdered manganese dioxide, as in the Bunsen and<br>
-Leclanch&eacute; batteries respectively; a roughened surface of
-platinum black<br>
-is used, as in the Smee battery; air is blown through the solution to<br>
-carry off the hydrogen, or the plates themselves are moved about in the<br>
-solution.<br>
-<br>
-(b) Imparting magnetization to a bar of iron or steel, thus making a<br>
-permanent magnet, is the polarization of the steel of which it is made.<br>
-Polarization may be permanent, as in steel, or only temporary, as in<br>
-soft iron.<br>
-<br>
-(c) The strain upon a dielectric when it separates two oppositely<br>
-charged surfaces. The secondary discharge of a Leyden jar, and its<br>
-alteration in volume testify to the strain put upon it by charging.<br>
-<br>
-(d) The alteration of arrangement of the molecules of an electrolyte by<br>
-a decomposing current. All the molecules are supposed to be arranged<br>
-with like ends pointing in the same direction, positive ends facing the<br>
-positively-charged plate and negative ends the negatively-charged one.<br>
-<br>
-(e) The production of counter-electro-motive force in a secondary<br>
-battery, or in any combination capable of acting as the seat of such<br>
-counter-electro-motive force. (See Battery, Secondary--Battery, Gas.)<br>
-The same can be found often in organized cellular tissue such as that of<br>
-muscles, nerves, or of plants. If a current is passed through this in<br>
-one direction, it often establishes a polarization or potential<br>
-difference that is susceptible of giving a return current in the<br>
-opposite direction when the charging battery is replaced by a conductor.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polarization Capacity.</span><br>
-A voltaic cell in use becomes polarized by its negative plate<br>
-accumulating hydrogen, or other cause. This gradually gives the plate a<br>
-positive value, or goes to set up a counter-electro-motive force. The<br>
-quantity of electricity required to produce the polarization of a<br>
-battery is termed its Polarization Capacity or Capacity of Polarization.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polarization of the Medium.</span><br>
-The dielectric polarization, q. v., of a dielectric, implying the<br>
-arrangement of its molecules in chains or filaments; a term due to<br>
-Faraday. He illustrated it by placing filaments of silk in spirits of<br>
-turpentine, and introduced into the liquid two conductors. On<br>
-electrifying one and grounding (or connecting to earth) the other one,<br>
-the silk filaments arranged themselves in a chain or string connecting<br>
-the points of the conductors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polar Region.</span><br>
-That part of the surface of a magnet whence the internal magnetic lines<br>
-emerge into the air. (S. P. Thompson.) As such lines may emerge from<br>
-virtually all parts of its surface, the polar regions are indefinite<br>
-areas, and are properly restricted to the parts whence the lines emerge<br>
-in greatest quantity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Polar Span.</span><br>
-A proportion of the circle which represents the transverse section of<br>
-the armature space between the pole pieces of the field magnet in a<br>
-dynamo or motor; it is the proportion which is filled by the faces of<br>
-the pole pieces.<br>
-<br>
-<br>
-425&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole, Analogous.</span><br>
-The end of a crystal of a pyroelectric substance, such as tourmaline,<br>
-which end when heated become positively electrified. On reduction of<br>
-temperature the reverse effect obtains.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole, Antilogous.</span><br>
-The end of a crystal of a pyroelectric substance, such as tourmaline,<br>
-which end, while increasing in temperature, becomes negatively<br>
-electrified. During reduction of its temperature the reverse effect<br>
-obtains.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole Changer.</span><br>
-(a) An automatic oscillating or vibrating switch or contact-breaker<br>
-which in each movement reverses the direction of a current from a<br>
-battery or other source of current of fixed direction, as such current<br>
-goes through a conductor.<br>
-<br>
-(b) A switch moved by hand which for each movement effects the above<br>
-result.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole, Negative.</span><br>
-(a) In a magnet the south pole; the pole into which the lines of force<br>
-are assumed to enter from the air or outer circuit.<br>
-<br>
-(b) In a current generator the pole or terminal into which the current<br>
-is assumed to flow from the external circuit. It is the negatively<br>
-charged terminal and in the ordinary voltaic battery is the terminal<br>
-connected to the zinc or positive plate.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole Pieces.</span><br>
-The terminations of the cores of field or other electro-magnets, or of<br>
-permanent magnets. These terminations are variously shaped, sometimes<br>
-being quite large compared to the core proper of the magnet.<br>
-<br>
-They are calculated so as to produce a proper distribution of and<br>
-direction of the lines of force from pole to pole. As a general rule the<br>
-active field should be of uniform strength and the pole pieces may be of<br>
-contour calculated to attain this end.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole, Positive.</span><br>
-(a) In a magnet the north pole; the pole from which lines of force are<br>
-assumed to emerge into the air.<br>
-<br>
-(b) In a current generator the pole or terminal whence the current is<br>
-assumed to issue into the outer circuit. It is the positively charged<br>
-terminal, and in the ordinary voltaic battery is the terminal connected<br>
-to the copper or carbon plate, termed the negative plate.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Poles.</span><br>
-(a) The terminals of an open electric circuit, at which there<br>
-necessarily exists a potential difference, produced by the generator or<br>
-source of electro-motive force in the circuit.<br>
-<br>
-(b) The terminals of an open magnetic circuit; the ends of a magnetized<br>
-mass of steel, iron or other paramagnetic substance.<br>
-<br>
-(c) The ends in general of any body or mass which show electric or<br>
-magnetic properties more developed than those of the central sections of<br>
-the body.<br>
-<br>
-<br>
-426&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole, Salient.</span><br>
-In dynamo and motor field magnets, salient poles are those projecting<br>
-from the base or main body of the field magnet, as distinguished from<br>
-consequent poles formed by coils wound on the main body itself.<br>
-<br>
-<br>
-<img style="width: 615px; height: 644px;" alt=""
- src="images/426F268.jpg"><br>
-Fig. 268. SALIENT POLES OF FIELD MAGNET.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Poles, Compensating.</span><br>
-A device for avoiding the cross-magnetizing effect on the commutator<br>
-core due to the lead of the brushes. It consists in maintaining a small<br>
-bar electro-magnet perpendicularly between the pole pieces. This<br>
-compensates the cross-magnetizing effect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Poles of Intensity.</span><br>
-The locus of highest magnetic force on the earth's surface. One such<br>
-pole is in Siberia, another is about lat. 52&deg; N., long. 92&deg; W.<br>
-<br>
-[Transcriber's note: 52&deg; N., long. 92&deg; W is about 250 miles
-Northeast of<br>
-Winnipeg.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Poles of Verticity.</span><br>
-The magnetic poles of the earth. (See Magnetic Poles.)<br>
-<br>
-<span style="font-weight: bold;">Pole Tips.</span><br>
-The extreme ends of the expanded poles of a field magnet. In some<br>
-machines some of the pole tips are made of cast iron, to alter the<br>
-distribution of the lines of force and resulting magnetic pull upon the<br>
-armatures. This is done to take off the weight of the armature from its<br>
-bearings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pole, Traveling.</span><br>
-A term applied to the poles produced in the action of a rotatory field,<br>
-whose poles constantly rotate around the circle of the field. (See<br>
-Field, Rotatory.)<br>
-<br>
-<br>
-417&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Porous Cup.</span><br>
-A cup of pipe clay, unglazed earthenware or other equivalent material<br>
-used in voltaic cells to keep two liquids separate and yet to permit<br>
-electrolysis and electrolytic conduction.<br>
-<br>
-They are necessarily only an expedient, as their porous nature permits<br>
-considerable diffusion, and were they not porous electrolytic action<br>
-would be impossible.<br>
-<br>
-Synonym--Porous Cell.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Porret's Phenomenon.</span><br>
-In electro-physiology, an increase in the diameter of a nerve produced<br>
-by the positive pole of a voltaic circuit, when placed in contact with<br>
-the tissue and near to the nerve in question, the other pole being<br>
-connected to a more or less remote part of the body.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Portelectric Railroad.</span><br>
-A railroad worked by solenoidal attraction, the car forming the core of<br>
-the solenoids. It includes a series of solenoids or hollow coils of<br>
-copper wire distributed all along the road and inclosing within<br>
-themselves the track. On this a cylindrical car with pointed ends moves<br>
-on wheels. Current is supplied to the solenoid in advance of the car,<br>
-and attracts it. As it advances it breaks the contacts of the attracting<br>
-solenoid and turns the current into the one next in advance. This<br>
-operation is repeated as the car advances.<br>
-<br>
-The solenoids are placed close together, each including in the trial<br>
-track 630 turns of No. 14 copper wire. The car was of wrought iron, 12<br>
-feet long, 10 inches in diameter and weighing 500 lbs. It was proposed<br>
-to employ the system for transportation of mail matter and similar uses.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Position Finder.</span><br>
-An instrument for determining the position of objects which are to be<br>
-fired at from forts. It is designed for use from forts situated on the<br>
-water.<br>
-<br>
-Fiske's position finder may be thus generally described. On a chart the<br>
-channel is divided into squares, and the position finder determines the<br>
-square in which a vessel lies. For each square the direction and<br>
-elevation of the guns is calculated beforehand. The enemy can therefore<br>
-be continuously located and fired at, although from smoke or other cause<br>
-the object may be quite invisible to the gunner.<br>
-<br>
-It comprises two telescopes situated at distant extremities of as long a<br>
-base line as is obtainable. These telescopes are kept directed upon the<br>
-object by two observers simultaneously. The observers are in constant<br>
-telephonic communication. As each telescope moves, it carries a contact<br>
-over an arc of conducting material. Below each telescope is an arm also<br>
-moving over an arc of conducting material. These arcs enter into a<br>
-Wheatstone bridge and are so connected that when the arm and the distant<br>
-telescope are at the same angle or parallel a balance is obtained. Thus<br>
-each observer has the power of establishing a balance. A chart is<br>
-provided for each of them, and over it the arm connected with the<br>
-distant telescope and an arm or indicator attached to the telescope at<br>
-that station move so that as long as both telescopes point at the object<br>
-and each observer maintains the electric balance, the intersection of<br>
-the arms shows the position on the chart.<br>
-<br>
-The Position Finder is a simplification and amplification of the Range<br>
-Finder, q. v. In practice the observers may be placed far from the<br>
-forts, and may telephone their observations thereto. It has been found<br>
-accurate within one-third of one per cent.<br>
-<br>
-<br>
-428&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Positive Direction.</span><br>
-The direction which lines of force are assumed to take in the air or<br>
-outer circuit from a positive to a negative region. It applies to<br>
-electrostatic, to magnetic and to electro-magnetic lines of force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Positive Electricity.</span><br>
-The kind of electricity with which a piece of glass is charged when<br>
-rubbed with silk; vitreous electricity.<br>
-<br>
-In a galvanic cell the surface of the copper or carbon plate is charged<br>
-with positive electricity. (See Electrostatic Series.)<br>
-<br>
-According to the single fluid theory positive electrification consists<br>
-in a surplus of electricity.<br>
-<br>
-[Transcriber's note: "Positive electricity" is a deficiency of
-electrons.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Post Office. adj.</span><br>
-Many pieces of electric apparatus of English manufacture are thus<br>
-qualified, indicating that they are of the pattern of the apparatus used<br>
-by the British Post Office in its telegraph department.<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Potential.</span><br>
-Potential in general may be treated as an attribute of a point in space,<br>
-and may express the potential energy which a unit mass would have if<br>
-placed at that point.<br>
-<br>
-This conception of potential is that of a property attributable to a<br>
-point in space, such that if a unit mass were placed there the forces<br>
-acting upon it would supply the force factor of energy, while the body<br>
-would supply the mass factor. This property is expressible in units,<br>
-which produce, if the supposed mass is a unit mass, units of work or<br>
-energy, but potential itself is neither.<br>
-<br>
-Thus taking gravitation, a pound mass on the surface of the earth<br>
-(assuming it to be a sphere of 4,000 miles radius) would require the<br>
-expenditure of 21,120,000 foot pounds to remove it to an infinite<br>
-distance against gravity. The potential of a point in space upon the<br>
-surface of the earth is therefore negative and is represented by<br>
--21,120,000*32.2 foot poundals (32.2 = acceleration of gravity). (See<br>
-Poundal.) In practice and conventionally all points on the earth's<br>
-surface are taken as of zero potential.<br>
-<br>
-[Transcriber's note; 21,120,000 foot pounds is about 8 KWh.]<br>
-<br>
-<br>
-429&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Absolute.</span><br>
-The absolute electrical potential at a point possesses a numerical value<br>
-and measures the tendency which the existing electric forces would have<br>
-to drive an electrified particle away from or prevent its approach to<br>
-the point, if such a particle, one unit in quantity, were brought up to<br>
-or were situated at that point. It is numerically equal to the number of<br>
-ergs of work which must be done to bring a positive unit of electricity<br>
-from a region where there is absolutely no electric force up to the<br>
-point in question. (Daniell.) Two suppositions are included in this. The<br>
-region where there is an electric force has to be and only can be at an<br>
-infinite distance from all electrified bodies. The moving of the<br>
-particle must take place without any effect upon the distribution of<br>
-electricity on other particles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Constant.</span><br>
-Unchanging potential or potential difference.<br>
-<br>
-The ordinary system of incandescent lighting is a constant potential<br>
-system, an unvarying potential difference being maintained between the<br>
-two leads, and the current varying according to requirements.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential Difference, Electric.</span><br>
-If of any two points the absolute potentials are determined, the<br>
-difference between such two expresses the potential difference.<br>
-Numerically it expresses the quantity of work which must be done to<br>
-remove a unit of electricity from one to the other against electric<br>
-repulsion, or the energy which would be accumulated in moving it the<br>
-other way.<br>
-<br>
-A positively charged particle is driven towards the point of lower<br>
-potential. A negatively charged body is driven in the reverse direction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential Difference, Electro-motive.</span><br>
-A difference of potential in a circuit, or in part of a circuit, which<br>
-difference produces or is capable of producing a current, or is due to<br>
-the flow of such current.<br>
-<br>
-It may be expressed as the fall in potential or the electro-motive force<br>
-included between any two points on a circuit. The current in an active<br>
-circuit is due to the total electro-motive force in the circuit. This is<br>
-distributed through the circuit in proportion to the resistance of its<br>
-parts. Owing to the distribution of electro-motive force throughout a<br>
-circuit including the generator, the terminals of a generator on closed<br>
-circuit may show a difference of potential far lower than the<br>
-electro-motive force of the generator on closed circuit. Hence potential<br>
-difference in such a case has been termed available electro-motive<br>
-force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Electric Absolute.</span><br>
-The mathematical expression of a property of a point in space, measuring<br>
-the tendency which existing electric forces would have to drive an<br>
-electrified unit particle away from or prevent its approach to the point<br>
-in question, according to whether the point was situated at or was at a<br>
-distance from the point in question.<br>
-<br>
-Potential is not the power of doing work, although, as it is expressed<br>
-always with reference to a unit body, it is numerically equal to the<br>
-number of ergs of work which must be done in order to bring a positive<br>
-unit of electricity from a region where there is no electric<br>
-force--which is a region at an infinite distance from all electrified<br>
-bodies--up to the point in question. This includes the assumption that<br>
-there is no alteration in the general distribution of electricity on<br>
-neighboring bodies. (Daniell.)<br>
-<br>
-In practice the earth is arbitrarily taken as of zero electric
-potential.<br>
-<br>
-<br>
-430&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Fall of.</span><br>
-The change in potential between any two points on an active circuit. The<br>
-change in potential due to the maintenance of a current through a<br>
-conductor.<br>
-<br>
-The fall in potential multiplied by the current gives work or energy<br>
-units.<br>
-<br>
-The fall of potential in a circuit and its subsequent raising by the<br>
-action of the generator is illustrated by the diagram of a helix. In it<br>
-the potential fall in the outer circuit is shown by the descent of the<br>
-helix. This represents at once the outer circuit and the fall of<br>
-potential in it. The vertical axis represents the portion of the circuit<br>
-within the battery or generator in which the potential by the action of<br>
-the generator is again raised to its original height.<br>
-<br>
-In a circuit of even resistance the potential falls evenly throughout<br>
-it.<br>
-<br>
-A mechanical illustration of the relation of fall of potential to<br>
-current is shown in the cut Fig. 269. A vertical wire is supposed to be<br>
-fixed at its upper end and a lever arm and cord at its lower end, with<br>
-weight and pulley imparts a torsional strain to it. The dials and<br>
-indexes show a uniform twisting corresponding to fall of potential. For<br>
-each unit of length there is a definite loss of twisting, corresponding<br>
-to fall of potential in a unit of length of a conductor of uniform<br>
-resistance. The total twisting represents the total potential<br>
-difference. The weight sustained by the twisting represents the current<br>
-maintained by the potential difference. For a shorter wire less twisting<br>
-would be needed to sustain the weight, as in a shorter piece of the<br>
-conductor less potential difference would be needed to maintain the same<br>
-current.<br>
-<br>
-<br>
-<img style="width: 224px; height: 830px;" alt=""
- src="images/430F269.jpg"><br>
-Fig. 269. MECHANICAL ILLUSTRATION OF <br>
-FALL OF POTENTIAL AND CURRENT STRENGTH.<br>
-<br>
-<br>
-431&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 639px; height: 296px;" alt=""
- src="images/431F270.jpg"><br>
-Fig. 270. ILLUSTRATION OF THE FALL AND <br>
-REDEVELOPMENT OF POTENTIAL IN AN ELECTRIC CIRCUIT.<br>
-<br>
-<br>
-The fall of potential in a circuit in portions of it is proportional to<br>
-the resistance of the portions in question. This is shown in the<br>
-diagram. The narrow lines indicate high and the broad lines low<br>
-resistance. The fall in different portions is shown as proportional to<br>
-the resistance of each portion.<br>
-<br>
-<br>
-<img style="width: 682px; height: 297px;" alt=""
- src="images/431F271.jpg"><br>
-Fig. 271. DIAGRAM OF FALL OF POTENTIAL IN A <br>
-CONDUCTOR OF UNEVEN RESISTANCE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Magnetic.</span><br>
-The magnetic potential at any point of a magnetic field expresses the<br>
-work which would be done by the magnetic forces of the field on a<br>
-positive unit of magnetism as it moves from that point to an infinite<br>
-distance therefrom. The converse applies to a negative unit.<br>
-<br>
-It is the exact analogue of absolute electric potential.<br>
-<br>
-The potential at any point due to a positive pole m at a distance r is<br>
-m/r;. that due to a negative pole - m at a distance r' is equal to<br>
--m/r';. that due to both is equal to m/r - m/r' or m(1/r - 1/r').<br>
-<br>
-Like electric potential and potential in general, magnetic potential<br>
-while numerically expressing work or energy is neither, although often<br>
-defined as such.<br>
-<br>
-<br>
-432&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Negative.</span><br>
-The reverse of positive potential. (See Potential, Positive.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Positive.</span><br>
-In general the higher potential. Taking the assumed direction of lines<br>
-of force, they are assumed to be directed or to move from regions of<br>
-positive to regions of negative potential. The copper or carbon plate of<br>
-a voltaic battery is at positive potential compared to the zinc plate.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Unit of Electric.</span><br>
-The arbitrary or conventional potential--or briefly, the potential of a<br>
-point in an electric field of force--is, numerically, the number of ergs<br>
-of work necessary to bring a unit of electricity up to the point in<br>
-question from a region of nominal zero potential--i. e., from the<br>
-surface of the earth. (Daniell.) This would give the erg as the unit of<br>
-potential.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potential, Zero.</span><br>
-The potential of the earth is arbitrarily taken as the zero of electric<br>
-potential.<br>
-<br>
-The theoretical zero is the potential of a point infinitely distant from<br>
-all electrified bodies.<br>
-<br>
-<br>
-<img style="width: 640px; height: 272px;" alt=""
- src="images/432F272.jpg"><br>
-Fig. 272. DIAGRAM OF POTENTIOMETER CONNECTIONS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Potentiometer.</span><br>
-An arrangement somewhat similar to the Wheatstone Bridge for determining<br>
-potential difference, or the electro-motive force of a battery. In<br>
-general principle connection is made so that the cell under trial would<br>
-send a current in one direction through the galvanometer. Another<br>
-battery is connected, and in shunt with its circuit the battery under<br>
-trial and its galvanometer are connected, but so that its current is in<br>
-opposition. By a graduated wire, like that of a meter bridge, the<br>
-potential of the main battery shunt can be varied until no current<br>
-passes. This gives the outline of the method only.<br>
-<br>
-<br>
-433&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-In the cut A B is the graduated potentiometer wire through which a<br>
-current is passed in the direction of the arrow. E is the battery under<br>
-trial, placed in opposition to the other current, with a galvanometer<br>
-next it. Under the conditions shown, if the galvanometer showed no<br>
-deflection, the E. M. F. of the battery would be to the E. M. F. between<br>
-the ends of the potentiometer wire, 1 . . . . .10, as 1.5 the distance<br>
-between the points of connection, A and D of the battery circuit, is to<br>
-10, the full length of the potentiometer wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Poundal.</span><br>
-The British unit of force; the force which acting on a mass of one pound<br>
-for one second produces an acceleration of one foot.<br>
-<br>
-[Transcriber's note: The force which acting on a mass of one pound<br>
-produces an acceleration of ONE FOOT PER SECOND PER SECOND.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Power. Activity;</span><br>
-the rate of activity, of doing work, or of expending energy. The<br>
-practical unit of electric power is the volt-ampere or watt, equal to<br>
-1E7 ergs per second. The kilowatt, one thousand watts or volt-amperes,<br>
-is a frequently adopted unit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Power, Electric.</span><br>
-As energy is the capacity for doing work, electric energy is
-represented <br>
-by electricity in motion against a resistance. This possesses a species
-<br>
-of inertia, which gives it a species of kinetic energy. To produce such
-<br>
-motion, electro- motive force is required. The product of E. M. F. by <br>
-quantity is therefore electric energy. (See Energy, Electric.)<br>
-<br>
-Generally the rate of energy or power is used. Its dimensions are<br>
-&nbsp;( ( (M^.5)*(L^.5) ) / T )&nbsp; *&nbsp;&nbsp; ( ( (M^.5) *(L^1.5)
-)/( T^2) )<br>
-&nbsp;(intensity or current rate)&nbsp;&nbsp; *&nbsp;&nbsp;
-(electro-motive force or potential)<br>
-&nbsp; = (M * (L^2) ) / (T^3),<br>
-which are the dimensions of rate of work or activity. The practical unit<br>
-of electric rate of energy or activity is the volt-ampere or watt. By<br>
-Ohm's law, q. v., we have C = E/R (C = current; E = potential difference<br>
-or electro-motive force; R = resistance.) The watt by definition = C*E.<br>
-By substitution from Ohm's formula we deduce for it the following<br>
-values: ((C^2) * R) and ((E^2) /R). From these three expressions the<br>
-relations of electric energy to E.M.F., Resistance, and Current can be<br>
-deduced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Power of Periodic Current.</span><br>
-The rate of energy in a circuit carrying a periodic current. In such a<br>
-circuit the electro-motive force travels in advance of the current it<br>
-produces on the circuit. Consequently at phases or intervals where,<br>
-owing to the alternations of the current, the current is at zero, the<br>
-electro-motive force may be quite high. At any time the energy rate is<br>
-the product of the electro-motive force by the amperage. To obtain the<br>
-power or average rate of energy, the product of the maximum<br>
-electro-motive force and maximum current must be divided by two and<br>
-multiplied by the cosine of the angle of lag, which is the angle<br>
-expressing the difference of phase.<br>
-<br>
-[Transcriber's note; The voltage phase will lead if the load is<br>
-inductive. The current phase will lead if the load is capacitive.<br>
-Capacitors or inductors may be introduced into power lines to correct<br>
-the phase offset introduced by customer loads.]<br>
-<br>
-<br>
-434&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pressel.</span><br>
-A press-button often contained in a pear-shaped handle, arranged for<br>
-attachment to the end of a flexible conductor, so as to hang thereby. By<br>
-pressing the button a bell may be rung, or a distant lamp may be<br>
-lighted.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pressure.</span><br>
-Force or stress exerted directly against any surface. Its dimensions are<br>
-force/area or ((M*L)/(T^2)) / (L^2) = M/(L* (T^2)).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pressure, Electric.</span><br>
-Electro-motive force or potential difference; voltage. An expression of<br>
-metaphorical nature, as the term is not accurate.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pressure, Electrification by.</span><br>
-A crystal of Iceland spar (calcium carbonate) pressed between the<br>
-fingers becomes positively electrified and remains so for some time.<br>
-Other minerals act in a similar way. Dissimilar substances pressed<br>
-together and suddenly separated carry off opposite charges. This is<br>
-really contact action, not pressure action.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Primary.</span><br>
-A term used to designate the inducing coil in an induction coil or<br>
-transformer; it is probably an abbreviation for primary coil.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Primary Battery.</span><br>
-A voltaic cell or battery generating electric energy by direct<br>
-consumption of material, and not regenerated by an electrolytic process.<br>
-<br>
-The ordinary voltaic cell or galvanic battery is a primary battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Prime. vb.</span><br>
-To impart the first charge to one of the armatures of a Holtz or other<br>
-influence machine.<br>
-<br>
-<br>
-<img style="width: 662px; height: 468px;" alt=""
- src="images/434F273.jpg"><br>
-Fig. 273. PRIME CONDUCTOR AND PROOF PLANE.<br>
-<br>
-<br>
-435&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Prime Conductor.</span><br>
-A metal or metal coated sphere or cylinder or other solid with rounded<br>
-ends mounted on insulating supports and used to collect electricity as<br>
-generated by a frictional electric machine.<br>
-<br>
-According to whether the prime conductor or the cushions are grounded<br>
-positive or negative electricity is taken from the ungrounded part.<br>
-Generally the cushions are grounded, and the prime conductor yields<br>
-positive electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Probe, Electric.</span><br>
-A surgeon's probe, designed to indicate by the closing of an electric<br>
-circuit the presence of a bullet or metallic body in the body of a<br>
-patient.<br>
-<br>
-Two insulated wires are carried to the end where their ends are exposed,<br>
-still insulated from each other. In probing a wound for a bullet if the<br>
-two ends touch it the circuit is closed and a bell rings. If a bone is<br>
-touched no such effect is produced. The wires are in circuit with an<br>
-electric bell and battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Projecting Power of a Magnet.</span><br>
-The power of projecting its lines of force straight out from the poles.<br>
-This is really a matter of magnetic power, rather than of shape of the<br>
-magnet. In electromagnets the custom was followed by making them long to<br>
-get this effect. Such length was really useful in the regard of getting<br>
-room for a sufficient number of ampere turns.<br>
-<br>
-<br>
-436&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 589px; height: 371px;" alt=""
- src="images/435F274.jpg"><br>
-Fig. 274. PRONY BRAKE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Prony Brake.</span><br>
-A device for measuring the power applied to a rotating shaft. It<br>
-consists of a clamping device to be applied more or less rigidly to the<br>
-shaft or to a pulley upon it. To the clamp is attached a lever carrying<br>
-a weight. The cut shows a simple arrangement, the shaft A carries a<br>
-pulley B to which the clamp B1 B2 is applied. The nuts C1 C2 are used<br>
-for adjustment.<br>
-<br>
-A weight is placed in the pan E attached to the end of the lever D. The<br>
-weight and clamp are so adjusted that the lever shall stand horizontally<br>
-as shown by the index E. If we call r the radius of the pulley and F the<br>
-friction between its surface and the clamp, it is evident that r F, the<br>
-moment of resistance to the motion of the pulley, is equal to the weight<br>
-multiplied by its lever arm or to W*R, where W indicates the weight and<br>
-R the distance of its point of application from the centre of the pulley<br>
-or r*F = R*W. The work represented by this friction is equal to the<br>
-distance traveled by the surface of the wheel multiplied by the<br>
-frictional resistance, or is 2*PI*r*n*F, in which n is the number of<br>
-turns per minute. But this is equal to 2*PI*R*W. These data being known,<br>
-the power is directly calculated therefrom in terms of weight and feet<br>
-per minute.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Proof-plane.</span><br>
-A small conductor, usually disc shaped, carried at the end of an<br>
-insulating handle. It is used to collect electricity by contact, from<br>
-objects electrostatically charged. The charge it has received is then<br>
-measured (see Torsion Balance) or otherwise tested. (See Prime<br>
-Conductor.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Proof-sphere.</span><br>
-A small sphere, coated with gold-leaf or other conductor, and mounted on<br>
-an insulated handle. It is used instead of a proof-plane, for testing<br>
-bodies whose curvature is small.<br>
-<br>
-<br>
-<img style="width: 619px; height: 461px;" alt=""
- src="images/436F275.jpg"><br>
-Fig. 275. BOX BRIDGE.<br>
-<br>
-<br>
-437&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Proportionate Arms. </span><br>
-In general terms the arms of a Wheatstone bridge<br>
-whose proportion has to be known to complete the measurement. There is a<br>
-different system of naming them. Some designate by this title the two<br>
-arms in parallel with each other branching at and running from one end<br>
-of the bridge to the two galvanometer connections. In the cut of the Box<br>
-Bridge, A C and A B are the proportionate arms. The third arm is then<br>
-termed the Rheostat arm. (Stewart &amp; Gee.)<br>
-<br>
-Others treat as proportionate arms the two side members of the bridge in<br>
-parallel with the unknown resistance and third or rheostat arm.<br>
-<br>
-Synonym--Ratio Arms.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Prostration, Electric.</span><br>
-Too great exposure to the voltaic arc in its more powerful forms causes<br>
-symptoms resembling those of sunstroke. The skin is sometimes affected<br>
-to such a degree as to come off after a few days. The throat, forehead<br>
-and face suffer pains and the eyes are irritated. These effects only<br>
-follow exposure to very intense sources of light, or for very long<br>
-times.<br>
-<br>
-[Transcriber's note: Arcs emit ultraviolet rays.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Protector, Comb.</span><br>
-A lightning arrester, q. v., comprising two toothed plates nearly<br>
-touching each other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Protector, Electric.</span><br>
-A protective device for guarding the human body against destructive or<br>
-injurious electric shocks. In one system, Delany's, the wrists and<br>
-ankles are encircled by conducting bands which by wires running along<br>
-the arms, back and legs are connected. A discharge it is assumed<br>
-received by the hands will thus be short circuited around the body and<br>
-its vital organs. India rubber gloves and shoe soles have also been<br>
-suggested; the gloves are still used to some extent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pull.</span><br>
-A switch for closing a circuit when pulled. It is used instead of a push<br>
-button, q.v., in exposed situations, as its contacts are better<br>
-protected than those of the ordinary push button.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pump, Geissler.</span><br>
-A form of mercurial air pump. It is used for exhausting Geissler tubes,<br>
-incandescent lamp bulbs and similar purposes.<br>
-<br>
-Referring to the cut, A is a reservoir of mercury with flexible tube C<br>
-connected to a tube at its bottom, and raised and lowered by a windlass<br>
-b, the cord from which passes over a pulley a. When raised the mercury<br>
-tends to enter the chamber B, through the tube T. An arrangement of<br>
-stopcocks surmounts this chamber, which arrangement is shown on a larger<br>
-scale in the three figures X, Y and Z. To fill the bulb B, the cocks are<br>
-set in the position Z; n is a two way cock and while it permits the<br>
-escape of air below, it cuts off the tube, rising vertically from it.<br>
-This tube, d in the full figure connects with a vessel o, pressure gauge<br>
-p, and tube c, the latter connecting with the object to be exhausted.<br>
-The bulb B being filled, the cock m is closed, giving the position Y and<br>
-the vessel A is lowered until it is over 30 inches below B.<br>
-<br>
-<br>
-438&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-This establishes a Torricellian vacuum in B. The cock n is now turned,<br>
-giving the position X, when air is at once exhausted from the vessel<br>
-connected to C. This process is repeated until full exhaustion is<br>
-obtained. In practice the first exhaustion is often effected by a<br>
-mechanical pump. By closing the cock on the outlet tube c but little air<br>
-need ever find its way to the chambers o and B.<br>
-<br>
-<br>
-<img style="width: 359px; height: 817px;" alt=""
- src="images/438F276.jpg"><br>
-Fig. 276. GEISSLER AIR PUMP.<br>
-<br>
-<br>
-439&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pumping.</span><br>
-In incandescent lamps a periodical recurring change in intensity due to<br>
-bad running of the dynamos, or in arc lamps to bad feeding of the<br>
-carbons.<br>
-<br>
-<br>
-<img style="width: 355px; height: 779px;" alt=""
- src="images/439F277.jpg"><br>
-Fig. 277. SPRENGEL AIR PUMP.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pump, Sprengel.</span><br>
-A form of mercurial air pump. A simple form is shown in the cut. Mercury<br>
-is caused to flow from the funnel A, through c d to a vessel B. A side<br>
-connection x leads to the vessel R to be exhausted. As the mercury<br>
-passes x it breaks into short columns, and carries air down between<br>
-them, in this way exhausting the vessel R. In practice it is more<br>
-complicated. It is said to give a better vacuum than the Sprengel pump,<br>
-but to be slower in action.<br>
-<br>
-<br>
-440&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pump, Swinburne.</span><br>
-A form of mechanical air pump for exhausting incandescent lamp bulbs.<br>
-Referring to the cut, A is a bulb on the upper part of a tube G; above A<br>
-are two other bulbs C and D. From the upper end a tube runs to the bulb<br>
-E. Through the cock L, and tube F connection is made with a mechanical<br>
-air pump. The tube H leads to a drying chamber I, and by the tube J<br>
-connects with the lamp bulbs or other objects to be exhausted. The tube<br>
-G enters the bottle B through an airtight stopper, through which a<br>
-second tube with stopcock K passes. In use a vacuum is produced by the<br>
-mechanical pumps, exhausting the lamp bulbs to a half inch and drawing<br>
-up the mercury in G. The bent neck in the bulb E, acts with the bulb as<br>
-a trap to exclude mercury from F. When the mechanical pumps have<br>
-produced a vacuum equal to one half inch of mercury, the cock L is<br>
-closed and K is opened, and air at high pressure enters. This forces the<br>
-mercury up to the vessel D, half filling it. The high pressure is now<br>
-removed and the mercury descends. The valve in D closes it as the<br>
-mercury falls to the level G. Further air from the lamps enters A, and<br>
-by repetition of the ascent of the mercury, is expelled, through D. The<br>
-mercury is again lowered, producing a further exhaustion, and the<br>
-process is repeated as often as necessary.<br>
-<br>
-<br>
-<img style="width: 239px; height: 678px;" alt=""
- src="images/440F278.jpg"><br>
-Fig. 278. SWINBURNE'S AIR PUMP.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Push-Button.</span><br>
-A switch for closing a circuit by means of pressure applied to a button.<br>
-The button is provided with a spring, so that when pushed in and<br>
-released it springs back. Thus the circuit is closed only as long as the<br>
-button is pressed. The electric connection may be made by pressing<br>
-together two flat springs, each connected to one of the wires, or by the<br>
-stem of the button going between two springs, not in contact, forcing<br>
-them a little apart to secure good contact, and thereby bridging over<br>
-the space between them.<br>
-<br>
-<br>
-441&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pyro-electricity.</span><br>
-A phenomenon by which certain minerals when warmed acquire electrical<br>
-properties. (Ganot.) The mineral tourmaline exhibits it strongly. It was<br>
-originally observed in this mineral which was found to first attract and<br>
-then to repel hot ashes.<br>
-<br>
-The phenomenon lasts while any change of temperature within certain<br>
-limits is taking place. In the case of tourmaline the range is from<br>
-about 10&ordm; C. (50&ordm; F.) to 150&ordm; C. (302&ordm; F.) Above or
-below this range it<br>
-shows no electrification.<br>
-<br>
-The effect of a changing of temperature is to develop poles, one<br>
-positive and the other negative. As the temperature rises one end is<br>
-positive and the other negative; as the temperature becomes constant the<br>
-polarity disappears; as the temperature falls the poles are reversed.<br>
-<br>
-If a piece of tourmaline excited by pyro-electricity is broken, its<br>
-broken ends develop new poles exactly like a magnet when broken.<br>
-<br>
-The following minerals are pyro-electric: Boracite, topaz, prehnite,<br>
-zinc silicate, scolezite, axenite. The following compound substances are<br>
-also so: Cane sugar, sodium- ammonium racemate and potassium tartrate.<br>
-<br>
-The list might be greatly extended.<br>
-<br>
-The phenomenon can be illustrated by sifting through a cotton sieve upon<br>
-the excited crystal, a mixture of red lead and flowers of sulphur. By<br>
-the friction of the sifting these become oppositely electrified; the<br>
-sulphur adheres to the positively electrified end, and the red lead to<br>
-the negatively electrified end. (See Analogous Pole-Antilogous Pole.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pyromagnetic Motor.</span><br>
-A motor driven by the alternation of attraction and release of an<br>
-armature or other moving part, as such part or a section of it is<br>
-rendered more or less paramagnetic by heat.<br>
-<br>
-Thus imagine a cylinder of nickel at the end of a suspension rod, so<br>
-mounted that it can swing like a pendulum. A magnet pole is placed to<br>
-one side to which it is attracted. A flame is placed so as to heat it<br>
-when in contact with the magnet pole. This destroys its paramagnetism<br>
-and it swings away from the magnet and out of the flame. It cools,<br>
-becomes paramagnetic, and as it swings back is reattracted, to be again<br>
-released as it gets hot enough. This constitutes a simple motor.<br>
-<br>
-A rotary motor may be made on the same lines. Nickel is particularly<br>
-available as losing its paramagnetic property easily.<br>
-<br>
-<br>
-442&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Various motors have been constructed on this principle, but none have<br>
-attained any practical importance. Owing to the low temperature at which<br>
-it loses its paramagnetic properties nickel is the best metal for<br>
-paramagnetic motors.<br>
-<br>
-In Edison's motor, between the pole pieces of an electro-magnet a<br>
-cylinder made up of a bundle of nickel tubes is mounted, so as to be<br>
-free to rotate. A screen is placed so as to close or obstruct the tubes<br>
-farthest from the poles. On passing hot air or products of combustion of<br>
-a fire or gas flame through the tubes, the unscreened ones are heated<br>
-most and lose their paramagnetism. The screened tubes are then attracted<br>
-and the armature rotates, bringing other tubes under the screen, which<br>
-is stationary. Then the attracted tubes are heated while the others<br>
-cool, and a continuous rotation is the result.<br>
-<br>
-<br>
-<img style="width: 453px; height: 613px;" alt=""
- src="images/442F279.jpg"><br>
-Fig. 279. EDISON'S PYROMAGNETIC MOTOR.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Pyromagnetic Generator.</span><br>
-A current generator producing electric energy directly from thermal<br>
-energy by pyromagnetism.<br>
-<br>
-Edison's pyromagnetic generator has eight electro-magnets, lying on<br>
-eight radii of a circle, their poles facing inward and their yokes<br>
-vertical. Only two are shown in the cut. On a horizontal iron disc are<br>
-mounted eight vertical rolls of corrugated nickel representing<br>
-armatures. On each armature a coil of wire, insulated from the nickel by<br>
-asbestus is wound. The coils are all in series, and have eight<br>
-connections with a commutator as in a drum armature. There are two main<br>
-divisions to the commutator. Each connects with an insulated collecting<br>
-ring, and the commutator and collecting rings are mounted on a spindle<br>
-rotated by power. Below the circle of vertical coils is a horizontal<br>
-screen, mounted on the spindle and rotating with it.<br>
-<br>
-A source of heat, or a coal stove is directly below the machine and its<br>
-hot products of combustion pass up through the coils, some of which are<br>
-screened by the rotating screen. The effect is that the coils are<br>
-subjecting to induction owing to the change in permeability of the<br>
-nickel cores, according as they are heated, or as they cool when the<br>
-screen is interposed. The two commutator segments are in constant<br>
-relation to the screen, and current is collected therefrom and by the<br>
-collecting rings is taken to the outside circuit.<br>
-<br>
-<br>
-443&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Pyromagnetism.</span><br>
-The development of new magnetic properties or alteration of magnetic<br>
-sensibility in a body by heat. Nickel and iron are much affected as<br>
-regards their paramagnetic power by rise of temperature.<br>
-<br>
-<br>
-<img style="width: 481px; height: 646px;" alt=""
- src="images/443F280.jpg"><br>
-Fig. 280. PYROMAGNETIC GENERATOR.<br>
-<br>
-<br>
-Pyrometer, Siemens' Electric.<br>
-An instrument for measuring high temperatures by the variations in<br>
-electric resistance in a platinum wire exposed to the heat which is to<br>
-be measured.<br>
-</big></big><big><big><br>
-</big></big><big><big><br>
-443&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Q.</span><br>
-Symbol for electric quantity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quad.</span><br>
-(a) A contraction for quadrant, used as the unit of inductance; the
-henry.<br>
-<br>
-(b) A contraction for quadruplex in telegraphy.<br>
-<br>
-[Transcriber's note: A modern use of "quad" is a unit of energy equal to<br>
-1E15&nbsp; (one quadrillion) BTU, or 1.055E18 joules. Global energy<br>
-production in 2004 was 446 quad.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quadrant.</span><br>
-A length equal to an approximate earth quadrant, equal to 1E9<br>
-centimeters. It has been used as the name for the unit of inductance,<br>
-the henry, q. v.<br>
-<br>
-Synonym--Standard Quadrant.<br>
-<br>
-<br>
-444&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quadrant, Legal.</span><br>
-The accepted length of the quadrant of the earth, 9.978E8 instead of 1E9<br>
-centimeters; or to 9,978 kilometers instead of 10,000 kilometers.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quadrature.</span><br>
-Waves or periodic motions the angle of lag of one of which, with<br>
-reference to one in advance of it, is 90&deg;, are said to be in
-quadrature<br>
-with each other.<br>
-<br>
-[Transcriber's note: If the voltage and current of a power line are in<br>
-quadrature, the power factor is zero (cos(90&deg;) = 0)&nbsp; and no
-real power<br>
-is delivered to the load.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Qualitative.</span><br>
-Involving the determination only of the presence or absence of a<br>
-substance or condition, without regard to quantity. Thus a compass held<br>
-near a wire might determine qualitatively whether a current was passing<br>
-through the wire, but would not be sufficient to determine its quantity.<br>
-(See Quantitative.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quality of Sound.</span><br>
-The distinguishing characteristic of a sound other than its pitch; the<br>
-timbre.<br>
-<br>
-It is due to the presence with the main or fundamental sound of other<br>
-minor sounds called overtones, the fundamental note prevailing and the<br>
-other ones being superimposed upon it. The human voice is very rich in<br>
-overtones; the telephone reproduces these, thus giving the personal<br>
-peculiarities of every voice.<br>
-<br>
-Synonym--Timbre.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quantitative.</span><br>
-Involving the determination of quantities. Thus a simple test would<br>
-indicate that a current was passing through a wire. This would be a<br>
-qualitative test. If by proper apparatus the exact intensity of the<br>
-current was determined, it would be a quantitative determination. (See<br>
-Qualitative.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quantity.</span><br>
-This term is used to express arrangements of electrical connections for<br>
-giving the largest quantity of current, as a quantity armature, meaning<br>
-one wound for low resistance.<br>
-<br>
-A battery is connected in quantity when the cells are all in parallel.<br>
-It is the arrangement giving the largest current through a very small<br>
-external resistance.<br>
-<br>
-The term is now virtually obsolete (Daniell); "in surface," "in<br>
-parallel," or "in multiple arc" is used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quantity, Electric.</span><br>
-Electricity may be measured as if it were a compressible gas, by<br>
-determining the potential it produces when stored in a defined<br>
-recipient. In this way the conception of a species of quantity is<br>
-reached. It is also measured as the quantity of current passed by a<br>
-conductor.<br>
-<br>
-Thus a body whose surface is more or less highly charged with<br>
-electricity, is said to hold a greater or less quantity of electricity.<br>
-<br>
-It may be defined in electrostatic or electro-magnetic terms. (See<br>
-Quantity, Electrostatic--Quantity, Electro-magnetic.)<br>
-<br>
-<br>
-445&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Quantity.</span><br>
-Electro-magnetic. Quantity is determined electro-magnetically by the<br>
-measurement of current intensity for a second of time: its dimensions<br>
-are therefore given by multiplying intensity or current strength by<br>
-time. The dimensions of intensity are<br>
-&nbsp; ( (M^.5) * (L^.5) ) / T<br>
-therefore the dimensions of electro-magnetic quantity are<br>
-&nbsp; ( ( (M^.5) * (L^.5) ) / T ) * T = ( (M^.5) * (L^.5) )<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Quantity, Electro-magnetic, Practical
-Unit of.</span><br>
-The quantity of electricity passed by a unit current in unit time; the<br>
-quantity passed by one ampere in one second; the coulomb.<br>
-<br>
-It is equal to 3E9 electrostatic absolute units of quantity and to 0.1<br>
-of the electro- magnetic absolute unit of quantity.<br>
-<br>
-One coulomb is represented by the deposit of<br>
-&nbsp; .00111815 gram, or .017253 grain of silver,<br>
-&nbsp; .00032959 gram, or .005804 grain of copper,<br>
-&nbsp; .0003392 gram,&nbsp; or .005232 grain of zinc.<br>
-<br>
-If water is decomposed by a current each coulomb is represented by the<br>
-cubic centimeters of the mixed gases (hydrogen and oxygen) given by the<br>
-following formula.<br>
-&nbsp; ( 0.1738 * 76 * (273 + C&ordm; ) ) / ( h * 273 )<br>
-in which C&ordm; is the temperature of the mixed gases in degree
-centigrade<br>
-and h is the<br>
-pressure in centimeters of mercury column; or by<br>
-&nbsp; ( 0.01058 * 30 (491 + F&ordm; - 32)&nbsp; ) / (h * 491 )<br>
-for degrees Fahrenheit and inches of barometer.<br>
-<br>
-[Transcriber's note: 6.24150962915265E18 electrons is one coulomb.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Quantity, Electrostatic.</span><br>
-Quantity is determined electro-statically by the repulsion a charge of<br>
-given quantity exercises upon an identical charge at a known distance.<br>
-The force evidently varies with the product of the two quantities, and<br>
-by the law of radiant forces also inversely with the square of the<br>
-distance. The dimensions given by these considerations is Q * Q/(L*L).<br>
-This is the force of repulsion. The dimensions of a force are<br>
-(M * L) /(T^2). Equating these two expressions we have:<br>
-&nbsp; (Q^2)/(L^2) = (M*L)/(T^2)<br>
-&nbsp; or<br>
-&nbsp; Q = ((M^.5)*(L^1.5)) / T<br>
-which are the dimensions of electrostatic quantity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quantity, Meter.</span><br>
-An electric meter for determining the quantity of electricity which<br>
-passes through it, expressible in coulombs or ampere hours. All<br>
-commercial meters are quantity meters.<br>
-<br>
-<br>
-446&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quartz.</span><br>
-A mineral, silica, SiO2. It has recently been used by C. V. Boys and<br>
-since by others in the making of filaments for torsion suspensions. The<br>
-mineral is melted, while attached to an arrow or other projectile. It is<br>
-touched to another piece of quartz or some substance to which it adheres<br>
-and the arrow is fired off from the bow. A very fine filament of<br>
-surpassingly good qualities for galvanometer suspension filaments is<br>
-produced.<br>
-<br>
-As a dielectric it is remarkable in possessing but one-ninth the<br>
-residual capacity of glass.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Quicking.</span><br>
-The amalgamating of a surface of a metallic object before silver<br>
-plating. It secures better adhesion of the deposit. It is executed by<br>
-dipping the article into a solution of a salt of mercury. A solution of<br>
-mercuric nitrate 1 part, in water 100 parts, both by weight, is used.<br>
-<br>
-</big></big><br>
-<big><big><br>
-446&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">R.</span><br>
-(a) Abbreviation and symbol for Reamur, as 10&ordm; R., meaning
-10&ordm; by the<br>
-Reamur thermometer. (See Reamur Scale.)<br>
-<br>
-(b) Symbol for resistance, as in the expression of Ohm's Law C=E/R.<br>
-(rho, Greek r) Symbol for specific resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Racing of Motors.</span><br>
-The rapid acceleration of speed of a motor when the load upon it is<br>
-removed. It is quickly checked by counter-electro-motive force. (See<br>
-Motor, Electric.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Radian.</span><br>
-The angle whose arc is equal in length to the radius; the unit angle.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Radiant Energy.</span><br>
-Energy, generally existing in the luminiferous ether, kinetic and<br>
-exercised in wave transmission, and rendered sensible by conversion of<br>
-its energy into some other form of energy, such as thermal energy.<br>
-<br>
-If the ether waves are sufficiently short and not too short, they<br>
-directly affect the optic nerve and are known as light waves; they may<br>
-be so short as to be inappreciable by the eye, yet possess the power of<br>
-determining chemical change, when they are known as actinic waves; they<br>
-may be also so long as to be inappreciable by the eye, when they may be<br>
-heat-producing waves, or obscure waves.<br>
-<br>
-Other forms of energy may be radiant, as sound energy dispersed by the<br>
-air, and gravitational energy, whose connection with the ether has not<br>
-yet been demonstrated.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Radiation.</span><br>
-The traveling or motion of ether waves through space.<br>
-<br>
-[Transcriber's note: The modern term corresponding to this definition is<br>
-photons. The modern concept of radiation also includes particles--<br>
-neutrons, protons, alpha (helium) and beta (electrons) rays and other<br>
-exotic items.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Radicals.</span><br>
-A portion of a molecule, possessing a free bond and hence free to<br>
-combine directly. A radical never can exist alone, but is only<br>
-hypothetical. An atom is a simple radical, an unsaturated group of atoms<br>
-is a compound radical.<br>
-<br>
-<br>
-447&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Radiometer.</span><br>
-An instrument consisting of four vanes poised on an axis so as to be<br>
-free to rotate, and contained in a sealed glass vessel almost perfectly<br>
-exhausted. The vanes of mica are blackened on one side.<br>
-<br>
-On exposure to light or a source of heat (ether waves) the vanes rotate.<br>
-The rotation is due to the beating back and forth of air molecules from<br>
-the surface of the vanes to the inner surface of the glass globe.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Radiometer, Electric.</span><br>
-A radiometer in which the motion of the molecules of air necessary for<br>
-rotation of the vane is produced by electrification and not by heating.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Radio-micrometer.</span><br>
-An instrument for detecting radiant energy of heat or light form. It<br>
-consists of a minute thermopile with its terminals connected by a wire,<br>
-the whole suspended between the poles of a magnet. A minute quantity of<br>
-heat produces a current in the thermopile circuit, which, reacted on by<br>
-the field, produces a deflection. A convex mirror reflecting light is<br>
-attached so as to move with the thermopile. The instrument is of<br>
-extraordinary sensitiveness. It responds to .5E-6 of a degree Centigrade<br>
-or about 1E-6 degree Fahrenheit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Radiophony.</span><br>
-The production of sound by intermittent action of a beam of light upon a<br>
-body. With possibly a few exceptions all matter may produce sound by<br>
-radiophouy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Range Finder.</span><br>
-An apparatus for use on shipboard to determine the distance of another<br>
-ship or object. It is designed for ships of war, to give the range of<br>
-fire, so as to set the guns at the proper elevation. The general<br>
-principle involved is the use of the length of the ship if possible, if<br>
-not of its width, as a base line. Two telescopes are trained upon the<br>
-object and kept trained continuously thereon. The following describes<br>
-the Fiske range finder.<br>
-<br>
-The range finder comprises two fairly powerful telescopes, each mounted<br>
-on a standard, which can be rotated round a vertical axis, corresponding<br>
-with the center of the large disc shown in the engraving. One-half of<br>
-the edge of this disc is graduated to 900 on either side of a zero<br>
-point, and below the graduation is fixed a length of platinum silver<br>
-wire. This wire only extends to a distance of 81.10 on either side of<br>
-zero, and is intended to form two arms of a Wheatstone bridge. The<br>
-sliding contact is carried by the same arm as the telescope standards,<br>
-so that it moves with the telescope. The two instruments are mounted at<br>
-a known distance apart on the ship, as shown diagrammatically in the<br>
-cut. Here A and B are the centers of the two discs, C and D the arms<br>
-carrying the telescopes, and E and F the platinum silver wires. Suppose<br>
-the object is at T, such that A B T is a right angle, then<br>
-AT=AB/sin(ATB).<br>
-<br>
-<br>
-448&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-If the two sectors are coupled up as shown, with a battery, h, and a<br>
-galvanometer, by the wires, a b and c d, then since the arm, e, on being<br>
-aligned on the object takes the position c1 while d remains at zero, the<br>
-Wheatstone bridge formed by these segments and their connections will be<br>
-out of balance, and a current will flow through the galvanometer, which<br>
-may be so graduated as to give the range by direct reading, since the<br>
-current through it will increase with the angle A T B.<br>
-<br>
-<br>
-<img style="width: 389px; height: 673px;" alt=""
- src="images/448F281.jpg"><br>
-Fig. 281. RANGE FINDER.<br>
-<br>
-<br>
-In general, however, the angle A B T will not be a right angle, but some<br>
-other angle. In this case AT = AB / sin(A T B) * sin( A B T), and hence<br>
-it will only be necessary to multiply the range reading on the<br>
-galvanometer by the sine of the angle A B T, which can be read directly<br>
-by the observer at B. This multiplication is not difficult, but by<br>
-suitably arranging his electrical appliances Lieutenant Fiske has<br>
-succeeded in getting rid of it, so that the reading of the galvanometer<br>
-always gives the range by direct reading, no matter what the angle at B<br>
-may be. To explain this, consider the two telescopes shown in the cut in<br>
-the positions C and D; the whole current then has a certain resistance.<br>
-<br>
-<br>
-449&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Next suppose them, still remaining parallel, in the positions C1 and D1.<br>
-The total resistance of the circuit is now less than before, and hence<br>
-if C1, one of the telescopes, is moved out of parallel to the other,<br>
-through a certain angle, the current through the galvanometer will be<br>
-greater than if it were moved through an equal angle out of a parallel<br>
-when the telescopes were in the positions C and D. The range indicated<br>
-is, therefore, decreased, and by properly proportioning the various<br>
-parts it is found that the range can always be read direct from the<br>
-galvanometer, or in other words the multiplication of A B/sin( A T B )<br>
-by sin( A B T ) is to all intents and purposes performed automatically.<br>
-There is, it is true, a slight theoretical error; but by using a small<br>
-storage battery and making the contents carefully it is said to be<br>
-inappreciable. Each telescope is fitted with a telephone receiver and<br>
-transmitter, so that both observers can without difficulty decide on<br>
-what point to align their telescopes. It will be seen that it is<br>
-necessary that the lines of sight of two telescopes should be parallel<br>
-when the galvanometer indicates no current. It has been proposed to<br>
-accomplish this by sighting both telescopes on a star near the horizon,<br>
-which being practically an infinite distance away insures the<br>
-parallelism of the lines of sight.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rate Governor.</span><br>
-An apparatus for securing a fixed rate of vibration of a vibrating reed.<br>
-It is applied in simultaneous telegraphy and telephoning over one wire.<br>
-The principle is that of the regular make and break mechanism, with the<br>
-feature that the contact is maintained during exactly one-half of the<br>
-swing of the reed. The contact exists during the farthest half of the<br>
-swing of the reed away from the attracting pole.<br>
-<br>
-<br>
-<img style="width: 648px; height: 375px;" alt=""
- src="images/449F282.jpg"><br>
-Fig. 282. LANGDON DAVIRS' RATE GOVERNOR.<br>
-<br>
-<br>
-In the left hand figure of the cut, K is the key for closing the<br>
-circuit. A is the base for attachment of the reed. V is the<br>
-contact-spring limited in its play to the right by the screw S. C is the<br>
-actuating magnet. By tracing the movements of the reed, shown on an<br>
-exaggerated scale in the three right hand figures, it will be seen that<br>
-the reed is in electric contact with the spring during about one-half<br>
-its movement. The time of this connection is adjustable by the screw S.<br>
-<br>
-Synonym--Langdon Davies' Rate Governor or Phonophone.<br>
-<br>
-<br>
-450&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ray, Electric. Raia torpedo.</span><br>
-The torpedo, a fish having the same power of giving electric shocks as<br>
-that possessed by the electric eel, q. v. (See also Animal Electricity.)<br>
-<br>
-<br>
-<img style="width: 390px; height: 593px;" alt=""
- src="images/450F283.jpg"><br>
-Fig. 283. TORPEDO OR ELECTRIC RAY<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reaction of Dynamo, Field and Armature.</span><br>
-A principle of the dynamo current generator, discovered by Soren Hjorth<br>
-of Denmark.<br>
-<br>
-When the armature is first rotated it moves in a field due to the<br>
-residual magnetism of the field magnet core. This field is very weak,<br>
-and a slight current only is produced. This passing in part or in whole<br>
-through the field magnet cores slightly strengthens the field, whose<br>
-increased strength reacts on the armature increasing its current, which<br>
-again strengthens the field. In this way the current very soon reaches<br>
-its full strength as due to its speed of rotation.<br>
-<br>
-The operation is sometimes termed building up.<br>
-<br>
-Sometimes, when there is but a trace of residual magnetism, it is very<br>
-hard to start a dynamo.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reading Telescope.</span><br>
-A telescope for reading the deflections of a reflecting galvanometer.<br>
-<br>
-A long horizontal scale is mounted at a distance from the galvanometer<br>
-and directly below or above the centre of the scale a telescope is<br>
-mounted. The telescope is so directed that the mirror of the<br>
-galvanometer is in its field of view, and the relative positions of<br>
-mirror, scale and telescope are such that the image of the scale in the<br>
-galvanometer mirror is seen by the observer looking through the<br>
-telescope.<br>
-<br>
-Under these conditions it is obvious that the graduation of the scale<br>
-reflected by the mirror corresponds to the deflection of the<br>
-galvanometer needle.<br>
-<br>
-The scale may be straight or curved, with the galvanometer in the latter<br>
-case, at its centre of curvature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reamur Scale.</span><br>
-A thermometer scale in use in some countries of Continental Europe. The<br>
-temperature of melting ice is 0&deg;; the temperature of condensing
-steam<br>
-is 80&deg;; the degrees are all equal in length. For conversion to<br>
-centigrade degrees multiply degrees Reamur by 5/4. For conversion to<br>
-Fahrenheit degrees multiply by 9/4 and add 32 if above 0&deg; R., and if<br>
-below subtract 32. Its symbol is R., as 10&deg; R.<br>
-<br>
-<br>
-451&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Recalescence.</span><br>
-A phenomenon occurring during the cooling of a mass of steel, when it<br>
-suddenly emits heat and grows more luminous for an instant. It is a<br>
-phase of latent heat, and marks apparently the transition from a<br>
-non-magnetizable to a magnetiz&nbsp; able condition.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Receiver.</span><br>
-In telephony and telegraphy, an instrument for receiving a message as<br>
-distinguished from one used for sending or transmitting one.<br>
-<br>
-Thus the Bell telephone applied to the ear is a receiver, while the<br>
-microphone which is spoken into or against is the transmitter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Receiver, Harmonic.</span><br>
-A receiver including an electro-magnet whose armature is an elastic<br>
-steel reed, vibrating to a particular note. Such a reed responds to a<br>
-series of impulses succeeding each other with the exact frequency of its<br>
-own natural vibrations, and does not respond to any other rapid series<br>
-of impulses. (See Telegraph Harmonic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reciprocal.</span><br>
-The reciprocal of a number is the quotient obtained by dividing one by<br>
-the number. Thus the reciprocal of 8 is 1/8.<br>
-<br>
-Applied to fractions the above operation is carried out by simply<br>
-inverting the fraction. Thus the reciprocal of 3/4 is 4/3 or 1-1/3.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Record, Telephone.</span><br>
-Attempts have been made to produce a record from the vibrations of a<br>
-telephone disc, which could be interpreted by phonograph or otherwise.<br>
-<br>
-<br>
-<img style="width: 684px; height: 489px;" alt=""
- src="images/451F284.jpg"><br>
-Fig. 284. MORSE RECORDER OR EMBOSSER.<br>
-<br>
-<br>
-452&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Recorder, Morse.</span><br>
-A telegraphic receiving apparatus for recording on a strip of paper the<br>
-dots and lines forming Morse characters as received over a telegraph<br>
-line. Its general features are as follows:<br>
-<br>
-A riband or strip of paper is drawn over a roller which is slightly<br>
-indented around its centre. A stylus or blunt point carried by a<br>
-vibrating arm nearly touches the paper. The arm normally is motionless<br>
-and makes no mark on the paper. An armature is carried by the arm and an<br>
-electro-magnet faces the armature. When a current is passed through the<br>
-magnet the armature is attracted and the stylus is forced against the<br>
-paper, depressing it into the groove, thus producing a mark. When the<br>
-current ceases the stylus is drawn back by a spring.<br>
-<br>
-<br>
-<img style="width: 710px; height: 462px;" alt=""
- src="images/452F285.jpg"><br>
-Fig. 285. INKING ROLLER MECHANISM OF MORSE RECORDER.<br>
-<br>
-<br>
-In some instruments a small inking roller takes the place of the stylus,<br>
-and the roller is smooth. The cut, Fig. 285, shows the plan view of the<br>
-ink-roller mechanism. J is the roller, L is the ink well, Cl is the arm<br>
-by which it is raised or lowered by the electro-magnet, as in the<br>
-embosser. S S is the frame of the instrument, and B the arbor to which<br>
-the arm carrying the armature is secured, projecting to the right. A<br>
-spring is arranged to rub against the edge of the inking roller and<br>
-remove the ink from it.<br>
-<br>
-The paper is fed through the apparatus by clockwork. At the present day<br>
-sound reading has almost entirely replaced the sight reading of the<br>
-recorder.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Recorder, Siphon.</span><br>
-A recording apparatus in which the inked marks are made on a strip of<br>
-paper, the ink being supplied by a siphon terminating in a capillary<br>
-orifice.<br>
-<br>
-In the cut N S represents the poles of a powerful electro-magnet. A<br>
-rectangular coil bb of wire is suspended between the coils. A stationary<br>
-iron core a intensifies the field. The suspension wire f f 1 has its<br>
-tension adjusted at h. This wire acts as conductor for the current.<br>
-<br>
-<br>
-453&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The current is sent in one or the other direction or is cut off in<br>
-practice to produce the desired oscillations of the coil b b. A glass<br>
-siphon n l works upon a vertical axis l. One end l is immersed in an ink<br>
-well m. Its longer end n touches a riband of paper o o. The thread k<br>
-attached to one side of the coil pulls the siphon back and forth<br>
-according to the direction of current going through the electro-magnet<br>
-cores. A spiral spring adjusted by a hand-screw controls the siphon. In<br>
-operation the siphon is drawn back and forth producing a zigzag line.<br>
-The upward marks represent dots, the downward ones dashes. Thus the<br>
-Telegraphic Code can be transmitted on it. To cause the ink to issue<br>
-properly, electrification by a static machine has been used, when the<br>
-stylus does not actually touch the paper, but the ink is ejected in a<br>
-series of dots.<br>
-<br>
-<br>
-<img style="width: 667px; height: 605px;" alt=""
- src="images/453F286.jpg"><br>
-Fig. 286. SIPHON RECORDER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reducteur for Ammeter.</span><br>
-A resistance arranged as a shunt to diminish the total current passing<br>
-through an ammeter. It is analogous to a galvanometer shunt. (See<br>
-Multiplying Power of Shunt.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Reducteur for Voltmeter.</span><br>
-A resistance coil connected in series with a Voltmeter to diminish the<br>
-current passing through it. Its resistance being known in terms of the<br>
-resistance of the voltmeter it increases the range of the instrument so<br>
-that its readings may cover double or more than double their normal<br>
-range.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Reduction of Ores, Electric.</span><br>
-Treatment of ores by the electric furnace (see Furnace, Electric.) The<br>
-ore mixed with carbon and flux is melted by the combined arc and<br>
-incandescent effects of the current and the metal separates. In another<br>
-type the metal is brought into a fusible compound which is electrolyzed<br>
-while fused in a crucible. Finally processes in which a solution of a<br>
-salt of the metal is obtained, from which the metal is obtained by<br>
-electrolysis, may be included. Aluminum is the metal to whose extraction<br>
-the first described processes are applied.<br>
-<br>
-<br>
-454&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Refraction, Electric Double.</span><br>
-Double refraction induced in some materials by the action of either an<br>
-electrostatic, magnetic or an electro-magnetic field.<br>
-<br>
-The intensity or degree of refracting power is proportional to the<br>
-square of the strength of field.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Refreshing Action.</span><br>
-In electro-therapeutics the restoration of strength or of nerve force by<br>
-the use of voltaic alternatives, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Region, Extra-polar.</span><br>
-In electro-therapeutics the area or region of the body remote from the<br>
-therapeutic electrode.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Region, Polar.</span><br>
-In electro-therapeutics the area or region of the body near the<br>
-therapeutic electrode.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Register, Electric.</span><br>
-There are various kinds of electric registers, for registering the<br>
-movements of watchmen and other service. Contact or press buttons may be<br>
-distributed through a factory. Each one is connected so that when the<br>
-circuit is closed thereby a mark is produced by the depression of a<br>
-pencil upon a sheet or disc of paper by electro-magnetic mechanism. The<br>
-paper is moved by clockwork, and is graduated into hours. For each<br>
-push-button a special mark may be made on the paper. The watchman is<br>
-required to press the button at specified times. This indicates his<br>
-movements on the paper, and acts as a time detector to show whether he<br>
-has been attending to his duty.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Register, Telegraphic.</span><br>
-A term often applied to telegraph recorders, instruments for producing<br>
-on paper the characters of the Morse or other alphabet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Regulation, Constant Current.</span><br>
-The regulation of a dynamo so that it shall give a constant current<br>
-against any resistance in the outer circuits, within practical limits.<br>
-It is carried out in direct current machines generally by independent<br>
-regulators embodying a controlling coil with plunger or some equivalent<br>
-electro-magnetic device inserted in the main circuit and necessarily of<br>
-low resistance. In some regulators the work of moving the regulator is<br>
-executed mechanically, but under electrical control; in others the<br>
-entire work is done by the current.<br>
-<br>
-A typical regulator or governor (Golden's) of the first class comprises<br>
-two driven friction wheels between which is a driving friction wheel,<br>
-which can engage with one driven wheel only at once. It is brought into<br>
-engagement with one or the other by a solenoid and plunger.<br>
-<br>
-<br>
-455&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-As it touches one wheel it turns it in one direction. This moves a<br>
-sliding contact in one direction so as to increase a resistance. This<br>
-corresponds to a motion of the plunger in one direction. As the driving<br>
-wheel moves in the opposite direction by a reverse action it diminishes<br>
-the resistance. Thus the increase and decrease of resistance correspond<br>
-to opposite movements of the solenoid plunger, and consequently to<br>
-opposite variations in the current. The whole is so adjusted that the<br>
-variations in resistance maintain a constant amperage. The resistance is<br>
-in the exciting circuit of the dynamo.<br>
-<br>
-In Brush's regulator, which is purely mechanical, a series dynamo is<br>
-made to give a constant current by introducing across the field magnets<br>
-a shunt of variable resistance, whose resistance is changed by an<br>
-electro-magnet, whose coils are in circuit with the main current. Carbon<br>
-resistance discs are used which the electro-magnet by its attraction for<br>
-its armature, presses with varying intensity. This alters the<br>
-resistance, decreasing it as the current increases and the reverse. As<br>
-the connection is in shunt this action goes to maintain a constant<br>
-current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Regulation, Constant Potential.</span><br>
-The regulation of constant potential dynamos is executed on the same<br>
-lines as that of constant current dynamos. If done by a controlling<br>
-coil, it must for constant potential regulation be wound with fine wire<br>
-and connected as a shunt for some part of the machine.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Regulation of Dynamos.</span><br>
-The regulation of dynamos so that they shall maintain a constant<br>
-potential difference in the leads of their circuit for multiple arc<br>
-systems or shall deliver a constant current in series systems. Hence two<br>
-different systems of regulation are required, (a) constant potential<br>
-regulation--(b) constant current regulation. The first named is by far<br>
-the more important, as it concerns multiple arc lighting, which is the<br>
-system universally used for incandescent lighting.<br>
-<br>
-S. P. Thompson thus summarizes the methods of governing or regulating<br>
-dynamos. Premising that alteration of the magnetic flux is the almost<br>
-universal way of control, it can be done in two ways; first, by varying<br>
-the excitation or ampere turns of the field, and second by varying the<br>
-reluctance of the magnetic circuit. The excitation or magnetic flux may<br>
-be varied<br>
-<br>
-(a) by hand, with the aid of rheostats and commutators in the exciting<br>
-circuit;<br>
-<br>
-(b) automatically, by governors, taking the place of the hand;<br>
-<br>
-(c) by compound windings. The magnetic circuit may have its reluctance<br>
-caused to vary in several ways;<br>
-<br>
-(d) by moving the pole pieces nearer to or further from the armature;<br>
-<br>
-(e) by opening or closing some gap in the magnetic circuit (field-magnet<br>
-core);<br>
-<br>
-(f) by drawing the armature endways from between the pole pieces;<br>
-<br>
-(g) by shunting some of the magnetic lines away from the armature by a<br>
-magnetic shunt.<br>
-<br>
-The latter magnetic circuit methods d, e, f, and g, have never met with<br>
-much success except on small machines or motors. Method e is adopted in<br>
-the Edison motor, the yoke being withdrawn or brought nearer the cores<br>
-of the coils. (See Regulation, Constant Current-Regulation, constant<br>
-Potential.)<br>
-<br>
-<br>
-456&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reguline. adj.</span><br>
-Having the characteristics of a piece of metal, being flexible,<br>
-adherent, continuous, and coherent. Applied to electrolytic deposits.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Relative.</span><br>
-Indicating the relation between two or more things without reference to<br>
-absolute value of any one of them. Thus one lamp may be of relatively<br>
-double resistance compared to another, but this states nothing of the<br>
-resistance in ohms of either lamp.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Relay.</span><br>
-A receiving instrument which moves in accordance with impulses of<br>
-currents received, and in so moving opens and closes a local circuit,<br>
-which circuit may include as powerful a battery as required or<br>
-desirable, while the relay may be on the other hand so delicate as to<br>
-work with a very weak current.<br>
-<br>
-<br>
-<img style="width: 607px; height: 318px;" alt=""
- src="images/456F287.jpg"><br>
-Fig. 287. RELAY.<br>
-<br>
-<br>
-The typical relay includes an electro-magnet and armature. To the latter<br>
-an arm is attached and the lower end of the arm works in pivots. As the<br>
-armature is attracted the arm swings towards the magnet. When the<br>
-current is cut off, the armature and arm are drawn back by a spring.<br>
-When the arm swings towards the magnet its upper end touching a contact<br>
-screw closes the local circuit. When it swings back it comes in contact<br>
-with a second screw, with insulated point, and opens the circuit as it<br>
-leaves the first named screw.<br>
-<br>
-One terminal connects with the arm through the pivots and frame. The<br>
-other connects with the contact screw through the frame carrying it.<br>
-<br>
-Synonym--Relay Magnet.<br>
-<br>
-<br>
-457&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Relay Bells.</span><br>
-Bells connected by relay connection to a main line for acoustic<br>
-telegraphy. A stroke on one bell indicates a dot and on the other a<br>
-dash. The system is now nearly extinct.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Relay, Box-sounding.</span><br>
-A relay which is surrounded by or mounted on a resonator or wooden box<br>
-of such proportions and size as to reinforce the sound. This enables a<br>
-relay to act as a sounder, its weak sounds being virtually magnified so<br>
-as to be audible.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Relay Connection.</span><br>
-A connection used in telegraphy, including a local battery, with a short<br>
-circuit normally open, but closed by a switch and a sounder or other<br>
-appliance. The latter is made very sensitive so as to be worked by a<br>
-feeble current, and is connected to the main line. A very slight current<br>
-closes the switch and the local battery comes into operation to work a<br>
-sounder, etc. When the current ceases on the main line the switch opens<br>
-and throws the local battery out of action. The switch is termed a<br>
-relay, q. v. A long main line may thus produce strong effects at distant<br>
-stations, the intensity of action depending on the local battery.<br>
-<br>
-<br>
-<img style="width: 708px; height: 454px;" alt=""
- src="images/457F288.jpg"><br>
-Fig. 288. RELAY OR LOCAL CIRCUIT.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Relay, Differential.</span><br>
-A relay containing two coils wound differentially, and of the same<br>
-number of turns and resistance. If two equal currents pass through the<br>
-coils they counteract each other and no action takes place. If there is<br>
-a difference in the currents the relay acts as one coil preponderates.<br>
-The coils may be wound for uneven currents with different resistance and<br>
-number of turns.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Relay, Microphone.</span><br>
-A relay connection applied to a telephone circuit. It consists of a<br>
-microphone mounted in front of the diaphragm of a telephone receiver. In<br>
-circuit with the microphone is a battery and second telephone receiver.<br>
-The microphone is supposed to intensify the sounds of the first<br>
-telephone.<br>
-<br>
-<br>
-458&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Relay, Polarized.</span><br>
-A relay whose armature is of steel, and polarized or permanently<br>
-magnetized, or in which a permanent magnet is used as the basis for the<br>
-electro-magnets. In the relay shown in the cut the coils shown are<br>
-mounted on cores carried on the end of a powerful bent permanent magnet.<br>
-Thus when no current passes their upper poles are both of the same sign,<br>
-and the horizontally vibrating tongue is held by the magnetic attraction<br>
-against one or the other pole piece. If a current is sent through the<br>
-electro-magnet it gives opposite polarity to the two polar extensions.<br>
-As the end of the vibrating tongue is of polarity determined by the<br>
-permanent magnet it is attracted to one pole and&nbsp; repelled from the<br>
-other. On cessation of current it remains attached by the permanent<br>
-magnetism. If now a current is sent in the opposite direction the two<br>
-poles again acquire opposite polarity, the reverse of the former, and<br>
-the tongue flies across to the opposite side. On cessation of current it<br>
-remains attached as before by the permanent magnetism.<br>
-<br>
-In its movements to and fro the relay tongue opens and closes a contact,<br>
-so as to work a sounder or other apparatus. The polarized relay is of<br>
-high sensibility, and requires little or no change of adjustment.<br>
-<br>
-<br>
-<img style="width: 426px; height: 473px;" alt=""
- src="images/458F288.jpg"><br>
-Fig. 288. POLARIZED RELAY<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reluctance.</span><br>
-In a magnetic circuit or portion thereof, the resistance offered to the<br>
-flow of lines of force. The magnetic circuit as has already been stated<br>
-is treated like an electric circuit, and in it reluctance occupies the<br>
-place of resistance in the electric circuit. It is the reciprocal of<br>
-permeance. S. P. Thompson expresses the law thus:<br>
-<br>
-Total number of magnetic lines = (magneto-motive force) / (magnetic<br>
-reluctance)<br>
-<br>
-Synonyms--Magnetic Reluctance-Magnetic Resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reluctance, Unit of.</span><br>
-The reluctance of a circuit through which unit magnetizing power<br>
-(magneto-motive force) can produce a unit of induction or one line of<br>
-force. This value is very high; the reluctance of ordinary magnetic<br>
-circuits ranges from 1E-5 to 1E-8 unit of reluctance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reluctivity.</span><br>
-Specific reluctance; the reluctance of a cube of material whose edge<br>
-measures one centimeter in length. It is a quality bearing the same<br>
-relation to reluctance that permeability does to permeance.<br>
-<br>
-It is defined as the reciprocal of magnetic permeability. (Kenelly.) If<br>
-plotted as a curve for different values of the magnetizing force it is<br>
-found to be nearly a straight line, a linear function of the magnetizing<br>
-force, H with the equation a + b H. Reluctivity is the property of a<br>
-substance; reluctance is the property of a circuit.<br>
-<br>
-<br>
-459&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Remanence.</span><br>
-The residual magnetism left after magnetic induction, expressed in lines<br>
-of force per square centimeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Repeater.</span><br>
-In telegraphy an instrument for repeating the signals through a second<br>
-line. It is virtually a relay which is operated by the sender, and which<br>
-in turn operates the rest of the main line, being situated itself at<br>
-about the middle point of the distance covered. In the simpler forms of<br>
-repeater two relays are used, one for transmission in one direction the<br>
-other for transmission in the other. An attendant switches one or the<br>
-other in as required.<br>
-<br>
-Thus a common relay is virtually a repeater for its local circuit. If<br>
-such a relay is placed half way down a line, and if the line beyond it<br>
-is connected as its local, it becomes a repeater.<br>
-<br>
-Some forms of repeaters are automatic, and repeat both ways without the<br>
-need of an attendant.<br>
-<br>
-It is the practice to somewhat prolong the signals sent through a<br>
-repeater.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Replenisher, Sir William Thomson's.</span><br>
-A static accumulating influence machine contained in Thomson's quadrant<br>
-electrometer and used to change the quadrants. The cut shows the<br>
-horizontal section and construction of the apparatus.<br>
-<br>
-It contains two gilt brass inductors A B, and two eccentric sectors or<br>
-carriers, C, D, which are mounted on an ebonite spindle, which is spun<br>
-around by the fingers. The springs s s1 connect each with its inductor;<br>
-the springs S S1 connect only each other, and touch the sectors as they<br>
-turn around.<br>
-<br>
-One of the inductors may be always assumed to be of slightly higher<br>
-potential than that of the other one. When the carriers are in contact<br>
-with the springs S S1 they are each charged by induction with<br>
-electricity opposite in sign to that of the nearest quadrant. As they<br>
-leave the springs S S1 in their rotation, they next touch the springs s<br>
-s1, but of the recently opposite inductor. They share each a portion of<br>
-its charge with the inductors building up their charges. The action is<br>
-repeated over and over again as they rotate.<br>
-<br>
-</big></big><big><big><img style="width: 574px; height: 594px;" alt=""
- src="images/460F289.jpg"><br>
-Fig. 289. DIAGRAM OF THOMSON'S REPLENISHER.<br>
-<br>
-</big></big><big><big><img style="width: 511px; height: 674px;" alt=""
- src="images/461F290.jpg"><br>
-Fig. 290. THOMSON'S REPLENISHER.<br>
-<br>
-<br>
-460&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reservoir, Common.</span><br>
-A term applied to the earth, because all electrified bodies discharge<br>
-into it if connected thereto.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Residual Atmosphere.</span><br>
-The air left in a receiver after exhaustion by an air pump. The<br>
-quantity, where good air pumps are used, is very minute.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Residue, Electric.</span><br>
-The residual charge of a condenser. (See Charge, Residual.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resin.</span><br>
-(a) The product obtained by non-destructive distillation of the juice of<br>
-the pitch pine. It is the solid residue left after the turpentine has<br>
-been evaporated or distilled. It is a mixture of abietic acid C44 H64 O5<br>
-and pinic acid C20 H30 O2. It is an insulator; its specific inductive<br>
-capacity is 2.55. (Baltzmann.)<br>
-<br>
-Synonyms--Colophony--Rosin.<br>
-<br>
-(b) The name is also generally applied to similar substances obtained<br>
-from the sap of other trees; thus shellac is a resin. The resins are a<br>
-family of vegetable products; the solid portions of the sap of certain<br>
-trees. Common resin, lac, dragons blood, are examples. They are all<br>
-dielectrics and sources of resinous or negative electricity when rubbed<br>
-with cotton, flannel, or silk. (See Electrostatic Series.)<br>
-<br>
-<br>
-461&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resinous Electricity.</span><br>
-Negative electricity; the electricity produced upon the surface of a<br>
-resinous body by rubbing it; such a body is shellac or sealing wax;<br>
-flannel and other substances may be used as the rubbing material. (See<br>
-Electrostatic Series.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance.</span><br>
-(a) The quality of an electric conductor, in virtue of which it opposes<br>
-the passage of an electric current, causing the disappearance of<br>
-electro-motive force if a current passes through it, and converting<br>
-electric energy into heat energy in the passage of a current through it.<br>
-If a current passes through a conductor of uniform resistance there is a<br>
-uniform fall of potential all along its length. If of uneven resistance<br>
-the fall in potential varies with the resistance. (See Potential, Fall<br>
-of.)<br>
-<br>
-The fall of potential is thus expressed by Daniell. "In a conductor, say<br>
-a wire, along which a current is steadily and uniformly passing, there<br>
-is no internal accumulation of electricity, no density of internal<br>
-distribution; there is, on the other hand, an unequally distributed<br>
-charge of electricity on the surface of the wire, which results in a<br>
-potential diminishing within the wire from one end of the wire to the<br>
-other."<br>
-<br>
-Resistance varies inversely with the cross section of a cylindrical or<br>
-prismatic conductor, in general with the average cross-section of any<br>
-conductor, and in the same sense directly with its true or average or<br>
-virtual length. It varies for different substances, and for different<br>
-conditions as of temperature and pressure for the same substance. A rise<br>
-of temperature in metals increases the resistance, in some bad<br>
-conductors a rise of temperature decreases the resistance.<br>
-<br>
-<br>
-462&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Approximately, with the exception of iron and mercury, the resistance of<br>
-a metallic conductor varies with the absolute temperature. This is very<br>
-roughly approximate.<br>
-<br>
-Except for resistance energy would not be expended in maintaining a<br>
-current through a circuit. The resistance of a conductor may be supposed<br>
-to have its seat and cause in the jumps from molecule to molecule, which<br>
-the current has to take in going through it. If so a current confined to<br>
-a molecule would, if once started, persist because there would be no<br>
-resistance in a molecule. Hence on this theory the Amp&eacute;rian
-currents<br>
-(see Magnetism, Ampere's Theory of) would require no energy for their<br>
-maintenance and Amp&eacute;re's theory would become a possible truth.<br>
-<br>
-When metals melt their resistance suddenly increases.<br>
-<br>
-Light rays falling on some substances, notably selenium, q. v., vary the<br>
-resistance.<br>
-<br>
-Longitudinal stretching of a conductor decreases it, it increases with<br>
-longitudinal compression, and increases in iron and diminishes in tin<br>
-and zinc when a transverse stress tends to widen the conductor.<br>
-<br>
-(b) The term resistance is used to express any object or conductor used<br>
-in circuit to develop resistance.<br>
-<br>
-[Transcriber's note: At room temperatures, the thermal motion of ions in<br>
-the conductor's crystal lattice scatters the electrons of the current.<br>
-Imperfections of the lattice contribute slightly. At low temperatures<br>
-superconductivity (zero resistance) can occur because an energy gap<br>
-between the electrons and the crystal lattice prevents any interaction.<br>
-At the time of this book, none of this was known. "Jumps from molecule<br>
-to molecule" is a good guess.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Apparent.</span><br>
-Impedance; the virtual resistance of a circuit including the spurious<br>
-resistance due to counter-electromotive force. It may be made up of true<br>
-resistance and partly of an inductive reaction, as it represents the net<br>
-factor, the entire obstruction to the passage of a current, and not<br>
-merely a superadded resistance or counter-electro-motive force.<br>
-<br>
-Synonym--Impedance.<br>
-<br>
-[Transcriber's note: Impedance can also have a component due to<br>
-capacitance.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Asymmetrical.</span><br>
-Resistance which varies in amount in different directions through a<br>
-conductor. It implies a compound or composite conductor such as the<br>
-human system. The presence of counter-electro-motive force in different<br>
-parts of a conductor may bring about asymmetrical resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, B. A. Unit of.</span><br>
-The British Association Ohm. (See Ohm, B. A.)<br>
-<br>
-<br>
-463&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance Box.</span><br>
-A box filled with resistance coils. The coils are connected in series so<br>
-that a circuit including any given number has their aggregate resistance<br>
-added to its own. The terminals of consecutive coils are connected to<br>
-short blocks of brass which are secured to the top of the box, lying<br>
-flatwise upon it, nearly but not quite in contact with each other. Plugs<br>
-of brass are supplied which can go in between pairs of blocks, which<br>
-have a pair of grooves reamed out to receive them. Such plugs short<br>
-circuit the coil below them when in position. The cut shows how such<br>
-coils are connected and the use of plugs to short circuit them. The<br>
-diagram shows the top of a Wheatstone bridge, q. v., resistance box with<br>
-connections for determining resistances.<br>
-<br>
-<br>
-<img style="width: 571px; height: 419px;" alt=""
- src="images/463F291.jpg"><br>
-Fig. 291. RESISTANCE BOX.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance Box, Sliding.</span><br>
-A resistance box whose coils are set in a circle. Two metal arms with<br>
-handles are pivoted at the centre of the circle and by moving them<br>
-around they make and break contacts so as to throw the coils in and out<br>
-of circuit. The object is to permit an operator to adjust resistance<br>
-without looking at the box--an essential in duplex telegraphy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Breguet Unit of.</span><br>
-The same in origin as the Digney Unit. (See Resistance, Digney Unit of.)<br>
-<br>
-It is equal to 9.652 Legal Ohms.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Carbon.</span><br>
-A resistance, a substitute for a resistance coil; it is made of carbon,<br>
-and is of various construction. In the Brush dynamo regulator a set of<br>
-four vertical piles of plates of retort carbon, q. v., is used as a<br>
-resistance, whose resistance is made to vary by changing the pressure.<br>
-This pressure automatically increases as the current strength increases,<br>
-thus reducing the resistance.<br>
-<br>
-<br>
-464&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance Coil, Standard.</span><br>
-A standard or resistance issued by the Electric Standard Committee of<br>
-Great Britain. The cut shows the standard ohm. It is formed either of<br>
-German silver, or of an alloy of silver, 66.6 per cent. and platinum,<br>
-33.4 per cent. The wire is insulated and doubled before winding as<br>
-described before. (See Coil, Resistance.) The two ends of the wire are<br>
-soldered, each one to a heavy copper wire or rod r. The whole coil is<br>
-enclosed in a brass case, and is enclosed with paraffine melted in at A.<br>
-A place for a thermometer is provided at t. By immersing the lower part<br>
-of the case B in water of different degrees of heat any desired<br>
-temperature can be attained.<br>
-<br>
-<br>
-<img style="width: 398px; height: 577px;" alt=""
- src="images/464F292.jpg"><br>
-Fig. 292. STANDARD OHM COIL.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Combined.</span><br>
-The actual resistance of several parallel conductors starting from the<br>
-same point and ending at the same point. If the individual resistance be<br>
-a b c d .. and the combined resistance be x then we&nbsp;&nbsp; have<br>
-x = 1 / (( 1/a)&nbsp; + (1/b) + (1/c) + (1/d) + &#8230;)<br>
-<br>
-Synonym--Joint Resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Critical.</span><br>
-In a series wound dynamo the resistance of the outer circuit above which<br>
-the machine will refuse to excite itself.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Dielectric.</span><br>
-The mechanical resistance of a dielectric to the tendency to perforation<br>
-or to the strains due to electrification. This is a phase of mechanical<br>
-resistance, and is distinct from the electrical or ohmic resistance of<br>
-the same substance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Digney Unit of.</span><br>
-The resistance of an iron wire, 1 kilometer long, 4 millimeters<br>
-diameter, temperature unknown.<br>
-<br>
-It is equal to 9.163 legal ohms.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Electrolytic.</span><br>
-The resistance of an electrolyte to the passage of a current decomposing<br>
-it. It is almost entirely due to electrolysis and is added to by<br>
-counter- electro-motive force, yet it is not treated specifically as<br>
-such, but as an actual resistance. When a current of a circuit of too<br>
-low voltage to decompose an electrolyte is caused by way of immersed<br>
-terminals to pass through an electrolyte the resistance appears very<br>
-high and sometimes almost infinite. If the voltage is increased until<br>
-the electrolyte is decomposed the resistance suddenly drops, and what<br>
-should be termed electrolytic resistance, far lower than the true<br>
-resistance, appears.<br>
-<br>
-<br>
-465&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, English Absolute or
-Foot-Second Unit of.</span><br>
-A unit based on the foot and second. It is equal to (( foot / second ) *<br>
-1E7) , being based on these dimensions.<br>
-<br>
-It is equal to 0.30140 legal ohm.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Equivalent.</span><br>
-A resistance equivalent to other resistances, which may include<br>
-counter-electro-motive force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Essential.</span><br>
-The resistance of the generator in an electric circuit; the same as<br>
-internal resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, External.</span><br>
-In an electric circuit the resistance of the circuit outside of the<br>
-generator, or battery.<br>
-<br>
-Synonym--Non-essential Resistance.<br>
-<br>
-<br>
-<img style="width: 361px; height: 553px;" alt=""
- src="images/465F293.jpg"><br>
-Fig. 293. RESISTANCE FRAME.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resistance Frame.</span><br>
-An open frame filled with resistance coils of iron, or German silver<br>
-wire. It is used as a resistance for dynamos and the larger or working<br>
-class of plant. The coils are sometimes connected so that by a switch<br>
-moving over a row of studs one or more can be thrown into series<br>
-according to the stud the switch is in contact with.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, German Mile Unit of.</span><br>
-The resistance of 8,238 yards of iron wire 1/6 inch in diameter. It is<br>
-equal to 56.81 legal ohms.<br>
-<br>
-<br>
-466&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Hittorf's.</span><br>
-A high resistance, often a megohm, composed of Hittorf's solution, q. v.<br>
-It is contained in a vertical glass tube near whose upper and lower ends<br>
-are electrodes of metallic cadmium attached to platinum wires. The<br>
-cadmium is melted in glass tubes, the platinum wire is inserted into the<br>
-melted metal and the tube is broken after all is solid. The resistance<br>
-should show no polarization current.<br>
-<br>
-<br>
-<img style="width: 310px; height: 570px;" alt=""
- src="images/466F294.jpg"><br>
-Fig. 294. HITTORF'S RESISTANCE<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Inductive.</span><br>
-A resistance in which self-induction is present; such as a coil of<br>
-insulated wire wound around an iron core.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Insulation.</span><br>
-The resistance of the insulation of an insulated conductor. It is stated<br>
-in ohms per mile. It is determined by immersing a section of the line in<br>
-water and measuring the resistance between its conductor and the water.<br>
-The section must be of known length, and its ends must both be above the<br>
-liquid.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resistance, Internal.</span><br>
-The resistance of a battery, or generator in an electric circuit as<br>
-distinguished from the resistance of the rest of the circuit, or the<br>
-external resistance.<br>
-<br>
-Synonym--Essential Resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Jacobi's Unit of.</span><br>
-The resistance of a certain copper wire 25 feet long and weighing 345<br>
-grains.<br>
-<br>
-It is equal to 0.6296 legal ohm.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Matthiessen's Meter-gram
-Standard.</span><br>
-The resistance of a pure hard drawn copper wire of such diameter that<br>
-one meter of it weighs one gram. It is equal to .1434 Legal Ohms at
-0&ordm;<br>
-C. (32&ordm; F.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Matthiessen's Unit of.</span><br>
-The resistance of a standard mile of pure annealed copper wire 1/16 inch<br>
-diameter, at a temperature of 15.5&ordm; C. (60&ordm; F.).<br>
-<br>
-It is equal to 13.44 legal ohms.<br>
-<br>
-<br>
-467&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Meter-millimeter Unit of.</span><br>
-The resistance of a wire of copper one meter long and one square<br>
-millimeter in section. It is equal to .02057 ohms at 0&ordm; C.
