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authornfenwick <nfenwick@pglaf.org>2025-02-06 22:26:51 -0800
committernfenwick <nfenwick@pglaf.org>2025-02-06 22:26:51 -0800
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+This eBook, including all associated images, markup, improvements,
+metadata, and any other content or labor, has been confirmed to be
+in the PUBLIC DOMAIN IN THE UNITED STATES.
+
+Procedures for determining public domain status are described in
+the "Copyright How-To" at https://www.gutenberg.org.
+
+No investigation has been made concerning possible copyrights in
+jurisdictions other than the United States. Anyone seeking to utilize
+this eBook outside of the United States should confirm copyright
+status under the laws that apply to them.
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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #54221 (https://www.gutenberg.org/ebooks/54221)
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-The Project Gutenberg EBook of Induction Coils, How to Make, Use, and
-Repair Them., by H. S. Norrie
-
-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/license
-
-
-Title: Induction Coils, How to Make, Use, and Repair Them.
- Including Ruhmkorff, Tesla, and medical coils, Roentgen
- Radiography, etc. etc.
-
-Author: H. S. Norrie
-
-Release Date: February 22, 2017 [EBook #54221]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK INDUCTION COILS ***
-
-
-
-
-Produced by Chris Curnow, Les Galloway and the Online
-Distributed Proofreading Team at http://www.pgdp.net (This
-file was produced from images generously made available
-by The Internet Archive)
-
-
-
-
-
-
-
-[Illustration: ONE OF TWO RUHMKORFF COILS MADE BY QUEEN & CO. THE
-OUTPUT WITH ABOUT 650 WATTS OF CURRENT IN THE PRIMARY WAS A TORRENT OF
-SPARKS 45 INCHES IN LENGTH.]
-
-
-
-
- INDUCTION COILS
-
- How to Make, Use, and Repair Them
-
- INCLUDING
-
- RUHMKORFF, TESLA, AND MEDICAL COILS,
- ROENTGEN RADIOGRAPHY, WIRELESS
- TELEGRAPHY, AND PRACTICAL INFORMATION
- ON PRIMARY AND
- SECONDARY BATTERY
-
- BY
- H. S. NORRIE
- (NORMAN H. SCHNEIDER)
-
- _SECOND EDITION, REVISED AND MUCH ENLARGED_
-
- [Illustration: Colophon]
-
- NEW YORK:
- SPON & CHAMBERLAIN, 12 CORTLANDT ST.
-
- LONDON:
- E. & F. N. SPON, Ltd., 125 STRAND
-
- 1901
-
-
-
-
- Entered, according to Act of Congress, in the year 1896
- Re-entered for Copyright in 1901
- By SPON & CHAMBERLAIN
- in the office of the Librarian of Congress, Washington, D. C.
-
-
- BURR PRINTING HOUSE,
- NEW YORK, N. Y., U. S. A.
-
-
-
-
-ERRATA.
-
-
-PAGE 55. Should read, "Cords being attached to binding posts Nos. 1 and
-2 are in circuit with the _Secondary_ Coil only. When at Nos. 2 and 3
-they receive the induced current or extra current in the _Primary_."
-
-INDEX. "Tesla coil, descriptive," should read "Tesla coil,
-_disruptive_."
-
-
-
-
-PREFACE TO THE SECOND EDITION.
-
-
-The great favor with which the first edition of this little work
-has been received and the steadily growing interest in its subject,
-together with many valuable improvements and researches, may be given
-as the reasons for this new edition.
-
-The book has been thoroughly revised, partly rewritten, and
-considerable new matter, with twenty-six new illustrations, added. It
-has been brought up to date as far as electrical science has gone.
-
-To detail all that has been done is too great a task for a preface; we
-may briefly mention the following new matter:
-
-Coils for gas and automobile engines; medical coils, concise directions
-for operation and repairs; new forms of contact breakers, including
-electrolytic and mechanical; gas-lighting apparatus; primary and
-secondary batteries.
-
-The chapter on X-Ray Apparatus has been entirely rewritten, and is
-thoroughly practical; and an entire chapter on Wireless Telegraphy has
-been added. In a book of this size it is not feasible to give specific
-directions and full dimensions for the manufacture of all the apparatus
-described. Indeed, much of the latter must be adapted to the particular
-purpose for which it is to be utilized. Again, the same amount of
-material will not always produce the same results. A little closer
-winding, greater pressure applied to the cooling wax of a condenser,
-and the output or capacity of either is changed.
-
-Matters purely of design or taste are to be governed by the creative
-faculty of the worker; but such general details and rules are given
-as will be sufficient to enable one possessing ordinary constructive
-ability to make his own apparatus.
-
-The whole process of coil-making does not require high mechanical
-skill, but chiefly patience and attention to details; and, perhaps best
-of all, but few tools are needed, all of a simple kind.
-
-We beg to acknowledge courtesies received from Messrs. Queen & Co., the
-_Scientific American_ for frontispiece and Fig. 13, Mr. Goldingham's
-book on Oil Engines for Fig. 12, and others who have been of assistance
-to the author. The best American and English practice has been adopted;
-the American standard gauges and sizes of wires are used, except where
-noted.
-
-A list of works, particularly of value to the coil worker, will be
-found following the index.
-
- H. S. NORRIE
- (Norman H. Schneider.)
-
-APRIL, 1901.
-
-
-
-
-CONTENTS.
-
-
- CHAPTER I.
-
- COIL CONSTRUCTION.
-
- Construction of Ruhmkorff Coils. Sizes of
- Wires. Winding of Primary and Secondary.
- Assembling. Connecting Up.
- Insulation. Coils in Series. Oil Immersed
- Coils. "Tesla" Coil. Disruptive
- "Tesla" Coil. Coils for Gas
- Engines. Spark Coils. Resistance
- Coils. General Remarks on Coils. The
- Testing of a Coil for Polarity. Failure
- to Work. Medical Coils. Medical Coil
- with Tube Regulation. Medical Coil
- with Interchangeable Secondaries. Bath
- Coils 1-64
-
-
- CHAPTER II.
-
- CONTACT BREAKERS.
-
- Construction of Contact Breakers. Various
- Forms of Simple Contact Breakers.
- The Mercury Vibrator. Polechanging
- Vibrator. Wehnelt Interrupter. Dessauer
- Contact Breaker. Steel Ribbon
- Interrupter. Contact Breakers in
- Vacuo. Queen Contact Breaker. Adjustable
- Contact Breaker for Medical
- Coils. The Queen Contact Breaker for
- Large Coils, Adjustable Cone Vibrator.
- Contacts 65-91
-
-
- CHAPTER III.
-
- INSULATIONS AND CEMENTS.
-
- Selection of Insulating Materials. Mineral
- Oil. Paraffin Wax. Resin Oils. Beeswax.
- Shellac Varnishes. Silk. Insulating
- Compounds 92-98
-
-
- CHAPTER IV.
-
- CONDENSERS.
-
- Construction of Condensers. Leyden Jar.
- Glass Plate Condenser. Paper Condensers.
- Series Condenser. Rolled-Up
- Condensers. Adjustable Condensers.
- Application of Condensers 99-119
-
-
- CHAPTER V.
-
- EXPERIMENTS.
-
- Luminous Effects Obtained by Means of a
- Ruhmkorff Coil. Materials Used.
- Spark Experiments. The Luminous
- Pane. Luminous Designs, etc. 120-130
-
-
- CHAPTER VI.
-
- SPECTRUM ANALYSIS.
-
- Color Produced by Burning Different
- Metals. The Spectroscope Shown in
- Connection with the Coil. The Screen.
- The Color Spaces in the Solar Spectrum.
- Color Values 131-139
-
-
- CHAPTER VII.
-
- CURRENTS IN VACUO.
-
- Different Forms of Mercury Air Pumps.
- Geissler Tubes. Discharges in Vacuo.
- Characteristic Colors of Different Gases
- in Tubes, etc. 140-152
-
-
- CHAPTER VIII.
-
- ROTATING EFFECTS.
-
- Effects of Discharges in Rotating Tubes.
- Construction of Rotating Wheels. Arrangement
- of Tubes, etc. 153-163
-
-
- CHAPTER IX.
-
- GAS LIGHTING.
-
- The Application of the Ruhmkorff Coil for
- Lighting Gas. Gas Lighting in Series.
- Gas Lighting in Multiple. Gas Lighting
- Diagram. Jump Spark Burner.
- Automatic Burners 164-177
-
-
- CHAPTER X.
-
- BATTERIES FOR COILS.
-
- The Selection of Suitable Batteries. Open
- Circuit Cells. Closed Circuit Cells.
- Description of Cells. Formulæ for Solutions
- for Different Kinds of Batteries.
- The Grenet Battery. Fuller Battery.
- Gravity Battery. Dun Cell. Gethins
- Cell. Gordon Battery. New Standard.
- Edison-Lalande Cell. Dry Batteries.
- Dry Cell Construction, etc. 178-199
-
-
- CHAPTER XI.
-
- STORAGE OR SECONDARY CELL.
-
- Construction of a Storage Cell. Connecting
- Up Cells. Charging Storage Batteries.
- Diagram for Charging from Dynamo
- Using a Rheostat. Diagram for Charging,
- using Lamp instead of Rheostat.
- Charging from. Primary Batteries.
- Testing Solutions. Setting Up the
- Storage Cell. The Harrison Cell. The
- "U. S." Storage Cell, etc. 200-223
-
-
- CHAPTER XII.
-
- TESLA AND HERTZ EFFECTS.
-
- Currents of High Frequency. Electric Resonator.
- The "Tesla" Effects. Coil
- Connected to Discharger. High Frequency
- Currents in Electro-Therapeutics,
- etc. 224-234
-
-
- CHAPTER XIII.
-
- THE "ROENTGEN" RAYS AND RADIOGRAPHY.
-
- General Arrangement of Connections for
- Coil and Crookes Tube for Making X Ray
- Negatives. The Fluoroscope. Phosphorus
- Tube. The Queen Self-Adjusting
- Crookes Tube. General Remarks,
- etc. 235-247
-
-
- CHAPTER XIV.
-
- WIRELESS TELEGRAPHY.
-
- Arrangements of Simple Circuits of Coil and
- Coherer for Receiving and Sending
- Messages. The Coherer. Carbon Coherer.
- Coherer without Filings. Aluminum
- Coherer. Steel Ball Coherer. The
- Oscillator. Clarke's Oscillator. Triple
- Oscillator. The Coil. Translating
- Devices. Air Conductor, etc. 248-265
-
- INDEX 266
-
- Bibliography 270
-
-
-
-
-CONTENTS OF TABLES.
-
-
- PAGE
-
- GOOD PROPORTIONS OF CORE LENGTHS 7
-
- TABLE OF "SECONDARY" WINDINGS 24
-
- POLARITY TESTS 45
-
- DIMENSIONS FOR DIFFERENT SPARK
- LENGTHS 50
-
- TABLE SHOWING RESISTANCES AND FEET
- PER POUND OF COPPER AND GERMAN
- SILVER WIRE 64
-
- SPECIFIC INDUCTIVE CAPACITY 119
-
- WAVE LENGTHS AND TEMPERATURES 138-139
-
- TABLE OF RELATIVE COSTS OF MATERIALS 191
-
-
-
-
-LIST OF ILLUSTRATIONS.
-
-
- FRONTISPIECE, THE QUEEN 45″ SPARK COIL.
-
- FIG. PAGE
-
- 1. Section of Coil 4
-
- 2. Insulating Tube Ends 10
-
- 3. Sectional Winding 11
-
- 4. Section " First Method 12
-
- 5. " " Second Method 13
-
- 6. Proportional Diagram of Coil 15
-
- 7. Section Winder, End View 17
-
- 8. " " Face View 17
-
- 9. Assembly of Coils 18
-
- 10. Polechanging Switch 31
-
- 11. Disruptive Tesla Coil 35
-
- 12. Spark Coil for Gas Engine 38
-
- 13. Reproduction of a 32-inch Spark 47
-
- 14. Simple Medical Coil 53
-
- 15. Connections for Simple Medical Coil 55
-
- 16. Interchangeable Medical Coil 56
-
- 17. Vibrator for Medical Coil 60
-
- 18. Simple Contact Breaker 65
-
- 19. Imperfect Form of Contact Breaker 67
-
- 20. Superior Form of Contact Breaker 67
-
- 21. Spotteswoode Contact Breaker 69
-
- 22. Polechanging Contact Breaker 74
-
- 23. Wehnelt Interrupter 78
-
- 24. Ribbon Vibrator 81
-
- 25. Queen Contact Breaker 82
-
- 26. Adjustable Contact Breaker 86
-
- 27. Cone Contact Breaker 88
-
- 28. Coil Head Contact Breaker 89
-
- 29. Leyden Jar 101
-
- 30. Plate Condenser 102
-
- 31. Arrangement of Condenser Plates 104
-
- 32. Condenser Charging, First Method 110
-
- 33. " " Second Method 112
-
- 34. Adjustable Condenser 118
-
- 35. Spark between Balls 125
-
- 36. Short Spark between Balls 125
-
- 37. Sparkling Pane 125
-
- 38. Luminous Design 128
-
- 39. Electric Brush 128
-
- 40. Spectrum—Solar 132
-
- 41. Spectroscope and Coil 133
-
- 42. Simple Air Pump 141
-
- 43. Geissler Air Pump 144
-
- 44. Sprengel Air Pump 144
-
- 45. Solution Tube 150
-
- 46. Fluorescent Bulbs 150
-
- 47. Ruby Tube—Crookes 150
-
- 48. Iridio-platinum Tube—Crookes 151
-
- 49. Revolving Wheel 154
-
- 50. Tube Holder 157
-
- 51. Side View of Wheel 157
-
- 52. Geissler Tubes 160
-
- 53. Triangle on Disc 161
-
- 54. Maltese Cross on Disc 161
-
- 55. Gas Lighting Circuit 165
-
- 56. Connections for Gas Burners 169
-
- 57. Bartholdi Automatic Burner 172
-
- 58. Connections for Automatic Burner 174
-
- 59. The Grenet Cell 180
-
- 60. The Fuller Cell 184
-
- 61. The Gethins Cell 193
-
- 62. Lead Plate for Storage Cell 201
-
- 63. Wooden Separator 201
-
- 64. Charging with Rheostat 207
-
- 65. Charging with Lamps 207
-
- 66. Harrison Electrodes 211
-
- 67. Hydrometer 221
-
- 68. Hertz Resonator 227
-
- 69. Tesla Circuit 229
-
- 70. Tesla Cut Out 231
-
- 71. Tesla Cut Out, Top Plan 232
-
- 72. Circuit for X Ray Apparatus 237
-
- 73. Queen's Self-Regulating X Ray Tube 240
-
- 74. Transmitter for Wireless Telegraphy 250
-
- 75. Receiver for Wireless Telegraphy 252
-
- 76. The Branley Coherer 254
-
- 77. Clarke's Oscillator 259
-
- 78. Triple Oscillator 259
-
- 79. Air Wire Insulators 263
-
-
-
-
-CHAPTER I.
-
-COIL CONSTRUCTION.
-
-
-In commencing a description of the Ruhmkorff coil and its uses, a brief
-mention of the fundamental laws of induction directly bearing on its
-action will assist in obtaining an intelligent conception of the proper
-manner in which it should be constructed and handled.
-
-Any variation or cessation of a current of electricity flowing in one
-conductor will induce a momentary current in an adjacent conductor; and
-if the second conductor be an insulated wire coiled around the first
-conductor, also a coil of insulated wire, the effect is heightened. The
-intensity of the secondary or induced current increases with the number
-of turns of its conductor, the abruptness and completeness of the
-variation of current in the first or primary coil, and the proximity of
-the coils. And the insertion of a mass of soft iron within the primary
-coil by its consequent magnetization and demagnetization augments still
-further the inductive effect. There are other contributing causes which
-cannot be treated of here, but are of not so much importance as the
-foregoing.
-
-In the Ruhmkorff coil, which is an application of the above laws, the
-primary coil is of large wire and the secondary coil of extremely fine
-wire, of a length many thousand times greater than the wire of the
-primary coil. The current is abruptly broken in the primary circuit
-by a suitable device—the contact breaker or rheotome. The current
-induced in the secondary at the make of the circuit is in the opposite
-direction to that of the primary coil and battery, but the current
-at the break of the circuit is in the same direction as that of the
-primary. The effect of the current at the break of the circuit is
-more powerful than that at the make, which latter is also somewhat
-neutralized by the opposing battery current. A condenser or Leyden jar
-is connected across the contact breaker to absorb an _extra current_
-induced in the primary coil by the break of the circuit, which would
-tend to prolong the magnetization of the core beyond the desired limit.
-
-The whole apparatus is mounted on a wood base, having the condenser in
-a false bottom for the sake of compactness.
-
-It is not herein intended to describe all the minor operations in the
-construction of a Ruhmkorff coil. A sufficient description and review
-of the main points to be considered, however, will be given to enable
-a person fairly proficient in the use of simple tools to construct a
-serviceable instrument.
-
-The parts and their arrangement in relation to one another are shown in
-Fig. 1, but are not drawn strictly to scale, although very nearly so.
-
- [Illustration: FIG. 1.]
-
-_C_ is the core, consisting of a bundle of soft iron wires as fine as
-can be obtained. The greater the subdivision of the core the quicker
-will it respond to the magnetizing current in the primary coil, and
-lose its magnetism when the current ceases. It has another advantage,
-in that the disadvantageous eddy, or Foucault currents, are lessened,
-which fact, however, is of not enough importance to need extended
-consideration.
-
-Many coil-makers saturate the core with paraffin or shellac, which
-is of slight benefit. This core is wrapped in an insulating layer of
-paraffined paper or enclosed in a rubber shell, there not being any
-great necessity to use more than ordinary insulation between the core
-and the primary coil.
-
-In the majority of induction coils or "transformers" used in the
-alternating current system of electric lighting, the iron cores form
-a closed magnetic circuit. A closed magnetic circuit in a Ruhmkorff
-coil could be obtained by extending the iron core at each end and then
-bending and securing the ends together, forming, as it were, a ring
-partly inside and partly outside the coil. But although the inductive
-effects would be heightened and less battery power required, the
-slowness of the circuit to demagnetize would alone be detrimental to
-rapid oscillations of current.
-
-There would also be a loss from a greater hysteresis (energy lost in
-the magnetization and demagnetization of iron). A core magnetizes
-quicker than it demagnetizes, and the latter is rarely complete; a
-certain amount of residual magnetism remains, hysteresis being strictly
-due to this retention of energy (Sprague). Hysteresis shows itself in
-heat, but must not be confounded with Foucault or eddy currents. The
-latter are corrected by subdividing the metal, but the former depends
-upon the quality of the metal, and increases with its length.
-
-Moreover, a coil with a closed magnetic circuit requires an independent
-contact breaker.
-
-In most of the alternating currents used in lighting their rapidity of
-alternation is but one hundred and twenty-five periods per second. As
-in the simple electromagnet, the proportions of diameter and length
-of the primary coil and core will determine its rapidity of action. A
-short fat coil and core will act much quicker than a long thin one. But
-on a short fat coil the outside turns would be too far removed from the
-intensest part of the primary field. A good proportion of core length
-is given in the following table:
-
- Spark Length Iron Core.
- of Coil.
- ¼ 4″ × ½″
- ½ 5″ × 10∕16″
- 1 7″ × ¾″
- 2 9″ × 1″
- 6 12″ × 1⅛″
- 12 19″ × 1½″
-
-The primary coil _P_ consists of two or not more than three layers of
-insulated copper wire of large diameter, being required to carry a
-heavy current in a 2-inch spark coil, probably from 8 to 10 amperes.
-In designing the primary coil a great advantage arises from using
-comparatively few turns but of large wire. Each turn of wire in the
-primary has a choking effect upon its neighbor by what is termed
-self-induction.
-
-As the primary coil and core may be considered as an electro magnet,
-it may not be out of place to notice the rule governing such.
-Magnetization of an iron core is mainly dependent upon the ampere turns
-of the coil surrounding it—that is, one ampere carried around the core
-for one hundred turns (100 ampere-turns) would equal in effect ten
-amperes flowing through ten turns. Practically speaking, there would
-be certain variations to the rule, for one difficulty would arise in
-that the smaller wire used in conveying the smaller current would fit
-more compactly and allow more turns to be nearer the core, the active
-effect of the turns always decreasing with their distance from the
-core. And although a large current and few turns would not have so much
-self-induction, there would be trouble at the contact breaker, owing
-to the large current it would have to control.
-
-The most suitable sizes of wire for the primary coil are: No. 16 B.
-& S. for coils up to 1 inch spark; No. 14 B. & S. up to 4 inches of
-spark, and No. 12 B. & S. for a 6-inch spark coil. The coil should be,
-say, one-twelfth of the core length shorter than the core.
-
-_I_ is the insulating tube between the primary coil and the secondary
-coil _S_. Here great precaution is necessary to prevent any liability
-of short circuiting or breaking through of sparks from the secondary
-coil. This danger cannot be underestimated, and the tube should be
-either of glass or hard rubber, free from flaws, varying in thickness
-with the dimensions of the coil. It should extend at least one-tenth
-of the total length of the primary coil beyond it at each end. The end
-of this tube can be turned down so as to allow of the hard rubber reel
-ends being slipped on and held in position by outside hard rubber
-rings (Fig. 2).
-
- [Illustration: FIG. 2.]
-
-The secondary coil consists of many turns of fine insulated copper wire
-separated from the primary coil by the insulating tube and a liberal
-amount of insulating compound at each end. In coils giving under 1 inch
-of spark this coil may be wound in two or more sections.
-
- [Illustration: FIG. 3.]
-
-The usual manner of constructing these sections is to divide up the
-space on the insulating tube by means of hard rubber rings placed at
-equal distances apart, in number according to the number of sections
-desired (Fig. 3). The space between each set of rings, or between
-the coil end and a ring, is wound with the wire selected, the filled
-sections constituting a number of complete coils, which are finally
-connected in series. The sectional method of winding prevents the
-liability of the spark jumping through a short circuit, but heightens
-its tendency to pass into the primary coil at the ends, where it must
-be therefore specially insulated from it.
-
- [Illustration: FIG. 4.]
-
-In winding these sections there is a method now generally adopted which
-has many good points, although at first it may seem complicated. The
-old way of filling two sections was to wind both in the same direction
-as full as desired, then join the outside end of the left-hand coil
-to the inside end of the right-hand coil. This necessitated bringing
-the outside end down between two disks, or in a vertical hole in the
-sectional divider, and thereby rendered it liable to spark through into
-its own coil. This is shown in Fig. 4, _A_ and _C_ inside ends, _B_ and
-_D_ outside ends, the disk being between _B_ and _C_.
-
- [Illustration: FIG. 5.]
-
-Reference to Fig. 3 shows the new method, and Fig. 5 shows an enlarged
-diagram of sections 2 and 3 of Fig. 3.
-
-Sections 1 and 3, Fig. 3, are filled with as many turns as desired; the
-spool is then turned end for end, and sections 2 and 4 are wound, being
-thus in the opposite direction of winding to sections 1 and 3.
-
-The inside ends of 1 and 2 and 3 and 4 are soldered together, and the
-outside ends of 2 and 3 are also soldered together.
-
-The outside ends of 1 and 4 serve as terminals for the coil.
-
-This method of connection leaves all the turns so joined that the
-current circulates in the same direction through them all, as will be
-seen by an examination of the enlarged diagram, Fig. 5.
-
-Sprague, in his "Electricity: Its Theory, Sources, and Application,"
-recommends that the turns of wire in the secondary coil shall gradually
-increase in number until the middle of the spool is reached, and then
-decrease to the spool end, in order that the greatest number of turns
-be in the strongest part of the magnetic field (see Fig. 6). _D D D_
-are section dividers, _S_ secondary windings, _P_ primary coil. The
-selection of the size of wire to be used depends on the requirements as
-to the spark. If a short thick spark be desired, use a thick wire, say
-No. 34 B. & S.; if a long thin one, use No. 36 to No. 40 B. & S.
-
- [Illustration: FIG. 6.]
-
-Although it is impossible to lay down rules for determining the exact
-amount of wire to be used to obtain a certain sized spark, yet a fair
-average is to allow 1¼ pounds No. 36 B. & S. per inch spark for small
-coils and slightly less for large ones.
-
-The most satisfactory and perhaps the easiest way for large coils is to
-wind the secondary in separate coils, made in a manner similar to that
-employed in winding coils for the Thompson reflecting galvanometer.
-This method, first described by Mr. F. C. Alsop in his treatise on
-"Induction Coils," is somewhat as follows:
-
-A special piece of apparatus (Figs. 7 and 8) is necessary, but presents
-no great difficulty in manufacture. A metal disk, _D_, one-sixth of
-an inch thick and 7 inches in diameter, is mounted on the shaft _S_.
-A second disk is provided with a collar and set screw, _A_, in order
-that it may be adjusted on the shaft at any desired distance from the
-stationary one. When the diameter of the coil to be wound has been
-decided upon, a wooden collar, _W_, with a bevelled surface is slipped
-on the shaft, it corresponding in diameter with the desired diameter of
-the hole through the centre of the secondary coil. As these coils are
-going to be made as flat rings and slipped on over the insulating tube,
-a remark here becomes necessary on this diameter. Reference to Fig. 9
-will show that it is intended that the coils near the reel ends shall
-fit very loosely on the tube _T_ (Fig. 1)—in fact, that there shall be
-a clearance of possibly one-half inch in the extreme end, diminishing
-gradually to a fifteenth of an inch in the centre coils. Therefore it
-becomes necessary to provide a number of wooden rings equal to the
-desired diameter of the central hole in the coil. The thickness of
-the wood determining the width of the individual coil depends on the
-selection of the operator; but the rule may be laid down that the
-narrower the coils the better the insulation of the complete coil will
-be on completion.
-
- [Illustration: FIG. 7.]
-
- [Illustration: FIG. 8.]
-
- [Illustration: FIG. 9.]
-
-One-sixteenth of an inch is a very fair average, and has been generally
-adopted by the writer.
-
-A quantity of paper rings are now cut out of stout writing paper which
-has been soaked in melted paraffin. If a block or pad of letter paper
-be soaked in paraffin and allowed to become cold under pressure, the
-ring may be scratched on the surface of it and the block cut through on
-a jig saw. The central apertures of course will vary in size with their
-position on the tube _T_ (Fig. 9).
-
-The coil winder is now either mounted in a lathe or fixed in a hand
-magnet winder in such manner that it can be steadily and rapidly
-rotated. The wire to be wound comes on spools, which can be so
-threaded on a piece of metal rod that they turn readily. A metal dish
-containing melted paraffin is provided with a round rod, preferably of
-glass, fixed under the paraffin surface, so that it can rotate freely
-when the wire passes under it through the paraffin. Two paper rings are
-slipped on the winder that they may form, as it were, reel ends for the
-coil, and if the metal disks have been warmed it is an easy matter to
-lay them flat.
-
-The end of the wire is then passed through the paraffin under the
-glass rod and through the hole _H_ in the metal disk for a distance
-of, say, 6 inches, and held to the disk outside with a dab of paraffin
-or beeswax. Then the winder is rotated and the space between the paper
-disks is filled with wire. The paraffin, being hot, will adhere to the
-wire, and cooling as the wire lays down on the winder, hold the turns
-together and at the same time insulate them from each other. It will
-not be possible to lay the wire in even layers, as would be necessary
-in winding a wider coil, but the spaces can be filled up, using
-ordinary care that no radical irregularity occurs—that is, that only
-adjacent layers are likely to commingle.
-
-When the space is filled up to the level of the paper disks and the
-paraffin is hard, loosen the set screw, and removing the outside disk,
-the coil can be slipped off, or a slight warming will loosen it. Any
-number of these coils can be made, and there are the advantages in
-this mode of construction that a bad coil will not spoil the whole
-secondary, and that the wire can be obtained in comparatively small
-quantities.
-
-As each coil will not be of very high resistance, the continuity of
-the wire can be readily tested by means of a few cells of battery,
-connecting one end of the coil to one pole of the battery, and the
-other pole of the battery and coil end touched to the tongue. If a
-burning sensation is experienced, the connection is not broken. Where
-possible the coils should be measured as to their resistance on a
-Wheatstone bridge.
-
-When the requisite number of coils has been prepared, they are
-assembled in the following manner (Fig. 9): The coils, having their
-aperture diameter graded, are placed in order, and starting with the
-one having the largest hole, it is slipped over the primary protection
-tube _T_, one end being brought out through a hole in the reel end
-drilled vertically or between the reel end and the coil. A couple of
-paper rings are then slipped on the tube, and another coil placed over
-them, having its ends connected as in Fig. 3. This process is continued
-until all the coils are in place. The annular space between the coils
-and the tube _T_ (Fig. 9) is filled in with melted paraffin and the
-coils gently pressed together, so as to form a compact mass, paraffin
-being poured over the outside of the whole combination. Before winding
-any wire used in this work it must be perfectly dry, which end can be
-accomplished by subjecting the whole spool to a short period of baking
-in a moderately warm oven.
-
-The accompanying table gives the length of No. 36 silk-covered wire
-that will fill a linear space equal to one thickness of the wire in
-different-sized rings. This size wire wound tight will give 125 turns
-per linear inch. Therefore on a ring having a middle aperture of 1½
-inches and an outside diameter of 4 inches, there will be 156 turns, or
-a total length of 1347 inches. This is obtained as follows: 1½ inches
-× 3.1416 = 4.7124 (or 4.712); 4 inches × 3.1416 = 12.5664 (or 12.56);
-(4.712 + 12.56)∕2 = mean circumference—viz., 8.635 inches.
-
-This mean × number of turns in thickness of ring between the two
-circumferences—viz., 156 = 1347 inches.
-
-
-TABLE OF SECONDARY WINDINGS.
-
- ————————————————————————-+——————————————————+——————————————————+
- | 1½″ | 2″ |
- NO. 36 SILK-COVERED WIRE.|Aperture Diameter,|Aperture Diameter,|
- 125 TURNS PER LINEAR | 4.712″ | 6.283″ |
- INCH. 13,306 FEET PER |Aperture |Aperture |
- POUND. | Circumference. | Circumference. |
- ————————————————————————-+——————+————-+————-+——————+————-+————-+
- Outside diameter | 4″ | 5″ | 6″ | 4″ | 5″ | 6″ |
- Outside circumference |12.56 |15.70|18.84|12.56 |15.70|18.84|
- Mean circumference | 8.635|10.20|11.78| 9.421|10.99|12.56|
- Turns between | | | | | | |
- circumferences | 156 | 219 |282 | 125 | 188 | 250 |
- Distance between aperture| | | | | | |
- and outside, in inches | 1.25 | 1.75| 2.25| 1 | 1.50| 2 |
- Length of wire, in inches| 1347 | 2234| 2650| 1178 | 2066| 3140|
- ————————————————————————-+——————+————-+————-+——————+————-+————-+
- ————————————————————————-+——————————————————+
- | 2½″ |
- NO. 36 SILK-COVERED WIRE.|Aperture Diameter,|
- 125 TURNS PER LINEAR | 7.854″ |
- INCH. 13,306 FEET PER |Aperture |
- POUND. | Circumference. |
- ————————————————————————-+——————+————-+————-+
- Outside diameter | 5″ | 6″ | 7″ |
- Outside circumference |15.70 |18.84|21.99|
- Mean circumference |11.78 |13.35|14.92|
- Turns between | | | |
- circumferences | 156 | 219 | 282 |
- Distance between aperture| | | |
- and outside, in inches | 1.25 | 1.75| 2.25|
- Length of wire, in inches| 1838 | 2924|4207 |
- ————————————————————————-+——————+————-+————-+
-
-To obtain the length of wire necessary for a ring occupying more than
-the space of one turn on the primary insulating tube, multiply the
-length before obtained by the number of turns in the space it occupies.
-Thus a flat ring one-tenth of an inch thick would equal 1347 inches ×
-12.5.
-
-This rule is necessarily only approximate, owing to the way the wires
-bed on each other from their cylindrical section. In actual practice,
-when the wire is run through the paraffin bath not more than 50 per
-cent of the calculated wire will occupy the space. And the thickness of
-the paper rings must also be added when figuring the total length of
-the coil. In the iron-clad transformers or induction coils of highest
-efficiency used in the alternating current electric light system, the
-rule for determining the windings of the coils is based on the ratio
-of the turns of wire in the primary to the turns in the secondary, the
-electromotive force in the primary, and the lines of force cut by the
-windings.
-
-The secondary ends can be attached to binding posts mounted on the reel
-ends. Unless these reel ends be very high and clear the outside of the
-coil considerably, it is better to mount the binding posts on the top
-of the hard rubber pillars. A neat plan is to mount on the top of the
-coil a hard rubber plate reaching from reel end to reel end, and place
-the binding posts on that.
-
-A discharger consists of two sliding metal rods with insulated handles
-passing through pillars attached to the secondary coil. The inside ends
-of these rods is provided with screw threads for the ready attachment
-of the balls, points, etc., which are to be used. The substance to be
-acted upon is laid on a rubber or glass table midway between the rod
-pillars and slightly below the level of the rods.
-
-By hinging the rod pillars, or using a ball and socket joint, the
-discharger can be inclined so as to be better brought near the
-substance on the table.
-
-The next important part of the coil is the contact breaker.
-
-The armature _R_ is a piece of soft iron carried at the end of a stiff
-spring, in about the middle of which, at _B_, is riveted a small
-platinum disk or stud. The adjusting screw _A_ has its point also
-furnished with a piece of platinum, which is intended to touch the
-platinum on the spring when the latter is in its normal position. The
-core _C_ of the coil serves as an electro-magnet. When the current
-flows from the battery (represented by the figure at _L_) through the
-primary coil and armature spring to the adjusting screw, it causes the
-armature to be drawn to the magnetized core, but thereby draws the
-platinum disk away from the adjusting screw. In so doing it breaks the
-circuit, the magnet loses its power, and the elasticity of the spring
-reasserting itself, carries the armature back, thereby reclosing the
-circuit. This is repeated many times in a second, the result being a
-continual vibration of the spring, and a consequent interruption to the
-current.
-
-The condenser or Leyden jar _J_, connected as in the diagram to the
-base of the vibrating spring at _K_ and to the adjusting screw wire
-_M_, is constructed as follows: On a sheet of insulated paper is laid
-a smaller sheet of tinfoil, one edge of which projects an inch or so
-over one end of the paper. Another sheet of paper covering this carries
-a second sheet of tinfoil, one end of which projects as in the first
-sheet, but at the opposite end of the paper. Tinfoil and paper sheets
-are laid in this manner alternately until a sufficient number is
-attained. The projecting ends are then clamped together and the whole
-pile immersed in melted paraffin, as will be described in a subsequent
-chapter. Wires are affixed to these clamped ends which serve to connect
-the condenser with the contact breaker. The conventional sign for a
-condenser is that used at _J_, showing the two series of plates, the
-insulation or dielectric, as it is called, being understood.
-
-The size of condenser to use with different-sized coils varies
-according to the winding of the primary and the battery used. A primary
-coil of few turns would not necessitate as large a condenser as one of
-a large number of turns. At the same time, a condenser may be made of
-too great a capacity, and thereby weaken the action of the coil.
-
-The base upon which the coil and its parts are mounted may be of dried
-polished wood. But where the coil is designed to give large sparks—over
-2 inches—it is an advantage to use hard rubber one quarter of an inch
-and upward in thickness. Glass, were it not for the difficulty of
-drilling it and its brittleness, would be a desirable material for a
-coil base in a dry atmosphere. Hard red or black fibre coated with
-shellac varnish is also serviceable, and, moreover, is extremely easy
-to work. Slate must never be used; there is too much liability of
-iron veins being found in it, which in such high tension experiments
-as will be described would seriously impair the usefulness of the
-apparatus. The material selected for the base must be one that will
-not absorb moisture. A paraffined surface collects moisture up to a
-certain point in isolated drops, whereas a glass and even a hard rubber
-surface condenses the moisture as a film, which latter is extremely
-undesirable. But unfortunately the fact that a paraffined surface
-does not present a pleasing appearance would probably result in its
-rejection. And lastly, by mounting the coil on hard rubber blocks, or
-extending the reel ends to raise the coil body, a high insulation can
-be obtained at the sacrifice perhaps of appearance or height. From
-the care taken to insulate the secondary coil, it may be considered a
-superfluous precaution to so carefully select a base, but practical
-work with the instrument at some important crisis will demonstrate
-the necessity of extreme care in the smallest details relating to
-insulation. It may be well to note here that hard rubber is acted upon
-by ozone, and is thereby impaired as an insulator.
-
- [Illustration: FIG. 10.]
-
-The base forms the top of a flat box in which the condenser lies; but
-there are a few points worth considering right here. As the connections
-of the coil will probably be under the base, a sufficient space must
-intervene between the base and the top of the condenser. It is a
-good plan to lay the condenser at least one half inch below the top
-of this box, and fill up to, say, one eighth of an inch with melted
-paraffin, leaving the condenser wires projecting for attachment. The
-connections of the primary coil and contact breaker should by all means
-be soldered, not simply wires held under screw nuts. And, moreover,
-all wires under the base should be so run that they do not cross one
-another, which precaution only requires a little planning. Then, when
-the connections are all made and the base laid on top of the box, it
-can be pressed down if the paraffin be warm, so that the screw heads
-and wires mark out their own channels and cavities in which to lie.
-
-A commutator or pole-changing switch is often added to change the
-polarity of the battery current. The diagram of connection is shown in
-Fig. 10. When the levers are as in the figure, the circuit is broken
-and no current flows through the coil.
-
-
-COILS IN SERIES.
-
-Ruhmkorff coils can be connected in series, but it is not to be
-recommended. When it becomes necessary, however, the cores should be
-removed, and one long core inserted, extending through each primary.
-This will bring the time constants of each primary coil together and
-prevent the interference otherwise present. The primary coils and
-secondary coils are connected in series by assuming that they are
-but adjacent sections of one complete instrument. Of course, as the
-resistance of the primary is raised, the electromotive force of the
-battery must be raised also.
-
-
-OIL IMMERSED COIL.
-
-A highly satisfactory induction coil can be made without much labor and
-few tools, and will prove useful in many experiments which would not
-warrant a more expensive instrument.
-
-Make a bundle of soft iron wires, No. 22 B W G, for the core, ten
-inches in length and one inch or more in diameter. Wrap this with
-insulating tape or even ordinary tape to prevent the primary coil from
-coming in contact with the iron. Now, wind on a primary of two layers
-No. 14 B & S gauge cotton-covered copper wire, and insert the coil into
-a hard rubber (or glass preferred) tube large enough to hold the coil
-tight and to project an inch or so beyond the core ends.
-
-A secondary coil of about one pound No. 36 cotton-covered magnet wire
-should now be made on a hard rubber spool, the hole through centre
-of this spool must be at least one inch larger in diameter than the
-diameter of the primary cover. This spool should not exceed four
-inches in length, and is to be slipped over the primary coil and held
-suspended by blocks of wood in such a manner that it does not touch
-the primary coil or cover. The whole outfit is now immersed in an
-earthenware or glass vessel filled with linseed or heavy paraffin oil.
-The contact breaker and condenser will be mounted independently; the
-condenser for the two-inch spark coil will be suitable (see Table on
-page—7).
-
-
-"TESLA" COIL.
-
-The coil just described, without contact breaker or iron core, can be
-connected up and used in place of a "Tesla coil," which it resembles.
-The coils used by Nikola Tesla are so many and varied that it becomes a
-difficult task to describe a mode of construction which will meet the
-wants of those who ask for "Tesla" coils. The _American Electrician_
-gives a description of one wherein a glass battery jar, 6 inches × 8
-inches, is wound with 60 to 80 turns of No. 18 B & S magnet wire. Into
-this is slipped a primary, consisting of 8 to 10 turns of No. 6 B & S
-wire, and the whole combination immersed in a vessel containing linseed
-or mineral oil.
-
- [Illustration: FIG. 11.]
-
-
-DISRUPTIVE "TESLA" COIL.
-
-For Fig. 11 the specification is as follows: Secondary, 300 turns of
-No. 30 B & S silk-covered magnet wire, wound on rubber tube or rod,
-and the ends encased in glass or rubber tubes. This is inserted _into_
-the primary, which consists of two coils, each of 20 turns No. 16 B &
-S rubber-covered wire, wound separately on a long rubber tube not less
-than ⅛ inch thick. The last tube must be large enough to be very loose
-when the secondary coil is inserted in it, and it must project at least
-two inches over each end of the secondary. A hard rubber division must
-be placed between these primary coils. The four ends of the latter
-coils are connected _C C_ to two condensers and _D D_ to two discharger
-balls, the secondary wires going to the exhibitive apparatus. A further
-description of these connections is to be found in Chapter XII., also
-notes upon the use of the disruptive coil.
-
-
-_Coils for Gas Engines._
-
-These are either primary only or primary and secondary. Two to three
-pounds of No. 14 B & S magnet wire are wound on an iron wire core eight
-to ten inches in length by one inch in diameter. The contact is made
-and broken in the igniter of the engine as at the wipe spring of a
-ratchet gas burner. Four to eight large cells of dry battery are used,
-or eight cells Edison-Lalande—iron-clad type. Number of cells varies
-with size of coil needed, some classes of engines require a heavier
-spark than others to ignite the vapor.
-
-When a primary and secondary are used, the primary should be made of
-two or three layers No. 14 B & S magnet wire, and a secondary of one
-pound No. 34 B & S magnet wire. There can be an independent contact
-breaker or the coil can be made up similar to a one-half inch spark
-Ruhmkorff coil (see Chapter I.).
-
- [Illustration: FIG. 12.]
-
-The method of connecting up a coil of the latter description is shown
-in Fig. 12, which is self-explanatory. It shows a form of cam-shaft
-switch which is operated by the engine, and which opens and closes the
-primary circuit of the induction coil, the sparks from the secondary
-winding passing between the points of the igniter in the engine
-cylinder. As shown in Fig. 12, the igniter or ignition plug is similar
-in operation to a coil discharger, the two terminals being, however,
-insulated from each other by the use of porcelain. To ensure a good
-insulation under the severe working conditions has been somewhat of a
-task, but it seems to have been attained in the types of igniters known
-as the Splitdorf and the Roche or New Standard.
-
-The Splitdorf gas-engine coil is the result of much experiment and
-careful design. It is built to stand hard usage, and the insulation
-used has been adopted only after exhaustive test. In automobile work,
-where a heavy strain is made upon the engine, as in climbing heavy
-grades, it has been found that a stronger spark gives surer results.
-This would indicate more battery current through the coil, and it is a
-wise precaution to have a few extra cells attached that can be switched
-on if necessary.
-
-In constructing spark coils for gas engines particular care must
-be given to the contact breaker. In most types of gas or oil vapor
-engines it is absolutely necessary to have the spark pass with uniform
-regularity, and immediately and surely when required. For automobiles
-or where the apparatus is subject to jar, a heavy iron vibrating
-armature would become unreliable by reason of its inertia and its
-responding to shock. At every jolt of the vehicle it would jar and get
-out of rhythm, and it certainly seems preferable to use a mechanical
-contact apparatus whenever feasible. In the older type of gas engine
-the spark is made by mechanism breaking contact right in the vapor. The
-actual arrangement of these devices is detailed and illustrated in the
-later works on gas and oil engines.
-
-
-RESISTANCE COILS.
-
-Although foreign to the title of this book, these coils will be
-mentioned, being often necessary as accessories to the operation of
-coils, wireless telegraphy, etc. These are coils of insulated German
-silver wire, wound to a specified resistance. The main feature about
-those designed for testing is that they are wound non-inductively—that
-is, the wire is wound double in such manner that the current flows
-both ways around the turns, and so neutralizes the inductive action.
-In cases where dynamo current is to be used, as in telegraphs operated
-from dynamo current, the coils are wound on tin tubes to make them
-fireproof and yet radiate the heat. As the resistance of German silver
-varies very largely, only approximate figures can be given. The table
-(page 64) has been made up from the best averages obtainable. The
-carrying capacity of resistance coils varies with their construction,
-the better they can radiate heat, the more current they can safely
-carry.
-
-
-GENERAL REMARKS ON COILS, ETC.
-
-Ruhmkorff induction coils should always be fitted with a switch to
-open, close, or reverse the power circuit, a double throw, double
-pole, baby knife switch, mounted on a separate porcelain base, is very
-suitable. Such a switch is open when the handle is vertical, and it
-should always be left so when changing connections, fixing battery,
-etc. A large, well-finished coil will have the secondary wires brought
-in rubber tubes to binding posts mounted on hard rubber pillars, or
-to binding posts mounted considerably above the coil cover level.
-A very neat mode is shown in the frontispiece on the large 45-inch
-spark coil. Here the secondary wires go to hard rubber pillars, which
-also carry adjustable rod dischargers. These rods are movable towards
-or away from each other by means of the large hard rubber handle to
-which they are connected by a simple system of levers. In this coil
-the secondary is moulded on a flexible tube, which fits loosely over
-the primary tube in order to compensate for changes of temperature
-and consequent expansions and contractions. All well-designed coils
-should be so arranged that the primary coil and core can be readily
-removed from the secondary, or _vice versa_. It is sometimes desirable
-to use a different primary. This arrangement will greatly facilitate
-any necessary repairs. It must be always remembered that the working
-of a coil depends on the insulation between primary and secondary.
-_Spare no pains to have perfect insulation_; it is a hopeless task to
-reinsulate a broken-down secondary, although the sectional method of
-winding facilitates repairs. In large winding rooms it is customary
-to have a revolution counter connected to the spindle, so that the
-number of turns can be seen at all times. A bicycle cyclometer can be
-readily fitted up for this purpose, and will be found of considerable
-assistance where a number of sections are needed, each with a similar
-number of turns. In the commercial construction of telephone coils and
-magnet spools it is often the rule to specify only the number of turns
-of the requisite size wire, the ampere turns of the coils being thus
-regulated.
-
-
-THE TESTING OF A COIL FOR POLARITY.
-
-This is often necessary, and may be done in a variety of ways. When the
-coil is working, and sparks be passed between fine wires mounted on the
-discharger, the positive wire tip will be cold, whereas the negative
-end will be quite hot. In vacuo, the positive shows a purple red when
-the negative glows with a bluish violet. The decomposition of water,
-which consists of oxygen and hydrogen in the formula H_{2}O, is readily
-accomplished by the secondary current, and the greatest volume of gas
-(hydrogen) will be evolved at the _negative pole_. For ready reference
-a summary of these facts is given below:
-
- Positive | Negative
- |
- Cold wire, | Hot wire,
- Anode, | Cathode,
- + sign, | - sign,
- Purple red, | Bluish violet,
- Zinc plate, | Carbon plate,
- (Carbon) pole, | Zinc pole,
- Oxygen gas. | Hydrogen gas.
-
-
-Although it is customary to use bundles of fine, soft iron wire for
-coil cores, very excellent results have been obtained with cores made
-up of soft iron filings. These filings should be tightly packed in the
-core tube and have a soft iron head at the contact breaker end. Filings
-demagnetize very quickly and prevent the formation of destructive eddy
-currents, which have been previously discussed (Chapter I.).
-
-Modern practice tends towards a lengthening of the core and primary, in
-some cases fully 20 per cent of the core length projects from each end
-of the coil. One result must be as in electromagnets, the longer the
-core, the longer it takes to magnetize or demagnetize. But even here
-it is a matter of individual construction.
-
-The common practice is to make coils to be in a horizontal position;
-there is no reason why they cannot be made to stand on end. In fact,
-this position to an extent takes off some of the strain on the primary.
-It is mostly a matter of choice or convenience.
-
-As to the possible output of an induction coil, it depends upon design
-and construction; but S. P. Thompson gives the following law in his
-work on Electricity and Magnetism: The electromotive force generated in
-the secondary circuit is to that employed in the primary nearly in the
-same proportion as the relative turns of the two coils.[1]
-
- [1] We do not attempt to reconcile this quotation with the enormous
-estimates of spark potential.
-
-In selecting a Ruhmkorff coil, it must be remembered that the rating
-in spark length is subject to question. Supposing two similar coils
-be operated, one with a rapid vibrator and the other with a slow
-vibrator, other things being equal, the slow vibrator will give the
-greatest spark length. Again, the appearance of the spark is of vast
-importance. Although two coils might be sparking across the same
-length air-gap, the one giving the whitest and thickest continuous
-succession of sparks is the better. Fig. 13 shows a reproduction from
-a photograph of a spark 32 inches long, generated by the coil shown on
-the frontispiece.
-
- [Illustration: FIG. 13.]
-
-It is easy to take a coil, and by snapping the vibrator contacts
-together a few times a spark of thin bluish character will jump across
-a gap, of length far exceeding the spark gap when vibrator is working
-at normal speed. But this spark only passes at irregular intervals,
-seemingly gathering strength for its forced leap. It must not be
-considered in rating the coil.
-
-In winding primary coils it is proposed to reduce the self-induction
-or inductance of its adjacent coils by means of similar methods used
-in winding electromagnets. The primary winding, instead of being
-composed of a number of turns of one large wire, is made up of a
-multiple winding of small wires, aggregating the conductivity of the
-large wire. This materially reduces sparking at the contact breaker,
-and certainly allows of a closer bedding of wire nearer the core, also
-giving a greater percentage of ampere turns. Another scheme which uses
-the Dessauer contact breaker provides two separate primary windings,
-opening one when the other closes. Such schemes as these come well
-within the scope of the experimenter, and it is highly possible that
-valuable improvements will be made in coil design during the coming
-years.