-(32&ordm; F.) The<br>
-term may also be applied to the resistance of similar sized wire of<br>
-other metals.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Mil-foot Unit of.</span><br>
-The resistance of a foot of copper wire one-thousandth of an inch in<br>
-diameter. It is equal to 9.831 ohms at 0&ordm; C. (32&ordm; F.) The
-term may also<br>
-be applied to the resistance of similar sized wire of other metals.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Non-essential.</span><br>
-The resistance of the portion of an electric circuit not within the<br>
-generator; the same as external resistance.<br>
-<br>
-Synonym--External Resistance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Non-inductive.</span><br>
-A resistance with comparatively little or negligible self-induction.<br>
-<br>
-<span style="font-weight: bold;">Resistance of Human Body.</span><br>
-The resistance of the human body is largely a matter of perfection of<br>
-the contacts between its surface and the electrodes. It has been<br>
-asserted that it is affected by disease. From 350 to 8,000 ohms have<br>
-been determined as resistances, but so much depends on the contacts that<br>
-little value attaches to the results.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Ohmic.</span><br>
-True resistance measured in ohms as distinguished from<br>
-counter-electro-motive force, q. v. The latter is called often spurious<br>
-resistance.<br>
-<br>
-Synonym--True Resistance.<br>
-<br>
-[Transcriber's note: "True" vs. "spurious" are interesting terms,<br>
-considering that today we define impedance as a combination of "real"<br>
-resistance and "imaginary" capacitive and inductive reactance.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Reduced.</span><br>
-The resistance of a conductor reduced to ohms, or to equivalent lengths<br>
-of a column of mercury, 1 square millimeter in cross area.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Siemen's Unit of.</span><br>
-The resistance of a column of mercury 1 meter long and 1 square<br>
-millimeter cross-sectional area at 0&ordm; C. (32&ordm; F.)<br>
-<br>
-It is equal to .9431 legal ohm.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resistance, Specific.</span><br>
-The relative resistance of a substance. It is expressed as the actual<br>
-resistance of a cube of the substance which is one centimeter on each<br>
-edge. For metals it is usually expressed in microhms, for liquids in<br>
-ohms.<br>
-<br>
-The resistances of a specified length of wire of specified diameter of<br>
-different substances is often given, and is really a particular way of<br>
-stating specific resistances.<br>
-<br>
-Synonym--Specific Conduction Resistance.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resistance, Spurious.</span><br>
-The counter-electro-motive force, q. v., operating to prevent a current<br>
-being produced of what should be its full strength were the true<br>
-resistance and actuating electro-motive force only concerned. Such<br>
-counter-electro-motive force may be treated as a spurious resistance and<br>
-such a value in ohms assigned to it as would correspond to its proper<br>
-effect.<br>
-<br>
-<br>
-468&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-In its effect on opposing a current and in resisting its formation it<br>
-differs from true resistance. The latter in diminishing current strength<br>
-absorbs energy and develops heat; spurious resistance opposes and<br>
-diminishes a current without absorption of energy or production of heat.<br>
-<br>
-[Transcriber's note: "Spurious resistance" is now called reactance,<br>
-consisting of capacitive reactance and inductive reactance. The<br>
-combination of reactance and (Ohmic/true) resistance is called<br>
-impedance. The calculation of impedance requires complex algebra, not<br>
-just real values used in DC circuit analysis.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Steadying.</span><br>
-When arc lamps are connected in parallel or multiple arc a small<br>
-resistance coil is sometimes placed in series with each lamp for<br>
-steadying purposes. It reduces the percentage of variation of resistance<br>
-in each lamp, which may be caused by a change in the position of the<br>
-carbons.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resistance, Swiss Unit of.</span><br>
-A unit constructed by the "Administration Suisse," based on the same<br>
-data as the Breguet and the Digney Units. (See Resistance, Digney Unit<br>
-of)<br>
-<br>
-It is equal to 10.30 legal ohms.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Thomson's Unit of.</span><br>
-A unit of resistance based on the foot and second.<br>
-<br>
-It is equal to 0.3166 legal ohm.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Unit.</span><br>
-Unit resistance is that of a conductor in which unit current is produced<br>
-by unit electro-motive force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resistance, Varley's Unit of.</span><br>
-The resistance of a standard mile of a special copper wire 1/16 inch<br>
-diameter.<br>
-<br>
-It is equal to 25.33 ohms.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resistance, Weber's Absolute Unit.</span><br>
-A metric system unit; (meter / second) * 1E7<br>
-<br>
-It is equal to 0.9089 legal ohm.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resonance, Electric.</span><br>
-A set of phenomena known as the Hertz experiments are grouped under this<br>
-title, which phenomena are incidents of and depend on the propagation of<br>
-electric waves through wires or current conductors, as well as through<br>
-the ether. Ordinarily a wire is only a seat of current, and is in its<br>
-nature inconsistent with wave propagation through its mass. Such waves<br>
-are virtually confined to the exterior of the wire. The point is that<br>
-the current-producing force is supposed to enter the wire at all points<br>
-from without, the current not being produced by an end-push. Hence in<br>
-rapidly recurring waves which are produced by a rapidly pulsatory or<br>
-alternating current, no time is afforded for the current-producing<br>
-force, in this case the wave-producing force, to penetrate into the<br>
-substance of the wire. In one of his experiments Dr. Hertz surrounded a<br>
-wire by a glass tube chemically silvered. The coating was so thin as to<br>
-be translucent. Through this metallic layer a current could be induced<br>
-in the wire in its interior. Any mechanical layer of metal took up the<br>
-induction itself, and protected the central wire. This gave a clue to<br>
-the thickness of metal penetrated by the rapid induced waves used by Dr.<br>
-Hertz.<br>
-<br>
-<br>
-469&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 613px; height: 312px;" alt=""
- src="images/469F295.jpg"><br>
-Fig. 295. ELECTRICAL RESONANCE EXCITER.<br>
-<br>
-<br>
-The method used for the production of rapid oscillations is the<br>
-following. To the terminals of an induction coil two metal spheres AA1<br>
-are connected as shown. This apparatus is termed the exciter; in its<br>
-discharge a series of isochronous discharges takes place, alternating in<br>
-direction. The period of duration T of a single one is given by the<br>
-formula T= 2* PI * squareRoot( LC ),&nbsp; in which C is the capacity
-and L<br>
-is the self-induction. The spheres may be 30 centimeters (11.8 inches)<br>
-in diameter, connected each to conductors 0.5 centimeter (.2 inch) in<br>
-diameter and 40 centimeters (15.7 inches) long each. For the length of<br>
-an undulation the formula gives for this apparatus 4.8 meters (15.75<br>
-feet) as the length of a wave, assuming for them the velocity of<br>
-propagation equal to that of light. The exciter may have 10,000 times<br>
-the rate of oscillation possessed by the plain induction coil.<br>
-<br>
-When this apparatus is worked it produces induced waves in every<br>
-neighboring conductor. The resonance effects appear in the size of the<br>
-spark induced. Thus a wire bent into a circle with its ends nearly<br>
-touching will give a spark, but if made of proper electrostatic<br>
-capacity, corresponding with the particular waves employed, the spark<br>
-will be very much larger. The ring, with its spark gap is termed a<br>
-resonator. It is used as an explorer to trace the waves.<br>
-<br>
-Waves thus produced are transmitted by stone walls and nonconductors in<br>
-general. A plate of zinc reflects part and transmits part. The reflected<br>
-waves can be traced by the resonator, their angle of reflection being<br>
-equal to their angle of incidence. They can be received by one parabolic<br>
-reflector, reflected to another and brought to a focus. They can be<br>
-reflected so as to produce interference or loops and nodes, and the<br>
-loops and nodes can be traced by the resonator. By a prism of asphalt<br>
-they are refracted exactly like light.<br>
-<br>
-From all this it is concluded that an additional proof is furnished of<br>
-the identity of light and electro-magnetic waves, and a very strong<br>
-experimental proof of Maxwell's theory of light is furnished.<br>
-<br>
-Synonym--Hertz's Experiments.<br>
-<br>
-<br>
-470&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 640px; height: 297px;" alt=""
- src="images/470F296.jpg"><br>
-Fig. 296. ELECTRICAL RESONATOR.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resonator, Electric.</span><br>
-A small open electric circuit, with ends nearly touching. When exposed<br>
-to electric resonance, or to a sympathetic electric oscillatory<br>
-discharge, a spark passes from across the gap. The production of this<br>
-spark is altogether a matter of the inductance of the resonator. The<br>
-simplest form is a circle of copper wire with its ends nearly touching.<br>
-The length of the gap is adjustable by bending. A screw adjustment may<br>
-also be provided. Another form is shown in the cut, Fig. 296. Here<br>
-sheets of tinfoil are used to regulate the electrostatic capacity, while<br>
-at m is shown the finger piece for regulating the size of the spark gap<br>
-a.<br>
-<br>
-Synonym--Spark Micrometer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Resultant.</span><br>
-The line indicating the result of the application of two or more forces<br>
-to a point. Its direction and length give the elements of direction and<br>
-intensity. (See Forces, Resolution of Forces, Composition of<br>
-Components.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Resultant Polarity.</span><br>
-The magnetic polarity imparted to a mass of iron acted on by two or more<br>
-separate inducing forces or currents. It appears in dynamos and motors.<br>
-The final polarity is the resultant of the inducing effect of the field<br>
-magnet poles and of the windings.<br>
-<br>
-<br>
-R<span style="font-weight: bold;">etardation.</span><br>
-In telegraphy a retardation of the rate of transmission of signals. It<br>
-is due to several causes.<br>
-<br>
-(a) The self-induction of the circuit, especially if it includes many<br>
-electro-magnets, produces extra currents (see Currents, Extra.) These<br>
-are opposed to the main current on closing it and hence retard the<br>
-action. They are in the same direction on opening it and hence again<br>
-retard the action.<br>
-<br>
-(b) Every line has a certain static capacity. This is affected by the<br>
-proximity of the lines to the earth. For each signal electricity has to<br>
-be charged upon the line until the line is charged to its end with a<br>
-certain proportion of the initial density. This charging takes time and<br>
-hence introduces retardation.<br>
-<br>
-(c) The cores of the electro-magnets of the relays or sounders are not<br>
-instantly magnetized and demagnetized. This magnetic lag, q. v.,<br>
-introduces retardation.<br>
-<br>
-<br>
-471&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Retardation of Phase.</span><br>
-The fractional lagging behind of waves or alternating currents; by<br>
-lagging behind a portion of a wave length the corresponding phases, as<br>
-of full amplitude, are kept back or retarded. The phase of current<br>
-intensity may be retarded with reference to the electro-motive force by<br>
-the introduction of transformers of high capacity with high resistance<br>
-on open secondary circuits.<br>
-<br>
-[Transcriber's note: Capacitors are used to correct current phase lag.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Retentivity.</span><br>
-Coercitive or coercive force; by virtue of which steel retains its<br>
-magnetism. It is the more modern name, "coercive force" as a term being<br>
-rejected by many.<br>
-<br>
-Synonyms--Coercive Force--Coercitive Force.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Retort Carbon.</span><br>
-Carbon deposited in coal gas retorts from decomposition of the<br>
-hydrocarbons. It is a very hard, pure form, and is of graphitic<br>
-modification. Owing to its great hardness it is little used for<br>
-electrical purposes, the molded carbons being easier to make. The<br>
-deposition occurs in the regular gas-making process, and is a<br>
-disadvantage to the working.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Return.</span><br>
-A line or conductor which is supposed to carry current back to its<br>
-starting point, after it has traversed a line. It may be a wire or the<br>
-grounding of the ends of a line [or] may make the earth act as a return,<br>
-termed ground- or earth-return. The best distinction of a return is to<br>
-so term the portion of a circuit on which no apparatus is placed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reversibility.</span><br>
-The principal in virtue of which a device for producing a given form of<br>
-energy can absorb the same and do work. The reversibility of the dynamo<br>
-is its quality in virtue of which it can act as a current generator,<br>
-thereby converting mechanical energy into electric energy, or if a<br>
-current is passed through it, it rotates, doing work, and thereby<br>
-converting electric energy into mechanical energy. The knowledge of this<br>
-principle can be traced back to Jacobi in 1850.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Reversible Bridge.</span><br>
-A form of Wheatstone's Bridge adapted for reversal of the positions or<br>
-interchange of the proportionate arms, v., so that the accuracy of the<br>
-coils can be tested.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheochord.</span><br>
-An apparatus by means of which variable quantities of wire are thrown<br>
-into the circuit; a rheostat using wire. (See Rheostat, Wheatstone's.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheometer.</span><br>
-A galvanometer. (Obsolete.)<br>
-<br>
-<br>
-472&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheomotor.</span><br>
-A source of current; a current generator; a producer of potential<br>
-difference. (Obsolete.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheophore.</span><br>
-The portion of an active circuit capable of deflecting a magnetic<br>
-needle. This properly includes all of the metallic conductor of a<br>
-circuit. (Obsolete.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheoscope.</span><br>
-A galvanoscope; an instrument for qualitatively detecting potential<br>
-difference, fall or rise. (See Galvanoscope.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheostat.</span><br>
-An adjustable resistance; an apparatus for changing the resistance<br>
-without opening the circuit. Its action may depend on the introduction<br>
-of variable lengths of mercury column, of some other liquid, or of wire<br>
-into a circuit. (See Rheostat, Wheatstone's.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheostat Arm.</span><br>
-The third arm of known resistance in a Wheatstone bridge. (See<br>
-Proportionate Arms.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheostatic Machine.</span><br>
-An apparatus for increasing potential difference. It consists of a<br>
-number of static condensers. They are charged in multiple arc or in<br>
-parallel, and are discharged in series. Secondary batteries may be used<br>
-for the charging; thus a static effect is produced from a galvanic<br>
-battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheostat, Wheatstone's.</span><br>
-This apparatus consists of two cylinders, one, A, made of brass, the<br>
-other, B, of wood, with a spiral groove. At its end is a copper ring a.<br>
-A fine brass wire has one end attached to this ring. Its other end is<br>
-fastened at e, and it is wound as shown; n and o are binding screws<br>
-connected, one with the cylinder-ring a, the other with the brass<br>
-cylinder, A. The current entering at o, traverses the wire on B, as<br>
-there the windings are insulated by the grooves, thence it passes to m<br>
-and by A, whose metal short circuits all the wire on it, to the<br>
-binding-post n. The handle, d, is turned one way or the other to<br>
-regulate the length of the wire through which the current must pass. On<br>
-each cylinder there is a square head, one of which is shown at c, so<br>
-that the handle can be shifted from one to the other as required; to A<br>
-if the wire is to be wound on that cylinder, to B if the reverse is<br>
-desired.<br>
-<br>
-<br>
-<img style="width: 604px; height: 669px;" alt=""
- src="images/473F297.jpg"><br>
-Fig. 297. WHEATSTONE'S RHEOSTAT.<br>
-<br>
-<br>
-473&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheotome.</span><br>
-An automatic circuit breaker, one which rapidly opens and closes a<br>
-circuit, as in the case of the primary of an induction coil an<br>
-interrupter. (Obsolete.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rheotrope.</span><br>
-A pole changer, current reverser, or commutator, g., such as the<br>
-commutator of an induction coil. (Obsolete.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rhigolene.</span><br>
-A petroleum product; a hydrocarbon of low boiling point. Its vapor is<br>
-used in flashing (q. v.) carbon filaments for incandescent lamps.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rhumbs.</span><br>
-In a mariners' compass, the thirty-two points, designated, north, north<br>
-by east, north north east, etc. (See Compass Mariner's-Compass, Points<br>
-of the.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rhumkorff Coil.</span><br>
-The induction coil, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rigidity, Molecular.</span><br>
-The tendency of molecules to resist rotation or change of position; the<br>
-assumed cause of magnetic coercive force, or retentivity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ring Contact.</span><br>
-A contact formed by a terminal clip in the shape of a ring, split or cut<br>
-at one point so that its ends tend to spring together. The other<br>
-terminal is a bar which passes into the cut and is tightly pressed by<br>
-the elastic ring.<br>
-<br>
-<br>
-<img style="width: 681px; height: 452px;" alt=""
- src="images/474F298.jpg"><br>
-Fig. 298. SWITCH WITH RING CONTACTS.<br>
-<br>
-<br>
-474&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ring, Faraday.</span><br>
-A closed ring of iron used as the core of a transformer or induction<br>
-coil. The term is derived from Faraday's classic experiment with such an<br>
-apparatus when he produced a spark by induction in a secondary circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Roaring.</span><br>
-A term applied to the noise sometimes produced in a voltaic arc, when<br>
-the electrodes are close together and a heavy current is passing.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rocker.</span><br>
-In a dynamo the movable piece, mounted concentrically with the<br>
-commutator, and carrying the rocker-arms and brush-holders. By moving it<br>
-the brushes are adjusted for proper lead.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rocker Arms.</span><br>
-The arms projecting from a rocker and each carrying one of the<br>
-brush-holders.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Roget's Spiral.</span><br>
-An experimental apparatus for illustrating the mutual attraction of<br>
-currents going in like direction. A cylindrical helix or spiral of wire<br>
-is suspended by one end. Its lower end just dips into a mercury cup. An<br>
-active circuit is connected, one terminal to the upper end, the other<br>
-terminal to the mercury cup, bringing the apparatus in series into the<br>
-circuit. The current as it passes causes the coil to shorten, each<br>
-spiral attracting its neighbors. This breaks the circuit by drawing the<br>
-lower end out of the mercury cup. The current being cut off the coils<br>
-cease to attract each other, and the end dips into the mercury cup<br>
-again. This closes the circuit, the coils again attract each other and<br>
-the same sequence follows and is repeated over and over again. A bright<br>
-spark is produced at each break of the mercury contact.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rotation of Liquids, Electro-dynamic.</span><br>
-By passing a current through a liquid, such as dilute sulphuric acid, it<br>
-rotates if exposed to the induction of a current flowing at right angles<br>
-to it. The condition resolves itself into a liquid traversed by<br>
-horizontal currents from centre to circumference or vice versa, rotated<br>
-by a current passing through a circular conductor below it.<br>
-<br>
-<br>
-475&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rotation of Liquids, Electro-magnetic.</span><br>
-The rotation produced in a liquid carrying centripetal or centrifugal<br>
-currents by an electromagnet. It is practically an intensification of<br>
-electro-dynamic rotation. (See Rotation of Liquids, Electro-dynamic.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Rubber.</span><br>
-In a frictional electric machine the cushion of leather which is pressed<br>
-against the plate as it rotates.<br>
-</big></big><br>
-<big><big><span style="text-decoration: underline;"><br>
-</span></big></big><big><big><br>
-475&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">S.</span><br>
-(a) Symbol for second.<br>
-<br>
-(b) Symbol for space, or length; L is preferable.<br>
-<br>
-(c) Symbol for south-seeking pole of a magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Saddle Bracket.</span><br>
-A bracket carried on the top of telegraph poles, carrying an insulator<br>
-for the upper wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Safety Device.</span><br>
-(a) A device to prevent overheating of any portion of a circuit by<br>
-excess of current. It generally consists of a slip of fusible metal<br>
-which if the current attains too much strength melts and opens the<br>
-circuit. To ensure its breaking a weight is sometimes suspended from the<br>
-strip. In one form an insulated German silver wire is wrapped around the<br>
-end of the fusible strip a number of times and its end is connected to<br>
-it. The other end of the German silver wire connects with the main lead,<br>
-so that all the current goes through both in series. If the German<br>
-silver wire becomes heated from excess of current the coil wrapped<br>
-tightly around the end of the fusible strip melts it and opens the<br>
-circuit.<br>
-<br>
-(b) Lightning arresters, q. v., may be cited under this heading.<br>
-<br>
-Synonyms--Automatic Cut Out--Safety Fuse, Plug, or Strip.<br>
-<br>
-<br>
-<img style="width: 474px; height: 314px;" alt=""
- src="images/475F299.jpg"><br>
-Fig. 299. COCKBURN SAFETY FUSE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Safety Fuse.</span><br>
-A strip of metal inserted so as to form part of a circuit and of such<br>
-size that a smaller current [than] would heat the regular wire of the<br>
-circuit dangerously, so as to cause a conflagration for instance, would<br>
-melt the fuse and open the circuit. As it sometimes happens that a<br>
-safety fuse melts without parting a weight is sometimes hung upon it, so<br>
-as to break it as it softens.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Salt.</span><br>
-A salt is a chemical compound containing two atoms of two radicals,.<br>
-which saturate each other. One atom or radical is electro-positive<br>
-referred to the other, which is electro-negative. By electrolysis salts<br>
-are decomposed, the atoms or radicals separating and uniting to form new<br>
-molecules.<br>
-<br>
-<br>
-476&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Saturated. adj.</span><br>
-A liquid is saturated with a substance when it has dissolved all that it<br>
-can, while an excess is present in the liquid. It is possible, by<br>
-dissolving some salts in hot water and allowing the solution to cool<br>
-without access of air, to obtain a supersaturated solution. On<br>
-introduction of a crystal of the salt, or often on mere access of air,<br>
-the solution forms crystals and the liquid left is saturated.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Saw, Electric.</span><br>
-A platinum coated steel wire mounted and connected to be raised to<br>
-incandescence for cutting purposes.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Schweigger's Multiplier.</span><br>
-An old term for the galvanometer as invented by Schweigger soon after<br>
-Oerstedt's discovery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Scratch Brushes.</span><br>
-Brushes for cleaning the surface of articles to be electroplated to give<br>
-a good metallic surface suitable for deposition. They have often wire<br>
-instead of bristles.<br>
-<br>
-<br>
-477&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 413px; height: 657px;" alt=""
- src="images/476F300.jpg"><br>
-Fig. 300. WIRE GAUZE ELECTRIC SCREEN.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Screen, Electric.</span><br>
-A large plate or a hollow case or cage of conducting material connected<br>
-with the earth, and used to protect any body placed within it from<br>
-electrostatic influences.<br>
-<br>
-If within a hollow conducting sphere an electrified body is placed, the<br>
-inner surface of the sphere will be charged with electricity of opposite<br>
-kind to that of the sphere, and the outer surface with the same kind as<br>
-that of the sphere. Thus the sum of the electricities called into action<br>
-by induction is zero. The two inner charges are bound to each other. The<br>
-induced charge on the outer surface of the sphere is all that has any<br>
-effect on objects in the outer air.<br>
-<br>
-If the outer surface is connected to the earth it becomes discharged,<br>
-and however highly electrified the body introduced into the sphere and<br>
-the inner surface of such sphere may be, they produce no external<br>
-effects, as they are bound one to the other.<br>
-<br>
-If the sphere is connected to the earth and an unelectrified object is<br>
-placed within it, such object will be perfectly shielded from the<br>
-effects of an outer electrostatic field. Perforated tinfoil or wire<br>
-gauze has just as good a result. A large plate of metal connected to the<br>
-earth has the same effect. The screen whether plane or hollow simply<br>
-retains a bound charge due to the field of force, thereby neutralizing<br>
-it, and the electricity of the opposite sign escapes to the earth. Thus<br>
-a true shielding or screening effect is produced.<br>
-<br>
-In the cut an experiment is shown in which an electric screen is carried<br>
-by a Leyden jar. Pith balls are suspended outside and inside of it. By<br>
-the approach of an electrified body the outer pith balls will diverge,<br>
-while no effect is produced upon the inner ones.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Secondary Actions.</span><br>
-In electrolysis the direct products of the electrical decomposition are<br>
-not always obtained at the electrodes, but products due to their<br>
-reaction on the water and other chemicals may appear. These constitute<br>
-secondary actions. Thus if a solution of copper sulphate is electrolyzed<br>
-with platinum electrodes, metallic copper appears at one pole and<br>
-sulphuric acid and oxygen gas at the other. But the products of<br>
-electrolysis by the current are copper (Cu) and sulphion (SO4). The<br>
-latter reacting on water sets free oxygen gas and forms sulphuric acid.<br>
-The latter is a secondary action.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Secondary Generator.</span><br>
-(a) An alternating current converter generating a so-called secondary<br>
-current.<br>
-<br>
-(b) A secondary battery, q. v., may be thus termed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Secondary, Movable.</span><br>
-The term movable secondaries has been applied to rings, spheres and<br>
-discs of conducting material, such as copper, whose behavior when near<br>
-the pole of an electro-magnet traversed by an alternating current, have<br>
-been studied by Elihu Thomson. Such masses are subjected to very<br>
-peculiar movements and mutual reactions. As the phenomena are due to<br>
-induced currents the above term has been applied to the masses in which<br>
-the currents are induced.<br>
-<br>
-<br>
-478&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Secondary Plates, Colors of.</span><br>
-In a secondary battery of the lead plate type, the color of the plates<br>
-is a good indication of the condition of the battery. The negative plate<br>
-should be brown or deep-reddish, the other should be slate-colored.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Secondary Poles.</span><br>
-Poles sometimes found in magnets existing in positions intermediate<br>
-between the end or true poles.<br>
-<br>
-Synonym--Consequent Poles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Seebeck Effect.</span><br>
-The production of a current by heating the junction of two different<br>
-metals forming part of a circuit, or the thermo-electric production of<br>
-current, is stated as the Seebeck effect, having been discovered by that<br>
-investigator.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Selenium.</span><br>
-A non-metallic element. It is interesting electrically on account of the<br>
-changes its electric resistance undergoes when it is subjected to light.<br>
-<br>
-In one set of experiments it was found that diffused light caused the<br>
-resistance to fall in the ratio of 11 to 9. Full sunlight reduced it to<br>
-one-half. Of the spectrum colors red was most powerful and the ultra red<br>
-region still more strongly affected its resistance.<br>
-<br>
-The effect produced by exposure to light is instantaneous, but on<br>
-removal to the dark only slowly disappears.<br>
-<br>
-A vessel of hot water was found to have no effect, showing that short<br>
-ether waves are essential to the effect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Selenium Cell.</span><br>
-A selenium resistance box. Vitreous selenium is made by keeping ordinary<br>
-selenium for some hours at a temperature of about 220&ordm; C.
-(428&ordm; F.)<br>
-after fusing. It is placed in an electric circuit as part of the<br>
-conductor.<br>
-<br>
-Its resistance can then be determined. It decreases in sunlight to about<br>
-one-half its resistance in the dark.<br>
-<br>
-The selenium cell is used in the Photophone, q. v. Otherwise it is<br>
-little more than a subject of experiment.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Selenium Eye.</span><br>
-A model eye in which selenium in circuit with a battery and galvanometer<br>
-takes the place of the retina of the human eye.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Self-repulsion.</span><br>
-When a body is electrified each molecule repels its neighbor and the<br>
-condition in question is thus designated. An electrified soap-bubble<br>
-expands in virtue of self-repulsion.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Semi-conductors.</span><br>
-Substances which conduct static electricity poorly, but quite<br>
-appreciably and beyond the extent of leakage. The following are<br>
-examples: Alcohol and ether, powdered glass, flowers of sulphur, dry<br>
-wood, paper, ice at 0&ordm; C. (32&ordm; F.)<br>
-<br>
-<br>
-479&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sensibility. </span><br>
-The measure of the effect of a current upon a galvanometer,<br>
-or any similar case.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sensitiveness, Angle of Maximum.</span><br>
-Every galvanometer has its angle of maximum sensitiveness, which is the<br>
-angle of deflection at which a small increment of current will produce<br>
-the greatest deflection. For every tangent galvanometer 45&deg; is the
-angle<br>
-in question. In using a galvanometer for direct reading methods it is an<br>
-object to have it work at its angle of maximum sensitiveness.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Separately Excited Dynamo.</span><br>
-A dynamo-electric machine whose field magnet is excited from an outside<br>
-source, which may be another dynamo or a battery. Alternating current<br>
-dynamos are often of this description.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Separate Touch.</span><br>
-In magnetism a method of inducing magnetism in a steel bar. The opposite<br>
-poles of two magnets are applied at the center of the bar to be<br>
-magnetized, but without touching each other, and are drawn apart to its<br>
-ends. They are returned through the air and the process is repeated a<br>
-number of times and on both sides of the bar if necessary.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Separation of Electricities.</span><br>
-Under the double fluid theory of electricity the action of<br>
-electrification in accumulating positive electricity in one conductor<br>
-and negative on the other of the excited surfaces of two conductors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Separator.</span><br>
-India rubber bands or other forms used in batteries to keep the plates<br>
-from touching in the cell; especially applied to secondary batteries,<br>
-where the plates are so near together as to require separators to<br>
-prevent short circuiting.<br>
-<br>
-<br>
-<img style="width: 699px; height: 108px;" alt=""
- src="images/479F301.jpg"><br>
-Fig. 301. SERIES CONNECTION.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Series.</span><br>
-(a) Arranged in succession as opposed to parallel. Thus if a set of<br>
-battery jars are arranged with the zinc of one connected to the carbon<br>
-of the next one for the entire number, it is said to be arranged in<br>
-series. When incandescent lamps are arranged in succession so that the<br>
-current goes through one after the other they are arranged in series.<br>
-<br>
-The opposite of parallel, q. v., or multiple arc, q. v.; it may be used<br>
-as a noun or as an adjective.<br>
-<br>
-(b) See Electro-Chemical Series;<br>
-<br>
-(c) Thermo-Electric Series<br>
-<br>
-(d) Electrostatic Series;<br>
-<br>
-(e) Electro-motive Series.<br>
-<br>
-Synonym--Cascade Connection (but little used.)<br>
-<br>
-<br>
-480&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<span style="font-weight: bold;">Series-multiple.</span><br>
-Arrangement of electric apparatus, in which the parts are grouped in<br>
-sets in parallel and these sets are connected in series. It is used as a<br>
-noun, as "arranged in series-multiple," or as an adjective, as "a<br>
-series-multiple circuit or system."<br>
-<br>
-<br>
-<img style="width: 648px; height: 163px;" alt=""
- src="images/480F302.jpg"><br>
-Fig. 302. SERIES-MULTIPLE CONNECTION.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Service Conductors.</span><br>
-In electric distribution the equivalents of service pipes in the<br>
-distribution of gas; wires leading from the street mains to the houses,<br>
-where current is to be supplied.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Serving.</span><br>
-The wrapping or winding of a cable composed of small size wire, laid<br>
-closely and smoothly with a tool called a serving mallet, or serving<br>
-block, or by machinery. It serves to protect the cable from wear.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shackle.</span><br>
-In telegraph lines a swinging insulator bracket for use where wires make<br>
-an angle with the pole. A journal box is attached to the pole, like half<br>
-of a gate hinge. To this a short iron arm is pivoted so as to be free to<br>
-swing through a considerable angle. At its end an insulator is carried<br>
-to which the wire is attached. The shackle swings into line with the<br>
-wire, or takes a position for two wires corresponding to the resultant<br>
-of their directions of pull.<br>
-<br>
-<br>
-<img style="width: 666px; height: 397px;" alt=""
- src="images/480F303.jpg"><br>
-Fig. 303. DOUBLE SHACKLE<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shadow. Electric.</span><br>
-A term applied to a phenomenon of high vacua. If an electric discharge<br>
-is maintained in a Crookes' tube the glass opposite the negative<br>
-electrode tends to phosphoresce. A plate of aluminum, used also as the<br>
-positive electrode, protects the glass directly behind it so as to<br>
-produce the effect of a shadow.<br>
-<br>
-Synonym--Molecular Shadow.<br>
-<br>
-[Transcriber's note: The effect is due to the "shadowing" of the<br>
-electrons streaming past the plate.]<br>
-<br>
-<br>
-481&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sheath for Magnet Coils.</span><br>
-In 1867 C. E. Varley proposed the use of a copper sheath surrounding a<br>
-magnet core to diminish self-induction. It has since been used by Brush<br>
-and others. Sometimes metallic foil is laid between the successive coils<br>
-of wire.<br>
-<br>
-Synonym--Mutual Induction Protector.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sheath for Transformers.</span><br>
-A protective sheath of copper, interposed between the primary and<br>
-secondary circuits of an alternating current transformer. It is<br>
-connected to the earth. If the primary coil loses its insulation before<br>
-it can leak to the secondary it is grounded. This protects the secondary<br>
-circuit from the high electro-motive force of the primary circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shellac.</span><br>
-A resin; produced as an exudation upon the branches of certain Asiatic<br>
-trees, such as the banyan (Ficus religiosa). It is due to punctures in<br>
-the bark of the trees in question, which punctures are made by the<br>
-female of the insect coccus ficus or c. lacca.<br>
-<br>
-Commercial shellac contains about 90 per cent. of resinous material, the<br>
-rest is made up of wax, gluten, coloring matter and other substances.<br>
-<br>
-Shellac is soluble in alcohol, and in aqueous solutions of ammonium<br>
-chloride, of borax and in strong ammonia solution. Long standing is<br>
-required in the case of the last named solvent. Dilute hydrochloric and<br>
-acetic acids dissolve it readily; nitric acid slowly; strong sulphuric<br>
-acid is without action on it. Alkalies dissolve it.<br>
-<br>
-In electric work it is used as an insulator and dielectric. Its<br>
-alcoholic solution is used to varnish glass plates of influence<br>
-machines, for the coils of induction coils and similar purposes.<br>
-<br>
-Resistance in ohms per centimeter cube at 28&deg; C. (82.4
-F.)--(Ayrton),<br>
-9.0E15<br>
-<br>
-Specific Inductive Capacity (W&uuml;llner),&nbsp;&nbsp; 2.95 to 3.73<br>
-<br>
-The same substance in less pure forms occurs in commerce, as stick lac,<br>
-lump lac, seed lac, button lac.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shellac Varnish.</span><br>
-Solution of shellac in alcohol; methylic alcohol (wood alcohol or wood<br>
-naphtha) is often used as solvent.<br>
-<br>
-Dr. Muirhead recommends button lac, dissolved in absolute alcohol, and<br>
-the top layers decanted. For highest insulation he dissolves the lac in<br>
-ordinary alcohol, precipitates by dropping into water, collects the<br>
-precipitate, dries and dissolves in absolute alcohol.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shielded. adj.</span><br>
-An electric measuring instrument of the galvanometer type is shielded<br>
-when it is so constructed that its indications are not seriously<br>
-affected by the presence of neighboring magnets or by fields of force.<br>
-Shielding can be effected by using a very strong permanent magnet to<br>
-produce a field within which the magnetic needle moves and which reacts<br>
-upon it, or by enclosing the instrument in a thick iron box.<br>
-<br>
-<br>
-482&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">S. H. M.</span><br>
-Symbol or abbreviation for "simple harmonic motion."<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shock, Break.</span><br>
-A term in electro-therapeutics; the shock received when an electric<br>
-circuit, including the patient in series, is broken or opened.<br>
-<br>
-Synonym--Opening Shock.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shock, Electric.</span><br>
-The effect upon the animal system of the discharge through it of<br>
-electricity with high potential difference. Pain, nervous shock, violent<br>
-muscular contortions accompany it. Of currents, an alternating current<br>
-is reputed worse than a direct current; intermediate is the pulsatory<br>
-current.<br>
-<br>
-The voltage is the main element of shock, amperage has also some direct<br>
-influence.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shock, Static.</span><br>
-A term in electro-therapeutics. The application of static discharges<br>
-from small condensers or Leyden jars to a patient who is insulated from<br>
-the ground with one electrode applied to the conducting surface on which<br>
-he rests, while the other, a spherical electrode, is brought near the<br>
-body so as to produce a disruptive or spark discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Short Circuit.</span><br>
-A connection between two parts of a circuit, which connection is of low<br>
-resistance compared to the intercepted portion. The term is used also as<br>
-a verb, as "to short circuit a lamp."<br>
-<br>
-<br>
-<img style="width: 671px; height: 252px;" alt=""
- src="images/482F304.jpg"><br>
-Fig. 304. DIAGRAM ILLUSTRATING SHORT CIRCUIT WORKING.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Short Circuit Working.</span><br>
-A method of working intermittently an electro-magnet so as to avoid<br>
-sparking. It consists in providing a short circuit in parallel with the<br>
-magnetic coils. This short circuit is of very low resistance. To throw<br>
-the magnet into action the short circuit is opened; to throw it out of<br>
-action the short circuit is closed. The shunt or short circuit must be<br>
-of negligibly small resistance and inductance.<br>
-<br>
-<br>
-483&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Shovel Electrodes.</span><br>
-Large plate electrodes used in a medical bipolar bath. (See Bath,<br>
-Bipolar.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shunt.</span><br>
-In a current circuit a connection in parallel with a portion of the<br>
-circuit. Thus in a dynamo a special winding for the field may have its<br>
-ends connected to the bushes, from which the regular external circuit<br>
-also starts. The field is then wound in shunt with the armature. In the<br>
-case of a galvanometer a resistance coil may be put in parallel with it<br>
-to prevent too much current going through the galvanometer; this<br>
-connection is a shunt.<br>
-<br>
-The word is used as a noun, as "a shunt," or "a connection or apparatus<br>
-in shunt with another," and as an adjective, as "a shunt connection," or<br>
-as a verb, as "to shunt a battery."<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shunt Box.</span><br>
-A resistance box designed for use as a galvanometer shunt. (See Shunt,<br>
-Galvanometer.) The box contains a series of resistance coils which can<br>
-be plugged in or out as required.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shunt, Electro-magnetic.</span><br>
-In telegraphy a shunt for the receiving relay consisting of the coils of<br>
-an electro-magnet. It is placed in parallel with the relay. Its poles<br>
-are permanently connected by an armature. Thus it has high<br>
-self-induction.<br>
-<br>
-On opening and closing the circuit by the sending key, extra currents<br>
-are produced in the shunt. The connections are so arranged that on<br>
-making the circuit the extra current goes through the relay in the same<br>
-direction as the principal current, while on breaking the circuit the<br>
-induced current goes in the opposite direction.<br>
-<br>
-Thus the extra currents accelerate the production and also the cessation<br>
-of signalling currents, tending to facilitate the operations of sending<br>
-despatches.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shunt, Galvanometer.</span><br>
-A resistance placed in parallel with a galvanometer, so as to short<br>
-circuit its coils and prevent enough current passing through it to<br>
-injure it. By knowing the resistance of the shunt and of the<br>
-galvanometer coils, the proportion of current affecting the galvanometer<br>
-is known. This gives the requisite factor for calculation. (See<br>
-Multiplying Power of Shunt.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shunt Ratio.</span><br>
-The coefficient expressing the ratio existing between the current in a<br>
-shunt and in the apparatus or conductor in parallel with it. (See<br>
-Multiplying Power of/ Shunt.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shunt Winding.</span><br>
-A dynamo or motor is shunt-wound when the field magnet winding is in<br>
-shunt or in parallel with the winding of the armature.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Shuttle Current.</span><br>
-A current alternating in direction; an alternating current.<br>
-<br>
-<br>
-484&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Side-Flash.</span><br>
-A bright flashing lateral discharge from a conductor conveying a current<br>
-due to a static discharge.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sighted Position.</span><br>
-In an absolute electrometer (see Electrometer, Absolute) the position of<br>
-the balanced arm carrying the movable disc or plate, when the disc and<br>
-guard plate are in one plane. The cross-hair on the lever-end is then<br>
-seen midway between two stops, or some other equivalent position is<br>
-reached which is discerned by sighting through a magnifying glass or<br>
-telescope.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Silver.</span><br>
-A metal; one of the elements; symbol Ag.; atomic weight, 108; valency,
-1;<br>
-equivalent, 108; specific gravity, 10.5. It is a conductor of
-electricity.<br>
-&nbsp; <small style="font-family: monospace;">Relative resistance,
-annealed,&nbsp;&nbsp; 1.0<br>
-&nbsp; Specific Resistance, annealed, at 0&deg; C. (32&deg;
-F.)&nbsp;&nbsp; 1.504 microhms.<br>
-&nbsp; Resistance of a wire at 0&deg; C. (32&deg; F.),
-Annealed.&nbsp;&nbsp; Hard Drawn.<br>
-&nbsp; (a) 1 foot long, weighing 1 grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.2190 ohms&nbsp;&nbsp; .2389 ohms.<br>
-&nbsp; (b) 1 foot long, 1/1000 inch thick,&nbsp;&nbsp;&nbsp;
-9.048&nbsp;&nbsp; "&nbsp;&nbsp;&nbsp; 9.826&nbsp;&nbsp;&nbsp; "<br>
-&nbsp; (c) 1 meter long, weighing 1 gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.1527&nbsp; "&nbsp;&nbsp;&nbsp;&nbsp; .1662&nbsp;&nbsp; "<br>
-&nbsp; (d) 1 meter long, 1 millimeter thick,&nbsp;&nbsp; .01916
-"&nbsp;&nbsp;&nbsp;&nbsp; .02080&nbsp; "</small><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; <small>Resistance
-annealed of a 1-inch cube, at 0&deg; C. (32&deg;F.)
-.5921 microhms.</small></span><small><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Percentage increase in
-resistance per degree C.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (1.8 F.) at about 20&deg;
-C. (68&deg; F.), annealed,&nbsp;&nbsp;
-0.377 per cent.</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Electro-chemical
-equivalent, (Hydrogen = .0105)&nbsp;&nbsp;
-.1134 mgs.</span></small>
-<br style="font-family: monospace;">
-<br>
-<br>
-<span style="font-weight: bold;">Silver Bath.</span><br>
-A solution of a salt of silver for deposition in the electroplating<br>
-process.<br>
-<br>
-The following is a typical formula:<br>
-<span style="font-family: monospace;">&nbsp;
-<small>Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-10.0&nbsp;&nbsp; parts by weight.</small></span><small><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Potassium
-Cyanide,&nbsp;&nbsp;
-5&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-</small><span style="font-family: monospace;"><small>&nbsp; Metallic
-Silver,&nbsp;&nbsp;&nbsp;&nbsp;
-2.5&nbsp;&nbsp;&nbsp;&nbsp; "</small>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"</span><br>
-<br>
-The silver is first dissolved as nitrate and converted into cyanide and<br>
-added in that form, or for 2.5 parts metallic silver we may read:<br>
-&nbsp; Silver cyanide,&nbsp;&nbsp; 3&nbsp;&nbsp; parts by weight.<br>
-<br>
-While many other formulas have been published the above is<br>
-representative of the majority. Other solvents for the silver than<br>
-potassium cyanide have been suggested, such as sodium hyposulphite, but<br>
-the cyanide solution remains the standard.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Silver Stripping Bath.</span><br>
-Various baths are used to remove silver from old electroplated articles.<br>
-Their composition depends upon the base on which the metal is deposited.<br>
-Silvered iron articles are placed as anodes in a solution of 1 part<br>
-potassium cyanide in 20 parts of water. As kathode a silver anode or a<br>
-copper one lightly oiled may be used. From the latter the silver easily<br>
-rubs off. For copper articles a mixture of fuming sulphuric acid and<br>
-nitric acid (40&ordm; Beaum&eacute;) may be used. The presence of any
-water in this<br>
-mixture will bring about the solution of the copper. Or fuming sulphuric<br>
-acid may be heated to between 300&ordm; and 400&ordm; F., some pinches
-of dry<br>
-pulverized potassium nitrate may be thrown in and the articles at once<br>
-dipped. These methods effect the solution of the silver, leaving the<br>
-copper unattacked.<br>
-<br>
-<br>
-485&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Simple Substitution.</span><br>
-A method of obtaining a resistance equal to that of a standard. The<br>
-standard is put in circuit with a galvanometer and the deflection is<br>
-noted. For the standard another wire is substituted and its length<br>
-altered until the same deflection is produced. The two resistances are<br>
-then evidently identical. The standard can be again substituted to<br>
-confirm the result.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sine Curve.</span><br>
-If we imagine a point moved back and forth synchronously with a<br>
-pendulum, and if such point made a mark upon paper, it would trace the<br>
-same line over and over again. If now the paper were drawn steadily<br>
-along at right angles to the line of motion of the point, then the point<br>
-would trace upon it a line like the profile of a wave. Such line is a<br>
-sine curve. It derives its name from the following construction. Let a<br>
-straight line be drawn, and laid off in fractions, such as degrees, of<br>
-the perimeter of a circle of given diameter. Then on each division of<br>
-the line let a perpendicular be erected equal in height to the sine of<br>
-the angle of the circle corresponding to that division; then if the<br>
-extremities of such lines be united by a curve such curve will be a sine<br>
-curve.<br>
-<br>
-In such a curve the abscissas are proportional to the times, while the<br>
-ordinates are proportional to the sines of angles, which angles are<br>
-themselves proportional to the times. The ordinates pass through<br>
-positive and negative values alternately, while the abscissas are always<br>
-positive.<br>
-<br>
-Any number of sine curves can be constructed by varying the diameter of<br>
-the original circle, or by giving to the abscissas a value which is a<br>
-multiple of the true length of the divisions of circle. If the pendulum<br>
-method of construction were used this would be attained by giving a<br>
-greater or less velocity to the paper as drawn under the pendulum.<br>
-<br>
-A species of equation for the curve is given as follows: y = sin( x )<br>
-<br>
-In this x really indicates the arc whose length is x, and reference<br>
-should be made to the value of the radius of the circle from which the<br>
-curve is described. It will also be noticed that the equation only<br>
-covers the case in which the true divisions of the circle are laid off<br>
-on the line. If a multiple of such divisions are used, say n times, or<br>
-1-n times, then the equation should read <br>
-y = n sin( x ) or y = sin( x ) / n<br>
-<br>
-Synonyms--Curve of Sines--Sinusoidal Curve--Harmonic Curve.<br>
-<br>
-<br>
-486&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sine Law.</span><br>
-The force acting on a body is directly proportional to the sine of the<br>
-angle of deflection when--<br>
-<br>
-I. The controlling force is constant in magnitude and direction; and<br>
-<br>
-II. The deflecting force, although variable in its direction in space,<br>
-is fixed in direction relatively to the deflecting body.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Single Fluid Theory.</span><br>
-A theory of electricity. Electricity, as has been said, being<br>
-conveniently treated as a fluid or fluids, the single fluid theory<br>
-attributes electrical phenomena to the presence or absence of a single<br>
-fluid. The fluid repels itself but attracts matter; an excess creates<br>
-positive, a deficiency, negative electrification; friction, contact<br>
-action or other generating cause altering the distribution creates<br>
-potential difference or electrification. The assumed direction (see<br>
-Direction) of the current and of lines of force are based on the single<br>
-fluid theory. Like the double fluid theory, q. v., it is merely a<br>
-convenience and not the expression of a truth. (See Fluid, Electric, and<br>
-Double Fluid Theory.)<br>
-<br>
-Synonym--Franklin's Theory.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Single Fluid Voltaic Cell.</span><br>
-A galvanic couple using only a single fluid, such as the Smee or Volta<br>
-cell.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Simple Harmonic Motion.</span><br>
-Motion of a point or body back and forth along a line; the motion of a<br>
-pendulum, as regards its successive swings back and forth, is an example<br>
-of harmonic motion.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sinistrotorsal. adj.</span><br>
-The reverse of dextrotorsal, q. v. A helix with left-handed winding, the<br>
-reverse of an ordinary screw, such as a wood-screw or corkscrew.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Skin Effect.</span><br>
-A current of very brief duration does not penetrate the mass of a<br>
-conductor. Alternating currents for this reason are mainly conducted by<br>
-the outer layers of a conductor. The above is sometimes called the skin<br>
-effect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sled.</span><br>
-A contact for electric cars of the conduit system. It is identical with<br>
-the plow, q.v., but is drawn after the cars instead of being pushed<br>
-along with them.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Slide Meter Bridge.</span><br>
-A name for a Slide Bridge one meter long. There are also slide half<br>
-meter and slide quarter meter bridges and others. (See Meter Bridge.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">S. N. Code.</span><br>
-Abbreviation for single needle code, the telegraphic alphabet used with<br>
-the single needle system.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Soaking-in-and-out.</span><br>
-A term for the phenomena of the residual electrostatic charge; the<br>
-gradual acquirement or loss by a condenser of a portion of its<br>
-electrostatic charge.<br>
-<br>
-<br>
-487&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Soldering, Electric.</span><br>
-(a) Soldering in which the solder is melted by means of electricity;<br>
-either current incandescence or the voltaic arc may be used. It is<br>
-identical in general with electric welding. (See Welding, Electric.)<br>
-<br>
-(b) The deposition by electric plating of a metal over the ends of two<br>
-conductors held in contact. This secures them as if by soldering. It is<br>
-used in connecting the carbon filament of an incandescent lamp with the<br>
-platinum wires that pass through the glass. Copper is the metal usually<br>
-deposited.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Solenoid.</span><br>
-The ideal solenoid is a system of circular currents of uniform<br>
-direction, equal, parallel, of equal diameter of circle, and with their<br>
-centers lying on the same straight line, which line is perpendicular to<br>
-their planes.<br>
-<br>
-<br>
-<img style="width: 608px; height: 311px;" alt=""
- src="images/487F305.jpg"><br>
-Fig. 305. EXPERIMENTAL SOLENOID.<br>
-<br>
-<br>
-The simple solenoid as constructed of wire, is a helical coil, of<br>
-uniform diameter, so as to represent a cylinder. After completing the<br>
-coil one end of the wire is bent back and carried through the centre of<br>
-the coil, bringing thus both ends out at the same end. The object of<br>
-doing this is to cause this straight return member to neutralize the<br>
-longitudinal component of the helical turns. This it does approximately<br>
-so as to cause the solenoid for its practical action to correspond with<br>
-the ideal solenoid.<br>
-<br>
-Instead of carrying one end of the wire through the centre of the coil<br>
-as just described, both ends may be bent back and brought together at<br>
-the centre.<br>
-<br>
-A solenoid should always have this neutralization of the longitudinal<br>
-component of the helices provided for; otherwise it is not a true<br>
-solenoid.<br>
-<br>
-Solenoids are used in experiments to represent magnets and to study and<br>
-illustrate their laws. When a current goes through them they acquire<br>
-polarity, attract iron, develop lines of force and act in general like<br>
-magnets.<br>
-<br>
-A solenoid is also defined as a coil of insulated wire whose length is<br>
-not small as compared with its diameter.<br>
-<br>
-<br>
-488&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sonometer, Hughes'.</span><br>
-A sound measurer; a modification of a portion of Hughes' induction<br>
-balance, used for testing the delicacy of the ear or for determining the<br>
-relative intensity of sounds. (See Hughes' Induction Balance.) It is the<br>
-arrangement of three coils, two mounted one at each of the ends of a<br>
-graduated bar, and the third one between them and free to slide back and<br>
-forth thereon.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sonorescence.</span><br>
-The property of producing sounds under the influence of momentary light<br>
-radiations rapidly succeeding each other. It is the property utilized in<br>
-the photophone, q. v.<br>
-<br>
-<br>
-<img style="width: 629px; height: 458px;" alt=""
- src="images/488F306.jpg"><br>
-Fig. 306. MORSE SOUNDER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sounder.</span><br>
-In telegraphy an instrument consisting of an electromagnet with armature<br>
-attached to an oscillating bar, the range of whose movements is<br>
-restricted by adjusting screws. The armature is drawn away from the<br>
-magnet by a spring. When a current is sent through the magnet the<br>
-armature is drawn towards the poles and produces a sound as the bar<br>
-strikes a striking piece or second adjusting screw. When the current<br>
-ceases the bar and armature are drawn back, striking the first mentioned<br>
-screw with a distinct sound, the back stroke.<br>
-<br>
-The sounder is used to receive Morse and analogous character messages.<br>
-The forward strokes correspond to the beginnings of the dots or dashes<br>
-of the code, the back strokes to beginnings of the intervals. The<br>
-distinction between dots and dashes is made by observing the interval<br>
-between forward and back stroke.<br>
-<br>
-Various devices are used to increase the sound. Sometimes a resonance<br>
-box is used on which the sounder is mounted.<br>
-<br>
-In practice sounders are generally placed on local circuits and are<br>
-actuated by relays.<br>
-<br>
-<br>
-489&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sound Reading.</span><br>
-The art or method of receiving telegraph messages by ear. It is now<br>
-universally used by all expert Morse operators. It can only be applied<br>
-to telegraph systems producing audible sounds; in some cases, as in<br>
-needle telegraphy, it may be quite inapplicable.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Space, Clearance.</span><br>
-The space between faces of the pole pieces and the surface of the<br>
-armature in a dynamo. It is really the air gap, but in calculating<br>
-dynamo dimensions the thickness of the insulated copper wire windings of<br>
-the commutator are counted in as part of the air gap, because copper is<br>
-almost the same as air in impermeability. Clearance space is a<br>
-mechanical factor; the air gap is an electric or magnetic factor.<br>
-<br>
-Synonym--Inter-air Space.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Space, Crookes' Dark.</span><br>
-In an exhausted tube, through which an electric discharge is caused to<br>
-pass, the space surrounding the negative electrode of the tube. This<br>
-space is free from any luminous effect, and by contrast with the light<br>
-of the discharge appears dark. The vacuum may be made so high that the<br>
-dark space fills the whole space between the electrodes. It is less for<br>
-a less vacuum and varies for other factors, such as the temperature of<br>
-the negative electrode from which it originates, the kind of residual<br>
-gas present, and the quality of the spark.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Space, Faraday's Dark.</span><br>
-The space in an exhausted tube between the luminous glows about the two<br>
-electrodes.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Space, Interferric.</span><br>
-A term for the air-gap in a magnetic circuit. It is etymologically more<br>
-correct than air-gap, for the latter is often two-thirds or more filled<br>
-with the insulating material and copper wire of the armature windings.<br>
-(See Space, Clearance.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spark Arrester.</span><br>
-A screen of wire netting fitting around the carbons of an arc lamp above<br>
-the globe to prevent the escape of sparks from the carbons.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Spark Coil.</span><br>
-A coil for producing a spark from a source of comparatively low<br>
-electro-motive force. It consists of insulated wire wound round a core<br>
-of soft iron, best a bundle of short pieces of wire. Such a coil may be<br>
-eight inches long and three inches thick, and made of No. 18-20 copper<br>
-wire, with a core one inch in diameter. On connecting a battery<br>
-therewith and opening or closing the circuit, a spark is produced by<br>
-self-induction, q. v. It is used for lighting gas.<br>
-<br>
-<br>
-490&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Spark, Duration of Electric.</span><br>
-Wheatstone determined the duration of the spark given by a Leyden jar as<br>
-1/24000 second. Feddersen by interposing a tube of water 9 millimeters<br>
-(.36 inch) long in its path found that it lasted 14/10000 second, and<br>
-with one 180 millimeters (7.2 inches) long, 188/10000 second. Lucas and<br>
-Cazin for a 5 millimeter (.2 inch) spark, with different numbers of<br>
-Leyden jars, found the following:<br>
-<small><span style="font-family: monospace;">Number of
-jars.&nbsp;&nbsp; Duration of Spark.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;
-2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .000026
-second</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;
-4&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .000041 "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;
-6&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .000045 "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;
-8&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .000047 "</span></small><br>
-<br>
-The duration increases with the striking distance, and is independent of<br>
-the diameter of the balls between which it is produced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spark Gap.</span><br>
-The space left between the ends of an electric resonator (see Resonator,<br>
-Electric) across which the spark springs. Its size may be adjustable by<br>
-a screw, something like the arrangement of screw calipers.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sparking.</span><br>
-In dynamo-electric machines, the production of sparks at the commutator<br>
-between the brushes and commutator sections. The sparks are often true<br>
-voltaic arcs, and in all cases are injurious if in any quantity, wearing<br>
-out the commutator and brushes.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sparking, Line or Points of Least.</span><br>
-In a dynamo or electric motor the diameter of the commutator<br>
-determining, or the points on the commutator marking the position of the<br>
-brushes where the sparking is a minimum. Field magnets powerful in<br>
-proportion to the armature are a preventative cause. The direction of<br>
-the line fixes the angle of lead to be given to the brushes.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sparking, Resistance to.</span><br>
-The resistance to disruptive discharge through its substance offered by<br>
-a dielectric or insulator. It does not depend on its insulating<br>
-qualities, but on its rigidity and strength.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spark, Length of.</span><br>
-The length of the spark accompanying the disruptive discharge is counted<br>
-as the distance from one electrode to the other in a straight line. It<br>
-is longer for an increased potential difference between the two<br>
-electrodes. If the gas or air between the electrodes is exhausted the<br>
-length increases, until the vacuum becomes too high, when the length<br>
-begins to decrease, and for a perfect vacuum no spark however small can<br>
-be produced. The shape of the conductor which is discharged, the<br>
-material of the electrodes, and the direction of the current are all<br>
-factors affecting the length of spark producible.<br>
-<br>
-<br>
-491&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spark Tube.</span><br>
-A tube used as a gauge or test to determine when the exhaustion of the<br>
-vacuum chamber or bulb of an incandescent lamp is sufficiently high.<br>
-<br>
-The interior of the tube is connected with the interior of the bulb or<br>
-chamber of the lamps in process of exhaustion, and hence shares their<br>
-degree of exhaustion. From time to time connections with an induction<br>
-coil are made. When the exhaustion is carried far enough no discharge<br>
-will take place through the vacuum. As long as the tube acts like a<br>
-Geissler tube the exhaustion is not considered perfect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Specific Heat of Electricity.</span><br>
-The heat absorbed or given out by a fluid in passing from one<br>
-temperature to another depends on its specific heat. In the Peltier and<br>
-the Thomson effects. q. v., the electric current acts as the producer of<br>
-a change of temperature, either an increase or decrease as the case may<br>
-be. This suggests an absorption of and giving out of heat which amount<br>
-of heat corresponding to a current of known amount is determinable, and<br>
-may be referred to any unit of quantity such as the coulomb. This or<br>
-some equivalent definite quantity of heat it has been proposed (Sir<br>
-William Thomson) to term the Specific Heat of Electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spent Acid.</span><br>
-Acid which has become exhausted. In a battery the acid becomes spent<br>
-from combination with zinc. It also loses its depolarizing power, if it<br>
-is a chromic acid solution or of that type, and then may be said to be<br>
-spent.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spent Liquor.</span><br>
-The liquor of a plating bath which has become exhausted from use, the<br>
-metal it contained being all or partly deposited.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sphygmograph, Electric.</span><br>
-An electric apparatus for recording the beat of the pulse, both as<br>
-regards its rate and strength.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sphygmophone.</span><br>
-An apparatus for examination of the pulse by the microphone and<br>
-telephone.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spiders.</span><br>
-Core-discs of a dynamo or motor armature are sometimes perforated with a<br>
-large central aperture, are fastened together with insulated bolts, and<br>
-the whole mass is secured to the shaft by three- or four-armed spiders.<br>
-These are like rimless wheels, the ends of their arms being secured to<br>
-the hollow cylinder constituting the armature core, and a central<br>
-aperture in their hub receiving the shaft.<br>
-<br>
-<br>
-492&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spiral.</span><br>
-This term is sometimes used instead of coil, as the primary spiral or<br>
-secondary spiral of an induction coil or transformer.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Spiral Winding.</span><br>
-The winding used on ring armatures. This may diagrammatically be<br>
-represented by a spiral carried around the ring shaped core. With two<br>
-field poles it gives two collecting points, positive and negative, with<br>
-four field poles it gives four collecting points, alternately positive<br>
-and negative.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Splice Box.</span><br>
-A box in which the splices in underground cables and electric lines are<br>
-contained. The splicing is generally done in the boxes with the cables<br>
-in place. They may be two-way for straight lines, or be four-way for two<br>
-side or lateral connections.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spluttering.</span><br>
-A term applied to a sound sometimes produced in a voltaic arc, perhaps<br>
-caused by impure or insufficiently baked electrodes. (Elihu Thomson.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Spring Control.</span><br>
-Control of or giving the restitutive force to the needle of a<br>
-galvanometer, core of a solenoid ammeter or moving part of any similar<br>
-instrument by a spring. As an example see Ammeter, Ayrton's.<br>
-<br>
-<br>
-<img style="width: 604px; height: 358px;" alt=""
- src="images/492F307.jpg"><br>
-Fig. 307. SPRING JACKS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spring Jack.</span><br>
-An arrangement for effecting, at one insertion of a species of plug, the<br>
-opening or breaking of a circuit and for the simultaneous connection to<br>
-the terminals formed by the breaking of two terminals of another system<br>
-or loop. Thus let a line include in its circuit two springs pressing<br>
-against each other, thereby completing the circuit. If a plug or wedge<br>
-of insulating material were inserted between the springs so as to press<br>
-them apart it would break the circuit and the whole would constitute a<br>
-spring jack cut-out. If each side of the plug had a strip of brass or<br>
-copper attached to it, and if the ends of another circuit were connected<br>
-to these strips, then the insertion of the plug would throw the new line<br>
-into the circuit of the other line.<br>
-<br>
-<br>
-493&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spring Jack Cut-out.</span><br>
-A cut-out, of the general construction of a spring jack, q. v., except<br>
-that a simple insulating plug or wedge is used in place of the<br>
-metal-faced wedge with its connections of the regular spring jack. The<br>
-insertion of an insulating wedge opens the circuit, which on its removal<br>
-is closed. The regular spring jack wedge will operate in the same way,<br>
-if its connections are kept open.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Spurious Voltage.</span><br>
-The voltage in excess of that developed by a secondary battery which is<br>
-required in the charging process. It is about .25 volt.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Square Wire.</span><br>
-Wire whose cross-section is a square. It has been used of iron for<br>
-building up the cores of armatures for dynamos or motors, for which it<br>
-is peculiarly suitable, and also of copper as a winding for armatures.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Staggering. adj.</span><br>
-When the brushes of a dynamo are set, one a little in advance of the<br>
-other on the surface of the commutator, they are said to be set<br>
-staggering. It is used to get over a break in the armature circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">State, Electrotonic.</span><br>
-A term expressing an abandoned theory. Faraday at one time proposed the<br>
-theory that a wire had to be in the electrotonic state to produce<br>
-electro-motive force by movement through an electric field. Any such<br>
-idea was ultimately abandoned by Faraday.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Static Breeze.</span><br>
-The electric breeze obtained by the silent discharge of high tension<br>
-electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Static Electricity.</span><br>
-Electricity at rest or not in the current form ordinarily speaking. The<br>
-term is not very definite and at any rate only expresses a difference in<br>
-degree, not in kind. The recognition of the difference in degree has now<br>
-to a great extent also disappeared.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Station, Central.</span><br>
-The building or place in which are placed electrical apparatus, steam<br>
-engines and plant supplying a district with electric energy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Station, Distant.</span><br>
-The place at the further end of a telegraph line, as referred to the<br>
-home station.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Station, Home.</span><br>
-The end of a telegraph line where the operators using the expression are<br>
-working.<br>
-<br>
-<br>
-494&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Station, Transforming.</span><br>
-In alternating current distribution, a building or place where a number<br>
-of transformers are worked, so that low potential or secondary circuits<br>
-are distributed therefrom.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Steel.</span><br>
-A compound of iron with carbon. The carbon may range from a few<br>
-hundredths of one per cent. up to two per cent. For magnets, tool steel<br>
-drawn to a straw color or a little lower is good. All shaping and filing<br>
-should be done before magnetization.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Steeling.</span><br>
-The deposition of iron on copper plates by electrolysis. In<br>
-electrotyping a thin deposit of iron is thus given the relief plates<br>
-before printing from them. The deposit is very hard and exceedingly<br>
-thin, so that it does not interfere with the perfection of the<br>
-impression in the printing process. As the iron becomes worn it can be<br>
-dissolved off with hydrochloric acid, which does not dissolve the<br>
-copper, and a new deposit can be given it. Thus the plate may last for<br>
-an indefinite number of impressions.<br>
-<br>
-The iron bath may be prepared by immersing in a solution of ammonium<br>
-chloride, two plates of iron, connected as anode and kathode in a<br>
-circuit. One plate dissolves while hydrogen is given off from the other.<br>
-The solution thus produced is used for a bath.<br>
-<br>
-The hardness of the deposit, which is really pure iron, gives the name<br>
-of "steeling."<br>
-<br>
-Synonym--Acierage.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">St. Elmo's Fire.</span><br>
-Luminous static discharge effects sometimes seen on objects elevated in<br>
-the air. They are especially noticed on ships' masts. The sailors term<br>
-them corpusants (holy bodies). They resemble tongues or globes of fire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Step-by-step Telegraphy.</span><br>
-A system of telegraphy in which in the receiving instrument a hand is<br>
-made to move step-by-step, with an escape movement around a dial. For<br>
-each step there is a letter and the hand is made to stop at one or the<br>
-other letter until the message is spelled out. (See Dial Telegraph.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Step-down. adj.</span><br>
-A qualification applied to a converter or transformer in the alternating<br>
-current distribution, indicating that it lowers potential difference and<br>
-increases current from the secondary.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Step-up. adj.</span><br>
-The reverse of step-down; a qualification of a transformer or converter<br>
-indicating that it raises the potential and decreases the current in the<br>
-secondary.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Sticking.</span><br>
-The adherence, after the current is cut off, of the armature to the<br>
-poles of a magnet. In telegraphy it is a cause of annoyance and<br>
-obstructs the working. It may, in telegraphy, be due to too weak a<br>
-spring for drawing back the armature, or to imperfect breaking of the<br>
-contact by the despatcher's key or by the receiver's relay.<br>
-<br>
-<br>
-495&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Stopping Off.</span><br>
-In electroplating the prevention of deposition of the plating metal on<br>
-any desired portions of the object. It is effected by varnishing the<br>
-places where no coating is desired. An article can be plated with<br>
-silver, stopped off in any desired design, and the unvarnished portions<br>
-may then be plated with gold in another bath. Various effects can be<br>
-produced by such means.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Storage Capacity.</span><br>
-A term for the ampere-hours of electricity, which can be taken in<br>
-current form from a storage battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Storage of Electricity.</span><br>
-Properly speaking electricity can only be stored statically or in static<br>
-condensers, such as Leyden jars. The term has been popularly applied to<br>
-the charging of secondary or storage batteries, in which there is really<br>
-no such thing as a storage of electricity, but only a decomposition and<br>
-opposite combination brought about, which leave the battery in a<br>
-condition to give a current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Storms, Electric.</span><br>
-Wide-spread magnetic and electric disturbances, involving the<br>
-disturbance of the magnetic elements and other similar phenomena. (See<br>
-Magnetic Storms.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Strain.</span><br>
-The condition of a body when subjected to a stress. Various consequences<br>
-may ensue from strain in the way of disturbance of electric and other<br>
-qualities of the body strained.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Stratification Tube.</span><br>
-A Geissler tube, q. v., for showing the stratification of the electric<br>
-discharge through a high vacuum.<br>
-<br>
-The stratifications are greatly intensified by the presence of a little<br>
-vapor of turpentine, alcohol, bisulphide of carbon and other substances.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Stray Field.</span><br>
-In a dynamo or motor the portion of the field whose lines of force are<br>
-not cut by the armature windings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Stray Power.</span><br>
-The proportion of the energy wasted in driving a dynamo, lost through<br>
-friction and other hurtful resistances.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Streamlets, Current.</span><br>
-A conception bearing the same relation to an electric current that lines<br>
-of force do to a field of force; elementary currents. If evenly<br>
-distributed the current is of uniform density; if unevenly distributed,<br>
-as in alternating currents, the current density varies in different<br>
-parts of the cross section of the conductor. This evenness or unevenness<br>
-may be referred to the number of streamlets per unit of area of<br>
-cross-section.<br>
-<br>
-[Transcriber's note: Streamlets per unit of area is redundant with<br>
-current density.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Stress.</span><br>
-Force exercised upon a solid tending to distort it, or to produce a<br>
-strain.<br>
-<br>
-<br>
-496&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Stress, Dielectric.</span><br>
-The condition of a dielectric when maintaining a charge; its two<br>
-extremities are in opposite states of polarity, or are under permanent<br>
-potential difference. As the two opposite polarities tend to unite a<br>
-condition of stress is implied in the medium which separates them.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Stress, Electro-magnetic.</span><br>
-The stress produced upon transparent substances in an electro-magnetic<br>
-field of force. It is shown in the modified optical properties of glass<br>
-and similar substances placed between the poles of a strong<br>
-electro-magnet.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Stress, Electrostatic.</span><br>
-The stress produced upon substances in an electrostatic field of force;<br>
-the exact analogue of electro-magnetic stress, and affecting transparent<br>
-substances in the same general way.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Striae, Electric.</span><br>
-In Geissler tubes the light produced by the electric discharge is filled<br>
-with striae, bright bands alternating with dark spaces; these may be<br>
-termed electric striae.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Striking Distance.</span><br>
-The distance that separates two conductors charged with electricity of<br>
-different potential, when a spark starts between them.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Striking Solution.</span><br>
-In silver-plating a bath composed of a weak solution of silver<br>
-cyanide-with a large proportion of free potassium cyanide. It is used<br>
-with a strong current and a large silver anode. This gives an<br>
-instantaneous deposition of metallic silver over the surface of the<br>
-article which goes to insure a perfect coating in the silver bath<br>
-proper. After a few seconds in the striking solution, the article is at<br>
-once removed to the plating bath.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Stripping.</span><br>
-The removal of electroplating from an object. It may be effected in<br>
-several ways. An object whose plating is to be removed is placed in a<br>
-plating bath of the solution of the metal with which it is coated. It is<br>
-connected as the anode to the positive plate of the battery or<br>
-corresponding terminal of the generator. A kathode connected to the<br>
-other terminal being placed in the bath, the coating is dissolved by<br>
-electrolytic action. Sometimes simple treatment with acid is employed.<br>
-Different stripping baths are described under the heads of the different<br>
-metals.<br>
-<br>
-<br>
-<span style="font-weight: bold;">S. U.</span><br>
-Symbol or abbreviation for Siemens' Unit of Resistance. (See Resistance,<br>
-Siemens' Unit of.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sub-branch.</span><br>
-A branch or lead of wire taken from a branch lead: a term used in<br>
-electric distribution.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sub-main.</span><br>
-In electric distribution a conductor connected directly to a main; a<br>
-branch.<br>
-<br>
-<br>
-497&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Subway, Electric.</span><br>
-A subterranean system of conduits for electric cables. As generally<br>
-constructed in this country it includes manholes, q. v., at the street<br>
-corners connected by ducts or pipes. These pipes are large enough to<br>
-hold a cable. To introduce a cable into a duct, which latter may be two<br>
-or three inches in diameter, and from two hundred to six or seven<br>
-hundred feet long, a wire or rope is first passed through the duct. This<br>
-is done by a set of short wooden rods with screws at the end so as to be<br>
-screwed together. Each rod must be shorter than the diameter of the<br>
-manhole. A rod is thrust in, another is screwed to it and thrust in, and<br>
-thus a set of rods is made to extend as far as desired. In pulling them<br>
-out a rope is attached and drawn through. This rope or a larger one is<br>
-used in drawing the cable through the duct. A windlass is employed to<br>
-draw the rope with cable attached through the ducts.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sulphating.</span><br>
-In storage battery cells, the formation of a hard white basic lead<br>
-sulphate, Pb2 S05. Its formation is due to over-exhaustion of the cells.<br>
-As long as the voltage is not allowed to fall below 1.90 volts per cell<br>
-little of it forms. As it accumulates it is apt to drop off the plate<br>
-and fall to the bottom, thus weakening the plate possibly, and depriving<br>
-it of active material, and clogging up the cell. If it carries a film of<br>
-metallic lead with it, there is danger of short circuiting the cell.<br>
-<br>
-The presence of some sodium sulphate in the solution is said to tend to<br>
-prevent sulphating, or to diminish it.<br>
-<br>
-Sulphur Dioxide.<br>
-A compound gas, S O2; composed of<br>
-<small style="font-family: monospace;"><span
- style="font-family: monospace;">&nbsp;</span>
-Sulphur,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-32<br>
-&nbsp;
-Oxygen,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-32<br>
-&nbsp; Molecular weight,&nbsp;&nbsp; 64<br>
-&nbsp; Specific gravity,&nbsp;&nbsp;&nbsp; 2.21.</small><br>
-<br>
-It is a dielectric of about the same resistance as air. Its specific<br>
-inductive capacity at atmospheric pressure is: 1.0037 (Ayrton).<br>
-<br>
-Synonyms--Sulphurous Acid--Sulphurous Acid Gas.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sunstroke, Electric.</span><br>
-Exposure to the arc light sometimes produces the effects observed in<br>
-cases of sunstroke. It is said that, in the case of workmen at electric<br>