-
-
-FAILURE TO WORK.
-
-The following are the commonest causes of coils not working to their
-best limit: Contact breaker contacts dirty, burned, stuck, too small,
-not in good parallel relation face to face of platinum.
-
-Secondary wires crossed outside coil, often happens that the secondary
-is quietly sparking away into or through some object touching it,
-particularly when long wire connections are run from secondary to place
-of desired sparking.
-
-Condenser too small, burned out, badly insulated (see other pages on
-this subject).
-
-Battery too small—too high internal resistance or wires leading from
-battery to coil too small—for ordinary coil work, distance of, perhaps,
-ten feet, use No. 10 to 12 B & S flexible lamp cord or solid wire.
-Ruhmkorff coils require plenty of current to produce large sparks.
-
-DIMENSIONS FOR DIFFERENT SPARK LENGTHS.
-
- ——————————————————————+————————-+——————-+————————-+——————-+———————
- | ½ | 1 | 2 | 6 | 12
- | inch | inch | inches | inches| inches
- ——————————————————————+————————-+——————-+————————-+——————-+———————
- Foil sheets | 5½ × 4 | 6 × 4 | 6 × 6 | 10 × 5| 12 × 8
- Number | 40 | 40 | 60 | 60 | 60
- Paper sheets | 6½ × 5 | 9 × 5 | 8½ × 7 | 12 × 7| 14 × 10
- Number | 60 | 60 | 80 | 80 | 80
- Core length | 5 | 7 | 9 | 12 | 19
- Core diameter | ⅝ | ¾ | 1″ | 1⅛ | 1½
- Primary size B & S | 16 | 14 | 14 | 12 | 10
- Secondary size B & S. | 36 | 36 | 36 | 36 | 38
- Core wire size B W G. | 22 | 22 | 22 | 22 | 22
- Quantity in pounds of | | | | |
- secondary wire | ¾ | 1¼ | 2½ | 7 | 12
- Layers of primary | 3 | 3 | 2 | 2 | 2
- Area of paper, sq. in.| 2,000 | 2,700 | 4,800 | 6,600 |11,000
- Area of foil, sq. in. | 880 | 960 | 2,100 | 3,000 | 5,760
- ——————————————————————+————————-+——————-+————————-+——————-+———————
-
-As it is not always convenient to procure paper and foil in set sizes,
-the area of material needed for condensers is also given. The above
-table is approximate. It represents data collected from the best modern
-practice. The gauge above given for copper wire is that of Brown &
-Sharpe, and is used throughout these pages.
-
-
-MEDICAL COILS.
-
-The main points of difference between coils for electrotherapeutics and
-Ruhmkorff coils is that the former are devoid of condensers, are rarely
-insulated to a high degree, and are arranged for current strength
-regulation. The modes of regulation are many, briefly the principal
-are: (_a_) In coils with independent circuit breakers, sliding both
-core and primary coil out of the secondary together or independently.
-(_b_) Moving a metal tube over or off the primary coil or core or both.
-Many combinations of these methods are practised. Attempts have been
-made to regulate battery current by rheostat, but it is not feasible,
-except in large stationary outfits. Cheap medical coils are wound with
-bare wire, with layers of thread between adjacent turns, or even only
-bedding the wire turns in paraffined paper. It is not intended to
-convey the idea that winding bare wire coils is a makeshift; far from
-it. This method is being very generally adopted in telephone work. But
-it requires special and delicate machinery, and is unsuited to amateur
-work, where slight differences of cost or labor are insignificant.
-Others for specific purposes consist of a primary coil only. The best
-and most complete made are so arranged that independent secondary
-coils of different sized wires can be used with the one primary, being
-readily slipped on or off as required. There is another scheme of
-regulation, where the coil is wound in sections and these sections cut
-in or out by means of a switch, but it is not desirable.
-
-
-MEDICAL COIL WITH TUBE REGULATION.
-
- [Illustration: FIG. 14.]
-
-Figure 14 shows a coil with tube mode of regulation. The core _C_
-consists of a piece of iron tube, very thin, 4 inches long by ⅜ inch
-diameter, and filled with soft iron wires. One end of this core is
-firmly fixed in the left-hand bobbin head. The object of the iron
-tube is to prevent the sliding tube from catching in the iron wires,
-otherwise it can be dispensed with. Over this tube is slipped a brass
-tube _T_, ending in a handle _H_ at the right-hand end; this must work
-easily over the core tube. The spool for the primary is now made up by
-fixing the other bobbin head on a paper or fibre tube and fastening
-its free end to the left-hand bobbin head, or the spool can be made in
-the usual way by glueing up two spool ends on a fibre or paper tube and
-securing the iron core firmly in one end, allowing room, of course, for
-the brass tube to slide in at the right-hand end. The primary winding
-is three or four layers of No. 20 B & S gauge cotton-covered magnet
-wire, the ends being brought out for future connection. Over this is
-now laid a few layers of paraffined paper, and ten or twelve layers of
-No. 36 B & S cotton-covered magnet wire is wound on for the secondary
-coil.
-
-The contact breaker _R_ is in no way different from the simple form
-described in Chapter II. Its construction can be readily seen from the
-figure.
-
-A layer of cloth of the kind used in covering electromagnets is laid on
-over the secondary, and the coil is ready to be attached to the base.
-The base is seven inches long by three wide, and has little feet at its
-four corners to elevate it from the table and prevent abrasion of the
-connections underneath.
-
- [Illustration: FIG. 15.]
-
-The connections are as given in Fig. 15. When in operation, the
-electrode cords being attached to binding posts, Nos. 1 and 2 are in
-circuit with the secondary coil only. When at Nos. 2 and 3 they receive
-the induced current or extra current in the primary, caused by the
-break of the battery circuit (see page 3).
-
-
-MEDICAL COIL WITH INTERCHANGEABLE SECONDARIES.
-
-This form of coil is the only one for practical medical work, and more
-space will be given to its construction than to the foregoing, which
-is suited only for limited use.
-
- [Illustration: FIG. 16.]
-
-Fig. 16 shows side elevation of coil on base. The design can be largely
-varied, also it can be used either for a wall board, a cabinet top,
-or made to be carried in a case containing battery, electrodes, etc.
-_S_ is one of the secondary coils, of which at least three should be
-provided. The dimensions are, of course, the same—namely, four inches
-long by 3½ inches wide over all. The spool ends are furnished with heel
-pieces, which slide under the brass track bar _T_. This accurately
-centres the coil and prevents it from working loose.
-
-
-WINDINGS FOR SECONDARY.
-
-The following windings for removable or interchangeable secondary coils
-are those most in use.
-
-Coil No. 1. 4500 feet (.375 pound) No. 36 B & S, approximating 1800
-ohms. This may be led out in three divisions by means of switch on coil
-head. First division, 4500 feet; second division, 3000 feet; third
-division, 1500 feet.
-
-Coil No. 2. 2400 feet (.6 pound) No. 31 B & S, about 350 ohms, divided
-into 2400 feet, 1500 feet, and 900 feet.
-
-Coil No. 3. 750 feet (1 pound) No. 22 B & S in one coil, or two
-divisions of 500 and 750 feet, respectively; approximate resistance of
-wire, 125 ohms.
-
-Coil No. 4. It may be necessary to obtain currents of extremely high
-tension, in which case a coil may be prepared of 5000 feet No. 38 B &
-S, or No. 40 B & S preferably.
-
-The finer the wire, the less current and the most sedative effect; the
-coarser the wire, the more current with corresponding increased painful
-action.
-
-The spools, in fact as much of the framework as possible, should be
-made of hard rubber, to which a fine finish can be given, although
-mahogany, rosewood, or even stained oak can be used. On each side of
-the right-hand spool heads a flat brass spring is screwed, making the
-contact for the secondary wires on brass strips screwed on top of
-the track rods. These secondary connections can be made by means of
-flexible cords to binding posts, but the sliding contact is preferable.
-The primary coil _P_ is firmly held in the left spool head, and
-consists of a core of No. 22 B W G soft iron wires, insulated and wound
-with three layers of No. 20 B & S magnet wire. The outside of this coil
-is neatly enclosed in a hard rubber tube to permit of the secondary
-coils sliding freely upon it. It is better, however, for the secondary
-coils not to touch the primary tube. The vibrator, or contact breaker,
-should be of the adjustable form shown in Fig. 17. The adjusting screw
-for the contact breaker can be mounted in a brass lug carried by the
-spool head.
-
-Connections of this coil are substantially the same as those of
-the first-described medical coil. This apparatus is well worthy of
-elaboration; it should be fitted with a ribbon vibrator as well as an
-adjustable speed slow vibrator, a switch controlling either. A great
-variety of secondary coils can be made, those of coarse wire taking
-the place of the current from the contact breaker. The vibrators
-should be operated from an independent battery, although in the last
-coil described the magnet may be wound with the same size wire as the
-primary and then be in series with it. The secondary spools can be
-made of stained hard wood ends fitted on to fibre tube, which latter
-is easily procurable. Particular attention should always be paid to
-the spools and heads; if not properly made, they may come apart, and a
-disastrous unravelling of the wires ensues.
-
- [Illustration: FIG. 17.]
-
-
-BATH COILS.
-
-A coil much used for electric baths has a primary winding only,
-regulated by the sliding in and out of the iron core, which
-necessitates the use of an independent vibrator, or else by varying
-the current strength with a rheostat. The general directions given
-before will answer in the present case, the only data necessary being
-the size of wire, which should be about six to ten layers of No. 20 B
-& S. The coil with movable secondaries here comes into service. Strong
-currents are needed for bath work, and any variety of winding can be
-used with this make of coil. There are so many descriptions of bath and
-small medical coils in the electrical magazines published for amateur
-workers, that it is hardly necessary here to give more than a mention
-of the principal ones.
-
-
-HINTS IN CARING FOR MEDICAL COILS.
-
-A few remarks on medical coils and their diseases may not be amiss;
-often a very little defect, if remedied in time, will prevent costly
-repairs.
-
-The main care in medical electrical apparatus is the battery (see
-Chapter X. for descriptions of coil batteries and their operation).
-Clean, fresh solutions and clean contacts are essential. Keep zincs
-well amalgamated, remove wires from binding posts, and scrape bright
-the metal where the wires make connection; see no fluid is splashed on
-contacts, clean all contact springs periodically. The Edison-Lalande
-battery is probably the best for medical use, but even this requires
-occasional attention as to contacts, new zincs, fresh solution, etc.
-
-Poor adjustment at contact breaker, dirty or corroded contacts, loose
-wires, loose binding posts, corroded binding posts, are often the only
-trouble in a coil refusing to work.
-
-Flexible cords are fruitful of trouble: the tinsel breaks, and there is
-no circuit; gets wet and crosses or causes a leak; cord tips get loose
-and alternately open and close a contact; one minute all is well, next
-minute no current can be obtained. Another trouble in acid batteries
-is caused by leaving the zincs in the fluid. It is easy to do it in
-most cases, although the ingenuity of the leading medical electrical
-apparatus makers to-day is directed to this point. Cleanliness and
-careful inspection of all contacts is well repaid; carelessness surely
-brings its evils.
-
-It is very desirable in medical work to eliminate the noise attendant
-upon the working of the coil vibrator. This jarring or humming is often
-in itself a source of irritation to a nervous patient. The sound can be
-deadened in various ways, for instance, by placing over the vibrator
-a temporary wood cover, lined with felt, resting upon a soft rubber
-gasket; or in any other manner that may suggest itself to the operator.
-
-TABLE SHOWING RESISTANCES AND FEET PER POUND OF COPPER AND GERMAN
-SILVER WIRES.
-
- ——————————+————————-+——————-++——————————-++——————————-
- | | || COPPER. || GERMAN
- | | || || SILVER.
- Gauge, | | ++——————————-++——————————-
- Browne |Diameter.| Feet || || ONLY
- & Sharpe. | |per lb.|| Ohms ||APPROXIMATE.
- | | || per ++——————————-
- | | || 1,000 ft. || Ohms
- | | || ||per 1,000 ft.
- ——————————+————————-+——————-++——————————-++——————————-
- 8 | .1285 | 20 || .62881 || 11.77
- 9 | .1144 | 25 || .79281 || 11.83
- 10 | .1019 | 32 || 1 || 18.72
- 11 | .09074 | 40 || 1.2607 || 25.59
- 12 | .08081 | 51 || 1.5898 || 29.75
- 13 | .07196 | 64 || 1.995 || 37.51
- 14 | .06408 | 81 || 2.504 || 47.30
- 15 | .05707 | 102 || 3.172 || 59.65
- 16 | .05082 | 129 || 4.001 || 75.22
- 17 | .04525 | 162 || 5.04 || 94.84
- 18 | .0403 | 204 || 6.36 || 119.61
- 19 | .03539 | 264 || 8.25 || 155.10
- 20 | .03196 | 325 || 10.12 || 190.18
- 21 | .02846 | 409 || 12.76 || 239.81
- 22 | .02535 | 517 || 16.25 || 302.38
- 23 | .02257 | 660 || 20.30 || 381.33
- 24 | .0201 | 823 || 25.60 || 480.83
- 25 | .0179 | 1039 || 32.20 || 606.31
- 26 | .01594 | 1310 || 40.70 || 764.59
- 27 | .01419 | 1650 || 51.30 || 964.13
- 28 | .01264 | 2082 || 64.80 || 1215.76
- 29 | .01126 | 2623 || 81.60 || 1533.06
- 30 | .01002 | 3311 || 103 || 1933.03
- 31 | .00893 | 4165 || 130 || 2437.23
- 32 | .00795 | 5263 || 164 || 3073.77
- 33 | .00708 | 6636 || 206 || 3875.61
- 34 | .0063 | 8381 || 260 || 4888.49
- 35 | .00561 | 10560 || 328 || 6163.97
- 36 | .005 | 13306 || 414 || 7770.81
- ——————————+————————-+——————-++——————————-++——————————-
-
-
-
-
-CHAPTER II.
-
-CONTACT BREAKERS.
-
-
- [Illustration: FIG. 18.]
-
-The simple form of contact breaker already described is useful up to a
-certain point, but it has disadvantages. Its rate of vibration is only
-variable through narrow limits, and it is not suitable for very heavy
-currents. But as it stands it has done long service, and will be used
-probably wherever the requirements from it are not exacting. The most
-desirable form of this simple spring break is shown in Fig. 18. _R_
-is the soft iron armature; _S_, the spring; _C_, check-nut which holds
-the adjusting screw _A_ from becoming loose; _T_, a second adjusting
-screw used to tighten the spring and so raise its rate of vibration;
-_K_ is the base to which one wire of the coil is attached; _L_, base of
-adjusting device to which battery wire runs at _I_. Where tightening
-screw T passes through the pillar of the adjusting screw, the hole
-therein is bushed with rubber to prevent accidental contact. Both _A_
-and _T_ are provided with insulating heads of rubber or ivory. At _B_
-are the platinum contacts, which should be fully ⅛ inch in diameter.
-
-One serious defect in the action of the simple spring vibrator (Fig.
-19) is the tendency of the spring to vibrate, as it were, sinusoidally.
-This causes an irregularity in the rate of the vibrations, which
-affects the discharge of the coil very considerably. By far the better
-plan is to use a very short thick spring riveted to an arm carrying
-the armature at its end (Fig. 20). _R_ is the armature, _S_ the piece
-of spring, and _K_ the point of attachment to the base. The actual
-width of the portion of the spring which vibrates—the hinge portion, it
-might be called—should not be over ⅛ inch.
-
- [Illustration: FIG. 19.]
-
- [Illustration: FIG. 20.]
-
-The rate of motion is high; but an erroneous notion has been taken of
-its performance by many persons in the knowledge of the writer. The
-rate of vibration is _not_ wholly dependent on the size, or, rather,
-smallness of its spring; the arm and armature considerably alter this,
-although they are not pliable, by reason of their mass and the momentum
-consequent on their mass.
-
-A word here on the size of the armature. It should be somewhat larger
-than the face of the electro-magnet core, and should be thick—that is,
-in a circular form—say one half its diameter. Of course this does not
-apply to the steel lever armature before mentioned. It is impossible to
-lay down arbitrary rules where the conditions are not determined, but a
-very small amount of experimenting will demonstrate the correct lines
-on which to build.
-
-When in action, all rapid rheotomes give out a definite musical note
-whereby the rate of vibration can be determined. Reference to any work
-on acoustics will show a table of the number of vibrations necessary to
-produce any stated musical note. The foregoing style of rheotome forms
-the basis of very nearly all those which are in use. The shorter and
-stouter a spring the more rapidly will it vibrate, and _vice-versa_.
-Carrying out this rule, we can manufacture an instrument which will
-give as high as 2500 vibrations per second (Fig. 21).
-
- [Illustration: FIG. 21.]
-
-The armature _A_ is a piece of flat hard steel bar ¼ × ½ inch, held
-rigidly on the metal support _S_ and just clearing the upper surfaces
-of the magnet cores _C_. The adjusting screw _P_ should be provided
-with an arm, _B B_, whereby the rotation of it can be delicately
-varied. This screw must also be firmly held or the high speed of the
-armature will jar it loose. A check-nut on each side of the frame
-carrying it should be provided in every case. The necessary platinum
-contact can be hammered into a hole drilled before the armature is
-hardened. The proper place for this contact is about one fourth of
-the total length of the armature from its support, although in the
-simple contact breaker it can be placed at the distance of one third
-if desired. The reason is that the concussion of the adjusting screw
-dampens the free vibration, and the amplitude thereof is lessened in
-addition to the counter vibrations of the screw disturbing the regular
-vibrationary series.
-
-Owing to the fact that the amplitude of the armature vibration is so
-small, a very delicate adjustment is necessary. The adjusting screw
-can be placed nearer the free end, but for the reasons given it is not
-to be desired. The metal bridge should be a solid casting, and the
-armature clamped by more than one screw.
-
-The mercury vibrator, which is applied to almost every large coil, is
-as follows:
-
-A pivoted arm carries on one end a soft iron armature, which is
-attracted by the coil core. The other end is provided with a platinum
-point adjustable by a set screw. This platinum point dips into a
-mercury cup—a glass cup containing mercury, with a thin layer of
-spirits of turpentine. The object of the spirits of turpentine, which
-is a non-conductor, is to help choke off the spark which would ensue
-whenever the platinum point was raised from the mercury.
-
-A form of contact breaker which will admit of great variation of speed,
-and which is adapted to carry large currents, is the wheel-break,
-constructed in the following manner:
-
-A brass or copper disk 3 inches or more in diameter and upward of ½
-inch thick has its periphery divided by a number of saw cuts, which
-divisions are often filled in with plugs of hard rubber or fibre. This
-disk is mounted on a shaft, which latter is either the shaft of an
-electro-motor, or is provided with a pulley by which it can be rapidly
-rotated. A strip of spring copper on each side of the disk presses
-upon the toothed surface, one strip being connected to the coil and
-the other to the battery or other current source. It will now be seen
-that when the disk rotates the slits or pieces of hard rubber cause the
-break in the circuit through the brushes or copper strips, the rapidity
-of the breaks depending upon the rate of rotation of the disk, and the
-number of slits in the wheel.
-
-The slits or rubber pieces should be one-half the width of the
-intervening brass, but must be at least one sixteenth of an inch in
-width, especially where a high voltage is used in the primary coil.
-
-The shaft of the machine may serve as one point of connection in place
-of one of the copper brushes; but in this event either a wide journal
-must be used, or else some conducting substance, as plumbago, replace
-the lubricating oil in the bearings.
-
-
-POLE CHANGING BREAKER.
-
-Fig. 22 shows a diagram of a pole changing contact breaker which will
-allow of rapid alternations of current. It is operated by an electric
-motor by preference, although any motive power can be applied to it.
-
- [Illustration: FIG. 22.]
-
-_W a W b_ are two brass wheels, the peripheries of which are broken by
-the insertion of insulating blocks _I I_, shown black in the sketch. _S
-S_ are the shafts on which the wheels are mounted, the two wheels being
-necessarily insulated from each other. 1, 2, 3, 4 are four brushes of
-copper pressing on the rim of the wheel and leading in the current
-from the battery _B_. The primary coil is attached to the brass
-body of the wheel or to the shafts. When the wheel is in the position
-shown, the coil and battery are on an open circuit; but on the wheel
-commencing to revolve, the brushes 1 and 2 bear on the brass, and the
-current flows from the positive pole of the battery to 2 through the
-wheel _W a_ to the coil _P_, up through wheel _W b_ and out at 1 back
-to the battery. The next position of the brushes 1 and 2 will be on
-the insulations, and 3 and 4 will come into action. Then the positive
-current will reach _W b_ by means of brush 3, and after traversing
-the primary coil and wheel _W a_, emerge at 4 to the battery, thus
-reversing the current through _P_ as many times as there are sets of
-segments, which latter can be multiplied according to requirements. The
-main point to be considered after that of good connections is that the
-brushes 1 and 3 and 2 and 4 do not at any time touch any part of the
-brass wheel at the same time, as this would short circuit the battery.
-This is avoided by making the insulating space longer than the brass
-surface, and adjusting the brushes as in the sketch, that each pair of
-them is a fraction further apart than the length of the brass tooth.
-
-Accordingly, a wheel may be constructed with many segments and rotated
-at a high speed and rapid reversals of current produced, the uses of
-which are manifold.
-
-As will be described in the notes on the Tesla effects, an
-electro-magnet, the poles of which are brought near the sparking point
-of the contact breaker, will help wipe out the spark, and so assist the
-suddenness of the break.
-
-An extremely successful expedient in operating contact breakers is
-to employ a high-pressure air blast directed point blank against the
-contact point. The effect of this air blast when the contact is made is
-of course null, but on the platinum surfaces becoming separated, the
-high air pressure produced forms a path of extremely high resistance,
-and tends to blow off the spark as soon as it is generated. The stream
-of air should issue from an insulated nozzle of glass or rubber, and
-should not contain moisture.
-
-
-WEHNELT INTERRUPTER.
-
-One of the most important inventions in coil work is the electrolytic
-interrupter of Wehnelt. Briefly, the apparatus consists of a vessel
-containing a solution of acid, into which dip two electrodes connected
-in series with the source of power and the primary of the coil. Upon
-passing a current through the combination the fluid becomes agitated at
-the electrodes and a rapid make and break of the current ensues (Fig.
-23).
-
- [Illustration: FIG. 23.]
-
-It requires considerable electromotive force for operation, a minimum
-of 40 volts being desirable. Its rapidity of action varies up to and at
-times exceeding 4000 interruptions per second. A Wehnelt interrupter
-can be made as follows: Procure a glass jar _J_ holding about one
-quart or a little less, also a cover for same _C_, a piece of sheet
-lead _L_ large enough to fit loosely across the jar and yet not touch
-the bottom, eight inches of one-quarter-inch glass tube _M_, a few
-inches of No. 20 platinum wire _P_, and two ounces of mercury. Heat
-the end of the glass tube in a gas flame, and bend an inch or less at
-a right angle; at the same time seal in the platinum wire by means of
-a blowpipe, so that the tip just projects from the bent end of the
-tube. This sealing can be accomplished readily by one unused to working
-glass, but almost any philosophical instrument maker will have it done
-at small cost. Holes being bored through the cover, the lead plate
-and the glass tube are fitted in, the platinum point almost touching
-the lead. Adjustment is, however, easy, as the tube, being turned,
-will retract or advance the platinum point from or towards the lead
-electrode. Nearly fill the jar with a solution composed of one part
-sulphuric acid to eight parts water, and fill up the glass tube with
-mercury. The connections can then be made by means of a clamp on the
-lead and a wire dipping into the mercury. Connect the lead plate _L_ to
-one pole of the battery or source of energy, and the platinum-mercury
-electrode _F_ to one post of primary. The other side of battery and
-coil being closed, the apparatus will begin to work. No condenser is
-needed with this interrupter.
-
-
-DESSAUER CONTACT BREAKER.
-
-This is a modification of the spring hammer-head type, but has a
-platinum contact on both sides of the spring. It thus obtains double
-vibrations, but is liable to stick. The elasticity of the spring
-normally prevents the circuit remaining closed on the forward movement
-of the hammer head, but this combination requires attention.
-
-
-STEEL RIBBON INTERRUPTER.
-
-For light currents and rapid vibrations, such as are employed in
-electrotherapy, the steel ribbon interrupter is suitable. It consists
-of a steel ribbon _V_ one-half inch wide by six or eight inches long
-and the thickness of a stout visiting-card. Near the end is riveted
-a platinum contact. One end of the ribbon is held by a brass upright
-_R_, to which connection is made to circuit; the other end is riveted
-to a threaded rod, which passes through a brass pillar, and is held
-by a thumb-screw and check nut _S_. Turning the thumb-screw either
-way tightens or loosens the ribbon and so raises or lowers the rate of
-vibration (Fig. 24).
-
-
-CONTACT BREAKERS IN VACUO.
-
-Contact breakers in vacuo, as applied to Ruhmkorff coils, are by no
-means of recent date. Poggendorff made use of such prior to 1859, and
-noted the diminished sparking at the contact breaker and increased
-effect in the secondary circuit.
-
- [Illustration: FIG. 24.]
-
- [Illustration: FIG. 25.]
-
-Mr. D. McFarlan Moore, whose experiments in vacuum tube lighting
-have proven so interesting, was granted patents upon various forms
-of contact breakers, in which the chief merit was that the contacts
-were broken in a vacuum. The sparking was almost eliminated, and the
-suddenness of the break of contact so accentuated as to materially
-improve the output of an induction coil. A perusal of his patents,
-copies of which may be procured through almost any bookseller, will
-prove profitable to the coil constructor.
-
-
-QUEEN CONTACT BREAKER.
-
-The most important advantage of this arrangement is the abrupt break,
-owing to a collar in the vibrator striking a movable contact while at
-full speed. Reference to Fig. 25 will show that the movable platinum
-contact is carried on a small vertical spring behind the vibrator
-spring, and projects through a collar on the vibrator spring. When
-the contact is made, the movement of the vibrator is not arrested,
-but continues at its full amplitude, thus allowing a long "make."
-The vibrator is kept moving at a constant amplitude by means of the
-small coil shown in the illustration, which is in shunt with the main
-circuit. In the old forms there has always been a liability of the
-platinum contacts sticking (or welding together). In the new form, as
-the break is made when the vibrator is in the middle of its swing, the
-sudden blow with the entire momentum of the iron hammer head is always
-sufficient to break the platinums apart. This form of contact breaker
-is very efficient on electric-light circuits, and operates with the
-utmost regularity.
-
-
-THE QUEEN CONTACT BREAKER FOR LARGE COILS.
-
-This is a device where the actual break is made in alcohol between
-large studs of platinum nearly one-quarter inch in diameter. The bottom
-contact can be raised or lowered by means of an adjusting screw. The
-top contact is secured into the bottom end of a rod passing down a
-guide tube into the alcohol to meet the lower contact. By means of
-an electric motor and a cam motion, the top contact and plunger are
-made to work up and down in the alcohol, thus making and breaking the
-current flow. One of the commendable features of this contact breaker
-is that the platinum studs are caused to revolve while in operation,
-thus presenting new faces to each other after each blow. The apparatus
-is not adapted for rapid action, but for the handling of heavy currents.
-
-
-ADJUSTABLE CONTACT BREAKER FOR MEDICAL COILS.
-
-An adjustable contact breaker for medical coils is shown in Fig. 26.
-_M M_ are the magnet coils, _A_ is the armature, carrying a platinum
-contact, which vibrates against the adjusting screw _P_. The armature
-is pivoted at _J_, but is held at a distance from the magnets by the
-springs _S S_. The other end of the armature carries a ball _B_, which
-can be slid up and down on the rod and set at any point by a set-screw.
-When the ball is at the end of the armature rod most remote from the
-magnets, the vibrations are slowest; when moved towards the magnets,
-the vibrations become more rapid. Adjustment of the two springs _S S_
-at _R R_ enables the contact breaker to operate on varying current
-strength, and also tends to lessen the jerkiness of gravity contact
-breakers. A flat spring, however, can be substituted for the spiral
-springs, in which case the pivot would be dispensed with and the spring
-riveted, as in the hammer form of vibrator. The illustration shows this
-arranged for a wall board, but it can readily be adapted for table work.
-
- [Illustration: FIG. 26.]
-
-
-ADJUSTABLE CONE VIBRATOR.
-
-Fig. 27 shows a form of contact breaker much used in portable medical
-coils for slow speeds. It consists of a cone of iron _H_, mounted on
-the vibrator spring, and furnished with adjustable contact spring
-and screw _A_. Its amplitude of vibration is limited by the two pins
-mounted on the disc, between which the cone vibrates. The disc is
-turned by hand, thus moving the pins, and so varying the travel of
-the cone _H_ to and from the core _C_. It does not give good results
-from the fact that the rhythmical movements are disturbed every time
-the cone strikes against the pins, also at the contact spring striking
-the contact screw. As we showed before, a really satisfactory contact
-breaker should have a spring, which allows of no sinusoidal movement.
-Where a pivoted armature is governed by a spiral spring, the result is
-a series of steady, rhythmical shocks, provided the adjustments are
-satisfactory.
-
- [Illustration: FIG. 27.]
-
-
-COIL HEAD CONTACT BREAKER.
-
-Fig. 28 shows the details of a contact breaker to be attached to
-the coil head direct. It is often used on very small coils, which,
-together with a miniature dry cell, is slipped into a pocket case.
-An important detail in small coils is to use a contact breaker of
-sufficient size. Most of them are not large enough to stand ordinary
-usage, the adjusting screw is not of sufficient diameter and the thread
-soon strips. There is no reason why the adjusting screw, its platinum
-tip, and the pillar or lug which holds it should not be solidly built,
-it would certainly require less adjustment. Either single or double
-check-nuts can be fitted to the adjustment screws of nearly all the
-forms of contact breakers described.
-
- [Illustration: FIG. 28.]
-
-
-CONTACTS.
-
-It is absolutely essential that the _diameter_ of contacts for all
-contact breakers should be as large as possible and their faces filed
-truly parallel to enable them to easily carry all the current required.
-One of the main causes of failure of coil is burning of the platinum
-point and platinum burr, the current being then materially reduced.
-Large sparks at point of rupture are often indications that the
-condenser is not working properly—perhaps has broken down or is not
-large enough. The contacts will sometimes fuse together; at any rate,
-the excessive sparking is an evidence of waste as much as in a dynamo
-generator.
-
-The adjustable method of arranging condensers (see Chapter IV.) is
-here of great value, but it is easy to attach more condenser sections
-to the contact screw pillar and vibrator pillar and notice result.
-In the construction of Ruhmkorff coils it is a good plan to make all
-connections possible on the coil base, instead of inside the condenser
-chamber. This is done either by means of rubber-covered wires or neat
-strips of brass, screwed down on the base from points of connection,
-and, of course, carefully bent over or well insulated from all other
-leads which they have to cross.
-
-The best makers of induction coils construct their instruments so
-that they can be readily taken apart with as little detachment of
-connections as possible.
-
-
-
-
-CHAPTER III.
-
-INSULATIONS AND CEMENTS.
-
-
-In selecting an insulating compound for apparatus designed to be
-under the influence of high tension currents, a glance at some of the
-peculiarities of such currents will not be out of place. Mineral oil is
-used in many of the converters employed to transform the high voltage
-currents on the mains of the alternating electric-light systems to the
-comparatively low voltage used at the points of consumption. Professor
-Elihu Thomson, in a series of experiments, noticed some interesting
-facts in the sparking distances of high potentials in oils.
-
-He found that discharges of low frequencies, as 125 alternations per
-second, were capable of puncturing mineral oils at one third to one
-half the thickness of an air layer sufficient to just resist punctures
-by the same discharge; but with frequencies of 50,000 to 100,000
-per second, an oil thickness of one thirtieth to one sixtieth was a
-sufficient barrier.
-
-At a frequency of 125 per second, a half-inch spark in the air
-penetrated one third to one fourth inch of oil; but at frequencies of
-50,000 to 100,000 per second, a layer of oil one fourth of an inch
-successfully resisted the passage of a spark which freely passed
-through 8 inches of air.
-
-The effect of drying an oil improved its insulating qualities. (Tesla
-uses boiled-out linseed-oil.)
-
-He also noted that pointed electrodes could be brought nearer together
-under oil than balls without allowing a discharge. Flat plates allowed
-of still greater sparking distances. Tesla notes that oil through which
-sparks have passed must be discarded, probably owing to particles of
-carbon being formed.
-
-Paraffin wax has a higher resistance than oil, providing it has not
-been heated over 135° C. It will stand alternate heating up to 100°
-C. and cooling, being of lower resistance when hot than when cold.
-But a serious permanent deterioration takes place when it has been
-heated over 100°C.; its color, from the normal pure white, changes to a
-yellowish tint when its insulation is impaired. Paraffin also undergoes
-a deterioration when heated for a long time even at 100° C., and should
-never be used for fine work when it is at all yellow. It is always best
-to melt it in a hot-water bath, not permitting, however, any steam or
-moisture to come near it. In this climate (United States) it is not
-so necessary to mix in any tallow to obviate brittleness, the average
-temperature of most workshops being sufficiently high to keep it from
-becoming brittle.
-
-Resin oils do not suffer permanent injury from being heated, as does
-paraffin, but their insulating properties diminish much more rapidly
-on becoming even warm, the initial resistance of resin oils being lower
-than that of paraffin.
-
-Paraffin has a fault—its tendency to absorb a slight degree of
-moisture. It has been found in telephone and telegraph cables
-saturated with paraffin that this is a very important cause of their
-deterioration. In Ruhmkorff coils, however, which are intended for
-operation in enclosed places free from damp atmospheres, the absorption
-of moisture would be probably reduced to its minimum.
-
-There is one substance which, were it not for its cost, would be far
-preferable to paraffin for coil work, and that is beeswax. Its cost,
-however, is generally five times that of paraffin, even when purchased
-in quantities. It never becomes brittle enough to be damaged in careful
-handling, its melting point is low, and it does not absorb moisture.
-But it must be unquestionably pure and clear.
-
-In foreign practice a variety of resinous mixtures are used to
-insulate the turns of the wire in Ruhmkorff coils.
-
-Equal parts of resin and beeswax used hot, paraffin, resin and tallow,
-and shellac and resin are employed.
-
-Shellac—that is, the yellow lac—is much used as a varnish for
-electrical instruments, being dissolved in alcohol to saturation. For
-dynamo armatures and similar apparatus the shellac varnish is of great
-service, and many good compounds of shellac, such as insullac and
-armalac, have been prepared for ready use. But (excluding beeswax) for
-our purposes paraffin stands pre-eminently at the head of the list.
-
-In using shellac varnish, in high tension work more particularly, care
-must be taken that the moisture has entirely evaporated. Although a
-piece of shellacked apparatus may appear perfectly dry, yet when the
-current is allowed to flow unlooked-for results may appear—it takes
-hours in a dry atmosphere for shellac varnish to dry. Baking the
-apparatus in a warm oven is a necessary expedient whenever feasible,
-care being taken not to burn or decompose the shellac. The proportions
-most generally used are 1 ounce shellac to 5 ounces alcohol. Stand the
-vessel containing the mixture in a warm place, and shake it frequently;
-filtration improves the varnish somewhat.
-
-A ready and efficient varnish for silk is prepared by mixing 6 ounces
-of boiled linseed-oil and 2 ounces of rectified spirits of turpentine.
-For paper, 1 part of Canada balsam and 2 parts of spirits of turpentine
-dissolved in a warm place and filtered before being used. A good
-insulating cement for Leyden jars and insulating stands is prepared
-from sulphur, 100 parts; tallow, 2 parts, and resin, 2 parts, melted
-together until of the consistence of syrup, and sufficient powdered
-glass added to make a paste. To be heated when applied, this will
-resist most acids. The resin and beeswax compound is handy when making
-experimental mercurial air pumps of glass tubes, as it has a fair
-tenacity, is not too brittle, and is easily used.
-
-
-
-
-CHAPTER IV.
-
-CONDENSERS.
-
-
-A condenser is an apparatus whereby a charge of electrical energy
-may be temporarily stored, the amount of energy it will hold
-determining its "capacity." The capacity of a condenser is measured
-in micro-farads, the commercial unit representing one millionth of a
-farad. A farad equals the capacity of a body raised to the potential of
-one volt by a charge of one ampere for one second at one volt—_i.e._ =
-one coulomb.
-
-The measurement of the capacity of a condenser is accomplished by
-the use of a ballistic galvanometer. The latter instrument has a
-bell-shaped magnet suspended in a coil of fine wire. When a momentary
-current is passed through this coil the magnet hardly commences to
-rotate until the current has practically ceased. A beam of light is
-reflected from a mirror fixed to the magnet on to a scale. The degree
-of deflection is compared with that obtained by the discharge of a
-condenser of known capacity, and the capacity of the condenser being
-measured is deduced by a simple rule. The farad, which is the unit of
-capacity requiring a condenser of an immense size, is replaced by a
-commercial unit, the micro-farad—that is, one millionth of a farad.
-
-The original form of the condenser was the Leyden jar, which owes its
-name from the town of Leyden in Europe.
-
- [Illustration: FIG. 29.]
-
-The Leyden jar is made as follows (Fig. 29): A clean uncracked glass
-jar with a wide mouth is coated on the inside and outside with tinfoil;
-sometimes loose tinfoil is filled inside, the tinfoil, however, not
-reaching more than two thirds of the jar's length from the bottom.
-A cork is fitted, and through the middle of it a wire is passed
-touching the inside coating of tinfoil and terminating in a metal
-sphere outside. A simple Leyden jar can be made in a few moments by
-half filling a glass bottle with water and wetting the lower half of
-the outside; a wire run through the cork into the water finishes the
-job. But this is at least only a makeshift, although a fair amount of
-current has been collected from a leather engine belt in motion in one
-thus made.
-
-A condenser can be easily made as follows (Fig. 30):
-
- [Illustration: FIG. 30.]
-
-Procure a clear glass plate, _G_, free from flaws, 11 inches square
-by 3∕32 inch thick. Give this a good coating of shellac varnish all
-over, sides and edges. Cut out of smooth tinfoil two sheets, _T_, 8
-inches square, and round off the corners with a pair of shears. There
-must be no sharp corners, projections, or angles to induce leakage.
-Lay the glass plate on a sheet of paper, and mark its outline thereon
-with a pencil; then remove it and substitute a sheet of the tinfoil,
-and mark that. This will enable you to centre the foil. Give one side
-of the glass plate another coat of varnish, and so lay it on the paper
-that its outline coincides with the pencil outline. When the varnish
-has partly dried take a sheet of the trimmed foil, and by observing
-the pencilled marks you can lay it on the varnished plate exactly in
-the centre. Lay down the top edge first along this line, and carefully
-deposit the remainder of the foil in place. Next, with a flat brush
-full of varnish go over the plate, pressing out any air bubbles, and
-ensuring both a flat and a well-varnished surface. When this is dry,
-turn over the plate and repeat the operation on the other side.
-
-If desired, a metal hemisphere of at least an inch in diameter may be
-attached with varnish, first scraping the foil to make a contact. The
-whole plate can be swung in a cradle of two silk threads, laid on a
-glass tumbler, or mounted on end in a shellacked block of wood.
-
-A strip of tinfoil, _S_, attached at the corner can be used as a
-connector. The plates must be joined in the following manner when two
-or more are used in conjunction, and a quantity of current is desired.
-They should be placed so the connecting strips project alternately from
-each side (Fig. 31), and all on each side joined so as to leave two
-terminals, one to the 1, 3, 5 plates, the other to the 2, 4, 6 plates,
-and so on, which, when joined, will have the same effect as would
-result from the use of two large plates of the same total area. The
-nearer the plates are together the greater capacity they will have,
-always supposing the insulation is good, the insulation being known
-as the dielectric. Another good method, when a high quality of glass
-can be procured, is to lay the tinfoil on the plates without varnish,
-piling one on top of the other, tinfoil and glass alternately, and
-clamping the whole securely, laying a piece of cloth top and bottom
-to avoid cracking the glass from the pressure. This must be kept from
-moisture; a strip of paraffined paper stuck along the edges and extra
-paraffin run on will answer very well.
-
- [Illustration: FIG. 31.]
-
-In constructing these glass condensers, they must be designed to
-correspond with the coil with which they are to be charged. In the
-foregoing description we have allowed a margin of 1½ inches of glass
-around the foil coatings. This will make 3 inches as the maximum
-distance between the coatings. Although a 2-inch spark from the coil
-would not jump this interval, a certain discharge will take place,
-and the less this occurs, the more serviceable the condenser will be.
-Therefore a greater margin should be allowed for a longer spark than 2
-inches.
-
-In the commercial condenser for telephone and telegraph use, paraffin
-and paper are substituted for glass, as will be described later.
-Heavy paraffin oil gives excellent results, but its fluidity is
-disadvantageous.
-
-There is no valid reason why paraffin could not be used on the glass
-plate condensers, care being observed that it is free from dirt and
-metallic chips. In fact, the space between the glass plates of the
-multiplate condenser may be filled in with paraffin, and thereby
-exclude the air. Only a condenser so built up is not convenient to take
-apart for experimental purposes.
-
-The foregoing description of a glass insulated condenser was written
-with the assumption that a good quality of glass be used. But the
-ordinary window glass is generally useless, and paraffined paper is
-preferable. The quality of glass known as "hard flint glass" is best,
-the superior qualities being imported from Europe. This latter is used
-in the manufacture of the standard Leyden jar for lecture purposes.
-
-Were it not for its cost, the finest dielectric we could use would be
-sheet mica. Unfortunately sheet mica over 3 inches square is expensive,
-and becomes rapidly more so as it becomes larger.
-
-Standard condensers for testing are made with mica carefully selected,
-and retain the charge for the maximum length of time. The built-up mica
-condenser is immersed in molten paraffin until the same has permeated
-the sheets, and then the complete mass is put under a pressure until
-the paraffin is well set.
-
-
-PAPER CONDENSER.
-
-The paper used in the manufacture of the commercial form is a special
-thin, tough linen paper carefully selected, sheet by sheet, to avoid
-pin-holes or flaws, and kept in an oven until used to ensure absolute
-dryness.
-
-When this cannot be procured, use thin unsized writing paper of a
-good quality, well dried, and absolutely clean. As an example of
-the necessity of cleanliness, a light lead-pencil mark would serve
-to conduct the current entirely from a charged sheet to wherever it
-terminated, and if suitably located, utterly destroy the usefulness
-of the apparatus. Ink, which most generally contains iron, will cause
-trouble, and although some cheap foreign condensers are built up of old
-ledger pages, yet their efficiency is very uncertain.
-
-The paper used in commercial condensers is from four to seven
-thousandths of an inch in thickness.
-
-
-SERIES.
-
-The smaller the amount of surface the less will be the capacity, but
-the quicker the discharge. The apparatus heretofore mentioned has had
-the alternate plates connected together in two series, presenting a
-large surface and rendering a large amount of current. A condenser
-so made will have a low voltage or potential, but is not so liable
-to leakage as one made to render a high potential. The multiple
-condenser of a large capacity will hardly discharge and spark over an
-air gap requiring a contact of the two electrodes. But a smaller one,
-consisting only of a single pair of small plates, will spark across
-quite a considerable air gap.
-
-A number of charged condensers may be put in series, and the resultant
-potential thereby increased. Cut a number of pieces of paper of the
-desired size, say 6 inches square, and a number of sheets of foil 3
-inches square. Round off the corners of the foil and build up first a
-sheet of paper, then a sheet of foil in its centre, then another paper
-and another foil sheet, and so on. There is to be no connection from
-sheet to sheet, only the inductive action of one on its neighbor. The
-foil must be considerably smaller than the paper in this construction,
-owing to the greater tendency to discharge round the edges of the
-sheets, owing to the greater potential of the current.
-
-When the requisite number of sheets have been built up, leave a sheet
-of foil top and bottom for connection, tie between two pieces of stout
-card or board, and immerse in the molten paraffin. When thoroughly
-soaked, remove and put under pressure until cold. It will be found
-undesirable to make these with more than a dozen pairs of sheets, but
-to make a number of blocks of that number for ready service.
-
- [Illustration: FIG. 32.]
-
-Fig. 32 shows the arrangement of the apparatus to charge a Leyden
-jar, the plate form being connected in a similar manner. The jar is
-stood upon an insulating support—a dry tumbler will answer—with the
-ball _B_ connected to one pole of the coil. From the outside tinfoil
-coating _T_ a wire runs to the discharger _D D_, which is in circuit
-with the secondary coil, _S_. The discharger balls _D D_ are carefully
-approximated until the spark just passes, this latter point being
-of great importance. Were the discharger balls too near the spark
-would probably pierce the dielectric of the condenser, therefore the
-balls should be carefully _brought near_ to each other until the
-exact distance is found. Even if the insulation of the condenser were
-not pierced, yet a path would probably be opened through which some
-succeeding discharge would pass, and ruin the instrument.
-
-Another method of charging is to leave an air gap at _B_; then there
-is not much liability of the condenser discharging back through the
-coil—an undesirable event, as it would most likely perforate the
-insulation of the coil.
-
- [Illustration: FIG. 33.]
-
-In designing or using any apparatus intended to hold a charge of high
-potential, it must be kept in mind how readily points or sharp edges
-serve to allow the current to pass off—we might almost say evaporate.
-Given two bodies, one a globe and the other a rectangular block, each
-well insulated from the earth or any other large body, and the globe
-would be found to hold its charge long after the block had dissipated
-all trace of the charge given to it. Therefore round off every edge and
-angle, projection or point.
-
-In making handles, supports, or any work requiring an intervening high
-insulation, hard rubber is preferable to glass where there is liability
-to moisture. When the apparatus is as shown in Fig. 33, the condenser
-is alternately charged and discharged with a loud noise, the vivid
-sparks passing across the discharger balls _D D_ possessing great
-deflagratory powers.
-
-In experimenting with a Ruhmkorff coil it is not advisable to leave the
-instrument working while the secondary terminals are beyond sparking
-distance, as there is a great strain on the secondary insulation. Nor
-is it wise to use only one electrode in an experiment, unless the other
-is connected to some apparatus of an approximate capacity to that at
-the other, for the foregoing reason.
-
-
-ROLLED-UP CONDENSERS.
-
-Now that the condenser has become so important a factor in telephone
-work, many schemes for cheapening and facilitating their manufacture
-have been devised. One in particular merits description, the
-"rolled-up" condenser having come largely into use. The tin-foil is
-supplied in rolls containing many yards of foil of the requisite width
-for the condenser to be made. Likewise rolls of paper are provided,
-exceeding in width, however, those of tin-foil. These rolls are
-arranged upon horizontal spindles in front of an empty spindle, or
-mandrel, upon which the condenser is to be formed. A few turns of the
-paper ribbon are made around the mandrel, then the foil is brought
-forward and a few turns made, then follows a turn of paper ribbon
-and another of foil, and finally a paper layer; and the mandrel being
-rotated, the alternate layers of foil and paper are laid on and rolled
-around each other on the mandrel until the requisite quantity is
-obtained. It then becomes an easy matter to cut the paper ends so no
-contact is possible between the layers of foil. The whole thing is
-slipped off the mandrel, secured by a rubber band or two, placed in a
-hot paraffin bath, and left to become saturated while still warm and
-before the paraffin has time to harden; the cylinder is put under a
-press and squeezed flat, driving out excess paraffin, and leaving the
-condenser in a convenient shape to handle. Connections are then made to
-the foil leaves, and a case of wood or metal completes the work.
-
-There is no reason why aluminum foil or lead foil, or, in fact, any
-thin sheet metal should not be used in condensers. In telephone work,
-paper covered with gilt paint was tried, and worked fairly well, but
-was ultimately rejected in favor of tin-foil. In some cases, when
-it is desired to construct a condenser for high potential work, the
-oil-tank apparatus can be used. This is readily made of any desired
-dimensions, as follows: Procure a square glass jar, such as is made
-for storage batteries, a few pieces of sheet metal cut to fit loosely
-in the jar, some glass rods and sufficient clean "transformer oil"
-or heavy paraffin oil to nearly fill the jar. The sheets of metal
-can then be hung from the glass rods into the jar, being separated
-one-half inch, and the oil poured in. Two plates, about 8 inches by 6
-inches, will hang nicely into a type D^3 Chloride Battery jar, which
-is 7⅞ inches long by 9½ inches high by 3¼ inches wide. Altering the
-relative distances between the plates will give considerable adjustment
-to this simple condenser, or, if desired, more plates may be inserted
-and connected up, as in the tin-foil condensers. This type can be made
-portable, but it is not to be recommended unless no objection is had
-to emptying and refilling the jar with oil.
-
-
-ADJUSTABLE CONDENSERS.
-
-In operating large coils, it is convenient to be able to vary the
-capacity of the condenser on the primary circuit. To make an adjustable
-condenser presents no more difficulty than a non-adjustable one, simply
-more labor. For example, the large condenser used with the 6-inch
-spark coil might be divided into four sections, containing 2000 square
-inches, 500 square inches, 300 square inches, and 200 square inches of
-surface (see Fig. 34). Wires leading from the ends of the foil sheets
-_C C_ are to be brought to the brass plates _G G_. The brass rods
-_B B_ are connected by binding posts to the coil, each strip being
-well insulated from its neighbor. Any combination is possible by the
-insertion of brass plugs in holes drilled between the strips. The plugs
-must be fully large enough to make good contact on each of the two
-strips between which they are inserted, and should be turned taper.