-furnaces, these effects are very noticeable. (See Prostration,<br>
-Electric.)<br>
-<br>
-[Transcriber's note: Effects are due to ultraviolet light.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Supersaturated. adj.</span><br>
-A liquid is supersaturated when it has dissolved a substance at a<br>
-temperature favorable to its solubility and its temperature has been<br>
-allowed to change, the liquid being kept free from agitation or access<br>
-of air, provided crystallization or precipitation has not taken place.<br>
-It expresses the state of a liquid when it holds in solution more than<br>
-the normal quantity of any substance soluble in it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Surface.</span><br>
-A galvanic battery is arranged in surface when all the positive plates<br>
-are connected together and all the negative plates are also connected.<br>
-This makes it equivalent to one large cell, the surface of whose plates<br>
-would be equal to the aggregate surface of the plates of the battery. It<br>
-is also used as an adjective, as "a surface arrangement of battery."<br>
-<br>
-<br>
-498&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Surface Density.</span><br>
-The relative quantity of an electric charge upon a surface.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Surface, Equipotential.</span><br>
-A surface over all of which the potential is the same. In a general<br>
-sense equipotential surfaces are given by planes or surfaces which cut<br>
-lines of force at right angles thereto, or which are normal to lines of<br>
-force. The conception applies to electrostatic and electro-magnetic<br>
-fields of force, and for current conductors the planes normal to the<br>
-direction of the current are equipotential surfaces.<br>
-<br>
-The contour of an equipotential surface of a field of force which is<br>
-drawn or represented by delineations of its lines of force can be<br>
-obtained by drawing a line normal thereto. This line will ordinarily be<br>
-more or less curved, and will be a locus of identical potentials.<br>
-<br>
-An electric equipotential surface may be described as electro-static,<br>
-electro- magnetic, or magnetic; or may be an equipotential surface of a<br>
-current conductor. Besides these there are mechanical and physical<br>
-equipotential surfaces, such as those of gravitation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Surface Leakage.</span><br>
-Leakage of current from one part of an insulating material to another by<br>
-the film of moisture or dirt on the surface.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Suspension.</span><br>
-This term is applied to methods of supporting galvanometer needles,<br>
-balance beams, magnetic compass needles and similar objects which must<br>
-be free to rotate. (See Suspension, Bifilar--Fibre and Spring<br>
-Suspension--Fibre Suspension--Knife Edge Suspension--Pivot<br>
-Suspension--Suspension, Torsion.)<br>
-<br>
-<br>
-<img style="width: 284px; height: 631px;" alt=""
- src="images/498F308.jpg"><br>
-Fig. 308. DIAGRAM OF BIFILAR SUSPENSION.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Suspension, Bifilar.</span><br>
-Suspension by two vertical parallel fibres, as of a galvanometer needle.<br>
-The restitution force is gravity, the torsion being comparatively slight<br>
-and negligible. Leaving torsion out of account the restitution force is<br>
-(a) proportional to the distance between the threads;. (b) inversely<br>
-proportional to their length; (c) proportional to weight of the needle<br>
-or other object suspended; (d) proportional to the angle of<br>
-displacement.<br>
-<br>
-<br>
-499&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Assume two masses A and B at the end of a weightless rod, suspended by<br>
-the parallel cords a A, b B. Let the rod be rotated through an angle<br>
-theta. Consider the cord a A. Its lower end is swung through the angle<br>
-theta, as referred to the center O; the cord is deflected from the<br>
-vertical by an angle psi, such that a A tang(psi)= O A 2 sin (theta/2).<br>
-The component of gravitation tending to restore A to A, acting towards A<br>
-is equal to m g tan(psi). Its moment around O is equal to (m g tan(psi))<br>
-* (O A cos(theta/2). The whole moment of the couple is 2 m g&nbsp;
-tan(psi).<br>
-0 A. cos(theta/2) = 2 m g (O A2/ a A) 2 sin(theta/2). Cos(theta/2) =<br>
-2mgl(OA2/aA) sin(theta). The moment of the restoring force is thus<br>
-proportional to the sine of the angle of deflection, and the<br>
-oscillations of such a system are approximately simple harmonic.<br>
-(Daniell.)<br>
-<br>
-If the twisting is carried so far as to cause the threads to cross and<br>
-come in contact with each other the suspension ceases to be a bifilar<br>
-suspension, but assumes the nature of a torsional suspension.<br>
-<br>
-<br>
-<img style="width: 755px; height: 308px;" alt="" src="images/499Fig.jpg"><br>
-[Transcriber's note: This is the image of the first paragraph.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Swaging, Electric.</span><br>
-Mechanical swaging in which the objects to be swaged are heated by an<br>
-electric current as in electric welding.<br>
-<br>
-<br>
-<span style="font-weight: bold;">S. W. G. </span><br>
-Abbreviation for Standard Wire Gauge.<br>
-<br>
-<br>
-<img style="width: 549px; height: 635px;" alt=""
- src="images/499F309.jpg"><br>
-Fig. 309. SIMPLE SWITCH.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Switch.</span><br>
-A device for opening and closing an electric circuit.<br>
-<br>
-A simple type is the ordinary telegrapher's switch. A bar of metal is<br>
-mounted horizontally by a pivot at one end, so as to be free to rotate<br>
-through an arc of a circle. In one position its free end rests upon a<br>
-stud of metal. One terminal of a circuit is attached to its journal, the<br>
-other to the stud. Resting on the stud it closes the circuit, in other<br>
-positions it opens the circuit.<br>
-<br>
-<br>
-500&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Automatic.</span><br>
-A switch opened and closed by the electric current. It is used for<br>
-lighting distant incandescent lamps. It includes one or two<br>
-electro-magnets operated by two push buttons. In the usual arrangement<br>
-one button is black and the other white, for extinguishing and lighting<br>
-respectively. When the white button is pushed it causes a current to<br>
-pass through one of the electro-magnets. This attracts its armature,<br>
-thereby making a contact and throwing the lamps into the lighting<br>
-circuit. Then they remain lighted until the black button is pressed.<br>
-This excites the other magnet, which attracts its armature, breaks the<br>
-contact and extinguishes the lights.<br>
-<br>
-The object of the automatic switch is to enable distant lamps to be<br>
-lighted without the necessity of carrying the electric leads or wires to<br>
-the place whence the lighting is to be done. A very small wire will<br>
-carry enough current to operate the magnets, and open circuit batteries,<br>
-such as Leclanch&eacute; batteries, may be used as the source of
-current for<br>
-the switch, but generally the lighting current is used for the purpose.<br>
-<br>
-A single magnet may do the work. When the lighting button is pressed the<br>
-magnet is excited, attracts its armature and holds it attracted, until<br>
-by pressing the black button the current is turned off from it. In this<br>
-case the lighting current is used to excite the magnet.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Switch Board.</span><br>
-A board or tablet to which wires are led connecting with cross bars or<br>
-other switching devices, so as to enable connections among themselves or<br>
-with other circuits to be made.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Circuit Changing.</span><br>
-A switch whose arm in its swing breaks one contact and swinging over<br>
-makes another. It is employed to change the connections of circuits from<br>
-one dynamo to another.<br>
-<br>
-Synonyms--Changing Switch--Changing Over Switch.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Switch, Double Break.</span><br>
-A form of switch in which double contact pieces are provided to give a<br>
-better contact. One form consists of a hinged bar whose end swings down<br>
-between two pairs of springs. Both pairs are connected to one terminal,<br>
-and the bar to the other terminal of a circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Double Pole.</span><br>
-A heavy switch for central station work, that connects and disconnects<br>
-two leads simultaneously.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Feeder.</span><br>
-A heavy switch, often of double contact type, for connecting and<br>
-disconnecting feeders from bus bars in central stations.<br>
-<br>
-<br>
-501&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Knife.</span><br>
-A switch whose movable arm is a narrow, deep bar of copper or brass, and<br>
-which in making contact is forced in edgeways between two springs<br>
-connected to one terminal. The bar is connected to the other terminal.<br>
-<br>
-Synonyms--Knife Break Switch--Knife Edge Switch.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Multiple.</span><br>
-A switch which in the swing of its bar connects one by one with a number<br>
-of contacts so that ultimately the end of its bar is in contact with all<br>
-at once. It is used to throw lights in and out in succession, and it<br>
-can, if the multiple contacts connect with resistances, make them<br>
-operate as a rheostat.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Switch, Pole Changing.</span><br>
-A switch for changing the direction of the current in a circuit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Switch, Reversing.</span><br>
-A switch, often of the plug type (see Plug Switch) for changing the<br>
-direction of current passing through a galvanometer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Snap.</span><br>
-A switch constructed to give a quick, sharp break. It has a spiral<br>
-spring interposed between the handle and arm. As the handle is drawn<br>
-back to open it the spring is first extended, the bar being held by the<br>
-friction of the contacts, until the spring suddenly jerks it up, thus<br>
-breaking the contact.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Switch, Storage Battery Changing.</span><br>
-A switch for changing storage battery connections from series to<br>
-multiple and back again.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Switch, Three Way.</span><br>
-A switch, so constructed that by turning its handle connection can be<br>
-made from one lead to either of two other leads, and also so that<br>
-connection can be completely cut off.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Sympathetic Vibration.</span><br>
-The establishment of periodic movement in one body by impulses of the<br>
-same period communicated to it from another body in motion. Thus if two<br>
-tuning forks are of the same pitch and one is sounded the other will<br>
-begin to sound by sympathy, the sound waves communicating the necessary<br>
-periodic impulses to it.<br>
-<br>
-Sympathetic vibrations are utilized in harmonic telegraphy. (See<br>
-Harmonic Receiver--Telegraph, Harmonic.)<br>
-</big></big><big><big><br>
-<br>
-501&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">T.</span><br>
-Symbol of time.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tailings.</span><br>
-(a) In high speed transmission of telegraph signals by the automatic<br>
-system, the definiteness of the signal marks is sometimes interfered<br>
-with by retardation. Wrong marks are thus produced called tailings.<br>
-<br>
-(b) The prolongation of the current at the distant receiving station of<br>
-a telegraph line due to the discharge of the line and to self-induction.<br>
-<br>
-Synonyms--Tailing--Tailing Current.<br>
-<br>
-<br>
-502&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tamidine.</span><br>
-Reduced nitro-cellulose. Nitro-cellulose is dissolved in a proper<br>
-solvent and is obtained by evaporation as a translucent solid mass. By<br>
-ammonium sulphide or other reagent it is reduced so as to be virtually<br>
-cellulose. It is cut into shape for filaments of incandescent lamps,<br>
-which shapes are carbonized and flashed.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tangent Law.</span><br>
-In a galvanometer the tangents of the angles of deflection of the needle<br>
-are proportional to the deflecting force--<br>
-<br>
-I.&nbsp; When the controlling force is unaltered in absolute magnitude
-and<br>
-direction by the motion of the needle.<br>
-<br>
-II. When the deflecting force acts at right angles always to the<br>
-controlling force.<br>
-<br>
-These conditions are usually secured by having the actuating coil<br>
-through which the current passes flat and of large diameter compared to<br>
-the length of the needle; by using the uniform field of the earth as the<br>
-control; by having a short needle; by placing the coil with its plane in<br>
-the magnetic meridian.<br>
-<br>
-For best proportions of tangent galvanometer coils see Bobbins.<br>
-<br>
-<br>
-<img style="width: 778px; height: 464px;" alt=""
- src="images/502F310.jpg"><br>
-Fig. 310. GRAPHIC CONSTRUCTION OF TANGENT SCALE.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tangent Scale.</span><br>
-An arc of a circle in which the number of graduations in any arc<br>
-starting from zero are proportional to the tangent of the angle<br>
-subtended by such arc. The system is for use with tangent galvanometers.<br>
-Thus if for 45&deg; a value of 100 is taken and marked on the scale
-then for<br>
-the arc 26&deg; 33' + a value of 50 should be marked on the scale
-because<br>
-such are the relative values of the tangents.<br>
-<br>
-Thus the scale instead of being divided into degrees is divided into<br>
-arcs of varying length, growing shorter as they are more distant from<br>
-the zero point, of such length that the first division being subtended<br>
-by a tangent of length 1, the first and second divisions added or taken<br>
-together as one arc are subtended by a tangent of length 2, and so on.<br>
-<br>
-In the cut a simple method of graphically laying out a tangent scale is<br>
-shown. In it C is the centre of the arc, and H the radius running to the<br>
-zero of the instrument. From C a circle is described and on H a vertical<br>
-line tangent to the arc is erected. Taking any part of the tangent, as<br>
-the length shown ending at D, it is divided into any number of equal<br>
-parts. Radii of the circle are now drawn whose prolongations pass<br>
-through the divisions on the tangent. These radii, where they intersect<br>
-the arc of the circle, determine equal divisions of the tangent scale,<br>
-which, as is evident from the construction, are unequal angular<br>
-divisions of the arc.<br>
-<br>
-<br>
-503&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tanning, Electric.</span><br>
-The tanning of hides in the manufacture of leather by the aid of<br>
-electrolysis. A current of electricity is maintained through the tanning<br>
-vats in which regular tanning liquor is contained. Very extraordinary<br>
-claims are made for the saving of time in the tanning process. What is<br>
-ordinarily a process of several months, and sometimes of a year, is said<br>
-to be reduced to one occupying a few days only. The action of<br>
-electrolysis is the one relied on to explain the results.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tapper.</span><br>
-The key used in single needle telegraph transmitters. It comprises two<br>
-flat springs L, E, each with a handle, normally pressed upward against<br>
-one contact bar Z, and when pressed down by the operator making contact<br>
-against a lower bar C when messages are to be transmitted. A double<br>
-tapper, such as shown, is used for each instrument.<br>
-<br>
-Synonyms--Double Tapper Key--Pedal Key.<br>
-<br>
-<br>
-<img style="width: 326px; height: 684px;" alt=""
- src="images/503F311.jpg"><br>
-Fig. 311. TAPPER.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Target, Electric.</span><br>
-A target registering or indicating electrically upon an annunciator the<br>
-point of impact of each bullet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Taste, Galvanic.</span><br>
-The effect produced upon the gustatory nerves by the passage of an<br>
-electric current, or by the maintenance of potential difference between<br>
-two portions of the tongue. It is very simply produced by placing a<br>
-silver coin above, and a piece of zinc below the tongue, or the reverse,<br>
-and touching their edges. A sour, peculiar taste is at once perceived.<br>
-It cannot be due to any measurable quantity of current or of<br>
-electrolytic decomposition, because the couple can do little more than<br>
-establish a potential difference. With a strong current the taste<br>
-becomes too strong for comfort, and if on a telegraph line the extra<br>
-currents produced by the signaling make the operation of tasting the<br>
-current a very unpleasant one. It is said that messages have been<br>
-received in this way, the receiver placing one terminal of the line on<br>
-his tongue, and a terminal attached to a grounded wire below it, and<br>
-then receiving the Morse characters by taste.<br>
-<br>
-<br>
-504&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Teazer.</span><br>
-Originally a fine wire coil wound on the field magnets of a dynamo in<br>
-shunt with the regular winding to maintain the magnetism. It was<br>
-originally used in electroplating machines to prevent inversion of the<br>
-magnetism, but has since developed into a component part of the winding<br>
-of the compound dynamo. (See Dynamo, Compound.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tee, Lead.</span><br>
-A lead pipe of T shape used for connecting branches to electric cables.<br>
-The tee is soldered by wiped joints to the lead sheathings of the cable<br>
-and branches after the wires have been connected, and the junctions<br>
-coated with insulating tape or cement, or both.<br>
-<br>
-It is sometimes made in two halves, and is known as a split tee.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tel-autograph.</span><br>
-A telegraph for reproducing the hand-writing of the sender at the<br>
-receiving end of the line. To save time a special spelling is sometimes<br>
-used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Teleautograph.</span><br>
-The special spelling used with the Tel-Autograph telegraph.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tele-barometer, Electric.</span><br>
-A barometer with electric attachment for indicating or recording at a<br>
-distance the barometric readings.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, ABC.</span><br>
-This term is applied to alphabet telegraphs indicating the message by<br>
-the movements of a pointer on a dial marked with the characters to be<br>
-sent. In England the Wheatstone ABC system is much employed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Automatic.</span><br>
-A telegraph system based on the operation of the transmitting instrument<br>
-by a perforated strip of paper drawn through it. The perforations made<br>
-by an apparatus termed a perforator, are so arranged as to give<br>
-telegraphic characters of the Morse or International Code in the<br>
-transmitting instrument. (See Perforator.) Bain in the year 1846 was the<br>
-originator of the system. He punched a fillet of paper with dots and<br>
-dashes, and drew it between two terminals of the line, thus sending over<br>
-the line a corresponding series of short and long currents which were<br>
-received by his chemical receiver. (See Chemical Receiver.) The method<br>
-was not successful. Its modern development, the Wheatstone Automatic<br>
-Telegraph, is highly so. The perforated paper by its perforations<br>
-controls the reciprocating movement of two rods, which pass through each<br>
-hole in two rows, corresponding to the two rods respectively as the<br>
-holes come opposite to the ends of the rods. The rods are kept<br>
-constantly moving up and down. If unperforated paper is above them their<br>
-upward motion is limited. This gives three positions for the rods, (a)<br>
-both down, (b) one up and the other down, (c) both up. These positions<br>
-of the rods work a pole changing key by which dots, spaces, and dashes<br>
-are transmitted to the receiving instrument, which is an exceedingly<br>
-delicate ink-printer. The latter can have its speed adjusted to receive<br>
-from 200 to 450 words per minute.<br>
-<br>
-<br>
-505&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Dial.</span><br>
-A telegraph in which as receiver a dial instrument is used. A pointer or<br>
-index hand moves around a dial. The dial is marked with letters of the<br>
-alphabet. The movements of the pointer are controlled by the<br>
-transmitting operator at a distant station. He by the same actions moves<br>
-a pointer on a duplicate instrument before him and the two are<br>
-synchronized to give identical indications. Thus a message is spelled<br>
-out letter by letter on both dials simultaneously. The motions of the<br>
-index are generally produced by what is virtually a recoil escapement.<br>
-The scape wheel is carried by the axle of the index, and a pallet or<br>
-anchor is vibrated by an electro-magnet whose armature is attached to<br>
-the stem of the pallet. As the pallet is vibrated it turns the wheel and<br>
-index one tooth for each single movement. There are as many teeth in the<br>
-wheel as there are characters on the dial. The two instruments being in<br>
-duplicate and synchronized, the pallets move exactly in unison, so that<br>
-identical readings of the dials are given. The pallets may be moved by<br>
-any kind of make and break mechanism, such as an ordinary telegraph key.<br>
-The index moves by steps or jerks, so that the system is sometimes<br>
-called step-by-step telegraphy.<br>
-<br>
-<br>
-<img style="width: 636px; height: 324px;" alt=""
- src="images/505F312.JPG"><br>
-Fig. 312. DIAL TELEGRAPH.<br>
-<br>
-<br>
-In the cut the make and break transmitter is shown at v v, with its<br>
-handle and contacts g and t. This mechanism sends impulses of current by<br>
-F and Z to the receiving magnet l. This attracts and releases its<br>
-armature K from contact into the position indicated by the dotted lines.<br>
-This works the rocker n on the pin o, and actuates the double or anchor<br>
-pawl s r, which turns the pallet or scrape wheel m.<br>
-<br>
-The system is dropping into disuse, being supplanted by the telephone.<br>
-<br>
-Synonym--Step-by-step Telegraph.<br>
-<br>
-<br>
-506&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Double Needle.</span><br>
-A telegraph system in which the message is read by the motions of two<br>
-vertical needles on the face of the instrument in front of the receiving<br>
-operator. An identical instrument faces the transmitting operator. By<br>
-two handles, one for each hand, the needles are caused by electric<br>
-impulses to swing to right and to left so as to give a telegraphic code.<br>
-It has been generally superseded by the single needle telegraph.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Duplex.</span><br>
-A telegraph capable of transmitting simultaneously two messages over one<br>
-wire. The methods of effecting it are distinct from those of multiplex<br>
-telegraphy. This term is used as a distinction from diode multiplex<br>
-telegraphy, in which the work is done on other principles. There are two<br>
-systems of duplex telegraphy, the differential and the bridge systems.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Duplex Bridge.</span><br>
-A system of duplex telegraphy employing the principle of the Wheatstone<br>
-bridge. The other or differential system depends on equality or<br>
-difference of currents; the bridge method on equality or difference of<br>
-potentials. The cut shows the system known as Steam's Plan.<br>
-<br>
-At the ends of the line wire are two cross connections like duplicate<br>
-galvanometer connections in a Wheatstone bridge, each including a<br>
-receiving relay. The rest of the connections are self-explanatory.<br>
-<br>
-When A depresses his key the current splits at the point indicating the<br>
-beginning of the bridge. One portion goes through the line to B and to<br>
-earth, the other goes to earth at A through the rheostats indicated by<br>
-the corrugated lines.<br>
-<br>
-On reaching B's end the current divides at the cross-connection and part<br>
-goes through the receiving relay shown in the center of that<br>
-cross-connection.<br>
-<br>
-Thus if A sends to B or B to A it is without effect on the home<br>
-receiving instrument. Now suppose that both simultaneously are sending<br>
-in opposite directions. If the connections be studied it will be seen<br>
-that every movement of the transmitting key will affect the balance of<br>
-the distant or receiving end of the bridge and so its instrument will<br>
-record the signals as they are sent.<br>
-<br>
-As shown in the cut the sending keys are on local circuits, and work<br>
-what are known as duplex transmitters. These are instruments which send<br>
-line signals without breaking the connection.<br>
-<br>
-<br>
-<img style="width: 584px; height: 350px;" alt=""
- src="images/507F313.jpg"><br>
-Fig. 313. STEARN'S PLAN OF DUPLEX BRIDGE TELEGRAPHY.<br>
-<br>
-<br>
-In Stearn's plan condensers are introduced as shown. By this plan<br>
-different receiving instruments can be used. The inventor once worked a<br>
-Morse instrument at one end of the line, and a Hughes' instrument at the<br>
-other end.<br>
-<br>
-<br>
-507&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br style="font-weight: bold;">
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph, Duplex, Differential.</span><br>
-A system of duplex telegraphy employing the differential action of two<br>
-exciting or magnetizing coils. The general principles are the following.<br>
-Suppose that at each of two stations, there is a magnet working as a<br>
-sounder or relay. Each magnet is differentially wound, with two coils of<br>
-opposite direction, of identical number of turns.<br>
-<br>
-When the sending key at a station A is depressed two exactly equal<br>
-currents go through the magnet in opposite directions. One called the<br>
-compensation current goes to the earth at the stations. The other called<br>
-the line current goes through the line, through the line coil of the<br>
-distant station E, thereby actuating the relay or sounder armature.<br>
-<br>
-The instrument of the sender A is unaffected because he is sending<br>
-opposite and equal currents through its two coils. A special resistance<br>
-is provided on the compensation circuit for keeping the currents exactly<br>
-equal in effect. Nothing the sender at A does affects his own<br>
-instrument.<br>
-<br>
-Now suppose E desires to telegraph back at the same time that A is<br>
-telegraphing to his station. He works his key. This does not affect his<br>
-own instrument except by sending the equal and opposite currents through<br>
-its coils. When his key is depressed and A's key is untouched, he works<br>
-A's receiving instrument.<br>
-<br>
-<br>
-508&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-When A's key is depressed simultaneously with B's key, the two line<br>
-currents are in opposition and neutralize each other. This throws out<br>
-the balance in the instruments and both armatures are attracted by the<br>
-compensation currents left free to act by the neutralization of the line<br>
-currents.<br>
-<br>
-<br>
-<img style="width: 652px; height: 379px;" alt=""
- src="images/508F314.jpg"><br>
-Fig. 314. DUPLEX TELEGRAPH, DIFFERENTIAL SYSTEM<br>
-<br>
-<br>
-Suppose that B is sending a dash, and it begins while A's key is raised.<br>
-The line and compensation currents in B's receiving instrument<br>
-neutralize each other and no effect is produced, while A's receiving<br>
-instrument begins to register or indicate a dash. Now suppose A starts<br>
-to send a dash while B's is half over. He depresses his key. This sends<br>
-the two opposite currents through his magnet. His line current<br>
-neutralizes B's working current so that the compensation currents in<br>
-both receiving instruments hold the armatures attracted for the two<br>
-dashes. Meanwhile A's dash ends and he releases his key. At once his<br>
-line current ceases to neutralize B's line current, his receiving<br>
-instrument is actuated now by B's line current, while B's receiving<br>
-instrument ceases to be actuated by the compensation current.<br>
-<br>
-Two assumptions are made in the above description. The line currents are<br>
-assumed to be equal in strength and opposite in direction at each<br>
-station. Neither of these is necessary. The line current received at a<br>
-station is always weaker than the outgoing line current, and it is the<br>
-preponderance of the compensation current over the partly neutralized<br>
-line current that does the work. As this preponderance is very nearly<br>
-equal to the line current received from the distant station, the signals<br>
-are actuated by almost the same current, whether it is compensation or<br>
-line current.<br>
-<br>
-<br>
-509&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Both line currents may coincide in direction. Then when the two keys are<br>
-depressed, a line current of double strength goes through both receiving<br>
-instruments and both work by preponderance of the double line current<br>
-over the compensation current. In other respects the operation is the<br>
-same as before described.<br>
-<br>
-<br>
-<img style="width: 596px; height: 343px;" alt=""
- src="images/509F315.jpg"><br>
-Fig. 315. DUPLEX TELEGRAPH, DIFFERENTIAL SYSTEM.<br>
-<br>
-<br>
-<img style="width: 557px; height: 393px;" alt=""
- src="images/509F316.jpg"><br>
-Fig. 316. DIFFERENTIAL DUPLEX TELEGRAPH CONNECTIONS.<br>
-<br>
-<br>
-The cut shows a diagram of the operation of one end of the line. R and R<br>
-are resistances, E and E are earth contacts, and the two circles show<br>
-the magnet of the receiving instrument wound with two coils in<br>
-opposition. The battery and key are also shown. It also illustrates what<br>
-happens if the key of the receiver is in the intermediate position<br>
-breaking contact at both 1 and 2. The sender's line current then goes<br>
-through both coils of the receiving instrument magnet, but this time in<br>
-series, and in coincident direction. This actuates the instrument as<br>
-before. Owing to the resistance only half the normal current passes, but<br>
-this half goes through twice as many coils or turns as if the receiver's<br>
-key was in either of the other two positions.<br>
-<br>
-In actual practice there are many refinements. To compensate for the<br>
-varying resistance of the line a rheostat or resistance with sliding<br>
-connection arm is connected in the compensation circuit so that the<br>
-resistance can be instantly changed. As the electro-static capacity of<br>
-the line varies sectional condensers are also connected in the<br>
-compensation circuits.<br>
-<br>
-<br>
-510&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph, Facsimile.</span><br>
-A telegraph for transmitting facsimiles of drawing or writing. The<br>
-methods employed involve the synchronous rotation of two metallic<br>
-cylinders, one at the transmitting end, the other at the receiving end.<br>
-<br>
-On the transmitter the design is drawn with non-conducting ink. A tracer<br>
-presses upon the surface of each cylinder and a circuit is completed<br>
-through the two contacts. In operation a sheet of chemically prepared<br>
-paper is placed over the surface of the receiving cylinder. The two<br>
-cylinders are rotated in exact synchronism and the tracers are traversed<br>
-longitudinally as the cylinders rotate. Thus a number of makes and<br>
-breaks are produced by the transmitting cylinder, and on the receiving<br>
-cylinder the chemicals in the paper are decomposed, producing marks on<br>
-the paper exactly corresponding to those on the transmitting cylinder.<br>
-<br>
-Synonyms--Autographic Telegraph--Pantelegraphy.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Harmonic Multiplex.</span><br>
-A telegraph utilizing sympathetic vibration for the transmission of<br>
-several messages at once over the same line. It is the invention of<br>
-Elisha Gray. The transmitting instrument comprises a series of vibrating<br>
-reeds or tuning-forks, each one of a different note, kept in vibration<br>
-each by its own electro-magnet. Each fork is in its own circuit, and all<br>
-unite with the main line so as to send over it a make and break current<br>
-containing as many notes superimposed as there are tuning forks. At the<br>
-other end of the line there are corresponding tuning forks, each with<br>
-its own magnet. Each fork at this end picks up its own note from the<br>
-makes and breaks on the main line, by the principle of sympathetic<br>
-vibration.<br>
-<br>
-To each pair of operators a pair of forks of identical notes are<br>
-assigned. As many messages can be transmitted simultaneously as there<br>
-are pairs of forks or reeds.<br>
-<br>
-The movements of a telegraph key in circuit with one of the transmitting<br>
-reeds sends signals of the Morse alphabet, which are picked out by the<br>
-tuning fork of identical note at the other end of the line.<br>
-<br>
-<br>
-511&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph, Hughes'.</span><br>
-A printing telegraph in very extensive use in continental Europe. Its<br>
-general features are as follows:<br>
-<br>
-The instruments at each end of the line are identical. Each includes a<br>
-keyboard like a piano manual, with a key for each letter or character.<br>
-On each machine is a type wheel, which has the characters engraved in<br>
-relief upon its face. With the wheel a "chariot" as it is termed also<br>
-rotates. The type wheels at both stations are synchronized. When a key<br>
-is depressed, a pin is thrown up which arrests the chariot, and sends a<br>
-current to the distant station. This current causes a riband of paper to<br>
-be pressed up against the face of both type wheels so as to receive the<br>
-imprint of the character corresponding to the key. The faces of the<br>
-wheels are inked by an inking roller.<br>
-<br>
-<br>
-Fig. 317. ELECTRO-MAGNET OF HUGHES' PRINTING TELEGRAPH.<br>
-<br>
-<br>
-The most characteristic feature is the fact that the current sent by<br>
-depressing a key does not attract an armature, but releases one, which<br>
-is then pulled back by a spring. The armature is restored to its<br>
-position by the mechanical operation of the instrument. The magnet used<br>
-is a polarized electro-magnet. Coils are carried on the ends of a strong<br>
-powerful magnet. The coils are so connected that a current sent through<br>
-them by depressing a key is in opposition to the magnetism of the<br>
-permanent magnet so that it tends to release the armature, and in<br>
-practice does so. This release permits the printing mechanism to act.<br>
-The latter is driven by a descending weight, so that very slight<br>
-electric currents can actuate the instruments.<br>
-<br>
-Synonym--Hughes' Type Printer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraphic Code.</span><br>
-(a) The telegraphic alphabet, as of the Morse System. (See Alphabet,<br>
-Telegraphic.)<br>
-<br>
-(b) A code for use in transmitting messages either secretly, or<br>
-comprising several words or short sentences in one word, in order to<br>
-economize in transmission. Such codes are extensively used in commercial<br>
-cable messages.<br>
-<br>
-<br>
-512&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph, Magneto-electric.</span><br>
-A telegraph in which the current is produced by magneto-electric<br>
-generators. It has been applied to a considerable extent in England. The<br>
-Wheatstone ABC or dial telegraph is operated by a magneto-generator<br>
-turned by hand.<br>
-<br>
-In this country the magneto-electric generator by which the calling bell<br>
-of a telephone is rung is an example. The magneto-electric key (See Key,<br>
-Magneto-electric) is for use in one kind of magneto-electric<br>
-telegraphing.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Morse.</span><br>
-A telegraph, characterized by the use of a relay, working a local<br>
-circuit, which circuit contains a sounder, or recorder for giving dot<br>
-and dash signals constituting the Morse alphabet. The signals are sent<br>
-by a telegraph key, which when depressed closes the circuit, and when<br>
-released opens it. The two underlying conceptions of the Morse Telegraph<br>
-system are the use of the dot and dash alphabet, and the use of the<br>
-local circuit, which circuit includes a receiving instrument, and is<br>
-worked by a relay, actuating a local battery. It would be difficult to<br>
-indicate any invention in telegraphy which has had such far-reaching<br>
-consequences as the one known as the Morse telegraph.<br>
-<br>
-In other places the principal apparatus of the system will be found<br>
-described. The cut Fig. 318, repeated here gives the general disposition<br>
-of a Morse system. (See Circuit, Local.)<br>
-<br>
-<br>
-<img style="width: 579px; height: 382px;" alt=""
- src="images/512F318.jpg"><br>
-Fig. 318. DIAGRAM OF MORSE SYSTEM.<br>
-<br>
-<br>
-513&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The key by which the messages are transmitted is shown in Fig. 319. M is<br>
-a base plate of brass. A is a brass lever, mounted on an arbor G carried<br>
-between adjustable set screws D. C is the anvil where contact is made by<br>
-depressing the key by the finger piece B of ebonite. E, Fl are adjusting<br>
-screws for regulating the vertical play of the lever. H is the switch<br>
-for opening or closing the circuit. It is opened for transmission, and<br>
-closed for receiving. By screws, L L, with wing nuts, K K, the whole is<br>
-screwed down to a table.<br>
-<br>
-<br>
-<img style="width: 620px; height: 408px;" alt=""
- src="images/513F319.jpg"><br>
-Fig. 319. MORSE TELEGRAPH KEY.<br>
-<br>
-<br>
-In the United States the simplest disposition of apparatus is generally<br>
-used. The main line is kept on closed circuit. In it may be included a<br>
-large number of relays at stations all along the line, each with its own<br>
-local circuit. There may be fifty of such stations. Battery is generally<br>
-placed at each end of the line. Very generally gravity batteries are<br>
-used, although dynamos now tend to supplant them in important stations.<br>
-<br>
-As relays the ordinary relay is used. Its local circuit includes a<br>
-sounder and local battery. The latter is very generally of the gravity<br>
-type, but oxide of copper batteries (See Battery, Oxide of Copper) are<br>
-now being introduced. At main or central offices, the terminals of the<br>
-lines reach switch boards, where by spring-jacks and plugs, any desired<br>
-circuits can be looped into the main circuit in series therewith.<br>
-<br>
-In European practise the main line is kept on open circuit. Polarized<br>
-relays are used to work the local circuits. The currents for these have<br>
-to be alternating in direction. When the line is not in use its ends are<br>
-connected to earth at both ends, leaving the battery out of circuit.<br>
-Each intermediate station has its own main, or line battery for use when<br>
-it desires to send a message. In the American system as first described,<br>
-it will be seen that the main batteries are at most two in number.<br>
-<br>
-For the details of the different apparatus, the following definitions<br>
-may be consulted: Embosser, Telegraphic--Recorder, Morse--Relay--Relay<br>
-Connection--Sounder.<br>
-<br>
-<br>
-514&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph, Multiplex.</span><br>
-A system of telegraphy by which a number of messages can be transmitted<br>
-in both directions over a single wire. The principles underlying the<br>
-systems are the following:<br>
-<br>
-Suppose that at the two extremities of a telegraph line two arms are<br>
-kept in absolute synchronous rotation. Let the arms in their rotation,<br>
-press upon as many conducting segments as there are to be transmissions<br>
-over the line. A transmitting and receiving set of instruments may be<br>
-connected to one segment at one end of the line, and another set to the<br>
-corresponding segment at the distant station. For each pair of segments<br>
-two sets can be thus connected. Then if the arm rotates so rapidly that<br>
-the contacts succeed each other rapidly enough each pair of sets of<br>
-instruments can be worked independently of the others. In practice this<br>
-rapid succession is effected by having a number of contacts made for<br>
-each pair during a single rotation of the arm or equivalent.<br>
-<br>
-The multiplex system has been perfected by the use of La Cour's phonic<br>
-wheel (see Phonic Wheel), and brought into a practical success by<br>
-Patrick B. Delany, of New York.<br>
-<br>
-Two phonic wheels rotate at each end of the line. They are kept in<br>
-synchronous motion by two vibrating steel reeds of exactly the same<br>
-fundamental note, and the axle of each wheel carries an arm whose end<br>
-trails over the contacts or distributor segments already spoken of. The<br>
-reeds are adjusted to vibrate at such speed that the trailer is in<br>
-contact with each segment about 1/500 second. The number of groups of<br>
-segments required for each working is determined by the retardation of<br>
-the signals owing to the static capacity of the line. To convert the<br>
-rapidly recurring impulses of current into practically a single current,<br>
-condensers are connected across the coils of the relay. One battery<br>
-serves for all the arms.<br>
-<br>
-Multiplex telegraphy can effect from two to six simultaneous<br>
-transmissions over one wire. For two or four transmissions the method<br>
-only distinguishes it from duplex or quadruplex telegraphy. The terms<br>
-diode, triode, tetrode, pentode and hexode working are used to indicate<br>
-respectively the simultaneous transmission of two, three, four, five, or<br>
-six messages over one wire.<br>
-<br>
-It will be seen that the multiplex process really assigns to each<br>
-transmission separate times, but divides these times into such short and<br>
-quickly recurring intervals that the work is executed as if there was<br>
-continuous contact. In no case is there the popular conception of the<br>
-sending of several messages actually simultaneously over one wire. Each<br>
-signal in reality has its own time assigned it, divided into short<br>
-periods of high frequency, and only utilizes the line when it is free.<br>
-<br>
-<br>
-515&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Over-house.</span><br>
-An English term for telegraph lines led over houses and supported on<br>
-standards on the roofs.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph Pole Brackets.</span><br>
-Arms for carrying insulators, which arms are attached to telegraph poles<br>
-or other support. They vary in style; sometimes they are straight bars<br>
-of wood gained into and bolted or spiked in place; sometimes they are of<br>
-iron.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph, Printing.</span><br>
-Various telegraphs have been invented for printing in the ordinary<br>
-alphabet the messages at the receiving end of the line.<br>
-<br>
-Representative instruments of this class are used for transmitting<br>
-different market and stock reports to business offices from the<br>
-exchanges. The type faces are carried on the periphery of a printing<br>
-wheel, which is rotated like the hand of a dial telegraph, and against<br>
-whose face a paper riband is pressed whenever the proper letter comes<br>
-opposite to it. As each letter is printed the paper moves forward the<br>
-space of one letter. Spacing between words is also provided for. In the<br>
-recent instruments two lines of letters are printed on the paper one<br>
-above the other.<br>
-<br>
-In England, and on the continent of Europe, printing instruments have<br>
-received considerable use for ordinary telegraphic work. Hughes' type<br>
-printer and Wheatstone's ABC telegraph meet with extensive use there for<br>
-ordinary transmission.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Quadruplex.</span><br>
-Duplex telegraphy is the sending of two messages in opposite directions<br>
-simultaneously through the same wire. Duplex telegraphy is the sending<br>
-of two messages simultaneously in the same direction. The two combined<br>
-constitute quadruplex telegraphy. [SIC]<br>
-<br>
-The system was suggested by Stark of Vienna and Bosscha of Leyden in<br>
-1855; the successful problem was solved by Edison in 1874.<br>
-<br>
-The principle is based on the two orders of difference in electric<br>
-currents; they may vary in strength or in direction. Thus we may have<br>
-one instrument which works with change of strength of current only, the<br>
-other with change of direction only. The two can be worked together if<br>
-the direction of the current can be altered without alteration of<br>
-strength, and if strength can be altered without alteration of<br>
-direction. Double current and single current working are so combined<br>
-that one relay works by one system of currents and another relay by the<br>
-other system. A current is constantly maintained through the line. The<br>
-relay operated by change in direction is a simple polarized relay which<br>
-works by change of direction of current. The relay operated by change in<br>
-strength is the ordinary unpolarized relay.<br>
-<br>
-<br>
-516&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-For the following description and the cuts illustrating it we are<br>
-indebted to Preece and Sivewright. The cut shows the arrangement of the<br>
-apparatus and connections for terminal offices.<br>
-<br>
-"Sufficient table room is provided to seat four clerks. The apparatus is<br>
-arranged for the two senders to sit together in the centre, the messages<br>
-to be forwarded being placed between them. The section on the left of<br>
-the switch Q is known as the 'A' side, that on the right as the 'B' side<br>
-of the apparatus.<br>
-<br>
-K1 the reversing key, reverses the direction of the current. K2 is a<br>
-simple key, known as the increment key; it is used simply to increase<br>
-the strength of the current.<br>
-<br>
-<br>
-<img style="width: 635px; height: 455px;" alt=""
- src="images/516F320.jpg"><br>
-Fig. 320. QUADRUPLEX TELEGRAPH CONNECTIONS.<br>
-<br>
-<br>
-The way in which the keys K1 and K2 combine their action is shown by<br>
-Fig. 321. E1 and E2 are the line batteries, the one having two and<br>
-one-third (2-1/3) the number of cells of the other, so that if E1 be the<br>
-electro-motive force of the smaller, that of the whole combined battery<br>
-will be 3.3 E1. The negative pole of E1 is connected to z and z1
-of&nbsp; K1<br>
-and the positive pole of E2 to a of K2 through a resistance coil s. A<br>
-wire, called the 'tap' wire, connects the positive pole of E1 and the<br>
-negative pole of E2 to b of K2. This wire has in it a resistance coil<br>
-r2. The springs c and c1 of Kl are connected to the lever L of K2. Now,<br>
-when both keys are at rest, the negative pole of E1 is to line through<br>
-z, and the positive pole of E1 to earth through b of K2 and c of K1; the<br>
-positive pole of E2 being insulated at a of K2.<br>
-<br>
-<br>
-517&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-There is thus a weak negative current flowing to line. When K1 alone is<br>
-worked, the current of E1 is reversed. When K2 is worked alone, c of K1<br>
-is transferred from b to a, and the strength of the negative current<br>
-going to line is increased through the increase of the electro-motive<br>
-force from E1 to 3.3 E1 for the whole battery is brought into play. When<br>
-K1 and K2 are depressed together, then the negative pole of E1 goes to<br>
-earth through Z1; and the positive pole of E2 to line through a of K2<br>
-and c1 of K1 and a positive current, due to the whole electro-motive<br>
-force 3.3 E1 goes to line. Hence the effect of working K1 is simply to<br>
-reverse the current, whatever its strength, while that of K2 is to<br>
-strengthen it, whatever its direction.<br>
-<br>
-The resistance coil s, of 100&deg; resistance, is called a spark coil,<br>
-because it prevents the high electro-motive force of the whole battery<br>
-from damaging the points of contact by sparking or forming an arc across<br>
-when signals are sent; and the resistance r2 is made approximately equal<br>
-to the combined resistance of E2 and the spark coil, so that the total<br>
-resistance of the circuit may not be altered by the working of the<br>
-apparatus.<br>
-<br>
-<br>
-<img style="width: 635px; height: 455px;" alt=""
- src="images/516F320.jpg"><br>
-Fig. 321. QUADRUPLEX TELEGRAPH.<br>
-<br>
-<br>
-A1 and B1 (Fig. 320) are the relays which are used to respond to the<br>
-changes in the currents sent by the keys K1 and K2 at the distant<br>
-station.<br>
-<br>
-A, is a simple polarized relay wound differentially, each wire having a<br>
-resistance of 200 [omega], and so connected up as to respond to the
-working of<br>
-the reversing key K1 of the distant station. It acts independently of<br>
-the strength of the current, and is therefore not affected by the<br>
-working of the increment key K2. It is connected up so as to complete<br>
-the local circuit of the sounder S1 and the local battery l1 and forms<br>
-the receiving portion of the 'A' side.<br>
-<br>
-B, is a non-polarized relay also wound differentially, each coil having
-<br>
-a resistance of 200 [omega]. It responds only to an increase in the <br>
-strength of the current, and therefore only to the working of the <br>
-increment key K2 of the distant station.<br>
-<br>
-[Transcriber's note: In current usage upper case omega indicates ohms
-and<br>
-lower case omega denotes angular frequency, 2*PI*f.]<br>
-<br>
-<br>
-518&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The relay spring is so adjusted that the armatures are not actuated by<br>
-the weak current sent from E by the key K1.<br>
-<br>
-In its normal position this relay completes the circuit of the local<br>
-battery through the sounder S. This sounder S, called the uprighting<br>
-sounder, acts as a relay to a second sounder, S2, called the reading<br>
-sounder, which is worked by another local battery, l2. Of course,<br>
-normally, the armature of S is held down and that of S2 is up, but when<br>
-the tongue t moves, as it does when the increment key K2 is depressed so<br>
-as to send the whole current to line, then the current from l is<br>
-interrupted, and the circuit of l2 is completed by the rising of the<br>
-armature of S, causing the reading sounder S2 to work. This is the 'B'<br>
-side.<br>
-<br>
-R is a rheostat for balancing the resistance of the line, as used in<br>
-duplex working.<br>
-<br>
-C is a condenser used for compensating the static charge of the line. It<br>
-is provided with an adjustable retardation coil, R1, to prolong the<br>
-effect of the compensating current from the condenser.<br>
-<br>
-G is a differential galvanometer, used for testing, and for facilitating<br>
-adjustment and balancing.<br>
-<br>
-Q is a switch for putting the line to earth, either for balancing, or<br>
-for any other purpose. There is on the earth wire leading from Q a<br>
-resistance coil, r1, equalling approximately the resistance of the whole<br>
-battery, 3.3 E1, and the resistance s.<br>
-<br>
-The connections shown in Fig. 321, are for an 'up' office. At a 'down'<br>
-office it is necessary to reverse the wires on the two lower terminals<br>
-of the galvanometer and the two battery wires on the reversing key K1.<br>
-<br>
-The keys K1 and K2 are, for repeaters, replaced by transmitters.<br>
-<br>
-The adjustment of this apparatus requires great care and great accuracy.<br>
-Its good working depends essentially on technical skill that can only be<br>
-acquired by patience and perseverance.<br>
-<br>
-Faults in working generally arise from careless adjustments, dirty<br>
-contacts, loose connections, battery failures, and the ordinary line<br>
-interruptions, but there are no troubles that are beyond the reach of<br>
-ordinary skill, and it can be safely said that, within moderate<br>
-distances, wherever and whenever duplex working is practicable, then<br>
-quadruplex working is so too."<br>
-<br>
-The above is a typical quadruplex bridge system. There is also a<br>
-differential system, the full description of which, in addition to what<br>
-has been given, is outside of the scope of this work.<br>
-<br>
-<br>
-519&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph Repeater.</span><br>
-An extension of the relay system, adopted for long lines. A repeating<br>
-station comprises in general terms duplicate repeating apparatus. One<br>
-set is connected for messages in one direction, the other for messages<br>
-in the opposite direction. The general operation of a repeating set is<br>
-as follows. The signals as received actuate a relay which by its local<br>
-circuit actuates a key, which in ordinary practise would be the sounder,<br>
-but in the repeater its lever opens and closes a circuit comprising a<br>
-battery and a further section of the line.<br>
-<br>
-Repeaters are placed at intervals along the line. Each repeater repeats<br>
-the signals received for the next section of line with a new battery. It<br>
-represents an operator who would receive and repeat the message, except<br>
-that it works automatically.<br>
-<br>
-The Indo-European line from London to Teheran, 3,800 miles long, is<br>
-worked directly without any hand retransmission, it being carried out by<br>
-five repeaters. This gives an average of over 500 miles for each<br>
-repeater.<br>
-[Transcriber's note: &#8230; 650 miles for each repeater.]<br>
-<br>
-Repeaters introduce retardation, and each repeater involves a reduction<br>
-in the rate of working. Yet in many cases they increase the speed of a<br>
-line greatly, as its speed is about equal to that of its worst section,<br>
-which may be far greater than that of the whole line in one.<br>
-<br>
-Synonym--Translater.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph Signal.</span><br>
-In the telegraph alphabet, a dot, or dash; the signal or effect produced<br>
-by one closing of the circuit. A dash is equal in length to three dots.<br>
-The space between signals is equal to one dot; the space between letters<br>
-to three dots; and the space between words to six dots.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telegraph, Single Needle.</span><br>
-A telegraph system in which the code is transmitted by the movements of<br>
-a needle shaped index which oscillates to right and left, the left hand<br>
-deflection corresponding to dots, the right hand deflection to dashes.<br>
-The instruments for sending and receiving are combined into one. The<br>
-needles are virtually the indexes of vertical galvanometers. In one form<br>
-by a tapper key (see Tapper), in another form by a key worked by a<br>
-drop-handle (the drop handle instrument), currents of opposite<br>
-directions are sent down the line. These pass through both instruments,<br>
-affecting both needles and causing them to swing to right or left, as<br>
-the operator moves his key.<br>
-<br>
-As galvanometer needle or actuating needle a soft iron needle is<br>
-employed, which is polarized by the proximity of two permanent magnets.<br>
-This avoids danger of reversal of polarity from lightning, a trouble<br>
-incident to the old system.<br>
-<br>
-<br>
-520&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The cut, Fig. 322, shows a single needle telegraph instrument of the<br>
-tapper form. The action of the tapper can be understood from the next<br>
-cut.<br>
-<br>
-<br>
-<img style="width: 480px; height: 683px;" alt=""
- src="images/520F322.JPG"><br>
-Fig. 322. SINGLE NEEDLE TELEGRAPH INSTRUMENT, DOUBLE<br>
-TAPPER FORM.<br>
-<br>
-<br>
-<img style="width: 269px; height: 587px;" alt=""
- src="images/520F323.JPG"><br>
-Fig. 323. DOUBLE TAPPER KEY FOR SINGLE NEEDLE TELEGRAPH.<br>
-<br>
-<br>
-C and Z are two strips of metal to which the positive and negative poles<br>
-of the battery are respectively connected. E and L are two metallic<br>
-springs; E is connected to earth, L is connected to the line; at rest<br>
-both press against Z. If L is depressed so as to touch C, the current<br>
-from the battery goes to the line by the key L, goes through the coils<br>
-of the distant instrument and deflects the needle to one side, and then<br>
-goes to the earth. If the key E is depressed, L retaining its normal<br>
-position, the direction of the current is reversed, for the other pole<br>
-of the battery is connected to the earth and the reverse current going<br>
-through the coils of the distant instrument deflects the galvanometer<br>
-needle to the other side.<br>
-<br>
-In the drop-handle type an analogous form of commutator worked by a<br>
-single handle produces the same effects.<br>
-<br>
-<br>
-521&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Wheatstone, A. B. C.</span><br>
-A magneto-electric telegraph of the dial system. An alternating current<br>
-magneto-generator is turned by hand and by depressing keys its current<br>
-is admitted to or cut off from the line and receiver's instrument. The<br>
-message is received by a dial instrument working by the escapement<br>
-motion described under Telegraph, Dial.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telegraph, Writing.</span><br>
-A telegraph in which the message is received in written characters. The<br>
-transmitter includes a stylus which is held in the hand and whose point<br>
-bears against the upper end of a vertical rod. The rod is susceptible of<br>
-oscillation in all directions, having at its base a spring support<br>
-equivalent to a universal joint.<br>
-<br>
-The stylus is moved about in the shape of letters. As it does this it<br>
-throws a series of resistances in and out of the circuit.<br>
-<br>
-At the receiving end of the line the instrument for recording the<br>
-message includes two electro-magnets with their cores at right angles to<br>
-each other and their faces near together at the point of the angle. An<br>
-armature is supported between the faces and through it a vertical rod<br>
-carried by a spring at its bottom rises. These magnets receive current<br>
-proportional to the resistances cut in and out by the motions of the<br>
-other rod at the transmitting end of the line. These resistances are<br>
-arranged in two series at right angles to each other, one for each<br>
-magnet. Thus the movements of the transmitting stylus and rod are<br>
-repeated by the end of the rod in the receiving instrument. A species of<br>
-pen is carried at the end of the rod of the receiving instrument, which<br>
-marks the letters upon a riband of paper which is fed beneath it.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telemanometer. Electric.</span><br>
-A pressure gauge with electric attachment for indicating or recording<br>
-its indications at a distance.<br>
-<br>
-It is applicable to steam boilers, so as to give the steam pressure in<br>
-any desired place.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telemeter, Electric.</span><br>
-An apparatus for electrically indicating or recording at a distance the<br>
-indications of any instrument such as a pressure gauge, barometer or<br>
-thermometer, or for similar work. The telemanometer applied to a boiler<br>
-comes into this class of instrument.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephotography.</span><br>
-The transmission of pictures by the electric current, the requisite<br>
-changes in the current being effected by the action of light upon<br>
-selenium. The picture is projected by a magic lantern. Its projection is<br>
-traversed by a selenium resistance through which the current passes.<br>
-This is moved systematically over its entire area, thus constituting the<br>
-transmitter, and synchronously with the motion of the selenium a contact<br>
-point at the other end of the line moves systematically over a sheet of<br>
-chemically prepared paper. The paper, which may be saturated with a<br>
-solution of potassium ferrocyanide and ammonium nitrate, is stained by<br>
-the passage of the current, and by the variation in intensity of<br>
-staining, which variation is due to variations in the current, produced<br>
-by the effects of the light upon the selenium, the picture is<br>
-reproduced.<br>
-<br>
-<br>
-522&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telepherage.</span><br>
-An electric transportation system, hitherto only used for the carrying<br>
-of ore, freight, etc. Its characteristic feature is that the electric<br>
-conductors, suspended from poles, supply the way on which carriages<br>
-provided with electric motors run. The motors take their current<br>
-directly from the conductors.<br>
-<br>
-There are two conducting lines, running parallel with each other,<br>
-supported at the opposite ends of transverse brackets on a row of<br>
-supporting poles. At each pole the lines cross over so that right line<br>
-alternates with left, between consecutive pairs of poles.<br>
-<br>
-The cars are suspended from pulleys running on one or the other of the<br>
-conductors. A train of such cars are connected and the current is taken<br>
-in near one end and leaves near the other end of the train. These<br>
-current connections are so distant, their distance being regulated by<br>
-the length of the train, that they are, for all but an instant at the<br>
-time of passing each of the poles, in connection with segments of the<br>
-line which are of opposite potential. To carry out this principle the<br>
-distance between contacts is equal to the distance between poles. Owing<br>
-to the crossing over of the lines the contacts are in connection as<br>
-described and thereby the actuating current is caused to go through the<br>
-motors.<br>
-<br>
-Cars running in one direction go on the electric conductors on the one<br>
-side, those running in the other direction go on the other conductor.<br>
-<br>
-A great many refinements have been introduced, but the system has been<br>
-very little used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephone.</span><br>
-An instrument for the transmission of articulate speech by the electric<br>
-current. The current is defined as of the undulatory type. (See Current,<br>
-Undulatory.)<br>
-<br>
-The cut shows what may be termed the fundamental telephone circuit. A<br>
-line wire is shown terminating in ground plates and with a telephone in<br>
-circuit at each end. The latter consists of a magnet N S with a coil of<br>
-insulated wire H surrounding one end. Facing the pole of the magnet is a<br>
-soft iron diaphragm D, held in a frame or mouthpiece T. Any change of<br>
-current in the line affects the magnetism of the magnet, causing it to<br>
-attract the diaphragm more or less. The magnet and diaphragm really<br>
-constitute a little electric motor, the diaphragm vibrating back and<br>
-forth through an exceedingly short range, for changes in the magnetic<br>
-attraction.<br>
-<br>
-The principle of the reversibility of the dynamo applies here. If the<br>
-magnet is subjected to no change in magnetism, and if the diaphragm is<br>
-moved or vibrated in front of its poles, currents will be induced in the<br>
-wire bobbin which surrounds its end. If two such magnets with bobbins<br>
-and diaphragms are arranged as shown, vibrations imparted to one<br>
-diaphragm will send currents through the line which, affecting the<br>
-magnetism of the distant magnet, will cause its diaphragm to vibrate in<br>
-exact accordance with the motions of the first or motor diaphragm. In<br>
-the combination one telephone represents a dynamo, the other a motor.<br>
-<br>
-If the vibrations of the diaphragm are imparted by the voice, the voice<br>
-with all its modulations will be reproduced by the telephone at the<br>
-distant end of the line.<br>
-<br>
-<br>
-523&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 605px; height: 202px;" alt=""
- src="images/523F324.JPG"><br>
-Fig. 324. DIAGRAM OF BELL TELEPHONES <br>
-AND LINE WITH EARTH CONNECTIONS.<br>
-<br>
-<br>
-<img style="width: 535px; height: 281px;" alt=""
- src="images/523F325.JPG"><br>
-Fig. 325. SECTION OF BELL TELEPHONE.<br>
-<br>
-<br>
-The above gives the essential features of the Bell telephone. In<br>
-practice the telephone is used only as the receiver. As transmitter a<br>
-microphone is employed. To give the current a battery, generally of the<br>
-open circuit type, is used, and the current in the line is an induced or<br>
-secondary one.<br>
-<br>
-The microphone which is talked to, and which is the seat of the current<br>
-variations which reproduce original sound, is termed the transmitter,<br>
-the telephone in which the sounds are produced at the distant end of the<br>
-line is termed the receiver.<br>
-<br>
-Fig. 325 shows the construction of the Bell telephone in universal use<br>
-in this country as the receiver. M is a bar magnet, in a case L L. B B<br>
-is a bobbin or coil of insulated wire surrounding one end of the magnet.<br>
-D is the diaphragm of soft iron plate (ferrotype metal), and E is the<br>
-mouthpiece. The terminals of the coil B B connect with the binding<br>
-screws C C. The wire in the coil is No. 36, A. W. G., and is wound to a<br>
-resistance of about 80 ohms.<br>
-<br>
-<br>
-524&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-As typical transmitter the Blake instrument may be cited. It is a carbon<br>
-microphone. It is shown in section in the cut; a is the mouthpiece and e<br>
-is a diaphragm of iron plate, although other substances could be used; f<br>
-is a steel spring, with a platinum contact piece at its end. One end<br>
-bears against the diaphragm, the other against a carbon block k. The<br>
-latter is carried by a brass block p, and pressure is maintained between<br>
-these contacts by the spring g and weight of the piece c, which by<br>
-gravity tends to press all together. The current passes by way of the<br>
-spring f, carbon button k and spring g through the circuit indicated.<br>
-<br>
-A battery is in circuit with these parts. If a telephone is also in<br>
-circuit, and the transmitter is spoken against, the diaphragm vibrating<br>
-affects the resistance of the carbon-platinum contact, without even<br>
-breaking the contact, and the telephone reproduces the sound. The heavy<br>
-piece of metal C acts by its inertia to prevent breaking of the contact.<br>
-The position of this piece c, which is carried by the brass plate m, is<br>
-adjusted by the screw n.<br>
-<br>
-<br>
-<img style="width: 279px; height: 752px;" alt=""
- src="images/524F326.JPG"><br>
-Fig. 326. SECTION OF BLAKE TRANSMITTER.<br>
-<br>
-<br>
-In practice the transmitter and battery are usually on a local circuit,<br>
-which includes the primary of an induction coil. The line and distant<br>
-receiving telephone are in circuit with the secondary of the induction<br>
-coil, without any battery.<br>
-<br>
-<span style="font-weight: bold;">Telephone, Bi-.</span><br>
-A pair of telephones carried at the ends of a curved bar or spring so<br>
-that they fit the head of a person using them. One telephone is held<br>
-against each ear without the use of the hands.<br>
-<br>
-<br>
-525&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephone, Capillary.</span><br>
-A telephone utilizing electro-capillarity for the production of<br>
-telephonic effects. The following describes the invention of Antoine<br>
-Breguet.<br>
-<br>
-The point of a glass tube, drawn out at its lower end to a capillary<br>
-opening dips vertically into a vessel. This vessel is partly filled with<br>
-mercury, over which is a layer of dilute sulphuric acid. The end of the<br>
-immersed tube dips into the acid, but does not reach the mercury. One<br>
-line contact is with mercury in the tube, the other with the mercury in<br>
-the vessel. The arrangement of tube and vessel is duplicated, giving one<br>
-set for each end of the line. On introducing a battery in the circuit<br>
-the level of the mercury is affected by electro-capillarity. The tubes<br>
-are closed by plates or diaphragms at their tops, so as to enclose a<br>
-column of air. It is evident that the pressure of this air will depend<br>
-upon the level of the mercury in the tube, and this depends on the<br>
-electro-motive force. On speaking against the diaphragm the sound waves<br>
-affect the air pressure, and consequently the level, enough to cause<br>
-potential differences which reproduce the sound in the other instrument.<br>
-<br>
-<br>
-<img style="width: 598px; height: 385px;" alt=""
- src="images/525F327.jpg"><br>
-Fig. 327. BREGURT'S CAPILLARY TELEPHONE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephone, Carbon.</span><br>
-A telephone transmitter based on the use of carbon as a material whose<br>
-resistance is varied by the degree of pressure brought to bear upon it.<br>
-Undoubtedly the surface contact between the carbon and the other<br>
-conducting material has much to do with the action. Many carbon<br>
-telephones have been invented. Under Telephone the Blake transmitter is<br>
-described, which is a carbon telephone transmitter. The Edison carbon<br>
-transmitter is shown in section in the cut. E is the mouth piece and D<br>
-the diaphragm. I is a carbon disc with adjusting screw V. A platinum<br>
-plate B B, with ivory button b, is attached to the upper surface of the<br>
-carbon disc. C C is an insulating ring. The wire connections shown bring<br>
-the disc into circuit. It is connected like a Blake transmitter. It is<br>
-now but little used.<br>
-<br>
-<br>
-<img style="width: 730px; height: 518px;" alt=""
- src="images/526F328.JPG"><br>
-Fig. 328. SECTION OF EDISON CARBON TRANSMITTER.<br>
-<br>
-<br>
-526&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telephone, Chemical.</span><br>
-A telephone utilizing chemical or electrolytic action in transmitting or<br>
-receiving. The electro-motograph is an example of a chemical receiver.<br>
-(See Electro-motograph.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephone, Electrostatic.</span><br>
-A telephone utilizing electrostatic disturbances for reproduction of the<br>
-voice. In the cut D and C are highly charged electrophori. The<br>
-diaphragms A and B when spoken to affect the potential of the<br>
-electrophorus so as to produce current variations which will reproduce<br>
-the sound. Dolbear and others have invented other forms of transmitters<br>
-based on electrostatic action. Receivers have also been constructed. A<br>
-simple condenser may be made to reproduce sound by being connected with<br>
-a powerful telephone current.<br>
-<br>
-<br>
-<img style="width: 550px; height: 197px;" alt=""
- src="images/526F329.JPG"><br>
-Fig. 329. DIAGRAM OF EDISON'S ELECTROSTATIC TELEPHONE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephone Induction Coil.</span><br>
-The induction coil used in telephone circuits for inducing current on<br>
-the main line. It is simply a small coil wound with two separate<br>
-circuits of insulated wire. In the Edison telephone the primary coil, in<br>
-circuit with the transmitter, is of No. 18 to 24 wire and of 3 to 4 ohms<br>
-resistance. The secondary in circuit with the line and receiving<br>
-instrument is of No. 36 wire and of 250 ohms resistance. The Bell<br>
-telephone induction coil has its primary of No. 18 to 24 wire wound to a<br>
-resistance of 1/2 ohm, and its secondary of No. 36 wire, and of 80 ohms<br>
-resistance.<br>
-<br>
-<br>
-527&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Telephone, Reaction.</span><br>
-A form of telephone containing two coils of insulated wire, one of which<br>
-is mounted on the disc, and the other on the magnet pole in the usual<br>
-way. These coils react upon each other so as to strengthen the effect.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephone, Thermo-electric.</span><br>
-A telephone transmitter including a thermo-electric battery, placed in<br>
-circuit with the line. A plate of vulcanite faces it. When the sound<br>
-waves strike the vulcanite they move it backward and forward. These<br>
-movements, owing to the elasticity of the vulcanite, produce minute<br>
-changes of temperature in it, which affecting the thermo-electric pile<br>
-produce in the circuit currents, which passing through a Bell telephone<br>
-cause it to speak. This type of instrument has never been adopted in<br>
-practice.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Telephote.</span><br>
-An apparatus for transmitting pictures electrically, the properties of<br>
-selenium being utilized for the purpose.<br>
-<br>
-Synonym--Pherope.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Teleseme.</span><br>
-An annunciator, displaying on a dial the object wanted by the person<br>
-using it. It is employed to transmit messages from rooms in a hotel to<br>
-the office, or for similar functions.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tele-thermometer.</span><br>
-A thermometer with electric attachment for indicating or recording its<br>
-indications at a distance.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tempering, Electric.</span><br>
-A process of tempering metals by electrically produced heat. The article<br>
-is made part of an electric circuit. The current passing through it<br>
-heats it, thereby tempering it. For wire the process can be made<br>
-continuous. The wire is fed from one roll to another, and if required<br>
-one roll may be immersed in a liquid bath or the wire between the rolls<br>
-may be led therein. The current is brought to one roll and goes through<br>
-the wire to the other. As it does this the wire is constantly fed from<br>
-one roll to another. The bath may be used as described to cool it after<br>
-the heating. The amount of heating may be regulated by the rate of<br>
-motion of the wire.<br>
-<br>
-<br>
-528&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Ten, Powers of.</span><br>
-This adjunct to calculations has become almost indispensable in working<br>
-with units of the C. G. S. system. It consists in using some power of 10<br>
-as a multiplier which may be called the factor. The number multiplied<br>
-may be called the characteristic. The following are the general<br>
-principles.<br>
-<br>
-The power of 10 is shown by an exponent which indicates the number of<br>
-ciphers in the multiplier. Thus 10^2 indicates 100; 10^3 indicates 1,000<br>
-and so on.<br>
-<br>
-The exponent, if positive, denotes an integral number, as shown in the<br>
-preceding paragraph. The exponent, if negative, denotes the reciprocal<br>
-of the indicated power of 10. Thus 10^-2 indicates 1/100; 10^-3
-indicates<br>
-1/1000 and so on.<br>
-<br>
-The compound numbers based on these are reduced by multiplication or<br>
-division to simple expressions. Thus: 3.14 X 10^7 = 3.14 X 10,000,000 =<br>
-31,400,000. 3.14 X 10^-7 = 3.14/10,000,000 or 314/1000000000. Regard
-must<br>
-be paid to the decimal point as is done here.<br>
-<br>
-To add two or more expressions in this notation if the exponents of the<br>
-factors are alike in all respects, add the characteristics and preserve<br>
-the same factor. Thus:<br>
-<br>
-&nbsp; (51X 10^6) + (54 X 10^6) = 105 X 10^6.<br>
-&nbsp; (9.1 X 10^-9) + (8.7 X 10^-9) = 17.8 X 10^-9.<br>
-<br>
-To subtract one such expression from another, subtract the<br>
-characteristics and preserve the same factor. Thus:<br>
-<br>
-&nbsp; (54 X 10^6) - (51 X 10^6) = 3 X 10^6.<br>
-<br>
-If the factors have different exponents of the same sign the factor or<br>
-factors of larger exponent must be reduced to the smaller exponent, by<br>
-factoring. The characteristic of the expression thus treated is<br>
-multiplied by the odd factor. This gives a new expression whose<br>
-characteristic is added to the other, and the factor of smaller exponent<br>
-is preserved for both,<br>
-<br>
-Thus:<br>
-&nbsp; (5 X 10^7) + (5 X10^9) = (5 X 10^7) + (5 X 100 X 10^7) = 505 X
-10^7.<br>
-<br>
-The same applies to subtraction. Thus:<br>
-&nbsp; (5 X 10^9) - (5 X 10^7) = (5 X 100 X 10^7) - (5 X 10^7) = 495 X
-10^7.<br>
-<br>
-If the factors differ in sign, it is generally best to leave the<br>
-addition or subtraction to be simply expressed. However, by following<br>
-the above rule, it can be done. Thus:<br>
-<br>
-Add<br>
-&nbsp; 5 X 10^-2 and 5 X 10^3.<br>
-&nbsp; 5 X 10^3 = 5 X 10^5 X 10^-2<br>
-&nbsp; (5 X 10^5 X 10^-2) + (5 X 10^-2) = 500005 X 10^-2<br>
-<br>
-This may be reduced to a fraction 500000/100 = 5000.05.<br>
-<br>
-To multiply add the exponents of the factors, for the new factor, and<br>
-multiply the characteristics for a new characteristic. The exponents<br>
-must be added algebraically; that is, if of different signs the<br>
-numerically smaller one is subtracted from the other one, and its sign<br>
-is given the new exponent.<br>
-<br>
-Thus;<br>
-&nbsp; (25 X 10^6) X (9 X 10^8) = 225 X 10^14.<br>
-&nbsp; (29 X 10^ -8) X (11 X 10^7) = 319 X 10^-1<br>
-&nbsp; (9 X 10^8) X (98 X 10^2) = 882 X 10^1<br>
-<br>
-<br>
-529 &nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY. <br>
-<br>
-<br>
-To divide, subtract (algebraically) the exponent of the divisor from <br>
-that of the dividend for the exponent of the new factor, and divide the
-<br>
-characteristics one by the other for the new characteristic. Algebraic <br>
-subtraction is effected by changing the sign of the subtrahend, <br>
-subtracting the numerically smaller number from the larger, and giving <br>
-the result the sign of the larger number.<br>
-(Thus to subtract 7 from 5 proceed thus; 5 - 7 = -2.)<br>
-<br>
-Thus;<br>
-&nbsp; (25 X 10^6) / (5 X 10^8) = 5 X 10^-2<br>
-&nbsp; (28 X 10^-8) / (5 X 10^3) = 5.6 X 10^-11<br>
-<br>
-[Transcriber's note: I have replaced ordinary exponential notation by<br>
-the more compact and simpler "programming" representation. The last two<br>
-example would be:<br>
-&nbsp; 25E6 / 5E8&nbsp; = 5E-2<br>
-&nbsp; 28E-8 / 5E3 = 5.6E-11<br>
-]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tension.</span><br>
-Electro-motive force or potential difference in a current system is<br>
-often thus termed. It is to be distinguished from intensity or current<br>
-strength, which word it too greatly resembles.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tension, Electric.</span><br>
-(a) The condition an electrified body is brought into by<br>
-electrification, when each molecule repels its neighbor. The condition<br>
-is described as one of self-repulsion.<br>
-<br>
-(b) The voltage or potential difference of a circuit is also thus<br>
-termed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Terminal.</span><br>
-The end of any open electric circuit, or of any electric apparatus; as<br>
-the terminals of a circuit, dynamo, or battery.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Terminal Pole.</span><br>
-In telegraph line construction the last pole of a series; one beyond<br>
-which the line is not carried. Such pole, as the pull of the wires is<br>
-all in one direction, requires special staying or support. The regular<br>
-line poles are free from this strain, as the wire pulls in both<br>
-directions.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tetanus, Acoustic.</span><br>
-A term in electro-therapeutics. An effect produced on a nerve by very<br>
-rapidly alternating induced currents. The currents are produced by an<br>
-induction coil with a vibrator giving a musical note. This is a species<br>
-of gauge of proper frequency of alternations.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Theatrophone.</span><br>
-An apparatus worked by automatic paying machinery by which a telephone<br>
-connection is made with a theatre or opera by the deposition of a coin<br>
-in a slot.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Therm.</span><br>
-A unit of heat. It has been proposed by the British Association and<br>
-amounts to a redefinition of the smaller calorie. It is the amount of<br>
-heat required to raise the temperature of one gram of water one degree<br>
-centigrade, starting at the temperature of maximum density of water.<br>
-<br>
-<br>
-530&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermaesthesiometer.</span><br>
-An electro-therapeutic instrument for testing the sensitiveness of the<br>
-surface of the body to changes of temperature. Vessels of mercury are<br>
-provided with thermometers to indicate their temperature. One vessel is<br>
-surrounded by an electric conductor wound in a number of turns. The<br>
-temperature is raised by passing a current through this. By successive<br>
-applications of the vessels to the same spot upon the skin the power of<br>
-differentiating temperatures is determined.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermo Call.</span><br>
-(a) An electric alarm or call bell operated by thermo-electric currents.<br>
-It may serve as a fire alarm or heat indicator, always bearing in mind<br>
-the fact that differential heat is the requisite in a thermo-electric<br>
-couple.<br>
-<br>
-(b) See Thermo-electric Call.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermo-chemical Battery.</span><br>
-A voltaic battery in which the electro-motive force is generated by<br>
-chemical action induced by heat.<br>
-<br>
-The chemical used generally is sodium nitrate or potassium nitrate. The<br>
-positive plate is carbon. On heating the battery the nitrate attacks the<br>
-carbon, burning it and produces potential difference. For negative plate<br>
-some metal unattacked by the nitrate may be employed.<br>
-<br>
-<br>
-<img style="width: 504px; height: 289px;" alt=""
- src="images/530F330.JPG"><br>
-Fig. 330. POUILLET'S THERMO-ELECTRIC BATTERY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermo-electric Battery or Pile.</span><br>
-A number of thermo-electric couples q. v., connected generally in<br>
-series.<br>
-<br>
-In Nobili's pile the metals are bismuth and antimony; paper bands<br>
-covered with varnish are used to insulate where required. In Becquerel's<br>
-pile copper sulphide (artificial) and German silver, (90 copper, 10<br>
-nickel) are the two elements. The artificial copper sulphide is made<br>
-into slabs 4 inches long, 3/4 inch wide, and 1/2 inch thick (about).<br>
-Water is used to keep one set of junctions cool, and gas flames to heat<br>
-the other set. In Fig. 331, c, d represent the binding screws. The<br>
-couples are mounted on a vertical standard, with adjusting socket and<br>
-screw B, so that its lower end can be immersed in cold water, or raised<br>
-therefrom as desired.<br>
-<br>
-<br>
-531&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 497px; height: 352px;" alt=""
- src="images/531F331.JPG"><br>
-FIG. 331. BECQUEREL'S THERMO-ELECTRIC BATTERIES.<br>
-<br>
-<br>
-Fig. 332 shows one couple of the battery. S is artificial antimony<br>
-sulphide; M is German silver; m is a protecting plate of German silver<br>
-to save the sulphide from wasting in the flame.<br>
-<br>
-<br>
-<img style="width: 322px; height: 412px;" alt=""
- src="images/531F332.JPG"><br>
-Fig. 332. ELEMENTS OF BECQUEREL'S THERMOELECTRIC BATTERIES.<br>
-<br>
-<br>
-Clamond's pile has been used in practical work. The negative element is<br>
-an alloy of antimony, 2 parts, zinc, 1 part. The positive element is tin<br>
-plate. Mica in some parts, and a paste of soluble glass and asbestus in<br>
-other parts are used as insulators. They are built up so as to form a<br>
-cylinder within which the fire is maintained. The air is relied on to<br>
-keep the outer junctions cool. The temperature does not exceed 200&deg;
-C.<br>
-(392&deg; F.)<br>
-<br>
-Sixty such elements have an electro-motive force of 300 volts and an<br>
-internal resistance of 1.5 ohms. Such a battery requires the consumption<br>
-of three cubic feet of gas per hour. (See Currents, Thermo-electric. )<br>
-<br>
-<br>
-532&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermo-electric Call.</span><br>
-A thermostat arranged to ring a bell or to give some indication when the<br>
-temperature rises or falls beyond certain points. It may be a compound<br>
-bar of brass and steel fixed at one end and free for the rest of its<br>
-length. Its end comes between two adjustable contacts. As the<br>
-temperature rises it bends one way (away from the brass side) and, if<br>
-hot enough, touching a contact gives one signal. If the temperature<br>
-falls it curves the other way, and if cold enough touches the other<br>
-contact, giving another signal. (See Thermostat, Electric.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermo-electric Couple.</span><br>
-If two dissimilar conductors form adjacent parts of a closed circuit,<br>
-and their junction is at a different temperature than that of the rest<br>
-of the circuit, a current will result. Such pair of conductors are<br>
-called a thermo-electric couple. They may be joined in series so as to<br>
-produce considerable electro-motive force. (See Thermo-electricity and<br>
-other titles in thermo-electricity.)<br>
-<br>
-The efficiency of a thermo-electric couple according to the second law<br>
-of thermo-dynamics is necessarily low--not over 10 per cent.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermo-electric Diagram.</span><br>
-A diagram indicating the change in potential difference for a fixed<br>
-difference of temperature between different metals at different<br>
-temperatures. It is laid out with rectangular co-ordinates. On one axis<br>
-temperatures are laid off, generally on the axis of abscissas. On the<br>
-other axis potential differences are marked. Different lines are then<br>
-drawn, one for each metal, which show the potential difference, say for<br>
-one degree centigrade difference of temperature between their junctions,<br>
-produced at the different temperatures marked on the axis of abscissas.<br>
-<br>
-<br>
-<img style="width: 616px; height: 325px;" alt=""
- src="images/532F333.JPG"><br>
-Fig. 333. THERMO-ELECTRIC DIAGRAM, <br>
-GIVING POTENTIAL DIFFERENCE IN C. G. S. UNITS.<br>
-<br>
-<br>
-Thus taking copper and iron we find at the temperature 0&deg; C.
-(32&deg; F.) a<br>
-difference of one degree C. (1.8&deg; F.) in their junctions will
-produce a<br>
-potential difference of 15.98 micro volts, while at 274.5&deg; C.
-(526.1&deg;<br>
-F.) the lines cross, and zero difference of potential is indicated.<br>
-Taking the lead line on the same diagram it crosses the iron line a<br>
-little above 350&deg; C. (662&deg; F.), indicating that if one junction
-is<br>
-heated slightly above and the other is heated slightly below this<br>
-temperature no potential difference will be produced. Lead and copper<br>
-lines, on the other hand, diverge more and more as the temperature<br>
-rises.<br>
-<br>
-<br>
-533&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermo-electric Inversion.</span><br>
-The thermo-electric relations of two conductors vary at different<br>
-temperatures. Sometimes at a definite point they have no electro-motive<br>
-force and after passing this point the positive plate becomes a negative<br>
-one and vice versa. This is inversion, or reversal. (See Thermo-electric<br>
-Diagram.)<br>
-<br>
-Synonym-- Thermo-electric Reversal.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermo-electricity.</span><br>
-Electric energy, electro-motive force or electrification produced from<br>
-heat energy by direct conversion. It is generally produced in a circuit<br>
-composed of two electric conductors of unlike material, which circuit<br>
-must possess at least two junctions of the unlike substances. By heating<br>
-one of these to a higher temperature than that of the other, or by<br>
-maintaining one junction at a different temperature from that of the<br>
-other a potential difference is created accompanied by an electric<br>
-current.<br>
-<br>
-In many cases differential application of heat to an identical material<br>
-will develop potential difference. This effect, the converse of the<br>
-Thomson effect, is not used to produce currents, as in a closed circuit<br>
-the potential differences due to differential heating would neutralize<br>
-each other.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermo-electric Junction.</span><br>
-A junction between two dissimilar conductors, which when heated or<br>
-cooled so as to establish a differential temperature, as referred to the<br>
-temperature of the other junction, produces potential difference and an<br>
-electric current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermo-electric Pile, Differential.</span><br>
-A thermo-electric pile arranged to have opposite faces subjected to<br>
-different sources of heat to determine the identity or difference of<br>
-temperature of the two sources of heat. It corresponds in use to a<br>
-differential air thermometer.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermo-electric Power.</span><br>
-The coefficient which, multiplying the difference of temperature of the<br>
-ends of a thermo-electric couple, gives the potential difference,<br>
-expressed in micro-volts. It has always to be assigned to a mean or<br>
-average temperature of the junctions, because the potential difference<br>
-due to a fixed difference of temperature between two metals varies with<br>
-the average temperature of the two junctions. (See Thermo-electric<br>
-Diagram.)<br>
-<br>
-For bismuth and antimony at 19.5&deg; C. (67.1&deg; F.) it is 103
-microvolts per<br>
-degree Centigrade (1.8&deg; F.). This means that if one junction is
-heated<br>
-to 19&deg; C. and the other to 20&deg; C. (66.2&deg; F. and 68.0&deg;
-F.) a potential<br>
-difference of 103 micro-volts will be produced.<br>
-<br>
-The potential difference is approximately proportional to the difference<br>
-of temperature of the two junctions if such difference is small. Hence<br>
-for large differences of potential the thermo-electric power coefficient<br>
-does not apply.<br>
-<br>
-As a differential function it is thus deduced by Sir William Thomson,<br>
-for expressing the E. M. F. in a thermo-electric circuit: If a circuit<br>
-is formed of two metals with the junctions at indefinitely near<br>
-temperatures, t and t + dt, and dE is the E. M. F. of the circuit, then<br>
-the differential coefficient dE/dt is called the thermo-electric power<br>
-of the two metals for the temperature t.<br>
-<br>
-<br>
-534&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermo-electric Series.</span><br>
-The arrangement of possible thermoelectric elements, q. v., in a table<br>
-in the order of their relative polarity. Bismuth and antimony form a<br>
-couple in which when their junction is heated the bismuth acts as the<br>
-positive or negatively charged element and antimony as the negative or<br>
-positively charged. Between these two extremes according to Seebeck the<br>
-series runs as follows:<br>
-<br style="font-family: monospace;">
-<small><span style="font-family: monospace;">&nbsp;
-Antimony,&nbsp;&nbsp; Silver,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Copper,</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Arsenic,&nbsp;&nbsp;&nbsp;
-Gold,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Platinum,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Iron,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Molybdenum,&nbsp;
-Palladium,</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Steel,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Tin,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Cobalt,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Cadmium,&nbsp;&nbsp;&nbsp;
-Lead,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Nickel,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Tungsten,&nbsp;&nbsp;
-Mercury,&nbsp;&nbsp;&nbsp;&nbsp; Bismuth.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Zinc,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Manganese,</span></small><br>
-<br>
-A differential temperature of 1&deg; C. (1.8&deg; F.) in a
-bismuth-antimony<br>
-couple maintains a potential difference of 103 micro-volts.<br>
-<br>
-Matthiessen gives a different series; it is arranged in two columns; the<br>
-first column has positive coefficients annexed the second has negative.<br>
-On subtracting the greater one from the lesser, which, if the two<br>
-elements are in different columns, of course amounts to adding after<br>
-changing the negative sign, the relative potential difference due to the<br>
-combination is obtained.<br>
-<small><span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-&nbsp;&nbsp;
-+&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
--</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Bismuth&nbsp;&nbsp;&nbsp;
-25&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Gas
-Coke&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 0.1</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Cobalt&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-9&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Zinc&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-0.2</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Potassium&nbsp;&nbsp;
-5.5&nbsp;&nbsp;&nbsp;
-Cadmium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 0.3</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Nickel&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Strontium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2.0</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Sodium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 3.&nbsp;&nbsp;&nbsp;&nbsp;
-Arsenic&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 3.8</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Lead&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1.03&nbsp;&nbsp;
-Iron&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-5.2</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Tin&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Red Phosphorous&nbsp;&nbsp; 9.6</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Copper&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Antimony&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 9.8</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-Silver&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Tellurium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 179.9</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Platinum&nbsp;&nbsp;&nbsp;
-0.7&nbsp;&nbsp;&nbsp;
-Selenium&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 290</span></small><br>
-<br>
-Thus the relative E. M. F. of a bismuth-nickel couple, as both are in<br>
-the + column, would be 25 - 5 = 20; that of a cobalt-iron couple, one<br>
-being in the + column the other in the - column, would be 9 + 5.2 =<br>
-14.2. Alloys are not always intermediate to their constituents, and<br>
-small amounts of impurities affect the results largely. This may account<br>
-for the discrepancies of different observers. Other compounds could be<br>
-introduced into the series.<br>
-<br>
-Artificial silver sulphide has been used by Becquerel in a<br>
-thermo-electric battery.<br>
-<br>
-<br>
-535&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermo-electric Thermometer.</span><br>
-A species of differential thermometer. It consists of two<br>
-thermo-electric junctions connected in opposition with a galvanometer in<br>
-the circuit. Any inequality of temperature in the two ends or junctions<br>
-produces a current shown by the galvanometer. It may be used to<br>
-determine the temperature of a distant place, one of the junctions being<br>
-located there and the other being under control of the operator. If the<br>
-latter junction is heated until no current is produced its temperature<br>
-is evidently equal to that of the distant couple or junction. The<br>
-heating may be done with hot water or mercury, or other melted metal.<br>
-The temperature of the water, or other substance, gives the temperature<br>
-of the distant place.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermolysis.</span><br>
-Decomposition by heat; dissociation. All compound bodies are<br>
-decomposable by heat if it is intense enough. Hence at very elevated<br>
-temperatures there can be no combustion.<br>
-<br>
-Synonym--Dissociation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermometer.</span><br>
-An instrument for indicating the intensity of heat. Three scales of<br>
-degrees of heat are used in practise, the Fahrenheit, R&eacute;amur, and<br>
-Centigrade, each of which is described under its own title. (See Zero,<br>
-Thermometric-Zero, Absolute.) The ordinary thermometer depends on the<br>
-expansion of mercury; in some cases alcohol is used. Besides these the<br>
-compound bar principle as used in the thermostat (see Thermostat,<br>
-Electric) is employed.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermometer, Electric.</span><br>
-(a) A thermometer whose indications are due to the change of resistance<br>
-in conductors with change of temperature. Two exactly similar resistance<br>
-coils maybe electrically balanced against each other. On exposing one to<br>
-a source of heat, its resistance will change and it will disturb the<br>
-balance. The balance is restored by heating the other coil in a vessel<br>
-of water when the temperature of the water gives the temperature of both<br>
-coils. The coils are enclosed in water-tight metallic cases.<br>
-<br>
-Synonym--Electric Resistance Thermometer.<br>
-<br>
-(b) A differential thermometer may be made by connecting with a pair of<br>
-conductors, two thermo-electric couples in opposition to each other, and<br>
-including a galvanometer in series. On heating the junction of one<br>
-couple more than that of the other a current at once goes through the<br>
-galvanometer.<br>
-<br>
-(c) (See Thermometer, Kinnersley's.)<br>
-<br>
-Synonym--Thermo-electrometer.<br>
-<br>
-<br>
-536&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<img style="width: 449px; height: 601px;" alt=""
- src="images/536F334.JPG"><br>
-Fig. 334. KINNERSLEY'S THERMOMETER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermometer, Kinnersley's.</span><br>
-A thermo-electrometer. A large glass tube is mounted on a standard and<br>
-communicates with a small tube parallel to it. Water is poured in so as<br>
-to rise in the small tube. Two wires terminating in bulbs enter the<br>
-large tube by its top and bottom. The upper wire can be adjusted by<br>
-moving up and down through a stuffing box. On discharging a Leyden jar<br>
-through the space between the knobs on the two wires the water for a<br>
-moment rises in the small tube. There is little or no accuracy in the<br>
-instrument. It is allied to the electric mortar (see Mortar, Electric)<br>
-as a demonstrative apparatus.<br>
-<br>
-Synonyms--Electric Thermometer--Thermo-electrometer.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thermo-multiplier.</span><br>
-A thermo-electric battery including a number of couples. The term is<br>
-generally applied to a small battery with its similar junctions facing<br>
-in one direction and used for repeating Melloni's experiments on radiant<br>
-energy, or so-called radiant heat.<br>
-<br>
-<br>
-537&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermophone.</span><br>
-An apparatus for reproducing sounds telephonically by the agency of<br>
-heat; a receiving telephone actuated by heat. Thus a wire may be<br>
-attached to the centre of a diaphragm and kept in tension therefrom, and<br>
-the transmitting telephone current may be caused to pass through it. The<br>
-wire changes in temperature and consequently in length with the pulses<br>
-of current going through it and vibrates the diaphragm, reproducing the<br>
-sound. It is to be distinguished from the thermo-electric telephone<br>
-which involves the action of potential difference produced by<br>
-thermo-electric action.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thermostat, Electric.</span><br>
-A thermostat or apparatus, similar to a thermometer in some cases, for<br>
-closing an electric circuit when heated. It is used in connection with<br>
-automatic fire alarms to give warning of fire. For this use a<br>
-temperature of 52&deg; C. (125&deg; F.) is an approved one for setting
-one at,<br>
-to complete the circuit. It is also applied to regulation of<br>
-temperature, as in incubators.<br>
-<br>
-(a) One kind of thermostat consists of a compound bar wound into a<br>
-spiral and fastened at one end, to which a terminal of a circuit is<br>
-connected. The bar may be made of two strips of brass and iron riveted<br>
-together, and wound into a spiral. When such a bar is submitted to<br>
-changes of temperature it bends in different directions, because brass<br>
-expands and contracts more under changes of temperature than does iron.<br>
-A contact point, to which the other terminal is connected, is arranged<br>
-to make contact with the spiral at any desired degree of temperature,<br>
-thus closing an electric circuit and ringing a bell, opening or closing<br>
-a damper, or doing anything else to notify an attendant or to directly<br>
-change the temperature.<br>
-<br>
-If the brass forms the outside of the spiral, increase of temperature<br>
-makes the bending of the spiral bring the coils still closer. If the<br>
-brass forms the inside, increase of temperature makes the spiral tend to<br>
-become less close. As shown in the cut, the brass should lie along the<br>
-inside of the spiral.<br>
-<br>
-Sometimes a straight compound bar is used, one of whose ends is fastened<br>
-and the other is free. As the temperature changes such a bar curves more<br>
-or less, its free end moving to and fro. Two contact screws are<br>
-provided, one on each side of its free end. If the temperature falls it<br>
-makes contact with one of these; if the temperature rises, it makes<br>
-contact with the other. Thus it may close one of two circuits, one for a<br>
-fall and the other for a rise in temperature.<br>
-<br>
-It is well to introduce a third bar between the brass and iron ones,<br>
-made of some material of intermediate coefficient of expansion.<br>
-<br>
-(b) Another kind of thermostat comprises a vessel of air or other gas,<br>
-which, expanding by heat, actuates a piston or other device and closes<br>
-an electric circuit. Synonym--Electro-pneumatic Thermostat.<br>
-<br>
-(c) Another form utilizes the expansion of mercury. The mercury is made<br>
-part of an open electric circuit. As it expands it comes in contact with<br>
-the other terminal of the circuit, thus completing it, when the current<br>
-gives an alarm or does as is provided for in the apparatus employed.<br>
-<br>
-Thermostats may be worked on either open or closed circuits; normally<br>
-the circuit may be open as described and may close on rise of<br>
-temperature, or it may be normally closed and open as the temperature<br>
-rises.<br>
-<br>
-<br>
-<img style="width: 378px; height: 644px;" alt=""
- src="images/537F335.JPG"><br>
-Fig. 335. ELECTRIC THERMOSTAT.<br>
-<br>
-<br>
-538&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Thomson Effect.</span><br>
-In an unequally heated conductor the differential heating is either<br>
-increased as in iron, or diminished as in copper by a current. In lead<br>
-the phenomenon does not occur. It is termed the Thomson effect. It is<br>
-intimately related to the Peltier effect.<br>
-<br>
-In a thermo-electric couple a heated junction is the source of<br>
-electro-motive force, if heated more than other parts of the circuit.<br>
-The current in a copper-iron junction flows from the copper to the iron<br>
-across the heated junction. A hot section of an iron conductor next to a<br>
-cold section of the same is a source of thermoelectricity, in the sense<br>
-that the hot section is negative to the colder. A current passing from<br>
-the hot to the cold iron travels against rising potentials, and cools<br>
-the iron in the cooler parts. As it passes to the hotter parts it<br>
-travels against falling potentials and hence heats the iron in these<br>
-parts. In this way a current intensifies differential heating in an iron<br>
-conductor.<br>
-<br>
-In copper the reverse obtains. In it the thermo-electric relations of<br>
-hot and cold copper are the reverse of those of iron, and a current<br>
-tends to bring all parts of a differentially heated copper conductor to<br>
-an identical temperature.<br>
-<br>
-As a current travels in iron from hot to cold it absorbs heat; in copper<br>
-traveling from cold to hot it absorbs heat.<br>
-<br>
-The convection of heat by a current of electricity in unequally heated<br>
-iron is negative, for it is opposed to that convection of heat which<br>
-would be brought about by the flow of water through an unequally heated<br>
-tube. In copper, on the other hand, the electric convection of heat is<br>
-positive. (Daniell.)<br>
-<br>
-The above effects of the electric current upon an unequally heated<br>
-conductor are termed the Thomson effects. In iron, at low red heat, they<br>
-are reversed and are probably again reversed at higher temperatures.<br>
-<br>
-<br>
-539&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Three Wire System.</span><br>
-A system of distribution of electric current for multiple arc or<br>
-constant potential service. It is the invention of Thomas A. Edison.<br>
-<br>
-It includes three main wires which start from the central station or<br>
-generating plant, and ramify with corresponding reduction in size,<br>
-everywhere through the district or building to be lighted. As ordinarily<br>
-carried out when dynamos are used, the dynamos are arranged in groups of<br>
-two. One lateral lead starts from the negative binding post of one<br>
-dynamo. The positive terminal of this dynamo connects to the negative of<br>
-the other. Between the two dynamos the central or neutral lead is<br>
-connected. The other lateral lead starts from the positive binding post<br>
-of the second dynamo.<br>
-<br>
-The lamps or other appliances are calculated for the potential<br>
-difference of a single dynamo. They are arranged between the neutral<br>
-wire and the laterals, giving as even a disposition as possible to the<br>
-two laterals.<br>
-<br>
-<br>
-<img style="width: 661px; height: 193px;" alt=""
- src="images/539F336.JPG"><br>
-Fig. 336. DIAGRAM OF THREE WIRE SYSTEM <br>
-SHOWING NEUTRAL WIRE.<br>
-<br>
-<br>
-If evenly arranged and all burning or using current, no current goes<br>
-through the neutral wire. If all the lamps situated on one lateral are<br>
-on open circuit all the current goes through the neutral wire. In other<br>
-cases the neutral wire receives the excess of current only.<br>
-<br>
-The advantages of the system are that it uses smaller wire than the two<br>
-wire system for lamps of the same voltage. If lamps of double the<br>
-voltage were used the two wire system would be most economical.<br>
-<br>
-<br>
-540&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Four wire and five wire systems have been more or less used, based on<br>
-identical considerations, and involving in each case the coupling of<br>
-three or of four dynamos respectively, or else employing a dynamo with<br>
-special armature connections to give the requisite three-fold or<br>
-four-fold division of total potential. In the five wire system the total<br>
-voltage is four times that of a single lamp, the lamps are arranged four<br>
-in series across the leads and the central wire is the only one that can<br>
-be considered a neutral wire. When lamps are burning entirely from three<br>
-side-leads they constitute a sort of three wire system by themselves,<br>
-and their central wire may for the time be a neutral wire.<br>
-<br>
-In some of the three wire mains, especially in the larger sizes, the<br>
-neutral wire is made of much smaller section than that of a lateral<br>
-conductor, because in extensive districts it is practically impossible<br>
-that the current should be concentrated in the neutral wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Throw.</span><br>
-In a galvanometer the instantaneous deflection of the needle when the<br>
-contact or closing of the circuit is instantaneous, or when the<br>
-discharge is completed before the needle begins to move. The throw of<br>
-the needle is the datum sought when the ballistic galvanometer is used.<br>
-<br>
-Synonym--Elongation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Throw-back Indicator.</span><br>
-A drop annunciator, whose shutter or drop is electrically replaced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thrust-bearings.</span><br>
-Bearings to support the end-thrust or push of a shaft. In disc armatures<br>
-where the field-magnets attract the armatures in the direction of their<br>
-axis of rotation, thrust-bearings have to be provided. In ordinary<br>
-cylinder or drum armatures end-thrust is not applied, as a little end<br>
-motion to and fro is considered advantageous as causing more even wear<br>
-of the commutator surface.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Thunder.</span><br>
-The violent report which, as we hear it, succeeds the lightning flash in<br>
-stormy weather. It is really produced simultaneously with the lightning<br>
-and is supposed to arise from disturbance of the air by the discharge.<br>
-The rolling noise has been attributed to successive reflections between<br>
-clouds and earth, and to series of discharges reaching the ear from<br>
-different distances and through air of varying density. The subject is<br>
-obscure. By timing the interval from lightning flash to the report of<br>
-the thunder an approximate estimate of the distance of the seat of<br>
-discharge can be made. The first sound of the thunder should be timed.<br>
-An almost concurrence of thunder and lightning indicates immediate<br>
-proximity of the discharge.<br>
-<br>
-[Transcriber's note: The speed of sound at sea level is about 5 seconds<br>
-per mile.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ticker.</span><br>
-A colloquial name for a stock or market report automatic printing<br>
-telegraph, which prints its quotations and messages on a long tape.<br>
-<br>
-<br>
-541&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Time Constant.</span><br>
-(a) When current is first turned into a circuit of considerable<br>
-self-induction it is resisted rather by the inductance than by the<br>
-resistance. It is governed by the ratio of resistance and self-induction<br>
-and this factor represents the time which it takes for the current to<br>
-reach a definite fraction of its final strength. This fraction is<br>
-(2.7183 - 1)/2.7183&nbsp; or 0.63. 2.7183 is the base of the Napierian
-system<br>
-of logarithms. Thus if in any circuit we divide the inductance in<br>
-henries by the resistance in ohms, the ratio gives the time-constant of<br>
-the circuit, or it expresses the time which it will take for the current<br>
-to reach 0.63 of its final value.<br>
-<br>
-(b) In a static condenser the time required for the charge to fall to<br>
-1/2.7183th part of its original value.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Time Cut-outs.</span><br>
-Cut-outs which automatically cut storage batteries out of the charging<br>
-circuit when they are sufficiently charged.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Time-fall.</span><br>
-In a secondary battery the decrease with use of electromotive force<br>
-maintained by a primary or secondary battery. As the battery becomes<br>
-spent its voltage falls. The conditions of the fall are represented by<br>
-its discharging curve. (See Curve, Discharging.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Time-reaction.</span><br>
-A term in electro-therapeutics; the period of time occupied in the<br>
-passage of the effects of an electric current from nerve to muscle.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Time-rise.</span><br>
-In a secondary battery the increase of electromotive force produced<br>
-during the charging process. Its rate and conditions are graphically<br>
-shown in the charging curve. (See Curve, Charging.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tin.</span><br>
-A metal; one of the elements; symbol, Sn; atomic weight, 117.8;<br>
-equivalent, 58.9 and 29.5; valency, 2 and 4; specific gravity, 7.3.<br>
-It is a conductor of electricity.<br>
-<small><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Relative resistance,
-compressed, (Silver = 1)&nbsp;&nbsp; 8.784</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Specific resistance at
-0&deg; C. (32&deg; F.),&nbsp;&nbsp;
-13.21&nbsp;&nbsp; microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a wire at
-0&deg; C. (32&deg; F.),</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long, weighing
-1
-grain,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1.380&nbsp;&nbsp; ohms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (b) 1 foot long, 1/1000
-inch thick,&nbsp;&nbsp;&nbsp;&nbsp;
-79.47&nbsp;&nbsp;&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (c) 1 meter long, weighing
-1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; .9632&nbsp;&nbsp; "</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (d) 1 meter long, 1
-millimeter thick,&nbsp;&nbsp;&nbsp;&nbsp;
-.1682&nbsp;&nbsp; "</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Resistance of a 1 inch
-cube at 0&deg; C. (32&deg;
-F.),&nbsp;&nbsp; 5.202&nbsp;&nbsp; microhms.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Percentage of variation in
-resistance</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp; per degree C.
-(1.8&deg; F.), at about 20&deg; C.
-(68&deg; F.),&nbsp; .0365</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; Electro-chemical
-equivalent (hydrogen = .0105),&nbsp;&nbsp;
-.619&nbsp;&nbsp; mgs.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.310&nbsp;&nbsp; "</span></small><br>
-<br>
-542&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tinnitus, Telephone.</span><br>
-A nervous affection of the ear, of the order of professional cramp; it<br>
-is attributed to too much use of the telephone.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tin Sounders.</span><br>
-A recent addition to the single needle telegraph. (See Telegraph, Single<br>
-Needle.) It consists of small tin plates, cut and bent, and so fitted in<br>
-pairs to the instrument, that the needle as deflected strikes one or the<br>
-other on its right and left hand movements. The sounders can be made to<br>
-give sufficiently distinctive sounds to make sound-reading, q. v.,<br>
-possible. Commercial tin plate, which is really tinned iron, seems to<br>
-give the best results.<br>
-<br>
-<br>
-<img style="width: 424px; height: 454px;" alt=""
- src="images/542F337.JPG"><br>
-Fig. 337. TIN SOUNDERS.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tissandier's Solution. </span><br>
-A solution for bichromate batteries. It is composed as follows:<br
- style="font-family: monospace;">
-<small><span style="font-family: monospace;">&nbsp;
-</span><span style="font-family: monospace;">Water,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-100 parts by weight</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; potassium
-bichromate,&nbsp; 16 parts</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 66&deg; sulphuric
-acid,&nbsp;&nbsp;&nbsp; 37 parts.</span></small><br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tongue of Polarized Relay.</span><br>
-The German silver extension of the vibrating or oscillating member of a<br>
-polarized relay, corresponding to the armature of an ordinary relay.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tongue of Polarized Relay, Bias of.</span><br>
-In a Siemens' polarized relay the pole pieces are adjustable so that<br>
-they may be brought nearer to or withdrawn from the tongue. One of the<br>
-poles is adjusted so as to be nearer the tongue. This one-sided<br>
-adjustment is the bias. Its effect is that when the relay is unexcited<br>
-this pole attracts the armature so that it normally is drawn towards it.<br>
-This ensures the normal contact of the tongue either with the contact<br>
-point, or with the insulated stop piece or adjustment screw. Without<br>
-bias the armature remains in contact with or drawn towards whichever<br>
-pole it was last attracted to. In its usual use a bias is given it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Top, Magnetic.</span><br>
-A toy illustrating magnetic attraction. It consists of a disc or body of<br>
-lead or other material, through which a magnetized steel spindle pointed<br>
-at its lower end is thrust. A number of short pieces of iron wire are<br>
-used with it. It is spun like an ordinary top upon the point of the<br>
-spindle and one of the pieces of iron wire is laid by the side of its<br>
-point. As it turns the magnetic adherence causes the piece of wire to be<br>
-carried along in one direction by the rotation of the spindle, until the<br>
-end is reached, when it goes over to the other side of the spindle and<br>
-travels back again.<br>
-<br>
-By using bent pieces of wire of various shapes the most curious effects<br>
-are produced. Circles and S shaped pieces give good effects. To increase<br>
-the mysterious effect covered iron wire (bonnet wire) may be employed.<br>
-<br>
-<br>
-<img style="width: 605px; height: 462px;" alt=""
- src="images/543F338.JPG"><br>
-Fig. 338. MAGNETIC TOP.<br>
-<br>
-<br>
-543&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Torpedo, Electric.</span><br>
-(a) A fish, the Raia Torpedo, which possesses the power of giving<br>
-electric shocks. (See Ray, Electric.)<br>
-<br>
-(b) An instrument of war; a torpedo whose operations include electrical<br>
-discharge or other electric function or factor of operation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Torpedo, Sims-Edison.</span><br>
-A torpedo driven by an electric motor, and also steered by electricity.<br>
-Its motions are all controlled from the shore. The torpedo proper is<br>
-carried some distance below the surface of the water by a vessel<br>
-immediately above it, from which it is suspended by two rigid bars. In<br>
-the torpedo is a cable reel on which the conducting cable is disposed.<br>
-An electric motor and controlling gear are also contained within the<br>
-torpedo. In its front the explosive is placed. It is driven by a screw<br>
-propeller actuated by the electric motor. As it moves it pays out cable<br>
-so that it has no cable to draw after it through the water, the cable<br>
-lying stationary in the water behind it. This avoids frictional<br>
-resistance to its motion. The maintenance of the torpedo at a proper<br>
-depth is one of the advantages of the system.<br>
-<br>
-<br>
-544&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Torque.</span><br>
-A force tending to produce torsion around an axis. An example is the<br>
-pulling or turning moment of an armature of an electric motor upon its<br>
-shaft. It is often expressed as pounds of pull excited at the end of a<br>
-lever arm one foot long.<br>
-<br>
-The expression is due to Prof. James Thompson, then of the University of<br>
-Glasgow.<br>
-<br>
-"Just as the Newtonian definition of force is that which produces or<br>
-tends to produce motion (along a line), so torque may be defined as that<br>
-which produces or tends to produce torsion (around an axis). It is<br>
-better to use a term which treats this action as a single definite<br>
-entity than to use terms like 'couple' and 'moment,' which suggest more<br>
-complex ideas." (S. P. Thompson.)<br>
-<br>
-A force, acting with radius r gives a torque equal to f X r ;&nbsp; f
-and r <br>
-may be expressed in any units. S. P. Thompson gives the following <br>
-equivalents :<br>
-<br>
-To reduce<br>
-&nbsp; dyne-centimeters to gram centimeters, divide by&nbsp;&nbsp; 981<br>
-&nbsp; dyne-centimeters to meter-kilograms&nbsp;&nbsp; divide
-by&nbsp;&nbsp; 981E5<br>
-&nbsp; dyne-centimeter, to
-pound-feet&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; divide
-by&nbsp;&nbsp; 13.56E6<br>
-&nbsp; pound-feet to
-meter-kilograms&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; divide
-by&nbsp;&nbsp; 7.23<br>
-<br>
-In each of these compound units the first unit is the force and the<br>
-second unit is the radius or lever arm of the torque.<br>
-<br>
-Synonyms--Turning Moment--Moment of Couple--Axial Couple--Angular<br>
-Force--Axial Force.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Torsion Balance, Coulomb's.</span><br>
-Originally an apparatus in which electrostatic attraction or repulsion<br>
-is measured against the torsion of a filament, often of silk-worm cocoon<br>
-fibre. It consists in one form of a cylindrical glass vessel in which a<br>
-light shellac needle is suspended horizontally by a fibre. This needle<br>
-carries at one end a gilded disc or sphere and is suspended by a fine<br>
-wire, or filament. A proof plane, q. v., is excited by touching it to<br>
-the body under trial; it is then inserted in the case. The disc on the<br>
-needle is first attracted and then repelled. The position finally taken<br>
-by the needle is noted. The force of torsion thus produced is determined<br>
-by twisting the filament by the torsion head on the top of the apparatus<br>
-so as to move the needle a certain distance towards the proof plane. The<br>
-more the torsion-head has to be turned to carry the needle through a<br>
-specified arc the greater is the torsion effected or the greater is the<br>
-repulsion exerted, The torsional force of a wire is proportional to the<br>
-angle of torsion; this gives the basis for the measurement.<br>
-<br>
-With magnetic needle it is used to measure magnetic repulsion and<br>
-attraction. The best material for the filament is quartz, but the<br>
-instrument is not very much used.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Torsion Galvanometer.</span><br>
-A galvanometer in which the torsion required to bring the index back to<br>
-zero, when the current tends to displace it, is made the measure of the<br>
-current strength or of the electro-motive force. It involves the use of<br>
-a torsion head, q. v., or its equivalent.<br>
-<br>
-<br>
-545&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Torsion Head.</span><br>
-The handle and disc from whose undersurface the filament depends to<br>
-which the needle or magnet is attached. It is turned to measure the<br>
-torsional effect, the edge of the disc being marked or graduated so as<br>
-to give the angle of deflection required to overcome the effect of the<br>
-torque of the needle.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Torsion Suspension.</span><br>
-Suspension by one or more wires, fibres, or ribands, involving the<br>
-restitutive force of torsion. Thus fibre suspension, q. v., is a variety<br>
-of torsion suspension.<br>
-<br>
-Often a single riband of steel stretched horizontally and secured at<br>
-both ends is used, the suspended object, e. g., a balance beam, being<br>
-attached at its own centre to the centre of the stretched riband. Quite<br>
-sensitive balances are constructed on this principle. It is peculiarly<br>
-available where an electric current is to be transmitted, as absolute<br>
-contact is secured, as in William Thomson's ampere balances.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Touch.</span><br>
-A term applied to methods of magnetization, as "single touch," "double<br>
-touch," or "separate touch," indicating how the poles of the inducing<br>
-magnet or magnets are applied to the bar to be magnetized. Under the<br>
-titles of Magnetization the different methods are described.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tourmaline.</span><br>
-A mineral; a subsilicate; characterized by the presence of boric<br>
-trioxide, which replaces aluminum oxide. It is notable for possessing<br>
-pyro-electric properties. (See Pyro-electricity.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tower, Electric.</span><br>
-The tower used in the tower system, q. v., of arc light illumination.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Tower System.</span><br>
-In electric lighting the system of lighting extended areas by powerful<br>
-arc lamps placed on high towers, generally of iron or steel frame-work.<br>
-The lights are thus maintained at a high elevation, giving greater<br>
-uniformity of illumination than if they were lower, but at the expense<br>
-of considerable light which is lost. Sometimes wooden masts are employed<br>
-instead of towers.<br>
-<br>
-The principle involved is that the intensity of light at any place given<br>
-by a source of illumination varies with the square of its distance from<br>
-the place in question. Hence in using strong arc lights it is an object<br>
-to have the distances of all parts of the area illuminated at as nearly<br>
-uniform distances from the light as possible. An approximation to<br>
-uniformity is secured by placing the lamps at a very high elevation.<br>
-<br>
-<br>
-546&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Transformer.</span><br>
-In alternate current lighting the induction coil by which the primary<br>
-current with high initial electro-motive force is caused to produce a<br>
-secondary current with low initial electromotive force.<br>
-<br>
-A typical transformer consists of a core of thin iron sheets. The<br>
-primary is of comparatively thin wire and often of ten or more times as<br>
-many turns as the secondary. The latter is of thicker wire. Where the<br>
-ratio of 10 to 1 as regards number of turns in the primary and secondary<br>
-obtains, the initial E. M. F. of the secondary is one-tenth that of the<br>
-primary circuit.<br>
-<br>
-The cores are laminated, as described, to avoid the formation of<br>
-Foucault currents.<br>
-<br>
-The counter-electro-motive force of the transformer when the secondary<br>
-circuit is open, prevents any but the slightest current from passing<br>
-through the primary. In proportion as the secondary is closed and its<br>
-resistance diminished, as by lighting more lamps in parallel, the<br>
-counter-electro-motive force of the transformer falls and more current<br>
-passes through the primary.<br>
-<br>
-<br>
-<img style="width: 532px; height: 712px;" alt=""
- src="images/546F339.JPG"><br>
-Fig. 339. FERRANTI'S TRANSFORMER.<br>
-<br>
-The economy of the apparatus is in the fact that counter-electromotive<br>
-force reduces current through a conductor without absorbing any energy.<br>
-A resistance coil cuts down a current, but absorbs energy equal to the<br>
-current multiplied by the potential difference between the terminals of<br>
-the coil. This electric energy is converted into heat energy and is<br>
-wasted. But the counter-electromotive force of a transformer is exerted<br>
-to reduce current without production of heat and with little waste of<br>
-energy. This is one of the advantages of the alternating current system<br>
-of distribution of electric energy.<br>
-<br>
-The object of a transformer being to secure safety to the person or to<br>
-life by the separation of the high potential primary or street circuit,<br>
-and the low potential house circuit, any contact of the two circuits in<br>
-the converter is a source of danger. Special care should be taken to<br>
-ensure absence of leakage, as it is termed. Mica or other insulation is<br>
-sometimes employed to prevent the wires from coming in contact by<br>
-piercing or sparking with the core and with each other.<br>
-<br>
-<br>
-547&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transformer, Commuting.</span><br>
-A type of continuous current transformer, resembling a dynamo with<br>
-armature and field both stationary, but with revolving commutator, by<br>
-which the magnetic polarity of a double wound armature is made to<br>
-rotate. This secures the desired action, of a change or lowering of<br>
-potential.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transformer, Continuous Alternating.</span><br>
-An apparatus for transforming a continuous into an alternating current<br>
-or the reverse. The combination of a continuous current dynamo with an<br>
-alternating current one is sometimes employed. It is a form of motor<br>
-dynamo.<br>
-<br>
-Another type is a regular dynamo with ordinary commutator and with, in<br>
-addition thereto, two, three or four contact rings, connecting to as<br>
-many symmetrically disposed points in the winding of the armature. This<br>
-will give out or receive alternating currents of two, three or four<br>
-phases according to the number of collecting rings. One winding serves<br>
-for both alternating and continuous currents.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transformer, Continuous Current.</span><br>
-A machine of the dynamo type for changing the potential of a circuit. In<br>
-one form two armatures are mounted on one shaft in a single field or in<br>
-separate fields; one is a motor armature driven by the original current;<br>
-the other generates the new current. This is a motor dynamo. In 1874<br>
-Gramme constructed a machine with ring armature with two windings, of<br>
-coarse and fine wire respectively, and with independent commutators.<br>
-Such dynamo could transform currents up or down.<br>
-<br>
-Continuous current transformers have attained an efficiency of 83 per<br>
-cent. at full load, and of 75 per cent. at half load. Owing to the<br>
-balancing of the self-inductions of the two windings these machines do<br>
-not spark. As the driven and driving parts are contained in one rotating<br>
-part their friction is very slight.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transformer, Core.</span><br>
-A transformer wound upon an enclosed core, such as the hedgehog<br>
-transformer (see Transformer, Hedgehog), or common induction coil.<br>
-<br>
-<br>
-548&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transformer, Hedgehog.</span><br>
-An induction coil transformer whose iron core is composed of a bundle of<br>
-iron wires, which after the wire windings are in place have their ends<br>
-spread out to reduce to some extent the reluctance of the circuit, which<br>
-at the best is high, as the air acts as the return circuit.<br>
-<br>
-This transformer has a low degree of hysteresis; and its efficiency for<br>
-very small loads or for no load is superior to that of the closed<br>
-magnetic circuit transformer.<br>
-<br>
-<br>
-<img style="width: 326px; height: 758px;" alt=""
- src="images/548F340.JPG"><br>
-Fig. 340. SWINBURNE'S HEDGEHOG TRANSFORMER.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Transformer, Multiple.</span><br>
-A transformer connected in parallel with others between the two leads of<br>
-the primary circuit. The term refers to the connection only and not to<br>
-any peculiarity of the transformer itself.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Transformer, Oil.</span><br>
-A transformer with oil insulation. The advantage of this insulation is<br>
-that if pierced it at once closes, so that no permanent injury ensues.<br>
-It is a self-healing form of insulation.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Transformer, Series.</span><br>
-Transformers connected in series upon the primary circuits. The term,<br>
-like "multiple transformers," only applies to the connection, not to the<br>
-transformer. Series transformers are but little used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transformer, Shell.</span><br>
-A transformer with its iron core entirely outside of and enclosing the<br>
-primary and secondary winding. It may be made by the use of outer iron<br>
-wire windings as core.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transformer, Welding.</span><br>
-The transformer used for electric welding. (See Welding, Electric.) It<br>
-is a transformer with very long primary and exceedingly short and thick<br>
-secondary. It is used with the alternating current in the primary, and<br>
-produces in the secondary circuit which includes the bars to be welded a<br>
-very low potential difference.<br>
-<br>
-Owing to the very low resistance of the secondary circuit this low<br>
-electro-motive force produces a very strong current, which develops the<br>
-requisite heat. The same type of transformer is used for brazing and<br>
-similar purposes.<br>
-<br>
-<br>
-549&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transmitter.</span><br>
-In general electric phraseology, any instrument which produces signals<br>
-to be transmitted through a line or circuit is a transmitter. Thus the<br>
-Morse key in telegraphy or the Blake transmitter in telephony are<br>
-examples of such.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transmitter, Carbon.</span><br>
-A form of microphone used as a telephone transmitter. (See Carbon<br>
-Telephone.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Transposing.</span><br>
-A method of laying metallic circuits for telephoning. The wires at short<br>
-intervals are crossed so that alternate sections lie on opposite sides<br>
-of each other. It is done to avoid induction.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Transverse Electro-motive Force.</span><br>
-Electro-motive force in a substance in which electric displacement is<br>
-taking place, produced by a magnetic field. It is sometimes assigned as<br>
-the cause of the Hall effect, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Trimmer, Brush.</span><br>
-A shears for cutting off evenly and squarely the ends of copper dynamo<br>
-brushes. The brushes when uneven from wear are removed from the brush<br>
-holders, and their ends are sheared off in the trimmer.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Trolley.</span><br>
-A grooved metallic pulley or set of pulleys which runs along an active<br>
-wire of a circuit, a lead from which trolley goes to earth or connects<br>
-with another wire, so that the trolley takes current generally for<br>
-operating a street car motor placed upon the circuit leading from it; a<br>
-rolling contact with an electric lead.<br>
-<br>
-Trolleys are principally used on electric railroads, and are now<br>
-universally of the sub-wire system, being at the end of a pole which is<br>
-inclined backward and forced upward by springs, so as to press the<br>
-trolley against the bottom of the wire. Thus the trolley does not<br>
-increase the sagging of the wire, but tends to push it up a little in<br>
-its passage.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Trolley, Double.</span><br>
-A trolley with two rollers or grooved wheels, placed side by side, and<br>
-running on two parallel leads of wire. It is adapted to systems<br>
-employing through metallic trolley lines with the motors in multiple<br>
-arc, connecting or across the two leads.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Trolley Section.</span><br>
-An unbroken or continuous section of trolley wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Trouv&eacute;'s Solution.</span><br>
-An acid exciting and depolarizing solution for a zinc-carbon battery.<br>
-Its formula is as follows: Water, 80 parts; pulverized potassium<br>
-bichromate, 12 parts; concentrated sulphuric acid, 36 parts; all parts<br>
-by weight. The pulverized potassium bichromate is added to the water,<br>
-and the acid is added slowly with constant stirring. As much as 25 parts<br>
-potassium bichromate may be added to 100 parts of water. The heating<br>
-produced by the acid and water dissolves nearly all the potassium salt.<br>
-Use cold.<br>
-<br>
-<br>
-550&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">True Contact Force.</span><br>
-A species of electro-motive force whose existence is supposed to be<br>
-proved by the Peltier effect. The lowering in temperature of a contact<br>
-of dissimilar metals is attributed to a force that helps the current on<br>
-its way if in the direction of thermo-current proper to the junction and<br>
-opposing it if in the reverse. The true contact force is taken to<br>
-explain this phenomenon; thermo-electric force cannot, as there is no<br>
-heat or cold applied to the junction.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Trumpet, Electric.</span><br>
-An apparatus consisting of a vibrating tongue, kept in motion by<br>
-electricity as in the buzzer, q. v., placed in the small end of a<br>
-trumpet-shaped tube.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Trunking Switchboard.</span><br>
-A telephone switchboard arranged in sections, which sections are<br>
-connected by trunk lines, through which trunk lines the desired<br>
-connections<br>
-are made.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Trunk Lines.</span><br>
-In telephone distribution systems, the lines connecting different<br>
-stations, or different sections of a switch-board and used by anyone<br>
-requiring such connections; one trunk line answers for a number of<br>
-subscribers.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tube, Electric.</span><br>
-A tube of glass around which is pasted a series of tinfoil circles,<br>
-diamonds, or little squares, or other form of interrupted conductor. The<br>
-pieces generally are placed in the line of a spiral. When a static<br>
-discharge of electricity takes place along the conductor a row of bright<br>
-sparks is produced at the breaks in the conductor. These by reflection<br>
-are multiplied apparently, and a beautiful effect of intersecting or<br>
-crossing spirals of sparks is presented.<br>
-<br>
-The experiment is in line with the luminous pane and lightning jar, and<br>
-is used merely as a demonstration, or lecture experiment.<br>
-<br>
-Synonym--Luminous Tube.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Tubular Braid.</span><br>
-A braid woven of tissue or worsted, and tubular or hollow. Its object is<br>
-to provide a covering which can be drawn over joints in covered wires.<br>
-In making the joint the ends of the wires are necessarily bared, and a<br>
-short piece of tubular braid is used for covering them. It is drawn by<br>
-hand over the joint.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Turns.</span><br>
-An expression applied to the convolutions of wire in a solenoid,<br>
-electro-magnet, or other apparatus or construction of that kind. A turn<br>
-indicates a complete encircling of the core or axis of the object. Thus<br>
-a wire wound five times around a bar gives five turns.<br>
-<br>
-While this is its primary meaning the term if compounded may refer to<br>
-virtual turns. Thus an ampere-turn means one ampere passing through one<br>
-turn. But ten ampere-turns may mean ten amperes passing through ten<br>
-turns, five amperes passing through two turns, and so on. This use is<br>
-analogous to a dimension of length in a compound word, as foot-pound.<br>
-<br>
-[Transcriber's note: "But ten ampere-turns may mean ten amperes passing<br>
-through ONE turn or one ampere through ten turns, and so on."]<br>
-<br>
-There may be a number of kinds of turns qualified by descriptive<br>
-adjectives, as series-turns, the turns of wire in a series circuit of a<br>
-compound dynamo. In the same way there are shunt-turns. If series<br>
-ampere-turns or shunt ampere-turns are meant the word ampere should be<br>
-included.<br>
-<br>
-<br>
-551&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Turns, Dead, of a Dynamo.</span><br>
-The rotations of a dynamo armature while it is building itself up or<br>
-exciting itself. The expression is a bad one, as it is likely to be<br>
-confounded with the dead turns of armature wire.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Turns, Primary Ampere-.</span><br>
-The ampere-turns in a primary circuit of an induction coil or<br>
-transformer. In an electric welding transformer, or in the transformer<br>
-used in the alternating current system, where efficiency is an important<br>
-element, the ampere-turns in primary and secondary for an efficiency of<br>
-100 per cent. should be equal. In the case of an experimental induction<br>
-coil other considerations outweigh that of mere efficiency. Insulation,<br>
-including security from piercing, and the production of as long a spark<br>
-as possible, are, in these cases, the controlling consideration.<br>
-<br>
-[Transcriber's note: A 100 per cent efficient transformer is impossible,<br>
-but over 99 per cent is common. At room temperature there is always some<br>
-lost flux, eddy currents and resistive losses.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Turns, Secondary Ampere-.</span><br>
-The ampere-turns on the secondary circuit of an induction coil or<br>
-transformer. These depend on the path provided for the current. If of<br>
-negligible inductance, such as a number of incandescent lamps would<br>
-provide, the ampere-turns should be equal to those of the primary coil.<br>
-(See Turns, Primary Ampere.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Typewriter, Electric.</span><br>
-A typewriter in which the work of printing or of pressing the type faces<br>
-against the paper, or printing ribbon, is done by electro-magnetic<br>
-attraction. The keys close electric circuits, throwing the<br>
-electro-magnetic action into play. This involves the use of electricity<br>
-for what is ordinarily only a mechanical process. The strength of the<br>
-impression, however, is independent of the touch of the operator. It has<br>
-not come into very extensive use.<br>
-<br>
-[Transcriber's note: IBM introduced widely used electric typewriters in<br>
-1935.]</big></big><br>
-<big><big><br>
-</big></big><big><big><br>
-551&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ultra-gaseous Matter.</span><br>
-Gas so rarefied that its molecules do not collide or very rarely do so.<br>
-<br>
-Experiments of very striking nature have been devised by Crookes and<br>
-others to illustrate the peculiar phenomena that this matter presents.<br>
-The general lines of this work are similar to the methods used in<br>
-Geissler tube experiments, except that the vacua used are very much<br>
-higher.<br>
-<br>
-When the vacuum is increased so that but one-millionth of the original<br>
-gas is left the radiant state is reached. The molecules in their kinetic<br>
-movements beat back and forth in straight lines without colliding, or<br>
-with very rare collisions. Their motions can be guided and rendered<br>
-visible by electrification. A tube or small glass bulb with platinum<br>
-electrodes sealed in it, is exhausted to the requisite degree and is<br>
-hermetically sealed by melting the glass. The electrodes are connected<br>
-to the terminals of an induction coil or other source of high tension<br>
-electrification. The molecules which come in contact with a negatively<br>
-electrified pole are repelled from it in directions normal to its<br>
-surface. They produce different phosphorescent or luminous effects in<br>
-their mutual collisions.<br>
-<br>
-Thus if they are made to impinge upon glass, diamond or ruby, intense<br>
-phosphorescence is produced. A piece of platinum subjected to molecular<br>
-bombardment is brought to white heat. A movable body can be made to move<br>
-under their effects. Two streams proceeding from one negative pole repel<br>
-each other. The stream of molecules can be drawn out of their course by<br>
-a magnet.<br>
-<br>
-The experiments are all done on a small scale in tubes and bulbs,<br>
-resembling to a certain extent Geissler tubes.<br>
-<br>
-[Transcriber's note: These effects are caused by plasma--ionized gas and<br>
-electrons.]<br>
-<br>
-<br>
-552&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unbuilding.</span><br>
-The loss of its charge or excitation by a self-exciting dynamo. It is<br>
-the reverse of building-up. The latter indicates the exciting of the<br>
-field by the action of the machine itself; the former the spontaneous<br>
-loss of charge on open circuit or from other cause.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Underground Conductor.</span><br>
-An electric conductor insulated and placed under the surface of the<br>
-earth, as distinguished from aerial conductors.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Underground Electric Subway.</span><br>
-A subway for the enclosing of electric telegraph and other conductors<br>
-under the surface, generally in the line of streets, to do away with<br>
-telegraph poles and aerial lines of wire. Many systems have been<br>
-devised. The general type includes tubes called ducts in sets, called<br>
-conduits, bedded in concrete or otherwise protected. Every two or three<br>
-hundred feet the sets lead into a cistern-like cavity called a manhole.<br>
-The insulated wires or cables, generally sheathed with a lead alloy are<br>
-introduced into the tubes through the man-holes. A rope is first fed<br>
-through the tube. To do this short rods which screw together are<br>
-generally employed. One by one they are introduced, and each end one is<br>
-screwed to the series of rods already in the duct. When the end of the<br>
-duct is reached the rope is fastened to the last rod, and the rods are<br>
-then drawn through, unscrewed one by one and removed, the rope following<br>
-them. By means of the rope a windlass or capstan may be applied to draw<br>
-the cable into the duct. At least at every second man-hole the cables<br>
-have to be spliced.<br>
-<br>
-Each cable may contain a large number of conductors of small size for<br>
-telephoning, or a smaller number for electric light and power. The<br>
-tendency is now to separate the different classes of wires in important<br>
-lines, placing the heavier wires on one side of the street and the<br>
-telephone and telegraph wires on the other. This of course necessitates<br>
-two separate conduits.<br>
-<br>
-The advantage of underground distribution affects not only the<br>
-appearance of streets in doing away with unsightly telegraph poles, but<br>
-it also removes an element of danger at fires. Aerial wires interfere<br>
-greatly with the handling of ladders at fires, and expose the firemen<br>
-who attempt to cut them to danger to their lives from shock.<br>
-<br>
-<br>
-533&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unidirectional. adj.</span><br>
-Having one direction as a "unidirectional current" or "unidirectional<br>
-leak." The term is descriptive, and applicable to many cases.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Uniform. adj.</span><br>
-Unvarying; as a uniform potential difference, uniform current or<br>
-conductor of uniform resistance per unit of length. The term is<br>
-descriptive, and its application and meaning are obvious.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Uniform Field of Force.</span><br>
-A field of evenly distributed force; one in which the number of lines of<br>
-force per unit of area of any equipotential surface is the same.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unipolar. adj.</span><br>
-Strictly speaking this term means having only one pole, and is applied<br>
-to magnets, armatures and the like. In its use a solecism is involved,<br>
-for there is no such condition possible as unipolar magnetism or<br>
-distribution of magnetism. An example of its use is shown in unipolar<br>
-magnets. (See Magnet, Unipolar.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unipolar Armature.</span><br>
-An armature of a unipolar dynamo; an armature whose windings<br>
-continuously cut the lines of force about the one pole, and hence whose<br>
-polarity is unchanged in its rotation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unipolar Current Induction.</span><br>
-Current induction produced by moving a conductor through a magnetic<br>
-field of force so that it always cuts the lines in similar relation to<br>
-itself. Thus it produces a constant current through its own circuit, if<br>
-a closed one, and no commutator is required. As this case always in<br>
-practice amounts to the cutting of lines of force in the neighborhood of<br>
-a single pole the term unipolar is employed to designate the action.<br>
-<br>
-The simplest representation of unipolar induction is the rotating of a<br>
-conductor around the end of a bar magnet, its axis of rotation<br>
-corresponding with the axis of the magnet.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Unipolar Dynamo.</span><br>
-A dynamo in which one part of the conductor slides on or around the<br>
-magnet, so as always to cut lines of force near the same pole of the<br>
-magnet.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unit.</span><br>
-A directly or indirectly conventional and arbitrary quantity, in terms<br>
-of which measurements of things with dimensions expressible in the<br>
-chosen units are executed.<br>
-<br>
-Thus for length the c. g. s. unit is the centimeter; the B. E. unit is<br>
-the foot.<br>
-<br>
-<br>
-554&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unit, Absolute.</span><br>
-A unit based on the three fundamental units of length, mass and time.<br>
-These units are the centimeter, gram and second. Each one in itself may<br>
-be termed a fundamental absolute unit. The system of such units is<br>
-termed the centimeter-gram-second system.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unit, Angle.</span><br>
-A factor or datum in angular velocity, q. v. It is the angle subtended<br>
-by a portion of the circumference equal in length to the radius of the<br>
-circle. It is equal very nearly to 57.29578&deg; or 57&deg; 17' 44.8".<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unit, B. A.</span><br>
-This term, while logically applicable to any of the British Association<br>
-units, is often restricted to the ohm as formerly defined by the British<br>
-Association, the B. A. Unit of Resistance, q. v.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Unit, Fundamental.</span><br>
-The three units of length, mass and time, the centimeter, gram and<br>
-second, are termed fundamental units. On them is based the absolute<br>
-system of units, and on multiples of them the practical system of units.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Unit Jar.</span><br>