-With the largest coils the condenser and contact breaker are generally
-mounted separately, and are fully adjustable.
-
- [Illustration: FIG. 34.]
-
-SPECIFIC INDUCTIVE CAPACITY.
-
- Dry air 1.000
- Sulphur 2.590
- Hard rubber 2.290
- Paraffin 1.996
- Shellac 2.750
- Kerosene 2.225
- Paraffin oil 2.710
- Castor oil 4.962
- Olive oil 3.575
-
-Condensers made with dielectric of high inductive capacity (insulation
-being equal) will retain greater charge than those made with
-dielectrics of low inductive capacity. Thus, one made with shellac
-would be nearly half as great again as with paraffin.
-
-Capacity of a condenser increases with area of foil surface, with
-diminished distance between foil plates and with increase of
-insulation.
-
-
-
-
-CHAPTER V.
-
-EXPERIMENTS.
-
-
-The luminous effects that can be obtained by means of a Ruhmkorff coil
-are exceedingly beautiful and instructive. The simplest experiment
-of this nature is the production of the spark consequent on the
-approximation of the electrodes attached to the secondary coil. This
-spark can be varied in both length, intensity, or shape by the form
-and nature of the substances between which it is permitted to pass.
-Attach to each end of the discharger a fine steel needle, and bring
-them together until the spark jumps from one to the other. A long thin
-snapping spark will pass, which, however, appears to be trying to take
-any but a straight path across the air gap. The peculiar crookedness
-of this, as in a lightning flash, is credited to the fact of particles
-of matter floating in the air conducting the current better than the
-pure air. The curious odor noticed in these discharges, as, in fact, in
-the working of all high-tension apparatus, is ozone—O_{3}, triatomic
-oxygen. This gas, so noticeable after a thunderstorm, has a powerful
-effect on the mucous membranes of the throat and nasal passages,
-and must be inhaled with caution. It is being used by the medical
-profession for the destruction of germs and for general therapeutic
-service.
-
-Substitute pieces of fine iron wire for the needles, and bring the ends
-together about one quarter the distance through which the normal spark
-will pass. The spark will be found to have changed its appearance, now
-being thick and redder, or, rather, of a deep yellow, and to possess
-vast heating qualities.
-
-The iron wire will melt at one electrode, and if the other be examined
-it will be perceived that it has not even become warm. The cold wire
-will be the one connected to the positive pole of the coil.
-
-Connecting the poles together with a piece of very fine iron wire will
-result in the deflagration of the wire in a vivid light.
-
-The short thick spark is termed the calorific spark, and believed to
-possess its yellow color from the combustion of the sodium in the air.
-This spark will easily ignite a piece of paper held in its path.
-
-Take a sheet of hard rubber and breathe on its surface; lay a wire from
-each pole of the secondary to points on the sheet, about twice as far
-apart as the spark would pass over in the air. The electric current
-will strive to complete its circuit; streams of violet light forming a
-perfect network will issue from each pole, until, provided the rubber
-is sufficiently damp, they will unite in a spark far exceeding its
-normal length in the air. It is curious to watch how the streams branch
-out from these two points, and how persistently they strive to meet
-each other. Scatter some finely powdered carbon on this sheet (crushed
-lead-pencil or electric light carbon is good material). The points may
-now be removed to still further distant places, and yet the current
-will work across. Each particle of carbon seems to be provided with
-innumerable scintillating diamonds, so sparkling is this effect.
-
-Hard rubber is not absolutely necessary for these experiments; glass
-will do, but the black background of the rubber intensifies the
-luminosity of the discharges. Take a teaspoonful of powdered carbon and
-scatter it between the points on the rubber, so that the spark can find
-a ready path, evidenced by but little visible light. It will be seen
-that this powder is blown away from one electrode after a few minutes,
-leaving the latter in the centre of a clear space, but at the other
-electrode not much disturbed.
-
-Bring the points so close to one another that the spark becomes short
-and fat; soon the carbon will commence to burn, forming a veritable arc
-light. Take two pointed lead-pencils and wrap a few turns of wire from
-the electrodes round the blunt ends of them; bring the pointed ends
-together, and an arc will soon be established; but at various points
-where the wire is wrapped the current will burn through the wood, and a
-number of incandescent points will ensue.
-
-In these experiments on the rubber sheet it will be noticed that the
-spark acts as it does in the air, inasmuch as it does not take a direct
-path, but jumps in an irregular track from point to point.
-
-If two small metal balls be substituted (Fig. 35) for the points
-between which the sparks be passing, it will be noted that the sparks
-do not pass through so great an air gap as before, or even as rapidly.
-
-The spark between two balls is much noisier than that passing between
-points, and if the balls be of about 1 inch in diameter, a curious
-effect ensues on the passage of the current (Fig. 36). This effect has
-been likened to a stream of water issuing from a horizontal nozzle into
-a cavity when the nozzle is moved up and down slowly in the space of a
-few inches.
-
- [Illustration: FIG. 35.]
-
- [Illustration: FIG. 36.]
-
-
-THE LUMINOUS PANE.
-
- [Illustration: FIG. 37.]
-
-This easily made exhibit (Fig. 37) is one that is susceptible of quite
-a number of applications. In its simple form it is but an enlarged
-version of the rubber sheet scattered with carbon dust. The old way
-to make it was to take a plate of glass and cement on one face of it
-a sheet of tinfoil, using shellac varnish preferably. When dry, the
-tinfoil was scored across and across in such manner as to divide
-it up into little squares or diamonds. When the current was applied
-to each end of the plate, the spark divided into innumerable little
-ones; between each bit of tinfoil and its neighbors there would be
-many little sparks, and the effect was very pretty, somewhat as
-was described before when the carbon dust was strewn between the
-electrodes. It is more easily and quickly prepared by giving a sheet
-of glass a coating of shellac varnish, and then sparingly dusting any
-powdered conductor over its surface, using perhaps carbon dust or
-filings of metal. By cutting out a stencil from a piece of thin card
-and laying it over the sparkling plate, the design shows out very
-strikingly, and various designs in stencils can be prepared, different
-powdered conductors giving different colored sparks.
-
-A long glass tube moistened inside with mucilage or shellac varnish and
-then having some conducting dust shaken through will also give quite a
-pleasing effect.
-
-
-LUMINOUS DESIGNS.
-
-Coat one side of a glass plate with tinfoil, leaving an attached strip
-for connection. Shellac a piece of paper of a size corresponding to the
-design to be rendered luminous. When the shellac has dried so far as to
-become "tacky," lay a sheet of foil on it and press it down evenly all
-over.
-
-Then draw on the paper a design that can be readily cut out. Use a pair
-of scissors or a very sharp knife. If the latter, lay the sheet on a
-piece of glass; but there is a greater tendency to tear the design when
-a knife is used if an unpractised hand wields it.
-
-This design may either be stuck on to the plain side of the glass plate
-with varnish or simply laid on (Fig. 38). Connect one secondary wire to
-the foil coating of the plate and the other to the design. This must be
-shown in the dark, and the luminosity will not be strikingly apparent
-until the eyes become accustomed to the darkness—that is, when the
-room has been previously lighted.
-
-One of the most beautiful and easily obtained phenomena of the
-high-tension discharge is the "electric brush" (Fig. 39). This occurs
-when the secondary electrodes of the coil are too far apart to allow
-of the free passage of the spark, and can only be seen at its best in
-a perfectly dark place. The ball tips before mentioned show this brush
-very plainly, or two sheets of tinfoil in circuit hung far enough apart
-to prevent vivid sparking will cause this so-called "silent" discharge.
-This latter arrangement should not be used for over fifteen minutes,
-as the ozone which is liberated in large quantities will affect those
-persons in the vicinity.
-
- [Illustration: FIG. 38.]
-
- [Illustration: FIG. 39.]
-
-In fact, when a rapid vibrator is being used with the coil, the leading
-wires from the secondary terminals present this brush appearance, the
-curious threads of light resembling luminous hairs waving in the air.
-The more rapid the vibrations the more prominent the brush effect, as
-will be seen in the Tesla coils. The positive ball of the discharger
-shows the brush as a spreading mass of luminous threads reaching out
-toward the negative ball, which latter resembles a star, as in the
-figure.
-
-The intensely disruptive power of the long spark is readily shown by
-its power to perforate substances, but great care must be taken that
-the secondary wires of a coil are led away from the body of the coil. A
-good plan is to hang two silk cords or stout threads from the ceiling,
-to which the secondary wires may be attached and kept in sight when
-experimenting at any distance from the coil.
-
-To pierce a piece of thin glass, take two lumps of paraffin about the
-size of a walnut, and, warming them and the glass sheet, stick them on
-opposite sides of the glass facing each other. Then warm the ends of
-the two pointed wires and thrust them into the lumps of paraffin, that
-they terminate on the glass surface directly opposite each other. On
-connecting these to the secondary coil a few impulses to the contact
-breaker will start an electric discharge sufficient to pierce the glass
-if the thickness be proportioned to the power of the apparatus. The
-great Spottiswood coil pierced a block of glass 6 inches in thickness.
-
-There is, however, a certain element of danger to the secondary
-insulation in performing this experiment.
-
-
-
-
-CHAPTER VI.
-
-SPECTRUM ANALYSIS.
-
-
-If a metal or the salt of a metal be burned in a flame it imparts to
-the flame a distinctive color; table salt thrown into the fire burns
-with a yellowish flame, denoting the presence of sodium, and a greenish
-tint, indicating the combustion of chlorine. Violet flames accompany
-the burning of the salts of potassium, and barium burns green. Lithium
-and strontium give a red hue. But to be ordinarily perceptible,
-the salts require for the most part to be present in considerable
-quantities. By the use of the spectroscope, however, extremely small
-proportions of these metals and salts can be readily detected and
-classified.
-
- [Illustration: FIG. 40.]
-
-If a beam of light be transmitted through a prism of glass the rays
-are decomposed, and what is known as a spectrum is formed (Fig.
-40). The most generally observed spectrum is the rainbow. When the
-light from a flame in which is burning some suitable substance be
-transmitted through the prism, the color which predominates in the
-flame will predominate in its spectrum. The combination of a prism and
-tubes for observing these effects is a spectroscope (Fig. 41). The
-short fat spark from the Ruhmkorff coil is most useful in this work.
-The electrodes are provided with a portion of the substance to be
-examined, and the spark is passed and viewed through the spectroscope.
-
- [Illustration: FIG. 41.]
-
-The spectroscope is shown in connection with the coil in Fig. 41. _A_
-is the aperture in the screen through which the rays from the metal
-burning at the discharger balls _D D_ passes. The lens at _L_ is used
-to view these rays after they have been decomposed by the prism _P_,
-which, as well as the lens, can be rotated. _I_ is the coil, _P P_ the
-primary and _S S_ the secondary wires, _C_ being a condenser bridged
-across the circuit.
-
-The screen should be pierced by a very narrow aperture, _A_, and be
-placed at a considerable distance from the prism _P_, that the rays
-issuing through the aperture may not strike the prism until they have
-widely diverged and become separated from each other. The aperture is
-practically formed of perfectly parallel knife edges, forming a slit
-not exceeding one hundredth of an inch in width.
-
-The colored spaces in the solar spectrum do not occupy an equal extent
-of area; the violet is the most extended, the orange the least. The
-proportion is in three hundred parts: Violet, 80; green, 60; yellow,
-48; red, 45; indigo, 40; orange, 27.
-
-The solar rays exhibit on careful examination dark lines crossing
-the spectrum at right angles to the order of the colors, and always
-occupying the same relative positions. These are called Fraunhofer's
-lines.
-
-If, however, the spectra of metals, gases, and other elements be
-examined they will be found to present certain characteristic _bright_
-lines, the body of the spectrum being often feeble or entirely dark.
-The spectrum of hydrogen gives two very bright lines of red and orange.
-
-An extremely minute quantity of an element is necessary to give
-distinct lines. Sodium gives a single or double line of yellow light in
-a position agreeing with that of the orange rays in the solar spectrum.
-
-Potassium gives a red line in the red end and a violet line in the
-violet end of the solar spectrum. Strontium presents eight bright
-lines; calcium gives mainly one broad green band and one bright orange
-band.
-
-In practical work with the spectroscope a solar spectrum is often
-arranged that it can be used as a comparison with the spectrum being
-investigated, one spectrum being formed above the other, and the
-observation made as to which lines coincide. Iron gives nearly sixty
-bright lines coinciding with the same number of dark lines of the solar
-spectrum.
-
-The violet rays of the solar spectrum are the rays which possess the
-maximum chemical action, the yellow the maximum light effect, the red
-the maximum heating effect. Beyond the violet band of the spectrum
-exist certain rays termed the invisible rays or ultra-violet rays,
-which in themselves are not luminous. Their vibratory rate is higher
-and their wave length shorter than the violet rays, according to the
-most generally accepted theory of light. These rays, when passed
-through certain substances, suffer a change and become visible
-in a luminous state of the substance, which luminosity is termed
-fluorescence.
-
-The bright yellow line of sodium in the orange rays is found in nearly
-all spectra, owing to its extensive diffusion in the atmosphere.
-
-Tesla has succeeded in producing electric waves of length approximating
-to those of white light, which appear to have very little heat. The
-ideal light is that which shows no heat and does not liberate noxious
-gases in the air, and were it not for its feeble luminosity, the light
-of the electric spark passing through a carbonic acid vacuum would
-approximate this most nearly.
-
-The present mode of obtaining light—that of raising to a high
-temperature some substance or collection of particles—seems certainly
-somewhat antiquated. The following notes may be of interest and
-assistance in researches bearing on the lighting question.
-
-Solid bodies, when heated, show a red glow in daylight at an elevation
-of temperature corresponding to 1000° Fahr.
-
- Temperature, Color of
- degrees F. Substance.
-
- 1000 Red.
- 1200 Orange.
- 1300 Yellow.
- 1500 Blue.
- 1700 Indigo.
- 2000 Violet.
- 2130 All colors—_i.e._, white.
-
-The number of vibrations per second necessary for the production of
-light, and the velocity of light being determined, the calculation of
-the wave lengths of the colored rays becomes possible.
-
-The following table (Sprague) shows this in ten-millionths of a
-millimetre (a millimetre = .039 inch) measured in the dark lines of the
-solar spectrum, from red to violet:
-
- Orange = 6.88
- Orange, Higher = 6.56
- Yellow = 5.89
- Green = 5.26
- Blue = 4.84
- Blue, Higher = 4.29
- Violet = 3.93
-
-
-
-
-CHAPTER VII.
-
-CURRENTS IN VACUO.
-
-
-Notwithstanding it requires an intensely high potential to enable the
-current to jump an air gap of 1 inch, the same potential will produce a
-luminous discharge through exhausted glass tubes aggregating 8 feet or
-even more.
-
-But the exhaustion can be carried so far that there is no apparent
-discharge; and, on the contrary, air at as high a pressure as 600
-pounds per square inch will resist the passage of the spark over an
-extremely short space. If the tubes be filled with various gases
-and then partially exhausted, the length of tube through which the
-luminous discharge will pass varies with the gas, becoming shorter in
-the following order: Hydrogen, nitrogen, air, oxygen, and carbonic
-acid—the shortest.
-
- [Illustration: FIG. 42.]
-
-Before detailing some of the more striking phenomena connected with
-high-tension discharges in vacuo, a description of a few forms of
-simple mercurial air pumps will be serviceable.
-
-Fig. 42: If a glass tube, _F_, stopped at one end, 3 feet long or
-over, be filled with mercury and the open end immersed in a vessel
-of mercury, _T_, the column of metal in the tube will sink until it
-attains a height, _M_, of about 30 inches, varying according to the
-condition of the atmosphere.
-
-The space between the mercury column and the top of the tube will be
-a fairly good vacuum. This fact was noted many years ago, and the
-gradual evolution of the mercurial air-pump based on this result can
-be followed in the articles on the mercurial air-pump by Silvanus P.
-Thompson, read before the Society of Arts, England, some years ago.
-
-Geissler, the first manufacturer of the "Geissler" or vacuum tube for
-electrical research, seeing the inconvenience of the above-described
-operation and the meagre results obtained, invented the pump called by
-his name (Fig. 43).
-
-_F E_ is a stout glass tube some 3 feet long, having a bulb, _B_, at
-its upper extremity, and a rubber tube, _S_, attached to the curved
-end. A reservoir of mercury, _R_, connects with this rubber tube, and a
-special glass tap is fixed in the upper end of the glass tube at _E_,
-beyond which tap being the point of attachment for the object to be
-exhausted. The operation is as follows: On turning the tap a part of
-the way it allows a passage between the tube _F E_ and the atmosphere.
-The reservoir _R_ is then raised until the mercury flows into the bulb
-and up the tube to the tap. The tap is then turned a fraction, and the
-communication with the air is shut off and opened between the object to
-be exhausted and the tube _F E_. The reservoir is then lowered and the
-mercury falls, drawing down the air from the object into the tube. The
-tap is then turned as in the first place, and the reservoir _R_ raised,
-when the air drawn into the tube is forced out by the rising column of
-metal. This operation being repeated many times, withdraws nearly all
-the air from the object—in fact, makes a fairly good vacuum. This pump
-has been much modified from the simple form described.
-
-The form of pump most used in the United States lamp factories is based
-on the application of the piston-like action of a quantity of mercury
-dropping down a tube. This is known as the Sprengel pump, after the
-inventor.
-
- [Illustration: FIG. 43.]
-
- [Illustration: FIG. 44.]
-
-Fig. 44: _F_ is a stout glass tube about 40 inches long by
-one-twelfth of an inch internal diameter, carrying the reservoir
-funnel _R_ at the top, a piece of soft rubber tubing, _S_, nipped by a
-pinch-cock being interposed to admit of the regulation of the mercurial
-drops. The lower end of this "fall tube," as it is called, is immersed
-in mercury contained in a suitable vessel, _V_, a branch tube being
-blown or cemented into the fall tube to admit of the connection of the
-object to be exhausted at _E_. _S_ is another piece of rubber tubing
-with a pinch-cock regulation. The point _H_ is the normal barometric
-height of the mercury—about 30 inches. On attaching a bulb, for
-example, at _E_, and regulating the pinch-cock at the top of the fall
-tube _F_, a succession of drops of mercury falls down the tube, each
-drop acting as a piston to drive the air before it, sucking the same
-from the bulb, and forcing it down through the tube and vessel out into
-the atmosphere.
-
-On its first being set into operation, the cushions of air between the
-drops silence their fall; but as a higher degree of rarefaction occurs,
-the air cushions become insufficient, and the drops fall with a sharp
-click on the top of the barometric column.
-
-One great disadvantage in this form of pump is the tendency to fracture
-of the glass tube that is manifested by the concussion of the drops of
-mercury at the barometric height. However, this has to a certain extent
-been obviated in later forms of this useful and efficient pump.
-
-For many electrical experiments, the simple exhaust tube (Fig.
-42) mentioned at the beginning of the article will be found very
-satisfactory. The top end need not necessarily be sealed off with
-glass, a cork having a wire, _W_, run through for connection being
-driven in, and a coat of paraffin or one of the cements mentioned in a
-later chapter be laid on.
-
-The second electrical connection is made by a wire dipping in the
-tumbler of mercury.
-
-
-DISCHARGES IN VACUO.
-
-In a simple glass tube having two wires carrying balls inserted
-through its ends, from which the air has been partially exhausted, the
-study of the changes shown by the passage of the spark is extremely
-interesting. Before the commencement of exhaustion no luminous effect
-can be discerned; at a low degree of exhaustion a luminosity appears
-between the ends of the wires, the negative pole being surrounded by a
-violet glow and a larger pear-shaped red discharge from the positive.
-An interval near the negative electrode is in darkness, widening as the
-exhaustion progresses. When the degree of exhaustion is very high, a
-series of arches concentric with the positive ball appear and become
-broader and more distinct as the rarefaction progresses. The arches or
-bands are called striæ, and are most distinct when the tube is made in
-the form of a narrow cylinder, with a bulb at each end. Carbonic acid
-gas vacua give the best results. If the finger be placed on the bulb at
-either end a luminous spot appears, and by using a very rapid contact
-breaker in the primary circuit, the luminous discharges become highly
-sensitive, being diverted from their regular path on the approach of
-the hand, a magnet, or a grounded wire. An extended treatment of these
-phenomena would be out of place here, but can be found in nearly all
-comprehensive works on electricity.
-
-If an incandescent-lamp bulb be held in the hand and one end be brought
-near to a terminal of the coil, a beautiful bluish light appears.[2]
-The carbon filament, if long, and not held by its loop, becomes
-electrified and oscillates, often giving out a clear, high, bell-like
-sound as it strikes the glass. Particles of carbon deposited on the
-glass during the burning of the lamp, shown in daylight as a blackening
-deposit, generally show little sparks, like stars scattered over the
-inside of the globe.
-
- [2] This depends on the degree of exhaustion.
-
-A vacuum tube will phosphoresce if held in the hand near a secondary
-terminal, or even if laid on the table near the coil, and will light
-quite brilliantly if one end be held against a terminal. This latter
-method, however, is generally inconvenient, as a certain amount of
-physical pain ensues from the discharge into the skin.
-
-Different gases in the tubes give characteristic colors. In carbonic
-acid gas the whitish green hue prevails; in hydrogen, white and red; in
-nitrogen, orange yellow. The characteristic spectra are given by the
-gases in the tubes, and can be readily examined in the spectroscope.
-But there is sometimes a slight variation in these colors, dependent
-upon changes in the current.
-
-In many Geissler tubes, a portion of the bulbs is made of uranium
-glass. On the passage of the spark in the tube this glass glows with
-a magnificent emerald green hue. Other tubes are constructed with an
-outside enveloping glass tube fitted with a corked orifice into which
-can be poured different solutions.
-
- [Illustration: FIG. 45.]
-
- [Illustration: FIG. 46.]
-
- [Illustration: FIG. 47.]
-
-Fig. 45 shows a solution tube to be filled with solution of sulphate of
-quinine, etc.
-
-Fig. 46 shows three exhausted tubes arranged in series.
-
-_A_ is of uranium glass, and glows dark green; _B_ of English glass,
-showing a blue hue, and _C_ of soft German glass, glowing with a bright
-apple-green tint.
-
-Crystals of nitrate of calcium, nitrate of silver, benzoic acid,
-tungstate of calcium, lithia benzoate, sodium salicylate, zinc
-sulphide, and acetate of zinc fluoresce.
-
-Fig. 47 is a highly exhausted tube, having at its lowest part a few
-pieces of ruby. When the secondary current is turned on at _P_ and _N_
-the rubies shine with a brilliant rich red, as if they were glowing hot.
-
- [Illustration: FIG. 48.]
-
-Fig. 48 shows the tube to exhibit the effect resulting from focussing
-the electric rays on a piece of iridio-platinum at _B_.
-
-The cup _A_ forms the negative pole; the metal disk _C_, the positive.
-
-On increasing the intensity of the spark, the metal at _B_ glows with
-extreme brilliancy, and melts if the intensity be carried too far.
-
-
-
-
-CHAPTER VIII.
-
-ROTATING EFFECTS.
-
-
-Although the luminous discharges in the exhausted tubes are extremely
-beautiful, yet the effect is indescribably enhanced when the tubes are
-rotated. Gassiot's star was the name given to the earliest exhibit of
-a rotating tube carrying a luminous discharge, owing to the curious
-phenomenon ensuing from the interruptions of the spark. As the human
-retina is only capable of retaining an impression for a fraction of a
-second, and as the tube is only momentarily luminous during the passage
-of the spark, the effect of the revolving tube is that of a series of
-such arranged as the radii of a circle, the number apparent, being
-governed by the rapidity of rotation and the rate of interruption of
-the current.
-
- [Illustration: FIG. 49.]
-
-Fig. 49 represents a form of rotating wheel which is easily made, and
-yet susceptible of many novel and attractive effects. Such a wheel,
-placed in a store window, would undoubtedly attract many persons by
-the beautiful variations of colored figures which it presents while
-in motion. And once a crowd is collected and its attention attracted
-to one spot, the capabilities of advertising the goods on sale are
-apparent.
-
-A pasteboard or light wooden disk _D_, 3 feet in diameter or over, is
-mounted on a shaft, _S_, operated by an electric motor or such power
-as may be attainable. Upon its surface are mounted the tube-holders _T
-T T T_, connected, as shown, by wires leading from the secondary of
-the Ruhmkorff coil. Starting at the shaft _S_, the circuit runs to the
-first tube-holder, where the continuity of the wire is broken to allow
-of the attachment of the vacuum tube. From the first tube-holder the
-wire runs in turn to each of the other three tube-holders, terminating
-at _R_, where it passes through a hole to a metal ring on the back of
-the disk shown by the dotted circle. This ring and the shaft are in
-connection with the secondary coil, by reason of its electrodes being
-attached to two brushes or strips of metal pressing, one on the ring,
-the other on the shaft; or the bearing in which the shaft turns may
-displace one of the brushes. _W W_ are two counterbalance weights,
-that the wheel may run smoothly and be not affected by the irregular
-distribution of the tubes or its surface. _E E_ are elastic bands,
-looped over the wire and through rings in the disk, that the wires may
-not be liable to touch or short circuit.