-A Leyden jar which is used as a unit of measure of charge.<br>
-<br>
-It consists of a Leyden jar about 4 inches long and 3/4 inch diameter,<br>
-with about 6 square inches of its outer and the same of its inner<br>
-surface coated with tinfoil. It is placed between a source of<br>
-electricity and a larger jar or battery of jars which is to be charged.<br>
-The inner coating connects with the machine; the outer coating with the<br>
-jars to be charged. Short conductors terminating in knobs connect with<br>
-inner and outer coatings, and the knobs are adjusted at any desired<br>
-distance apart.<br>
-<br>
-By the charging operation the large jar or battery of jars receives a<br>
-charge by induction, and the charge of the small jar is at first equal<br>
-to this quantity. After a while a spark passes from knob to knob,<br>
-discharging the small jar. This indicates the reception by the large<br>
-jars of the quantity of electricity represented by the charge of the<br>
-small jar. The charging goes on, and for every spark approximately the<br>
-same quantity of electricity is received by the larger jars.<br>
-<br>
-The sparking distance m is directly proportional to the quantity of<br>
-electricity, and inversely proportional to the area of coated surface,<br>
-or is proportional to the potential difference of the two coats. This is<br>
-only true for short sparking distance, hence for accuracy the knobs<br>
-should be adjusted not too far from each other.<br>
-<br>
-<br>
-555&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Unit of Supply.</span><br>
-A commercial unit for the sale of electric energy, as defined<br>
-provisionally by the English Board of Trade; 1,000 amperes flowing for<br>
-one hour under an E. M. F. of 1 volt; 3,600,000 volt-coulombs, or 1,000<br>
-watt-hours, are its equivalent. It is equal to 1000/746 = 1.34 electric<br>
-horse power.<br>
-<br>
-Synonym--Board of Trade Unit.<br>
-<br>
-[Transcriber's note: Now called a kilowatt-hour.]<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Units, Circular.</span><br>
-A system of units of cross-sectional area, designed especially for use<br>
-in describing wire conductors. The cross-sectional area of such is<br>
-universally a circle, and the areas of two wires of different sizes vary<br>
-with the square of their radii or diameters. Hence if the area of a<br>
-circle of known diameter is determined it may be used as a unit for the<br>
-dimensions of other circles. Any other circle will have an area<br>
-proportioned to the area of the unit circle, as the squares of the<br>
-diameters are to each other.<br>
-<br>
-In practise the commonest circular unit is the circular mil. This is the<br>
-area of a circle one mil, 1/1000 inch, in diameter and is equal to<br>
-.0000007854 square inch. A wire two mils in diameter has an area of four<br>
-circular mils; one ten mils in diameter has an area of one hundred<br>
-circular mils.<br>
-<br>
-Thus if the resistance of a given length of wire 1 mil in diameter is<br>
-stated, the corresponding resistance of the same length of wire of the<br>
-same material, but of other diameter, is given by dividing the first<br>
-wire's resistance by the square of the diameter in mils of the wire in<br>
-question.<br>
-<br>
-As it is a basic unit, most conveniently applied by multiplication, the<br>
-smaller units are used; these are the circular mil, and circular<br>
-millimeter.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Units, Derived.</span><br>
-Units derived by compounding or other processes, from the three<br>
-fundamental units. Such are the units of area, volume, energy and work,<br>
-momentum and electric units generally. In some cases the dimensions of<br>
-the derived unit may reduce to those of a simple unit as inductance<br>
-reduces to length, but the unit, as deduced from the fundamental ones,<br>
-is still a derived unit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Units, Practical.</span><br>
-A system of units employed in practical computation. The absolute units,<br>
-especially in electricity, have been found too large or too small, and<br>
-the attempt to make them more convenient has resulted in this system. It<br>
-is based on exactly the same considerations as the absolute system of<br>
-units, except that multiples of the original fundamental units of<br>
-length, mass, and time have been taken as the base of the new system.<br>
-These basic units are multiples of the fundamental units. They are the<br>
-following: The unit of length is 1E9 centimeters; the unit of mass is<br>
-1E-11 gram; the unit of time remains 1 second.<br>
-<br>
-While this has conduced to convenience in giving better sized units,<br>
-micro- and mega-units and other multiples or fractions have to be used.<br>
-The following are the principal practical electric units:<br>
-<small><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Electrostatic&nbsp;&nbsp;&nbsp;&nbsp; Electromagnetic</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-C. G. S Units.&nbsp;&nbsp;&nbsp; C. G. S. Units.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Intensity-Ampere&nbsp;&nbsp;
-equal to&nbsp;&nbsp;&nbsp;&nbsp;
-3E9&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1E-1</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Quantity-Coulomb&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3E9&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1E-1</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Potential-Volt&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; (1/3)*
-E-2&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1E8</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance-Ohm&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; (1/9)*
-E-11&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 1E9</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">Capacity-Farad&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-9E11&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-1E-9</span></small><br>
-<br>
-<br>
-556&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Universal Battery System.</span><br>
-A term in telegraphy. If several equal and high resistance telegraphic<br>
-circuits are connected in parallel with each other from terminal to<br>
-terminal of a battery of comparatively low resistance each circuit will<br>
-receive the same current, and of practically the same strength as if<br>
-only one circuit was connected. This is termed the universal battery<br>
-system. It is a practical corollary of Ohm's law. The battery being of<br>
-very low resistance compared to the lines the joining of several lines<br>
-in parallel practically diminishes the total resistance of the circuit<br>
-in proportion to their own number. Thus suppose a battery of ten ohms<br>
-resistance and ten volts E. M. F. is working a single line of one<br>
-hundred ohms resistance. The total resistance of the circuit is then one<br>
-hundred and ten ohms. The total current of the circuit, all of which is<br>
-received by the one line is 10/110 = .09 ampere, or 90 milliamperes. Now<br>
-suppose that a second line of identical resistance is connected to the<br>
-battery in parallel with the first. This reduces the external resistance<br>
-to fifty ohms, giving a total resistance of the circuit of sixty ohms.<br>
-The total current of the circuit, all of which is received by the two<br>
-lines in equal parts, is 10/60 = .166 amperes. But this is equally<br>
-divided between two lines, so that each one receives .083 ampere or 83<br>
-milliamperes; practically the same current as that given by the same<br>
-battery to the single line. It will be seen that high line resistance<br>
-and low battery resistance, relatively speaking, are required for the<br>
-system. For this reason the storage battery is particularly available.<br>
-The rule is that the resistance of the battery shall be less than the<br>
-combined resistance of all the circuits worked by it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Unmarked End.</span><br>
-The south-seeking pole of a magnet, so called because the other end,<br>
-called the marked end, is usually marked with a scratch or notch by the<br>
-maker, while the south pole is unmarked.<br>
-</big></big><big><big><span style="text-decoration: underline;"><br>
-</span></big></big><big><big><br>
-556&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">V.</span><br>
-(a) Symbol for velocity.<br>
-<br>
-(b) Symbol or abbreviation for volume.<br>
-<br>
-(c) Symbol or abbreviation for volt.<br>
-<br>
-<br>
-557&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">V. A.</span><br>
-Symbol or abbreviation for voltaic alternatives, q. v.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vacuum.</span><br>
-A space destitute of any substance. The great pervading substance is in<br>
-general sense the atmosphere. It is the gaseous mixture which surrounds<br>
-and envelopes the earth and its inhabitants. It consists of a simple<br>
-mixture of oxygen, 1 part, nitrogen, 4 parts, with 4 to 6 volumes of<br>
-carbonic acid gas in 10,000 volumes of air, or about one cubic inch to<br>
-one cubic foot. It presses with a force of about 14.7 lbs. per square<br>
-inch under the influence of the force of gravity. The term vacuum in<br>
-practise refers to any space from which air has been removed. It may be<br>
-produced chemically. Air may be displaced by carbonic acid gas and the<br>
-latter may be absorbed by caustic alkali or other chemical. The air may<br>
-be expelled and the space may be filled with steam which is condensed to<br>
-produce the vacuum. Of course in all cases the space must be included in<br>
-an hermetically sealed vessel, such as the bulb of an incandescent lamp.<br>
-But the universal method of producing a vacuum is by air pumps. An<br>
-absolute vacuum means the entire absence of gas or air, something almost<br>
-impossible to produce. A high vacuum is sometimes understood to mean one<br>
-in which the path of the molecules is equal in length to the diameter of<br>
-the containing vessels, as in Crookes' Radiometer and other apparatus<br>
-for illustrating the radiant condition of matter. The air left after<br>
-exhaustion is termed residual air or residual atmosphere.<br>
-<br>
-[Transcriber's note: Dry air is about .78 nitrogen, .21 oxygen, .01<br>
-argon, .00038 carbon dioxide, and trace amounts of other gases. Argon<br>
-was suspected by Henry Cavendish in 1785. It was discovered in 1894 by<br>
-Lord Rayleigh and Sir William Ramsay.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vacuum, Absolute.</span><br>
-A space free of all material substance. It is doubtful whether an<br>
-absolute vacuum has ever been produced.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vacuum, High.</span><br>
-An approximate vacuum, so nearly perfect that the molecules of the<br>
-residual gas in their kinetic motions rarely collide, and beat back and<br>
-forth between the walls of the containing vessel, or between any solid<br>
-object contained in the vessel and the walls of the vessel. The gas in<br>
-such a vacuum is in the radiant or ultra-gaseous state. (See<br>
-Ultra-gaseous Matter.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vacuum, Low.</span><br>
-A vacuum inferior to a high vacuum; a vacuum in which the molecules<br>
-collide with each other and do not move directly from side to side of<br>
-the containing vessel.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vacuum, Partial.</span><br>
-A space partially exhausted of air so as to contain less than an equal<br>
-volume of the surrounding atmosphere. It really should come below a low<br>
-vacuum, but is often treated as synonymous therewith.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vacuum, Torricellian.</span><br>
-The vacuum existing above the mercurial column in a barometer tube. The<br>
-principle of this vacuum is applied in the Geissler and other air pumps.<br>
-(See Pump, Geissler--Pump, Sprengel--Pump, Swinburne.)<br>
-<br>
-<br>
-558&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Valency.</span><br>
-The relative power of replacing hydrogen or combining therewith<br>
-possessed by different elements; the number of atomic bonds belonging to<br>
-any element. Thus oxygen has a twofold valency, is bivalent or is a<br>
-dyad, and combines with two atoms of hydrogen because the latter has a<br>
-unitary atomicity, is monovalent or is a monad.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Valve, Electrically Controlled.</span><br>
-A valve which is moved by or whose movements are regulated by<br>
-electricity.<br>
-<br>
-In the block system of railroad signaling the semaphores are worked by<br>
-weights and pneumatic cylinders and pistons. The valves for admitting or<br>
-releasing the compressed air are operated by coil and plunger mechanism.<br>
-There are many other instances of the control of valves by the electric<br>
-current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vapor Globe.</span><br>
-A protecting glass globe surrounding an incandescent lamp, when the lamp<br>
-is to be used in an atmosphere of explosive vapor, as in mines or<br>
-similar places; or when in a place where it is exposed to dripping water<br>
-which would break the hot lamp bulb if it fell upon it.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Variable Period.</span><br>
-The period of adjustment when a current is started through a conductor<br>
-of some capacity. It is the period of duration of the variable state, q.<br>
-v., in a conductor. As indicated in the next definition in a cable of<br>
-high electrostatic capacity a variable period of nearly two minutes may<br>
-exist. This indicates the retardation in signaling to be anticipated in<br>
-cables and other lines of high capacity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Variable State.</span><br>
-When an electric circuit is closed the current starts through the<br>
-conductor with its full strength from the point of closure, and advances<br>
-with a species of wave front so that some time elapses before it attains<br>
-its full strength in the most distant parts of the conductor, owing to<br>
-its having to charge the conductor to its full capacity at the given<br>
-potential. The state of the line while the current thus varies is called<br>
-the variable state.<br>
-<br>
-A long telegraph line when a message is being transmitted may be always<br>
-in the variable state. The current at the receiving end may never attain<br>
-its full strength.<br>
-<br>
-In the case of such a conductor as the Atlantic cable, 108 seconds would<br>
-be required for a current to attain 9/10 of its full strength at the<br>
-distant end, and but 1/5 second to attain 1/100 of its final value.<br>
-During the period of increase of current the variable state exists.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Variation of the Compass.</span><br>
-The declination of the magnetic needle. (See Elements, Magnetic.) As the<br>
-declination is subject to daily, annual and secular variations, it is<br>
-unfortunate that this term is synonymous with declination. Thus the<br>
-variation of the compass means its declination, while there is also the<br>
-variation of the declination and of other elements. The term variation<br>
-of the compass is more colloquial than the more definite expression<br>
-"declination," or "magnetic declination."<br>
-<br>
-<br>
-559&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Variometer.</span><br>
-An apparatus used in determining the relative values of the horizontal<br>
-component of the earth's magnetic field in different places.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Varley's Condenser.</span><br>
-A static condenser whose conducting surfaces are platinum electrodes<br>
-immersed in dilute sulphuric acid. When the potential difference is<br>
-1/50th that of a Daniell's cell, two square inches of platinum have a<br>
-capacity equal to that of an air condenser whose plates have an area of<br>
-80,000,000 square inches, and separated 1/8th of an inch from each<br>
-other. As the E. M. F. increases the capacity also increases.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Varley's Resistances.</span><br>
-Variable resistances formed of discs of carbonized cloth, q. v., piled<br>
-up, and pressed together more or less firmly to vary the resistance as<br>
-desired.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Varnish.</span><br>
-A glossy transparent coating of the nature of paint, applied as a<br>
-protective, or ornamental coating to objects.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Varnish, Electric.</span><br>
-Alcoholic or etherial varnishes are the best for electrical apparatus.<br>
-They dry quickly and perfectly, and tend to form surfaces unfavorable to<br>
-the hygroscopic collection of water. Sealing wax dissolved in alcohol,<br>
-or shellac dissolved in the same solvent are used for electrical<br>
-apparatus, although the first is rather a lacquer than a varnish.<br>
-Etherial solution of gum-copal is used to agglomerate coils of wire. It<br>
-is well to bake varnished objects to harden the coating.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Varnish, Red.</span><br>
-A solution of sealing wax in 90 per cent. alcohol. It is best made thin<br>
-and applied in several coats, each coat being allowed to dry perfectly<br>
-before the next is applied. It is often seen on Leyden jars. It is a<br>
-protector from surface leakage.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vat.</span><br>
-A vessel for chemical or other solutions. A depositing vat is one in<br>
-which a plating solution is worked, for the deposition of electroplate<br>
-upon articles immersed in the liquid, and electrolyzed by an electric<br>
-current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Velocity.</span><br>
-The rate of motion of a body. It is usually expressed in distance<br>
-traversed per second of time. The absolute unit is one centimeter per<br>
-second or kine. The foot per second is very largely used also.<br>
-<br>
-The dimensions of velocity are length (L) divided by time (T) or L/T.<br>
-<br>
-<span style="font-weight: bold;">Velocity, Angular.</span><br>
-Velocity in a circle defined by the unit angle, or the angle which<br>
-subtends a circular arc equal in length to itself. The radius of the<br>
-circle traversed by the moving body does not enter into this definition,<br>
-as the real velocity of the object is not stated. If its angular<br>
-velocity and the radius of the path it travels are given its actual<br>
-velocity can be deduced.<br>
-<br>
-<br>
-560&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Velocity of Signaling.</span><br>
-The speed of transmission of electric signals is affected by the nature<br>
-of the line, as regards its static capacity, and by the delicacy of the<br>
-receiving instruments, which may need a more or less strong current to<br>
-be affected. Thus of an original current one per cent. may suffice to<br>
-operate a sensitive instrument. This might give almost the velocity of<br>
-light, while if the instrument would only respond to the full current<br>
-nearly two minutes (see Variable State) might be required for the<br>
-production of a signal.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Velocity Ratio.</span><br>
-A term applied to the ratios existing between the electrostatic and<br>
-electro-magnetic units. If we take as numerators the dimensions of the<br>
-different qualities in the electrostatic system, and their dimensions in<br>
-the electro-magnetic system as denominators, the fractions thus obtained<br>
-reduce to expressions containing only velocity or V in some form. Thus<br>
-if we divide the dimensions of the electrostatic quantity by the<br>
-dimensions of electro-magnetic quantity the quotient is simply V or<br>
-velocity. A like division for potential, electrostatic and<br>
-electro-magnetic gives (1/V), and so on.<br>
-<br>
-The value of the velocity ratio is very nearly 3E10 (sometimes given as<br>
-2.98E10) centimeters per second. This is almost exactly that of light<br>
-(2.9992E10 centimeters per second.) This is one of the proofs of Clerk<br>
-Maxwell's magnetic theory of light. (See Maxwell's Theory of Light.)<br>
-<br>
-[Transcriber's note: The SI metre was defined in 1983 such that the<br>
-speed of light in a vacuum is exactly 299,792,458 metres per second or<br>
-about 186,282.397 miles per second.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ventilation of Armature.</span><br>
-In a dynamo or motor ventilation of the armature is often provided for<br>
-by apertures through it in order to prevent heating. This heating is<br>
-caused by Foucault currents. By proper disposition of the interior of<br>
-the armature with properly disposed vanes and orifices an action like<br>
-that of a fan blower can be produced, which by creating a current of air<br>
-cools the machine very efficiently.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Verticity, Poles of.</span><br>
-Points upon the earth's surface where the horizontal component of<br>
-magnetic force disappears, leaving only the vertical component active.<br>
-The term is derived from the verticity of the dipping needle when over<br>
-either of them.<br>
-<br>
-<br>
-561&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vibration Period.</span><br>
-In electrical resonance the period of a vibration in an electrical<br>
-resonator. The length of this period indicates the quality of the<br>
-resonator in responding to electrical oscillations by sympathetic<br>
-vibration. For conductors of small resistance the period is thus<br>
-calculated. Let T be the period of one-half a full vibration; L the<br>
-absolute coefficient of self-induction expressed in centimeters or in<br>
-henries X 10-9; C the electrostatic capacity of the terminals, also<br>
-expressed in the same unit; v the velocity of light in centimeters per<br>
-second. Then we have the formula<br>
-<br>
-&nbsp; T = PI * SquareRoot( L * C ) / v<br>
-<br>
-[Transcriber's note: If the inductance is in henries and the capacitance<br>
-in farads, frequency in hertz = 1/(2 * PI * squareRoot( L * C ) )]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vibration, Sympathetic.</span><br>
-A vibration in a cord or other body susceptible of elastic vibration<br>
-produced by the vibrations of exactly the same period in a neighboring<br>
-vibrating body. Thus if two tuning forks are tuned to precisely the same<br>
-pitch, and are placed near each other, if one is sounded it will start<br>
-the other into vibration by sympathy.<br>
-<br>
-In electricity its application is found in electric resonance<br>
-experiments. The resonator has a definite period of electric resonance,<br>
-and is made to give a spark by the exciter of identical period. This is<br>
-by what may be called electric sympathetic vibration, and is exactly<br>
-analogous to the action of the tuning forks upon each other.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vibrator, Electro-magnetic.</span><br>
-The make and break mechanism used on induction coils, or other similar<br>
-apparatus in which by alternate attractions by and releases from an<br>
-electro-magnet an arm or spring is kept in motion. In most cases the<br>
-work is done by a single magnet, whose armature is attracted to the<br>
-magnet, when the latter is excited, but against the action of a spring<br>
-which tends to pull it away from the magnet. In its motions a make and<br>
-break action is produced, to give the requisite alternations of<br>
-attraction and release. Two electro-magnets may be connected so as<br>
-alternately to be excited and keep an arm carrying a mutual armature in<br>
-vibration, or the same result may be attained by a polarized relay. The<br>
-make and break is illustrated under Bell, Electric--Coil, Induction--<br>
-Anvil.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Villari's Critical Value.</span><br>
-Magnetization induced or residual in a wire is diminished on stretching,<br>
-provided that the magnetization corresponds to an inducing force above a<br>
-certain critical value, known as above; this being (Sir Wm. Thomson)<br>
-about 24 times the terrestrial intensity. Below that critical value<br>
-tension increases the magnetization of a magnetized wire. The effects of<br>
-transverse expansive stress are opposed to those of longitudinal<br>
-stretching. (Daniell.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Viole's Standard of Illuminating Power.</span><br>
-A standard authorized by the International Congress of 1881. It is the<br>
-light given by one square centimeter of platinum, melted, but just at<br>
-the point of solidification. It is equal to 20 English standard candles<br>
-almost exactly.<br>
-<br>
-It has not been very widely accepted, the tendency among photometrists<br>
-being to adhere to the old standards, carcel or candle. It is obvious<br>
-that actual use of the Viole would be very inconvenient and would<br>
-involve expensive apparatus, difficult to work with.<br>
-<br>
-Synonym--Viole.<br>
-<br>
-<br>
-562&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vis Viva.</span><br>
-The kinetic energy of a body in motion; "mechanical energy."<br>
-<br>
-<span style="font-weight: bold;">Vitreous Electricity.</span><br>
-Positive electricity; the electricity produced on the surface of glass<br>
-by rubbing it with silk and other substances. (See Electrostatic<br>
-Series.)<br>
-<br>
-The term "positive electricity" should be allowed to supplant it. It is<br>
-the analogue and opposite of resinous electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vitriol, Blue.</span><br>
-A colloquial or trade name for copper sulphate (Cu SO4).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vitriol, Green.</span><br>
-A colloquial or trade name for ferrous sulphate (Fe SO4).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vitriol, White.</span><br>
-A colloquial or trade name for zinc sulphate (Zn SO4).<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volt.</span><br>
-The practical unit of electro-motive force or potential difference. It<br>
-may be referred to various data.<br>
-<br>
-An electro-motive force of one volt will cause a current of one ampere<br>
-to flow through a resistance of one ohm.<br>
-<br>
-A condenser of one farad capacity charged with one coulomb will have a<br>
-rise of potential of one volt.<br>
-<br>
-The cutting of 100,000,000 lines of force per second by a conductor<br>
-induces one volt E. M. F.<br>
-<br>
-A Daniell's battery gives an E. M. F. of 1.07 volts; about the most<br>
-familiar approximate standard that can be cited.<br>
-<br>
-It is equal to 1/300 absolute electrostatic unit.<br>
-<br>
-It is equal to 1E8 absolute electro-magnetic units.<br>
-<br>
-[Transcriber's note: The SI definition of a volt: The potential<br>
-difference across a conductor when a current of one ampere dissipates<br>
-one watt of power.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltage.</span><br>
-Potential difference or electro-motive force expressed in volts; as a<br>
-voltage of 100 volts. Thus voltage may express the electro-motive force<br>
-absorbed in a conductor, while electro-motive force is a term generally<br>
-applied where it is produced, evolved or present in the object. The term<br>
-voltage of a lamp expresses simply the volts required, but does not<br>
-suggest the possession of electromotive force.<br>
-<br>
-<br>
-563&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltage, Terminal.</span><br>
-The voltage or potential difference at the terminals of an electric<br>
-current generator, such as a dynamo, as distinguished from the total<br>
-electro-motive force of the dynamo or generator.<br>
-<br>
-In batteries the distinction is not generally made in practice; the<br>
-total electro-motive force of the battery is made the basis of<br>
-calculations.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltaic. adj.</span><br>
-This adjective is used to qualify a great many things appertaining to or<br>
-connected with current electricity. It is derived from Volta, the<br>
-inventor of the voltaic battery, and now tends to displace the term<br>
-"galvanic," formerly in general use.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltaic Alternatives.</span><br>
-A term used in electro-therapeutics or medical electricity to indicate<br>
-an alternating battery current.<br>
-<br>
-Synonym--Alternative current.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Voltaic Effect.</span><br>
-The potential difference developed by contact of different conductors.<br>
-It is the basis of the contact theory, q. v., of electricity, although<br>
-it may be accepted as the expression for a condition of things by those<br>
-who reject the above theory. This potential difference is slight when<br>
-the conductors are separated, but it is calculated that it would be<br>
-enormous could the metals be so quickly separated as to hold each its<br>
-own charge.<br>
-<br>
-Thus if a copper and a zinc plate are assumed to be in contact, really<br>
-1/20000000 centimeter or 1/50000000 inch apart, they may be treated as a<br>
-pair of condenser plates. Being so near, their density of charge, which<br>
-is a strongly bound charge, is enormous. If it were possible to separate<br>
-them without permitting any discharge, their potential would rise by the<br>
-separation, on the principle of Epinus' condenser, q. v., to such an<br>
-extent that they would spark through twenty feet of air. (See Volta's<br>
-Fundamental Experiment.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Voltaic Electricity.</span><br>
-Electricity of low potential difference and large current intensity;<br>
-electricity such as produced by a voltaic battery; current or dynamic<br>
-electricity as opposed to static electricity.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltameter.</span><br>
-In general an apparatus for determining the quantity of electricity<br>
-passing through a conductor by measuring the electrolytic action it can<br>
-perform.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltameter, Copper.</span><br>
-An apparatus which may be of similar construction with the silver<br>
-voltameter (see Voltameter, Silver), but in which a copper anode and a<br>
-solution of copper sulphate are substituted for the silver anode and<br>
-silver nitrate solution. One coulomb corresponds to .329 milligram or<br>
-.005084 grain of copper deposited. It is not accepted as of as high a<br>
-standard as the silver voltameter.<br>
-<br>
-The electrodes should be placed half an inch from each other. Two square<br>
-plate electrodes may conveniently be used, and not less than two square<br>
-inches on each plate should be the area per ampere of current.<br>
-<br>
-<br>
-564&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Voltameter, Differential, Siemens'.</span><br>
-A volume or gas voltameter with duplicate eudiometers and pairs of<br>
-electrodes. It is used for determining the resistance of the platinum<br>
-conductor used in his pyrometer. A current divides between the two<br>
-voltameters; in one branch of the circuit the platinum conductor is<br>
-placed, in the other a known resistance. The current strength varying<br>
-inversely with the resistance, the resistances of the two conductors are<br>
-inversely proportional to the gas evolved.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Voltameter, Gas.</span><br>
-A voltameter whose indications are based on the electrolysis of water,<br>
-made an electrolyte by the addition of sulphuric acid. The gases evolved<br>
-are measured. It may take several forms.<br>
-<br>
-In one form it is an apparatus consisting of a single eudiometer or<br>
-graduated glass tube with upper end closed and its lower end or mouth<br>
-open, collecting the mixture of hydrogen and oxygen.<br>
-<br>
-In the form shown in the cut three tubes are connected, the side tubes<br>
-representing eudiometers. For each side tube there is a platinum<br>
-electrode. In this apparatus the oxygen and hydrogen are connected in<br>
-opposite tubes. A is an open tube filled with dilute sulphuric acid. By<br>
-opening the cocks on B and C they can both be completely filled with<br>
-acid. As shown in the cut, this operation is not yet completed. The<br>
-hydrogen alone may in this case be measured.<br>
-<br>
-The mixed gas voltameter has only one eudiometer.<br>
-<br>
-The exact equivalents are only approximately known. The volume of mixed<br>
-gases per coulomb is given as .1738 cubic centimeters (Ayrton); .172<br>
-cubic centimeters (Hospitalier); and other values by other authorities.<br>
-The hydrogen is equal to 1/3 of the mixed gases almost exactly.<br>
-<br>
-Synonyms--Volume Voltameter--Sulphuric Acid Voltameter.<br>
-<br>
-The gas is measured at 0&ordm; (32&ordm; F.) and 76 centimeters, or 30
-inches<br>
-barometer.<br>
-<br>
-<br>
-<img style="width: 234px; height: 522px;" alt=""
- src="images/564F341.JPG"><br>
-Fig. 341. GAS VOLTAMETER.<br>
-<br>
-<br>
-565&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-If the gas is measured in cubic inches, the temperature in degrees F.,<br>
-and the barometric height in inches, the following formula may be used<br>
-for reduction to standard pressure and temperature. It is the volume<br>
-corresponding to one coulomb.<br>
-&nbsp; ( .01058 * 30 * (491 + F&ordm; - 32) ) / (h* 491)<br>
-<br>
-For the metric measurements and degrees C.<br>
-&nbsp; (.1738 * 76 * (273 + C&ordm;)) / (h X 273)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltameter, Silver.</span><br>
-An apparatus consisting of a platinum vessel containing a solution of<br>
-silver nitrate into which solution a silver anode dips, whose end is<br>
-wrapped in muslin to prevent the detachment of any particles. When a<br>
-current is passed by connecting one terminal to the dish and the other<br>
-to the rod, securing a proper direction of current, silver will be<br>
-deposited on the dish and the same amount will be dissolved from the<br>
-rod. The dish is weighed before and after the test. Its increase in<br>
-weight gives the silver deposited.<br>
-<br>
-<br>
-<img style="width: 627px; height: 568px;" alt=""
- src="images/565F342.JPG"><br>
-FIG. 342. SILVER VOLTAMETER.<br>
-<br>
-<br>
-In the cut Ag is the silver anode, Pt is the platinum dish, r is the<br>
-conducting rod, p is a wooden standard, Cu is a copper plate on which<br>
-the dish rests and which also serves as a conductor and contact surface,<br>
-b is a muslin cloth to place over the silver plate to prevent detached<br>
-particles falling in the dish; s s' are the binding screws.<br>
-<br>
-The weight of silver corresponding to a coulomb is given variously by<br>
-different authorities. Ayrton and Daniell take 1.11815 milligrams or<br>
-.017253 grain of metallic silver. Other determinations are as follows:<br>
-&nbsp; 1.1183 milligrams&nbsp;&nbsp; (Kohlrausch).<br>
-&nbsp; 1.124&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-(Merscart).<br>
-<br>
-The solution of silver nitrate should be from 15 to 30 per cent. of<br>
-strength. The current should not exceed one ampere per six square<br>
-inches; or in other words not more than about 3/1000 grain of silver<br>
-should be deposited per second on a square inch area of the dish. The<br>
-edge of the silver disc or anode should be about equidistant from the<br>
-side and bottom of the dish. The latter notes are due to Lord Rayleigh.<br>
-<br>
-<br>
-566&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Voltameter, Weight.</span><br>
-A voltameter in which the amount of decomposition is determined by<br>
-weighing the products, or one of the products of the electrolysis. The<br>
-titles Voltameter, Copper, and Voltameter, Silver, may be cited.<br>
-<br>
-<br>
-<img style="width: 623px; height: 465px;" alt=""
- src="images/566F343.JPG"><br>
-Fig. 343. WEIGHT VOLTAMETERS.<br>
-<br>
-<br>
-In the cuts are shown examples of weight gas voltameters. These are<br>
-tubes light enough to be weighed when charged. Each contains a<br>
-decomposition cell T, with its platinum electrodes, and charged with<br>
-dilute sulphuric acid, while t is calcium chloride or other drying agent<br>
-to collect any water carried off as vapor or as spray by the escaping<br>
-gases; c are corks placed in position when the weighing is being<br>
-executed, so as to prevent the calcium chloride from absorbing moisture<br>
-from the air.<br>
-<br>
-In use the tubes are weighed. They are then connected to the circuit,<br>
-after removal of the corks, and the decomposition proceeds. After a<br>
-sufficient time they are removed, the corks put in place, and they are<br>
-weighed again. The loss gives the water decomposed.<br>
-<br>
-The water corresponding to one coulomb is<br>
-<small><span style="font-family: monospace;">&nbsp; .09326
-milligram&nbsp;&nbsp; .001430 grain,&nbsp;&nbsp; Ayrton,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-.092&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Hospitalier,</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-.0935&nbsp;&nbsp;&nbsp;&nbsp;
-"&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-Daniell.</span></small><br>
-<br>
-<br>
-567&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltametric Law.</span><br>
-The law on which voltameters are based. The amount of chemical<br>
-decomposition produced by an electric current in a given electrolyte is<br>
-proportional to the quantity of electricity passed through the solution.<br>
-<br>
-<br>
-<span style="font-family: monospace;"><img
- style="width: 500px; height: 568px;" alt="" src="images/567F344.JPG"></span><br>
-Fig. 344. VOLTA'S FUNDAMENTAL EXPERIMENT.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volta's Fundamental Experiment.</span><br>
-The moistened finger is placed on the upper plate of a condensing or<br>
-electrophorous electroscope. The other hand holds a plate of zinc z,<br>
-soldered to a plate of copper c. The lower plate is touched with the<br>
-copper. On removing the cover the gold leaves l diverge and with<br>
-negative electricity. Hence zinc is supposed to be positively<br>
-electrified when in contact with copper. The experiment is used to<br>
-demonstrate the contact theory of electricity.<br>
-<br>
-<br>
-568&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volta's Law of Galvanic Action.</span><br>
-The electro-motive force between any two metals in an electro-chemical<br>
-series (see Electro-Chemical Series) is equal to the sum of the<br>
-electro-motive forces between all the intervening metals.<br>
-<br style="font-weight: bold;">
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Volta's Law of Thermo-electricity.</span><br>
-In a compound circuit, consisting of a number of different metals, all<br>
-points of which are at the same temperature, there is no current.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volt, B. A.</span><br>
-The volt based on the B. A. ohm. It is equal to .9889 legal volt.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volt, Congress.</span><br>
-The volt based upon the congress or legal ohm; the legal volt.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volt-coulomb.</span><br>
-The unit of electric work; the watt-second; it is equivalent to<br>
-<small><span style="font-family: monospace;">&nbsp;
-1.0E7&nbsp;&nbsp;&nbsp;&nbsp; ergs.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp; .24068&nbsp;&nbsp;
-gram degree C. (calorie)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp; .737337&nbsp; foot
-lbs.,</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp; .00134&nbsp;&nbsp;
-horse power seconds.</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Volt Indicator.</span><br>
-A form of easily read voltameter for use in electric light stations and<br>
-for similar work.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volt, Legal.</span><br>
-The legal volt based upon the legal ohm. It is equal to 1.00112 B. A.<br>
-volt.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltmeter.</span><br>
-An instrument for determining the potential difference of any two<br>
-points.<br>
-<br>
-In many cases it is a calibrated galvanometer wound with a coil of high<br>
-resistance. The object to be attained is that it shall receive only an<br>
-insignificant portion of current and that such portion shall suffice to<br>
-actuate it. If connected in parallel with any portion of a circuit, it<br>
-should not noticeably diminish its resistance.<br>
-<br>
-The divisions into which ammeters range themselves answer for<br>
-voltmeters. In practice the same construction is adopted for both. The<br>
-different definitions of ammeters in disclosing the general lines of<br>
-these instruments are in general applicable to voltmeters, except that<br>
-the wire winding of the coils must be of thin wire of great length. The<br>
-definitions of ammeters may be consulted with the above understanding<br>
-for voltmeters.<br>
-<br>
-In the use made of voltmeters there is a distinction from ammeters. An<br>
-ammeter is a current measurer and all the current measured must be<br>
-passed through it. But while a voltmeter is in fact a current measurer,<br>
-it is so graduated and so used that it gives in its readings the<br>
-difference of potential existing between two places on a circuit, and<br>
-while measuring the current passing through its own coils, it is by<br>
-calibration made to give not the current intensity, but the<br>
-electro-motive force producing such current.<br>
-<br>
-In use it may be connected to two terminals of an open circuit, when as<br>
-it only permits an inconsiderable current to pass, it indicates the<br>
-potential difference existing between such points on open circuit. Or it<br>
-may be connected to any two parts of a closed circuit. Owing to its high<br>
-resistance, although it is in parallel with the intervening portion of<br>
-the circuit, as it is often connected in practice, it is without any<br>
-appreciable effect upon the current. It will then indicate the potential<br>
-difference existing between the two points.<br>
-<br>
-<br>
-569&nbsp;&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltmeter, Battery.</span><br>
-A voltmeter for use in running batteries. In one form (Wirt's) it is<br>
-constructed for a low range of voltage, reading up to two and a half<br>
-volts and having exactly one ohm resistance, thus giving the battery<br>
-some work to do.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Voltmeter, Cardew.</span><br>
-A voltmeter in which the current passing through its conductor heats<br>
-such conductor, causing it to expand. Its expansion is caused to move an<br>
-index needle. By calibration the movements of the needle are made to<br>
-correspond to the potential differences producing the actuating currents<br>
-through it. The magnetic action of the current plays no part in its<br>
-operation. It is the invention of Capt. Cardew, R. E.<br>
-<br>
-The construction of the instrument in one of its most recent forms is<br>
-shown in the cut. On each side of the drum-like case of the instrument<br>
-are the binding screws. These connect with the blocks m and n. To these<br>
-the fine wire conductor is connected and is carried down and up over the<br>
-two pulleys seen at the lowest extremity, its centre being attached to<br>
-c. From c a wire is carried to the drum p, shown on an enlarged scale on<br>
-the left of the cut. A second wire from the same drum or pulley connects<br>
-to the spring S. The winding of the two wires is shown in the separate<br>
-figure of c, where it is seen that they are screwed fast to the<br>
-periphery of the little drum, and are virtually continuations of each<br>
-other. By the screw A the tension of the spring S is adjusted.<br>
-<br>
-On the shaft of the little drum p is a pinion, which works into the<br>
-teeth of the cog-wheel r. The shaft of r is extended through the dial<br>
-of the instrument, and carries an index. The dial is marked off for<br>
-volts; g g and h h are standards for carrying the pulleys.<br>
-<br>
-<br>
-570&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The action of the instrument is as follows. The current passing through<br>
-the wire heats it. This current by Ohm's law is proportional to the<br>
-electro-motive force between the terminals. As it is heated it expands<br>
-and as it cools contracts, definite expanding and contracting<br>
-corresponding to definite potential differences. As the wire expands and<br>
-contracts the block or pin c moves back and forth, thus turning the drum<br>
-p and cogwheel r one way or permitting it to turn the other way under<br>
-the pull of the spring S.<br>
-<br>
-<br>
-<img style="width: 376px; height: 649px;" alt=""
- src="images/570F345.JPG"><br>
-Fig. 345. CARDEW VOLTMETER.<br>
-<br>
-<br>
-In this construction for a given expansion of the wire the piece c only<br>
-moves one half as much. The advantage of using a wire twice as long as<br>
-would be required for the same degree of movement were the full<br>
-expansion utilized is that a very thin wire can be employed. Such a wire<br>
-heats and cools more readily, and hence the instrument reaches its<br>
-reading more quickly or is more deadbeat, if we borrow a phraseology<br>
-properly applicable only to instruments with oscillating indexes.<br>
-<br>
-In the most recent instruments about thirteen feet of wire .0025 inch in<br>
-diameter, and made of platinum-silver alloy is used.<br>
-<br>
-<br>
-571&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-If the potential difference to be measured lies between 30 and 120 volts<br>
-the wire as described suffices. But to extend the range of the<br>
-instrument a resistance in series is required. If such resistance is<br>
-double that of the instrument wire, and remains double whether the<br>
-latter is hot or cold the readings on the scale will correspond to<br>
-exactly twice the number of volts. This is brought about in some<br>
-instruments by the introduction in series of a duplicate wire, precisely<br>
-similar to the other wire, and like it, carried around pulleys and kept<br>
-stretched by a spring.<br>
-<br>
-[Transcriber's note: If the series resistance is twice that of the<br>
-voltmeter, the indicated voltage will be ONE THIRD of the total<br>
-voltage.]<br>
-<br>
-Thus whatever ratio of resistance exists between the two wires cold, it<br>
-is always the same at any temperature, as they both increase in<br>
-temperature at exactly the same rate. Tubes are provided to enclose the<br>
-stretched wires and pulleys, which tubes are blackened.<br>
-<br>
-The voltmeter is unaffected by magnetic fields, and, as its<br>
-self-induction is very slight, it is much used for alternating currents.<br>
-The tubes containing the wire may be three feet long.<br>
-<br>
-Its disadvantages are thus summarized by Ayrton. It absorbs a good deal<br>
-of energy; it cannot be constructed for small potential differences, as<br>
-the wire cannot be made thicker, as it would make it more sluggish;<br>
-there is vagueness in the readings near the zero point and sometimes<br>
-inaccuracy in the upper part of the scale.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Volts, Lost.</span><br>
-The volts at the terminals of a dynamo at full load fall short of their<br>
-value on open circuit. The difference of the two values are termed lost<br>
-volts.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Voltmeter, Electrostatic.</span><br>
-A voltmeter based on the lines of the quadrant electrometer. It includes<br>
-two sets of quadrants, each oppositely excited by one of the two parts,<br>
-whose potential difference is to be determined. They attract each other<br>
-against a controlling force as of gravity.<br>
-<br>
-One form has the two sets poised on horizontal axes, bringing the parts<br>
-so that the flat quadrants move in vertical planes.<br>
-<br>
-In another form a number of quadrants are used in each set, the members<br>
-of the two sets alternating with each other. One set is fixed, the<br>
-others move and carry the index.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Vulcanite.</span><br>
-Vulcanized india rubber which by high proportion of sulphur and proper<br>
-vulcanization has been made hard. It is sometimes distinguished from<br>
-ebonite as being comparatively light in color, often a dull red, while<br>
-ebonite is black. For its electrical properties see Ebonite.<br>
-<br>
-Both substances have their defects, in producing surface leakage.<br>
-Washing with weak ammonia, or with dilute soda solution, followed by<br>
-distilled water, is recommended for the surface, if there is any trouble<br>
-with surface leakage. It may also be rubbed over with melted paraffine<br>
-wax.<br>
-<br>
-</big></big><big><big><br>
-572&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">W.</span><br>
-(a) A symbol or abbreviation for watt.<br>
-<br>
-(b) A symbol or abbreviation for work.<br>
-<br>
-(c) A symbol or abbreviation for weight.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Wall Bracket.</span><br>
-A telegraph bracket to be attached to the external walls of buildings to<br>
-which wires are attached as they come from the poles to reach<br>
-converters, or for direct introduction into a building.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Wall Sockets.</span><br>
-Sockets for incandescent lamps constructed to be attached to a wall.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Ward.</span><br>
-Direction in a straight line; a term proposed by Prof. James Thompson.<br>
-The words "backward" and "forward" indicate its scope.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Water.</span><br>
-A compound whose molecule consists of two atoms of hydrogen and one atom<br>
-of oxygen; formula, H2 O.<br>
-<br>
-Its specific gravity is 1, it being the base of the system of specific<br>
-gravities of solids and liquids.<br>
-<br>
-If pure, it is almost a non-conductor of electricity. If any impurity is<br>
-present it still presents an exceedingly high, almost immeasurable true<br>
-resistance, but becomes by the presence of any impurity an electrolyte.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Water Equivalent.</span><br>
-In a calorimeter of any kind the weight of water which would be raised<br>
-as much as is the calorimeter with its contents by the addition of any<br>
-given amount of heat received by the calorimeter.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Waterproof Lamp Globe.</span><br>
-An outer globe for incandescent lamps, to protect them from water.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Watt.</span><br>
-(a) The practical unit of electric activity, rate of work, or rate of<br>
-energy. It is the rate of energy or of work represented by a current of<br>
-one ampere urged by one volt electro-motive force; the volt-ampere.<br>
-<br>
-It is the analogue in electricity of the horse power in mechanics;<br>
-approximately, 746 watts represent one electric horse power.<br>
-<br>
-Ohm's law, taken as C = E/R, gives as values for current, C and E/R, and<br>
-for electro- motive force C R. In these formulas, C represents current<br>
-strength, R represents resistance and E represents electro-motive force.<br>
-Then a watt being the product of electro-motive force by current<br>
-strength, we get the following values for rate of electric energy, of<br>
-which the watt is the practical unit: (1) E2/R -- (2) C*E -- (3) C2 * R.<br>
-<br>
-<br>
-The equivalents of the watt vary a little according to different<br>
-authorities. Ayrton gives the following equivalents: 44.25 foot pounds<br>
-per minute--.7375 foot pounds per second--1/746 horse power. These<br>
-values are practically accurate. Hospitalier gives .7377 foot pounds per<br>
-second. Hering gives .737324 foot pounds per second, and 1000/745941<br>
-horse power.<br>
-<br>
-<br>
-573&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-It is equal to 1E7 ergs per second.<br>
-<br>
-Synonym--Volt-ampere.<br>
-<br>
-(c) It has been proposed to use the term as the unit of energy, instead<br>
-of activity or rate of energy (Sir C. W. Siemens, British Association,<br>
-1882); this use has not been adopted and may be regarded as abandoned.<br>
-<br>
-[Transcriber's note; Watt is a unit of POWER--energy per unit of time.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Watt-hour.</span><br>
-A unit of electric energy or work; one watt exerted or expended for one<br>
-hour.<br>
-<br>
-It is equivalent to :<br>
-<small><span style="font-family: monospace;">&nbsp;&nbsp; 866.448&nbsp;
-gram-degrees C. (calories)</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 2654.4&nbsp;&nbsp;&nbsp;
-foot lbs.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-3600&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; watt-seconds or volt-coulombs.</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;
-60&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; watt-minutes.</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Watt-minute.</span><br>
-A unit of electric energy or work; one watt exerted or expended for one<br>
-minute.<br>
-<br>
-It is equivalent to<br>
-<small><span style="font-family: monospace;">&nbsp; 14.4408&nbsp;
-gram-degrees C. (calories),</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; 44.240&nbsp;&nbsp; foot
-pounds,</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-60&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; watt seconds or volt-coulombs,</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;
-1/60&nbsp;&nbsp;&nbsp;&nbsp; watt hour.</span></small><br>
-<br>
-<br>
-<span style="font-weight: bold;">Watts, Apparent.</span><br>
-The product in an alternating current dynamo of the virtual amperes by<br>
-the virtual volts. To give the true watts this product must be<br>
-multiplied by the cosine of the angle of lead or lag. (See Current,<br>
-Wattless.)<br>
-<br>
-[Transcriber's note: This is now called a volt-amp. The usual usage is<br>
-KVA, or kilovolt-ampere.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Watt-second.</span><br>
-A unit of electric energy or work. One watt exerted or expended for one<br>
-second.<br>
-<br>
-It is equivalent to<br>
-<small><span style="font-family: monospace;">&nbsp;
-.24068&nbsp;&nbsp;&nbsp;&nbsp; gram degree C. (calorie),</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; .000955&nbsp;&nbsp;&nbsp;
-lb. degree F.,</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; .737337&nbsp;&nbsp;&nbsp;
-foot lbs.,</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; .0013406&nbsp;&nbsp; horse
-power second (English),</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; .0013592&nbsp;&nbsp; horse
-power second (metric).</span></small><br>
-<br>
-Synonym--Volt-coulomb.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Waves, Electro-magnetic.</span><br>
-Ether waves caused by electromagnetic disturbances affecting the<br>
-luminiferous ether. (See Discharge, Oscillatory--Maxwell's Theory of<br>
-Light--Resonance. Electric.)<br>
-<br>
-[Transcriber's note: The Michaelson-Morley experiment (1887) had already<br>
-called ether into question, but quantum theory and photons are decades<br>
-in the future.]<br>
-<br>
-<br>
-574&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Weber.</span><br>
-(a.) A name suggested by Clausius and Siemens to denote a magnet pole of<br>
-unit strength. This use is abandoned.<br>
-<br>
-(b.) It has been used to designate the unit of quantity--the coulomb.<br>
-This use is abandoned.<br>
-<br>
-(c.) It has been used to designate the unit of current strength the<br>
-ampere. This use is abandoned.<br>
-<br>
-[Transcriber's note: Definition (a) is now used. One weber of magnetic<br>
-flux linked to a circuit of one turn produces an electromotive force of<br>
-1 volt if it is reduced to zero at a uniform rate in 1 second.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Weber-meter.</span><br>
-An ampere-meter or ammeter. The term is not used since the term "weber,"<br>
-indicating the ampere or coulomb, has been abandoned.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Welding, Electric.</span><br>
-Welding metals by heat produced by electricity. The heat may be produced<br>
-by a current passing through the point of junction (Elihu Thomson) or by<br>
-the voltaic arc. (Benardos &amp; Olzewski.)<br>
-<br>
-<br>
-<img style="width: 448px; height: 489px;" alt=""
- src="images/574F346.JPG"><br>
-Fig. 346. ELECTRIC WELDING INDUCTION COIL.<br>
-<br>
-<br>
-The current process is carried out by pressing together the objects to<br>
-be united, while holding them in conducting clamps. A heavy current is<br>
-turned on by way of the clamps and rapidly heats the metals at the<br>
-junction, which is of course the point of highest resistance. As the<br>
-metal softens, it is pressed together, one of the clamps being mounted<br>
-with feed motion, flux is dropped on if necessary, and the metal pieces<br>
-unite.<br>
-<br>
-The most remarkable results are thus attained; almost all common metals<br>
-can be welded, and different metals can be welded together. Tubes and<br>
-other shapes can also be united. In many cases the weld is the strongest<br>
-part.<br>
-<br>
-<br>
-575&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The alternating current is employed. A special dynamo is sometimes used<br>
-to produce it. This dynamo has two windings on the armature. One is of<br>
-fine wire and is in series with the field magnets and excites them. The<br>
-other is of copper bars, and connects with the welding apparatus, giving<br>
-a current of high intensity but actuated by low potential.<br>
-<br>
-Where the special dynamo is not used, an induction coil or transformer<br>
-is used. The primary includes a large number of convolutions of<br>
-relatively fine wire; the secondary may only be one turn of a large<br>
-copper bar.<br>
-<br>
-The cut shows in diagram an electric welding coil. P is the primary coil<br>
-of a number of turns of wire; S S is the secondary, a single copper bar<br>
-bent into an almost complete circle. It terminates in clamps D D for<br>
-holding the bars to be welded. B C, B' C are the bars to be welded. They<br>
-are pressed together by the screw J. The large coil I of iron wire<br>
-surrounding the coils represents the iron core.<br>
-<br>
-The real apparatus as at present constructed involves many<br>
-modifications. The diagram only illustrates the principle of the<br>
-apparatus.<br>
-<br>
-In welding by the voltaic arc the place to be heated is made an<br>
-electrode of an arc by connection with one terminal of an electric<br>
-circuit. A carbon is connected to the other terminal. An arc is started<br>
-by touching and withdrawal of the carbon. The heat may be used for<br>
-welding, soldering, brazing, or even for perforating or dividing metal<br>
-sheets.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Welding Transformer.</span><br>
-The induction coil or transformer used in electric welding. For its<br>
-general principles of construction, see Welding, Electric.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Wheatstone's Bridge.</span><br>
-A system of connections applied to parallel circuits, including<br>
-resistance coils for the purpose of measuring an unknown resistance. A<br>
-single current is made to pass from A through two parallel connected<br>
-branches, joining together again at C. A cross connection B D has a<br>
-galvanometer or other current indicator in circuit. In any conductor<br>
-through which a current is passing, the fall of potential at given<br>
-points is proportional to the resistance between such points. Referring<br>
-to the diagram a given fall of potential exists between A and C. The<br>
-fall between A and B is to the fall between A and C as the resistance r<br>
-between A and B is to the resistance r + r' between A and C. The same<br>
-applies to the other branch, with the substitution of the resistances s<br>
-and S' and the point D for r r' and B. Therefore, if this proportion<br>
-holds, r : r' : : s : S'. No current will go through B D , and the<br>
-galvanometer will be unaffected. Assume s' to be of unknown resistance,<br>
-the above proportion will give it, if r, r' and s are known, or if the<br>
-ratio of r to r' and the absolute value of s is known.<br>
-<br>
-<br>
-576&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-In use the resistances r, r', and s are made to vary as desired. To<br>
-measure an unknown resistance it is introduced at S', and one of the<br>
-other resistances is varied until the galvanometer is unaffected. Then<br>
-the resistance of S' is determined by calculation as just explained. The<br>
-artificial resistances may be resistance coils, q. v., or it is enough<br>
-to have one unknown resistance at s. Then if the length of wire ABC is<br>
-accurately known, the point B can be shifted along it until the balance<br>
-is attained. The relative lengths A B, and B C, will then give the ratio<br>
-r : r' needed for the calculation. This assumes the wire ABC to be of<br>
-absolutely uniform resistance. This is the principle of the meter-bridge<br>
-described below. The use of coils is the more common method and is<br>
-carried out by special resistance boxes, with the connections arranged<br>
-to carry out the exact principle as explained. The principle of<br>
-construction and use of a resistance box of the Wheatstone bridge type,<br>
-as shown in the cut, is described under Box Bridge, q. v.<br>
-<br>
-<br>
-<img style="width: 414px; height: 610px;" alt=""
- src="images/576F347.JPG"><br>
-FIG. 347. WHEATSTONE BRIDGE CONNECTIONS.<br>
-<br>
-<br>
-<img style="width: 582px; height: 430px;" alt=""
- src="images/576F348.JPG"><br>
-FIG. 348. TOP OF BOX BRIDGE.<br>
-<br>
-<br>
-577&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-The next cut shows the sliding form of bridge called the meter bridge,<br>
-if the slide wire is a meter long or a half- or a quarter-meter bridge,<br>
-etc., according to the length of this wire. It is described under Meter<br>
-Bridge, q. v. Many refinements in construction and in proper proportion<br>
-of resistances for given work apply to these constructions.<br>
-<br>
-Synonyms--Electric Balance--Resistance Bridge--Wheatstone's Balance.<br>
-<br>
-<br>
-<img style="width: 614px; height: 396px;" alt=""
- src="images/577F349.JPG"><br>
-Fig. 349. METER BRIDGE.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Whirl, Electric.</span><br>
-(a) A conductor carrying an electric current is surrounded by circular<br>
-lines of force, which are sometimes termed an electric whirl.<br>
-<br>
-(b) The Electric Flyer. (See Flyer, Electric.)<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Wimshurst Electric Machine.</span><br>
-An influence machine for producing high potential or static electricity.<br>
-<br>
-Two circular discs of thin glass are mounted on perforated hubs or<br>
-bosses of wood or ebonite. Each hub has a groove turned upon it to<br>
-receive a cord. Each disc is shellacked. They are mounted on a<br>
-horizontal steel spindle so as to face and to be within one-eighth of an<br>
-inch of each other. On the outside of each disc sixteen or eighteen<br>
-sectors of tinfoil or thin metal are cemented.<br>
-<br>
-<br>
-578&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-Two curved brass rods terminating in wire brushes curved into a<br>
-semi-ellipse just graze the outer surfaces of the plates with their<br>
-brushes. They lie in imaginary planes, passing through the axis of the<br>
-spindle and at right angles from each other.<br>
-<br>
-Four collecting combs are arranged horizontally on insulating supports<br>
-to collect electricity from the horizontal diameters of the discs. These<br>
-lie at an angle of about 45&deg; with the other equalizing rods.