-
-At Fig. 50 is an enlarged view of a tube-holder, although, as it
-is meant only as a diagram, considerable variation of design is
-permissible. The springs at _H H_, to which the wires run, being bent
-back, the metal pins _P P_ may be thrust through the rings on the ends
-of the tube, and the elasticity and pressure of the spring will hold it
-in place and make the necessary contact. A wooden block, _B_, secured
-to the face of the disk, is provided with a thumb-screw, _S_, securing
-the tube-holder to it, by means of which the tube-holders may be
-turned a trifle upon their axes and so vary the effect of the wheel.
-
- [Illustration: FIG. 50.]
-
- [Illustration: FIG. 51.]
-
-Fig. 51 is a side view of the wheel, showing one manner of mounting
-the disk and its connections. The same figures apply to the parts as
-in the preceding figure. _M N_ are the wires leading to the coil, _P_
-is a pulley on the shaft whereby the rotary power may be applied. The
-wires on the face of the disk are not shown, as they would impair the
-clearness of the diagram unnecessarily.
-
-The greatest danger in the operation of such a piece of apparatus
-will be the tendency of the high tension spark to wander where it is
-not wanted, and to take short but forbidden paths back to the coil.
-However, care and perhaps experiment will prove the remedy. It will be
-noticed by reference to Fig. 49 that a circle has been drawn almost
-bisecting two of the tube-holders. This circle represents a circle of
-danger, and where a thin material has been used for the disk, the disk
-may very well be reinforced by a piece of stouter card cemented on its
-face.
-
-The disk, whether of wood or of pasteboard, must have a liberal coating
-of insulation, either shellac varnish, paraffin, or beeswax, and be
-absolutely free from unnecessary holes. Moreover, the ring _R_ must be
-of such a distance from the support _F_, if the latter be metal, as
-will preclude any jumping of the spark. A Ruhmkorff coil giving upward
-of three quarters of an inch of spark will be large enough to operate a
-wheel carrying four 8-inch tubes.
-
-The wheel may be set back in a window and surrounded by dark fabrics,
-or built in, as it were, in a cave of such. The judicious use of
-pieces of looking-glass scattered on the sides of the cave, in such
-manner as to reflect the light of the tubes, will enhance the effect.
-There is no danger of fire where ordinary care is used, as the _long_
-spark necessary to the production of the luminosity will hardly ignite
-anything but gas, unless specially arranged to do so.
-
-Fig. 52 is a triangle formed of three Geissler tubes, and intended for
-rotation as a whole. _M M_ are two pieces of mica or glass, to prevent
-any possibility of the spark jumping and short circuiting, in which
-event the tubes would fail to light.
-
- [Illustration: FIG. 52.]
-
-This triangle is shown diagrammatically at _A B C_, Fig. 53, mounted
-on an insulated rotating disk. Before commencement of rotation, and
-upon the current being turned on to the tubes, a simple triangle will
-result, but at a certain stage of rotation the Maltese cross shown
-is formed. A still higher rate of rotation will produce the double
-star, Fig. 54, and as the rotation and rate of vibration of the coil
-contact-breaker is varied, an apparently endless succession of stars or
-triangles appears to grow out into view.
-
- [Illustration: FIG. 53.]
-
- [Illustration: FIG. 54.]
-
-Although Figs. 53 and 54 serve to illustrate a triangle of tubes and
-its variations, a very pretty and simple effect can be obtained with it
-as follows: Three strips of looking-glass are cut and scratched across
-their silvered surface, as described for the luminous pane, Fig. 37.
-The current then being allowed to pass, and the wheel being rotated,
-the triangle acts as in the preceding paragraphs, multiplying and
-forming figures, which are extremely interesting to watch.
-
-While treating on the subject of store-window attractions, a few
-suggestions on a display of stationary Geissler tubes may be made.
-Starting with the assumption that the platform on which the goods
-would be displayed is of wood, a very small amount of preparation is
-necessary. The platform is covered with a dark material free from
-gloss, such as canton flannel, on which the tubes are laid in any fancy
-pattern, or may be scattered haphazard. Fine bare wire (No. 36 B. & S.
-is not any too small) is run from tube to tube, using care that it does
-not touch itself in such manner as to short circuit the current. There
-is not much necessity to cover the wires, unless the rate of vibration
-of the contact be so rapid as to show the brush discharge from the wire
-strands. In a jewelry store the cylindrical portions of the tubes may
-be covered with strips of dark cloth, concealing all but the bulbs.
-The Uranium bulbs will resemble emeralds; the yellow bulbs, topaz; and
-the blue, turquoise—certainly a very striking collection of gems. A few
-diamond-shaped pieces of the foil-coated glass scratched across, by the
-whiteness of the tiny sparks will aid to set off the whole. The outfit
-is not expensive: a coil giving a one half inch spark will light from
-four to six tubes to great brilliancy. Cloths with metallic threads
-woven in them must not be used, nor any of the metallic powders known
-in the trade as "glitters."
-
-
-
-
-CHAPTER IX.
-
-GAS LIGHTING.
-
-
-When it is desired to light clusters of gas jets situated in
-inaccessible places, or a number of them simultaneously, this method
-finds ready application. It operates in the division of a long spark
-among a number of burners, the gas being turned on at the main and
-the primary circuit of a Ruhmkorff coil closed and opened until the
-succession of sparks ignites the gas, Fig. 55. There are various
-commercial forms of these burners, prominent among which is the "Smith
-jump spark" burner.
-
- [Illustration: FIG. 55.]
-
-A lava tip is provided with a mica or isinglass flange midway between
-the tip and the lower end of the burner. This flange isolates the
-electrodes from any possibility of the spark straying away to the
-metallic pillar in which the burner is inserted. The multiple lava tip
-burner is intended for use where a very short burner is needed, also
-for flash rings multiple lights. Here the tips are placed close enough
-together to ignite by contagion. In this case one of the common tips
-is removed from the ring and a multiple lava tip substituted. It is
-customary to allow sixteen burners to one inch of spark. Any number of
-series can be operated alternately by means of a suitable switch.
-
-The wire used to connect the burners is generally bare copper, and as
-small in diameter as will sustain its own weight without injury, the
-amount of the current being infinitesimal. It is supported on porcelain
-or glass knobs screwed to the wall or ceiling, being carefully planned
-to avoid any metallic substances to which the spark might be tempted
-to escape. In wiring chandeliers, the wire is run through glass tubes
-wherever there is any liability of its coming near the metal pipes.
-There is a very great danger of this jumping of the spark where it is
-not wanted, and the utmost care must be taken in planning the course
-the wires shall take. Even a damp wall will cause trouble or a gilt
-cornice, although the latter may be entirely insulated from the ground.
-The switch bases for the groups of circuits must be of hard rubber, and
-the switch points and levers be placed so far apart that there is no
-liability of the spark jumping, which it certainly will do if it gets
-a chance. Ordinary insulated wires are ineffectually protected by the
-rubber compounds used. Glass, mica, and better still, a large air gap
-are the only insulations that will serve, for the tremendous potential
-or voltage of the current must be carefully considered whenever
-insulation is necessary. The coil is better provided with a spring key
-in the primary circuit than a vibrator, it gives better control of the
-circuit and probably a larger and better spark.
-
-
-GAS LIGHTING IN MULTIPLE.
-
-The spark which occurs at the contact breaker of a Ruhmkorff coil
-is held in check by the condenser; were no condenser used, it would
-possess considerable powers of combustion. Using a large primary coil
-and a few cells of open circuit battery, this spark is made to pass
-across the path of a gas jet, which it instantly ignites. The contact
-breaker consists of a platinum point, fixed on the gas tip, and a
-German silver spring, carried on a lever, which latter is pulled across
-the tip so as to make and break the circuit at the burner orifice. Some
-burners are provided with a ratchet arrangement, by which pulling the
-lever once turns on and lights the gas, pulling again turns it off;
-others require the gas to be turned on first.
-
- [Illustration: FIG. 56.]
-
-Reference to Fig. 56 will show the connections to two burners _P P_ and
-an automatic burner _A_, to be described later. The coil _C_ is a core
-of soft iron, about ¾ inch diameter and eight to ten inches long, wound
-with from two to four pounds of magnet wire, Nos. 12 or 14 B & S. One
-side of the battery goes to ground or to the gas pipe, thus forming the
-return circuit. The wiring on the fixtures is done with No. 20 to 24 B
-& S gas fixture wire, insulated with four windings of silk or cotton.
-This is fastened to the lacquered brass work by means of thick shellac
-varnish, it being tied on first with thread, which can readily be
-removed when shellac is dry and hard. The wire is held on the insulated
-collar of the burner by a small nut and screw, and great care must be
-taken to ensure no grounding. The setting up of a gas-lighting outfit
-is extremely simple, but it often fails for want of care. There must be
-the best possible insulation between wire and metal work.
-
-
-AUTOMATIC BURNERS.
-
-There are several forms of these burners, but the principle of all is
-the same. A gas burner protrudes from the top of a brass case which
-encloses the actuating mechanism. This mechanism consists of two
-electromagnets, the armature of one opening a valve and allowing the
-gas to flow, at the same time vibrating a platinum-tipped rod, which
-produces a series of sparks at the burner tip. These sparks ignite the
-gas, and a second magnet is provided to shut off the flow of gas, thus
-extinguishing the light. Some devices use one electromagnet for both
-lighting or extinguishing, but the majority are with double magnets.
-The circuit is worked from a push button situated at any desired
-location, and having a white and black button, one for lighting and
-the other for extinguishing. The principal automatic burners are the
-Holtzer, the Boston, and the Bartholdi, between which there lies little
-choice, so admirably are they constructed.
-
-
-BARTHOLDI AUTOMATIC BURNER.
-
-Instead of a rotating stop-cock, as in other automatics, a gravity
-valve is employed in the Bartholdi, which is held to its seat by the
-weight of the armature and connecting stem, as shown in Fig. 57. When
-the gas is turned off the valve rests upon its seat, as indicated in
-the cut. By a closure of the electric circuit at the turn-on button,
-two of the helices _M P_ are energized, causing the armature _J_ to
-be lifted, thus, by means of the stem _H_, raising the valve _G_ from
-its seat into the dotted position, and opening the gas way so that
-the gas may issue to the tip, as shown by the arrows. At the same
-time, the top of the valve strikes against the end of the lever _W_,
-causing the circuit to be broken at the spark points _T U_, resulting
-in a continuous sparking as long as the finger presses the button.
-The magnet when raising the armature has also twisted or partially
-revolved it, so as to bring the notch _d_ in the armature over the end
-of the hook _e_, as shown in dotted lines. When the circuit is broken
-by lifting the finger from the button the notch falls into the hook and
-the valve is locked open.
-
- [Illustration: FIG. 57.]
-
-To extinguish the flame the turn-off button is pressed, when a second
-magnet (not shown in cut) lifts the armature and twists it in the
-opposite direction, so that when the circuit is broken the armature
-falls free to its normal position, closing the valve.
-
- [Illustration: FIG. 58.]
-
-In wiring up an automatic burner it is necessary to run two wires to
-it, one from the white button and another from black button on push
-plate _S_. Reference to Fig. 58 will make this clear. Most burners
-are provided with two binding posts inside the brass case, and the
-wires are run through a rubber-bushed hole in the base. If the push
-has already been set in position and wired up, as per Fig. 58, have
-the buttons pressed alternately, when on touching the binding posts
-on automatic with the wires, the lighting or extinguishing connection
-is easily selected. The lighting armature in most automatic burners
-buzzes violently, while the extinguishing one only strikes once on
-contact being made. Fig. 58 shows how to connect up two pushes to one
-automatic, one push, perhaps, being located downstairs and the other
-upstairs in the case of a hall lamp. In setting up these burners care
-must be taken not to bend contacts or alter adjustment, and absolute
-precaution is necessary that no crosses or weakly insulated places
-are in circuit. After burning for some time it often happens that the
-burner refuses to light, only buzzing feebly or not at all. If feebly,
-the trouble is in battery, which should consist of, at least, four or
-six cells of open circuit battery with low internal resistance, such as
-Samson-Law carbon cylinder, or for occasional use large, dry cells.
-
-If no click is heard on pressing white button, examine all connections;
-if still no trouble is found, examine the platinum break. The platinum
-tip may be bent by the continual hammering against the platinum tip on
-vibrating rod, preventing contact on collar, or that soot has formed
-there. These are the commonest maladies of automatic burners, and can
-be easily remedied by readjusting platinum tip and cleaning. Contacts
-here must be clean. In general wiring use waterproof office wire or,
-better still, rubber-covered wire; for fixtures use the fixture wire
-before described. When shellacking the wire to the fixture don't
-attempt to connect up batteries until the shellac is dry and hard,
-say for half a day. Electric gas-lighting is fruitful of trouble if
-the work is not well done. Another cause of trouble may arise from a
-dirty burner not allowing the gas to strike near the contact (clean
-the burner), or the collar carrying contact may have shifted, perhaps
-short-circuited; it should be insulated with a thin strip of asbestos.
-Although white lead at the joints makes a fairly good contact, some
-persons prefer to use tin-foil, a piece of foil being worked around
-screw thread and the burner screwed on; it prevents leaks as well as
-lead if well done, and makes better contact. As a short circuit on
-the wires will cause all the burners to fail, many devices have been
-invented to open the circuit upon such an occurrence. These will be
-found described in the catalogues of electrical stores; they do not
-come within the province of this book for description.
-
-
-
-
-CHAPTER X.
-
-BATTERIES FOR COILS.
-
-
-In selecting a battery to operate the coil, one is needed which will
-supply a large steady current for a considerable period. Although the
-primary circuit is opened and closed rapidly, yet the class known
-as open circuit cells is not suitable, even though they have a low
-internal resistance, and thereby render a large current. Such cells
-are only suitable for the uses for which they are mostly designed,
-bell-ringing or annunciator work. There is one case, however, where an
-open circuit cell may be used with an induction coil, and that is in
-gas lighting as previously described; but here a dozen or so impulses
-of current are generally sufficient, followed by long periods of rest.
-For the latter work the cells in common use are the Samson, Champion,
-and Monarch, all of which are of low internal resistance and great
-recuperative power.
-
-The reason that such cells will not work for long periods, is that they
-polarize. This latter action takes place in these open circuit cells,
-which are of the Leclanché type as follows: A positive plate of zinc
-is immersed in a solution of ammonium chloride (or salammoniac), and a
-negative plate of carbon and peroxide of manganese, contained either in
-a porous cup or compressed into a block also stands in the solution.
-Care is taken that these two plates do not touch each other. When the
-outside circuit is closed the zinc combines with the chlorine of the
-solution liberating free hydrogen and ammonia. The hydrogen appears
-at the negative plate, where it is acted upon by the oxygen of the
-peroxide of manganese to form water.
-
-But when the circuit is of too low resistance, the oxidizing action of
-the peroxide of manganese is not rapid enough, and a film of hydrogen,
-which is a poor conductor, forms over the negative plate, increasing
-the internal resistance of the cell and setting up local action. In
-the best class of these open circuit cells, this hydrogen is absorbed
-after a rest, and the battery recuperates and is ready for work again.
-The circuit of the Ruhmkorff coil is low, and this polarization always
-occurs a few minutes after the contact-breaker is started.
-
- [Illustration: FIG. 59.]
-
-In the class of closed circuit cells, chosen for the present purpose,
-the Grenet or bottle bichromate is one of the handiest for occasional
-use. A glass bottle-shaped jar, _J_, Fig. 59, is provided with a hard
-rubber cap, _G_, on which are mounted the binding posts _A B_. To
-the underside of this cap are attached two carbon plates _C C_, which
-reach nearly to the bottom of the jar, being connected together on the
-cap by a varnished copper strip, the latter being in turn connected to
-one binding post. Through the centre of the cap passes a brass rod,
-_R_, having attached to its lower end a piece of sheet zinc, _Z_, well
-amalgamated with mercury. This process of amalgamation consists in
-cleaning the zinc, then rubbing its surface with a rag dipped in dilute
-sulphuric acid, and pouring a few drops of mercury on the wet zinc.
-The mercury will spread readily over the zinc, provided it has been
-well cleaned, and if properly done should give the zinc plate a bright,
-shining appearance.
-
-When the cell is not in use, the zinc is drawn up into the neck of
-the bottle and clamped by a set screw against the brass rod. A copper
-spring pressing on the rod serves to carry the current to the second
-binding post.
-
-This cell originated in France, whence its name, but a cheaper form is
-now made in the United States known as the Novelty Grenet. The shape of
-the jar is somewhat different, and the carbon is moulded, whereas the
-French carbon is sawed from the carbon deposited in the gas retort; but
-the American form is practically of as great utility as the French, and
-the cost recommends it.
-
-The bichromate solutions are affected by light, and deteriorate less it
-kept in stoneware jugs. The Grenet battery can very well be fitted into
-a neat wood case, which will serve the further purpose of preventing
-chance knocks from fracturing the glass jar.
-
-Carbons which are used in batteries containing the foregoing solution
-should be well washed in warm water whenever the solution is changed,
-and especially when it is intended to put the battery out of active
-service. When the solution acquires a decidedly green hue it should
-be replaced with fresh. The electromotive force of this cell varies
-from 1.90 to 2 volts, and the amperage is dependent on the size of the
-plates, running from 5 amperes upward.
-
-The glass jar is filled up to the commencement of the neck with a
-solution of bichromate of potash or sodium, called electropoion fluid,
-and prepared as follows: To 1 gallon of water add 1 pound of bichromate
-of sodium, mixing in a stoneware vessel. When dissolved add 3 pounds
-of sulphuric acid in a thin stream, stirring slowly. As the mixture
-heats on the introduction of the acid, care must be used to pour in the
-latter slowly. This solution should not be used until quite cold.
-
-The sodium salt is preferable to the potassium, owing to its not
-forming the crystals of chrome alum, and also on account of its lower
-cost and greater solubility, the latter being four times greater than
-that of the potassium salt. The commercial acid used should contain at
-least 90 per cent pure acid and should be free from impurities. On
-filling the battery use utmost care not to splash the solution on any
-of the metal work, or it will cause corrosion. Although the salts in
-the solution will most likely make a stain, the corrosive action of the
-acid can be arrested if the solution be splashed on the clothes by the
-prompt application of ammonia solution.
-
- [Illustration: FIG. 60.]
-
-The "Fuller" cell, Fig. 60, which is another type of the bichromate
-cell, is one from which a steady current can be obtained for a
-longer interval than from the Grenet, but the current is less. The
-electromotive force is the same, but the current is only 3 amperes,
-except in certain modifications.
-
-In the porous cup is a cone-shaped zinc having a stout copper wire cast
-in. This wire is occasionally covered with rubber insulation, but,
-as a rule, is bare. The porous cup is of unglazed porcelain, thick,
-but very porous. This sets in the glass jar, a wooden cover fitting
-_loosely_ over the whole to exclude dust. Through this cover passes
-the wire leading from the zinc, and also the carbon plate carrying a
-machine screw and check nuts for connection. The cover is dipped in
-melted paraffin, as is also the upper end of the carbon and the rim
-of the glass jar. This is to prevent the creeping of the salts in the
-solutions and the corrosion of the brass work.
-
-Into the porous cup is poured a solution composed of 18 parts by weight
-of common salt and 72 parts by weight of water. Electropoion fluid is
-held by the glass jar, the two solutions reaching a level of two thirds
-the height of the jar. One ounce of mercury is added to the porous cup
-solution to ensure the complete and continuous amalgamation of the
-zinc. The salt can be more readily dissolved in warm water, but _all_
-solutions must be used _cold_. It is not always necessary to renew the
-solutions when the battery fails to give out its accustomed strength,
-but several ounces of water can be substituted for a similar amount of
-fluid in the porous cup. Stir the solution by moving the zinc up and
-down, and a temporary improvement will be noticed.
-
-To obtain a greater current from this cell, use a larger zinc, such as
-a well-amalgamated zinc plate, and add a teaspoonful of sulphuric acid
-to clean water for the porous cup solution. Additional carbon plates
-connected together and placed round the porous cup will lower the
-resistance of the cell and increase the current, and also tend to keep
-down the polarization.
-
-A new form of this battery was described by M. Morisot a short time ago.
-
-The positive pole is of retort carbon in the outer cell in a
-depolarizing mixture made of 1 part sulphuric acid, 3 parts saturated
-solution bichromate of potash, crystals of the latter salt being
-suspended in the cell to keep up the saturation. A porous cup contains
-a solution of caustic soda. The zinc is in a second porous cup placed
-within the first, which holds a caustic soda solution of greater
-density. The electromotive force is 2½ volts when the cell is first
-placed in circuit, and will remain at 2.4 for some hours. The internal
-resistance is low, but varies with the thickness of the porous cups.
-This cell is not suitable for any but use for a few hours at one time.
-
-The Dun cell has a negative electrode of a carbon porous cup filled
-with broken carbon. The zinc is in the form of a heavy ring, and hangs
-at the top of the solution in the outer jar. Permanganate of potash
-crystals are placed in the porous cup, and the entire cell filled with
-a solution of caustic potash 1 part to water 5 parts. The voltage is
-1.8, and the internal resistance being low the resultant current is
-large.
-
-A cell with an electrode of aluminum in a solution of caustic potash
-and carbon in strong nitric acid in porous cup is claimed to have an
-electromotive force of 2.8, but the nitric acid is not a desirable acid
-to handle.
-
-Metallic magnesium in a salammoniac solution with a copper plate in a
-hydrochloric acid and sulphate of copper mixture is of high voltage,
-nearly 3 volts being obtained, and the current is large, but it is a
-new combination and has not as yet stood the test of time.
-
-There are other formulæ for solutions to be used in Fuller or Grenet
-cells which may be useful to the experimenter. Trouvé's is as follows:
-Water, 36 parts; bichromate of potash, 3 parts; sulphuric acid, 15
-parts, all by weight. Bottone's: Chromic acid, 6 parts; water, 20
-parts; chlorate of potassium (increases electromotive force), ⅓ part;
-sulphuric acid, 3½ parts, all by weight. A convenient "red salt" or
-"electric sand": Sulphate of soda, 14 parts; sulphuric acid, 68 parts;
-bichromate of potash, 29 parts; soda dissolved in heated acid, and
-potash stirred in slowly. When cold can be broken up and prepared when
-required by dissolving in five times its weight of water.
-
-The chromic acid used in Bottone's solution is very soluble in water,
-it being possible to dissolve five or six times the amount in the same
-quantity of water as of bichromate of potash. The simple solution of
-chromic acid is 1 pound to 1 pint of water, to which is added 6 ounces
-of sulphuric acid.
-
-When it becomes necessary to cut zinc plates, it may be readily done by
-making a deep scratch on the surface, filling the scratch first with
-dilute sulphuric acid, and then with mercury. The mercury will quickly
-eat into the metal, and the plate may be easily broken across or cut
-with a saw. Zinc plates can be bent into shape by the application of
-heat. Hold the plate in front of a hot fire until it cannot be touched
-by the bare hand: it will be found that it has softened so that it
-can be bent around a suitable wooden form. As zinc plates are most
-attacked at the surface of the acid solution, it is advisable to coat
-the extreme upper portion of them with varnish or paraffin. Rolled
-zinc is always preferable to cast, especially so when immersed in acid
-solutions.
-
-To avoid confusion, it may be stated here that it is the rule to speak
-of the zinc element as the positive plate and the negative electrode or
-pole, and the carbon _vice versa_. The portion of the element immersed
-in the solution is the plate, the part outside, the pole or electrode.
-In diagrams and also in formulæ positive is shown by a + (plus) sign
-and negative by a-(minus) sign.
-
-The relation of cost of the materials most used is shown in the
-subjoined table, which cost, however, varies with the market:
-
- Sulphuric acid, chemically pure 18
- " " commercial 1.5
- Muriatic " 1.12
- Nitric " 3.5
- Electropoion fluid 2
- Bichromate of potash 10.5
- " " soda 8.5
- Caustic soda 9
- Salammoniac 7
- Chromic acid 19
- Blue vitriol 4
- Litharge 5.75
- Mercury bisulphate 94
- Paraffin 9
- Beeswax 35 to 45
- Shellac varnish 87
- Tinfoil 35
-
-
-GRAVITY BATTERY.
-
-A cheap modification of the Daniell cell. A glass jar has at the bottom
-a copper plate consisting of 4 to 6 leaves of thin sheet copper, set
-on their edges in a starlike shape, a copper wire being attached to
-the copper rivet which holds the leaves together. A mass of crystals
-of sulphate of copper is filled in and laid on the top of the copper
-electrode an inch or so above its top. The negative plate is a
-variously shaped plate of cast zinc hung from the edge of the jar and
-reaching about 2 inches from the top into the fluid. Water is poured in
-until it covers the zinc, and the battery is complete. The sulphate of
-copper deposits its metallic copper on the copper leaves and liberates
-sulphuric acid, which rises and attacks the zinc, setting free sulphate
-of zinc. The sulphate of zinc solution being of greater density remains
-near the bottom, and the sulphate of zinc solution stays near the zinc.
-When the cell is left too long on an open circuit the two solutions
-tend to mix, and copper is deposited on the zinc. The sulphate of zinc
-finally saturates the top solution, which has to be partly drawn off
-and replaced by fresh water and crystals of sulphate of copper dropped
-into the jar to take the place of that which has been decomposed.
-Electromotive force 1 volt, current from 3∕10 to 5∕10 of an ampere.
-The practical working of this cell will be treated of later on in
-these pages.
-
- [Illustration: FIG. 61.]
-
-The Gethins (Fig. 61) and the Hussey bluestone cells both have the
-zincs standing in porous cups (shown by dotted lines), which in turn
-are supported half-way down the jar, generally resting on the copper
-strip acting as a porous partition between the fluids. The zinc stands
-in a solution of zinc sulphate, or a weak sulphuric acid solution.
-The internal resistance is low, and the current large, being from 1
-to 5 amperes. These cells are the ideal bluestone cells for charging
-storage batteries requiring very little attention. The special Gethins
-cell shown in the figure has the copper made with a collar, which
-encircles the porous cup, and thereby lowers the internal resistance
-of the battery. The voltage not being over 1 volt, however, renders
-these cells hardly suitable for direct connection. Five cells connected
-in multiple would give all of 10 amperes of current, and 1 volt, and
-a number of these multiple groups could be connected in series for a
-higher voltage.
-
-
-GORDON BATTERY
-
-is similar in operation to the Edison-Lalande, but differs in details
-of construction. The zinc is a heavy ring suspended outside, but not
-touching a perforated tin cylinder closed at the bottom, containing the
-oxide of copper in flakes. Its internal resistance is slightly higher
-than the Edison-Lalande cell, otherwise there is little choice. The 6 ×
-8 size is excellent for coil work, giving 250 actual ampere hours and
-remaining on open circuit for long periods without deterioration.
-
-
-EDISON-LALANDE CELL.
-
-This is a practical form of the old Lalande-Chaperon cell, and gives
-a steady, large current, being of low internal resistance, but is of
-low electromotive force, being less than .70 volt on closed circuit
-of medium resistance. Being of low internal resistance, however, its
-output is large—three cells of the type _S_; internal resistance, 0.025
-ohm. Capacity, 300 ampere hours, will about equal one cell type E 5
-of the Chloride Storage Battery. The elements of this cell consist of
-positive plates of amalgamated zinc, suspended on each side of negative
-plates of the black oxide of copper in an electrolyte solution of
-caustic potash. In action the decomposition of water forms an oxide of
-zinc from the positive element, which with the potash in combination
-leaves a soluble salt of zinc and potash. The hydrogen of the water
-acts on the oxide plates to form metallic copper, thus really reducing,
-instead of increasing, the internal resistance of the cell. A layer
-of heavy paraffin oil is poured on top of the solution to prevent the
-action of air.
-
-
-NEW STANDARD,
-
-or Roche dry cell. This cell possesses remarkable recuperative powers
-and low internal resistance. Made in many sizes, the best suited for
-medical coils is No. 2; dimensions, 5-7∕8 × 2-7∕16 inches. For heavier
-work the No. 5, 6 × 2-9∕16 inches, and known as the Navy Standard, is
-recommended. A convenient size for portable medical coils is No. 3, 3¾
-× 1⅞ inches, taking up very little room, yet giving a large output.
-Two of these latter cells enclosed in the coil case will give with a
-suitably wound primary (No. 18 to 20 B & S) as strong a current as can
-be used in electrotherapy. For Ruhmkorff coils cells Nos. 6 and 7 (6
-× 3 inches and 7 × 3 inches) furnish a most desirable battery for all
-work not needing the constant operation of the contact breaker, such
-as wireless telegraphy, gas-lighting, etc. They will do service on
-X-ray work, but the writer prefers a storage cell or the copper oxide
-types. The E. M. F. of the above cells is one and six-tenths volts, and
-current from 9 amperes to the No. 7 size, which gives 24 amperes on
-short circuit.
-
-
-DRY-CELL CONSTRUCTION.
-
-As a matter of practice, there is no really dry cell; all so-called
-cells contain liquid held in suspension, and their output is limited
-to the amount of fluid. One of this type can easily be made in the
-following manner: A containing jar is made up of first-quality sheet
-zinc, the edges being joined by a turned seam and then soldered, the
-bottom of zinc being also soldered in. In soldering here, as actually
-in all such operations, be _absolutely sure_ the edges of the metal
-are clean. The jar is partially filled with the following composition:
-Oxide of zinc, 1 part; sal ammoniac, 1 part; plaster of paris, 3
-parts; chloride of zinc, 1 part; water, 2 parts, all by weight; or sal
-ammoniac, 1 part; chloride of calcium, 5 parts; calcined magnesia, 5
-parts; water, 2 parts, or enough water to make a thin paste. A brass
-binding post is soldered to the zinc case and a carbon plate having a
-binding post is inserted in the centre of the cell, care being taken
-that it does not touch the zinc. A small disc of wood laid in the
-bottom of the cell will prevent contact at the bottom. Molten pitch
-or a composition of pitch and rosin in the proportion of 6 to 1 is
-poured on top, so as to seal the cell. As gas is generated in the cell,
-a safety valve should be provided, either a piece of porous cane or
-a short length of hard rubber tube, inside of which have been placed
-a few strands of woollen thread. This class of cell is so cheap and
-so many forms are available for choice that it is rarely desirable
-to make one's own. They will not do for steady current, but only for
-intermittent work. The large sizes being of low internal resistance,
-can be used for signalling in wireless telegraphy, where it is not
-possible to use wet (or free fluid) cells. The principal dry cells on
-the market are the Mesco, the O. K., the Nungesser, and the Samson
-semi-dry cell.
-
-
-
-
-CHAPTER XI.
-
-STORAGE OR SECONDARY CELL.
-
-
-The development of the storage or secondary cell has been one of the
-most important electrical advances of the century. For purposes of
-experiment or work, where a large or steady current is required from
-compact and readily tended apparatus, the storage cell proves its
-utility. The simplest form was that used by the early experimenters,
-and as it is easy to make, a form of it may very well be described.
-
- [Illustration: FIG. 62.]
-
- [Illustration: FIG. 63.]
-
-From a sheet of lead ⅛ inch thick two or more pieces are cut of
-the requisite size, say, 5 inches square. In making these plates,
-they should be cut so as to leave a strip 1 inch wide and 3 inches
-long, projecting from one corner, _A_ (Fig. 62), for the purpose of
-connection. This is for the reason that the fumes of the sulphuric
-acid solution would quickly corrode any wires or screws in the plates,
-and also to give a better connection. The number of plates cut must
-be an odd one, as it is general to make the two outside plates of the
-same polarity—viz., negative. These plates are then scored with a steel
-point across and across on both sides to perhaps a depth of 1∕64 of an
-inch. This scoring is not absolutely necessary; it somewhat hastens the
-formation of the plates. The plates are then laid face to face, being
-separated by pieces of wood, rubber, or, still better, by a piece of
-grooved wood, Fig. 63 having a thin piece of asbestos on each side.
-These grooves are to carry off the gas, and should run up and down the
-board, as in the figure. The wood is ⅛ of an inch thick or thereabouts,
-and preferably perforated with holes ¼ of an inch or larger. When laid
-together, a few strong rubber bands hold the plates from coming apart.
-To prevent lateral motion, a few rubber pins may be thrust through
-the plates. The alternate strips are to be connected together in two
-series, as in a condenser, and the complete series placed in a jar
-containing a mixture of seven parts of water to one of sulphuric acid.
-The terminal of the strips connected to the smallest number of plates
-is to be marked _P_ or +, for positive.
-
-This terminal is now to be connected to a charging current (not over 1
-ampere), as described in the directions for charging batteries, for
-eight hours, and then discharged at a rate not over 1 ampere for six
-hours. Then the connections are to be reversed and the cell charged
-backward, as it were, and discharged. This has to be repeated for a
-long period, perhaps a month, before the cell is in good condition; on
-the final charge it is to be connected positive to positive of charging
-source. This operation is called "forming," and the result is to change
-the metallic lead of the positive plate into red-brown peroxide of
-lead, and the lead negative plates into spongy lead.
-
-In modern commercial cells this operation is no longer pursued, the
-plates are variously constructed of lead frameworks holding plugs of
-litharge or lead oxide, which is "formed" with great facility. For many
-purposes other than operating Ruhmkorff coils, a few simple cells made,
-as described, are handy to have and easy to make. In sealing the cells
-up for portability, care must always be taken to leave a small hole in
-the cover for the escape of the sulphurous acid gas.
-
-
-CHARGING STORAGE BATTERIES.
-
-Although the charging of a storage or secondary battery is by no means
-a difficult operation, yet it requires care, and one unaccustomed
-to the work will meet many slight difficulties which may seriously
-affect the results. Pre-eminently the best charging source is a direct
-current, constant potential electric-light circuit. The amount of
-current required varies according to the type and make of the cell, but
-we will select one of a capacity of 50 ampere hours for illustration.
-
-By 50 ampere hours is meant a delivery of 1 ampere per hour for fifty
-hours, or a rate of discharge equal to the above, as 2 amperes per hour
-for twenty-five hours. In practice a secondary cell will not be found
-to act exactly as above, the total amount of current decreasing as
-the discharge is greater. Each cell is constructed to discharge at a
-certain rate, above which it is not safe to go. Five amperes per hour
-is a suitable rate for a fifty-hour cell, and should not be greatly
-exceeded. The Chloride type, however, is one which can be discharged
-at a higher rate than normal without any serious results, the latter
-being generally a bulging or "buckling," as it is called, of the plates
-whereby they short circuit or fall apart. The voltage of the charging
-source should be at least 10 per cent over that of the battery when
-fully charged. The voltage of a cell of storage battery varies from
-about 2.3 at commencement of discharge to 1.7, at which latter voltage
-discharge must be stopped and charging recommenced.
-
-Fig. 64 shows the connections to charge a storage battery from an
-electric-light circuit. The latter must be direct current and of low
-tension. The circuit from the negative lead runs to the rheostat handle
-_R_, thence through as many coils as are in circuit (varied by moving
-the handle over the contact pieces in connection with the resistance
-coils). The positive of the cell is connected to the positive main.
-
-In connecting storage cells to the mains the utmost care must be taken
-that the terminals are correctly attached. It happens in isolated
-plants that some change is made in the wiring or the switchboard,
-which reverses the current without warning being given to the battery
-charger. It is the safest way to test the polarity of the terminals of
-_both_ battery and mains each time charging is commenced. For polarity
-tests see Chapter I. It is immaterial on which side of the battery the
-rheostat or similar device is placed.
-
- [Illustration: FIG. 64.]
-
- [Illustration: FIG. 65.]
-
-Fig. 65 shows the employment of lamps instead of the rheostat. The
-lamps _L L_ regulate the current flow by the manner in which the
-circuit is arranged. If only one lamp be turned on, the current
-necessary for only one lamp circulates through the battery. Each
-additional lighted lamp adds to the current by decreasing the
-resistance of the circuit. _S_ is a switch which must always be left
-open when the dynamos are to be stopped.
-
-
-CHARGING FROM PRIMARY BATTERY.
-
-In many instances an electric-light circuit is not available for
-charging purposes, in which event recourse must be made to a primary
-battery. The one most suited for the work is the modified Daniell,
-or copper and zinc combination in solutions of sulphate of copper
-(bluestone) and sulphate of zinc respectively.
-
-There are many good forms of this cell on the market, chief of which
-are the simple gravity, the Gethins, and the Hussey, which have
-been previously described. An example will now be described of the
-operations necessary with the gravity cell, charging one 50-ampere
-hour storage cell. At least six cells of gravity will be required, as
-the voltage of each cell is never over 1 volt, and is dependent on
-the resistance in the external circuit falling as the resistance is
-lowered. Place the six clean glass jars on a firm foundation, where
-there is no liability of shaking and no dust likely to settle. Unfold
-the copper strips into the form of a star, bending the corners for half
-an inch so as to give an anchorage in the bluestone. Place them into
-the bottom of the jars and pour in water enough to cover them at least
-3 inches below the surface. Now carefully drop in 4 pounds of clean
-bluestone, which will fill in the angles between the copper wings, at
-the same time holding the element down to the bottom of the jar. Hang
-the zincs from the top edge of the jar, and fill up with water to 1
-inch from the top. The addition of 5 ounces of sulphate of zinc per
-cell will render the cells immediately available, and for the further
-hastening of the chemical action, the copper wire from each copper may
-be inserted in the binding post-hole of the zinc belonging to its own
-cell and screwed tight for a few hours; or the cells may be connected
-together in series, and the wire from the last copper be screwed to the
-zinc of the first, thus putting the whole series on short circuit. The
-only advantage of the first method being a saving of time when a number
-of cells is being set up. This saving of time is often of consequence,
-as the longer the newly set-up cell is on open circuit, the more
-copper will be deposited on the zinc, which is highly undesirable.
-This is shown by the blackening of the zinc as soon as it is put in
-the solution, which blackening it is hard to prevent entirely. When
-the cell is working satisfactorily it will show a clearly defined line
-between the colorless solution above and the deep blue solution beneath.
-
-Gravity cells should never be moved. If no sulphate of zinc is
-available, half a teaspoonful of sulphuric acid may be poured in over
-the zinc, which will tend to form the sulphate of zinc. Without any of
-these helps the cell will take at least twenty-four hours on a short
-circuit before it will give its normal current. This current should
-be from 4∕10 to 5∕10 of an ampere. Five cells set up by the writer
-varied after the addition of the zinc sulphate from 200 milli-amperes
-(thousandths of an ampere) to 300 milli-amperes, although they were
-apparently all set up alike; but after twelve hours' short circuiting
-they all gave a fairly uniform current of from 470 to 500 milli-amperes.
-
- [Illustration: FIG. 66.]
-
-From time to time on storage battery work, say, every week, the
-specific gravity of the top solution must be tested with a hydrometer
-(see Fig. 66), which should be put into the solution and allowed to
-come to rest. The indicated number at the level of the liquid should
-be 25°. If the number is higher some solution should be drawn off
-and clear water added, until the hydrometer settles down to 25° or
-thereabouts. The inside of the glass jar for 1 inch from the top may be
-greased to prevent the salts of zinc creeping over the edge, or half an
-inch of heavy paraffin oil be poured on the top to prevent evaporation
-and creeping. When the zinc gets very much coated with the dark deposit
-it must be taken out and scraped and washed. When the bluestone needs
-replenishing, drop in carefully and be sure none lodges on the zinc
-element.
-
-
-SETTING UP THE STORAGE CELL.
-
-Each manufacturer of storage cells issues specific directions for the
-charging of his own make, but generally the method is as follows:
-The acid solution is prepared by mixing one volume of sulphuric acid
-to from four to seven volumes of water, according to the make of the
-cell. The sulphuric acid should have a specific gravity of 1.82 and be
-chemically pure. _The acid must always be poured into the water, and
-slowly, stirring all the time, then set aside for the mixture to cool._
-It is best to mix the solution in a separate earthenware vessel, and
-when two or more cells are to be set up, to mix all the solution at
-one time, to ensure the same strength, unless a hydrometer is used to
-determine this.
-
-A good method to ascertain the exact quantity of solution required
-is to place the elements in the jar and cover 1 inch deep at least
-with water, then remove the elements and pour off the volume of water
-corresponding to the proportion of acid to be added, and lastly pouring
-the remaining water into the mixing vessel, prepare the solution, or
-electrolyte, as it is called. New elements should be wetted with pure
-water before being immersed in the solution. An ordinary charge of
-the electrolyte requires from six to ten hours to cool thoroughly, as
-considerable heat is evolved in the mixing.
-
-Having now prepared the storage battery solution and set up the primary
-cells, the charging can be proceeded with. The current must be turned
-on the storage cell immediately the elements are placed in the acid.
-Connect the wire from the zinc of the primary battery to the negative
-of the storage cell and the copper wire to the positive. As the current
-from a gravity cell is but small, it will take quite a time to charge a
-storage cell of 50 ampere hours' capacity fully; it is a good scheme to
-get the cell charged up from a dynamo source, and use the gravity cells
-to keep it charged; but this cannot always be done, and the gravity
-battery will do the work in time. As the best storage cells render but
-90 per cent of the current put into them, they must be charged over the
-number of hours for which they are required to deliver current.
-
-When the cell is fully charged the solution will become milky and
-give off gas freely. This gas in large quantities is detrimental to
-health, and on no account should a storage cell be _charged_ in a
-sleeping apartment. It affects the throat and lungs, and renders them
-susceptible to take cold under suitable circumstances. The average
-voltage of storage cells, when tested with the charging current on, is
-2.4 volts, and the lowest they should be allowed to reach is 1.9 volts,
-unless otherwise specified by the manufacturers.
-
-Cells in poor condition are liable to form a _white_ deposit of
-sulphate of lead, this fault being known as "sulphating." This trouble
-requires much careful nursing, and the cells must be charged for a long
-time at a very low rate until the plates of the positive element regain
-their normal gray color. Chips of straw or excelsior, etc., falling in
-between the plates will carbonize and cause trouble.
-
-Most portable cells are sealed, but all cells can be easily sealed with
-paraffin wax for amateur use. Cover the elements fully ½ inch above
-the normal height of the electrolyte with water before pouring in the
-electrolyte. Melt some paraffin in an earthenware jar and pour it on
-top of the water, about the middle of the surface, when it will spread,
-and care having been taken to have the jar sides dry, will cake solid
-and form a good seal. Then bore a hole with a brace and bit or some
-such tool through the wax and pour out the water. The cell can then
-be set up as usual, the hole being only partly closed to allow of the
-escape of the generated gas. A glass or rubber tube can be sealed into
-the hole in the wax, and makes a more finished job.
-
-While on the subject of primary batteries for charging storage cells, a
-few remarks on their electromotive force may not be amiss. Although the
-specifications issued by the manufacturers specify an excess charging
-voltage of 10 per cent over the total voltage of the storage cells,
-this does not apply to primary cells in its entirety. The voltage of
-five gravity cells in series would aggregate 5 volts, and the voltage
-of one storage cell but 2 volts, but there would not be 5 volts
-available to force the charging current through the latter. In the
-first place there is the counter electromotive force of the storage
-cell working against the gravity battery. Simple subtraction would show
-only 3 volts excess in favor of the primary electromotive force; but
-the working voltage of a galvanic cell varies according to external
-resistance of the cell and the external resistance of the circuit.
-When the internal resistance is high, as in the gravity cell, and the
-circuit resistance is low, in this case being the storage cell, the
-available electromotive force of the primary is low also.
-
-In many cases it is desired to operate a Ruhmkorff coil from an
-electric-light main direct. This can readily be done if the circuit be
-of the constant potential class—that is, one constructed to furnish
-current for incandescent lamps in multiple. With the direct current,
-such as the Edison, all that is necessary is either to interpose a
-rheostat, as in Fig. 64, or to use the lamps, as in Fig. 65. The
-manner of connecting up is the same as if the storage cell B be
-replaced by the coil. Using the formula _C_ = _E_∕_R_, for example,
-if the circuit be at 110 volts and the coil require 10 amperes, a
-resistance of 11 ohms will be required. Or using the lamps in the
-diagram, Fig. 65, about 20 lamps are to be put in circuit. If the
-current be an alternating one, the contact-breaker will have to be
-screwed down or short circuited.
-
-
-THE "U. S." STORAGE CELL.
-
-This cell is of the lead-zinc type, being the practical form of the
-Reynier cell. It is to be recommended for working Ruhmkorff coils, its
-output weight for weight being far in excess of the lead-lead types.
-This cell is readily portable and easy of operation, the zinc electrode
-being the only one needing renewal, and that at very infrequent
-intervals.
-
-The lead electrode consists of plates of peroxide clamped together,
-and presents quite a large surface. The zinc in most types is of
-the circular sheet form, and encloses the lead block, being kept
-amalgamated by mercury lying in the bottom of the cell. The E. M. F.
-on open circuit is about 2.5 volts, which is higher than any lead-lead
-combination. On closed-circuit work this drops to from 2.35 volts
-downwards. During action, when a large amount of current is being drawn
-from the cell, a white sulphate appears, but this disappears upon
-the cell being recharged or even left to rest. Bubbles of gas, which
-sometimes form under the peroxide block, should be removed by gently
-tilting the cell or hitting the table or shelf upon which it stands
-a smart blow. The large type No. 3 is suitable for X-ray work, and a
-still larger cell is made, which is preferable for heavy or continuous
-discharges of current.
-
-
-HARRISON CELL.
-
-The No. 1 cell recently put upon the market has given excellent results
-for open circuit work. It consists of a negative element with lead
-peroxide as a depolarizer. The positive element is self-amalgamating
-zinc, which is free from local action. The electrolyte is dilute
-pure sulphuric acid. The potential is high, being 2.5 volts, and
-the internal resistance is 0.14 ohm. This cell belongs to a group
-which is midway between primary and storage, or secondary cells. Its
-construction is similar to the lead-zinc secondary cell, in place of
-which it may be used, it being easy to recharge an exhausted cell by
-passing a weak current through it in reverse direction, thus recharging
-the peroxide of lead grid and renewing the zinc and electrolyte.
-
-The large size, or type No. 3, which the manufacturers are producing,
-differs from the No. 1 cell in that it has a larger negative element,
-or grid, and has two zincs, instead of one; consequently, it has a
-lower internal resistance—0.07 ohm—and a higher discharge rate with
-a capacity of 150 ampere hours. The potential is 2.5 volts. It is
-suitable for coil work or for sparking gas engines, and for ease of
-manipulation and convenience is to be highly recommended.
-
- [Illustration: FIG. 67.]
-
-The elements are shown in Fig. 67, lead grid _L_, which is filled
-in with paste of peroxide of lead, and which neither buckles nor
-disintegrates. The zinc _Z_, however, possesses a novel feature.
-A cavity is cast in the zinc element and filled with an amalgam of
-mercury, the copper electrode passing through this amalgam into the
-solid zinc, as shown in the cut. As the action of the battery proceeds,
-this amalgam forces its way into the pores of the element and keeps
-up so good an amalgamation of both copper rod and zinc that zincs can
-be used up to a point when the rising internal resistance makes it
-economy to throw them away, and absolutely no perceptible local action
-takes place in the cell upon continued open circuit. A preparation
-is furnished if desired, which forms a jelly of the electrolyte,
-making the cell readily portable. Like all of these combinations, its
-electromotive force exceeds two volts, and its internal resistance is
-low enough to advise its employment in coil work.
-
-When a storage battery is to remain unused for a long time it must
-first be fully charged, and then every week or so the charging current
-passed through it until it bubbles. Where it is to be laid away
-for a long period of time, and weekly charging is not feasible, the
-following operations are necessary: First, fully charge battery, remove
-electrolyte, and replace by water immediately. Discharge at normal rate
-until voltage runs down to 1.7 per cell. Gradually decrease resistance
-until battery is almost on short circuit. Let it stand for a day, then
-pour off the water, and keep elements in a dry, clean place.
-
-
-
-
-CHAPTER XII.
-
-TESLA AND HERTZ EFFECTS.
-
-
-The currents of high frequency used by Tesla in his researches are
-produced by electrical rather than mechanical means. The alternating
-current dynamo used by him renders a current of 10,000 alternations
-per second, but the actual current necessary to the performance of
-the luminous effects has a frequency of millions of oscillations per
-second, produced by the discharge of Leyden jars or condensers.
-
-Dr. Oliver J. Lodge, in his "Modern Views of Electricity," shows
-that the discharge of the Leyden jar is in general oscillatory, the
-apparently single and momentary spark, when analyzed in a very rapidly
-rotating mirror, is shown to consist of a series of alternating
-flashes, rapidly succeeding one another and lasting individually
-less than one hundred thousandth of a second. The capacity of the
-condenser and inertia of the circuit regulate the rapidity of these
-oscillations. A 1 microfarad condenser discharging through a coil of
-large self-induction, such as one having an iron core, may oscillate
-only a few hundred times per second. On the other hand, a Leyden jar
-of the 1 pint size discharging through a short circuit will set up
-oscillations, perhaps ten million per second; and a still smaller jar
-would give oscillations away up in the billions. But these small jars
-are quickly discharged, and require a constant replenishing.