-Discharging<br>
-rods connect with the collecting combs.<br>
-<br>
-The principle of the machine is that one set of sector plates act as<br>
-inductors for the other set. Its action is not perfectly understood.<br>
-<br>
-It works well in damp weather, far surpassing other influence machines<br>
-in this respect. On turning the handle a constant succession or stream<br>
-of sparks is produced between the terminals of the discharging rods.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Windage.</span><br>
-In a dynamo the real air gap between the armature windings and pole<br>
-pieces is sometimes thus termed.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Wind, Electric.</span><br>
-The rush of air particles from a point connected to a statically charged<br>
-condenser.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Winding, Compound.</span><br>
-A method of winding a generator or motor in which a shunt winding is<br>
-used for the field magnets and in which also a second winding of the<br>
-magnet is placed in series with the outer circuit. (See Winding,<br>
-Series--Winding, Shunt.)<br>
-<br>
-<br>
-<img style="width: 607px; height: 372px;" alt=""
- src="images/578F350.JPG"><br>
-Fig. 350. CHARACTERISTIC CURVES OF SHUNT AND SERIES WINDING.<br>
-<br>
-<br>
-The object of compound winding is to make a self-regulating dynamo and<br>
-this object is partly attained for a constant speed.<br>
-<br>
-The characteristic curves of shunt and series winding are of opposite<br>
-natures. The first increases in electro-motive force for resistance in<br>
-the outer circuit, the latter decreases under the same conditions. If<br>
-the windings are so proportioned that these conditions for each one of<br>
-the two windings are equal and opposite, it is evident that the<br>
-characteristic may be a straight line. This, however, it will only be at<br>
-a single speed of rotation.<br>
-<br>
-<br>
-579&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Winding, Disc.</span><br>
-A winding which (S. P. Thompson) may be treated as a drum winding<br>
-extended radially, the periphery corresponding to the back end of the<br>
-drum. The magnet poles are generally placed so as to face the side or<br>
-sides of the disc.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Winding, Lap.</span><br>
-A method of winding disc and drum armatures. It consists in lapping back<br>
-each lead of wire towards the preceding lead upon the commutator end of<br>
-the armature. Thus taking the letter U as the diagrammatical<br>
-representation of a turn of wire in connecting its ends to the<br>
-commutator bars they are brought towards each other so as to connect<br>
-with contiguous commutator bars. This carries out the principle of<br>
-keeping the two members of the U moving in regions of opposite polarity<br>
-of field, so that the currents induced in them shall have opposite<br>
-directions, thus producing a total current in one sense through the bent<br>
-wire.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Winding, Long Shunt.</span><br>
-A system of compound winding for dynamos and motors. The field is wound<br>
-in series and, in addition thereto, there is a shunt winding connected<br>
-across from terminal to terminal of the machine, and which may be<br>
-regarded either as a shunt to the outer circuit, or as a shunt to the<br>
-series-field and armature winding. (See Winding, Short Shunt.)<br>
-<br>
-Synonyms--Series and Long Shunt Winding.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Winding, Multiple.</span><br>
-A winding of an electro-magnet, in which separate coils are wound on the<br>
-core, so that one or any number may be used as desired in parallel or in<br>
-series. For each coil a separate binding post should be provided.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Winding, Multipolar.</span><br>
-Winding adapted for armatures of multi-polar dynamos or motors.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Winding, Series.</span><br>
-A method of winding a generator or motor, in which one of the<br>
-commutator-brush connections is connected to the field-magnet winding;<br>
-the other end of the magnet winding connects with the outer circuit. The<br>
-other armature-brush connects with the other terminal of the outer<br>
-circuit.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Winding, Series and Separate Coil.</span><br>
-A method of automatic regulation applied to alternating current dynamos.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Winding, Short Shunt.</span><br>
-A method of compound winding for dynamos and motors. The field is wound<br>
-in series, and in addition thereto there is a shunt winding connected<br>
-from brush to brush only, thus paralleling the armature. (See Winding,<br>
-Long Shunt.)<br>
-<br>
-Synonyms--Series and Short Shunt Winding.<br>
-<br>
-<br>
-580&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Winding, Shunt.</span><br>
-A method of winding a generator or motor. Each commutator-brush has two<br>
-connections. One set are the terminals of the outer circuit, the other<br>
-set are the terminals of the field-magnet windings. In other words, the<br>
-field-magnet windings are in shunt or in parallel with the outer<br>
-circuit.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Winding, Shuttle.</span><br>
-A method of dynamo or motor-armature winding. A single groove passes<br>
-longitudinally around the core and in this the wire is continuously<br>
-wound. The system is not now used. The old Siemens' H armature<br>
-illustrates the principle.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Winding, Wave.</span><br>
-A method of winding disc and drum armatures. It consists in advancing<br>
-the commutator ends of the U shaped turns progressively, so that as many<br>
-commutator bars intervene between any two consecutive commutator<br>
-connections of the wire as there are leads of wire on the drum between<br>
-consecutive leads of the wire. This is carried out with due regard to<br>
-the principle that taking the letter U as the diagrammatical<br>
-representation of a turn of wire, its two members must move through<br>
-regions of the field of opposite polarity.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Wire Finder.</span><br>
-A galvanometer or other instrument used for identifying the ends of a<br>
-given wire in a cable containing several.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Work.</span><br>
-When a force acts upon a body and the body moves in the direction of the<br>
-force, the force does work. Hence, work is the action of a force through<br>
-space against resistance.<br>
-<br>
-It is generally expressed in compound units of length and weight, as<br>
-foot-pounds, meaning a pound raised one foot.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Work, Electric, Unit of.</span><br>
-The volt-coulomb, q. v., or watt-second, as it is often termed.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Working, Diode.</span><br>
-In multiplex telegraphy the transmission of two messages,<br>
-simultaneously, over one wire. (See Telegraphy, Multiple.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Working, Contraplex.</span><br>
-A variety of duplex telegraphy in which the messages are sent from<br>
-opposite ends of the line, simultaneously, so as to be transmitted in<br>
-opposite directions. (See Working, Diplex.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Working, Diplex.</span><br>
-In duplex telegraphy the sending of two independent messages from the<br>
-same end of the line in the same direction.<br>
-<br>
-<br>
-581&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Working, Double Curb.</span><br>
-A method of working telegraph lines. When a signal is sent the line is<br>
-charged. This has to be got rid of, and is an element of retardation. In<br>
-double curb working it is disposed of by sending a momentary current<br>
-first in the reverse, and then in the same, and finally in the reverse<br>
-direction. This is found to reduce the charge to a very low point.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Working, Hexode.</span><br>
-In multiplex telegraphy the transmission of six messages simultaneously<br>
-over one wire. (See Telegraphy, Multiplex.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Working, Pentode.</span><br>
-In multiplex telegraphy the transmission of five messages simultaneously<br>
-over one wire. (See Telegraphy, Multiplex.)<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Working, Reverse Current.</span><br>
-A method of telegraphy, in which the currents are reversed or alternated<br>
-in direction.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Working, Single Curb.</span><br>
-A simpler form of telegraph signaling than double curb working. It<br>
-consists in sending a reverse current through the line for each signal<br>
-by reversing the battery connection.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Working, Tetrode.</span><br>
-In multiplex telegraphy the transmission of four messages simultaneously<br>
-over the same line. (See Telegraphy, Multiplex.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Working, Triode.</span><br>
-In multiplex telegraphy the transmission of three messages<br>
-simultaneously over the same wire. (See Telegraphy, Multiplex.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Work, Unit of.</span><br>
-The erg, q. v. It is the same as the unit of energy, of which work is<br>
-the corelative, being equal and opposite to the energy expended in doing<br>
-it. There are many other engineering units of work, as the foot-pound<br>
-and foot-ton.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Yoke.</span><br>
-In an electro-magnet, the piece of iron which connects the ends furthest<br>
-from the poles of the two portions of the core on which the wire is<br>
-wound.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Zamboni's Dry Pile.</span><br>
-A voltaic pile or battery. It is made of discs of paper, silvered or<br>
-tinned on one side and sprinkled on the other with binoxide of<br>
-manganese. Sometimes as many as 2,000 of such couples are piled up in a<br>
-glass tube and pressed together with two rods which form the terminals.<br>
-They maintain a high potential difference, but having very high<br>
-resistance and slight polarization capacity, give exceedingly small<br>
-quantities.<br>
-<br>
-<span style="font-weight: bold;">Zero.</span><br>
-(a) The origin of any scale of measurement.<br>
-<br>
-(b) An infinitely small quantity or measurement.<br>
-<br>
-<br>
-582&nbsp;&nbsp; STANDARD ELECTRICAL DICTIONARY.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Zero, Absolute.</span><br>
-From several considerations it is believed that at a certain temperature<br>
-the molecules of all bodies would touch each other, their kinetic motion<br>
-would cease, and there would be no heat. This temperature is the<br>
-absolute zero. It is put at -273&deg; C. (-459&deg; F.)<br>
-<br>
-[Transcriber's note; The modern value is 0</big></big><big><big>&deg;</big></big><big><big>
-Kelvin,&nbsp; -273.15</big></big><big><big>&deg;</big></big><big><big>
-C, or<br>
--459.67</big></big><big><big>&deg;</big></big><big><big> F. The lowest
-reported temperature observed is 1E-10</big></big><big><big>&deg;</big></big><big><big>
-K.]<br>
-<br>
-<br>
-<span style="font-weight: bold;">Zero, Potential.</span><br>
-Conventionally, the potential of the earth. True zero potential could<br>
-only exist in the surface of a body infinitely distant from other<br>
-electrified bodies.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Zero, Thermometric.</span><br>
-There are three thermometric zeros. In the R&eacute;aumur and centigrade<br>
-scales, it is at the temperature of melting ice; in the Fahrenheit<br>
-scale, it is 32&deg; F. below that temperature, or corresponds to
--17.78&deg; C.<br>
-<br>
-The third is the absolute zero. (See Zero, Absolute.)<br>
-<br>
-<br>
-<span style="font-weight: bold;">Zinc.</span><br>
-A metal; one of the elements; atomic weight, 65.1;<br>
-specific gravity, 6.8 to 7.2.<br>
-<small><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-microhms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance at 0&deg; C. (32&deg;
-F.), per centimeter cube,&nbsp;&nbsp;
-5.626</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance at 0&deg; C. (32&deg;
-F.), per inch
-cube,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; 2.215</span><br
- style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">Relative resistance (silver =
-1),&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-3.741</span><br style="font-family: monospace;">
-<br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-ohms.</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">Resistance of a wire, 1 foot
-long, weighing 1 grain,&nbsp;&nbsp; .5766</span><br
- style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (a) 1 foot long, 1
-millimeter
-diameter,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-33.85</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (b) 1 meter long, weighing
-1
-gram,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.4023</span><br style="font-family: monospace;">
-<span style="font-family: monospace;">&nbsp; (c) 1 meter long, 1
-millimeter
-diameter,&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
-.07163</span></small>
-<br>
-<br>
-Zinc is principally used in electrical work as the positive plate in<br>
-voltaic batteries.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Zincode.</span><br>
-The terminal connecting with the zinc plate, or its equivalent in an<br>
-electric circuit; the negative electrode; the kathode. A term now little<br>
-used.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Zinc Sender.</span><br>
-An apparatus used in telegraphy for sending a momentary reverse current<br>
-into the line after each signal, thus counteracting retardation.<br>
-<br>
-<br>
-<span style="font-weight: bold;">Zone, Peripolar.</span><br>
-In medical electricity, the region surrounding the polar zone, q. v.<br>
-<br>
-<br style="font-weight: bold;">
-<span style="font-weight: bold;">Zone, Polar.</span><br>
-In medical electricity, the region surrounding the electrode applied to<br>
-the human body.<br>
-<br>
-<br>
-</big></big><big><big><br>
-583-624&nbsp; INDEX.<br>
-<br>
-&nbsp;&nbsp;&nbsp; Page<br>
-A&nbsp; 7<br>
-Absolute&nbsp; 7<br>
-Absolute Calibration&nbsp; 97<br>
-Absolute Electric Potential&nbsp; 429<br>
-Absolute Electrometer&nbsp; 222<br>
-Absolute Galvanometer&nbsp; 266<br>
-Absolute Measurement&nbsp; 8<br>
-Absolute Potential&nbsp; 428<br>
-Absolute Temperature&nbsp; 8<br>
-Absolute Unit&nbsp; 554<br>
-Absolute Unit Resistance, Weber's&nbsp;&nbsp; 468<br>
-Absolute Vacuum&nbsp; 557<br>
-Absolute Zero&nbsp; 581<br>
-Abscissa&nbsp; 7<br>
-Abscissas, Axis of&nbsp;&nbsp; 54<br>
-Absorption, Electric&nbsp;&nbsp; 8<br>
-A. C. C.&nbsp; 8<br>
-Acceleration&nbsp; 8<br>
-Accumulator&nbsp; 8<br>
-Accumulator, Electrostatic&nbsp; 8<br>
-Accumulator, Water Dropping&nbsp;&nbsp; 9<br>
-Acetic Acid Battery&nbsp;&nbsp; 58<br>
-Acheson Effect&nbsp;&nbsp; 208<br>
-Acid, Carbonic&nbsp; 108<br>
-Acid, Chromic, Battery&nbsp; 61<br>
-Acid, Hydrochloric, Battery&nbsp;&nbsp; 66<br>
-Acid, Spent&nbsp; 491<br>
-Acid, Sulphuric&nbsp;&nbsp;&nbsp; 497<br>
-Acidometer&nbsp; 10<br>
-Acierage&nbsp; 494<br>
-Aclinic Line&nbsp; 10<br>
-Acoustic Telegraphy&nbsp;&nbsp; 10<br>
-Acoutemeter&nbsp; 10, 53<br>
-Action, Electrophoric&nbsp;&nbsp; 230<br>
-Action, Local&nbsp; 331<br>
-Action, Magne-crystallic&nbsp;&nbsp; 335<br>
-Action, Refreshing&nbsp; 454<br>
-Action, Secondary&nbsp; 477<br>
-Actinic Photometer&nbsp; 411<br>
-Actinic Rays.&nbsp;&nbsp; 11<br>
-Actinism&nbsp; 11<br>
-Actinometer, Electric&nbsp;&nbsp; 11<br>
-Active Electric Circuit,&nbsp;&nbsp; 123<br>
-Activity&nbsp; 11<br>
-Actual Horse Power&nbsp; 290<br>
-Adapter&nbsp; 11<br>
-A. D. C.,&nbsp;&nbsp; 11<br>
-Adherence, Electro-magnetic&nbsp;&nbsp; 11<br>
-Adherence, Magnetic&nbsp; 338<br>
-Adjuster, Cord&nbsp;&nbsp; 152<br>
-Adjustment of Brushes&nbsp; 90<br>
-Admiralty Rules of Heating&nbsp; 12<br>
-AEolotropic&nbsp; 34<br>
-Aerial Cable&nbsp; 95<br>
-Aerial Conductor&nbsp; 12<br>
-Affinity&nbsp; 12<br>
-Affinity, Molecular&nbsp;&nbsp; 380<br>
-After Current,.&nbsp;&nbsp; 159<br>
-Agglomerate Leclanch&eacute; Battery&nbsp; 66<br>
-Agir Motor&nbsp;&nbsp; 13<br>
-Agone&nbsp; 13<br>
-Agonic Line,&nbsp;&nbsp; 13<br>
-Air&nbsp; 13<br>
-Air Blast&nbsp; 13<br>
-Air Condenser&nbsp; 14<br>
-Air Field&nbsp; 252<br>
-Air Gaps&nbsp; 15<br>
-Air Line Wire&nbsp; 15<br>
-Air Pump, Heated&nbsp;&nbsp; 15<br>
-Air Pump, Mercurial&nbsp;&nbsp; 16<br>
-Air Pumps, Short Fall&nbsp;&nbsp; 16<br>
-Alarm, Burglar&nbsp;&nbsp; 16<br>
-Alarm, Electric&nbsp; 17<br>
-Alarm, Fire, Electric Automatic&nbsp;&nbsp; 257<br>
-Alarm, Fire and Heat&nbsp; 17<br>
-Alarm, Overflow&nbsp;&nbsp; 18<br>
-Alarm, Water Level&nbsp;&nbsp; 18<br>
-Alcohol, Electric Rectification of&nbsp;&nbsp; 18<br>
-Alignment,&nbsp;&nbsp; 18<br>
-Allotropy&nbsp; 18<br>
-Alloy&nbsp; 18<br>
-Alloy, Platinum&nbsp; 419<br>
-Alloy, Platinum-Silver&nbsp; 419<br>
-Alloys, Paillard&nbsp; 400<br>
-Alphabet, Telegraphic&nbsp;&nbsp; 19<br>
-Alternating&nbsp; 23<br>
-Alternating Current&nbsp; 159<br>
-Alternating Current Arc&nbsp; 23<br>
-Alternating Current Dynamo&nbsp; 193<br>
-Alternating Current Generator or Dynamo&nbsp; 24<br>
-Alternating Current Meter&nbsp; 373<br>
-Alternating Current System&nbsp; 23<br>
-Alternating Field&nbsp; 252<br>
-Alternative Current&nbsp; 563<br>
-Alternative Path&nbsp; 24<br>
-Alternatives, Voltaic&nbsp;&nbsp; 563<br>
-Alternator&nbsp; 24<br>
-Alternator, Constant Current&nbsp;&nbsp; 24<br>
-Alternator, Dead Point of an&nbsp;&nbsp; 177<br>
-Alternation&nbsp; 23<br>
-Alternation, Complete&nbsp;&nbsp; 23<br>
-Alternation, Cycle of&nbsp;&nbsp; 175<br>
-Alum Battery&nbsp; 58<br>
-Aluminum&nbsp; 24<br>
-Aluminum Battery&nbsp; 58<br>
-Amalgam&nbsp; 24<br>
-Amalgamation&nbsp; 25<br>
-Amber&nbsp; 25<br>
-American Twist Joint&nbsp;&nbsp; 309<br>
-Ammeter&nbsp; 26<br>
-Ammeter, Ayrton&nbsp;&nbsp; 26<br>
-Ammeter, Commutator&nbsp;&nbsp; 26<br>
-Ammeter, Cunynghame's&nbsp;&nbsp; 26<br>
-Ammeter, Eccentric Iron Disc&nbsp; 27<br>
-Ammeter, Electro-magnetic&nbsp; 27<br>
-Ammeter, Gravity&nbsp; 27<br>
-Ammeter, Magnetic Vane&nbsp; 27<br>
-Ammeter, Magnifying Spring&nbsp;&nbsp; 28<br>
-Ammeter, Permanent Magnet&nbsp;&nbsp; 28<br>
-Ammeter, Reducteur for&nbsp;&nbsp; 453<br>
-Ammeter, Solenoid&nbsp;&nbsp; 28<br>
-Ammeter, Spring&nbsp;&nbsp; 28<br>
-Ammeter, Steel Yard&nbsp; 28<br>
-Ammunition Hoist, Electric&nbsp;&nbsp; 29<br>
-Amperage&nbsp; 29<br>
-Ampere&nbsp; 29<br>
-Ampere- and Volt-meter Galvanometer&nbsp; 274<br>
-Ampere Arc&nbsp;&nbsp; 30<br>
-Ampere Balance&nbsp; 56<br>
-Ampere Currents&nbsp; 30<br>
-Ampere Feet&nbsp; 30<br>
-Ampere-hour&nbsp; 30<br>
-Amperes, Lost&nbsp;&nbsp; 30<br>
-Amp&ecirc;re's Memoria Technica&nbsp;&nbsp; 30<br>
-Ampere Meters&nbsp; 26, 30<br>
-Ampere Meter, Balance&nbsp; 391<br>
-Ampere Meter, Neutral Wire&nbsp;&nbsp; 391<br>
-Ampere-minute&nbsp; 30<br>
-Ampere Ring&nbsp; 30<br>
-Ampere-second&nbsp; 30<br>
-Ampere's Theory of Magnetism&nbsp; 354<br>
-Ampere-turns&nbsp; 31<br>
-Ampere-turns, Primary&nbsp;&nbsp; 31<br>
-Ampere-turns, Secondary&nbsp;&nbsp; 31, 551<br>
-Ampere Windings&nbsp; 31<br>
-Amp&eacute;rian Currents&nbsp; 165<br>
-Amplitude of Waves&nbsp; 31<br>
-Analogous Pole&nbsp; 31, 425<br>
-Analysis&nbsp; 31<br>
-Analysis, Electric&nbsp; 32<br>
-Analysis, Electrolytic&nbsp; 214<br>
-Analyzer, Electric&nbsp;&nbsp; 32<br>
-Anelectrics&nbsp; 32<br>
-Anelectrotonus&nbsp; 32<br>
-Angle of Declination&nbsp; 32, 177<br>
-Angle of the Polar Span&nbsp; 32<br>
-Angle of Inclination or Dip&nbsp; 33<br>
-Angle of Lag&nbsp; 33-318<br>
-Angle of Lead&nbsp; 33<br>
-Angle of Maximum Sensitiveness&nbsp; 479<br>
-Angle of Polar Span&nbsp; 423<br>
-Angle, Polar&nbsp;&nbsp; 423<br>
-Angle, Unit&nbsp; 554<br>
-Angular Currents&nbsp; 165<br>
-Angular Currents, Laws of&nbsp;&nbsp; 165<br>
-Angular Force&nbsp; 544<br>
-Angular Velocity&nbsp; 32, 559<br>
-Animal Electricity&nbsp; 33<br>
-Animal System, Electric Excitability of&nbsp;&nbsp; 247<br>
-Anion&nbsp; 33<br>
-Anisotropic&nbsp; 34<br>
-Annealing, Electric&nbsp; 34<br>
-Annular Electro-magnet&nbsp; 216<br>
-Annunciator&nbsp; 34<br>
-Annunciator Clock&nbsp; 35<br>
-Annunciator Clock, Electric&nbsp;&nbsp; 127<br>
-Annunciator Drop&nbsp; 35<br>
-Annunciator, Gravity Drop&nbsp;&nbsp; 35<br>
-Annunciator, Needle&nbsp; 35<br>
-Annunciator, Swinging or Pendulum&nbsp; 35<br>
-Anodal Diffusion&nbsp; 35<br>
-Anode&nbsp; 36<br>
-Anodic Closure Contraction&nbsp; 36<br>
-Anodic Duration Contraction&nbsp; 36<br>
-Anodic Opening Contraction&nbsp; 36<br>
-Anodic Reactions&nbsp; 36<br>
-Anomalous Magnet&nbsp; 335<br>
-Anti-induction Conductor&nbsp;&nbsp; 36, 145<br>
-Anti-magnetic Shield&nbsp; 37<br>
-Antilogous Pole,&nbsp;&nbsp; 425<br>
-Antimony&nbsp; 37<br>
-Anvil&nbsp; 37<br>
-A. O. C.&nbsp; 38<br>
-Aperiodic&nbsp; 38<br>
-Aperiodic Galvanometer&nbsp; 266<br>
-Apparent Coefficient of Magnetic Induction&nbsp; 346<br>
-Apparent Resistance&nbsp; 297, 462<br>
-Apparent Watts&nbsp; 573<br>
-Arago's Disc&nbsp; 88<br>
-Arc&nbsp; 39<br>
-Arc, Ampere&nbsp;&nbsp; 30<br>
-Arc, Compound.&nbsp;&nbsp; 39<br>
-Arc, Electric Blow-pipe&nbsp;&nbsp; 84<br>
-Arc, Metallic&nbsp; 39<br>
-Arc, Micrometer&nbsp;&nbsp; 39, 376<br>
-Arc, Multiple&nbsp;&nbsp; 387<br>
-Arc, Simple&nbsp; 39<br>
-Arc, Voltaic&nbsp;&nbsp; 39<br>
-Arc Box, Multiple&nbsp;&nbsp; 387<br>
-Arc Lamp&nbsp; 319<br>
-Arc Lamp, Differential&nbsp;&nbsp; 320<br>
-Arc Lamp, Double Carbon&nbsp;&nbsp; 191<br>
-Areometer&nbsp; 41<br>
-Areometer, Bead&nbsp;&nbsp; 41<br>
-Argyrometry&nbsp; 41<br>
-Arm&nbsp;&nbsp; 41<br>
-Armature&nbsp; 41<br>
-Armature, Bar&nbsp;&nbsp; 42<br>
-Armature, Bipolar&nbsp;&nbsp; 42<br>
-Armature Bore&nbsp; 42<br>
-Armature Chamber&nbsp; 42<br>
-Armature, Closed Coil&nbsp;&nbsp; 43<br>
-Armature Coil, or Coils&nbsp;&nbsp; 43<br>
-Armature Conductors, Lamination of&nbsp;&nbsp; 319<br>
-Armature Core&nbsp; 43<br>
-Armature, Cylinder&nbsp;&nbsp; 43<br>
-Armature, Cylindrical&nbsp;&nbsp; 45<br>
-Armature, Disc&nbsp;&nbsp; 43<br>
-Armature, Drum&nbsp; 45<br>
-Armature Factor&nbsp; 45<br>
-Armature, Flat Ring&nbsp;&nbsp; 45<br>
-Armature, Girder&nbsp;&nbsp; 49<br>
-Armature, H&nbsp; 49<br>
-Armature, Hinged&nbsp;&nbsp; 45<br>
-Armature, Hole&nbsp; 45<br>
-Armature, Intensity&nbsp;&nbsp; 45<br>
-Armature Interference&nbsp; 45<br>
-Armature, Load of&nbsp;&nbsp; 46<br>
-Armature, Multipolar&nbsp;&nbsp; 46<br>
-Armature, Neutral&nbsp;&nbsp; 46<br>
-Armature, Neutral Relay&nbsp; 46, 390<br>
-Armature, Non-polarized&nbsp;&nbsp; 46<br>
-Armature of Influence Machine&nbsp; 46<br>
-Armature of Leyden Jar or Static Condenser&nbsp; 46<br>
-Armature, Open Coil&nbsp;&nbsp; 46<br>
-Armature, Perforated&nbsp;&nbsp; 45<br>
-Armature, Pivoted&nbsp;&nbsp; 47<br>
-Armature Pockets&nbsp; 47<br>
-Armature, Polarized&nbsp;&nbsp; 47<br>
-Armature, Pole&nbsp;&nbsp; 47<br>
-Armature, Quantity&nbsp;&nbsp; 47<br>
-Armature, Radial&nbsp;&nbsp; 47<br>
-Armature Reactions&nbsp; 41<br>
-Armature, Revolving, Page's&nbsp;&nbsp; 47<br>
-Armature, Ring&nbsp;&nbsp; 48<br>
-Armature, Rolling&nbsp; 49<br>
-Armatures, Gyrostatic Action of&nbsp;&nbsp; 288<br>
-Armature, Shuttle&nbsp; 49<br>
-Armature, Siemens' Old&nbsp; 49<br>
-Armature, Spherical&nbsp; 49<br>
-Armature, Stranded Conductor&nbsp;&nbsp; 49<br>
-Armature, Unipolar&nbsp; 50, 553<br>
-Armature, Ventilation of&nbsp;&nbsp; 560<br>
-Armor of Cable&nbsp; 50<br>
-Arm, Rheostat&nbsp;&nbsp; 472<br>
-Arms, Proportionate&nbsp;&nbsp; 436<br>
-Arms, Ratio&nbsp; 437<br>
-Arms, Rocker&nbsp; 50-474<br>
-Arrester, Lightning&nbsp;&nbsp; 328<br>
-Arrester, Lightning, Counter-electro-motive Force&nbsp;&nbsp; 329<br>
-Arrester, Lightning, Plates&nbsp;&nbsp; 329<br>
-Arrester, Lightning, Vacuum.&nbsp;&nbsp; 329<br>
-Arrester Plate&nbsp; 417<br>
-Arrester, Spark&nbsp;&nbsp; 489<br>
-Arrival Curve&nbsp; 168<br>
-Articulate Speech&nbsp; 50<br>
-Artificial Carbon&nbsp; 106<br>
-Artificial Magnet&nbsp; 335<br>
-Ascending Lightning&nbsp; 330<br>
-Assymmetrical Resistance&nbsp; 462<br>
-Astatic&nbsp; 50<br>
-Astatic Circuit&nbsp; 12<br>
-Astatic Couple&nbsp; 157<br>
-Astatic Galvanometer&nbsp; 266<br>
-Astatic Needle&nbsp; 50<br>
-Astronomical Meridian,&nbsp;&nbsp; 372<br>
-Asymptote&nbsp; 51<br>
-Atmosphere&nbsp; 51<br>
-Atmosphere, Residual&nbsp; 51, 460<br>
-Atmospheric Electricity&nbsp; 51<br>
-Atom&nbsp; 52<br>
-Atomic Attraction&nbsp;&nbsp; 52<br>
-Atomic Current&nbsp; 160<br>
-Atomic Energy&nbsp; 238<br>
-Atomic Heat&nbsp; 52-285<br>
-Atomic Weight&nbsp; 53<br>
-Atomicity&nbsp;&nbsp; 52<br>
-Attracted Disc Electrometer&nbsp; 223<br>
-Attraction&nbsp; 53<br>
-Attraction, Atomic&nbsp; 52<br>
-Attraction, Magnetic&nbsp;&nbsp; 338<br>
-Attraction, Molar&nbsp;&nbsp; 380<br>
-Attraction, Molecular&nbsp; 380<br>
-Attraction and Repulsion, Electro-dynamic&nbsp; 211<br>
-Attraction and Repulsion, Electro-magnetic&nbsp; 217<br>
-Attraction and Repulsion, Electro-static&nbsp;&nbsp; 234<br>
-Attraction and Repulsion, Electro-static, Coulomb's Law of&nbsp;&nbsp;
-155<br>
-Audiometer&nbsp; 53<br>
-Aura, Electrical&nbsp;&nbsp; 53<br>
-Aurora&nbsp; 53<br>
-Austral Pole&nbsp; 54<br>
-Autographic Telegraph&nbsp; 510<br>
-Automatic Circuit Breaker&nbsp; 121<br>
-Automatic Cut Out&nbsp; 175, 475<br>
-Automatic Drop&nbsp; 192<br>
-Automatic Electric Bell&nbsp; 78<br>
-Automatic Electric Fire Alarm&nbsp; 257<br>
-Automatic Switch&nbsp;&nbsp; 500<br>
-Automatic Telegraph&nbsp; 504<br>
-A. W. G.,&nbsp;&nbsp;&nbsp; 54<br>
-Axial Couple&nbsp; 514<br>
-Axial Force&nbsp; 544<br>
-Axial Magnet&nbsp; 336<br>
-Axis, Electric&nbsp;&nbsp; 54<br>
-Axis, Magnetic&nbsp;&nbsp; 338<br>
-Axis of Abscissas&nbsp;&nbsp; 54<br>
-Axis of Ordinates&nbsp; 54, 397<br>
-Axis of X&nbsp; 54<br>
-Axis of Y&nbsp; 54, 397<br>
-Ayrton's Ammeter&nbsp; 26<br>
-Azimuth&nbsp;&nbsp;&nbsp; 54<br>
-Azimuth Circle&nbsp; 54<br>
-Azimuth Compass&nbsp; 141<br>
-Azimuth, Magnetic&nbsp;&nbsp; 338<br>
-<br>
-B&nbsp;&nbsp; 55<br>
-B. A.&nbsp;&nbsp; 55<br>
-Back Electro-motive Force of Polarization&nbsp; 156<br>
-Back Induction&nbsp; 55<br>
-Back Shock or Stroke of Lightning&nbsp; 55<br>
-Back Stroke&nbsp; 55<br>
-Bagration Battery&nbsp; 59<br>
-Balance&nbsp; 55<br>
-Balance, Ampere&nbsp; 56<br>
-Balance Ampere Meter&nbsp; 391<br>
-Balance, Electric&nbsp; 577<br>
-Balance, Inductance&nbsp;&nbsp; 293<br>
-Balance, Plating&nbsp; 417<br>
-Balance, Slide&nbsp; 374<br>
-Balance, Thermic&nbsp;&nbsp; 85<br>
-Balance, Torsion, Coulomb's&nbsp;&nbsp; 544<br>
-Balance, Wheatstone's&nbsp; 577<br>
-Balata&nbsp; 56<br>
-Ballistic Galvanometer&nbsp; 567<br>
-Balloon Battery&nbsp; 59<br>
-B. and S. W. G.&nbsp;&nbsp; 56<br>
-Banked Battery&nbsp; 59<br>
-Bank of Lamps&nbsp; 323<br>
-B. A. Ohm&nbsp; 394<br>
-Barad&nbsp; 56<br>
-Bar, Armature&nbsp;&nbsp; 42<br>
-Bar, Bus&nbsp; 94<br>
-Bar Electro-magnet&nbsp; 217<br>
-Bar Magnet&nbsp; 336<br>
-Barometer&nbsp; 56<br>
-Bar, Omnibus&nbsp;&nbsp; 94<br>
-Bar Photometer&nbsp; 411<br>
-Bars, Commutator&nbsp;&nbsp; 56, 140<br>
-Bath&nbsp; 57<br>
-Bath, Bipolar Electric&nbsp;&nbsp; 57<br>
-Bath, Copper&nbsp; 152<br>
-Bath, Copper Stripping&nbsp;&nbsp; 152<br>
-Bath, Electric Head&nbsp;&nbsp; 284<br>
-Bath, Electric Shower&nbsp;&nbsp; 57<br>
-Bath, Gold&nbsp; 279<br>
-Bath, Gold Stripping&nbsp; 279<br>
-Bath, Multipolar Electric&nbsp;&nbsp; 57<br>
-Bath, Nickel&nbsp; 391<br>
-Bath, Plating&nbsp; 418<br>
-Baths, Electro-medical&nbsp;&nbsp; 222<br>
-Bath, Silver&nbsp; 484<br>
-Bath, Silver Stripping&nbsp;&nbsp; 484<br>
-Bath, Stripping&nbsp; 57<br>
-Bath, Unipolar Electric&nbsp;&nbsp; 57<br>
-Batten&nbsp; 57-58<br>
-Battery, Acetic Acid&nbsp;&nbsp; 58<br>
-Battery, Alum&nbsp; 58<br>
-Battery, Aluminum&nbsp; 58<br>
-Battery, Bagration&nbsp; 59<br>
-Battery, Balloon&nbsp;&nbsp; 59<br>
-Battery, Banked&nbsp; 59<br>
-Battery, Bichromate&nbsp;&nbsp; 59<br>
-Battery, Bunsen&nbsp;&nbsp; 59<br>
-Battery, Cadmium&nbsp;&nbsp; 60<br>
-Battery, Callan&nbsp; 60<br>
-Battery, Camacho's&nbsp;&nbsp; 60<br>
-Battery, Carr&eacute;'s&nbsp;&nbsp; 60<br>
-Battery, Cautery&nbsp;&nbsp; 61<br>
-Battery Cell, Element of a&nbsp;&nbsp; 237<br>
-Battery, Chloric Acid&nbsp; 61<br>
-Battery, Chloride of Lime&nbsp;&nbsp; 61<br>
-Battery, Chromic Acid&nbsp;&nbsp; 61<br>
-Battery, Closed Circuit&nbsp;&nbsp; 61<br>
-Battery, Column&nbsp;&nbsp; 61<br>
-Battery, d'Arsonval's&nbsp;&nbsp; 62<br>
-Battery, de la Rue&nbsp; .62<br>
-Battery, de la Rive's Floating&nbsp;&nbsp; 179<br>
-Battery, Dry&nbsp; 63<br>
-Battery, Elements of&nbsp;&nbsp; 63<br>
-Battery, Faradic&nbsp; 63<br>
-Battery, Ferric Chloride&nbsp;&nbsp; 63<br>
-Battery, Fuller's&nbsp; 63<br>
-Battery, Gas&nbsp; 63<br>
-Battery, Gas, Grove's&nbsp;&nbsp; 281<br>
-Battery Gauge&nbsp; 64<br>
-Battery, Gravity&nbsp;&nbsp; 64<br>
-Battery, Grenet&nbsp;&nbsp; 65<br>
-Battery, Grove's&nbsp; 65<br>
-Battery, Hydrochloric Acid&nbsp;&nbsp; 66<br>
-Battery, Lalande &amp; Chaperon&nbsp;&nbsp; 69<br>
-Battery, Lalande-Edison&nbsp;&nbsp; 69<br>
-Battery, Lead Chloride&nbsp;&nbsp; 66<br>
-Battery, Lead Sulphate&nbsp; 66<br>
-Battery, Leclanch&eacute;&nbsp;&nbsp; 66<br>
-Battery, Leclanch&eacute; Agglomerate&nbsp; 66<br>
-Battery, Local&nbsp;&nbsp; 66, 831<br>
-Battery, Magnetic&nbsp;&nbsp; 338<br>
-Battery, Main&nbsp; 66<br>
-Battery, Mari&eacute; Davy's&nbsp;&nbsp; 67<br>
-Battery, Maynooth's&nbsp;&nbsp; 67<br>
-Battery, Medical&nbsp; 67<br>
-Battery, Meidinger's&nbsp; 68<br>
-Battery, Mercury Bichromate&nbsp;&nbsp; 63<br>
-Battery Mud&nbsp; 68<br>
-Battery, Multiple Connected&nbsp;&nbsp; 68<br>
-Battery, Niaudet's&nbsp; 61<br>
-Battery, Nitric Acid&nbsp;&nbsp; 68<br>
-Battery of Dynamos&nbsp; 6S<br>
-Battery of Leyden Jars,&nbsp;&nbsp; 68<br>
-Battery, Open Circuit&nbsp; 68<br>
-Battery or Pile, Thermo-electric&nbsp;&nbsp; 530<br>
-Battery, Oxide of Copper&nbsp;&nbsp; 68<br>
-Battery, Peroxide of Lead&nbsp;&nbsp; 69<br>
-Battery, Platinized Carbon&nbsp;&nbsp; 69<br>
-Battery, Plunge&nbsp;&nbsp; 69<br>
-Battery, Pneumatic&nbsp;&nbsp; 69<br>
-Battery, Primary&nbsp;&nbsp; 69, 434<br>
-Battery, Pulvermacher's Electro-medical&nbsp;&nbsp; 69<br>
-Battery, Sal Ammoniac&nbsp;&nbsp; 69<br>
-Battery, Salt, or Sea Salt&nbsp; 69<br>
-Battery, Sand&nbsp; 70<br>
-Battery, Secondary&nbsp; 70<br>
-Battery, Secondary, Plant&eacute;'s&nbsp;&nbsp; 72<br>
-Battery, Secondary, Real Efficiency of&nbsp;&nbsp; 205<br>
-Battery, Sir William Thomson's&nbsp;&nbsp; 72<br>
-Battery, Siemens and Halske's&nbsp; 72<br>
-Battery, Skrivanow&nbsp;&nbsp; 72<br>
-Battery, Smee's&nbsp;&nbsp; 73<br>
-Battery Solutions, Chromic Acid&nbsp;&nbsp; 73<br>
-&nbsp; 119, 178, 192, 232, 318, 421, 542, 549<br>
-Battery, Spiral&nbsp; 73<br>
-Battery, Split&nbsp;&nbsp; 73<br>
-Battery, Sulphate of Mercury&nbsp;&nbsp; 67<br>
-Battery System, Universal&nbsp; 556<br>
-Battery, Thermo-chemical&nbsp;&nbsp; 530<br>
-Battery, Trough&nbsp; 73<br>
-Battery, Trouv&eacute;'s Blotting Paper&nbsp;&nbsp; 73<br>
-Battery, Tyer's&nbsp; 74<br>
-Battery, Upward's&nbsp; 75<br>
-Battery, Varley's&nbsp; 76<br>
-Battery, Volta's&nbsp;&nbsp; 76<br>
-Battery, Voltaic or Galvanic&nbsp;&nbsp; 76<br>
-Battery Voltmeter&nbsp; 569<br>
-Battery, Water&nbsp; 77<br>
-Battery, Wollaston&nbsp; 78<br>
-B. A. Unit,&nbsp; 554<br>
-B. A. Unit of Resistance&nbsp; 78, 462<br>
-B. A. Volt&nbsp; 568<br>
-B. E.&nbsp;&nbsp; 78<br>
-Bead Areometer&nbsp; 41<br>
-Becquerel's Laws of Thermo-electricity&nbsp;&nbsp; 78<br>
-Beaum&eacute; Hydrometer&nbsp; 78<br>
-Bed-piece&nbsp; 78<br>
-Bell, Automatic Electric&nbsp;&nbsp;&nbsp; 78<br>
-Bell, Call&nbsp;&nbsp; 78, 98<br>
-Bell Call&nbsp; 79<br>
-Bell Call, Extension&nbsp;&nbsp; 248<br>
-Bell, Circular&nbsp; 79<br>
-Bell, Differentially Wound&nbsp;&nbsp; 79<br>
-Bell, Electric&nbsp; 79<br>
-Bell, Electro-mechanical&nbsp;&nbsp;&nbsp; 80<br>
-Bell, Indicating&nbsp;&nbsp; 80, 297<br>
-Bell, Magneto&nbsp; 80<br>
-Bell, Magneto Call&nbsp;&nbsp; 361<br>
-Bell, Night&nbsp; 392<br>
-Bell-shaped Magnet,&nbsp;&nbsp; 336<br>
-Bells, Relay&nbsp; 80, 457<br>
-Bell, Trembling&nbsp;&nbsp; 78<br>
-Bell, Vibrating.&nbsp;&nbsp;&nbsp; 78<br>
-Belts, Joints in&nbsp; 311<br>
-Bennett's Electroscope&nbsp; 233<br>
-Bias&nbsp; 80<br>
-Bias of Tongue of Polarized Relay&nbsp; 542<br>
-Bichromate Battery&nbsp; 59<br>
-Bichromate Mercury Battery&nbsp; 63<br>
-Bifilar Suspension&nbsp; 498<br>
-Bifilar Winding&nbsp; 81<br>
-Binary Compound&nbsp; 81<br>
-Binding&nbsp;&nbsp; 81<br>
-Binding Posts or Screws&nbsp; 81<br>
-Binnacle&nbsp; 81<br>
-Biology, Electro-&nbsp; 208<br>
-Bioscopy, Electric&nbsp;&nbsp; 82<br>
-Bipolar Armature&nbsp; 42<br>
-Bipolar Electric Bath&nbsp; 57<br>
-Bisected Coils&nbsp; 132<br>
-Bismuth&nbsp; 82<br>
-Bi-telephone&nbsp; 82, 524<br>
-Black, Platinum&nbsp;&nbsp; 419<br>
-Blasting, Electric&nbsp; 83<br>
-Bleaching, Electric&nbsp;&nbsp; 83<br>
-Block, Branch&nbsp;&nbsp; 87<br>
-Block, Cross-over&nbsp;&nbsp; 158<br>
-Block System&nbsp; 83<br>
-Block Wire&nbsp; 83<br>
-Blotting Paper Battery, Trouv&eacute;'s&nbsp;&nbsp; 73<br>
-Blow-pipe&nbsp; 83<br>
-Blow-pipe, Electric Arc&nbsp;&nbsp; 84<br>
-Blue Magnetism&nbsp; 355<br>
-Bluestone&nbsp; 84<br>
-Blue Vitriol&nbsp;&nbsp; 562<br>
-Board, Cross-connecting&nbsp;&nbsp; 157<br>
-Board, Fuse&nbsp;&nbsp; 263<br>
-Board, Hanger&nbsp;&nbsp; 284<br>
-Board, Key&nbsp;&nbsp; 313<br>
-Board, Multiple Switch&nbsp;&nbsp; 387<br>
-Board of Trade Ohm&nbsp; 394<br>
-Board of Trade Unit&nbsp; 555<br>
-Board, Switch&nbsp; 500<br>
-Boat, Electric&nbsp;&nbsp; 84<br>
-Bobbins&nbsp; 84<br>
-Body Protector&nbsp; 84<br>
-Bohenberger's Electroscope&nbsp; 233<br>
-Boiler Feed, Electric&nbsp; 84<br>
-Boiling&nbsp;&nbsp; 84<br>
-Boll&nbsp; 85<br>
-Bolometer&nbsp;&nbsp; 85<br>
-Bombardment, Molecular&nbsp;&nbsp; 380<br>
-Bore, Armature&nbsp;&nbsp; 42<br>
-Boreal Pole&nbsp; 85<br>
-Bot&nbsp; 85<br>
-Bound Charge&nbsp; 115<br>
-Box Bridge&nbsp; 85<br>
-Box, Cable&nbsp; 95<br>
-Box, Cooling&nbsp; 151<br>
-Box, Distributing&nbsp;&nbsp; 190<br>
-Boxes, Flush&nbsp; 258<br>
-Box, Fishing&nbsp; 311<br>
-Box, Fuse&nbsp; 263<br>
-Boxing the Compass&nbsp; 86<br>
-Box, Junction&nbsp; 311<br>
-Box, Multiple Arc&nbsp;&nbsp; 387<br>
-Box, Resistance&nbsp; 462<br>
-Box, Resistance, Sliding&nbsp;&nbsp; 463<br>
-Box Sounding Relay&nbsp; 457<br>
-Box, Splice&nbsp;&nbsp; 492<br>
-Bracket, Saddle&nbsp;&nbsp; 475<br>
-Bracket, Wall&nbsp;&nbsp; 572<br>
-Braid, Tubular&nbsp; 550<br>
-Brake, Electro-magnetic&nbsp;&nbsp; 86<br>
-Brake, Magneto-electric&nbsp;&nbsp; 362<br>
-Brake, Prony&nbsp; 435<br>
-Branch&nbsp;&nbsp; 87<br>
-Branch Block&nbsp; 87<br>
-Branch Circuit&nbsp; 121<br>
-Branch Conductor&nbsp; 87<br>
-Branding, Electric&nbsp;&nbsp; 87<br>
-Brassing&nbsp; 87<br>
-Brazing, Electric&nbsp;&nbsp; 87<br>
-Break&nbsp; 88<br>
-Break, Circuit Loop&nbsp;&nbsp; 125<br>
-Break-down Switch&nbsp; 88<br>
-Breaker, Automatic Circuit&nbsp;&nbsp; 121<br>
-Breaker, Circuit&nbsp; 121<br>
-Breaker, Circuit, File&nbsp;&nbsp; 121<br>
-Breaker, Contact&nbsp; 121, 146<br>
-Break Induced Current&nbsp; 162<br>
-Breaking Weight&nbsp; 89<br>
-Break, Loop&nbsp;&nbsp;&nbsp; 332<br>
-Break Shock&nbsp; 482<br>
-Breath Figures, Electric&nbsp;&nbsp; 89<br>
-Breeze, Electric&nbsp;&nbsp; 89<br>
-Breeze, Static&nbsp; 493<br>
-Breguet Unit of Resistance&nbsp; 463<br>
-Bridge&nbsp;&nbsp; 89<br>
-Bridge, Box&nbsp; 89<br>
-Bridge, Inductance&nbsp;&nbsp; 293<br>
-Bridge, Induction&nbsp;&nbsp; 293<br>
-Bridge Key&nbsp;&nbsp; 313<br>
-Bridge, Magnetic&nbsp; 338<br>
-Bridge, Meter&nbsp; 373<br>
-Bridge, Resistance&nbsp;&nbsp; 577<br>
-Bridge, Reversible&nbsp;&nbsp;&nbsp; 472<br>
-Bridge, Slide&nbsp; 374<br>
-Bridge, Wheatstone .&nbsp;&nbsp; 575<br>
-Bridge, Wheatstone, Commercial&nbsp;&nbsp; 36<br>
-British Association Bridge&nbsp; 89<br>
-Britannia Joint&nbsp; 309<br>
-Broadside Method&nbsp; 89<br>
-Broken Circuit&nbsp; 125<br>
-Bronzing&nbsp; 89<br>
-Brush&nbsp; 90<br>
-Brush, Carbon&nbsp; 90<br>
-Brush, Collecting&nbsp; 90<br>
-Brush, Discharge&nbsp;&nbsp; 187<br>
-Brushes, Adjustment of&nbsp;&nbsp; 90<br>
-Brushes, Lead of&nbsp;&nbsp; 90<br>
-Brushes, Negative Lead of&nbsp;&nbsp; 324<br>
-Brushes, Scratch&nbsp;&nbsp; 476<br>
-Brush, Faradic&nbsp;&nbsp; 251<br>
-Brush Holders&nbsp; 91<br>
-Brush, Pilot&nbsp; 91<br>
-Brush, Rotating&nbsp;&nbsp;&nbsp; 91<br>
-Brush, Third&nbsp; 91<br>
-Brush Trimmer&nbsp; 549<br>
-Brush, Wire Gauge&nbsp;&nbsp; 92<br>
-Buckling&nbsp; 92<br>
-Bug&nbsp; 92<br>
-Bug Trap&nbsp; 92<br>
-Bunched Cable&nbsp; 95<br>
-Bunsen Battery&nbsp; 59<br>
-Bunsen Disc&nbsp; 92<br>
-Bunsen's Photometer&nbsp;&nbsp; 412<br>
-Buoy, Electric&nbsp; 93<br>
-Burglar Alarm&nbsp; 16<br>
-Burner, Electric Gas&nbsp;&nbsp; 93<br>
-Burning&nbsp; 94<br>
-Bus Bar&nbsp; 94<br>
-Bus Rod&nbsp; 94<br>
-Bus Wire&nbsp; 94<br>
-Butt Joint&nbsp; 310<br>
-Button, Call&nbsp;&nbsp; 98<br>
-Button, Press&nbsp;&nbsp; 94<br>
-Button, Push&nbsp;&nbsp; 93, 98<br>
-Buzzer&nbsp; 94<br>
-B. W. G.&nbsp; 94<br>
-<br>
-C&nbsp; 95<br>
-C. C.&nbsp; 109<br>
-Cable&nbsp; 95<br>
-Cable, Aerial&nbsp; 95<br>
-Cable, Armature of&nbsp;&nbsp; 50<br>
-Cable, Armor of&nbsp;&nbsp; 50<br>
-Cable Box&nbsp; 95<br>
-Cable, Bunched&nbsp; 95<br>
-Cable, Capacity of&nbsp;&nbsp; 95<br>
-Cable Clip&nbsp; 97<br>
-Cable Core&nbsp; 96<br>
-Cable, Duplex&nbsp;&nbsp; 96<br>
-Cable, Flat&nbsp;&nbsp; 96<br>
-Cablegram&nbsp; 96<br>
-Cable Grip&nbsp; 96<br>
-Cable Hanger&nbsp; 96<br>
-Cable Hanger Tongs&nbsp; 97<br>
-Cable, Suspension Wire of&nbsp;&nbsp; 97<br>
-Cable Tank&nbsp; 97<br>
-Cadmium Battery&nbsp; 60<br>
-Calamine&nbsp; 97<br>
-Cal Electricity&nbsp; 208<br>
-Calibration&nbsp; 97<br>
-Calibration, Absolute&nbsp;&nbsp; 97<br>
-Calibration, Invariable&nbsp;&nbsp; 97<br>
-Calibration, Relative&nbsp; 98<br>
-Call Bell&nbsp; 78, 79, 98<br>
-Call Bell, Extension&nbsp;&nbsp; 248<br>
-Call Bell, Magneto&nbsp;&nbsp; 361<br>
-Call Button&nbsp; 98<br>
-Call, Thermo&nbsp; 530<br>
-Call, Thermo-electric&nbsp;&nbsp; 531<br>
-Callan Battery&nbsp;&nbsp; 60<br>
-Calling Drop&nbsp; 98<br>
-Calorie or Calory&nbsp; 98<br>
-Calorimeter&nbsp; 98<br>
-Calorimetric Photometer&nbsp; 412<br>
-Calory or Calorie&nbsp; 98<br>
-Cam, Listening&nbsp;&nbsp; 330<br>
-Camacho's Battery&nbsp; 60<br>
-Candle&nbsp; 99<br>
-Candle, Concentric&nbsp;&nbsp; 99<br>
-Candle, Debrun&nbsp;&nbsp; 99<br>
-Candle, Decimal&nbsp; 99<br>
-Candle, Electric&nbsp;&nbsp; 99<br>
-Candle-foot&nbsp; 259<br>
-Candle, German Standard&nbsp;&nbsp; 99<br>
-Candle Holder&nbsp; 99<br>
-Candle, Jablochkoff&nbsp;&nbsp; 100<br>
-Candle, Jamin&nbsp;&nbsp; 100<br>
-Candle, Meter&nbsp;&nbsp;&nbsp; 374<br>
-Candle Power&nbsp; 100<br>
-Candle Power, Nominal&nbsp;&nbsp; 101<br>
-Candle Power, Rated&nbsp; 101<br>
-Candle Power, Spherical&nbsp;&nbsp; 101<br>
-Candle, Standard&nbsp;&nbsp; 101<br>
-Candle, Wilde&nbsp;&nbsp; 101<br>
-Caoutchouc&nbsp; 101<br>
-Cap, Insulator&nbsp; 306<br>
-Capacity, Carrying&nbsp;&nbsp; 108<br>
-Capacity, Dielectric&nbsp;&nbsp; 102<br>
-Capacity, Electric or Electrostatic&nbsp;&nbsp; 102<br>
-Capacity, Instantaneous&nbsp; 102<br>
-Capacity, Magnetic Inductive&nbsp;&nbsp; 346, 349<br>
-Capillarity, Electro-&nbsp; 209<br>
-Capillary Electrometer&nbsp; 224<br>
-Capacity of a Telegraph Conductor&nbsp; 103<br>
-Capacity of Cable&nbsp; 95<br>
-Capacity of Polarization of a Voltaic Cell&nbsp; 103<br>
-Capacity, Polarization&nbsp; 424<br>
-Capacity, Residual&nbsp; 103<br>
-Capacity, Specific Inductive&nbsp;&nbsp; 103<br>
-Capacity, Storage&nbsp; 105, 495<br>
-Capacity, Unit of&nbsp;&nbsp; 105<br>
-Capillarity&nbsp; 105<br>
-Capillary Telephone&nbsp; 525<br>
-Carbon&nbsp; 106<br>
-Carbon, Artificial&nbsp; 106<br>
-Carbon Brush&nbsp; 90<br>
-Carbon, Concentric&nbsp; 107<br>
-Carbon, Cored&nbsp;&nbsp; 107<br>
-Carbon Dioxide&nbsp; 107<br>
-Carbon Holders&nbsp; 107<br>
-Carbonic Acid,&nbsp;&nbsp; 108<br>
-Carbonic Acid Gas&nbsp; 108<br>
-Carbonization&nbsp; 107<br>
-Carbonized Cloth&nbsp; 107<br>
-Carbon, Platinized, Battery&nbsp;&nbsp; 69<br>
-Carbon Resistance&nbsp;&nbsp; 463<br>
-Carbon, Retort&nbsp;&nbsp;&nbsp; 471<br>
-Carbons, Lamp, Flashing of Incandescent&nbsp;&nbsp; 257<br>
-Carbon, Telephone&nbsp; 525<br>
-Carbon Transmitter&nbsp; 549<br>
-Carbon, Volatilization of&nbsp;&nbsp; 108<br>
-Carburetted Hydrogen, Heavy&nbsp;&nbsp; 397<br>
-Carcel&nbsp; 108<br>
-Carcel Gas Jet&nbsp; 108<br>
-Carcel Lamp&nbsp; 108<br>
-Card, Compass&nbsp;&nbsp; 142<br>
-Cardew Voltmeter&nbsp; 569<br>
-Carr&eacute;'s Battery&nbsp; 60<br>
-Carrying Capacity&nbsp; 108<br>
-Cascade&nbsp; 108<br>
-Cascade, Charging and Discharging Leyden Jars in&nbsp;&nbsp; 108<br>
-Cascade, Gassiot's&nbsp;&nbsp; 275<br>
-Case-hardening, Electric&nbsp;&nbsp; 109<br>
-Cataphoresis&nbsp; 109<br>
-Catch, Safety&nbsp; 175<br>
-Cathode, etc. See Kathode&nbsp;&nbsp; 312<br>
-Caustry, Galvano&nbsp; 109<br>
-Cautery Battery&nbsp;&nbsp; 61<br>
-Cautery, Electric&nbsp; 109<br>
-Cautery, Galvano&nbsp; 109<br>
-Cautery, Galvano-electric&nbsp; 109<br>
-Cautery, Galvano-thermal&nbsp;&nbsp; 109<br>
-Cell, Battery, Element of a&nbsp;&nbsp; 237<br>
-Cell, Constant&nbsp; 109<br>
-Cell, Electrolytic&nbsp;&nbsp; 109<br>
-Cell, Porous&nbsp;&nbsp;&nbsp; 427<br>
-Cell, Selenium&nbsp;&nbsp; 478<br>
-Cell, Standard Voltaic&nbsp; 109<br>
-Cell, Standard Voltaic, Daniells'&nbsp; 109<br>
-Cell, Standard Voltaic, Latimer Clark's&nbsp; 110<br>
-Central Station&nbsp; 493<br>
-Central Station Distribution or Supply&nbsp; 112<br>
-Centre of Gravity&nbsp; 112<br>
-Centre of Gyration&nbsp; 112<br>
-Centre of Oscillation&nbsp; 112<br>
-Centre of Percussion&nbsp; 112<br>
-Centrifugal Force&nbsp; 112<br>
-Centrifugal Governor&nbsp; 113<br>
-C. G. S.&nbsp; 113<br>
-Chain, Molecular&nbsp; 380<br>
-Chamber, Armature&nbsp; 42<br>
-Chamber of Incandescent Lamp&nbsp; 113<br>
-Change, Chemical&nbsp; 116<br>
-Changer, Pole&nbsp; 425<br>
-Changing Over Switch&nbsp; 500<br>
-Changing Switch&nbsp; 500<br>
-Chaperon, Lalande &amp;, Battery&nbsp;&nbsp; 69<br>
-Characteristic&nbsp; 169<br>
-Characteristic Curve&nbsp; 113, 168<br>
-Characteristic Curve, External&nbsp; 171<br>
-Characteristic Curve of Converter&nbsp; 169<br>
-Characteristic, Drooping&nbsp;&nbsp; 114<br>
-Characteristic, External&nbsp;&nbsp; 114<br>
-Characteristic, Internal&nbsp;&nbsp; 114<br>
-Characteristics of Sound&nbsp; 114<br>
-Charge&nbsp; 114<br>
-Charge and Discharge Key&nbsp;&nbsp;&nbsp; 313<br>
-Charge, Bound&nbsp;&nbsp; 115<br>
-Charge Current&nbsp; 160<br>
-Charge, Density of&nbsp;&nbsp; 115, 180<br>
-Charge, Dissipation of&nbsp;&nbsp; 115<br>
-Charge, Distribution of&nbsp;&nbsp; 115<br>
-Charge, Free&nbsp; 115<br>
-Charge, Negative&nbsp; 389<br>
-Charge, Residual&nbsp;&nbsp; 116<br>
-Charging Curve&nbsp; 170<br>
-Chatterton's Compound&nbsp; 116<br>
-Chemical Change&nbsp; 116<br>
-Chemical Electric Meter&nbsp;&nbsp; 375<br>
-Chemical, Electro-, Equivalents&nbsp;&nbsp; 244<br>
-Chemical Element&nbsp; 236<br>
-Chemical Energy&nbsp; 239<br>
-Chemical Equivalent&nbsp; 244<br>
-Chemical, Cautery Galvano&nbsp;&nbsp; 265<br>
-Chemical Recorder&nbsp; 117<br>
-Chemical Telephone&nbsp; 526<br>
-Chemical Equivalent, Thermo-&nbsp;&nbsp; 245<br>
-Chemistry&nbsp; 118<br>
-Chemistry, Electro-&nbsp;&nbsp; 209<br>
-Cheval, Force de&nbsp; 260<br>
-Chicle&nbsp; 56<br>
-Chimes, Electric&nbsp;&nbsp; 118<br>
-Chloric Acid Battery&nbsp; 61<br>
-Chloride, Ferric, Battery&nbsp;&nbsp; 63<br>
-Chloride, Lead, Battery&nbsp; 66<br>
-Chloride of Lime Battery&nbsp; 61<br>
-Chlorimeter&nbsp;&nbsp; 73<br>
-Choking Coil&nbsp; 132<br>
-Chronograph, Electric&nbsp;&nbsp; 118<br>
-Chromic Acid Battery&nbsp;&nbsp; 61<br>
-Chromic Acid Battery Solutions&nbsp; 73<br>
-Chromoscope&nbsp; 119<br>
-Chutaux's Solution&nbsp; 119<br>
-Cipher Code&nbsp; 130<br>
-Circle, Azimuth&nbsp;&nbsp; 54<br>
-Circle, Delezenne's&nbsp; 133<br>
-Circle, Galvanic or Voltaic&nbsp;&nbsp; 119<br>
-Circle, Magic&nbsp; 119<br>
-Circuit&nbsp; 120<br>
-Circuit, Astatic&nbsp;&nbsp; 120<br>
-Circuit, Branch&nbsp; 121<br>
-Circuit Breaker&nbsp; 121<br>
-Circuit Breaker, Automatic&nbsp;&nbsp; 121<br>
-Circuit Breaker, File&nbsp; 121<br>
-Circuit Breaker, Mercury&nbsp; 121<br>
-Circuit Breaker, Pendulum&nbsp; 121<br>
-Circuit Breaker, Tuning-fork&nbsp; 121<br>
-Circuit, Broken&nbsp; 125<br>
-Circuit Changing Switch&nbsp; 500<br>
-Circuit, Closed, Battery&nbsp;&nbsp; 61<br>
-Circuit, Derivative&nbsp; 123<br>
-Circuit, Derived&nbsp;&nbsp; 123<br>
-Circuit, Electrostatic&nbsp;&nbsp; 123<br>
-Circuit, Electric, Active&nbsp;&nbsp; 123<br>
-Circuit, External&nbsp;&nbsp; 123<br>
-Circuit, Grounded&nbsp;&nbsp; 123<br>
-Circuit, Incomplete&nbsp; 125<br>
-Circuit Indicator&nbsp; 298<br>
-Circuit Induction, Open&nbsp;&nbsp; 303<br>
-Circuit, Leg of&nbsp;&nbsp; 325<br>
-Circuit, Local&nbsp;&nbsp; 331<br>
-Circuit, Loop&nbsp; 125<br>
-Circuit, Loop Break&nbsp; 125<br>
-Circuit, Magnetic&nbsp; 340<br>
-Circuit, Magnetic Double&nbsp;&nbsp; 340<br>
-Circuit, Main&nbsp; 125<br>
-Circuit, Main Battery&nbsp;&nbsp; 125<br>
-Circuit, Metallic&nbsp; 125<br>
-Circuit, Negative Side of&nbsp;&nbsp; 125<br>
-Circuit, Open&nbsp; 125<br>
-Circuit, Positive Side of&nbsp;&nbsp; 125<br>
-Circuit, Recoil&nbsp;&nbsp; 125<br>
-Circuit, Return&nbsp; 125<br>
-Circuits, Forked&nbsp;&nbsp; 126<br>
-Circuit, Short&nbsp;&nbsp; 482<br>
-Circuit, Shunt&nbsp;&nbsp; 123, 126<br>
-Circuit, Simple&nbsp; 126<br>
-Circuits, Parallel&nbsp;&nbsp; 123, 126<br>
-Circuit, Voltaic&nbsp; 126<br>
-Circuit Working, Short&nbsp;&nbsp; 482<br>
-Circular Bell,&nbsp; 79<br>
-Circular Current,&nbsp;&nbsp; 160<br>
-Circular, Mil&nbsp;&nbsp; 379<br>
-Circular Units&nbsp; 126, 555<br>
-Circumflux&nbsp; 126<br>
-Clamp&nbsp; 126<br>
-Clark's Compound&nbsp; 126<br>
-Cleansing, Fire&nbsp;&nbsp; 257<br>
-Clearance Space,&nbsp;&nbsp; 489<br>
-Cleat, Crossing&nbsp;&nbsp; 127<br>
-Cleats&nbsp; 127<br>
-Cleavage, Electrification by&nbsp;&nbsp; 127<br>
-Clip, Cable&nbsp; 97<br>
-Clock, Annunciator&nbsp;&nbsp; 35<br>
-Clock, Controlled&nbsp;&nbsp; 127<br>
-Clock, Controlling&nbsp;&nbsp; 127<br>
-Clock, Electric Annunciator&nbsp;&nbsp; 127<br>
-Clock, Electrolytic&nbsp;&nbsp; 128<br>
-Clock, Master&nbsp; 127<br>
-Clock, Secondary&nbsp; 127<br>
-Clock, Self-winding, Electric&nbsp; 128<br>
-Clockwork Feed&nbsp; 128<br>
-Cloisons&nbsp; 128<br>
-Closed Circuit Battery&nbsp; 61<br>
-Closed Coil Armature&nbsp; 43<br>
-Closure&nbsp; 128<br>
-Closure Contraction, Kathodic&nbsp;&nbsp; 312<br>
-Cloth, Carbonized&nbsp; 107<br>
-Club-foot Electro-magnet&nbsp; 217<br>
-Clutch&nbsp; 128<br>
-Clutch, Electro-magnetic&nbsp; 128<br>
-Coatings of a Condenser, or Prime Conductor&nbsp; 129<br>
-Cockburn Fuse&nbsp;&nbsp; 263<br>
-Code, Cipher&nbsp; 130<br>
-Code, S. N.&nbsp;&nbsp; 486<br>
-Code, Telegraphic&nbsp;&nbsp; 130, 511<br>
-Coefficient&nbsp; 130<br>
-Coefficient, Apparent, of Magnetic Induction&nbsp;&nbsp; 346<br>
-Coefficient, Economic&nbsp;&nbsp; 130, 204, 205<br>
-Coefficient of Electrical Energy&nbsp; 205<br>
-Coefficient of Expansion&nbsp; 247<br>
-Coefficient of Induced Magnetization&nbsp; 359, 354<br>
-Coefficient of Magnetic Induction&nbsp; 346, 349<br>
-Coefficient of Mutual Induction&nbsp; 301<br>
-Coefficient of Self-induction&nbsp; 298<br>
-Coercitive Force&nbsp; 471<br>
-Coercive Force&nbsp;&nbsp; 471<br>
-Coercive or Coercitive Force&nbsp; 131<br>
-Coil and Plunger&nbsp; 131<br>
-Coil and Coil Plunger&nbsp; 131<br>
-Coil and Plunger, Differential&nbsp;&nbsp;&nbsp; 132<br>
-Coil, Armature&nbsp;&nbsp; 43<br>
-Coil, Choking&nbsp;&nbsp; 132<br>
-Coil, Earth&nbsp;&nbsp; 133<br>
-Coil, Electric&nbsp;&nbsp;&nbsp; 133<br>
-Coil, Exploring&nbsp;&nbsp; 350<br>
-Coil, Flat&nbsp;&nbsp; 133<br>
-Coil, Induction&nbsp;&nbsp; 133<br>
-Coil, Induction, Inverted&nbsp;&nbsp;&nbsp; 136<br>
-Coil, Induction, Telephone&nbsp;&nbsp; 137<br>
-Coil. Kicking&nbsp; 132<br>
-Coil, Magnet&nbsp; 336<br>
-Coil, Magnetizing&nbsp;&nbsp; 137<br>
-Coil, Reaction&nbsp;&nbsp; 132<br>
-Coil, Resistance&nbsp;&nbsp;&nbsp; 137<br>
-Coil, Resistance, Standard&nbsp;&nbsp; 464<br>
-Coil, Rhumkorff&nbsp;&nbsp; 138<br>
-Coil, Ribbon&nbsp;&nbsp; 138<br>
-Coils, Bisected&nbsp; 132<br>
-Coils, Compensating&nbsp;&nbsp; 138<br>
-Coils, Sectioned&nbsp;&nbsp; 138<br>
-Coils, Henry's&nbsp;&nbsp; 138<br>
-Coils, Idle&nbsp; 295<br>
-Coil, Single, Dynamo&nbsp;&nbsp; 202<br>
-Coil, Spark&nbsp;&nbsp; 489<br>
-Coil, Sucking&nbsp; 132<br>
-Collecting Brush&nbsp; 90<br>
-Collecting Ring&nbsp; 139<br>
-Collector&nbsp; 139<br>
-Colombin,&nbsp; 139<br>
-Colophony&nbsp; 460<br>
-Colors of Secondary Plates&nbsp; 478<br>
-Column Battery&nbsp; 61<br>
-Column, Electric&nbsp;&nbsp;&nbsp; 139<br>
-Comb&nbsp; 140<br>
-Combined Resistance&nbsp; 464<br>
-Comb Protector&nbsp; 437<br>
-Commercial Efficiency&nbsp;&nbsp; 204<br>
-Commercial Efficiency of Dynamo&nbsp; 195<br>
-Commercial Wheatstone Bridge&nbsp; 86<br>
-Common Reservoir&nbsp; 460<br>
-Communicator&nbsp; 140<br>
-Commutation, Diameter of&nbsp;&nbsp; 182<br>
-Commutator&nbsp; 140<br>
-Commutator Ammeter&nbsp; 26<br>
-Commutator Bars&nbsp; 140, 56<br>
-Commutator, Flats in&nbsp;&nbsp; 140<br>
-Commutator, High Bars of&nbsp;&nbsp; 289<br>
-Commutator, Neutral Line of&nbsp;&nbsp; 390<br>
-Commutator, Neutral Point of&nbsp;&nbsp; 390<br>
-Commutator of Current Generators and Motors&nbsp; 140<br>
-Commutators, Bars of&nbsp;&nbsp; 56<br>
-Commutator Segments&nbsp; 56<br>
-Commutator, Split Ring&nbsp;&nbsp; 141<br>
-Commuted Current&nbsp; 160<br>
-Commuter&nbsp; 140<br>
-Commuting Transformer&nbsp; 547<br>
-Compass&nbsp; 141<br>
-Compass, Azimuth&nbsp; 141<br>
-Compass, Boxing the&nbsp;&nbsp; 86<br>
-Compass Card,&nbsp; 142<br>
-Compass, Declination&nbsp;&nbsp; 142<br>
-Compass, Inclination&nbsp;&nbsp; 142<br>
-Compass, Mariners'&nbsp; 142<br>
-Compass, Points of the&nbsp;&nbsp; 143<br>
-Compass, Spirit&nbsp; 143<br>
-Compass, Surveyors&nbsp;&nbsp; 143<br>
-Compass, Variation of the&nbsp;&nbsp; 32, 558<br>
-Compensating Coils&nbsp; 138<br>
-Compensating Magnet&nbsp; 336<br>
-Compensating Poles&nbsp; 426<br>
-Compensating Resistance&nbsp; 144<br>
-Complementary Distribution&nbsp; 144<br>
-Complete Alternation&nbsp; 23<br>
-Component&nbsp; 144<br>
-Components of Earth's Magnetism&nbsp; 356<br>
-Composition of Forces&nbsp; 260<br>
-Compound Arc&nbsp; 39<br>
-Compound, Binary&nbsp; 81<br>
-Compound, Chatterton's&nbsp;&nbsp; 116<br>
-Compound, Clark's&nbsp;&nbsp; 126<br>
-Compound Dynamo&nbsp; 195<br>
-Compounding, Over-&nbsp;&nbsp; 399<br>
-Compound Magnet&nbsp; 336<br>
-Compound or Compound Wound Motor&nbsp; 382<br>
-Compound Winding&nbsp;&nbsp; 578<br>
-Concentration of Ores, Magnetic&nbsp;&nbsp; 340<br>
-Concentrator, Magnetic&nbsp;&nbsp;&nbsp; 340<br>
-Concentric Candle&nbsp; 99<br>
-Concentric Carbon&nbsp; 107<br>
-Condenser&nbsp; 144<br>
-Condenser, Coatings of a, or Prime Conductor&nbsp;&nbsp; 129<br>
-Condenser, Epinus'&nbsp;&nbsp; 242<br>
-Condenser, Plate&nbsp; 417<br>
-Condenser, Sliding&nbsp; 144<br>
-Condenser, Varley's&nbsp;&nbsp; 559<br>
-Condensing Electroscope&nbsp; 233<br>
-Conductance&nbsp; 144<br>
-Conductance, Magnetic&nbsp; 340<br>
-Conduction&nbsp; 144<br>
-Conduction, Electrolytic&nbsp;&nbsp;&nbsp; 215<br>
-Conductive Discharge&nbsp; 187<br>
-Conductivity&nbsp; 144<br>
-Conductivity, Magnetic&nbsp;&nbsp; 340<br>
-Conductivity, Specific&nbsp; 145<br>
-Conductivity, Unit of&nbsp;&nbsp; 145<br>
-Conductivity, Variable&nbsp;&nbsp; 145<br>
-Conductor&nbsp; 145<br>
-Conductor, Anti-induction&nbsp;&nbsp; 145<br>
-Conductor, Branch&nbsp; 87<br>
-Conductor, Capacity of a Telegraph&nbsp; 103<br>
-Conductor, Conical&nbsp; 145<br>
-Conductor, Imbricated&nbsp;&nbsp; 146<br>
-Conductor, Interpolar&nbsp; 307<br>
-Conductor, Leakage&nbsp;&nbsp; 325<br>
-Conductor, Prime&nbsp; 146, 434<br>
-Conductors, Equivalent&nbsp; 146<br>
-Conductors, Lamination of Armature&nbsp; 319<br>
-Conductors, Service&nbsp; 481<br>
-Conductor, Underground&nbsp;&nbsp; 552<br>
-Congress Ohm&nbsp; 395<br>
-Congress Volt&nbsp;&nbsp; 568<br>
-Conical Conductor&nbsp; 145<br>
-Conjugate&nbsp; 146<br>
-Connect&nbsp; 146<br>
-Connection, Cross&nbsp;&nbsp; 158<br>
-Connection, Relay&nbsp;&nbsp; 457<br>
-Connector&nbsp;&nbsp; 146<br>
-Consequent Points&nbsp; 422<br>
-Consequent Poles&nbsp; 146, 478<br>
-Conservation of Electricity&nbsp; 146<br>
-Conservation of Energy&nbsp; 239<br>
-Constant Current&nbsp; 160<br>
-Constant Current Alternator&nbsp; 24<br>
-Constant Current Regulation&nbsp; 454<br>
-Constant, Dielectric&nbsp; 183<br>
-Constant, Galvanometer&nbsp;&nbsp; 268<br>
-Constant Potential&nbsp; 429<br>
-Constant Potential Regulation&nbsp; 455<br>
-Constant, Time&nbsp;&nbsp;&nbsp; 54l<br>
-Contact Breaker&nbsp; 121, 146<br>
-Contact, Electric&nbsp;&nbsp; 147<br>
-Contact Electricity&nbsp; 147<br>
-Contact Faults&nbsp; 147<br>
-Contact Key, Double&nbsp;&nbsp; 314<br>
-Contact Key, Sliding&nbsp;&nbsp;&nbsp; 316<br>
-Contact Lamp&nbsp; 320<br>
-Contact, Line of&nbsp;&nbsp; 330<br>
-Contact Point&nbsp; 147<br>
-Contact Potential Difference&nbsp; 147<br>
-Contact Ring&nbsp; 473<br>
-Contact Spring&nbsp; 148<br>
-Contact Series&nbsp; 147<br>
-Contact Theory&nbsp; 148<br>
-Continuity, Magnetic&nbsp;&nbsp; 340<br>
-Continuous Alternating Transformer&nbsp; 547<br>
-Continuous Current&nbsp; 161<br>
-Continuous Current Transformer&nbsp; 384, 547<br>
-Contraction, Anodic Closure&nbsp; 36<br>
-Contraction, Anodic Duration&nbsp;&nbsp; 36<br>
-Contraction, Anodic Opening&nbsp; 36<br>
-Contraction, Kathodic Closure&nbsp;&nbsp; 312<br>
-Contraction, Kathodic Duration&nbsp; 312<br>
-Contractures&nbsp; 148<br>
-Contraplex Working&nbsp; 580<br>
-Control, Electro-magnetic&nbsp;&nbsp; 218<br>
-Control, Gravity&nbsp;&nbsp; 281<br>
-Controlled Clock,&nbsp; 127<br>
-Controlling Clock&nbsp; 127<br>
-Controlling Field&nbsp; 148<br>
-Controlling Force&nbsp; 148<br>
-Controlling Magnet&nbsp; 185, 336<br>
-Control, Magnetic&nbsp;&nbsp; 341<br>
-Control, Spring&nbsp; 492<br>
-Convection, Electric&nbsp;&nbsp; 149<br>
-Convection, Electrolytic&nbsp;&nbsp; 149, 214<br>
-Convection of Heat, Electric&nbsp;&nbsp; 149<br>
-Convective Discharge&nbsp; 187<br>
-Conversion, Efficiency of&nbsp;&nbsp; 205<br>
-Converter&nbsp; 149<br>
-Cooling Box&nbsp; 151<br>
-Co-ordinates, Origin of&nbsp;&nbsp; 391<br>
-Co-ordinates, System of&nbsp;&nbsp; 150<br>
-Copper&nbsp; 151<br>
-Copper Bath&nbsp; 152<br>
-Copper Stripping Bath&nbsp; 152<br>
-Copper Voltameter&nbsp; 563<br>
-Cord Adjuster&nbsp; 152<br>
-Cord, Flexible&nbsp;&nbsp; 152<br>
-Cord, Pendant&nbsp;&nbsp; 405<br>
-Core&nbsp; 152<br>
-Core, Armature&nbsp;&nbsp; 43<br>
-Core, Cable&nbsp;&nbsp;&nbsp; 96<br>
-Cored Carbon&nbsp; 107<br>
-Core-discs&nbsp; 152<br>
-Core-discs, Perforated&nbsp;&nbsp; 154<br>
-Core-discs, Pierced&nbsp;&nbsp; 152<br>
-Core-discs, Toothed&nbsp;&nbsp; 154<br>
-Core, Laminated&nbsp;&nbsp; 154<br>
-Core, Magnet&nbsp;&nbsp; 336<br>
-Core Ratio&nbsp; 154<br>
-Core, Ribbon&nbsp;&nbsp; 154<br>
-Core, Ring&nbsp; 155<br>
-Cores, Krizik's&nbsp;&nbsp; 318<br>
-Core, Stranded&nbsp;&nbsp; 155<br>
-Core, Tangentially Laminated&nbsp;&nbsp; 155<br>
-Core Transformer&nbsp; 155<br>
-Core, Tubular&nbsp; 155<br>
-Corpusants&nbsp; 155<br>
-Corresponding Points&nbsp; 422<br>
-Coulomb&nbsp; 155<br>
-Coulomb's Law of Electrostatic Attraction and Repulsion&nbsp; 155<br>
-Coulomb's Law of Magnetic Attraction and Repulsion&nbsp; 338<br>
-Coulomb's Torsion Balance&nbsp; 544<br>
-Coulomb, Volt-&nbsp;&nbsp; 568<br>
-Counter, Electric&nbsp;&nbsp; 156<br>
-Counter Electro-motive Force&nbsp; 156, 228<br>
-Counter-electro-motive Force Lightning Arrester&nbsp; 329<br>
-Counter Inductive Effect&nbsp; 204<br>
-Couple&nbsp; 156<br>
-Couple, Astatic&nbsp; 157<br>
-Couple, Axial&nbsp; 544<br>
-Couple, Magnetic&nbsp;&nbsp;&nbsp; 341<br>
-Couple, Moment of&nbsp; 544<br>
-Couple, Thermo-electric&nbsp;&nbsp; 532<br>
-Couple, Voltaic or Galvanic&nbsp;&nbsp; 156<br>
-Coupling&nbsp; 259<br>
-Coupling of Dynamo&nbsp; 201<br>
-C. P.&nbsp; 157<br>
-Crater&nbsp; 157<br>
-Creep, Diffusion&nbsp;&nbsp; 184<br>
-Creeping&nbsp; 157<br>
-Creeping, Magnetic&nbsp; 341<br>
-Creeping of Magnetism&nbsp; 356<br>
-Crith&nbsp; 157<br>
-Critical Current&nbsp; 161<br>
-Critical Distance of Alternative Path&nbsp; 190<br>
-Critical Resistance&nbsp; 464<br>
-Critical Speed&nbsp; 157<br>
-Critical Value, Villari's&nbsp;&nbsp; 561<br>
-Crookes' Dark Space&nbsp; 489<br>
-Cross&nbsp; 157<br>
-Cross-connecting Board&nbsp; 157<br>
-Cross Connection&nbsp; 158<br>
-Cross Induction&nbsp; 298<br>
-Crossing Cleat&nbsp; 127<br>
-Crossing Wires&nbsp; 158<br>
-Cross-magnetizing Effect&nbsp; 158, 298<br>
-Cross-over Block&nbsp; 158<br>
-Cross, Peltier's&nbsp; 405<br>
-Cross Talk&nbsp; 158<br>
-Crucible, Electric&nbsp;&nbsp;&nbsp; 158<br>
-Crystallization, Electric&nbsp;&nbsp; 158<br>
-Cube, Faraday's&nbsp;&nbsp; 249<br>
-Culture. Electro-&nbsp; 209<br>
-Cunynghame's Ammeter&nbsp; 26<br>
-Cup, Mercury&nbsp;&nbsp; 371<br>
-Cup, Porous&nbsp;&nbsp; 159, 426<br>
-Current&nbsp; 159<br>
-Current, After&nbsp; 159<br>
-Current, Alternating&nbsp; 159<br>
-Current, Alternating System&nbsp;&nbsp; 23<br>
-Current, Alternative&nbsp; 563<br>
-Current Arc, Alternating&nbsp;&nbsp; 23<br>
-Current, Atomic&nbsp; 160<br>
-Current, Break Induced&nbsp;&nbsp; 162<br>
-Current, Charge&nbsp; 160<br>
-Current, Circular&nbsp;&nbsp; 160<br>
-Current, Commuted&nbsp;&nbsp; 160<br>
-Current, Constant&nbsp;&nbsp; 160<br>
-Current, Continuous&nbsp; 161<br>
-Current, Continuous, Transformer&nbsp;&nbsp; 384<br>
-Current, Critical&nbsp;&nbsp; 161<br>
-Current, Daniel&nbsp; 161<br>
-Current, U. S. or Siemens' Unit&nbsp;&nbsp; 161<br>
-Current, Demarcation&nbsp;&nbsp; 161<br>
-Current Density&nbsp; 161<br>
-Current, Derived&nbsp;&nbsp; 164<br>
-Current, Diacritical&nbsp;&nbsp; 161<br>
-Current, Diaphragm&nbsp;&nbsp; 161<br>
-Current, Direct&nbsp; 162<br>
-Current, Direct Induced&nbsp;&nbsp; 162<br>
-Current, Direction of&nbsp; 162<br>
-Current, Displacement&nbsp;&nbsp; 162<br>
-Current, Extra&nbsp;&nbsp; 162<br>
-Current, Faradic&nbsp;&nbsp; 162<br>
-Current, Field of Force of a&nbsp;&nbsp; 255<br>
-Current, Foucault&nbsp;&nbsp; 163<br>
-Current, Franklinic&nbsp;&nbsp; 163<br>
-Current Generator&nbsp; 277<br>
-Current, Induced&nbsp; 163<br>
-Current Induction&nbsp; 163<br>
-Current Induction, Unipolar&nbsp;&nbsp; 553<br>
-Current Intensity&nbsp; 163<br>
-Current, Inverse Induced&nbsp;&nbsp; 163<br>
-Current, Jacobi's Unit of&nbsp;&nbsp; 163<br>
-Current, Joint&nbsp;&nbsp; 163<br>
-Current, Linear&nbsp;&nbsp; 164<br>
-Current, Make and Break&nbsp;&nbsp; 164, 367<br>
-Current, Make Induced&nbsp;&nbsp; 163<br>
-Current Meter&nbsp; 164, 375<br>
-Current Meter, Alternating&nbsp;&nbsp; 373<br>
-Current, Negative&nbsp; 164<br>
-Current, Nerve and Muscle&nbsp;&nbsp; 164<br>
-Current, Opposed&nbsp;&nbsp; 164<br>
-Current, Partial&nbsp;&nbsp; 164<br>
-Current, Polarizing&nbsp;&nbsp; 164<br>
-Current, Positive&nbsp;&nbsp; 164<br>
-Current, Power of Periodic&nbsp;&nbsp; 433<br>
-Current, Pulsatory&nbsp; 164<br>
-Current, Rectified&nbsp;&nbsp; 164<br>
-Current, Rectilinear&nbsp;&nbsp; 165<br>
-Current, Redressed&nbsp;&nbsp; 165<br>
-Current Regulation, Constant&nbsp;&nbsp;&nbsp; 454<br>
-Current, Reverse Induced&nbsp;&nbsp; 163<br>
-Current Reverser&nbsp; 165<br>
-Currents, Ampere&nbsp; 30<br>
-Currents, Amp&eacute;rian&nbsp;&nbsp; 165<br>
-Currents, Angular.&nbsp;&nbsp; 165<br>
-Currents, Angular, Laws of&nbsp;&nbsp; 165<br>
-Currents, Earth&nbsp;&nbsp; 166<br>
-Current, Secondary&nbsp; 166<br>
-Current, Secretion&nbsp;&nbsp; 166<br>
-Currents, Eddy&nbsp;&nbsp; 163<br>
-Currents, Eddy Displacement&nbsp; 162<br>
-Currents in Parallel Circuits, Independence of&nbsp;&nbsp; 297<br>
-Current, Sinuous&nbsp;&nbsp; 166<br>
-Current, Sheet&nbsp;&nbsp; 166<br>
-Current, Shuttle&nbsp;&nbsp; 483<br>
-Currents, Local&nbsp;&nbsp; 163<br>
-Currents, Local&nbsp; 331<br>
-Currents, Multiphase&nbsp;&nbsp; 166<br>
-Currents, Natural&nbsp;&nbsp; 166, 389<br>
-Currents, Nerve&nbsp;&nbsp; 390<br>
-Currents of Motion&nbsp; 167<br>
-Currents of Rest&nbsp; 167<br>
-Currents, Orders of&nbsp;&nbsp; 167<br>
-Currents, Parasitical&nbsp;&nbsp; 163<br>
-Currents, Polyphase&nbsp;&nbsp; 167<br>
-Currents, Rotatory&nbsp; 167<br>
-Currents, Thermo-electric&nbsp;&nbsp; 167<br>
-Current Streamlets&nbsp; 495<br>
-Current, Swelling&nbsp;&nbsp; 167<br>
-Current, Tailing&nbsp; 501<br>
-Current, Undulatory&nbsp;&nbsp; 167<br>
-Current, Unit&nbsp; 167<br>
-Current, Wattless&nbsp;&nbsp; 168<br>
-Curve, Arrival&nbsp; 168<br>
-Curve, Characteristic&nbsp;&nbsp; 113, 168<br>
-Curve, Characteristic, of Converter&nbsp;&nbsp; 169<br>
-Curve, Charging&nbsp;&nbsp; 170<br>
-Curve, Discharging&nbsp;&nbsp; 170<br>
-Curve, Elastic&nbsp; 206<br>
-Curve, Electro-motive Force&nbsp;&nbsp; 170<br>
-Curve, External Characteristic&nbsp;&nbsp; . 171<br>
-Curve, Harmonic&nbsp; 174, 485<br>
-Curve, Horse Power&nbsp;&nbsp; 171<br>
-Curve, Isochasmen&nbsp;&nbsp; 171<br>
-Curve, Life&nbsp;&nbsp;&nbsp; 171<br>
-Curve, Load&nbsp; 172<br>
-Curve, Magnetization&nbsp;&nbsp; 172<br>
-Curve of Distribution of Potential in Armature&nbsp; 172<br>
-Curve of Dynamo&nbsp; 173<br>
-Curve of Saturation of Magnetic Circuit&nbsp; 174<br>
-Curve of Sines&nbsp; 173, 485<br>
-Curve of Torque&nbsp; 174<br>
-Curve, Permeability Temperature&nbsp;&nbsp; 174<br>
-Curve, Sine&nbsp;&nbsp; 174, 485<br>
-Curve, Sinusoidal&nbsp; 174, 485<br>
-Curves, Magnetic&nbsp;&nbsp; 341<br>
-Cut In&nbsp; 174<br>
-Cut Out&nbsp; 174<br>
-Cut Out, Automatic&nbsp;&nbsp; 175, 475<br>
-Cut Out, Magnetic&nbsp; 175<br>
-Cut Out, Plug&nbsp;&nbsp; 175<br>
-Cut Out, Safety&nbsp; 175<br>
-Cut Out, Spring Jack&nbsp;&nbsp; 493<br>
-Cut Outs, Time&nbsp; 541<br>
-Cut Out, Wedge&nbsp; 175<br>
-Cutting of Lines of Force&nbsp; 175<br>
-Cycle of Alternation&nbsp; 175<br>
-Cycle of Magnetization&nbsp; 360<br>
-Cylinder, Armature&nbsp; 43<br>
-Cylinder, Electric Machine&nbsp;&nbsp; 333<br>
-Cylindrical Armature&nbsp; 45<br>
-Cystoscopy&nbsp; 175<br>
-<br>
-Damper&nbsp; 176<br>
-Damping&nbsp; 176<br>
-Damping Magnet&nbsp; 336<br>
-Daniell's Standard Voltaic Cell&nbsp; 109<br>
-Dark Space, Faraday's&nbsp;&nbsp; 249<br>
-D'Arsonval's Battery&nbsp; 62<br>
-Dash-pot&nbsp; 176<br>
-Dead Beat&nbsp; 38, 176<br>
-Dead Beat Discharge&nbsp; 187<br>
-Dead Earth&nbsp; 176, 203<br>
-Dead Point of an Alternator&nbsp; 177<br>
-Dead Turns&nbsp; 177<br>
-Dead Turns of a Dynamo&nbsp; 551<br>
-Dead Wire&nbsp; 177<br>
-Death, Electrical&nbsp;&nbsp; 177<br>
-Debrun Candle&nbsp; 99<br>
-Decalescence&nbsp; 177<br>
-Decay of Magnetism&nbsp; 356<br>
-Deci&nbsp; 177<br>
-Decimal Candle&nbsp; 99<br>
-Declination, Angle of&nbsp;&nbsp; 32-177<br>
-Declination Compass&nbsp; 142<br>
-Declination, Magnetic&nbsp;&nbsp; 342<br>
-Declination Map&nbsp; 309<br>
-Declination of the Magnetic Needle&nbsp; 178<br>
-Decomposition&nbsp; 178<br>
-Decomposition, Electrolytic&nbsp;&nbsp; 178<br>
-Decrement&nbsp; 178<br>
-De-energize&nbsp; 178<br>
-Deflagration&nbsp; 178<br>
-Deflagrator, Hare's&nbsp;&nbsp; 73<br>
-Deflecting Field&nbsp; 178<br>
-Deflection&nbsp; 178<br>
-Deflection Method&nbsp; 178<br>
-Deflection of Magnet&nbsp; 337<br>
-Degeneration, Reaction of&nbsp;&nbsp; 179<br>
-Degradation of Energy&nbsp; 239<br>
-Deka&nbsp; 179<br>
-De la Rive's Floating Battery&nbsp; 179<br>
-De la Rue Battery&nbsp; 62<br>
-Delaurier's Solution&nbsp; 179<br>
-Delezenne's Circle&nbsp; 133<br>
-Demarcation Current&nbsp; 161<br>
-Demagnetization&nbsp; 179<br>
-Density, Current&nbsp;&nbsp; 161<br>
-Density, Electrical&nbsp; 115<br>
-Density, Electric Superficial&nbsp;&nbsp; 180<br>
-Density, Field&nbsp;&nbsp; 252<br>
-Density, Magnetic&nbsp;&nbsp; 342<br>
-Density of Charge&nbsp; 115, 180<br>
-Dental Mallet, Electric&nbsp;&nbsp; 180<br>
-Deposit, Electrolytic&nbsp;&nbsp; 180<br>
-Deposit, Nodular&nbsp;&nbsp; 392<br>
-Depolarization&nbsp; 180<br>
-Depolarizing Fluid&nbsp; 258<br>
-Derivation, Points of&nbsp;&nbsp; 180, 423<br>
-Derivative Circuit&nbsp; 123<br>
-Derived Circuit&nbsp; 123<br>
-Derived Current&nbsp; 164<br>
-Derived Units&nbsp; 555<br>
-Desk Push&nbsp; 180<br>
-Detector&nbsp; 180<br>
-Detector, Lineman's&nbsp; 180<br>
-Deviation of Discharge&nbsp; 188<br>
-Deviation, Quadrantal&nbsp;&nbsp; 180<br>
-Deviation, Semi-circular&nbsp;&nbsp; 181<br>
-Device, Safety&nbsp; 475<br>
-Dextrotorsal&nbsp; 181<br>
-Diacritical&nbsp; 181<br>
-Diacritical Current&nbsp; 161<br>
-Diagometer&nbsp; 181<br>
-Diagnosis, Electro-&nbsp; 181, 210<br>
-Diagram, Thermo-electric&nbsp;&nbsp; 532<br>
-Dial Telegraph&nbsp; 505<br>
-Diamagnetic&nbsp; 181<br>
-Diamagnetic Polarity&nbsp; 181, 423<br>
-Diamagnetism&nbsp; 182<br>
-Diameter of Commutation&nbsp; 182<br>
-Diapason, Electric&nbsp; 182<br>
-Diaphragm&nbsp; 182<br>
-Diaphragm Current&nbsp; 161<br>
-Dielectric,&nbsp; 182<br>
-Dielectric Capacity&nbsp;&nbsp; 102<br>
-Dielectric Constant&nbsp; 183<br>
-Dielectric, Energy of&nbsp;&nbsp; 183<br>
-Dielectric Polarization&nbsp; 183<br>
-Dielectric Resistance&nbsp; 183, 464<br>
-Dielectric Strain&nbsp; 183<br>
-Dielectric Strength&nbsp; 183<br>
-Dielectric Stress&nbsp; 496<br>
-Differential Arc Lamp&nbsp; 320<br>
-Differential Coil and Plunger&nbsp; 132<br>
-Differential Galvanometer&nbsp; 268<br>
-Differentially Wound Bell,&nbsp;&nbsp; 79<br>
-Differential Magnetometer&nbsp; 365<br>
-Differential Motor&nbsp; 382<br>
-Differential Relay&nbsp; 457<br>
-Differential Thermo-electric Pile&nbsp; 533<br>
-Differential Winding Working&nbsp; 183<br>
-Diffusion&nbsp; 184<br>
-Diffusion, Anodal .&nbsp;&nbsp; 35<br>
-Diffusion Creep&nbsp; 184<br>
-Digney Unit of Resistance&nbsp; 464<br>
-Dimensions and Theory of Dimensions&nbsp; 184<br>
-Dimmer&nbsp; 185<br>
-Diode Working&nbsp; 580<br>
-Dioxide, Carbon&nbsp;&nbsp; 107<br>
-Dioxide, Sulphur&nbsp; 497<br>
-Dip, Magnetic&nbsp; 342, 346<br>
-Dip of Magnetic Needle&nbsp; 185<br>
-Dipping&nbsp; 185<br>
-Dipping Needle&nbsp; 185<br>
-Direct Current&nbsp; 162<br>
-Direct Current Dynamo&nbsp; 197<br>
-Direct Induced Current,&nbsp; .&nbsp; 162<br>
-Direct Reading Galvanometer&nbsp; 269<br>
-Directing Magnet&nbsp; 185<br>
-Direction&nbsp; 185<br>
-Direction of Current&nbsp; 162<br>
-Direction, Positive&nbsp;&nbsp; 428<br>
-Directive Power&nbsp; 187<br>
-Disc, Arago's&nbsp;&nbsp; 38<br>
-Disc, Armature&nbsp; 43<br>
-Disc, Bunsen&nbsp;&nbsp; 92<br>
-Disc, Dynamo&nbsp; 197<br>
-Disc, Faraday's&nbsp; 249<br>
-Discharge and Charge Key&nbsp; 313<br>
-Discharge, Brush&nbsp; 187<br>
-Discharge, Conductive&nbsp; 187<br>
-Discharge, Convective&nbsp; 187<br>
-Discharge, Dead Beat&nbsp;&nbsp; 187<br>
-Discharge, Disruptive&nbsp;&nbsp; 187<br>
-Discharge, Duration of&nbsp;&nbsp; 188<br>
-Discharge, Glow&nbsp; 187<br>
-Discharge, Impulsive&nbsp;&nbsp; 188<br>
-Discharge Key, Kempe's&nbsp;&nbsp; 315<br>
-Discharge, Lateral&nbsp; 188<br>
-Discharge of Magnetism&nbsp; 356<br>
-Discharge, Oscillatory&nbsp; 188<br>
-Discharger&nbsp; 188<br>
-Discharger, Henley's Universal&nbsp;&nbsp; 189<br>
-Discharger, Universal&nbsp; 189<br>
-Discharger, Universal, Henley's&nbsp; 189<br>
-Discharge, Silent&nbsp; 187, 189, 206<br>
-Discharge, Spark&nbsp;&nbsp; 189<br>
-Discharge, Surging&nbsp;&nbsp; 188<br>
-Discharging Curve&nbsp; 170<br>
-Discharging Rod&nbsp; 189<br>
-Discharging Tongs&nbsp; 189<br>
-Disconnection&nbsp; 189<br>
-Discontinuity, Magnetic&nbsp; 342<br>
-Discovery, Oerstedt's&nbsp; 394<br>
-Disc Winding&nbsp; 579<br>
-Dispersion Photometer&nbsp; 412<br>
-Displacement Current&nbsp; 162<br>
-Displacement, Electric&nbsp;&nbsp; 188<br>
-Displacement, Oscillatory&nbsp;&nbsp; 398<br>
-Disruptive Discharge&nbsp; 187<br>
-Disruptive Tension&nbsp; 189<br>
-Dissimulated Electricity&nbsp; 189<br>
-Dissipation of Charge&nbsp; 115<br>
-Dissociation&nbsp; 189, 535<br>
-Distance, Critical, of Alternative Path&nbsp;&nbsp; 190<br>
-Distance, Explosive&nbsp;&nbsp; 190<br>
-Distance, Sparking&nbsp;&nbsp; 190<br>
-Distance, Striking&nbsp;&nbsp;&nbsp; 496<br>
-Distant Station&nbsp; 493<br>
-Distillation&nbsp; 190<br>
-Distortion of Field&nbsp; 252<br>
-Distributing Box&nbsp; 190<br>
-Distributing Switches&nbsp; 190<br>
-Distribution, Complementary&nbsp;&nbsp; 144<br>
-Distribution, Isolated&nbsp;&nbsp; 309<br>
-Distribution of Charge&nbsp; 115<br>
-Distribution of Electric Energy, Systems of&nbsp;&nbsp; 190<br>
-Distribution of Magnetism, Lamellar,&nbsp;&nbsp; 357<br>
-Distribution of Magnetism, Solenoidal&nbsp; 358<br>
-Distribution of Supply, Central Station&nbsp;&nbsp; 112<br>
-Door Opener, Electric&nbsp;&nbsp; 190<br>
-Dosage, Galvanic&nbsp; 190<br>
-Double Break Switch&nbsp; 500<br>
-Double Carbon Arc Lamp&nbsp; 191<br>
-Double Contact Key&nbsp; 314<br>
-Double Curb Working&nbsp; 581<br>
-Double Fluid Theory&nbsp; 191<br>
-Double Fluid Voltaic Cell&nbsp; 191<br>
-Double Magnetic Circuit&nbsp; 340<br>
-Double Needle Telegraph&nbsp; 506<br>
-Double Plug&nbsp; 191<br>
-Double Pole Switch&nbsp; 500<br>
-Double Tapper Key&nbsp; 314<br>
-Double Touch, Magnetization by&nbsp; 358<br>
-Double Trolley&nbsp; 549<br>
-Double Wedge&nbsp; 191<br>
-Doubler&nbsp; 191<br>
-D. P.&nbsp; 191<br>
-Drag&nbsp; 191<br>
-Drag of Field&nbsp; 254<br>
-Dreh-Strom&nbsp; 191<br>
-Drill, Electric&nbsp;&nbsp; 191<br>
-Drip Loop&nbsp; 192<br>
-Driving Horns&nbsp; 192<br>
-Dronier's Salt&nbsp; 192<br>
-Drooping Characteristic&nbsp; 114<br>
-Drop, Annunciator&nbsp;&nbsp; 35<br>
-Drop, Automatic&nbsp;&nbsp; 192<br>
-Drop, Calling&nbsp;&nbsp; 98<br>
-Drum Armature&nbsp; 45<br>
-Drum, Electric&nbsp;&nbsp; 193<br>
-Dry Battery&nbsp; 63<br>
-Dry Pile, Zamboni's&nbsp;&nbsp; 581<br>
-Dub's Laws&nbsp; 193<br>
-Duct&nbsp; 193<br>
-Duplex Bridge Telegraph&nbsp; 506<br>
-Duplex Cable&nbsp; 96<br>
-Duplex Differential Telegraph&nbsp; 507<br>
-Duplex Telegraph,&nbsp; 506<br>
-Duration Contraction, Kathodic&nbsp; 312<br>
-Duration of Electric Spark&nbsp; 490<br>
-Dyad&nbsp; 193<br>
-Dyeing, Electric&nbsp; 193<br>
-Dynamic Electricity&nbsp; 193<br>
-Dynamic, Electro-&nbsp;&nbsp; 211<br>
-Dynamic Induction, Magnetic&nbsp;&nbsp; 347<br>
-Dynamo, Alternating Current&nbsp;&nbsp; 193<br>
-Dynamo, Alternating Current Regulation of&nbsp;&nbsp; 195<br>
-Dynamos, Battery of&nbsp;&nbsp;&nbsp; 68<br>
-Dynamo, Commercial Efficiency of&nbsp;&nbsp; 195<br>
-Dynamo, Compound&nbsp;&nbsp; 195<br>
-Dynamo, Coupling of&nbsp;&nbsp; 201<br>
-Dynamo, Curve of&nbsp; 173<br>
-Dynamo, Dead Turns of a&nbsp;&nbsp; 551<br>
-Dynamo, Direct Current&nbsp;&nbsp; 197<br>
-Dynamo, Disc&nbsp; 197<br>
-Dynamo-electric Machine&nbsp; 197<br>
-Dynamo, Electroplating&nbsp; 198<br>
-Dynamo, Equalizing&nbsp; 198<br>
-Dynamo, Field and Armature Reaction of&nbsp; 450<br>
-Dynamo, Far Leading&nbsp; 198<br>
-Dynamo or Magneto-electric Generator, Flashing in a&nbsp;&nbsp; 257<br>
-Dynamo, Inductor&nbsp;&nbsp; 199<br>
-Dynamo, Interior Pole&nbsp; 199<br>
-Dynamo, Iron Clad&nbsp; 200<br>
-Dynamo, Ironwork Fault of a&nbsp;&nbsp; 308<br>
-Dynamo, Motor&nbsp; 200<br>
-Dynamo, Multipolar&nbsp;&nbsp; 200<br>
-Dynamo, Non-polar&nbsp;&nbsp; 200<br>
-Dynamo, Open Coil&nbsp; 200<br>
-Dynamo, Overtype&nbsp; 399<br>
-Dynamos, Regulation of&nbsp;&nbsp; 455<br>
-Dynamo, Ring&nbsp; 200<br>
-Dynamo, Self Exciting&nbsp; 201<br>
-Dynamo, Separate Circuit&nbsp; 201<br>
-Dynamo, Separately Excited&nbsp;&nbsp; 201, 479<br>
-Dynamo, Series&nbsp;&nbsp; 201<br>
-Dynamo, Shunt&nbsp;&nbsp; 202<br>
-Dynamo, Single Coil&nbsp; 202<br>
-Dynamo, Tuning Fork&nbsp;&nbsp; 202<br>
-Dynamo, Unipolar&nbsp; 202, 553<br>
-Dynamograph&nbsp; 199<br>
-Dynamometer&nbsp; 200<br>
-Dyne&nbsp; 203<br>
-<br>
-Earth&nbsp; 203<br>
-Earth Coil&nbsp; 133<br>
-Earth Currents&nbsp; 166<br>
-Earth, Dead&nbsp; 176, 203<br>
-Earth, Magnetization by&nbsp;&nbsp; 359<br>
-Earth, Partial&nbsp; 203, 404<br>
-Earth Plate&nbsp; 203<br>
-Earth Return&nbsp; 203<br>
-Earth's Magnetism, Components of&nbsp;&nbsp; 356<br>
-Earth, Solid&nbsp; 203<br>
-Earth, Swinging&nbsp;&nbsp;&nbsp; 203<br>
-Earth, Total&nbsp;&nbsp; 203<br>
-Ebonite&nbsp; 203<br>
-Eccentric Iron Disc Ammeter&nbsp; 27<br>
-Economic Coefficient&nbsp; 130, 204, 205<br>
-Eddy Currents&nbsp; 163<br>
-Eddy Displacement Currents&nbsp; 162<br>
-Ediswan&nbsp; 204<br>
-Edison Effect&nbsp; 204<br>
-Edison-Lalande Battery&nbsp; 69<br>
-Eel, Electric&nbsp; 204<br>
-Effect, Acheson&nbsp; 208<br>
-Effect, Counter-inductive&nbsp;&nbsp; 204<br>
-Effect, Cross-magnetizing&nbsp;&nbsp; 158, 298<br>
-Effect, Edison&nbsp; 204<br>
-Effect, Faraday&nbsp;&nbsp; 249<br>
-Effect, Ferranti&nbsp;&nbsp; 251<br>
-Effect, Hall&nbsp;&nbsp; 284<br>
-Effect, Joule&nbsp;&nbsp; 311<br>
-Effect, Kerr&nbsp; 235, 312<br>
-Effect, Mordey&nbsp;&nbsp; 381<br>
-Effect, Page&nbsp;&nbsp; 401<br>
-Effect, Peltier&nbsp; 404<br>
-Effect, Photo-voltaic&nbsp;&nbsp; 415<br>
-Effect, Seebeck&nbsp; 478<br>
-Effect, Skin&nbsp; 486<br>
-Effect, Thomson&nbsp;&nbsp; 538<br>
-Effect, Voltaic&nbsp;&nbsp; 563<br>
-Efficiency&nbsp; 204<br>
-Efficiency, Commercial&nbsp;&nbsp; 204<br>
-Efficiency, Electrical&nbsp;&nbsp; 205<br>
-Efficiency, Gross&nbsp; 205<br>
-Efficiency, Intrinsic&nbsp; 205<br>
-Efficiency, Net&nbsp; 205<br>
-Efficiency of Conversion&nbsp; 205<br>
-Efficiency of Secondary Battery Quantity&nbsp;&nbsp; 205<br>
-Efficiency of Secondary Battery, Real&nbsp;&nbsp; 205<br>
-Efflorescence&nbsp; 206<br>
-Effluvium, Electric&nbsp;&nbsp; 206<br>
-Egg, Philosopher's&nbsp;&nbsp; 409<br>
-Elastic Curve&nbsp; 206<br>
-Elasticity, Electric&nbsp;&nbsp; 206<br>
-Electrepeter&nbsp;&nbsp; 206<br>
-Electric, Absolute, Potential&nbsp;&nbsp; 429<br>
-Electric Absorption&nbsp; 8<br>
-Electric Actinometer&nbsp; 11<br>
-Electric Alarm&nbsp; 17<br>
-Electrical Classification of Elements&nbsp;&nbsp; 237<br>
-Electrically Controlled Valve&nbsp; 558<br>
-Electric Ammunition Hoist&nbsp; 29<br>
-Electric Analysis&nbsp; 32<br>
-Electric Analyzer&nbsp; 32<br>
-Electric Annealing&nbsp; 34<br>
-Electric Annunciator Clock&nbsp; 127<br>
-Electric Arc Blow-pipe&nbsp; 84<br>
-Electric Aura&nbsp; 53<br>
-Electric Automatic Fire Extinguisher&nbsp; 257<br>
-Electric Axis&nbsp; 54<br>
-Electric Balance&nbsp; 577<br>
-Electric Bath, Bipolar&nbsp; 57<br>
-Electric Bath, Multipolar&nbsp;&nbsp; 57<br>
-Electric Bath, Unipolar&nbsp;&nbsp; 57<br>
-Electric Bell&nbsp; 79<br>
-Electric Bell, Automatic&nbsp;&nbsp; 78<br>
-Electric Bioscopy&nbsp; 82<br>
-Electric Blasting&nbsp; 83<br>
-Electric Bleaching&nbsp; 83<br>
-Electric Boat&nbsp; 84<br>
-Electric Boiler Feed&nbsp; 84<br>
-Electric Branding&nbsp; 87<br>
-Electric Brazing&nbsp; 87<br>
-Electric Breath Figures&nbsp; 89<br>
-Electric Breeze&nbsp; 89<br>
-Electric Buoy&nbsp; 93<br>
-Electric Candle&nbsp; 99<br>
-Electric Case Hardening&nbsp; 109<br>
-Electric Cautery&nbsp; 109<br>
-Electric Chimes&nbsp; 118<br>
-Electric Chronograph&nbsp; 118<br>
-Electric Circuit, Active&nbsp; 123<br>
-Electric Clock, Self-winding&nbsp;&nbsp;&nbsp; 128<br>
-Electric Coil&nbsp; 133<br>
-Electric Column&nbsp; 139<br>
-Electric Contact&nbsp; 147<br>
-Electric Convection&nbsp; 149<br>
-Electric Convection of Heat&nbsp; 149, 286<br>
-Electric Counter&nbsp; 156<br>
-Electric Crucible&nbsp; 158<br>
-Electric Crystallization&nbsp; 158<br>
-Electric Death&nbsp; 177<br>
-Electric Density&nbsp; 115<br>
-Electric Dental Mallet&nbsp; 180<br>
-Electric Diapason&nbsp; 182<br>
-Electric Displacement&nbsp; 189<br>
-Electric Door Opener&nbsp; 190<br>
-Electric Double Refraction&nbsp; 454<br>
-Electric Drill&nbsp;&nbsp; 191<br>
-Electric Drum&nbsp; 193<br>
-Electric Dyeing&nbsp; 193<br>
-Electric Eel&nbsp; 204<br>
-Electric Efficiency&nbsp;&nbsp; 205<br>
-Electric Effluvium&nbsp; 206<br>
-Electric Elasticity&nbsp; 206<br>
-Electric Endosmose&nbsp; 238<br>
-Electric Energy&nbsp; 239<br>
-Electric Energy, Coefficient of&nbsp; 205<br>
-Electric Energy, Systems of Distribution of&nbsp;&nbsp; 190<br>
-Electric Engraving&nbsp; 245<br>
-Electric Entropy&nbsp; 242<br>
-Electric Etching&nbsp; 245<br>
-Electric Evaporation&nbsp; 246<br>
-Electric Excitability of Animal Systems&nbsp; 247<br>
-Electric Exosmose&nbsp; 247<br>
-Electric Expansion&nbsp; 247<br>
-Electric Fire Alarm, Automatic&nbsp; 257<br>
-Electric Floor Matting&nbsp; 369<br>
-Electric Fluid&nbsp; 258<br>
-Electric Fly or Flyer&nbsp; 259<br>
-Electric Fog&nbsp; 259<br>
-Electric Furnace&nbsp; 263<br>
-Electric Fuse&nbsp; 264<br>
-Electric Gas Burners&nbsp; 93<br>
-Electric Headlight&nbsp; 285<br>
-Electric Head Bath&nbsp; 284<br>
-Electric Heat&nbsp; 285<br>
-Electric Heater&nbsp; 286<br>
-Electric Horse Power&nbsp; 290<br>
-Electric Image&nbsp; 296<br>
-Electric Incandescence&nbsp; 297<br>
-Electric Influence&nbsp; 305<br>
-Electric Insulation&nbsp; 305<br>
-Electricities, Separation of&nbsp;&nbsp; 479<br>
-Electricity&nbsp; 206<br>
-Electricity, Animal&nbsp;&nbsp; 33<br>
-Electricity, Atmospheric&nbsp;&nbsp;&nbsp; 51<br>
-Electricity, Cal&nbsp; 208<br>
-Electricity, Conservation of&nbsp;&nbsp; 146<br>
-Electricity, Contact&nbsp; 147<br>
-Electricity, Dissimulated&nbsp;&nbsp; 189<br>
-Electricity, Dynamic&nbsp;&nbsp; 193<br>
-Electricity, Frictional&nbsp;&nbsp; 262<br>
-Electricity, Latent&nbsp;&nbsp; 323<br>
-Electricity, Negative&nbsp;&nbsp; 389<br>
-Electricity, Plant&nbsp;&nbsp; 317<br>
-Electricity, Positive&nbsp; 428<br>
-Electricity, Specific Heat of&nbsp;&nbsp; 491<br>
-Electricity, Static&nbsp; 493<br>
-Electricity, Storage of&nbsp;&nbsp; 495<br>
-Electricity, Voltaic&nbsp;&nbsp; 563<br>
-Electricity, Vitreous&nbsp;&nbsp; 562<br>
-Electric Machine, Plate&nbsp; 417<br>
-Electric Machine, Wimshurst&nbsp;&nbsp; 577<br>
-Electric Mains&nbsp; 367<br>
-Electric Mass&nbsp; 368<br>
-Electric Matter&nbsp; 368<br>
-Electric Meter, Chemical&nbsp;&nbsp; 375<br>
-Electric Meter, Thermal&nbsp;&nbsp; 375<br>
-Electric Meter, Time&nbsp;&nbsp; 375<br>
-Electric Mortar&nbsp; 382<br>
-Electric Motor&nbsp; 382<br>
-Electric or Electrostatic Capacity&nbsp; 102<br>
-Electric Organ&nbsp; 397<br>
-Electric Oscillations&nbsp; 398<br>
-Electric Osmose&nbsp; 398<br>
-Electric Pen&nbsp; 405<br>
-Electric Pendulum&nbsp; 405<br>
-Electric Piano&nbsp; 415<br>
-Electric Picture&nbsp;&nbsp; 415<br>
-Electric Pistol&nbsp; 416<br>
-Electric Popgun&nbsp; 282<br>
-Electric Portrait&nbsp; 415<br>
-Electric Potential Difference&nbsp;&nbsp; 429<br>
-Electric Potential, Unit of&nbsp;&nbsp; 432<br>
-Electric Power&nbsp;&nbsp; 433<br>
-Electric Pressure&nbsp; 434<br>
-Electric Probe&nbsp; 435<br>
-Electric Prostration&nbsp; 437<br>
-Electric Protector&nbsp;&nbsp; 437<br>
-Electric Radiometer&nbsp; 447<br>
-Electric Ray&nbsp; 450<br>
-Electric Rectification of Alcohol&nbsp; 18<br>
-Electric Reduction of Ores&nbsp; 453<br>
-Electric Reduction of Phosphorous&nbsp;&nbsp; 410<br>
-Electric Register&nbsp; 454<br>
-Electric Residue&nbsp; 116, 460<br>
-Electricity, Resinous&nbsp;&nbsp; 461<br>
-Electric Resonance&nbsp;&nbsp; 468<br>
-Electric Resonator&nbsp; 470<br>
-Electric Rings&nbsp; 392<br>
-Electrics&nbsp; 208<br>
-Electric Saw&nbsp; 476<br>
-Electric Screen,&nbsp;&nbsp; 476<br>
-Electric Shadow&nbsp;&nbsp; 480<br>
-Electric Shock&nbsp; 482<br>
-Electric Shower Bath&nbsp;&nbsp; 57<br>
-Electric Soldering&nbsp; 487<br>
-Electric Spark, Duration of&nbsp;&nbsp; 490<br>
-Electric Sphygmophone&nbsp; 491<br>
-Electric Storms&nbsp; 495<br>
-Electric Striae&nbsp; 496<br>
-Electric Subway&nbsp;&nbsp; 496<br>
-Electric Subway, Underground&nbsp;&nbsp; 552<br>
-Electric Sunstroke&nbsp;&nbsp; 497<br>
-Electric Superficial Density&nbsp; 180<br>
-Electric Swaging&nbsp; 499<br>
-Electric Tele-barometer&nbsp; 504<br>
-Electric Telemanometer&nbsp;&nbsp; 521<br>
-Electric Telemeter&nbsp; 521<br>
-Electric Tempering&nbsp; 527<br>
-Electric Tension&nbsp; 529<br>
-Electric Thermometer&nbsp; 535<br>
-Electric Thermostat&nbsp; 537<br>
-Electric Torpedo&nbsp; 543<br>
-Electric Tower&nbsp; 545<br>
-Electric Transmission of Energy&nbsp; 240<br>
-Electric Trumpet&nbsp; 550<br>
-Electric Tube&nbsp; 550<br>
-Electric Typewriter&nbsp; 551<br>
-Electric Unit of Work&nbsp; 580<br>
-Electric Varnish&nbsp; 559<br>
-Electric Welding&nbsp;&nbsp; 574<br>
-Electric Whirl&nbsp; 577<br>
-Electric Wind&nbsp; 578<br>
-Electrification&nbsp; 208<br>
-Electrification by Cleavage&nbsp; 127<br>
-Electrification by Pressure&nbsp; 434<br>
-Electrified Body, Energy of an&nbsp;&nbsp; . 241<br>
-Electrization&nbsp; 208<br>
-Electro-biology&nbsp; 208<br>
-Electro-capillarity&nbsp; 209<br>
-Electro-chemical Equivalents&nbsp; 209, 244<br>
-Electro-chemical Series&nbsp; 209<br>
-Electro-chemistry&nbsp;&nbsp; 209<br>
-Electro-culture&nbsp; 209<br>
-Electrode&nbsp; 210<br>
-Electrode, Indifferent&nbsp;&nbsp; 210<br>
-Electrodes, Erb's Standard of&nbsp;&nbsp; 210<br>
-Electrodes, Non-polarizable&nbsp; 210<br>
-Electrodes, Shovel&nbsp;&nbsp; 483<br>
-Electrode, Therapeutic&nbsp;&nbsp; 210<br>
-Electro-diagnosis&nbsp; 181, 210<br>
-Electro-dynamic&nbsp; 211<br>
-Electro-dynamic Attraction and Repulsion,&nbsp;&nbsp; 211<br>
-Electro-dynamic Rotation of Liquids&nbsp; 474<br>
-Electro-dynamometer, Siemens'&nbsp; 212<br>
-Electro-gilding&nbsp; 277<br>
-Electro-kinetic&nbsp; 211<br>
-Electrolier&nbsp; 212<br>
-Electrolysis&nbsp; 212<br>
-Electrolysis, Laws of&nbsp;&nbsp; 213<br>
-Electrolyte&nbsp; 214<br>
-Electrolytic Analysis&nbsp; 214<br>
-Electrolytic Cell&nbsp; 109<br>
-Electrolytic Clock&nbsp; 128<br>
-Electrolytic Conduction&nbsp; 215<br>
-Electrolytic Convection&nbsp; 149, 214<br>
-Electrolytic Deposit&nbsp; 180<br>
-Electrolytic Iron&nbsp; 308<br>
-Electrolytic Resistance&nbsp; 464<br>
-Electro-magnet&nbsp; 215, 337<br>
-Electro-magnet, Annular&nbsp;&nbsp; 216<br>
-Electro-magnet, Bar&nbsp; 217<br>
-Electro-magnet, Club-foot&nbsp;&nbsp; 217<br>
-Electro-magnet, Hinged&nbsp; 217<br>
-Electro-magnet, Hughes'&nbsp;&nbsp;&nbsp; 291<br>
-Electro-magnetic Ammeter&nbsp; 27<br>
-Electro-magnetic and Magnetic Equipotential Surface&nbsp; 244<br>
-Electro-magnetic Attraction and Repulsion&nbsp; 217<br>
-Electro-magnetic Brake&nbsp; 86<br>
-Electro-magnetic Clutch&nbsp; 128<br>
-Electro-magnetic Control&nbsp; 218<br>
-Electro-magnetic Eye&nbsp; 248<br>
-Electro-magnetic Field of Force&nbsp; 218<br>
-Electro-magnetic Force&nbsp; 260<br>
-Electro-magnetic Gun&nbsp; 282<br>
-Electro-magnetic Induction&nbsp; 218, 299<br>
-Electro-magnetic Inertia&nbsp; 305<br>
-Electro-magnetic Induction, Mutual&nbsp; 302<br>
-Electro-magnetic Interrupter for Tuning Fork&nbsp; 307<br>
-Electro-magnetic Leakage&nbsp; 219<br>
-Electro-magnetic Lines of Force&nbsp; 219<br>
-Electro-magnetic Liquids, Rotation of&nbsp;&nbsp; 475<br>
-Electro-magnetic Meter&nbsp; 375<br>
-Electro-magnetic Quantity&nbsp; 445<br>
-Electro-magnetic Quantity, Practical Unit of&nbsp;&nbsp; 445<br>
-Electro-magnetic Shunt&nbsp; .483<br>
-Electro-magnetic Stress&nbsp; 219, 496<br>
-Electro-magnetic Theory of Light&nbsp; 219<br>
-Electro-magnetic Unit of Energy&nbsp; 220<br>
-Electro-magnetic Vibrator&nbsp; 561<br>
-Electro-magnetic Waves,&nbsp;&nbsp; 573<br>
-Electro-magnet, Ironclad&nbsp;&nbsp; 219<br>
-Electro-magnetism&nbsp; 220<br>
-Electro-magnet, Joule's&nbsp; 337<br>
-Electro-magnet, Long Range&nbsp; 220<br>
-Electro-magnet, One Coil&nbsp; 219<br>
-Electro-magnet, Plunger&nbsp; 220<br>
-Electro-magnet, Polarized&nbsp; 220<br>
-Electro-magnets, Interlocking&nbsp;&nbsp; 221<br>
-Electro-magnets, Multiple Wire Method of Working&nbsp;&nbsp; 388<br>
-Electro-magnet, Stopped Coil&nbsp; 221<br>
-Electro-magnets, Surgical&nbsp;&nbsp; 222<br>
-Electro-mechanical Bell&nbsp; 80<br>
-Electro-mechanical Equivalent&nbsp; 244<br>
-Electro-medical Baths&nbsp; 222<br>
-Electro-medical Battery, Pulvermacher's&nbsp; 69<br>
-Electro-metallurgy&nbsp; 222<br>
-Electrometer&nbsp; 222<br>
-Electrometer, Absolute&nbsp; 222<br>
-Electrometer. Attracted Disc&nbsp;&nbsp; 223<br>
-Electrometer, Capillary&nbsp; 224<br>
-Electrometer Gauge&nbsp; 226<br>
-Electrometer, Lane's&nbsp;&nbsp; 226<br>
-Electrometer, Quadrant&nbsp;&nbsp; 226<br>
-Electrometer, Thermo-&nbsp;&nbsp; 536<br>
-Electrometer, Weight&nbsp; 223<br>
-Electro-motive Force&nbsp; 227<br>
-Electro-motive Force, Counter-&nbsp;&nbsp; 228<br>
-Electro-motive Force Curve&nbsp; 170<br>
-Electro-motive Force, Impressed&nbsp;&nbsp; 297<br>
-Electro-motive Force, Motor&nbsp; 384<br>
-Electro-motive Force. Oscillatory&nbsp; 398<br>
-Electro-motive Force, Transverse&nbsp; 549<br>
-Electro-motive Force, Unit&nbsp;&nbsp; 228<br>
-Electro-motive Intensity&nbsp; 228<br>
-Electro-motive Potential Difference&nbsp; 429<br>
-Electro-motive Series&nbsp; 228<br>
-Electro-motograph&nbsp; 229<br>
-Electro-motor&nbsp; 229<br>
-Electro-muscular Excitation&nbsp; 229<br>
-Electro-negative&nbsp;&nbsp; 229<br>
-Electro-optics&nbsp; 229<br>
-Electrophoric Action&nbsp; 230<br>
-Electrophorus&nbsp; 230<br>
-Electro-physiology&nbsp; 231<br>
-Electroplating&nbsp; 231, 418<br>
-Electroplating Dynamo&nbsp; 198<br>
-Electro-pneumatic Signals&nbsp; 231<br>
-Electropoion Fluid&nbsp; 232<br>
-Electro-positive&nbsp; 232<br>
-Electro-puncture&nbsp; 232<br>
-Electro-receptive&nbsp; 232<br>
-Electroscope&nbsp; 232<br>
-Electroscope, Bennett's&nbsp;&nbsp; 233<br>
-Electroscope, Bohenberger's&nbsp;&nbsp; 233<br>
-Electroscope, Condensing&nbsp; 233<br>
-Electroscope, Gold Leaf&nbsp;&nbsp; 233<br>
-Electroscope, Pith Ball&nbsp; 234<br>
-Electrostatic Attraction and Repulsion&nbsp; 234<br>
-Electrostatic Attraction and Repulsion. Coulomb's Law of&nbsp;&nbsp; 155<br>
-Electrostatic Circuit&nbsp; 123<br>
-Electrostatic Equipotential Surface&nbsp; 244<br>
-Electrostatic Field of Force&nbsp; 254<br>
-Electrostatic Force&nbsp; 260<br>
-Electrostatic Induction&nbsp; 302<br>
-Electrostatic Induction, Coefficient of&nbsp;&nbsp; 234<br>
-Electrostatic Induction, Mutual&nbsp;&nbsp; 303<br>
-Electrostatic Lines of Force&nbsp; 234<br>
-Electrostatic Quantity&nbsp; 445<br>
-Electrostatic Refraction&nbsp; 235<br>
-Electrostatics&nbsp; 235<br>
-Electrostatic Series&nbsp; 235<br>
-Electrostatic Stress&nbsp; 236, 496<br>
-Electrostatic Telephone&nbsp; 526<br>
-Electrostatic Voltmeter&nbsp; 571<br>
-Electro-thermal Equivalent&nbsp; 245<br>
-Electro-therapeutics or Therapy&nbsp; 236<br>
-Electrotonic State&nbsp; 493<br>
-Electrotonus&nbsp; 236<br>
-Electrotype&nbsp; 236<br>
-Element, Chemical&nbsp;&nbsp; 236<br>
-Element, Galvanic&nbsp; 264<br>
-Element, Mathematical&nbsp;&nbsp; 237<br>
-Element, Negative&nbsp; 390<br>
-Element of a Battery Cell&nbsp; 237<br>
-Element, Positive&nbsp; 277<br>
-Elements, Electrical Classification of&nbsp;&nbsp; 237<br>
-Elements, Magnetic&nbsp;&nbsp; 342<br>
-Elements of Battery&nbsp; 63<br>
-Elements, Thermo-electric&nbsp;&nbsp; 237<br>
-Element, Voltaic&nbsp; 237<br>
-Elias' Method of Magnetization&nbsp; 360<br>
-Elongation&nbsp; 237, 540<br>
-Elongation, Magnetic&nbsp;&nbsp; 344<br>
-Embosser, Telegraph&nbsp;&nbsp; 237<br>
-E. M. D. P.&nbsp; 238<br>
-E. M. F.&nbsp; 238<br>
-Energy&nbsp; 238<br>
-Energy, Atomic&nbsp; 238<br>
-Energy, Chemical&nbsp; 239<br>
-Energy, Conservation of&nbsp;&nbsp;&nbsp; 239<br>
-Energy, Degradation of&nbsp;&nbsp; 239<br>
-Energy, Electric&nbsp; 239<br>
-Energy, Electrical, Coefficient of&nbsp;&nbsp; 205<br>
-Energy, Electric Transmission of&nbsp;&nbsp; 240<br>
-Energy, Electro-magnetic, Unit of&nbsp;&nbsp; 220<br>
-Energy, Kinetic&nbsp; 241<br>
-Energy, Mechanical&nbsp;&nbsp; 241<br>
-Energy Meter&nbsp; 375<br>
-Energy, Molar&nbsp; 241<br>
-Energy, Molecular&nbsp;&nbsp; 241<br>
-Energy of an Electrified Body&nbsp; 241<br>
-Energy of Dielectric&nbsp; 183<br>
-Energy of Position&nbsp; 211<br>
-Energy of Stress&nbsp; 241<br>
-Energy, Physical&nbsp;&nbsp; 241<br>
-Energy, Potential, or Static&nbsp;&nbsp; 241<br>
-Energy, Radiant&nbsp;&nbsp;&nbsp; 446<br>
-Energy, Thermal&nbsp;&nbsp; 242<br>
-End-on Method&nbsp; 238<br>
-End or Pole, Marked&nbsp; 368<br>
-Endosmose, Electric&nbsp;&nbsp; 238<br>
-End Play&nbsp; 238<br>
-End, Unmarked&nbsp;&nbsp; 556<br>
-English Absolute or Foot Second Unit of Resistance&nbsp; 465<br>
-Engraving, Electric&nbsp;&nbsp; 245<br>
-Entropy&nbsp; 242<br>
-Entropy, Electric&nbsp; 242<br>
-Epinus Condenser&nbsp; 242<br>
-E. P. S.&nbsp; 243<br>
-Equator, Magnetic&nbsp;&nbsp; 344<br>
-Equator of Magnet&nbsp;&nbsp; 337<br>
-Equipotential&nbsp; 244<br>
-Equipotential Surface&nbsp; 498<br>
-Equipotential Surface, Electrostatic&nbsp; 244<br>
-Equipotential Surface, Magnetic and Electro-magnetic&nbsp;&nbsp; 244<br>
-Equalizer&nbsp; 243<br>
-Equalizer, Feeder&nbsp; 251<br>
-Equalizing Dynamo&nbsp; 198<br>
-Equivalent, Chemical&nbsp;&nbsp; 116, 244<br>
-Equivalent Conductors&nbsp; 146<br>
-Equivalent, Electro-thermal&nbsp;&nbsp; 245<br>
-Equivalent, Joule's&nbsp; 311<br>
-Equivalent Resistance&nbsp; 465<br>
-Equivalents, Electro-chemical&nbsp; 209, 244<br>
-Equivalent, Thermo-chemical&nbsp;&nbsp; 245<br>
-Equivalent, Water&nbsp;&nbsp; 572<br>
-Equivolt&nbsp; 245<br>
-Erb's Standard of Electrodes&nbsp; 210<br>
-Erg&nbsp;&nbsp; 245<br>
-Erg-ten&nbsp; 245<br>
-Error, Heating&nbsp; 286<br>
-Escape&nbsp; 245<br>
-Essential Resistance&nbsp; 465, 466<br>
-Etching, Electric&nbsp;&nbsp; 245<br>
-Ethene&nbsp; 397<br>
-Ether&nbsp; 246<br>
-Eudiometer&nbsp;&nbsp; 246<br>
-Evaporation, Electric&nbsp; 246<br>
-Ewing's Theory of Magnetism&nbsp; 356<br>
-Exchange, Telephone&nbsp; 246<br>
-Excitation, Electro-muscular&nbsp;&nbsp; 229<br>
-Excitability, Faradic&nbsp;&nbsp; 246<br>
-Excitability, Galvanic&nbsp;&nbsp; 247<br>
-Excitability of Animal System, Electric&nbsp;&nbsp; 247<br>
-Exciter&nbsp; 247<br>
-Exosmose, Electric&nbsp; 247<br>
-Expansion, Coefficient of&nbsp;&nbsp; 247<br>
-Expansion, Electric&nbsp; 247<br>
-Experiment, Franklin's&nbsp;&nbsp; 261<br>
-Experiment, Hall's&nbsp;&nbsp; 284<br>
-Experiment, Kerr's&nbsp; 312<br>
-Experiment, Matteueci's&nbsp;&nbsp; 369<br>
-Experiments, Hertz's&nbsp; 470<br>
-Experiment, Volta's Fundamental&nbsp; 567<br>
-Experiment with Frog, Galvani's&nbsp;&nbsp; 262<br>
-Exploder&nbsp; 247<br>
-Explorer&nbsp; 247<br>
-Exploring Coil&nbsp; 350<br>
-Explosive Distance&nbsp; 190<br>
-Extension Bell Call&nbsp; 248<br>
-Extension, Polar&nbsp; 423<br>
-External Characteristic&nbsp; 114<br>
-External Characteristic Curve&nbsp; 171<br>
-External Circuit&nbsp; 123<br>
-External Resistance&nbsp; 465, 467<br>
-Extinguisher, Automatic Electric Fire&nbsp;&nbsp;&nbsp; 257<br>
-Extra Current&nbsp; 162<br>
-Extra-polar Region&nbsp; 454<br>
-Eye, Electro-magnetic&nbsp; 248<br>
-Eye, Selenium&nbsp; 478<br>
-<br>
-Facsimile Telegraph&nbsp; 510<br>
-Factor, Armature&nbsp;&nbsp; 45<br>
-Fahrenheit Scale&nbsp; 248<br>
-Fall of Potential&nbsp; 430<br>
-False Poles, Magnetic&nbsp;&nbsp; 350<br>
-Farad&nbsp; 248<br>
-Faraday, Effect&nbsp;&nbsp; 249<br>
-Faraday's Cube&nbsp; 249<br>
-Faraday's Dark Space&nbsp; 249, 489<br>
-Faraday's Disc&nbsp; 249<br>
-Faraday's Net&nbsp; 250<br>
-Faraday's Ring&nbsp; 473<br>
-Faraday's Transformer&nbsp; 250<br>
-Faraday's Voltameter&nbsp; 250<br>
-Faradic&nbsp; 250<br>
-Faradic Battery&nbsp; 63<br>
-Faradic Brush&nbsp; 251<br>
-Faradic Current&nbsp; 162<br>
-Faradic Excitability&nbsp; 246<br>
-Faradization&nbsp;&nbsp; 251<br>
-Faradization, Galvano-&nbsp; 265<br>
-Far Leading Dynamo&nbsp; 198<br>
-Fault of a Dynamo, Ironwork&nbsp;&nbsp; 308<br>
-Faults&nbsp; 251<br>
-Faults, Contact&nbsp;&nbsp; 147<br>
-Feed Clockwork&nbsp; 128<br>
-Feeder&nbsp; 251<br>
-Feeder, Equalizer&nbsp;&nbsp; 251<br>
-Feeder, Main or Standard&nbsp;&nbsp; 251<br>
-Feeder, Negative&nbsp;&nbsp; 251<br>
-Feeder, Neutral&nbsp;&nbsp; 251<br>
-Feeder, Positive&nbsp;&nbsp; 251<br>
-Feeder, Switch&nbsp;&nbsp; 500<br>
-Feet, Ampere&nbsp;&nbsp; 30<br>
-Ferranti Effect&nbsp; 251<br>
-Ferric Chloride Battery&nbsp; 63<br>
-Ferro-magnetic&nbsp; 252<br>
-Fibre and Spring Suspension&nbsp;&nbsp; 252<br>
-Fibre Suspension&nbsp; 252<br>
-Field, Air&nbsp; 252<br>
-Field, Alternating&nbsp;&nbsp; 252<br>
-Field and Armature Reaction of Dynamo,&nbsp; 450<br>
-Field, Controlling&nbsp;&nbsp;&nbsp; 148<br>
-Field, Deflecting&nbsp;&nbsp; 178<br>
-Field Density&nbsp; 252<br>
-Field, Distortion of&nbsp;&nbsp; 252<br>
-Field, Drag of&nbsp; 254<br>
-Field, Intensity of a Magnetic&nbsp;&nbsp; 306<br>
-Field Magnet&nbsp; 337<br>
-Field of Force&nbsp; .&nbsp; 254<br>
-Field of Force, Electro-magnetic&nbsp; 218<br>
-Field of Force, Electrostatic&nbsp;&nbsp; 254<br>
-Field of Force, Magnetic&nbsp;&nbsp; 344<br>
-Field of Force of a Current&nbsp; 255<br>
-Field of Force, Uniform&nbsp;&nbsp; 553<br>
-Field, Pulsatory&nbsp;&nbsp; 256<br>
-Field, Rotating&nbsp;&nbsp; 256<br>
-Field, Stray&nbsp; 256, 495<br>
-Field, Uniform&nbsp; 256<br>
-Field, Uniform Magnetic&nbsp;&nbsp; 345<br>
-Field, Waste&nbsp;&nbsp; 256<br>
-Figure of Merit&nbsp; 256<br>
-Figures, Haldat's&nbsp;&nbsp; 284<br>
-Figures, Lichtenberg's&nbsp;&nbsp; 327<br>
-Figures, Magnetic&nbsp;&nbsp; 345<br>
-Filament&nbsp; 256<br>
-Filament, Magnetic&nbsp;&nbsp; 345<br>
-Filaments, Paper&nbsp;&nbsp; 402<br>
-File, Circuit Breaker&nbsp;&nbsp; 121<br>
-Finder, Position&nbsp;&nbsp; 427<br>
-Finder, Range&nbsp;&nbsp; 447<br>
-Finder, Wire&nbsp; 580<br>
-Fire Alarm, Electric Automatic&nbsp; 257<br>
-Fire and Heat Alarm&nbsp; 17<br>
-Fire Extinguisher, Electric Automatic&nbsp; 257<br>
-Fire Cleansing&nbsp; 257<br>
-Fire, St. Elmo's&nbsp;&nbsp; 494<br>
-Fishing Box&nbsp; 311<br>
-Flashing in a Dynamo or Magneto-Electric Generator&nbsp; 257<br>
-Flashing of Incandescent Lamp Carbons&nbsp; 257<br>
-Flashing Over&nbsp; 258<br>
-Flash, Side&nbsp;&nbsp; 484<br>
-Flat Cable&nbsp; 96<br>
-Flat Coil&nbsp; 133<br>
-Flat Ring Armature&nbsp; 45<br>
-Flats&nbsp; 258<br>
-Flats in Commutator&nbsp; 140<br>
-Flexible Cord&nbsp; 152<br>
-Floating Battery, De la Rive's&nbsp;&nbsp; 179<br>
-Floating Magnets, Meyer's&nbsp; 370<br>
-Floor Matting, Electric&nbsp; 369<br>
-Floor Push&nbsp; 258<br>
-Fluid, Depolarizing&nbsp;&nbsp; 258<br>
-Fluid, Electric&nbsp; 258<br>
-Fluid, Electropoion&nbsp;&nbsp; 232<br>
-Fluid, Insulator.&nbsp;&nbsp; 306<br>
-Fluid, North Magnetic&nbsp;&nbsp; 357<br>
-Fluids, Magnetic&nbsp; 345<br>
-Fluid, South Magnetic&nbsp; 356<br>
-Fluid Theory, Single&nbsp;&nbsp; 486<br>
-Fluorescence&nbsp; 258<br>
-Flush Boxes&nbsp; 258<br>
-Fluviograph&nbsp; 259<br>
-Flux, Magnetic&nbsp; 345<br>
-Fly or Flyer, Electric&nbsp;&nbsp; 259<br>
-Foci Magnetic&nbsp; 259<br>
-Fog, Electric&nbsp; 259<br>
-Following Horns&nbsp; 259<br>
-Foot-candle&nbsp; 259<br>
-Foot, Mil-&nbsp; 379<br>
-Foot-pound&nbsp; 259<br>
-Foot-step&nbsp; 259<br>
-Force&nbsp; 259<br>
-Force, Annular&nbsp; 544<br>
-Force, Axial&nbsp; 544<br>
-Force, Centrifugal&nbsp;&nbsp; 112<br>
-Force, Coercive or Coercitive&nbsp;&nbsp; 131-471<br>
-Force, Controlling&nbsp; 148<br>
-Force, Counter-electro-motive&nbsp;&nbsp; 156<br>
-Force de Cheval&nbsp; 260<br>
-Force, Electro-magnetic&nbsp; 260<br>
-Force, Electro-motive&nbsp;&nbsp; 227<br>
-Force, Electro-motive, Transverse&nbsp;&nbsp; 549<br>
-Force, Electrostatic&nbsp;&nbsp; 260<br>
-Force, Field of&nbsp; 254<br>
-Force, Field of, of a Current&nbsp;&nbsp; 255<br>
-Force, Field of, Electrostatic&nbsp; 254<br>
-Force, Kapp Line of&nbsp;&nbsp; 312<br>
-Force, Lines of&nbsp; 330<br>
-Force, Magnetic&nbsp; 346<br>
-Force, Magnetic Field of&nbsp;&nbsp; 344<br>
-Force, Magnetic Lines of&nbsp;&nbsp; 348<br>
-Force, Magneto-motive&nbsp; 365<br>
-Force, Motor Electro-motive&nbsp;&nbsp; 384<br>
-Force of Polarization, Back Electro-motive&nbsp; 156<br>
-Force, Oscillatory, Electro-motive&nbsp;&nbsp; 398<br>
-Force, Photo-electro-motive&nbsp;&nbsp; 410<br>
-Forces, Composition of&nbsp;&nbsp; 260<br>
-Forces, Parallelogram of&nbsp;&nbsp; 260<br>
-Forces, Resolution of&nbsp; 261<br>
-Force, True Contact&nbsp;&nbsp; 549<br>
-Force, Tubes of&nbsp;&nbsp; 261<br>
-Force, Unit of&nbsp; 261<br>
-Forked Circuits&nbsp; 126<br>
-Fork, Tuning, Dynamo&nbsp;&nbsp; 202<br>
-Forming&nbsp; 261<br>
-Formula of Merit&nbsp; 256<br>
-Foucault Current&nbsp; 163<br>
-Foundation Ring&nbsp; 261<br>
-Fourth State of Matter&nbsp; 261<br>
-Frame&nbsp; 261<br>
-Frame, Resistance&nbsp;&nbsp; 465<br>
-Franklinic Current&nbsp; 163<br>
-Franklin's Experiment&nbsp; 261<br>
-Franklin's Plate&nbsp; 262<br>
-Franklin's Theory&nbsp; 262-486<br>
-Free Charge&nbsp; 115<br>
-Free Magnetism&nbsp; 356<br>
-Frequency&nbsp; 262<br>
-Frequency, High&nbsp; 289<br>
-Frictional Electricity&nbsp; 262<br>
-Frictional Electric Machine&nbsp; 333<br>
-Frictional Heating&nbsp; 262<br>
-Friction Gear, Magnetic&nbsp;&nbsp; 276<br>
-Friction, Magnetic&nbsp; 295-346<br>
-Fringe&nbsp; 262<br>
-Frog, Galvani's Experiment with&nbsp;&nbsp; 262<br>
-Frog, Rheoscopic&nbsp;&nbsp; 262<br>
-Frying&nbsp; 263<br>
-Fulgurite&nbsp; 263<br>
-Fuller's Battery&nbsp; 63<br>
-Fulminating Pane&nbsp; 262<br>
-Fundamental Unit&nbsp; 554<br>
-Furnace, Electric&nbsp;&nbsp; 263<br>
-Fuse Block&nbsp; 175<br>
-Fuse Board&nbsp; 263<br>
-Fuse Box&nbsp; 263<br>
-Fuse, Cockburn&nbsp;&nbsp; 263<br>
-Fuse, Electric&nbsp;&nbsp; 264<br>
-Fuse Links&nbsp; 330<br>
-Fuse, Safety&nbsp;&nbsp; 175-475<br>
-<br>
-Galvanic&nbsp; 264<br>
-Galvanic Action, Volta's Law of&nbsp; 568<br>
-Galvanic Dosage&nbsp; 190<br>
-Galvanic Element&nbsp; 264<br>
-Galvanic Excitability&nbsp; 247<br>
-Galvanic or Voltaic Battery&nbsp; 76<br>
-Galvanic or Voltaic Circle&nbsp; 119<br>
-Galvanic or Voltaic Couple&nbsp; 156<br>
-Galvanic Polarization&nbsp; 265<br>
-Galvani's Experiment with Frog&nbsp; 262<br>
-Galvanism&nbsp; 265<br>
-Galvanization&nbsp; 265<br>
-Galvanization, Labile&nbsp;&nbsp; 265<br>
-Galvanized Iron&nbsp; 265<br>
-Galvano-cautery&nbsp; 109<br>
-Galvano-cautery, Chemical&nbsp;&nbsp; 265<br>
-Galvano-electric Cautery&nbsp; 109<br>
-Galvano-faradization&nbsp; 265<br>
-Galvanometer&nbsp; 265<br>
-Galvanometer, Absolute&nbsp;&nbsp; 266<br>
-Galvanometer, Aperiodic&nbsp;&nbsp; 266<br>
-Galvanometer, Astatic&nbsp;&nbsp; 266<br>
-Galvanometer, Ballistic&nbsp;&nbsp; 267<br>
-Galvanometer Constant&nbsp; 268<br>
-Galvanometer, Differential&nbsp;&nbsp; 268<br>
-Galvanometer, Direct Reading&nbsp;&nbsp; 269<br>
-Galvanometer, Marine&nbsp;&nbsp; 269<br>
-Galvanometer, Mirror&nbsp;&nbsp; 271<br>
-Galvanometer, Potential&nbsp; 269<br>
-Galvanometer, Proportional&nbsp;&nbsp; 269<br>
-Galvanometer, Quantity&nbsp;&nbsp; 269<br>
-Galvanometer, Reflecting&nbsp;&nbsp; 270<br>
-Galvanometer, Shunt&nbsp;&nbsp; 271-483<br>
-Galvanometer, Sine&nbsp; 271<br>
-Galvanometer, Tangent&nbsp;&nbsp;&nbsp; 272<br>
-Galvanometer, Torsion&nbsp;&nbsp; 273-544<br>
-Galvanometer, Upright&nbsp;&nbsp; 274<br>
-Galvanometer, Vertical&nbsp; 274<br>
-Galvanometer, Volt and Ampere Meter&nbsp; 274<br>
-Galvano-plastics&nbsp;&nbsp; 275<br>
-Galvano-puncture&nbsp; 232-275<br>
-Galvanoscope&nbsp; 275<br>
-Galvano-thermal Cautery&nbsp; 100<br>
-Gap, Spark&nbsp;&nbsp; 490<br>
-Gas Battery&nbsp; 63<br>
-Gas Battery, Grove's&nbsp;&nbsp; 281<br>
-Gas Burner, Electric&nbsp;&nbsp; 93<br>
-Gas, Carbonic Acid&nbsp;&nbsp; 108<br>
-Gas, Electrolytic&nbsp; 275<br>
-Gases, Magnetism of&nbsp;&nbsp; 357<br>
-Gases, Mixed&nbsp; 275<br>
-Gas Jet, Carcel&nbsp;&nbsp; 108<br>
-Gas, Olefiant&nbsp; 397<br>
-Gassing&nbsp;&nbsp; 275<br>
-Gassiot s Cascade&nbsp; 275<br>
-Gastroscope&nbsp; 275<br>
-Gas Voltameter&nbsp; 564<br>
-Gauge, Battery&nbsp; 64<br>
-Gauge, Electrometer&nbsp;&nbsp; 226<br>
-Gauss&nbsp; 275<br>
-Gauss' Principle&nbsp; 276<br>
-Gauss, Tangent Positions of&nbsp;&nbsp; 276<br>
-Gauze Brush, Wire&nbsp; 92<br>
-Gear, Magnetic&nbsp; 346<br>
-Gear, Magnetic Friction&nbsp;&nbsp;&nbsp; 276<br>
-Geissler Pump&nbsp; 437<br>
-Geissler Tubes&nbsp; 276<br>
-Generating Plate&nbsp; 277<br>
-Generator, Current&nbsp;&nbsp; 277<br>
-Generator Inductor&nbsp; 199<br>
-Generator, Magneto-electric&nbsp; 362<br>
-Generator, Magneto-electric, Flashing in a Dynamo or&nbsp;&nbsp; 257<br>
-Generator, Motor&nbsp; 384<br>
-Generator, Pyromagnetic.&nbsp;&nbsp; 442<br>
-Generators and Motors, Commutator of Current&nbsp; 140<br>
-Generator, Secondary&nbsp;&nbsp; 277-477<br>
-Geographic Meridian&nbsp; 372<br>
-German Mile Unit of Resistance&nbsp; 466<br>
-German Silver&nbsp; 277<br>
-German Standard Candle&nbsp; 99<br>
-Gilding, Electro-&nbsp; 277<br>
-Gilding Metal&nbsp;&nbsp; 277<br>
-Gimbals&nbsp; 278<br>
-Girder Armature&nbsp; 49<br>
-Glass&nbsp; 278<br>
-Globe or Globular Lightning&nbsp; 330<br>
-Glow Discharge&nbsp; 187<br>
-Gold&nbsp; 278<br>
-Gold Bath&nbsp; 279<br>
-Gold Leaf Electroscope&nbsp; 233<br>
-Gold Stripping Bath&nbsp; 279<br>
-Governor, Centrifugal&nbsp;&nbsp; 113<br>
-Governor, Rate&nbsp;&nbsp; 449<br>
-Graduator&nbsp; 279<br>
-Gram&nbsp; 280<br>
-Gram-atom&nbsp; 280<br>
-Gram-molecule&nbsp; 280<br>
-Graphite&nbsp; 280<br>
-Gravitation&nbsp; 280<br>
-Gravity, Acceleration of&nbsp;&nbsp; 280<br>
-Gravity Ammeter&nbsp; 27<br>
-Gravity Battery&nbsp; 64<br>
-Gravity, Centre of&nbsp;&nbsp; 112<br>
-Gravity Control&nbsp; 281<br>
-Gravity Drop Annunciator&nbsp; 35<br>
-Grease Spot&nbsp; 92<br>
-Green Vitriol&nbsp; 562<br>
-Grenet Battery&nbsp; 65<br>
-Grid&nbsp; 281<br>
-Grid Plug&nbsp;&nbsp; 420<br>
-Grip, Cable&nbsp;&nbsp; 96<br>
-Gross Efficiency&nbsp; 205<br>
-Ground&nbsp; 281<br>
-Grounded Circuit&nbsp; 123<br>
-Ground Plate&nbsp; 417<br>
-Ground Wire&nbsp; 281<br>
-Grove's Battery&nbsp; 65<br>
-Grove's Gas Battery&nbsp; 281<br>
-Guard Ring&nbsp; 282<br>
-Guard Tube&nbsp; 282<br>
-Gun, Electro-magnetic&nbsp;&nbsp; 282<br>
-Gutta Percha&nbsp; 282<br>
-Gyration, Centre of&nbsp;&nbsp; 112<br>
-Gyrostatic Action of Armatures&nbsp; 283<br>
-<br>
-H&nbsp;&nbsp; 283<br>
-H Armature&nbsp; 49<br>
-Haarlem Magnet&nbsp; 337<br>
-Hair, Removal of, by Electrolysis&nbsp;&nbsp; 283<br>
-Haldat's Figures&nbsp; 284<br>
-Hall Effect&nbsp; 284<br>
-Hall Effect, Real&nbsp; 284<br>
-Hall Effect, Spurious&nbsp;&nbsp; 284<br>
-Halleyan Lines&nbsp; 308<br>
-Hall's Experiment&nbsp; 284<br>
-Halske's and Siemens' Battery&nbsp; 72<br>
-Hand Hole&nbsp; 190<br>
-Hanger Board&nbsp; 284<br>
-Hanger, Cable&nbsp;&nbsp; 96<br>
-Hanger, Cable, Tongs&nbsp; 97<br>
-Harcourt's Pentane Standard&nbsp; 406<br>
-Hare's Deflagrator&nbsp; 73<br>
-Harmonic&nbsp;&nbsp; 23<br>
-Harmonic Curve&nbsp; 174, 485<br>
-Harmonic Motion, Simple&nbsp;&nbsp; 486<br>
-Harmonic Receiver&nbsp; 284, 451<br>
-Head Bath, Electric&nbsp;&nbsp; 284<br>
-Head-light, Electric&nbsp; 285<br>
-Head, Torsion&nbsp;&nbsp; 544<br>
-Heat&nbsp; 285<br>
-Heat and Fire Alarm&nbsp; 17<br>
-Heat, Atomic&nbsp;&nbsp; 52, 285<br>
-Heat, Electric&nbsp;&nbsp; 285<br>
-Heat, Electric, Convection of&nbsp;&nbsp; 149, 286<br>
-Heat, Irreversible.&nbsp; 286<br>
-Heat, Mechanical Equivalent of&nbsp; 286<br>
-Heat, Molecular&nbsp; 286<br>
-Heat, Specific&nbsp; 286<br>
-Heat, Specific, of Electricity&nbsp;&nbsp; 288<br>
-Heat Units&nbsp; 288<br>
-Heater, Electric&nbsp; 286<br>
-Heating, Admiralty Rules of&nbsp; 12<br>
-Heating Error&nbsp; 286<br>
-Heating, Frictional&nbsp;&nbsp; 262<br>
-Heating Magnet&nbsp; 286<br>
-Heavy Carburetted Hydrogen,&nbsp;&nbsp; 397<br>
-Hecto&nbsp; 288<br>
-Hedgehog Transformer&nbsp; 548<br>
-Heliograph&nbsp; 288<br>
-Helix&nbsp; 288<br>
-Henley's Universal Discharger&nbsp; 189<br>
-Henry&nbsp; 288<br>
-Henry's Coils&nbsp; 138<br>
-Hermetically Sealed&nbsp;&nbsp; 289<br>
-Hertz's Experiments&nbsp; 470<br>
-Heterostatic Method&nbsp; 280<br>
-Hexode Working&nbsp; 581<br>
-High Bars of Commutator&nbsp; 289<br>
-High Frequency&nbsp; 289<br>
-High Vacuum&nbsp; 557<br>
-Hinged Armature&nbsp; 45<br>
-Hinged Electro-magnet&nbsp; 217<br>
-Hissing&nbsp; 289<br>
-Hittorf's Resistance&nbsp; 466<br>
-Hittorf's Solution&nbsp; 289<br>
-Hoffer's Method of Magnetization&nbsp; 360<br>
-Hole Armature&nbsp; 45<br>
-Hole, Hand&nbsp;&nbsp; 190<br>
-Holders&nbsp; 289<br>
-Holder, Brush&nbsp;&nbsp; 91<br>
-Holder, Candle&nbsp;&nbsp; 99<br>
-Holders, Carbon&nbsp;&nbsp; 107<br>
-Holophote Lamp&nbsp; 321<br>
-Holtz's Influence Machine&nbsp; 334<br>
-Home Station&nbsp; 493<br>
-Hood&nbsp; 290<br>
-Horizontal Induction&nbsp; 302<br>
-Horns&nbsp; 290<br>
-Horns, Driving&nbsp;&nbsp; 132<br>
-Horns, Following&nbsp;&nbsp; 259<br>
-Horns, Leading&nbsp;&nbsp; 324<br>
-Horns, Trailing&nbsp;&nbsp; 259<br>
-Horse Power&nbsp; 290<br>
-Horse Power, Actual&nbsp;&nbsp; 290<br>
-Horse Power Curve&nbsp; 171<br>
-Horse Power, Electric&nbsp;&nbsp; 290<br>
-Horse Power Hour&nbsp; 290<br>
-Horse Power, Indicated&nbsp;&nbsp; 290<br>
-Horseshoe Magnet&nbsp; 337<br>
-Hour, Ampere-&nbsp; 30<br>
-Hour, Horse Power&nbsp;&nbsp; 290<br>
-H. P.&nbsp; 290<br>
-Hughes' Electro-magnet&nbsp; 291<br>
-Hughes' Induction Balance&nbsp; 291<br>
-Hughes' Sonometer&nbsp; 488<br>
-Hughes' Telegraph&nbsp;&nbsp; 511<br>
-Hughes' Theory of Magnetism&nbsp; 357<br>
-Hughes' Type Printer&nbsp; 511<br>
-Human Body, Resistance of&nbsp;&nbsp; 467<br>
-Hydrochloric Acid Battery&nbsp; 66<br>
-Hydro-electric&nbsp; 293<br>
-Hydro-electric Machine&nbsp; 293<br>
-Hydrogen&nbsp; 294<br>
-Hydrogen, Carburetted, Heavy&nbsp; 397<br>
-Hydrometer, Beaum&eacute;&nbsp;&nbsp; 78<br>
-Hygrometer&nbsp; 294<br>
-Hyperbolic Logarithms&nbsp; 389<br>
-Hysteresis&nbsp; 295<br>
-Hysteresis, Magnetic&nbsp;&nbsp; 294<br>
-Hysteresis, Static&nbsp; 295<br>
-Hysteresis, Viscous&nbsp;&nbsp; 295, 356<br>
-<br>
-Idioelectrics&nbsp; 295<br>
-Idiostatic Method&nbsp; 295<br>
-Idle Coils&nbsp; 295<br>
-Idle Poles&nbsp; 296<br>
-Idle Wire&nbsp; 291<br>
-Igniter&nbsp; 296<br>
-I. H P.&nbsp; 296<br>
-Illuminating Power&nbsp; 296<br>
-Illuminating Power, Spherical&nbsp; 296<br>
-Illuminating Power, Standard of, Viole's&nbsp;&nbsp; 561<br>
-Illumination, Unit of&nbsp;&nbsp; 296<br>
-Image, Electric&nbsp; 296<br>
-Imbricated Conductor&nbsp; 146<br>
-Immersion, Simple&nbsp; 185<br>
-Impedance&nbsp; 297, 462<br>
-Impedance, Impulsive&nbsp;&nbsp; 297<br>
-Impedance, Oscillatory&nbsp;&nbsp; 297<br>
-Impressed Electro-motive Force&nbsp; 297<br>
-Impulse&nbsp; 297<br>
-Impulsive Discharge&nbsp; 188<br>
-Impulsive Impedance&nbsp; 297<br>
-In-and-out, Soaking&nbsp; 486<br>
-Incandescence, Electric&nbsp;&nbsp; 297<br>
-Incandescent Lamp&nbsp; 321<br>
-Incandescent Lamp Carbons, Flashing of&nbsp;&nbsp; 257<br>
-Incandescent Lamp, Chamber of&nbsp;&nbsp; 113<br>
-Incandescent Lamp, Life of&nbsp;&nbsp; 327<br>
-Incandescent Lamp, Three Filament&nbsp;&nbsp; 322<br>
-Inclination Compass&nbsp; 142<br>
-Inclination, Magnetic&nbsp;&nbsp; 346<br>
-Inclination Map&nbsp; 297<br>
-Inclination or Dip, Angle of&nbsp;&nbsp; 33<br>
-Incomplete Circuit&nbsp; 125<br>
-Increment Key&nbsp; 314<br>
-Independence of Currents in Parallel Circuits&nbsp; 297<br>
-India Rubber&nbsp; 102<br>
-Indicated Horse Power&nbsp; 290<br>
-Indicating Bell&nbsp;&nbsp; 80, 297<br>
-Indicator&nbsp; 298<br>
-Indicator, Circuit&nbsp; 298<br>
-Indicator, Throw-back&nbsp;&nbsp; 540<br>
-Indicator, Volt&nbsp; 568<br>
-Indifferent Electrode&nbsp; 210<br>
-Indifferent Point&nbsp; 421<br>
-Induced Current&nbsp; 163<br>
-Induced Magnetization, Coefficient of&nbsp; 354, 359<br>
-Inductance&nbsp; 298<br>
-Inductance Balance&nbsp; 293<br>
-Inductance Bridge&nbsp; 293<br>
-Induction, Anti-, Conductor&nbsp;&nbsp; 36<br>
-Induction, Back&nbsp; 55<br>
-Induction Balance, Hughes&nbsp; 291<br>
-Induction, Coefficient of Magnetic&nbsp; 349<br>
-Induction, Coefficient of Mutual&nbsp;&nbsp; 301<br>
-Induction, Coefficient of Self-&nbsp;&nbsp; 298<br>
-Induction Coil&nbsp; 133<br>
-Induction Coil, Inverted&nbsp;&nbsp; 136<br>
-Induction Coil, Telephone&nbsp;&nbsp; 137, 526<br>
-Induction, Cross&nbsp;&nbsp; 298<br>
-Induction Current&nbsp; 163<br>
-Induction, Electro-magnetic&nbsp;&nbsp; 218, 299<br>
-Induction, Electrostatic&nbsp; 302<br>
-Induction, Electrostatic, Coefficient of&nbsp; 234<br>
-Induction, Horizontal&nbsp;&nbsp; 302<br>
-Induction, Lateral&nbsp;&nbsp; 302<br>
-Induction, Lines of&nbsp;&nbsp; 330<br>
-Induction, Magnetic&nbsp;&nbsp; 302, 346<br>
-Induction, Magnetic, Apparent Coefficient of&nbsp; 346<br>
-Induction, Magnetic, Coefficient of&nbsp; 346<br>
-Induction, Magnetic Dynamic&nbsp;&nbsp; 347<br>
-Induction, Magnetic, Self-&nbsp; 352<br>
-Induction, Magnetic Static&nbsp;&nbsp; 347<br>
-Induction, Magnetic, Tube of&nbsp;&nbsp; 347<br>
-Induction, Mutual, Electro-magnetic&nbsp;&nbsp; 302<br>
-Induction, Mutual, Electrostatic&nbsp; 303<br>
-Induction, Open Circuit&nbsp;&nbsp; 303<br>
-Induction, Oscillatory&nbsp; 398<br>
-Induction Protector, Mutual&nbsp;&nbsp; 481<br>
-Induction, Self-&nbsp;&nbsp; 303<br>
-Induction Sheath&nbsp; 303<br>
-Induction. Unipolar&nbsp;&nbsp; 304<br>
-Induction, Unit of Self-&nbsp;&nbsp; 304<br>
-Induction, Vertical&nbsp; 304<br>
-Inductive Capacity, Magnetic&nbsp;&nbsp; 346, 349<br>
-Inductive Effect, Counter-&nbsp;&nbsp; 204<br>
-Inductive Resistance&nbsp; 466<br>
-Inductophone&nbsp; 304<br>
-Inductor&nbsp; 305<br>
-Inductor Dynamo&nbsp; 199<br>
-Inductor Generator&nbsp; 199<br>
-Inductor, Magneto-&nbsp; 363<br>
-Inductor, Pacinotti's&nbsp;&nbsp; 400<br>
-Inductorium&nbsp; 138<br>
-Inertia&nbsp; 305<br>
-Inertia, Electro-magnetic&nbsp;&nbsp; 305<br>
-Inertia, Magnetic&nbsp; 347<br>
-Infinity Plug&nbsp; 305, 420<br>
-Influence, Electric&nbsp;&nbsp; 305<br>
-Influence Machine&nbsp; 334<br>
-Influence Machine, Armature of&nbsp;&nbsp; 46<br>
-Influence Machine, Holtz&nbsp;&nbsp; 334<br>
-Influence, Magnetic&nbsp; 346<br>
-Installation&nbsp; 305<br>
-Instantaneous Capacity&nbsp; 102<br>
-Insulating Stool&nbsp; 305<br>
-Insulating Tape&nbsp; 305<br>
-Insulating Varnish&nbsp; 306<br>
-Insulation, Electric&nbsp;&nbsp; 305<br>
-Insulation, Magnetic&nbsp;&nbsp; 347<br>
-Insulation, Oil&nbsp; 396<br>
-Insulation Resistance&nbsp; 466<br>
-Insulator&nbsp; 306<br>
-Insulator Caps&nbsp; 306<br>
-Insulator, Fluid&nbsp;&nbsp; 306<br>
-Insulator, Line or Telegraph&nbsp;&nbsp; 306<br>
-Intensity&nbsp; 306<br>
-Intensity Armature&nbsp; 45<br>
-Intensity Current&nbsp; 163<br>
-Intensity, Electro-motive&nbsp;&nbsp; 228<br>
-Intensity, Magnetic&nbsp; 348<br>
-Intensity of a Magnetic Field&nbsp; 306<br>
-Intensity of Magnetization&nbsp; 360<br>
-Intensity, Poles of&nbsp; 426<br>
-Inter-air Space&nbsp; 489<br>
-Intercrossing&nbsp; 307<br>
-Interference, Armature&nbsp;&nbsp; 45<br>
-Interferric Space&nbsp; 489<br>
-Interior Pole Dynamo&nbsp; 191<br>
-Interlocking- Electro-magnets.&nbsp;&nbsp; 229<br>
-Intermediate Metals, Law of&nbsp;&nbsp; 323<br>
-Intermittent,&nbsp; 307<br>
-Internal Characteristic&nbsp; 114<br>
-Internal Resistance&nbsp; 466<br>
-lnterpolar Conductor&nbsp; 307<br>
-Interpolar Region&nbsp; 307<br>
-Interpolation&nbsp; 307<br>
-Interrupter, Electro-magnetic, for Tuning Fork&nbsp;&nbsp; 307<br>
-Intrinsic Efficiency&nbsp; 205<br>
-Invariable Calibration&nbsp;&nbsp; 97<br>
-Inverse Induced Current&nbsp; 163<br>
-Inverse Squares, Law of&nbsp;&nbsp; 323<br>
-Inversion, Thermo-electric&nbsp;&nbsp; 533<br>
-Ions&nbsp; 307<br>
-Iron&nbsp; 308<br>
-Ironclad Dynamo&nbsp; 200<br>
-Ironclad Electro-magnet,&nbsp;&nbsp; 219<br>
-Ironclad Magnet&nbsp; 356<br>
-Iron Disc Ammeter, Eccentric&nbsp;&nbsp; 27<br>
-Iron, Electrolytic&nbsp;&nbsp; 308<br>
-Iron, Galvanized&nbsp;&nbsp; 265<br>
-Ironwork Fault of a Dynamo&nbsp; 308<br>
-Irreversible Heat&nbsp; 286<br>
-Isochasmen Curve&nbsp; 171<br>
-Isochronism&nbsp; 308<br>
-Isoclinic Lines&nbsp; 308<br>
-Isoclinic Map&nbsp; 308<br>
-Isodynamic Lines&nbsp; 308<br>
-Isodynamic Map&nbsp; 308<br>
-Isoelectric Points&nbsp; 422<br>
-Isogonal Lines&nbsp; 308<br>
-Isogonic Map&nbsp; 309<br>
-Isolated Distribution&nbsp; 309<br>
-Isolated Plant&nbsp; 309<br>
-Isolated Supply&nbsp; 309<br>
-Isotropic&nbsp; 309<br>
-Isthmus Method of Magnetization&nbsp; 360<br>
-I. W. G.,&nbsp;&nbsp; 309<br>
-<br>
-J&nbsp; 309<br>
-Jablochkoff Candle&nbsp; 160<br>
-Jack. Spring-&nbsp; 492<br>
-Jacketed Magnet&nbsp; 356<br>
-Jacobi's Law&nbsp; 309<br>
-Jacobi's Method of Magnetization&nbsp; 360<br>
-Jacobi's Unit of Current&nbsp; 163<br>
-Jacobi's Unit of Resistance&nbsp;&nbsp; 466<br>
-Jamin Candle&nbsp; 100<br>
-Jar, Leyden&nbsp;&nbsp; 325<br>
-Jar, Lightning&nbsp;&nbsp; 330<br>
-Jar, Luminous&nbsp; 332<br>
-Jars, Leyden, Charging and Discharging&nbsp;&nbsp; 108<br>
-Jar, Unit&nbsp;&nbsp; 554<br>
-Jewelry&nbsp; 309<br>
-Joulad&nbsp; 311<br>
-Joule&nbsp; 311<br>
-Joule Effect&nbsp; 311<br>
-Joule's Electro-magnet&nbsp; 337<br>
-Joule's Equivalent,&nbsp;&nbsp; 311<br>
-Joint, American Twist&nbsp; 309<br>
-Joint, Britannia&nbsp;&nbsp; 309<br>
-Joint, Butt&nbsp;&nbsp; 310<br>
-Joint Current&nbsp; 160<br>
-Joint, Lap&nbsp; 310<br>
-Joint, Marriage&nbsp;&nbsp; 310<br>
-Joint, Resistance&nbsp;&nbsp; 464<br>
-Joints in Belts&nbsp; 311<br>
-Joint, Sleeve&nbsp;&nbsp; 310<br>
-Joint, Splayed&nbsp;&nbsp; 311<br>
-Junction Box&nbsp; 311<br>
-Junction, Thermo-electric&nbsp;&nbsp; 533<br>
-<br>
-K.&nbsp;&nbsp; 311<br>
-Kaolin&nbsp; 311<br>
-Kapp. Line of Force&nbsp;&nbsp; 312<br>
-Kathelectrotonus&nbsp; 312<br>
-Kathode&nbsp; 312<br>
-Kathodic Closure Contraction&nbsp; 312<br>
-Kathodic Duration Contraction&nbsp; 312<br>
-K. C. C.&nbsp; 312<br>
-K. D. C.&nbsp; 312<br>
-Kempe's Discharge Key&nbsp; 315<br>
-Keeper&nbsp; 312<br>
-Kerr Effect&nbsp; 235, 312<br>
-Kerr's Experiment&nbsp; 312<br>
-Key&nbsp; 313<br>
-Key Board&nbsp; 313<br>
-Key, Bridge&nbsp;&nbsp; 313<br>
-Key, Double Contact&nbsp; 314<br>
-Key, Double Tapper&nbsp; 314<br>
-Key, Charge and Discharge&nbsp;&nbsp; 313<br>
-Key, Increment&nbsp; 314<br>
-Key, Kempe's Discharge&nbsp;&nbsp; 315<br>
-Key, Magneto-electric&nbsp;&nbsp; 315<br>
-Key, Make and Break&nbsp;&nbsp; 316<br>
-Key, Plug&nbsp;&nbsp; 316<br>
-Key, Reversing&nbsp; 316<br>
-Key, Sliding-contact&nbsp;&nbsp; 316<br>
-Key, Telegraph&nbsp;&nbsp; 316<br>
-Kicking Coil&nbsp; 132<br>
-Kilo&nbsp; 316<br>
-Kilodyne&nbsp; 316<br>
-Kilogram&nbsp; 317<br>
-Kilojoule&nbsp; 317<br>
-Kilometer&nbsp; 317<br>
-Kilowatt&nbsp; 317<br>
-Kine&nbsp; 317<br>
-Kinnersley's Thermometer&nbsp; 536<br>
-Kinetics, Electro-&nbsp;&nbsp; 211<br>
-Kinetic Energy&nbsp; 241<br>
-Kirchoff's Laws&nbsp; 317<br>
-Knife Break Switch&nbsp; 501<br>
-Knife Edge Suspension&nbsp; 317<br>
-Knife Edge Switch&nbsp; 501<br>
-Knife Switch&nbsp; 501<br>
-Knot&nbsp; 317<br>
-Kohlrausch's Law&nbsp; 317<br>
-Kookogey's Solution&nbsp;&nbsp; 318<br>
-Krizik's Cores&nbsp; 318<br>
-<br>
-L&nbsp; 318<br>
-Lag, Angle of&nbsp;&nbsp; 33, 318<br>
-Lag, Electric&nbsp;&nbsp; 332<br>
-Lag, Magnetic&nbsp;&nbsp; 348<br>
-Lalande &amp; Chaperon Battery&nbsp; 69<br>
-Lalande-Edison Battery&nbsp; 69<br>
-Lamellar Distribution of Magnetism&nbsp; 357<br>
-Laminated&nbsp; 318<br>
-Laminated Core&nbsp; 154<br>
-Laminated Core, Tangentially&nbsp;&nbsp; 155<br>
-Lamination&nbsp; 318<br>
-Lamination of Armature Conductors&nbsp; 319<br>
-Lamination of Magnet&nbsp; 361<br>
-Lamp, Arc&nbsp; 319<br>
-Lamp, Arc, Double Carbon&nbsp;&nbsp; 191<br>
-Lamp Carbons, Flashing of Incandescent&nbsp;&nbsp; 257<br>
-Lamp, Carcel&nbsp;&nbsp; 108<br>
-Lamp, Contact&nbsp; 320<br>
-Lamp, Differential Arc&nbsp;&nbsp; 320<br>
-Lamp Globe, Waterproof&nbsp;&nbsp; 572<br>
-Lamp, Holophote&nbsp; 321<br>
-Lamp-hour&nbsp; 321<br>
-Lamp, Incandescent&nbsp;&nbsp; 321<br>
-Lamp, Incandescent, Chamber of&nbsp;&nbsp; 113<br>
-Lamp, Incandescent, Three Filament&nbsp; 322<br>
-Lamp, Life of Incandescent&nbsp;&nbsp; 327<br>
-Lamp, Lighthouse&nbsp;&nbsp; 322<br>
-Lamp, Monophote&nbsp;&nbsp; 321<br>
-Lamp, Pilot&nbsp; 323<br>
-Lamp, Polyphote&nbsp; 323<br>
-Lamp, Semi-Incandescent&nbsp;&nbsp; 323<br>
-Lamp-socket&nbsp; 323<br>
-Lamps, Bank of&nbsp; 323<br>
-Lane's Electrometer&nbsp; 226<br>
-Langdon Davies' Rate Governor or Phonophone&nbsp; 450<br>
-Lenz's Law&nbsp; 325<br>
-Lap Joint&nbsp; 310<br>
-Lap Winding&nbsp; 570<br>
-Latent Electricity&nbsp; 323<br>
-Lateral Discharge&nbsp; 188<br>
-Lateral Induction&nbsp; 302<br>
-Latitude, Magnetic&nbsp;&nbsp; 348<br>
-Law, Jacobi's&nbsp; 309<br>
-Law, Kohlrausch's&nbsp;&nbsp; 317<br>
-Law, Lenz's&nbsp; 325<br>
-Law of Angular Currents&nbsp; 165<br>
-Law of Electrolysis&nbsp; 213<br>
-Law of Intermediate Metals&nbsp; 323<br>
-Law of Inverse Squares&nbsp; 323<br>
-Law of Magnetic Attraction and Repulsion. Coulomb's&nbsp;&nbsp; 338<br>
-Law of Successive Temperatures&nbsp; 324<br>
-Law, Magnus'&nbsp;&nbsp; 367<br>
-Law, Ohm's&nbsp; 396<br>
-Law, Pfl&uuml;ger's.&nbsp;&nbsp; 409<br>
-Law, Right Handed Screw&nbsp; 324<br>
-Law, Sine&nbsp; 486<br>
-Laws, Kirchoff's&nbsp; 317<br>
-Laws of Thermo-electricity, Becquerel's&nbsp;&nbsp; 78<br>
-Law, Tangent&nbsp;&nbsp; 502<br>
-Law, Voltametric&nbsp;&nbsp; 567<br>
-Lead&nbsp; 324<br>
-Lead, Angle of&nbsp;&nbsp; 33<br>
-Lead Chloride Battery&nbsp; 66<br>
-Lead of Brushes&nbsp; 90<br>
-Lead of Brushes, Negative&nbsp; 324<br>
-Lead, Peroxide of, Battery&nbsp;&nbsp; 69<br>
-Lead Sulphate Battery&nbsp; 66<br>
-Lead Tee&nbsp; 504<br>
-Leading Horns&nbsp; 324<br>
-Leading-in Wires&nbsp; 324<br>
-Leak&nbsp; 324<br>
-Leakage&nbsp; 324<br>
-Leakage Conductor&nbsp; 325<br>
-Leakage, Electro-magnetic&nbsp;&nbsp; 219<br>
-Leakage, Magnetic.&nbsp;&nbsp; 348<br>
-Leakage, Surface&nbsp; 498<br>
-Leclanch&eacute; Agglomerate Battery&nbsp; 66<br>
-Leclanch&eacute; Battery&nbsp; 66<br>
-Leg of Circuit&nbsp; 325<br>
-Legal Ohm&nbsp; 395<br>
-Legal Quadrant&nbsp; 444<br>
-Legal Volt&nbsp; 568<br>
-Length of Spark&nbsp; 490<br>
-Letter Boxes, Electric&nbsp;&nbsp; 325<br>
-Leyden Jar&nbsp; 325<br>
-Leyden Jar, Armature of&nbsp;&nbsp; 46<br>
-Leyden Jars, Battery of&nbsp;&nbsp; 68<br>
-Leyden Jars, Charging and Discharging&nbsp; 108<br>
-Leyden Jars, Sir William Thomson's&nbsp;&nbsp; 326<br>
-Lichtenberg's Figures&nbsp; 327<br>
-Life Curve&nbsp; 171<br>
-Life of Incandescent Lamp&nbsp; 327<br>
-Light, Electro-magnetic, Theory of&nbsp;&nbsp; 219<br>
-Light, Maxwell's Theory of&nbsp; 369<br>
-Lighthouse Lamp&nbsp; 322<br>
-Lightning&nbsp; 327<br>
-Lightning Arrester&nbsp; 328<br>
-Lightning Arrester, Counter-electro-motive Force&nbsp; 329<br>
-Lightning Arrester Plates&nbsp; 329<br>
-Lightning Arrester, Vacuum&nbsp;&nbsp; 329<br>
-Lightning, Ascending&nbsp; 330<br>
-Lightning, Globe or Globular&nbsp;&nbsp; 330<br>
-Lightning Jar&nbsp; 330<br>
-Lightning, Back Stroke or Shock of&nbsp; 55<br>
-Lime, Chloride of, Battery&nbsp;&nbsp; 61<br>
-Limit, Magnetic&nbsp; 348<br>
-Limit of Magnetization&nbsp; 361<br>
-Linear Current&nbsp; 164<br>
-Lineman's Detector&nbsp; 180<br>
-Line of Commutator, Neutral&nbsp;&nbsp; 300<br>
-Line of Contact&nbsp; 330<br>
-Line of Force, Kapp&nbsp; 312<br>
-Line of Magnet, Neutral&nbsp; 361<br>
-Line or Telegraph Insulator&nbsp; 306<br>
-Lines, Halleyan&nbsp;&nbsp; 308<br>
-Lines, Isoclinic&nbsp; 308<br>
-Lines, Isodynamic&nbsp; 308<br>
-Lines, Isogonal&nbsp;&nbsp; 308<br>
-Lines, Isogonic&nbsp;&nbsp; 308<br>
-Lines of Force&nbsp; 330<br>
-Lines of Force, Cutting of&nbsp; 175<br>
-Lines of Force, Electro-magnetic&nbsp; 219<br>
-Lines of Force, Electrostatic&nbsp;&nbsp; 234<br>
-Lines of Force, Magnetic&nbsp;&nbsp; 348<br>
-Lines of Induction&nbsp; 330<br>
-Lines of Slope&nbsp; 330<br>
-Lines or Points of Least Sparking&nbsp; 490<br>
-Lines, Trunk&nbsp;&nbsp; 550<br>
-Links, Fuse&nbsp; 330<br>
-Liquids, Electro-dynamic Rotation of&nbsp;&nbsp; 474<br>
-Liquids, Electro-magnetic Rotation of&nbsp;&nbsp;&nbsp; 475<br>
-Liquor, Spent&nbsp;&nbsp; 491<br>
-Listening Cam&nbsp; 330<br>
-Lithanode&nbsp; 331<br>
-Load&nbsp; 331<br>
-Load Curve&nbsp; 172<br>
-Load of Armature&nbsp; 46<br>
-Local Action&nbsp; 331<br>
-Local Battery&nbsp; 331<br>
-Local Circuit&nbsp; 331<br>
-Local Currents&nbsp; 163, 331<br>
-Localization&nbsp; 331<br>
-Locus&nbsp; 331<br>
-Lodestone&nbsp; 332<br>
-Logarithm&nbsp; 332<br>
-Logarithms, Hyperbolic&nbsp;&nbsp; 389<br>
-Logarithms, Napierian&nbsp; 389<br>
-Local Battery&nbsp; 66<br>
-Long Coil Magnet&nbsp;&nbsp; 361<br>
-Long Range Electro-magnet&nbsp; 220<br>
-Long Shunt and Series Winding&nbsp; 579<br>
-Long Shunt Winding&nbsp; 579<br>
-Loop&nbsp; 332<br>
-Loop Break&nbsp; 332<br>
-Loop, Circuit&nbsp;&nbsp; 125<br>
-Loop, Drip&nbsp;&nbsp; 192<br>
-Lost Amperes&nbsp; 30<br>
-Lost Volts&nbsp; 571<br>
-Low Vacuum&nbsp; 557<br>
-Luces&nbsp; 332<br>
-Luminous Jar&nbsp; 332<br>
-Luminous Pane&nbsp; 401<br>
-Luminous Tube&nbsp; 550<br>
-Lux&nbsp; 332<br>
-<br>
-M&nbsp; 332<br>
-Machine, Cylinder Electric&nbsp; 333<br>
-Machine, Electric, Wimshurst&nbsp;&nbsp; 577<br>
-Machine, Frictional Electric&nbsp;&nbsp; 333<br>
-Machine, Holtz Influence&nbsp;&nbsp; 334<br>
-Machine, Hydro-electric&nbsp;&nbsp; 293<br>
-Machine, Influence&nbsp; 334<br>
-Machine, Nairne's Electrical&nbsp;&nbsp; 389<br>
-Machine, Plate Electrical&nbsp;&nbsp; 417<br>
-Machine, Rheostatic&nbsp; 472<br>
-Machine, Toeppler-Holtz&nbsp;&nbsp; 334<br>
-Machine, Wimshurst&nbsp; 335<br>
-Mack&nbsp; 335<br>
-Magic Circle&nbsp; 119<br>
-Magne-crystallic Action&nbsp; 335<br>
-Magnet&nbsp; 335<br>
-Magnet, Anomalous&nbsp;&nbsp; 335<br>
-Magnet, Artificial&nbsp; 335<br>
-Magnet, Axial&nbsp;&nbsp; 336<br>
-Magnet, Bar&nbsp; 336<br>
-Magnet, Bell Shaped&nbsp;&nbsp; 336<br>
-Magnet Coils, Sheath for&nbsp;&nbsp; 481<br>
-Magnet, Compensating&nbsp;&nbsp; 336<br>
-Magnet, Compound&nbsp;&nbsp; 336<br>
-Magnet, Controlling&nbsp;&nbsp; 185, 336<br>
-Magnet, Damping&nbsp;&nbsp; 336<br>
-Magnet, Deflection of&nbsp;&nbsp; 337<br>
-Magnet, Directing&nbsp;&nbsp; 185<br>
-Magnet, Electro-&nbsp;&nbsp; 215, 337<br>
-Magnet, Equator of&nbsp;&nbsp; 337<br>
-Magnet, Field&nbsp;&nbsp; 337<br>
-Magnet, Haarlem&nbsp;&nbsp; 337<br>
-Magnet, Heating&nbsp;&nbsp; 286<br>
-Magnet, Horseshoe&nbsp;&nbsp; 337<br>
-Magnet, Ironclad&nbsp;&nbsp; 356<br>
-Magnet, Joule's Electro-&nbsp;&nbsp; 337<br>
-Magnet-keeper&nbsp; 361<br>
-Magnet, Lamination of&nbsp;&nbsp; 361<br>
-Magnet, Long Coil&nbsp; 361<br>
-Magnet, Natural&nbsp; 361<br>
-Magnet, Neutral Line of&nbsp;&nbsp; 361<br>
-Magnet, Normal&nbsp;&nbsp; 361<br>
-Magnet Operation&nbsp; 365<br>
-Magnet, Permanent&nbsp; 365<br>
-Magnet Pole&nbsp; 365<br>
-Magnet, Portative Power of&nbsp;&nbsp; 366<br>
-Magnet, Projecting Power of a&nbsp;&nbsp; 435<br>
-Magnet, Relay&nbsp;&nbsp; 457<br>
-Magnet, Simple&nbsp;&nbsp; 366<br>
-Magnet, Solenoidal&nbsp;&nbsp; 366<br>
-Magnet, Sucking&nbsp;&nbsp; 366<br>
-Magnet, Unipolar&nbsp; 366<br>
-Magnet Coil&nbsp; 336<br>
-Magnet Core&nbsp; 336<br>
-Magnet Poles, Secondary&nbsp;&nbsp; 366<br>
-Magnet Pole, Unit&nbsp; 366<br>
-Magnetic Adherence&nbsp; 338<br>
-Magnetic and Electro-magnetic Equipotential Surface&nbsp; 244<br>
-Magnetic Attraction&nbsp; 338<br>
-Magnetic Attraction and Repulsion, Coulomb's Law of&nbsp;&nbsp; 338<br>
-Magnetic Axis&nbsp; 338<br>
-Magnetic Azimuth&nbsp; 338<br>
-Magnetic Battery&nbsp; 338<br>
-Magnetic Bridge&nbsp; 338<br>
-Magnetic Circuit&nbsp; 340<br>
-Magnetic Circuit, Curve of Saturation of&nbsp;&nbsp; 174<br>
-Magnetic Concentration of Ores&nbsp; 340<br>
-Magnetic Concentrator&nbsp; 340<br>
-Magnetic Continuity&nbsp; 340<br>
-Magnetic Conductance and Conductivity&nbsp; 340<br>
-Magnetic Control&nbsp; 341<br>
-Magnetic Couple&nbsp; 341<br>
-Magnetic Creeping&nbsp; 341<br>
-Magnetic Curves&nbsp; 341<br>
-Magnetic Cut Out&nbsp; 175<br>
-Magnetic Declination&nbsp; 342<br>
-Magnetic Density&nbsp; 342<br>
-Magnetic Dip&nbsp; 342, 346<br>
-Magnetic Discontinuity&nbsp; 342<br>
-Magnetic Double Circuit&nbsp; 340<br>
-Magnetic Eye, Electro-&nbsp;&nbsp; 248<br>
-Magnetic Elements&nbsp; 342<br>
-Magnetic Elongation&nbsp; 344<br>
-Magnetic Equator&nbsp; 344<br>
-Magnetic False Poles&nbsp; 350<br>
-Magnetic, Ferro-&nbsp; 252<br>
-Magnetic Field, Intensity of a&nbsp;&nbsp; 306<br>
-Magnetic Field of Force&nbsp; 344<br>
-Magnetic Field, Uniform&nbsp;&nbsp; 345<br>
-Magnetic Figures&nbsp; 345<br>
-Magnetic Filament&nbsp; 345<br>
-Magnetic Fluid, North&nbsp;&nbsp; 357<br>
-Magnetic Fluids&nbsp; 345<br>
-Magnetic Flux&nbsp; 345<br>
-Magnetic Force&nbsp; 346<br>
-Magnetic Friction&nbsp; 295, 346<br>
-Magnetic Friction Gear&nbsp;&nbsp; 276<br>
-Magnetic Fluid, South&nbsp;&nbsp; 356<br>
-Magnetic Foci&nbsp; 259<br>
-Magnetic Gear&nbsp; 346<br>
-Magnetic Hysteresis&nbsp; 294<br>
-Magnetic Inclination&nbsp; 346<br>
-Magnetic Induction&nbsp; 302<br>
-Magnetic Induction, Apparent Coefficient of&nbsp;&nbsp; 346<br>
-Magnetic Induction, Coefficient of&nbsp;&nbsp; 346-349<br>
-Magnetic Induction, Dynamic&nbsp;&nbsp; 347<br>
-Magnetic Induction, Static&nbsp;&nbsp; 347<br>
-Magnetic Induction, Tube of&nbsp;&nbsp; 347<br>
-Magnetic Inductive Capacity&nbsp; 349<br>
-Magnetic Inertia&nbsp; 347<br>
-Magnetic Influence&nbsp; 346<br>
-Magnetic Insulation&nbsp; 347<br>
-Magnetic Intensity&nbsp;&nbsp; 348<br>
-Magnetic Lag&nbsp; 348<br>
-Magnetic Latitude&nbsp; 348<br>
-Magnetic Leakage&nbsp; 348<br>
-'Magnetic Limit&nbsp; 348<br>
-Magnetic Lines of Force&nbsp; 348<br>
-Magnetic Mass&nbsp; 349<br>
-Magnetic Matter&nbsp; 349<br>
-Magnetic Memory&nbsp; 349<br>
-Magnetic Meridian&nbsp; 349<br>
-Magnetic Moment&nbsp; 349<br>
-Magnetic Needle&nbsp; 349<br>
-Magnetic Needle, Declination of the&nbsp; 178<br>
-Magnetic Needle, Dip of&nbsp;&nbsp; 185<br>
-Magnetic Needle, Oscillation of a&nbsp;&nbsp; 397<br>
-Magnetic Output&nbsp; 399<br>
-Magnetic Parallels&nbsp; 349<br>
-Magnetic Permeability&nbsp; 349<br>
-Magnetic Perturbations&nbsp; 350<br>
-Magnetic Poles&nbsp; 350<br>
-Magnetic Potential&nbsp; 350, 431<br>
-Magnetic Proof Piece&nbsp; 350<br>
-Magnetic Proof Plane&nbsp; 350<br>
-Magnetic Quantity&nbsp; 350<br>
-Magnetic Reluctance&nbsp; 351, 458<br>
-Magnetic Reluctivity&nbsp; 351<br>
-Magnetic Remanence&nbsp; 358<br>
-Magnetic Repulsion&nbsp; 338<br>
-Magnetic Resistance&nbsp; 458<br>
-Magnetic Retentivity&nbsp; 351<br>
-Magnetic Rotatory Polarization&nbsp; 351<br>
-Magnetic Saturation&nbsp; 251<br>
-Magnetic Screen&nbsp; 351<br>
-Magnetic Self-induction&nbsp; 352<br>
-Magnetic Separator&nbsp; 352<br>
-Magnetic Shell&nbsp; 352<br>
-Magnetic Shell, Strength of&nbsp;&nbsp; 352<br>
-Magnetic Shield&nbsp; 353<br>
-Magnetic Shunt&nbsp; 353<br>
-Magnetic Storms&nbsp; 353<br>
-Magnetic Strain&nbsp; 354<br>
-Magnetic Stress&nbsp; 354<br>
-Magnetic Susceptibility&nbsp; 254, 359<br>
-Magnetic Tick&nbsp; 354<br>
-Magnetic Top&nbsp; 542<br>
-Magnetic Twist&nbsp; 354<br>
-Magnetic Vane Ammeter&nbsp; 27<br>
-Magnetic Variations&nbsp; 354<br>
-Magnetism, Ampere's Theory of&nbsp;&nbsp; 354<br>
-Magnetism, Blue&nbsp; 355<br>
-Magnetism, Components of Earth's&nbsp;&nbsp; 356<br>
-Magnetism, Creeping of&nbsp;&nbsp; 356<br>
-Magnetism, Decay of&nbsp;&nbsp; 356<br>
-Magnetism, Discharge of&nbsp;&nbsp; 356<br>
-Magnetism, Electro&nbsp; 220<br>
-Magnetism, Ewing's Theory of&nbsp; 356<br>
-Magnetism, Free&nbsp;&nbsp; 356<br>
-Magnetism, Hughes' Theory of&nbsp; 357<br>
-Magnetism, Lamellar Distribution of&nbsp; 357<br>
-Magnetism of Gases&nbsp; 357<br>
-Magnetism, Red&nbsp; 357<br>
-Magnetism, Residual&nbsp; 358<br>
-Magnetism, Solenoidal Distribution of&nbsp;&nbsp; 358<br>
-Magnetism, Sub-permanent&nbsp;&nbsp; 358<br>
-Magnetism, Terrestrial&nbsp; 358<br>
-Magnetism, Weber's Theory of&nbsp;&nbsp; 358<br>
-Magnetization by the Earth&nbsp; 359<br>
-Magnetization by Double Touch&nbsp; 358<br>
-Magnetization by Separate Touch&nbsp; 359<br>
-Magnetization by Single Touch&nbsp; 359<br>
-Magnetization, Coefficient of Induced&nbsp; 359<br>
-Magnetization Curve&nbsp; 172<br>
-Magnetization, Cycle of&nbsp; 360<br>
-Magnetization, Elias' Method of&nbsp;&nbsp; 360<br>
-Magnetization, Hoffer's Method of&nbsp;&nbsp; 360<br>
-Magnetization, Intensity of&nbsp;&nbsp; 360<br>
-Magnetization, Isthmus Method of&nbsp; 360<br>
-Magnetization, Jacobi's Method&nbsp; 360<br>
-Magnetization, Limit of&nbsp; 361<br>
-Magnetization, Maximum&nbsp;&nbsp; 361<br>
-Magnetization, Specific&nbsp;&nbsp; 361<br>
-Magnetization, Surface&nbsp;&nbsp; 356<br>
-Magnetizing Coil&nbsp;&nbsp; 127<br>
-Magneto&nbsp; 361<br>
-Magneto Bell&nbsp; 80<br>
-Magneto Call Bell&nbsp; 361<br>
-Magneto-electric&nbsp; 361<br>
-Magneto-electric Brake&nbsp; 362<br>
-Magneto-electric Generator&nbsp; 362<br>
-Magneto-electric Generator, or Dynamo, Flashing in a&nbsp;&nbsp; 257<br>
-Magneto-electric Key&nbsp; 315<br>
-Magneto-electric Telegraph&nbsp; 512<br>
-Magnetograph&nbsp; 363<br>
-Magneto-inductor&nbsp; 363<br>
-Magnetometer&nbsp; 363<br>
-Magnetometer, Differential&nbsp;&nbsp; 365<br>
-Magnetometry&nbsp; 364<br>
-Magneto-motive Force&nbsp; 365<br>
-Magnetophone&nbsp; 367<br>
-Magnetoscope&nbsp; 365<br>
-Magnifying Spring Ammeter&nbsp; 28<br>
-Magnus' Law&nbsp; 367<br>
-Main Battery&nbsp; 66<br>
-Main Battery Circuit&nbsp; 125<br>
-Main Circuit&nbsp; 125<br>
-Main or Standard Feeder&nbsp; 251<br>
-Mains, Electric&nbsp;&nbsp; 367<br>
-Make&nbsp;&nbsp; 367<br>
-Make and Break Current&nbsp; 164, 367<br>
-Make and Break Key&nbsp; 316<br>
-Make-induced Current&nbsp; 163<br>
-Malapterurus&nbsp; 367<br>
-Map, Declination&nbsp;&nbsp; 309<br>
-Map, Inclination&nbsp;&nbsp; 297<br>
-Map, Isoclinic&nbsp;&nbsp; 308<br>
-Map, Isodynamic&nbsp;&nbsp; 308<br>
-Map, Isogonic&nbsp; 309<br>
-Mari&eacute; Davy's Battery&nbsp; 67<br>
-Marine Galvanometer&nbsp; 269<br>
-Mariner's Compass&nbsp; 142<br>
-Marked End or Pole&nbsp; 368<br>
-Marriage Joint&nbsp; 310<br>
-Mass, Electric&nbsp;&nbsp; 368<br>
-Mass, Magnetic&nbsp;&nbsp; 349<br>
-Master Clock&nbsp; 127<br>
-Mathematical Element&nbsp; 237<br>
-Matteueci's Experiment&nbsp; 369<br>
-Matter, Electric&nbsp; 368<br>
-Matter, Fourth State of&nbsp;&nbsp; 261<br>
-Matter, Magnetic&nbsp;&nbsp; 349<br>
-Matter, Radiant&nbsp; 368<br>
-Matter, Ultra Gaseous&nbsp; 551<br>
-Matthiessen's Meter-gram Standard Resistance,.&nbsp;&nbsp; 466<br>
-Matthiessen's Unit of Resistance&nbsp;&nbsp; 466<br>
-Matting, Electric Floor&nbsp;&nbsp; 369<br>
-Maximum Magnetization&nbsp; 361<br>
-Maxwell's Theory of Light&nbsp; 369<br>
-Mayer's Floating Magnet&nbsp; 370<br>
-Maynooth's Battery&nbsp; 67<br>
-Measurement, Absolute&nbsp;&nbsp; 8<br>
-Measurements&nbsp; 370<br>
-Mechanical Equivalent of Heat&nbsp; 286<br>
-Mechanical Energy&nbsp; 241<br>
-Mechanical Equivalent, Electro-&nbsp;&nbsp; 244<br>
-Medical Battery&nbsp; 67<br>
-Medium, Polarization of the&nbsp;&nbsp; 424<br>
-Meg or Mega&nbsp; 370<br>
-Meidinger's Battery&nbsp; 68<br>
-Memoria Technica, Amp&eacute;re's&nbsp;&nbsp; 30<br>
-Memory, Magnetic&nbsp;&nbsp; 349<br>
-Mercury&nbsp; 371<br>
-Mercury Bichromate, Battery&nbsp; 63<br>
-Mercury Circuit Breaker&nbsp; 121<br>
-Mercury Cups&nbsp; 371<br>
-Mercury, Sulphate of, Battery&nbsp;&nbsp; 67<br>
-Mercurial Air Pump&nbsp; 16<br>
-Meridian, Astronomical&nbsp;&nbsp; 372<br>
-Meridian, Geographic&nbsp;&nbsp; 372<br>
-Meridian, Magnetic.&nbsp;&nbsp; 349<br>
-Merit, Figure of&nbsp;&nbsp; 256<br>
-Merit, Formula of&nbsp;&nbsp; 256<br>
-Metal, Gilding&nbsp;&nbsp; 277<br>
-Metallic Arc&nbsp; 39<br>
-Metallic Circuit&nbsp; 125<br>
-Metallochromes&nbsp; 392<br>
-Metallurgy, Electro-&nbsp; 222<br>
-Metals, Law of Intermediate&nbsp; 323<br>
-Meter. Alternating Current&nbsp;&nbsp; 373<br>
-Meter, Ampere and Volt, Galvanometer .&nbsp;&nbsp; 274<br>
-Meter, Balance Ampere&nbsp;&nbsp; 391<br>
-Meter Bridge&nbsp; 373<br>
-Meter Bridge, Slide&nbsp;&nbsp; 486<br>
-Meter Candle&nbsp; 374<br>
-Meter, Chemical Electric&nbsp;&nbsp; 375<br>
-Meter, Current&nbsp; 375<br>
-Meter, Electro-magnetic&nbsp;&nbsp; 375<br>
-Meter, Energy&nbsp; 375<br>
-Meter Gram Standard Resistance, Matthiesen's&nbsp;&nbsp; 466<br>
-Meter-millimeter&nbsp; 375<br>
-Meter-millimeter Unit of Resistance&nbsp;&nbsp; 466<br>
-Meter, Neutral Wire Ampere.&nbsp;&nbsp; 391<br>
-Meter, Quantity&nbsp; 445<br>
-Meters. Ampere&nbsp; 39<br>
-Meter, Thermal-Electric&nbsp;&nbsp; 375<br>
-Meter, Time Electric&nbsp;&nbsp; 375<br>
-Meter, Watt&nbsp; 375<br>
-Method, Broadside&nbsp;&nbsp; 89<br>
-Method, Deflection&nbsp;&nbsp; 178<br>
-Method, End on&nbsp;&nbsp; 238<br>
-Method, Idiostatic&nbsp;&nbsp; 295<br>
-Method, Multiple Wire&nbsp; 388<br>
-Method, Null&nbsp; 393<br>
-Method of Magnetization, Elias'&nbsp; 360<br>
-Method of Magnetization, Isthmus&nbsp;&nbsp; 360<br>
-Method of Magnetization, Jacobi's&nbsp;&nbsp; 360<br>
-Methven Standard or Screen&nbsp; 376<br>
-Mho,&nbsp;&nbsp; 376<br>
-Mica&nbsp; 376<br>
-Mica, Moulded&nbsp;&nbsp; 376<br>
-Micro&nbsp; 376<br>
-Micrometer&nbsp; 376<br>
-Micrometer, Arc&nbsp;&nbsp; 39, 376<br>
-Micrometer, Spark&nbsp;&nbsp; 470<br>
-Micron&nbsp; 376<br>
-Microphone&nbsp; 376<br>
-Microphone Relay&nbsp; 377, 457<br>
-Microscope. Photo-electric&nbsp;&nbsp; 410<br>
-Microtasimeter&nbsp; 377<br>
-Mil&nbsp; 379<br>
-Mil, Circular&nbsp;&nbsp; 379<br>
-Mil-foot&nbsp; 379<br>
-Mil-foot Unit of Resistance&nbsp; 467<br>
-Milli&nbsp; 379<br>
-Milligram&nbsp; 379<br>
-Millimeter&nbsp; 379<br>
-Milli-oerstedt&nbsp; 380<br>
-Mil, Square&nbsp; 379<br>
-Minute, Ampere-&nbsp; 30<br>
-Mirror Galvanometer.&nbsp;&nbsp; 271<br>
-Mixed Gases&nbsp; 275<br>
-mm.&nbsp; 380<br>
-Molar&nbsp; 380<br>
-Molar Energy&nbsp; 241<br>
-Molecular Affinity&nbsp; 380<br>
-Molecular Attraction&nbsp; 380<br>
-Molecular Bombardment&nbsp; 380<br>
-Molecular Chain&nbsp; 380<br>
-Molecular Energy&nbsp; 241<br>
-Molecular Heat&nbsp; 286<br>
-Molecular Rigidity&nbsp; 380, 473<br>
-Molecular Shadow&nbsp; 480<br>
-Molecule&nbsp; 380<br>
-Moment&nbsp; 381<br>
-Moment, Magnetic&nbsp;&nbsp; 349<br>
-Moment of Couple&nbsp; 544<br>
-Moment, Turning&nbsp;&nbsp; 544<br>
-Monophote Lamp&nbsp; 321<br>
-Mordey Effect&nbsp; 381<br>
-Morse Receiver&nbsp; 381<br>
-Morse Recorder&nbsp; 451<br>
-Morse Telegraph&nbsp; 512<br>
-Mortar, Electric&nbsp;&nbsp; 382<br>
-Motion, Currents of&nbsp;&nbsp; 167<br>
-Motograph, Electro-&nbsp;&nbsp; 229<br>
-Motor. Compound or Compound Wound,.&nbsp;&nbsp; 382<br>
-Motor, Differential&nbsp;&nbsp; 382<br>
-Motor, Dynamo&nbsp;&nbsp; 200<br>
-Motor, Electric&nbsp;&nbsp; 382<br>
-Motor, Electro-&nbsp;&nbsp; 229<br>
-Motor, Electro-motive Force&nbsp;&nbsp; 384<br>
-Motor-generator&nbsp; 384<br>
-Motor, Multiphase&nbsp; 384<br>
-Motor, Overtype&nbsp;&nbsp; 399<br>
-Motor, Prime&nbsp; 385<br>
-Motor, Pulsating&nbsp; 386<br>
-Motor, Pyromagnetic&nbsp;&nbsp; 442<br>
-Motor, Reciprocating&nbsp;&nbsp; 385<br>
-Motor, Series&nbsp;&nbsp; 386<br>
-Motor, Shunt&nbsp;&nbsp; 386<br>
-Moulded Mica&nbsp; 376<br>
-Moulding&nbsp; 58<br>
-Movable Secondary&nbsp; 477<br>
-Mud, Battery&nbsp; 68<br>
-Multiphase Currents&nbsp; 166<br>
-Multiphase Motor&nbsp; 384<br>
-Multiple&nbsp; 386<br>
-Multiple Arc&nbsp; 387<br>
-Multiple Arc Box&nbsp; 387<br>
-Multiple Connected Battery&nbsp; 68<br>
-Multiple-series&nbsp; 387, 480<br>
-Multiple Switch&nbsp; 501<br>
-Multiple Switch Board&nbsp; 387<br>
-Multiple Transformer&nbsp; 548<br>
-Multiple Winding&nbsp; 579<br>
-Multiple Wire Method&nbsp; 388<br>
-Multiplex Harmonic Telegraph&nbsp; 510<br>
-Multiplex Telegraph&nbsp; 514<br>
-Multiplex Telegraphy&nbsp; 388<br>
-Multiplier, Schweigger's&nbsp; 476<br>
-Multiplying Power&nbsp; 347, 349<br>
-Multiplying Power of a Shunt&nbsp; 388<br>
-Multipolar Armature&nbsp; 46<br>
-Multipolar Dynamo&nbsp; 200<br>
-Multipolar Electric Bath&nbsp; 57<br>
-Multipolar Winding&nbsp; 579<br>
-Muscular Pile&nbsp; 388<br>
-Mutual Electro-magnetic Induction&nbsp; 302<br>
-Mutual Electrostatic Induction&nbsp; 303<br>
-Mutual Induction, Coefficient of&nbsp;&nbsp; 301<br>
-Mutual Induction Protector&nbsp; 481<br>
-Myria&nbsp; 388<br>
-<br>
-Nairne's Electrical Machine&nbsp; 389<br>
-Napierian Logarithms&nbsp; 389<br>
-Nascent State&nbsp; 389<br>
-Natural Currents&nbsp; 166, 389<br>
-Natural Magnet&nbsp; 361<br>
-Needle&nbsp; 389<br>
-Needle Annunciator&nbsp; 35<br>
-Needle, Astatic&nbsp;&nbsp; 50<br>
-Needle, Dipping&nbsp; 185<br>
-Needle, Magnetic&nbsp; 349<br>
-Needle, Orientation of a Magnetic&nbsp;&nbsp; 397<br>
-Needle of Oscillation&nbsp; 389<br>
-Needle Telegraph, Single&nbsp;&nbsp; 519<br>
-Needle, Telegraphic&nbsp; 389<br>
-Negative Charge&nbsp; 389<br>
-Negative Current&nbsp; 164<br>
-Negative Electricity&nbsp; 389<br>
-Negative, Electro-&nbsp;&nbsp; 229<br>
-Negative Element&nbsp; 390<br>
-Negative Feeder&nbsp; 251<br>
-Negative Lead of Brushes&nbsp; 324<br>
-Negative Plate&nbsp; 417<br>
-Negative Pole&nbsp; 425<br>
-Negative Potential&nbsp; 432<br>
-Negative Side of Circuit&nbsp; 125<br>
-Nerve and Muscle Current&nbsp; 164<br>
-Nerve Currents&nbsp; 390<br>
-Net Efficiency&nbsp; 205<br>
-Net, Faraday's&nbsp;&nbsp; 250<br>
-Network&nbsp; 390<br>
-Neutral Armature&nbsp; 46<br>
-Neutral Feeder&nbsp; 251<br>
-Neutral Line of Commutator&nbsp; 390<br>
-Neutral Line of Magnet&nbsp; 361<br>
-Neutral Point&nbsp; 421<br>
-Neutral Point of Commutator&nbsp; 390<br>
-Neutral Point, Thermo-electric&nbsp;&nbsp; 390<br>
-Neutral Relay Armature&nbsp; 46, 390<br>
-Neutral Temperature&nbsp; 390<br>
-Neutral Wire&nbsp; 390<br>
-Neutral Wire Ampere Meter&nbsp; 391<br>
-N. H. P.&nbsp; 391<br>
-Niaudet's Battery&nbsp;&nbsp; 61<br>
-Nickel&nbsp; 391<br>
-Nickel Bath&nbsp; 391<br>
-Night Bell&nbsp; 392<br>
-Nitric Acid Battery&nbsp; 68<br>
-Nobili's Rings&nbsp; 392<br>
-Nodal Point&nbsp; 422<br>
-Nodular Deposit&nbsp; 392<br>
-Nominal Candle Power&nbsp; 101<br>
-Non-conductor&nbsp; 392<br>
-Non-essential Resistance&nbsp; 465-467<br>
-Non-inductive Resistance&nbsp; 467<br>
-Non-polar Dynamo&nbsp;&nbsp; 200<br>
-Non-polarizable Electrodes&nbsp; 210<br>
-Non-Polarized Armature&nbsp; 46<br>
-Normal Magnet&nbsp; 361<br>
-North Magnetic Fluid&nbsp; 357<br>
-North Pole&nbsp; 392<br>
-North Seeking Pole&nbsp; 393<br>
-Null Method&nbsp; 393<br>
-Null Point&nbsp; 422<br>
-<br>
-Occlusion&nbsp; 393<br>
-Oerstedt&nbsp; 394<br>
-Oerstedt's Discovery&nbsp; 394<br>
-Oerstedt, Milli-&nbsp; 380<br>
-Ohm&nbsp; 394<br>
-Ohmage&nbsp; 394<br>
-Ohm, B. A.&nbsp; 394<br>
-Ohm, Board of Trade&nbsp;&nbsp; 394<br>
-Ohm, Congress&nbsp;&nbsp; 395<br>
-Ohmic Resistance&nbsp; 394, 467<br>
-Ohm, Legal&nbsp; 395<br>
-Ohmmeter&nbsp; 395<br>
-Ohm, Rayleigh&nbsp;&nbsp; 396<br>
-Ohm's Law&nbsp; 396<br>
-Ohm, True&nbsp; 396<br>
-Oil Insulation&nbsp; 396<br>
-Oil Transformer&nbsp; 548<br>
-Old Armature, Siemens'&nbsp;&nbsp; 49<br>
-Olefiant Gas&nbsp; 397<br>
-Omnibus Bar&nbsp; 94<br>
-Omnibus Rod&nbsp; 94<br>
-Omnibus Wire&nbsp; 94<br>
-One Coil Electro-magnet&nbsp; 219<br>
-Open&nbsp; 397<br>
-Open Circuit&nbsp; 125<br>
-Open Circuit Battery&nbsp; 68<br>
-Open Circuit Induction&nbsp; 303<br>
-Open Circuit Oscillation&nbsp; 397<br>
-Open Coil Armature&nbsp; 46<br>
-Open Coil Dynamo&nbsp; 200<br>
-Opening Shock&nbsp; 482<br>
-Operation, Magnet&nbsp; 365<br>
-Opposed Current&nbsp; 164<br>
-Optics, Electro-&nbsp;&nbsp; 229<br>
-Orders of Currents&nbsp; 167<br>
-Ordinate&nbsp; 397<br>
-Ordinates, Axis of&nbsp; 54, 397<br>
-Ores, Electric Reduction of&nbsp; 453<br>
-Ores, Magnetic Concentration of&nbsp;&nbsp; 340<br>
-Organ, Electric&nbsp; 397<br>
-Orientation of a Magnetic Needle&nbsp; 397<br>
-Origin of Co-ordinates&nbsp; 397<br>
-Oscillation, Centre of&nbsp; 112<br>
-Oscillation, Electric&nbsp; 398<br>
-Oscillation, Needle of&nbsp;&nbsp; 389<br>
-Oscillation, Open Circuit&nbsp;&nbsp; 397<br>
-Oscillatory&nbsp; 23<br>
-Oscillatory Discharge&nbsp; 188<br>
-Oscillatory Displacement&nbsp; 398<br>
-Oscillatory Electro-motive Force&nbsp; 398<br>
-Oscillatory Impedance&nbsp; 297<br>
-Oscillatory Induction&nbsp; 398<br>
-Osmose, Electric&nbsp; 398<br>
-Outlet&nbsp; 399<br>
-Output&nbsp; 399<br>
-Output, Magnetic&nbsp;&nbsp; 399<br>
-Output, Unit of&nbsp;&nbsp; 399<br>
-Over-compounding&nbsp; 399<br>
-Over, Flashing&nbsp;&nbsp; 258<br>
-Overflow Alarm&nbsp; 18<br>
-Over-house Telegraph&nbsp; 515<br>
-Overload&nbsp; 399<br>
-Overtype Dynamo or Motor&nbsp; 399<br>
-Oxide of Copper Battery&nbsp; 68<br>
-Ozone&nbsp; 399<br>
-<br>
-Pacinotti's Inductor&nbsp;&nbsp; 400<br>
-Pacinotti's Ring&nbsp; 400<br>
-Pacinotti Teeth&nbsp; 400<br>
-Page Effect&nbsp; 401<br>
-Page's Revolving Armature&nbsp; 47<br>
-Paillard Alloys&nbsp; 400<br>
-Palladium&nbsp; 401<br>
-Pane, Fulminating&nbsp;&nbsp; 262<br>
-Pane, Luminous&nbsp;&nbsp; 401<br>
-Pantelegraphy&nbsp; 402, 510<br>
-Paper Filaments&nbsp; 402<br>
-Parabola&nbsp; 402<br>
-Parabolic Reflector&nbsp; 402<br>
-Paraffine&nbsp; 402<br>
-Paraffine Wax&nbsp; 402<br>
-Paragr&ecirc;les&nbsp; 403<br>
-Parallax&nbsp; 403<br>
-Parallel&nbsp; 403<br>
-Parallel Circuits&nbsp; 123-126<br>
-Parallelogram of Forces&nbsp; 260<br>
-Parallels, Magnetic&nbsp; 349<br>
-Paramagnetic&nbsp; 403<br>
-Paramagnetism&nbsp;&nbsp; 404<br>
-Parasitical Currents&nbsp; 163<br>
-Parchmentizing&nbsp; 404<br>
-Partial Current&nbsp; 164<br>
-Partial Earth&nbsp; 203, 404<br>
-Partial Vacuum&nbsp; 557<br>
-Passive State&nbsp; 404<br>
-Path, Alternative&nbsp;&nbsp; 24<br>
-P. D.&nbsp; 404<br>
-Peltier's Cross&nbsp; 405<br>
-Peltier Effect&nbsp; 404<br>
-Pen, Electric&nbsp;&nbsp; 405<br>
-Pendant Cord&nbsp; 405<br>
-Pendulum Circuit Breaker&nbsp; 121<br>
-Pendulum, Electric&nbsp; 405<br>
-Pendulum or Swinging Annunciator&nbsp; 35<br>
-Pentane Standard, Harcourt's&nbsp;&nbsp; 406<br>
-Pentode Working&nbsp; 581<br>
-Percussion, Centre of&nbsp;&nbsp; 112<br>
-Perforated Armature&nbsp; 45<br>
-Perforated Core Discs&nbsp; 154<br>
-Perforator&nbsp; 407<br>
-Period&nbsp;&nbsp; 407<br>
-Period, Vibration&nbsp;&nbsp; 560<br>
-Periodic&nbsp; 23<br>
-Periodic Current, Power of&nbsp;&nbsp; 433<br>
-Periodicity&nbsp; 262, 408<br>
-Peripolar Zone&nbsp; 582<br>
-Permanency&nbsp; 408<br>
-Permanent Magnet&nbsp; 365<br>
-Permanent Magnet Ammeter&nbsp; 28<br>
-Permanent State&nbsp; 408<br>
-Permeability&nbsp; 346-349<br>
-Permeability-temperature Curve,&nbsp;&nbsp; 174<br>
-Permeameter&nbsp; 408<br>
-Permeance&nbsp; 408<br>
-Peroxide of Lead Battery&nbsp; 69<br>
-Perturbations, Magnetic&nbsp;&nbsp; 350<br>
-Pfl&uuml;ger's Law&nbsp; 409<br>
-Phantom Wires&nbsp; 409<br>
-Phase&nbsp; 409<br>
-Phase, Retardation of&nbsp;&nbsp; 471<br>
-Phenomenon, Porret's&nbsp;&nbsp; 427<br>
-Pherope&nbsp; 409, 527<br>
-Philosopher's Egg&nbsp; 409<br>
-Phonautograph,&nbsp;&nbsp; 409<br>
-Phone&nbsp;&nbsp; 409<br>
-Phonic Wheel&nbsp; 409<br>
-Phonograph&nbsp; 410<br>
-Phonophone or Rate Governor, Langdon Davies'&nbsp;&nbsp; 450<br>
-Phonozenograph&nbsp; 410<br>
-Phosphorescence&nbsp; 410<br>
-Phosphorous, Electrical Reduction of&nbsp;&nbsp; 410<br>
-Photo-electric Microscope&nbsp; 410<br>
-Photo-electricity&nbsp; 410<br>
-Photo-electro-motive Force&nbsp; 410<br>
-Photometer&nbsp; 411<br>
-Photometer, Actinic&nbsp;&nbsp; 411<br>
-Photometer, Bar&nbsp; 411<br>
-Photometer, Bunsen's&nbsp; 412<br>
-Photometer, Calorimetric&nbsp;&nbsp; 412<br>
-Photometer, Dispersion&nbsp; 412<br>
-Photometer, Shadow&nbsp; 414<br>
-Photometer, Translucent Disc&nbsp;&nbsp; 412<br>
-Photophore&nbsp; 415<br>
-Photo-voltaic Effect&nbsp; 415<br>
-Physical Energy&nbsp; 241<br>
-Physiology, Electro-&nbsp;&nbsp; 231<br>
-Piano, Electric&nbsp;&nbsp; 415<br>
-Pickle&nbsp; 415<br>
-Picture, Electric&nbsp;&nbsp; 415<br>
-Piece, Bed&nbsp; 78<br>
-Piece, Magnetic Proof&nbsp; 350<br>
-Piece, Pole&nbsp;&nbsp; 423<br>
-Pierced Core-discs,&nbsp;&nbsp; 152<br>
-Pile&nbsp; 415<br>
-Pile, Differential Thermo-electric&nbsp;&nbsp; 533<br>
-Pile, Muscular&nbsp; 388<br>
-Pile or Battery, Thermo-electric&nbsp;&nbsp; 530<br>
-Pilot Brush&nbsp; 91<br>
-Pilot Lamp&nbsp; 323<br>
-Pilot Transformer&nbsp; 415<br>
-Pilot Wires&nbsp; 415<br>
-Pistol, Electric&nbsp; 416<br>
-Pith&nbsp; 416<br>
-Pith Ball Electroscope&nbsp; 234<br>
-Pith-balls&nbsp; 416<br>
-Pivoted Armature&nbsp; 47<br>
-Pivot Suspension&nbsp; 416<br>
-Plane, Magnetic Proof&nbsp;&nbsp; 350<br>
-Plant&nbsp; 417<br>
-Plant Electricity&nbsp; 417<br>
-Plant, Isolated&nbsp;&nbsp; 309<br>
-Plant&eacute;'s Secondary Battery,&nbsp;&nbsp; 72<br>
-Plate, Arrester&nbsp;&nbsp; 417<br>
-Plate Condenser&nbsp; 417<br>
-Plate, Earth&nbsp; 203<br>
-Plate Electrical Machine&nbsp; 417<br>
-Plate, Franklin's&nbsp; 262<br>
-Plate, Generating&nbsp;&nbsp; 277<br>
-Plate, Ground&nbsp;&nbsp; 417<br>
-Plate, Negative&nbsp;&nbsp; 417<br>
-Plate, Positive&nbsp;&nbsp; 277, 417<br>
-Plating Balance&nbsp; 417<br>
-Plating Bath&nbsp; 418<br>
-Plating, Electro-&nbsp;&nbsp; 418<br>
-Platinized Carbon Battery&nbsp; 69<br>
-Platinoid&nbsp; 418<br>
-Platinum&nbsp; 419<br>
-Platinum Alloy&nbsp; 419<br>
-Platinum Black&nbsp; 419<br>
-Platinum Silver Alloy&nbsp; 419<br>
-Platinum Sponge&nbsp; 419<br>
-Play, End&nbsp; 238<br>
-Plow&nbsp; 420<br>
-Pl&uuml;cker Tubes&nbsp; 420<br>
-Plug&nbsp; 420<br>
-Plug Cut Out&nbsp; 175<br>
-Plug, Double&nbsp; 191<br>
-Plug, Grid&nbsp;&nbsp; 420<br>
-Plug, Infinity&nbsp;&nbsp; 305, 420<br>
-Plug Key&nbsp; 316<br>
-Plug Switch&nbsp; 420<br>
-Plumbago&nbsp; 421<br>
-Plunge Battery&nbsp; 69<br>
-Plunge&nbsp; 421<br>
-Plunger and Coil&nbsp; 131<br>
-Plunger and Coil, Differential&nbsp;&nbsp; 132<br>
-Plunger, Coil and&nbsp; 131<br>
-Plunger Electro-magnet&nbsp;&nbsp; 220<br>
-Pneumatic Battery&nbsp; 69<br>
-Pneumatic Signals, Electro-&nbsp;&nbsp; 231<br>
-P.O.&nbsp; 421<br>
-Pockets, Armature&nbsp; 47<br>
-Poggendorf's Solution&nbsp; 421<br>
-Point, Contact&nbsp; 147<br>
-Point, Indifferent&nbsp;&nbsp; 421<br>
-Point, Neutral&nbsp; 421<br>
-Point. Nodal&nbsp; 422<br>
-Point, Null&nbsp;&nbsp; 422<br>
-Point of Commutator, Neutral&nbsp;&nbsp; 390<br>
-Point Poles&nbsp; 422<br>
-Points, Consequent&nbsp;&nbsp; 422<br>
-Points, Corresponding&nbsp;&nbsp; 422<br>
-Points, Iso-electric&nbsp;&nbsp; 422<br>
-Points of Derivation&nbsp; 180, 423<br>
-Point, Thermo-electric Neutral&nbsp;&nbsp; 390<br>
-Polar Angle&nbsp;&nbsp; 423<br>
-Polar Extension&nbsp; 423<br>
-Polarity, Diamagnetic&nbsp;&nbsp; 181, 423<br>
-Polarity, Resultant&nbsp;&nbsp; 470<br>
-Polarization&nbsp; 423<br>
-Polarization, Back Electro-motive force of&nbsp;&nbsp; 156<br>
-Polarization Capacity&nbsp; 424<br>
-Polarization, Dielectric&nbsp;&nbsp; 183<br>
-Polarization, Galvanic&nbsp; 265<br>
-Polarization, Magnetic Rotary&nbsp;&nbsp; 351<br>
-Polarization of the Medium&nbsp; 424<br>
-Polarized Armature&nbsp; 47<br>
-Polarized Electro-magnet&nbsp; 220<br>
-Polarized Relay&nbsp; 458<br>
-Polarized Relay, Tongue of&nbsp;&nbsp; 542<br>
-Polarizing Current&nbsp; 164<br>
-Polar Region&nbsp; 424<br>
-Polar Span&nbsp; 424<br>
-Polar Span, Angle of&nbsp;&nbsp; 32, 423<br>
-Polar Tips&nbsp; 423<br>
-Polar Zone&nbsp; 582<br>
-Pole, Analogous&nbsp;&nbsp; 31, 425<br>
-Pole, Antilogous&nbsp;&nbsp; 425<br>
-Pole, Armature&nbsp;&nbsp; 47<br>
-Pole, Austral&nbsp; 54<br>
-Pole, Boreal&nbsp;&nbsp; 85<br>
-Pole Brackets, Telegraph&nbsp;&nbsp; 515<br>
-Pole Changer&nbsp; 425<br>
-Pole Changing Switch,&nbsp;&nbsp; 501<br>
-Pole Dynamo, Interior&nbsp;&nbsp; 199<br>
-Pole, Magnet&nbsp;&nbsp; 366<br>
-Pole, Negative&nbsp;&nbsp; 425<br>
-Pole, North&nbsp; 392<br>
-Pole, North-seeking&nbsp; 393<br>
-Pole or End, Marked&nbsp;&nbsp; 368<br>
-Pole Piece&nbsp; 423<br>
-Pole Pieces&nbsp; 425<br>
-Pole, Positive&nbsp;&nbsp; 425<br>
-Pole, Salient&nbsp; 426<br>
-Pole, Terminal&nbsp;&nbsp; 529<br>
-Pole Tips&nbsp; 290, 426<br>
-Pole, Traveling&nbsp; 426<br>
-Pole, Unit Magnet&nbsp;&nbsp; 366<br>
-Poles&nbsp; 425<br>
-Poles, Compensating&nbsp;&nbsp; 426<br>
-Poles, Consequent&nbsp;&nbsp; 146<br>
-Poles, Idle&nbsp; 296<br>
-Poles, Magnetic&nbsp; 350<br>
-Poles, Magnetic, False&nbsp;&nbsp; 350<br>
-Poles of Intensity&nbsp; 426<br>
-Poles of Verticity&nbsp; 426, 560<br>
-Poles, Point&nbsp; 422<br>
-Poles, Secondary&nbsp; 478<br>
-Poles, Secondary Magnet&nbsp;&nbsp; 366<br>
-Polyphase Currents&nbsp; 167<br>
-Polyphote Lamp&nbsp; 323<br>
-Popgun, Electric&nbsp; 282<br>
-Porous Cell&nbsp; 427<br>
-Porous Cup&nbsp; 159, 426<br>
-Porret's Phenomenon&nbsp; 427<br>
-Portative Power of Magnet&nbsp; 366<br>
-Portelectric Railroad&nbsp; 427<br>
-Portrait, Electric&nbsp; 415<br>
-Position, Energy of&nbsp;&nbsp; 241<br>
-Position Finder&nbsp; 427<br>
-Position, Sighted&nbsp;&nbsp; 484<br>
-Positive Current&nbsp; 164<br>
-Positive Direction&nbsp; 428<br>
-Positive Electricity&nbsp; 428<br>
-Positive Element&nbsp; 277<br>
-Positive Feeder&nbsp; 251<br>
-Positive Plate&nbsp; 277, 417<br>
-Positive Pole&nbsp; 425<br>
-Positive Potential&nbsp; 432<br>
-Positive Side of Circuit&nbsp; 125<br>
-Post Office&nbsp; 428<br>
-Posts, Binding, or Screws&nbsp; 81<br>
-Potential&nbsp; 428<br>
-Potential, Absolute&nbsp;&nbsp; 428<br>
-Potential, Constant&nbsp; 429<br>
-Potential Difference, Contact&nbsp;&nbsp; 147<br>
-Potential Difference, Electric&nbsp;&nbsp; 429<br>
-Potential Difference, Electro-motive&nbsp;&nbsp; 429<br>
-Potential, Electric Absolute&nbsp; 429<br>
-Potential, Fall of&nbsp; 430<br>
-Potential Galvanometer&nbsp; 269<br>
-Potential in Armature, Curve of Distribution of&nbsp;&nbsp; 172<br>
-Potential, Magnetic&nbsp;&nbsp; 350, 431<br>
-Potential, Negative&nbsp; 432<br>
-Potential or Static Energy&nbsp; 241<br>
-Potential, Positive&nbsp; 432<br>
-Potential Regulation, Constant&nbsp;&nbsp; 455<br>
-Potential, Unit of Electric&nbsp;&nbsp; 432<br>
-Potential, Zero&nbsp;&nbsp; 432, 582<br>
-Potentiometer&nbsp;&nbsp; 432<br>
-Poundal&nbsp; 433<br>
-Pound-foot&nbsp; 259<br>
-Power&nbsp; 438<br>
-Power, Candle&nbsp;&nbsp; 100<br>
-Power, Directive&nbsp;&nbsp; 187<br>
-Power, Electric&nbsp;&nbsp; 433<br>
-Power, Horse&nbsp; 290<br>
-Power, Illuminating&nbsp; 296<br>
-Power, Multiplying&nbsp; 349<br>
-Power of Magnet, Portative&nbsp;&nbsp; 366<br>
-Power of Periodic Current&nbsp; 433<br>
-Powers of Ten&nbsp; 527<br>
-Power, Stray&nbsp; 495<br>
-Power, Thermo-electric&nbsp;&nbsp; 533<br>
-Press Button&nbsp; 94<br>
-Pressel&nbsp; 434<br>
-Pressure&nbsp; 434<br>
-Pressure, Electric&nbsp; 434<br>
-Pressure, Electrification by&nbsp;&nbsp; 434<br>
-Primary&nbsp; 434<br>
-Primary Ampere-turns&nbsp; 31, 551<br>
-Primary Battery&nbsp; 69, 434<br>
-Prime&nbsp; 434<br>
-Prime Conductor&nbsp; 146, 434<br>
-Prime Conductor, Coatings of a&nbsp; 129<br>
-Prime Motor&nbsp;&nbsp; 385<br>
-Principle, Gauss'&nbsp;&nbsp; 276<br>
-Printing Telegraph&nbsp; 515<br>
-Probe, Electric&nbsp; 435<br>
-Projecting Power of a Magnet&nbsp; 435<br>
-Prony Brake&nbsp; 435<br>
-Proof Piece, Magnetic&nbsp; 350<br>
-Proof-plane&nbsp; 436<br>
-Proof Plane, Magnetic&nbsp;&nbsp; 350<br>
-Proof-sphere&nbsp; 436<br>
-Proportional Galvanometer&nbsp; 269<br>
-Proportionate Arms&nbsp; 436<br>
-Prostration, Electric&nbsp; 437<br>
-Protector, Body&nbsp;&nbsp; 84<br>
-Protector, Comb&nbsp;&nbsp; 437<br>
-Protector, Electric&nbsp;&nbsp;&nbsp; 437<br>
-Pull&nbsp; 437<br>
-Pulsatory Current&nbsp; 164<br>
-Pulsatory Field&nbsp; 256<br>
-Pulsating Motor&nbsp; 386<br>
-Pulvermacher's Electro-medical Battery&nbsp; 69<br>
-Pump, Geissler&nbsp;&nbsp; 437<br>
-Pump, Sprengel&nbsp;&nbsp; 439<br>
-Pump, Swinburne&nbsp;&nbsp; 440<br>
-Pumping&nbsp; 439<br>
-Puncture-electro&nbsp; 232<br>
-Puncture-galvano&nbsp; 232<br>
-Push Button&nbsp; 93. 98, 440<br>
-Push, Desk&nbsp;&nbsp; 180<br>
-Push, Floor&nbsp; 258<br>
-Pyro-electricity&nbsp; 441<br>
-Pyromagnetic Generator&nbsp; 442<br>
-Pyromagnetic Motor&nbsp; 441<br>
-Pyromagnetism&nbsp; 443<br>
-Pyrometer, Siemens' Electric&nbsp;&nbsp; 443<br>
-<br>
-Q&nbsp; 443<br>
-Quad&nbsp; 288, 443<br>
-Quadrant&nbsp; 288, 443<br>
-Quadrantal Deviation&nbsp; 180<br>
-Quadrant, Legal&nbsp; 444<br>
-Quadrant, Standard&nbsp;&nbsp; 444<br>
-Quadrature&nbsp;&nbsp; 444<br>
-Quadruplex Telegraph&nbsp; 515<br>
-Qualitative&nbsp; 444<br>
-Quality of Sound&nbsp; 444<br>
-Quantitative&nbsp; 444<br>
-Quantity&nbsp; 444<br>
-Quantity Armature&nbsp; 47<br>
-Quantity, Electric&nbsp; 444<br>
-Quantity, Electro-magnetic&nbsp; 445<br>
-Quantity, Electro-magnetic, Practical Unit of&nbsp;&nbsp; 445<br>
-Quantity, Electrostatic&nbsp; 445<br>
-Quantity Galvanometer&nbsp; 269<br>
-Quantity, Magnetic&nbsp; 350<br>
-Quantity Meter&nbsp; 445<br>
-Quartz&nbsp; 445<br>
-Quicking&nbsp; 446<br>
-<br>
-R&nbsp; 446<br>
-Racing of Motors&nbsp; 446<br>
-Radial Armature&nbsp; 47<br>
-Radian&nbsp; 446<br>
-Radiant Energy&nbsp; 446<br>
-Radiant Matter&nbsp; 368<br>
-Radiation&nbsp; 446<br>
-Radicals&nbsp; 446<br>
-Radiometer&nbsp; 447<br>
-Radiometer, Electric&nbsp;&nbsp; 447<br>
-Radio-micrometer&nbsp; 447<br>
-Radiophony&nbsp; 447<br>
-Railroad, Portelectric&nbsp;&nbsp; 427<br>
-Range Finder&nbsp; 447<br>
-Rate Governor&nbsp; 449<br>
-Rate Governor or Phonophone, Langdon Davies'&nbsp;&nbsp; 450<br>
-Rated Candle Power&nbsp; 101<br>
-Ratio Arms&nbsp; 437<br>
-Ratio, Core&nbsp;&nbsp; 154<br>
-Ratio, Shunt&nbsp; 483<br>
-Ratio, Velocity&nbsp; 560<br>
-Ray, Electric&nbsp; 450<br>
-Rayleigh Ohm&nbsp; 396<br>
-Reaction Coil&nbsp; 132<br>
-Reaction of a Dynamo Field and Armature&nbsp; 450<br>
-Reaction of Degeneration&nbsp; 179<br>
-Reactions, Anodic&nbsp; 36<br>
-Reactions, Armature&nbsp;&nbsp; 47<br>
-Reaction Telephone&nbsp; 527<br>
-Reaction Wheel&nbsp; 259<br>
-Reading Galvanometer, Direct&nbsp;&nbsp; 269<br>
-Reading, Sound&nbsp;&nbsp; 489<br>
-Reading Telescope&nbsp; 450<br>
-Real Efficiency of Secondary Battery&nbsp; 205<br>
-Real Hall Effect&nbsp; 284<br>
-R&eacute;aumur Scale&nbsp; 450<br>
-Recalescence&nbsp; 451<br>
-Receiver&nbsp; 451<br>
-Receiver, Harmonic&nbsp;&nbsp; 284, 451<br>
-Receiver, Morse&nbsp;&nbsp; 381<br>
-Receptive, Electro-&nbsp;&nbsp; 232<br>
-Recharge&nbsp; 115<br>
-Reciprocal&nbsp; 451<br>
-Reciprocating Motor&nbsp; 385<br>
-Recoil Circuit&nbsp; 125<br>
-Recorder, Chemical&nbsp; 117<br>
-Recorder, Morse&nbsp; 451<br>
-Recorder, Siphon&nbsp;&nbsp; 452<br>
-Record, Telephone&nbsp;&nbsp; 451<br>
-Rectification of Alcohol, Electric&nbsp; 18<br>
-Rectified Current&nbsp; 164<br>
-Rectilinear Current&nbsp; 165<br>
-Red Varnish&nbsp; 559<br>
-Red Magnetism&nbsp; 357<br>
-Redressed Current&nbsp; 165<br>
-Reduced Resistance&nbsp; 467<br>
-Reducteur for Ammeter&nbsp; 453<br>
-Reducteur for Voltmeter&nbsp; 453<br>
-Reduction of Ores, Electric&nbsp;&nbsp; 453<br>
-Reduction of Phosphorous, Electrical&nbsp; 410<br>
-Reflecting Galvanometer&nbsp; 270<br>
-Reflector, Parabolic&nbsp; 402<br>
-Refraction, Electric Double&nbsp;&nbsp; 454<br>
-Refraction, Electrostatic&nbsp;&nbsp; 235<br>
-Refreshing Action&nbsp; 454<br>
-Region, Extra-polar&nbsp;&nbsp; 454<br>
-Region, Intrapolar&nbsp;&nbsp; 307<br>
-Region, Polar&nbsp; 424<br>
-Register, Electric&nbsp; 454<br>
-Register, Telegraphic&nbsp;&nbsp; 454<br>
-Regulation, Constant Current&nbsp;&nbsp; 454<br>
-Regulation, Constant Potential&nbsp;&nbsp; 455<br>
-Regulation of Alternating Current Dynamo&nbsp; 195<br>
-Regulation of Dynamos&nbsp; 455<br>
-Reguline&nbsp; 456<br>
-Relative&nbsp; 456<br>
-Relative Calibration&nbsp; 98<br>
-Relay&nbsp; 456<br>
-Relay Bell&nbsp; 80<br>
-Relay Bells&nbsp; 457<br>
-Relay, Box Sounding&nbsp; 457<br>
-Relay Connection&nbsp; 457<br>
-Relay, Differential&nbsp; 457<br>
-Relay Magnet&nbsp; 457<br>
-Relay, Microphone&nbsp; 377, 457<br>
-Relay, Neutral, Armature&nbsp;&nbsp; 390<br>
-Relay, Polarized&nbsp;&nbsp; 457<br>
-Reluctance&nbsp; 458<br>
-Reluctance, Magnetic&nbsp;&nbsp; 351, 458<br>
-Reluctance, Unit of&nbsp;&nbsp; 438<br>
-Reluctivity&nbsp; 459<br>
-Reluctivity, Magnetic&nbsp;&nbsp; 351<br>
-Remanence&nbsp; 459<br>
-Remanence, Magnetic&nbsp; 358<br>
-Removal of Hair by Electrolysis&nbsp; 283<br>
-Renovate&nbsp; 115<br>
-Repeater&nbsp; 459<br>
-Repeater, Telegraph&nbsp;&nbsp; 518<br>
-Replenisher, Sir Wm. Thomson's&nbsp; 459<br>
-Repulsion, Magnetic&nbsp; 338<br>
-Repulsion and Attraction, Electrostatic&nbsp;&nbsp; 234<br>
-Repulsion and Attraction, Electro-magnetic&nbsp; 217<br>
-Reservoir, Common&nbsp;&nbsp; 460<br>
-Residual Atmosphere&nbsp; 460<br>
-Residual Capacity&nbsp; 103<br>
-Residual Charge&nbsp; 116<br>
-Residual Magnetism&nbsp; 358<br>
-Residue, Electric&nbsp; 116, 460<br>
-Resin&nbsp; 460<br>
-Resinous Electricity&nbsp; 461<br>
-Resistance&nbsp; 461<br>
-Resistance, Apparent&nbsp; 297, 462<br>
-Resistance, Assymmetrical&nbsp;&nbsp; 462<br>
-Resistance Box&nbsp; 462<br>
-Resistance, B. A. Unit of&nbsp;&nbsp; 462<br>
-Resistance Box, Sliding&nbsp; 463<br>
-Resistance, Breguet Unit of&nbsp;&nbsp; 463<br>
-Resistance Bridge&nbsp; 577<br>
-Resistance Coil&nbsp; 137<br>
-Resistance Coil, Standard&nbsp;&nbsp; 464<br>
-Resistance, Carbon&nbsp;&nbsp; 463<br>
-Resistance, Combined&nbsp; 464<br>
-Resistance, Compensating&nbsp;&nbsp; 144<br>
-Resistance, Critical&nbsp; 464<br>
-Resistance, Dielectric&nbsp; 183, 464<br>
-Resistance, Digney Unit of&nbsp;&nbsp; 464<br>
-Resistance, Electrolytic&nbsp; 464<br>
-Resistance, English Absolute or Foot-second Unit of&nbsp; 465<br>
-Resistance, Equivalent&nbsp;&nbsp; 465<br>
-Resistance, Essential&nbsp;&nbsp; 465<br>
-Resistance, External&nbsp;&nbsp; 465<br>
-Resistance Frame&nbsp; 465<br>
-Resistance, German Mile Unit of&nbsp;&nbsp; 466<br>
-Resistance, Hittorf's&nbsp;&nbsp; 466<br>
-Resistance, Inductive&nbsp; 466<br>
-Resistance, Insulation&nbsp;&nbsp; 466<br>
-Resistance, Internal&nbsp;&nbsp; 466<br>
-Resistance, Jacobi's Unit of&nbsp;&nbsp; 466<br>
-Resistance, Joint&nbsp; 464<br>
-Resistance, Magnetic&nbsp;&nbsp; 351, 458<br>
-Resistance, Matthiessen's Meter-gram Standard of&nbsp;&nbsp;&nbsp; 466<br>
-Resistance, Matthiessen's Unit of&nbsp;&nbsp; 466<br>
-Resistance, Meter-millimeter Unit of&nbsp;&nbsp; 466<br>
-Resistance, Mil-foot Unit of&nbsp;&nbsp; 467<br>
-Resistance, Non-essential&nbsp; 465, 467<br>
-Resistance, Non-inductive&nbsp;&nbsp; 467<br>
-Resistance of Human Body&nbsp; 467<br>
-Resistance, Ohmic&nbsp; 394, 467<br>
-Resistance, Reduced&nbsp; 467<br>
-Resistance, Siemens' Unit of&nbsp; 467<br>
-Resistance, Specific&nbsp; 467<br>
-Resistance. Specific Conduction&nbsp; 467<br>
-Resistance, Spurious&nbsp;&nbsp; 467<br>
-Resistance, Steadying&nbsp; 468<br>
-Resistance, Swiss Unit of&nbsp;&nbsp; 468<br>
-Resistance, Thomson's Unit of&nbsp;&nbsp; 468<br>
-Resistance to Sparking&nbsp; 490<br>
-Resistance, True&nbsp; 467<br>
-Resistance, Unit&nbsp; 468<br>
-Resistance, Unit of, B. A.&nbsp;&nbsp; 78<br>
-Resistance, Varley's&nbsp; 559<br>
-Resistance, Varley's Unit of&nbsp; 468<br>
-Resistance, Virtual&nbsp;&nbsp; 297<br>
-Resistance, Weber's Absolute Unit&nbsp;&nbsp; 468<br>
-Resolution of Forces&nbsp; 261<br>
-Resonator, Electric&nbsp;&nbsp; 468-470<br>
-Rest, Currents of&nbsp;&nbsp; 167<br>
-Resultant&nbsp; 470<br>
-Resultant Polarity&nbsp; 470<br>
-Retardation&nbsp; 470<br>
-Retardation of Phase&nbsp; 471<br>
-Retentivity&nbsp; 471<br>
-Retentivity, Magnetic&nbsp;&nbsp; 351<br>
-Retort Carbon&nbsp; 471<br>
-Return&nbsp; 471<br>
-Return Circuit&nbsp; 125<br>
-Return, Earth&nbsp; 203<br>
-Return Stroke&nbsp; 55<br>
-Reversal, Thermo-Electric&nbsp;&nbsp; 533<br>
-Reverse Current Working&nbsp; 581<br>
-Reverse-induced Current&nbsp; 163<br>
-Reverser, Current&nbsp;&nbsp; 165<br>
-Reversibility&nbsp; 471<br>
-Reversible Bridge&nbsp; 472<br>
-Reversing Key&nbsp; 316<br>
-Reversing Switch&nbsp; 501<br>
-Revivify&nbsp; 115<br>
-Revolving Armature, Page's&nbsp;&nbsp; 47<br>
-Rheochord&nbsp; 472<br>
-Rheometer&nbsp; 472<br>
-Rheomotor&nbsp; 472<br>
-Rheophore&nbsp; 472<br>
-Rheoscope&nbsp; 472<br>
-Rheoscopic Frog&nbsp; 262<br>
-Rheostat&nbsp; 472<br>
-Rheostat Arm&nbsp; 472<br>
-Rheostatic Machine&nbsp; 472<br>
-Rheostat, Wheatstone's&nbsp;&nbsp; 472<br>
-Rheotome&nbsp; 473<br>
-Rheotrope&nbsp; 473<br>
-Rhigolene&nbsp; 473<br>
-Rhumbs&nbsp; 473<br>
-Rhumkorff Coil&nbsp; 138, 473<br>
-Ribbon Coil&nbsp; 138<br>
-Ribbon Core&nbsp; 154<br>
-Right-handed Screw Law&nbsp; 324<br>
-Rigidity, Molecular&nbsp; 380, 473<br>
-Ring, Ampere&nbsp;&nbsp; 30<br>
-Ring Armature&nbsp; 48<br>
-Ring. Collecting&nbsp;&nbsp; 139<br>
-Ring Contact&nbsp; 473<br>
-Ring Core&nbsp; 155<br>
-Ring, Dynamo&nbsp; 200<br>
-Ring, Faraday's&nbsp;&nbsp; 473<br>
-Ring, Foundation&nbsp;&nbsp; 261<br>
-Ring, Guard&nbsp; 282<br>
-Ring, Pacinotti's&nbsp;&nbsp; 400<br>
-Rings, Electric&nbsp;&nbsp; 392<br>
-Rings, Nobili's&nbsp; 392<br>
-Ring, Split, Commutator&nbsp;&nbsp; 141<br>
-Roaring&nbsp; 474<br>
-Rocker&nbsp; 474<br>
-Rocker Arms&nbsp; 50, 474<br>
-Rod, Bus&nbsp; 94<br>
-Rod, Discharging&nbsp;&nbsp; 189<br>
-Rod, Omnibus&nbsp;&nbsp; 94<br>
-Roget's Spiral&nbsp; 474<br>
-Rolling Armature&nbsp; 49<br>
-Rosin&nbsp; 460<br>
-Rotary Polarization, Magnetic&nbsp;&nbsp; 351<br>
-Rotating Brush&nbsp;&nbsp; 91<br>
-Rotating Field&nbsp; 256<br>
-Rotation of Liquids, Electro-dynamic&nbsp;&nbsp; 474<br>
-Rotation of Liquids, Electro-magnetic&nbsp;&nbsp; 475<br>
-Rotatory Currents&nbsp; 167<br>
-Rubber&nbsp; 102, 475<br>
-Rubber, India&nbsp;&nbsp; 102<br>
-<br>
-Saddle Bracket&nbsp; 475<br>
-Safety Catch&nbsp; 175<br>
-Safety Cut Out&nbsp; 175<br>
-Safety Device&nbsp; 475<br>
-Safety Fuse&nbsp; 175, 475<br>
-Safety Fuse, Plug, or Strip&nbsp;&nbsp; 475<br>
-Sal Ammoniac Battery&nbsp; 69<br>
-Salient Pole&nbsp; 426<br>
-Salt&nbsp; 475<br>
-Salt, Dronier's&nbsp; 192<br>
-Salt or Sea-salt Battery&nbsp; 69<br>
-Sand Battery&nbsp; 90<br>
-Saturated&nbsp; 476<br>
-Saturation, Magnetic&nbsp;&nbsp; 351<br>
-Saw, Electric&nbsp;&nbsp; 476<br>
-Scale, Fahrenheit&nbsp;&nbsp; 248<br>
-Scale, R&eacute;aumur&nbsp;&nbsp; 450<br>
-Scale, Tangent&nbsp; 502<br>
-Schweigger's Multiplier&nbsp; 476<br>
-Scratch Brushes&nbsp; 476<br>
-Screen, Electric&nbsp;&nbsp; 476<br>
-Screen, Magnetic&nbsp;&nbsp; 351<br>
-Screen, Methven&nbsp; 376<br>
-Screws or Posts, Binding&nbsp;&nbsp; 81<br>
-Sealed, Hermetically&nbsp; 289<br>
-Sea Salt or Salt Battery&nbsp; 69<br>
-Secohm&nbsp; 288<br>
-Second, Ampere-&nbsp;&nbsp; 30<br>
-Secondary Actions&nbsp; 477<br>
-Secondary Ampere-turns&nbsp; 31, 551<br>
-Secondary Battery&nbsp; 70<br>
-Secondary Battery, Efficiency of, Quantity&nbsp; 205<br>
-Secondary Battery, Plant&eacute;'s&nbsp;&nbsp; 72<br>
-Secondary Clock&nbsp; 127<br>
-Secondary Current&nbsp; 166<br>
-Secondary Generator&nbsp; 277, 477<br>
-Secondary Magnet Poles&nbsp; 366<br>
-Secondary, Movable&nbsp; 477<br>
-Secondary Plates, Colors of&nbsp;&nbsp; 478<br>
-Secondary Poles&nbsp; 478<br>
-Secretion Current&nbsp; 166<br>
-Section Trolley&nbsp; 549<br>
-Sectioned Coils&nbsp; 138<br>
-Seebeck Effect&nbsp; 478<br>
-Segments&nbsp; 56<br>
-Segments, Commutator&nbsp;&nbsp; 56<br>
-Selenium&nbsp; 478<br>
-Selenium Cell&nbsp; 478<br>
-Selenium Eye&nbsp; 478<br>
-Self-exciting Dynamo&nbsp; 201<br>
-Self-induction&nbsp; 303<br>
-Self-induction, Magnetic&nbsp;&nbsp; 352<br>
-Self-induction, Unit of&nbsp;&nbsp; 304<br>
-Self-repulsion&nbsp; 478<br>
-Self-winding Electric Clock&nbsp; 128<br>
-Semi-circular Deviation&nbsp; 181<br>
-Semi-conductors&nbsp; 478<br>
-Semi-incandescent Lamp&nbsp; 323<br>
-Sender, Zinc&nbsp; 582<br>
-Sensibility&nbsp; 479<br>
-Sensitiveness, Angle of Maximum&nbsp;&nbsp; 479<br>
-Separate Circuit Dynamo&nbsp; 201<br>
-Separate Touch&nbsp; 359, 479<br>
-Separate Touch, Magnetization by&nbsp;&nbsp; 359<br>
-Separately Excited Dynamo&nbsp; 201, 479<br>
-Separation of Electricities&nbsp; 479<br>
-Separator&nbsp; 479<br>
-Separator, Magnetic&nbsp;&nbsp; 352<br>
-Series&nbsp; 479<br>
-Series and Long Shunt Winding&nbsp; 579<br>
-Series and Separate Coil Winding&nbsp; 579<br>
-Series and Short Shunt Winding&nbsp; 580<br>
-Series, Contact&nbsp; 147<br>
-Series Dynamo&nbsp; 201<br>
-Series, Electro-chemical&nbsp;&nbsp; 209<br>
-Series, Electro motive&nbsp;&nbsp; 228<br>
-Series, Electrostatic&nbsp;&nbsp; 235<br>
-Series Motor&nbsp; 386<br>
-Series, Multiple-&nbsp;&nbsp; 387<br>
-Series-multiple&nbsp; 480<br>
-Series, Thermo-electric&nbsp;&nbsp; 534<br>
-Series Transformer&nbsp; 548<br>
-Series Winding&nbsp; 579<br>
-Service Conductors&nbsp; 480<br>
-Serving&nbsp; 480<br>
-Shackle&nbsp; 480<br>
-Shadow, Electric&nbsp;&nbsp; 480<br>
-Shadow, Molecular&nbsp;&nbsp; 480<br>
-Shadow Photometer&nbsp; 414<br>
-Sheath for Magnet Coils&nbsp; 481<br>
-Sheath for Transformers&nbsp; 481<br>
-Sheath, Induction&nbsp; 303<br>
-Sheet Current&nbsp; 166<br>
-Shell, Magnetic&nbsp; 352<br>
-Shell, Strength of Magnetic&nbsp; 352<br>
-Shellac&nbsp; 481<br>
-Shellac Varnish&nbsp; 481<br>
-Shield, Anti-magnetic&nbsp;&nbsp; 37<br>
-Shield, Magnetic&nbsp;&nbsp; 351, 353<br>
-Shielded&nbsp; 481<br>
-S. H. M.&nbsp; 482<br>
-Shock, Back, or Stroke of Lightning&nbsp;&nbsp; 55<br>
-Shock, Break&nbsp;&nbsp; 482<br>
-Shock, Electric&nbsp;&nbsp; 482<br>
-Shock, Opening&nbsp;&nbsp; 482<br>
-Shock, Static&nbsp; 482<br>
-Short Circuit&nbsp; 482<br>
-Short Circuit Working&nbsp; 482<br>
-Short Fall Air Pumps&nbsp; 16<br>
-Short Shunt Winding&nbsp;&nbsp; 579<br>
-Shovel Electrodes&nbsp; 483<br>
-Shower Bath, Electric&nbsp;&nbsp; 57<br>
-Shunt&nbsp; 483<br>
-Shunt Box&nbsp;&nbsp; 483<br>
-Shunt Circuit&nbsp; 123, 126<br>
-Shunt Dynamo&nbsp; 202<br>
-Shunt, Electro-magnetic&nbsp;&nbsp; 483<br>
-Shunt, Galvanometer&nbsp;&nbsp; 271, 483<br>
-Shunt, Magnetic&nbsp;&nbsp; 353<br>
-Shunt Motor&nbsp; 386<br>
-Shunt. Multiplying Power of a&nbsp;&nbsp; 388<br>
-Shunt Ratio&nbsp; 483<br>
-Shunt Winding&nbsp; 580<br>
-Shuttle Armature&nbsp; 49<br>
-Shuttle Current&nbsp; 483<br>
-Shuttle Winding&nbsp; 483, 580<br>
-Side Flash&nbsp; 484<br>
-Siemens and Halske's Battery&nbsp; 72<br>
-Siemens' Differential Voltameter&nbsp; 564<br>
-Siemens' Electro-dynamometer&nbsp; 212<br>
-Siemens' Old Armature&nbsp; 49<br>
-Siemens' Unit of Resistance&nbsp; 467<br>
-Sighted Position&nbsp; 484<br>
-Signaling, Velocity of&nbsp; 560<br>
-Signals, Electro-pneumatic&nbsp;&nbsp; 231<br>
-Signal, Telegraph&nbsp; 519<br>
-Silent Discharge&nbsp; 187, 189, 206<br>
-Silver&nbsp; 484<br>
-Silver Bath&nbsp; 484<br>
-Silver, German&nbsp;&nbsp; 277<br>
-Silver Stripping Bath&nbsp; 484<br>
-Silver Voltameter&nbsp; 565<br>
-Simple Arc&nbsp; 39<br>
-Simple Circuit&nbsp; 126<br>
-Simple Harmonic Motion&nbsp; 486<br>
-Simple Immersion&nbsp; 185<br>
-Simple Magnet&nbsp; 366<br>
-Simple Substitution&nbsp; 485<br>
-Sims-Edison Torpedo&nbsp; 543<br>
-Sine Curve&nbsp; 174, 485<br>
-Sine Galvanometer&nbsp; 271<br>
-Sine Law&nbsp; 486<br>
-Sines, Curve of&nbsp; 173, 485<br>
-Single Coil Dynamo&nbsp; 202<br>
-Single Curb Working&nbsp; 581<br>
-Single Fluid Theory&nbsp; 486<br>
-Single Fluid Voltaic Cell&nbsp; 486<br>
-Single Needle Telegraph&nbsp; 519<br>
-Single Touch, Magnetization by&nbsp; 359<br>
-Sinistrotorsal&nbsp; 486<br>
-Sinuous Current&nbsp; 166<br>
-Sinusoidal Curve&nbsp; 174, 485<br>
-Siphon Recorder&nbsp; 452<br>
-Sir William Thomson's Battery&nbsp; 72<br>
-Skin Effect&nbsp; 486<br>
-Skrivanow Battery&nbsp; 72<br>
-Sled&nbsp; 486<br>
-Sleeve, Joint&nbsp;&nbsp; 310<br>
-Slide, Balance&nbsp;&nbsp; 374<br>
-Slide Bridge&nbsp; 374<br>
-Slide Meter Bridge&nbsp; 486<br>
-Sliding Condenser&nbsp; 144<br>
-Sliding-contact Key&nbsp; 316<br>
-Sliding Resistance Box&nbsp; 463<br>
-Slope, Lines of&nbsp;&nbsp; 330<br>
-Smee's Battery&nbsp; 73<br>
-S. N. Code&nbsp; 486<br>
-Snap Switch&nbsp; 501<br>
-Soaking-in-and-out&nbsp; 486<br>
-Socket, Lamp&nbsp;&nbsp; 323<br>
-Socket, Wall&nbsp; 572<br>
-Soldering, Electric&nbsp;&nbsp; 487<br>
-Solenoid&nbsp; 487<br>
-Solenoid Ammeter&nbsp; 28<br>
-Solenoidal Distribution of Magnetism&nbsp; 358<br>
-Solenoidal Magnet&nbsp; 366<br>
-Solid Earth&nbsp; 203<br>
-Solutions, Battery, Chromic Acid&nbsp;&nbsp; 73<br>
-Solution, Chutaux's&nbsp; 119<br>
-Solution, Delaurier's&nbsp;&nbsp;&nbsp; 179<br>
-Solution, Hittorf's&nbsp;&nbsp; 289<br>
-Solution, Kookogey's&nbsp;&nbsp; 318<br>
-Solution, Poggendorf's&nbsp; 421<br>
-Solution, Striking&nbsp; 496<br>
-Solution, Tissandier's&nbsp; 542<br>
-Solution, Trouv&eacute;'s&nbsp;&nbsp; 549<br>
-Sonometer, Hughes'&nbsp;&nbsp; 488<br>
-Sonorescence&nbsp; 488<br>
-Sound, Characteristics of&nbsp;&nbsp; 114<br>
-Sounder&nbsp; 488<br>
-Sounders, Tin&nbsp;&nbsp; 542<br>
-Sound, Quality of&nbsp;&nbsp; 444<br>
-Sound Reading&nbsp; 489<br>
-South Magnetic Fluid&nbsp; 356<br>
-Space, Clearance&nbsp; 489<br>
-Space, Crookes' Dark&nbsp;&nbsp;&nbsp; 489<br>
-Space, Dark, Faraday's&nbsp;&nbsp; 249, 489<br>
-Space, Faraday's Dark&nbsp;&nbsp; 249, 489<br>
-Space, Inter-air&nbsp;&nbsp; 489<br>
-Space, Interferric&nbsp;&nbsp; 489<br>
-Span, Polar&nbsp; 424<br>
-Span, Polar, Angle of the&nbsp;&nbsp; 32<br>
-Spark Arrester&nbsp; 489<br>
-Spark Coil&nbsp; 489<br>
-Spark Discharge&nbsp; 189<br>
-Spark, Duration of Electric&nbsp;&nbsp; 490<br>
-Spark Gap&nbsp; 490<br>
-Spark, Length of&nbsp;&nbsp; 490<br>
-Spark Micrometer&nbsp; 470<br>
-Spark Tube&nbsp; 491<br>
-Sparking&nbsp; 490<br>
-Sparking Distance&nbsp; 190<br>
-Sparking, Lines or Points of Least&nbsp;&nbsp; 490<br>
-Sparking, Resistance to&nbsp;&nbsp; 490<br>
-Specific Conduction Resistance&nbsp; 467<br>
-Specific Conductivity&nbsp; 145<br>
-Specific Heat&nbsp; 286<br>
-Specific Heat of Electricity&nbsp; 491<br>
-Specific Inductive Capacity&nbsp; 103<br>
-Specific Magnetization&nbsp; 361<br>
-Specific Resistance&nbsp; 467<br>
-Speech, Articulate&nbsp;&nbsp; 50<br>
-Speed, Critical&nbsp;&nbsp; 157<br>
-Spent Acid&nbsp; 491<br>
-Spent Liquor&nbsp; 491<br>
-Spherical Armature&nbsp; 49<br>
-Spherical Candle Power&nbsp; 101<br>
-Spherical Illuminating Power&nbsp; 296<br>
-Sphygmophone&nbsp; 491<br>
-Sphygmophone, Electric&nbsp; 491<br>
-Spiders&nbsp; 491<br>
-Spiral&nbsp;&nbsp; 492<br>
-Spiral Battery&nbsp; 73<br>
-Spiral, Roget's&nbsp;&nbsp;&nbsp; 474<br>
-Spiral Winding&nbsp; 492<br>
-Spirit Compass&nbsp; 143<br>
-Splayed Joint&nbsp; 311<br>
-Splice Box&nbsp; 492<br>
-Split Battery&nbsp; 73<br>
-Split Ring Commutator&nbsp; 141<br>
-Spluttering&nbsp; 492<br>
-Sponge, Platinum&nbsp;&nbsp; 419<br>
-Spot, Grease&nbsp; 92<br>
-Sprengel Pump&nbsp; 439<br>
-Spring Ammeter&nbsp; 28<br>
-Spring and Fibre Suspension&nbsp; 252<br>
-Spring-contact&nbsp; 148<br>
-Spring Control&nbsp; 492<br>
-Spring Jack Cut-out&nbsp; 493<br>
-Spurious Hall Effect&nbsp; 284<br>
-Spurious Resistance&nbsp; 467<br>
-Spurious Voltage&nbsp; 493<br>
-Square Mil&nbsp; 379<br>
-Square Wire&nbsp; 493<br>
-Squares, Law of Inverse&nbsp;&nbsp; 323<br>
-St. Elmo's Fire&nbsp; 494<br>
-Staggering&nbsp; 493<br>
-Standard Candle&nbsp; 101<br>
-Standard Candle, German&nbsp; 99<br>
-Standard, Harcourt's Pentane&nbsp;&nbsp; 406<br>
-Standard, Methven&nbsp;&nbsp; 376<br>
-Standard of Illuminating Power, Viole's&nbsp;&nbsp; 561<br>
-Standard or Main Feeder&nbsp; 251<br>
-Standard Quadrant&nbsp; 444<br>
-Standard Resistance Coil&nbsp; 464<br>
-Standard Voltaic Cell&nbsp; 109<br>
-Standard Voltaic Cell, Daniell's&nbsp; 109<br>
-Standard Voltaic Cell, Latimer Clark's.&nbsp;&nbsp; 110<br>
-State, Electrotonic&nbsp;&nbsp; 493<br>
-State, Nascent&nbsp; 389<br>
-State of Matter, Fourth&nbsp;&nbsp; 261<br>
-State, Passive&nbsp; 404<br>
-State, Permanent&nbsp;&nbsp; 408<br>
-Static Breeze&nbsp; 493<br>
-Static Condenser, Armature of&nbsp;&nbsp; 46<br>
-Static Electricity&nbsp; 493<br>
-Static Hysteresis&nbsp; 295<br>
-Static Induction, Magnetic&nbsp;&nbsp; 347<br>
-Static Shock&nbsp; 482<br>
-Station, Central&nbsp;&nbsp;&nbsp; 493<br>
-Station, Distant&nbsp;&nbsp; 493<br>
-Station, Home&nbsp; 493<br>
-Station, Transforming&nbsp; 494<br>
-Steadying Resistance&nbsp; 468<br>
-Steel&nbsp; 494<br>
-Steeling&nbsp; 494<br>
-Steel Yard Ammeter&nbsp; 28<br>
-Step-by-step Telegraph&nbsp; 506<br>
-Step-by-step Telegraphy&nbsp; 494<br>
-Step-down&nbsp; 494<br>
-Step, Foot-&nbsp;&nbsp;&nbsp; 259<br>
-Sticking&nbsp; 494<br>
-Stool, Insulating&nbsp; 305<br>
-Stopped Coil Electro-magnets&nbsp; 221<br>
-Stopping Off&nbsp; 495<br>
-Storage Battery&nbsp; 70<br>
-Storage Battery Changing Switch&nbsp; 501<br>
-Storage Battery, Plant&eacute;'s&nbsp;&nbsp; 72<br>
-Storage Capacity&nbsp; 105, 495<br>
-Storage of Electricity&nbsp; 495<br>
-Storms, Electric&nbsp;&nbsp; 495<br>
-Storms. Magnetic&nbsp;&nbsp; 353<br>
-Strain&nbsp; 495<br>
-Strain, Dielectric&nbsp;&nbsp; 183<br>
-Strain, Magnetic&nbsp; 354<br>
-Stranded Conductor Armature&nbsp; 49<br>
-Stranded Core&nbsp; 155<br>
-Stray Field&nbsp; 256, 495<br>
-Stray Power&nbsp; 495<br>
-Streamlets. Current&nbsp; 495<br>
-Strength, Dielectric&nbsp;&nbsp; 183<br>
-Strength of Magnetic Shell&nbsp; 352<br>
-Stress&nbsp; 495<br>
-Stress, Dielectric&nbsp; 496<br>
-Stress, Electro-magnetic&nbsp;&nbsp; 219, 496<br>
-Stress, Electrostatic&nbsp; 236, 496<br>
-Stress, Energy of&nbsp;&nbsp; 241<br>
-Stress, Magnetic&nbsp;&nbsp; 354<br>
-Striae, Electric&nbsp;&nbsp; 496<br>
-Striking Distance&nbsp; 496<br>
-Striking Solution&nbsp; 496<br>
-Stripping&nbsp; 496<br>
-Stripping Bath&nbsp; 57<br>
-Stripping Bath, Gold&nbsp;&nbsp; 279<br>
-Stripping Bath, Silver&nbsp;&nbsp; 484<br>
-Stroke, Back&nbsp;&nbsp; 55<br>
-Stroke or Shock of Lightning, Back&nbsp;&nbsp; 55<br>
-Stroke, Return&nbsp; 55<br>
-Sub-branch&nbsp; 496<br>
-Sub-main&nbsp; 496<br>
-Sub-permanent Magnetism&nbsp; 358<br>
-Substitution, Simple&nbsp;&nbsp; 485<br>
-Subway, Electric&nbsp; 496<br>
-Successive Temperatures, Law of&nbsp;&nbsp; 324<br>
-Sucking Coil&nbsp; 182<br>
-Sucking Magnet&nbsp; 366<br>
-Sulphate of Lead Battery&nbsp; 66<br>
-Sulphate of Mercury Battery&nbsp; 67<br>
-Sulphating&nbsp; 497<br>
-Sulphur Dioxide&nbsp; 497<br>
-Sulphuric Acid&nbsp; 497<br>
-Sulphuric Acid Voltameter&nbsp; 564<br>
-Sulphurous Acid Gas&nbsp;&nbsp; 497<br>
-Sunstroke, Electric&nbsp; 497<br>
-Superficial Density, Electric&nbsp;&nbsp; 180<br>
-Supersaturated,&nbsp;&nbsp; 497<br>
-Supply, Isolated&nbsp;&nbsp; 309<br>
-Surface&nbsp; 497<br>
-Surface Density&nbsp; 498<br>
-Surface, Equipotential&nbsp;&nbsp; 498<br>
-Surface Leakage&nbsp; 498<br>
-Surface Magnetization&nbsp; 356<br>
-Surgical Electro-magnet&nbsp; 222<br>
-Surging Discharge&nbsp; 188<br>
-Surveyors' Compass&nbsp; 143<br>
-Susceptibility, Magnetic&nbsp; 354, 359<br>
-Suspension&nbsp; 498<br>
-Suspension, Bifilar&nbsp; 498<br>
-Suspension, Fibre&nbsp; 252<br>
-Suspension, Knife Edge&nbsp; 317<br>
-Suspension, Pivot&nbsp; 416<br>
-Suspension, Spring and Fibre&nbsp;&nbsp; 252<br>
-Suspension, Torsion&nbsp; 545<br>
-Suspension Wire of Cable&nbsp;&nbsp; 97<br>
-Swaging. Electric&nbsp; 499<br>
-Swelling Current&nbsp; 167<br>
-S. W. G.&nbsp; 499<br>
-Swinburne Pump&nbsp; 440<br>
-Swinging Earth&nbsp; 203<br>
-Swinging or Pendulum Annunciator&nbsp; 35<br>
-Swiss Unit of Resistance&nbsp;&nbsp; 468<br>
-Switch&nbsp; 499<br>
-Switch, Automatic&nbsp; 500<br>
-Switch Board&nbsp; 500<br>
-Switch Board, Multiple&nbsp;&nbsp; 387<br>
-Switch Board, Trunking&nbsp;&nbsp; 550<br>
-Switch, Break-down&nbsp;&nbsp; 88<br>
-Switch, Changing&nbsp; 500<br>
-Switch, Changing Over&nbsp;&nbsp; 500<br>
-Switch, Circuit Changing&nbsp;&nbsp; 500<br>
-Switch, Double Break&nbsp;&nbsp; 500<br>
-Switch, Double Pole&nbsp;&nbsp; 500<br>
-Switch Feeder&nbsp; 500<br>
-Switch, Knife&nbsp;&nbsp; 501<br>
-Switch, Knife Break&nbsp;&nbsp; 501<br>
-Switch, Knife Edge&nbsp;&nbsp; 501<br>
-Switch, Multiple&nbsp; 501<br>
-Switch, Plug&nbsp; 420<br>
-Switch, Pole Changing&nbsp;&nbsp; 501<br>
-Switch, Reversing&nbsp;&nbsp; 501<br>
-Switch, Snap&nbsp;&nbsp; 501<br>
-Switch, Storage Battery Changing&nbsp;&nbsp; 501<br>
-Switch, Three Way&nbsp;&nbsp; 501<br>
-Switches, Distributing&nbsp;&nbsp; 190<br>
-Symmer's Theory&nbsp; 191<br>
-Sympathetic Vibration&nbsp; 501, 561<br>
-System, Block&nbsp;&nbsp; 83<br>
-System of Co-ordinates&nbsp; 150<br>
-System, Tower&nbsp;&nbsp; 545<br>
-<br>
-T&nbsp; 501<br>
-Tailing Current&nbsp; 501<br>
-Tailings&nbsp; 501<br>
-Talk, Cross&nbsp; 158<br>
-Tamidine&nbsp; 502<br>
-Tangent Galvanometer&nbsp; 272<br>
-Tangent Law&nbsp; 502<br>
-Tangent Positions of, Gauss&nbsp;&nbsp; 276<br>
-Tangent Scale&nbsp; 502<br>
-Tangentially Laminated Core&nbsp; 155<br>
-Tank, Cable&nbsp; 97<br>
-Tape, Insulating&nbsp;&nbsp; 305<br>
-Tapper Key, Double&nbsp;&nbsp; 314<br>
-Teazer&nbsp; 504<br>
-Technica, Memoria, Amp&eacute;re's&nbsp;&nbsp; 30<br>
-Tee, Lead&nbsp; 504<br>
-Teeth, Pacinotti&nbsp;&nbsp; 400<br>
-Tel-autograph&nbsp; 504<br>
-Tele-barometer, Electric&nbsp;&nbsp; 504<br>
-Telegraph, A. B. C.&nbsp; 504<br>
-Telegraph, Autographic&nbsp;&nbsp; 510<br>
-Telegraph, Automatic&nbsp; 504<br>
-Telegraph, Dial&nbsp; 505<br>
-Telegraph, Double Needle&nbsp;&nbsp; 506<br>
-Telegraph, Duplex&nbsp; 506<br>
-Telegraph, Duplex, Bridge&nbsp; 506<br>
-Telegraph, Duplex, Differential&nbsp;&nbsp; 507<br>
-Telegraph Embosser&nbsp; 237<br>
-Telegraph, Facsimile&nbsp; 510<br>
-Telegraph, Harmonic Multiplex&nbsp;&nbsp; 510<br>
-Telegraph. Hughes'&nbsp;&nbsp; 511<br>
-Telegraph Insulator&nbsp; 306<br>
-Telegraph Key&nbsp; 316<br>
-Telegraph, Magneto-electric&nbsp;&nbsp; 512<br>
-Telegraph, Morse&nbsp; 512<br>
-Telegraph, Multiplex&nbsp; 514<br>
-Telegraph, Single Needle&nbsp;&nbsp; 519<br>
-Telegraph, Overhouse&nbsp; 515<br>
-Telegraph Pole Brackets&nbsp; 515<br>
-Telegraph, Printing&nbsp; 515<br>
-Telegraph, Quadruplex&nbsp;&nbsp; 515<br>
-Telegraph Repeater&nbsp; 518<br>
-Telegraph Signal&nbsp; 519<br>
-Telegraph, Step-by-step&nbsp; 506<br>
-Telegraph, Wheatstone's, A. B. C.&nbsp;&nbsp; 521<br>
-Telegraph. Writing&nbsp; 521<br>
-Telegraphic Alphabet&nbsp; 19<br>
-Telegraphic Code&nbsp; 130, 511<br>
-Telegraphic Needle&nbsp; 389<br>
-Telegraphic Register&nbsp; 454<br>
-Telegraphy, Multiplex&nbsp; 388<br>
-Telegraphy, Step-by-step&nbsp;&nbsp; 494<br>
-Telemanometer, Electric&nbsp;&nbsp; 521<br>
-Telemeter, Electric&nbsp;&nbsp; 521<br>
-Telepherage&nbsp; 522<br>
-Telephone&nbsp; 522<br>
-Telephone, Bi-&nbsp; 524<br>
-Telephone, Capillary&nbsp;&nbsp; 525<br>
-Telephone, Carbon&nbsp;&nbsp; 525<br>
-Telephone, Chemical&nbsp;&nbsp; 526<br>
-Telephone, Electrostatic&nbsp;&nbsp; 526<br>
-Telephone Exchange&nbsp; 246<br>
-Telephone Induction Coil&nbsp; 137, 526<br>
-Telephone, Reaction&nbsp;&nbsp; 527<br>
-Telephone Record&nbsp; 451<br>
-Telephone, Thermo-electric&nbsp;&nbsp; 527<br>
-Telephone Tinnitus&nbsp; 542<br>
-Telephotography&nbsp; 521<br>
-Telephote&nbsp; 527<br>
-Telescope, Reading&nbsp; 450<br>
-Teleseme&nbsp; 527<br>
-Tele-thermometer&nbsp; 527<br>
-Terminal&nbsp; 529<br>
-Terminal Pole&nbsp; 529<br>
-Terminal Voltage&nbsp; 562<br>
-Temperature, Absolute&nbsp;&nbsp; 8<br>
-Temperature, Neutral&nbsp; 390<br>
-Temperatures, Laws of Successive&nbsp;&nbsp; 324<br>
-Tempering, Electric&nbsp; 527<br>
-Temporary Magnetism or Magnetization&nbsp; 357<br>
-Ten, Powers of&nbsp;&nbsp;&nbsp; 527<br>
-Tension&nbsp; 529<br>
-Tension, Disruptive&nbsp; 189<br>
-Tension, Electric&nbsp; 529<br>
-Terrestrial Magnetism&nbsp;&nbsp; 358<br>
-Tetanus, Acoustic&nbsp;&nbsp; 529<br>
-Tetrode Working&nbsp; 581<br>
-Theatrophone&nbsp; 529<br>
-Theory, Contact&nbsp; 148<br>
-Theory, Double Fluid&nbsp;&nbsp; 191<br>
-Theory, Franklin's&nbsp; 262<br>
-Theory of Dimensions&nbsp; 184<br>
-Theory of Light, Electro-magnetic&nbsp; 219<br>
-Theory of Light, Maxwell's&nbsp; 369<br>
-Theory of Magnetism, Amp&eacute;re's&nbsp; 354<br>
-Theory of Magnetism, Ewing's&nbsp; 356<br>
-Theory of Magnetism, Hughes'&nbsp;&nbsp; 357<br>
-Theory of Magnetism, Weber's&nbsp;&nbsp; 358<br>
-Theory, Symmer's&nbsp; 191<br>
-Therapeutic Electrode&nbsp; 210<br>
-Therapeutics, Electro-&nbsp;&nbsp; 236<br>
-Therm&nbsp; 529<br>
-Thermaesthesiometer&nbsp; 530<br>
-Thermal Electric Meter&nbsp; 375<br>
-Thermal Equivalent, Electro-&nbsp;&nbsp; 245<br>
-Thermal Energy&nbsp; 242<br>
-Thermic Balance&nbsp; 85<br>
-Thermo Call&nbsp; 530<br>
-Thermo-chemical Battery&nbsp; 530<br>
-Thermo-chemical Equivalent&nbsp; 245<br>
-Thermo-electric Battery or Pile&nbsp; 530<br>
-Thermo-electric Call&nbsp; 531<br>
-Thermo-electric Couple&nbsp; 532<br>
-Thermo-electric Current&nbsp; 167<br>
-Thermo-electric Diagram&nbsp; 532<br>
-Thermo-electric Element&nbsp; 237<br>
-Thermo-electric Inversion&nbsp; 533<br>
-Thermo-electric Junction&nbsp; 533<br>
-Thermo-electric Neutral Point&nbsp;&nbsp; 390<br>
-Thermo-electric Pile, Differential&nbsp; 533<br>
-Thermo-electric Power&nbsp; 533<br>
-Thermo-electric Reversal&nbsp; 533<br>
-Thermo-electric Series&nbsp; 534<br>
-Thermo-electric Telephone&nbsp; 527<br>
-Thermo-electric Thermometer&nbsp; 535<br>
-Thermo-electricity&nbsp; 533<br>
-Thermo-electricity, Laws of, Becquerel's&nbsp; 78<br>
-Thermo-electricity, Volta's Law of&nbsp; 568<br>
-Thermo-electrometer&nbsp; 536<br>
-Thermolysis&nbsp; 535<br>
-Thermo-multiplier&nbsp; 536<br>
-Thermometer&nbsp; 535<br>
-Thermometer, Electric&nbsp;&nbsp; 535<br>
-Thermometer, Kinnersley's&nbsp;&nbsp; 536<br>
-Thermometer, Tele-&nbsp;&nbsp; 527<br>
-Thermometer, Thermo-electric&nbsp;&nbsp; 535<br>
-Thermophone&nbsp; 537<br>
-Thermostat, Electric&nbsp;&nbsp; 537<br>
-Third Brush&nbsp; 91<br>
-Thomson Effect&nbsp; 538<br>
-Thomson's Replenisher, Sir William&nbsp;&nbsp; 459<br>
-Thomson's Battery, Sir William&nbsp; 72<br>
-Thomson's Unit of Resistance&nbsp; 468<br>
-Three Filament Incandescent Lamp&nbsp; 322<br>
-Three Way Switch&nbsp; 501<br>
-Three Wire System&nbsp; 539<br>
-Throw&nbsp; 237, 540<br>
-Throw-back Indicator&nbsp; 540<br>
-Thrust Bearings&nbsp; 540<br>
-Thunder&nbsp; 540<br>
-Ticker&nbsp;&nbsp; 540<br>
-Tick, Magnetic&nbsp;&nbsp; 354<br>
-Timbre&nbsp;&nbsp; 444<br>
-Time Constant&nbsp; 541<br>
-Time Cut-outs&nbsp; 541<br>
-Time Electric Meter&nbsp; 375<br>
-Time-fall&nbsp;&nbsp; 541<br>
-Time-reaction&nbsp; 541<br>
-Time-rise&nbsp; 541<br>
-Tin&nbsp; 541<br>
-Tin Sounders&nbsp; 542<br>
-Tinnitus, Telephone&nbsp;&nbsp; 542<br>
-Tips, Polar&nbsp;&nbsp; 423<br>
-Tips, Pole&nbsp;&nbsp; 290, 426<br>
-Tissandier's Solution&nbsp; 542<br>
-Toeppler-Holtz Machine&nbsp; 334<br>
-Tongs, Cable Hanger&nbsp; 97<br>
-Tongs, Discharging&nbsp; 189<br>
-Tongue of Polarized Relay&nbsp; 542<br>
-Tongue of Polarized Relay, Bias of&nbsp;&nbsp; 542<br>
-Toothed Core-discs&nbsp; 154<br>
-Top, Magnetic&nbsp;&nbsp; 542<br>
-Torpedo, Electric&nbsp; 543<br>
-Torpedo, Sims-Edison&nbsp;&nbsp; 543<br>
-Torque&nbsp; 543<br>
-Torque, Curve of&nbsp;&nbsp; 174<br>
-Torricellian Vacuum&nbsp; 557<br>
-Torsion Balance, Coulomb's&nbsp;&nbsp; 544<br>
-Torsion Galvanometer&nbsp; 273, 544<br>
-Torsion Head&nbsp; 544<br>
-Torsion Suspension&nbsp; 545<br>
-Total Earth&nbsp; 203<br>
-Touch&nbsp; 545<br>
-Touch, Separate&nbsp;&nbsp; 479<br>
-Tourmaline&nbsp;&nbsp; 545<br>
-Tower, Electric&nbsp;&nbsp; 545<br>
-Tower System&nbsp;&nbsp; 545<br>
-Trailing Horns&nbsp; 259<br>
-Transformer&nbsp; 545<br>
-Transformer, Commuting&nbsp; 547<br>
-Transformer, Continuous Alternating&nbsp;&nbsp; 547<br>
-Transformer, Continuous Current&nbsp;&nbsp; 384, 547<br>
-Transformer, Core&nbsp; 547<br>
-Transformer, Faraday's&nbsp;&nbsp; 250<br>
-Transformer, Hedgehog&nbsp;&nbsp; 548<br>
-Transformer, Multiple&nbsp;&nbsp; 548<br>
-Transformer, Oil&nbsp; 548<br>
-Transformer, Pilot&nbsp;&nbsp; 415<br>
-Transformer, Series&nbsp;&nbsp; 548<br>
-Transformer. Sheath for&nbsp; 481<br>
-Transforming Station&nbsp; 494<br>
-Transformer, Welding&nbsp;&nbsp; 548, 575<br>
-Translator&nbsp; 519<br>
-Translucent Disc Photometer&nbsp; 412<br>
-Transmitter&nbsp; 548<br>
-Transmitter, Carbon&nbsp;&nbsp; 549<br>
-Transmission of Energy, Electric&nbsp;&nbsp; 240<br>
-Transposing&nbsp; 549<br>
-Transverse Electro-motive Force&nbsp; 549<br>
-Trap, Bug&nbsp; 92<br>
-Traveling Pole&nbsp; 426<br>
-Trembling Bell&nbsp; 78<br>
-Trolley&nbsp; 549<br>
-Trolley, Double&nbsp;&nbsp; 549<br>
-Trolley Section&nbsp; 549<br>
-Trough Battery&nbsp;&nbsp; 73<br>
-Trouv&eacute;'s Blotting Paper Battery&nbsp; 73<br>
-Trouv&eacute;'s Solution&nbsp; 549<br>
-True Contact Force&nbsp; 549<br>
-True Ohm&nbsp; 396<br>
-True Resistance&nbsp; 467<br>
-Trimmer, Brush&nbsp;&nbsp; 549<br>
-Trumpet, Electric&nbsp;&nbsp; 550<br>
-Trunk Lines&nbsp; 550<br>
-Trunking Switch Board&nbsp; 550<br>
-Tube, Electric&nbsp;&nbsp; 550<br>
-Tube, Guard&nbsp; 282<br>
-Tube, Luminous&nbsp;&nbsp; 550<br>
-Tube of Magnetic Induction&nbsp; 347<br>
-Tube, Spark&nbsp; 491<br>
-Tube, Stratification&nbsp;&nbsp; 495<br>
-Tubes, Geissler&nbsp;&nbsp; 276<br>
-Tubes of Force&nbsp;&nbsp; 261<br>
-Tubes, Pl&uuml;cker&nbsp; 420<br>
-Tubular Braid&nbsp; 550<br>
-Tubular Core&nbsp; 155<br>
-Tubular Magnet&nbsp; 356<br>
-Tuning Fork Circuit Breaker&nbsp; 121<br>
-Tuning Fork Dynamo&nbsp; 202<br>
-Tuning Fork, Interrupter for&nbsp; 307<br>
-Turning Moment&nbsp; 544<br>
-Turns&nbsp; 550<br>
-Turns, Ampere-&nbsp; 31<br>
-Turns, Dead, of a Dynamo&nbsp;&nbsp; 551<br>
-Turns, Primary Ampere-&nbsp;&nbsp; 551<br>
-Turns, Secondary Ampere-&nbsp;&nbsp; 551<br>
-Twist Joint, American&nbsp; 309<br>
-Twist, Magnetic&nbsp;&nbsp; 354<br>
-Tyer's Battery&nbsp; 74<br>
-Typewriter, Electric&nbsp;&nbsp; 551<br>
-Type Printer, Hughes'&nbsp;&nbsp; 511<br>
-<br>
-Ultra-gaseous Matter&nbsp; 551<br>
-Unbuilding&nbsp; 552<br>
-Underground Conductor&nbsp; 552<br>
-Underground Electric Subway&nbsp; 552<br>
-Undulatory&nbsp; 23<br>
-Undulatory Current&nbsp; 167<br>
-Unidirectional&nbsp; 553<br>
-Uniform Field&nbsp; 256<br>
-Uniform Field of Force&nbsp; 553<br>
-Uniform Magnetic Field&nbsp; 345<br>
-Unipolar&nbsp; 553<br>
-Unipolar Armature&nbsp; 50, 553<br>
-Unipolar Current Induction&nbsp; 553<br>
-Unipolar Dynamo&nbsp; 202-553<br>
-Unipolar Electric Bath&nbsp; 57<br>
-Unipolar Induction&nbsp;&nbsp; 304<br>
-Unipolar Magnet&nbsp; 366<br>
-Unit&nbsp; 553<br>
-Unit, Absolute&nbsp;&nbsp; 554<br>
-Unit Angle&nbsp; 554<br>
-Unit. B. A.&nbsp;&nbsp; 554<br>
-Unit, B. A., of Resistance&nbsp;&nbsp; 462<br>
-Unit Current&nbsp; 167<br>
-Unit Electro-motive Force&nbsp; 228<br>
-Unit, Fundamental&nbsp;&nbsp; 554<br>
-Unit Jar&nbsp; 554<br>
-Unit Magnet Pole&nbsp; 366<br>
-Unit of Capacity&nbsp; 105<br>
-Unit of Conductivity&nbsp; 145<br>
-Unit of Electric Potential&nbsp; 432<br>
-Unit of Energy, Electro-magnetic&nbsp;&nbsp; 220<br>
-Unit of Force&nbsp; 261<br>
-Unit of Illumination&nbsp; 296<br>
-Unit of Output&nbsp; 399<br>
-Unit of Reluctance&nbsp; 458<br>
-Unit of Resistance, B. A.&nbsp;&nbsp; 78<br>
-Unit of Resistance, Breguet&nbsp;&nbsp; 463<br>
-Unit of Resistance, Digney&nbsp; 464<br>
-U nit of Resistance, English Absolute or Foot-second&nbsp;&nbsp; 465<br>
-Unit of Resistance, German Mile&nbsp; 466<br>
-Unit of Resistance, Jacobi's&nbsp; 466<br>
-Unit of Resistance, Meter-millimeter.&nbsp;&nbsp; 466<br>
-Unit of Resistance, Mil-foot&nbsp;&nbsp; 467<br>
-Unit of Resistance, Siemens'&nbsp; 467<br>
-Unit of Resistance, Swiss&nbsp; 468<br>
-Unit of Resistance, Thomson's&nbsp;&nbsp; 468<br>
-Unit of Resistance, Varley's&nbsp;&nbsp; 468<br>
-Unit of Self-induction&nbsp; 304<br>
-Unit of Supply&nbsp; 554<br>
-Unit of Work&nbsp; 581<br>
-Unit Resistance&nbsp; 468<br>
-Units, Circular&nbsp; 126, 555<br>
-Units, Derived&nbsp;&nbsp; 555<br>
-Units, Heat&nbsp;&nbsp; 288<br>
-Units, Practical&nbsp; 555<br>
-Universal Battery System&nbsp; 556<br>
-Universal Discharger&nbsp; 189<br>
-Unmarked End&nbsp; 556<br>
-Upright Galvanometer&nbsp; 274<br>
-Upward's Battery&nbsp; 75<br>
-<br>
-V&nbsp; 556<br>
-V. A.&nbsp; 557<br>
-Vacuum&nbsp; 557<br>
-Vacuum, Absolute&nbsp; 557<br>
-Vacuum, High&nbsp; 557<br>
-Vacuum Lightning Arrester&nbsp; 329<br>
-Vacuum, Low&nbsp;&nbsp; 557<br>
-Vacuum, Partial&nbsp; 557<br>
-Vacuum, Torricellian&nbsp;&nbsp; 557<br>
-Valency&nbsp; 557<br>
-Valve, Electrically Controlled&nbsp;&nbsp; 558<br>
-Vapor Globe&nbsp; 558<br>
-Variable Conductivity&nbsp; 145<br>
-Variable Period&nbsp; 558<br>
-Variable State&nbsp; 558<br>
-Variation of the Compass&nbsp; 32, 558<br>
-Variations, Magnetic&nbsp;&nbsp; 354<br>
-Variometer&nbsp; 559<br>
-Varley's Battery&nbsp; 76<br>
-Varley's Condenser&nbsp;&nbsp; 559<br>
-Varley's Resistance&nbsp; 559<br>
-Varley's Unit of Resistance&nbsp;&nbsp; 468<br>
-Varnish&nbsp; 559<br>
-Varnish, Electric&nbsp;&nbsp;&nbsp; 559<br>
-Varnish, Insulating&nbsp;&nbsp; 306<br>
-Varnish, Red&nbsp; 559<br>
-Varnish, Shellac&nbsp; 481<br>
-Vat&nbsp; 559<br>
-Velocity&nbsp; 559<br>
-Velocity, Angular&nbsp; 32, 559<br>
-Velocity of Signaling&nbsp; 560<br>
-Velocity Ratio&nbsp; 560<br>
-Ventilation of Armature&nbsp; 560<br>
-Vertical Galvanometer&nbsp; 274<br>
-Vertical Induction&nbsp; 304<br>
-Verticity, Poles of&nbsp;&nbsp; 426, 560<br>
-Vibrating Bell&nbsp; 78<br>
-Vibration Period&nbsp; 560<br>
-Vibration, Sympathetic&nbsp;&nbsp; 501, 561<br>
-Vibrator, Electro-magnetic&nbsp;&nbsp; 561<br>
-Villari's Critical Value&nbsp;&nbsp; 561<br>
-Viole&nbsp; 562<br>
-Viole's Standard of Illuminating Power&nbsp; 561<br>
-Virtual Resistance&nbsp; 297<br>
-Viscous Hysteresis&nbsp; 295, 356<br>
-Vis Viva&nbsp; 562<br>
-Vitreous Electricity&nbsp; 562<br>
-Vitriol, Blue&nbsp; 562<br>
-Vitriol, Green&nbsp;&nbsp;&nbsp; 562<br>
-Vitriol, White&nbsp;&nbsp; 562<br>
-Volatilization of Carbon&nbsp; 108<br>
-Volt&nbsp; 562<br>
-Volt-ampere&nbsp; 573<br>
-Volt and Ampere Meter Galvanometer&nbsp; 274<br>
-Volt, B. A.&nbsp; 568<br>
-Volt, Congress&nbsp;&nbsp; 568<br>
-Volt, Coulomb&nbsp;&nbsp; 568, 573<br>
-Volt Indicator&nbsp; 568<br>
-Volt. Legal&nbsp;&nbsp; 568<br>
-Voltage&nbsp; 562<br>
-Voltage, Spurious&nbsp; 493<br>
-Voltage, Terminal&nbsp;&nbsp; 562<br>
-Voltaic&nbsp; 563<br>
-Voltaic Alternatives&nbsp; 563<br>
-Voltaic Arc&nbsp; 39<br>
-Voltaic Cell, Daniell's Standard&nbsp; 109<br>
-Voltaic Cell, Double Fluid&nbsp; 191<br>
-Voltaic Cell, Capacity of Polarization of a&nbsp;&nbsp; 103<br>
-Voltaic Cell, Single Fluid&nbsp;&nbsp; 486<br>
-Voltaic Cell, Standard&nbsp;&nbsp; 109<br>
-Voltaic Cell, Standard, Latimer Clark's&nbsp;&nbsp; 110<br>
-Voltaic Circuit&nbsp; 126<br>
-Voltaic Effect&nbsp; 563<br>
-Voltaic Electricity&nbsp; 563<br>
-Voltaic Element&nbsp; 237<br>
-Voltaic or Galvanic Battery&nbsp; 76<br>
-Voltaic or Galvanic Circle&nbsp; 119<br>
-Voltaic or Galvanic Couple&nbsp; 156<br>
-Voltameter&nbsp;&nbsp; 563<br>
-Voltameter, Copper&nbsp;&nbsp; 563<br>
-Voltameter, Differential, Siemens'&nbsp;&nbsp; 564<br>
-Voltameter, Faraday's&nbsp;&nbsp; 250<br>
-Voltameter, Gas&nbsp;&nbsp; 564<br>
-Voltameter, Silver&nbsp; 565<br>
-Voltameter, Sulphuric Acid&nbsp;&nbsp;&nbsp; 564<br>
-Voltameter, Volume&nbsp;&nbsp; 564<br>
-Voltameter, Weight&nbsp;&nbsp; 566<br>
-Voltametric Law&nbsp; 567<br>
-Volta's Battery&nbsp; 76<br>
-Volta's Fundamental Experiments&nbsp;&nbsp; 567<br>
-Volta's Law of Galvanic Action&nbsp; 568<br>
-Volta's Law of Thermo-electricity&nbsp; 568<br>
-Voltmeter&nbsp; 568<br>
-Voltmeter, Battery&nbsp;&nbsp; 569<br>
-Voltmeter, Cardew&nbsp; 569<br>
-Voltmeter, Electrostatic&nbsp;&nbsp; 571<br>
-Voltmeter, Reducteur for&nbsp;&nbsp; 453<br>
-Volts, Lost&nbsp; 571<br>
-Volume Voltameter&nbsp; 564<br>
-Vulcanite&nbsp; 571<br>
-<br>
-W&nbsp; 572<br>
-Wall Bracket&nbsp; 572<br>
-Wall Socket&nbsp; 572<br>
-Ward&nbsp; 572<br>
-Waste Field&nbsp; 256<br>
-Water&nbsp; 572<br>
-Water Battery&nbsp; 77<br>
-Water Equivalent&nbsp; 572<br>
-Water Level Alarm&nbsp; 18<br>
-Waterproof Lamp Globe&nbsp; 572<br>
-Wattless Current&nbsp; 168<br>
-Watt&nbsp; 572<br>
-Watt-hour&nbsp; 573<br>
-Watt Meter&nbsp; 375<br>
-Watt-minute&nbsp; 573<br>
-Watt-second&nbsp; 573<br>
-Watts, Apparent&nbsp; 573<br>
-Wave Winding&nbsp; 580<br>
-Waves, Amplitude of&nbsp;&nbsp; 31<br>
-Waves. Electro-magnetic&nbsp;&nbsp; 573<br>
-Wax, Paraffine&nbsp;&nbsp; 402<br>
-Weber&nbsp;&nbsp; 574<br>
-Weber s Absolute Unit Resistance&nbsp; 468<br>
-Weber-meter&nbsp; 574<br>
-Weber's Theory of Magnetism&nbsp; 358<br>
-Wedge Cut-out&nbsp; 175<br>
-Wedge. Double&nbsp;&nbsp; 191<br>
-Weight, Atomic&nbsp;&nbsp; 53<br>
-Weight, Breaking&nbsp;&nbsp; 89<br>
-Weight Electrometer&nbsp; 223<br>
-Weight Voltameter&nbsp; 566<br>
-Welding, Electric&nbsp; 574<br>
-Welding Transformer&nbsp; 548, 575<br>
-Wheatstone's A. B. C. Telegraph&nbsp; 521<br>
-Wheatstone's Balance&nbsp;&nbsp; 577<br>
-Wheatstone's Bridge&nbsp;&nbsp; 575<br>
-Wheatstone's Bridge, Commercial&nbsp;&nbsp; 86<br>
-Wheatstone's Rheostat&nbsp;&nbsp;&nbsp; 472<br>
-Wheel, Phonic&nbsp;&nbsp; 409<br>
-Wheel, Reaction&nbsp;&nbsp; 259<br>
-Whirl, Electric&nbsp;&nbsp; 577<br>
-White Vitriol&nbsp;&nbsp; 562<br>
-Wilde Candle&nbsp;&nbsp; 101<br>
-Wimshurst Electric Machine&nbsp; 335, 577<br>
-Wimshurst Machine&nbsp; 335, 577<br>
-Wind, Electric&nbsp; 578<br>
-Windage&nbsp; 578<br>
-Windings, Ampere&nbsp;&nbsp; 31<br>
-Winding, Bifilar&nbsp; 81<br>
-Winding, Compound&nbsp;&nbsp; 578<br>
-Winding, Disc&nbsp; 579<br>
-Winding, Lap&nbsp; 579<br>
-Winding, Long Shunt&nbsp; 579<br>
-Winding, Long Shunt and Series&nbsp; 579<br>
-Winding, Multiple&nbsp;&nbsp; 579<br>
-Winding, Multipolar&nbsp;&nbsp; 579<br>
-Winding, Series&nbsp; 579<br>
-Winding, Series and Separate Coil&nbsp;&nbsp; 579<br>
-Winding, Series and Short Shunt&nbsp;&nbsp; 580<br>
-Winding, Short Shunt&nbsp;&nbsp; 579<br>
-Winding, Shunt&nbsp; 483, 580<br>
-Winding Shuttle&nbsp; 580<br>
-Winding, Wave&nbsp; 580<br>
-Winding Working, Differential&nbsp; 183<br>
-Wire, Block&nbsp; 83<br>
-Wire, Bus&nbsp; 94<br>
-Wire, Dead&nbsp;&nbsp; 177<br>
-Wire Finder&nbsp;&nbsp; 580<br>
-Wire Gauze Brush&nbsp; 92<br>
-Wire, Idle&nbsp; 296<br>
-Wire, Neutral&nbsp;&nbsp; 390<br>
-Wire, Omnibus&nbsp;&nbsp; 94<br>
-Wire, Square&nbsp; 493<br>
-Wire System, Three&nbsp;&nbsp; 539<br>
-Wires, Crossing&nbsp;&nbsp; 158<br>
-Wires, Leading-in&nbsp;&nbsp; 324<br>
-Wires, Phantom&nbsp;&nbsp; 409<br>
-Wires, Pilot&nbsp; 415<br>
-Wollaston Battery&nbsp; 78<br>
-Work&nbsp; 580<br>
-Work, Electric, Unit of&nbsp;&nbsp; 580<br>
-Work, Unit of&nbsp; 581<br>
-Working, Contraplex&nbsp;&nbsp; 580<br>
-Working, Diode&nbsp;&nbsp; 580<br>
-Working, Diplex&nbsp;&nbsp; 580<br>
-Working, Double Curb&nbsp;&nbsp; 581<br>
-Working, Hexode&nbsp;&nbsp; 581<br>
-Working, Pentode&nbsp;&nbsp; 581<br>
-Working, Reverse Current&nbsp; 581<br>
-Working, Single Curb&nbsp;&nbsp; 581<br>
-Working Tetrode&nbsp; 581<br>
-Writing Telegraph&nbsp; 521<br>
-<br>
-X, Axis of&nbsp;&nbsp; 54<br>
-<br>
-Y, Axis of&nbsp;&nbsp; 54, 397<br>
-Yoke&nbsp; 581<br>
-<br>
-Zamboni's Dry Pile&nbsp; 581<br>
-Zero&nbsp; 581<br>
-Zero, Absolute&nbsp; 581<br>
-Zero Potential&nbsp; 432, 582<br>
-Zero, Thermometric&nbsp;&nbsp; 582<br>
-Zinc&nbsp;&nbsp; 582<br>
-Zinc Sender&nbsp; 582<br>
-Zincode&nbsp; 582<br>
-Zone, Peripolar&nbsp;&nbsp; 582<br>
-Zone, Polar&nbsp;&nbsp; 582</big></big><br>
-<br>
-<br>
-
-
-<pre>
-
-
-
-
-
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