-
-The discharge actually consists of a principal discharge in one
-direction, and then several reflex actions back and forth, becoming
-feebler until their cessation. In their vibration they generate waves
-in the surrounding medium, similar in many respects to sound waves, but
-of infinitely higher velocity. Their length depends on the rate of
-vibration of the source and their velocity. The microfarad discharge
-before mentioned will have a wave length of perhaps 1200 miles, the
-small jar not over 70 feet; and yet the true light wave has only an
-average length of one fifty thousandth of 1 inch. These waves travel
-into space until they either die out from exhaustion or are absorbed
-by some suitable body; but they possess the quality of resonance in a
-degree like those of sound. Two tuning forks of the same pitch will
-influence one another—that is, one on being vibrated will start the
-other in vibration, even at a considerable distance, but the electric
-waves far surpass them in this respect.
-
- [Illustration: FIG. 68.]
-
-Dr. Hertz made the first practical experiments in this direction with
-his electric resonator (Fig. 68). This apparatus consisted of a 3-inch
-spark induction coil, _I_, the secondary wires _S S_ being connected
-to the copper rods _R R_, provided with metal balls _B B_, nearly 11
-inches in diameter. The discharging balls _D D_ were approximated
-until a satisfactory discharge passed between them. A large wire ring
-having a spark gap in its circuit was so influenced by the resonance
-as to show minute sparks passing across this gap even when the ring
-was situated in a distant room. In many experiments with a rapidly
-vibrating induction coil current, a sparking has been noticed in
-metallic objects in the same room, in one instance it being discovered
-in the metallic designs on a wall-paper.
-
-
-THE "TESLA" EFFECTS.
-
-In exploring the comparatively new field opened up by Professor
-Crookes, Nikola Tesla has stimulated research into the mysteries of
-high tension and frequency currents and their effects. In the majority
-of his experiments Tesla uses alternating currents generated by
-machinery of his own design, but in a large number of cases his effects
-can be duplicated with an induction coil suitably energized. In the
-latter case the apparatus consists of a battery, a Ruhmkorff coil, two
-condensers, and a second specially constructed induction or disruptive
-coil, with some few subsidiary implements. The contact-breaker or
-rheotome must be one giving interruptions of very rapid sequence.
-
- [Illustration: FIG. 69.]
-
-Fig. 69 shows a diagram of the Tesla arrangement with a Ruhmkorff
-coil. The terminals of the secondary coil of the Ruhmkorff coil _I_
-terminate at the condensers _C C_. Bridged across the wires before
-they reach the condensers is the discharger _D_. The second terminals
-of the condensers are led through the split primary of the disruptive
-coil, terminating at the points _B B_ of the second discharger. The
-secondary of the disruptive coil is either outside or inside the
-primary coil. The condensers are of special design, being small, but of
-high insulation. They each consist of two plates of metal a few inches
-square immersed in oil and arranged so they can be brought nearer
-together or further apart, as necessary. Within limits, the smaller
-these plates are the more frequent will be the oscillations of their
-discharge. They also fulfil another purpose, they help nullify the high
-self-induction of the secondary coil by adding capacity to it.
-
- [Illustration: FIG. 70.]
-
-The discharger tips are preferably metal balls under 1 inch
-in diameter. Tesla uses various forms of dischargers, but for
-experimental purposes the two metal balls will answer. They are
-adjusted when the whole apparatus is working according to the results
-desired. The mica plates serve to establish an air current up through
-the gap, making the discharge more abrupt, an air blast being also
-used at times for the furtherance of this object. The device (Fig. 70)
-consists of an electro-magnet, _C_, set with its poles _P_ across the
-air gap, helping to wipe out the spark, as in a well-known form of
-lightning arrester. This form, described by Tesla, has the pole pieces
-_P_ shielded by mica plates _M_, to prevent the sparks jumping into the
-magnets. Fig. 70 is an elevation and Fig. 71 a plan of this device.
-
- [Illustration: FIG. 71.]
-
-The resonance effects obtained during the operation of a Tesla coil
-are very marked, and their study may lead to the solution of the
-problems of communication between distant points without the use of
-other conducting media than the atmosphere. But the main use to which
-the Tesla currents have been put is that of artificial illumination.
-These currents have enabled experimenters to obtain a high luminosity
-in vacua by the aid of only one conducting wire—in fact, in some cases
-without the utilization of any conductor than the air. An ordinary
-incandescent lamp connected to one terminal of the coil will show in
-a fair degree some of the luminescent phenomena. The brush effects
-from the terminals of the secondary coil are extremely marked and
-interesting; but to detail the experiments that can be performed with
-the Tesla disruptive coil would be an impossibility here. Reference is
-recommended to the published works of Nikola Tesla, which happily are
-readily procurable.
-
-These currents of high frequency have of late been turned to account
-in electrotherapeutics, principally for the stimulation they exert on
-the nutritive process. They also exert a very great influence on the
-vasomotor centres, as is evidenced by the reddening of the skin and
-exudation of perspiration. This result is readily obtainable by placing
-the patient in connection with one electrode on an insulating stool,
-and terminating the other electrode at a large metal plate situated a
-few feet distant; or the patient may be surrounded by a coil of wire in
-connection with the coil of sufficient diameter, however, to prevent
-contact.
-
-
-
-
-CHAPTER XIII.
-
-THE "ROENTGEN" RAYS AND RADIOGRAPHY.
-
-
-Although the remarkable discovery that it was possible by electrical
-means to depict an image of an object on a photographic sensitized
-plate, despite the intervention of solid bodies, was first given to the
-world at large by Professor Roentgen, yet he was undoubtedly led to
-the results by consideration of the works of previous experimenters in
-electrical discharges through vacua.
-
-It is not intended here to trace the previous work of Professor
-Crookes, the inventor of the radiometer, which is actuated by the
-heat rays of light, nor of Hertz, who found that gold leaf was
-transparent to rays emanating from certain vacuum tubes carrying
-a luminous electrical discharge. It is mainly the purpose of these
-pages to give directions for practical work, and not deal in theories,
-interesting though they be. At the beginning of X-ray investigation
-many claims were made which have since been disproven, but the
-fundamental operations remain the same. A Crookes tube of special
-design is energized from a coil or similar electrical distributor,
-and by means of the resultant rays otherwise opaque objects appear
-partially transparent, their shadows being cast upon the screen of a
-fluoroscope, or these shadows are allowed to act upon a sensitized
-photographic plate, and subsequent development reveals outlines or
-shadowgraphs. The general arrangement of apparatus is shown in Fig. 72.
-_C_ is a Ruhmkorff coil, giving not less than 2 inches of spark; _B_
-the battery operating same; _T_ the modified form of Crookes tube used
-most generally; _X_ the object under observation; _F_ the fluoroscope
-or the sensitized photographic plate. The usual precautions are
-taken to avoid the leakage of current from the secondary wires, the
-tube _T_ being best mounted in a wooden stand (Fig. 72), and the wire
-connections brought to it as direct as possible. No condenser, stand,
-etc., are shown in drawing, to avoid unnecessary complication.
-
- [Illustration: FIG. 72.]
-
-
-THE FLUOROSCOPE.
-
-This is a funnel-shaped cardboard box with an opening at the smaller
-end for the eyes and a piece of card across the larger end. The inside
-surface of this card is covered with crystals of barium platino
-cyanide, the most satisfactory fluorescent substance obtainable. The
-earlier fluoroscopes were made with tungstate of calcium, but the above
-salt has proven far more satisfactory. The operation of the fluoroscope
-is simple. It is held in the hand by a convenient handle, the open
-end pressed close to the eyes, so as to exclude outside light, and
-with the hand or other object held against the outside of the big end,
-or screen, it is directed towards the Crookes tube. The screen then
-appears to glow with a bluish light, and the shadow of the object is
-distinctly seen on the screen. Different adjustments of the coil give
-results which will be treated upon later.
-
-
-PHOSPHORUS TUBE.
-
-Messrs. Siemens and Halske manufactured a tube which allowed of a
-slight variation of vacuum by using the vapor of phosphorus. An
-auxiliary tube containing phosphorus was added to the main tube, and
-upon heat being applied to it by means of a lamp, vapor is given off,
-which materially reduces the vacuum of the main tube. When the opposite
-result is desired part of the current is diverted through the auxiliary
-tube, and the vapor is caused to solidify itself upon the walls of the
-tube.
-
- [Illustration: FIG. 73.]
-
-
-THE CROOKES TUBE.
-
-The most satisfactory tube for X-ray work is one where the vacuum is
-readily adjustable. Reference to Fig. 73 shows the Queen form. A small
-bulb, containing a chemical which gives off vapor when heated and
-reabsorbs it when cooled, is directly connected to the main tube and
-surrounded by an auxiliary tube, which is exhausted to a low vacuum. In
-the auxiliary tube the cathode is opposite to the above-mentioned bulb,
-so that any discharge through it will heat the bulb by the bombardment
-of the cathode rays. The cathode is connected to a spark point, which
-can be adjusted to any distance from the cathode of the main tube. The
-anode of the small tube is directly connected to that of the main tube.
-When the tube is put into operation the vacuum and, consequently, the
-resistance of the main tube being high, the current preferably passes
-by the spark point and auxiliary tube, heating the chemical for a
-few seconds until sufficient vapor has been driven into the main tube
-to permit the current to pass through the latter. After this only an
-occasional spark will jump across the gap to counteract the tendency of
-the reabsorption of the vapor and consequent raising in resistance of
-the main tube.
-
-This device presents easy means of adjusting the vacuum in the main
-tube. With the spark point at a considerable distance from cathode the
-vacuum will be high. When the spark gap is short the vacuum will become
-low. The main bulb is about 4½ inches in diameter, and at the place
-where the X-rays pass only 1∕64 of an inch in thickness. The cathode is
-of aluminum, the anode of platinum. In starting this tube, it is best
-to make the spark gap about one inch in width. When connected up and
-working properly the main bulb will be filled with a green striated
-luminosity between anode and cathode, and the tip of the chemical bulb
-will have the shadow of the little platinum tip thrown upon it. The
-green light is not always brilliant; at times it is quite weak, but yet
-does its work well. A brilliant green light is often one of the signs
-of wrong connection, and particularly so when the little shadow on the
-chemical bulb is absent. Never run these or any other tubes backwards,
-but be sure the current is flowing in correct direction at first
-operation.
-
-Other forms of Crookes tubes differ only in form, or are devoid of
-adjustment, and the connections of coil, tube, etc., are the same.
-
-
-GENERAL REMARKS.
-
-A high vacuum gives greater penetrative power than a low vacuum. Where
-the operator has not an adjustable tube it is imperative that he have
-at least two tubes, one high and one low. It is the contrasts which
-render the X-ray practical, and these contrasts are largely governed
-by the vacuum. In locating a metallic substance in the human body a
-high vacuum tube would be needed, that the bones and dense tissue be
-rendered more transparent. On the other hand, to make a radiograph
-of the bones, a lower vacuum is necessary in order to get a contrast
-between the bones and the tissues. In general, a high vacuum is
-best for fluoroscope work and a low vacuum for making pictures on a
-photographic plate. Short exposures in radiography are obtained by
-powerful rays and consequently by coils operating at considerable
-energy. In extended examinations or where a subject is under the X-rays
-for more than a minute or so, a screen should be interposed between
-the subject and the tube to avoid the burning effect which is often
-noticeable. This screen consists of a piece of cardboard well covered
-with gold leaf, and should be grounded—that is, a connection be run
-from the gold surface to a water-pipe or other ground connection.
-Sheet lead is an efficient screen to the rays, and, if desired, a lead
-screen can be made, partially enclosing the apparatus, to protect the
-operator. But it must be large enough and far enough distant from the
-coil and tube to avoid any possibility of leakage of current or even
-inductive influence. In operating X-ray machines never attempt to alter
-connections or make adjustments other than at coil platinum screw or
-Crookes tube spark gap without first shutting off current. Remember
-that a very unpleasant shock can be easily obtained from touching the
-apparatus with only one hand. It is often advisable to remove one's
-watch, particularly when using Ruhmkorff coils of large size.
-
-The tube may be worked until it shows a slight redness in the centre of
-the platinum, but care must then be taken not to increase current, or
-the platinum will melt. Never allow the tube to come in contact with
-any object other than its stand and connections while working, and be
-sure the wires from secondary do not come near tube until they reach
-places of attachment, or they may spark through glass and ruin the tube.
-
-In making radiographs on sensitized plates the unused plates should
-be kept at a considerable distance from the coil while working. Better
-still if they are in another room. Plates for X-ray work are made by
-most photographic supply dealers; in fact, almost any good brand of
-sensitized plates or even films will answer. When making a radiograph,
-the plate can either be left in the holder or well wrapped in black
-paper, but current should never be turned on coil before the plate
-and subject are in position. In photographing the chest, neck, etc.,
-the plate can be strapped on to the part; but the subject must remain
-absolutely still. The time of exposure varies considerably with the
-size of coil, thickness of object, etc. Radiographs of the hand have
-been taken by simply laying the hand on top of the plateholder and
-operating tube for 100 seconds. But, as a rule, longer exposures are
-necessary. Most radiographs will generally require that the plate be
-"intensified" and a developer used that gives great detail, such as
-metol quinol, etc. At any rate, great care should be exercised in
-developing the plate, as many a good radiograph has been spoiled by
-undue haste.
-
-
-
-
-CHAPTER XIV.
-
-WIRELESS TELEGRAPHY.
-
-
-In Chapter XII. we showed how Dr. Hertz caused electric waves to pass
-through space and become visible by sparks across an air gap in a wire
-ring situated at a distance from the source of energy. The apparatus
-used, and termed an electric resonator, is in principle similar to that
-of the wireless telegraph. The minute sparks instead of idly passing
-across the air gap are made to traverse a "coherer" (to be afterwards
-more fully described). This "coherer" substantially consists of a
-resistance, preferably metal filings placed in series, with a battery
-and relay. Normally, the resistance is so adjusted that the battery
-current is not strong enough to operate the relay. A wire is led from
-one side of this coherer up into the air to intercept the Hertzian
-waves, the other side of the coherer is put to earth, or "grounded."
-When a wave strikes the air wire it sends a current through the coherer
-to ground (as before it sent a spark across the air gap), and this wave
-acts on the filings in its passage through them; in effect, to lower
-their resistance, so that the current is increased through the relay
-circuit and the relay armature is attracted to its magnet. The relay
-makes contact in the usual manner at the platinum points, and in its
-turn causes the local circuit, sounder, bell, or pen register to record
-the wave (or signal). After each wave the filings are in such state
-that to restore them to their former high resistance it is necessary
-to give the coherer a smart tap. This is generally accomplished
-automatically by means of an arm extending from the sounder lever,
-which strikes against the coherer each time the sounder armature is
-moved.
-
- [Illustration: FIG. 74.]
-
-Figures 74 and 75 are diagrams of a simple circuit, Fig. 74 being the
-transmitting apparatus and Fig. 75 the receiving apparatus.
-
-In Fig. 74 _P P_ and _S S_ are the primary and secondary of a Ruhmkorff
-coil, _D_ two brass balls on the discharger, _B_ the battery, _K_ a
-key, in place of the usual contact breaker, which is either absent or
-screwed down; _V_ a wire leading from one arm of the discharger up into
-the air, of a height varying with the results desired; _G_ a ground
-plate in connection with the other discharger arm.
-
-The coil condenser is left out of the diagram for sake of clearness;
-but, of course, is necessary to the operation of the apparatus.
-
-In Fig. 75, _C_ is the coherer, also called the Branly tube, or radio
-conductor; _S_ a telegraph sounder, or electric bell; _R_ a relay;
-_R B_ and _L B_ the relay battery and local battery, respectively;
-_G_ a ground connection; _M_ a resistance, or choke coil, and _V_ a
-vertical wire, as in the transmitter; in fact, in the station set the
-same vertical wire answers for both transmitter and receiver.
-
- [Illustration: FIG. 75.]
-
-The coil to be used may be from two inches of spark upwards, dependent
-upon the distance the signals have to travel. The relay battery may
-be two cells of dry battery, the local battery as much as is desired
-to operate the bell, sounder, or pen register receiving the signals.
-Presuming the apparatus set up and adjusted, and designating the
-transmitter as Station A and the receiver as Station B, the operation
-will be as follows: A pressure and release of key _K_ sends an impulse
-of current through the primary _P_, inducing a current in _S_, which
-manifests itself by a spark between the discharger balls at _D_. An
-electric wave is released, which, starting from _V_, Station A, meets
-in its passage _V_ of Station B. Travelling along this wire to the
-ground, it finds two paths—through _C_ or _R_. As the choke coil deters
-it from passing through the relay, it finds passage through _C_ and so
-to ground.
-
-
-THE COHERER.
-
-Many forms of this apparatus are in use, but as yet no definite design
-can be recommended for specific purposes. The most general mode of
-construction is that of the Branley Coherer, as shown in Fig. 76.
-
- [Illustration: FIG. 76.]
-
-It consists of a glass tube, 2 inches long by ¼ inch inside diameter,
-furnished with well-fitted metal plugs at each end, to which
-connections are made. These plugs can be slid in and out of tube for
-adjustment, the gap between them being loosely filled with fine metal
-filings. The metal used varies, according to the operator's preference,
-the most generally adopted being pure nickel for both plugs and
-filings. Another mode of construction for purely experimental use is
-to merely cork the ends of the tube and pass the wires through these
-corks into the filings, ensuring, however, good contact between wires
-and filings. Marconi's favorite form is a glass tube two inches long
-with silver plugs, each one-quarter inch long, in each end, intervening
-space being partially filled with a mixture of nickel and silver
-filings. These plugs are then adjusted to as close as one-twenty-fifth
-of an inch, and the whole apparatus exhausted of air either by means of
-a leading-in tube or by placing coherer in a vessel from which the air
-can be drawn. As a rule, coherers containing air become less sensitive
-after continued use.
-
-
-CARBON COHERER.
-
-Pointed carbon rods can be inserted in the tube instead of metal,
-and carbon dust substituted for the metal filings; but this form is
-suitable only for special purposes. It is very delicate in its action,
-but somewhat uncertain.
-
-
-COHERER WITHOUT FILINGS.
-
-Were it not for reasons, such as difficulty of decoherence, the metal
-filings might be dispensed with and two rods of metal placed in light
-contact. The construction of the coherer reminds one very much of the
-microphone, a satisfactory coherer having been made out of the old
-"nail microphone," four wire nails being placed crossing one another in
-the battery circuit, in one case acting as a sound transmitter, whence
-the name; in the other as a coherer.
-
-
-ALUMINIUM COHERER.
-
-Aluminium, a metal which has steadily grown into favor, and which is
-now readily obtainable, can be made to serve in the present apparatus
-in place of nickel both as to electrodes and filings. It is advisable,
-however, to use aluminium electrodes of slightly larger diameter than
-those of other metals.
-
-
-STEEL BALL COHERER.
-
-A recent writer has recommended the use of balls of steel, such as are
-used in ball bearings, such, however, not to exceed ⅜ inch diameter.
-Such a coherer would take the form of an upright glass tube, with
-electrodes exerting pressure on a series of four or more steel balls.
-Decoherence here becomes difficult, and mention is but made of it to
-show the variety of forms which this important little article may
-assume.
-
-Coherers are adjusted by advancing or receding the electrodes,
-altering the quantity of the filings, etc. There exists but little
-difficulty in operating coherers; considerable latitude is permissible
-as to adjustment, size, character, etc. There does not seem so much
-difficulty in obtaining sensitiveness as in guarding against external
-electrical disturbances. Wings or vanes of thin sheet metal are
-sometimes attached to the metal ends or electrodes of the coherer for
-purposes of adjustment, their size and capacity being determined by
-experiment. It is best that they present no sharp angles, but be of a
-disc, or spherical, form, the better not to dissipate energy.
-
-
-THE OSCILLATOR.
-
-This is the name given the contrivance at the ends of the discharger,
-_D_ being the point at which the electrical oscillations, or waves, are
-radiated.
-
-
-CLARKE'S OSCILLATOR.
-
-This consists of two brass spheres, generally 3 inches in diameter,
-and mounted on a stand or sometimes on top of the induction coil. The
-distance between the balls is readily adjustable by either attaching
-the balls on the ends of two sliding rods, or causing the balls
-themselves to slide on the rods (Fig. 77).
-
- [Illustration: FIG. 77.]
-
- [Illustration: FIG. 78.]
-
-
-TRIPLE OSCILLATOR.
-
-Here three balls are used, two outside ones connected to the circuit,
-being one-half inch diameter, and the middle one, isolated from all
-connection, of three inches in diameter. This form is best mounted on
-a separate stand, the balls either being on glass or hard rubber legs
-(Fig. 78). Connecting wires from the secondary of the coil must in all
-cases be run with the greatest precautions against crosses, as directed
-in Chapter V.
-
-It is possible to make many different designs in oscillators. Some
-experimenters use the simple Clarke form, others prefer the triple
-balls; yet, again, others vary the sizes and the relative sizes of the
-balls. One form of oscillator prescribes the balls to be immersed in
-oil or vaseline. Such methods all have their adherents. Even the plain
-points of an induction coil discharger will serve for short-distance
-work.
-
-Oscillators are adjusted by altering their proximity to one another,
-and should have care given to keep the spheres bright. It is easy to
-alter capacity of an oscillator by connecting its spheres to other
-insulated spheres.
-
-
-THE COIL.
-
-The coil for wireless telegraphy does not differ from the regular
-Ruhmkorff, except that in place of the contact breaker a signal or
-Morse telegraph key is substituted. Of course, the contact breaker can
-be made to perform the same duty by retracting the adjusting screw out
-of reach of the platinum on spring, and then operating the hammer and
-spring in same manner as key.
-
-
-TRANSLATING DEVICES.
-
-Under this head are included relay sounder, bell, or register, which
-are at receiving set. They do not differ from the regular telegraphic
-apparatus. The sounder may be of the Western Union pattern, wound to
-4 ohms; the relay also Western Union pattern, and wound to 150 or 250
-ohms, as best suits the individual case.
-
-In order to protect the receiver from the action of the transmitter
-belonging to the same set of instruments, particularly when powerful
-waves are generated, it has been found at times necessary to enclose
-the receiver in a metal case. Marconi has patents on such devices,
-particularly on a movable shutter in the case, which opens when the
-transmitter is not in operation. Edouard Branly placed his receiving
-set in a metal case with a vertical slit eight inches by one-tenth of
-an inch.
-
-
-AIR CONDUCTOR.
-
-The vertical wire extending from the coherer up into the air must be
-insulated from all other objects in the best possible manner. A bare
-copper wire of No. 14 B & S gauge can be suspended from porcelain
-insulating knobs, which in turn can be strung from each other by means
-of stout silk cord or even wire. There is a special form of insulator
-used in electric construction work, and known as a circuit breaker,
-which will answer and which is easy of attachment; reference to Fig.
-79 will show manner of using.
-
- [Illustration: FIG. 79.]
-
-Temporary grounds can be made to water pipes, but it is better to use
-regular telephone copper ground-plates sunk deep in moist earth.
-
-At South Foreland, England, a mast has been erected, 150 feet in height
-for transmission across Channel, a distance of nearly thirty miles. At
-Notre Dame University, Illinois, Professor Green used a wire 150 feet
-in length, suspended from top of a high church tower, but was unable
-to transmit much over three miles, owing, presumably, to fact that
-the intervening country was well supplied with overhead wires, which
-probably intercepted the waves.
-
-It has been claimed that earthed or grounded air wires are necessary,
-but balls or similar "capacities" are not of service on the top of the
-wire. A theory has been advanced that the currents do not pass from
-air wire tip to air wire tip, but are conducted by the varying strata
-of the earth. No general confirmation is obtainable, however, and
-the experimental reader will find a wide field for research in this
-direction. Marconi, on the other hand, has accomplished much with zinc
-cylinders under six feet high, _not grounded in any respect_, indeed,
-and he also finds it impossible to assume a proportion between distance
-of effect and height of air wire. The following investigations and
-experiments are of interest in this connection:
-
-At a meeting of the Institution of Electrical Engineers, in December,
-1898, Dr. Oliver Lodge showed that there must be a certain relative
-position between the receiving and transmitting circuits.
-
-He placed on one side of a room a box, containing a battery, bell,
-relay, and coherer properly connected up. On the other side he had
-an induction coil and pair of parallel discharger rods, with a spark
-gap to transmit waves across the room. When the rods of the receiver
-and transmitter were placed parallel to each other the receiving
-bell was operated; when the receiving rods of the transmitter were
-at right angles to those of the receiver the bell either failed to
-work, or weakened very considerably. He also told of an experiment
-made to determine the influence of different methods of grounding the
-apparatus. He found that when the apparatus was connected by a wire
-laid on the ground, there was the required response at the receiving
-station; but when the two stations were situated each side of a lake,
-and the ground wires immersed in the water, the receiving instrument
-failed to work. It seemed to him that the conductivity and power
-absorption of ether wave energy by water was too great to allow of the
-transmission of Hertz waves. This would seem to bear out the results
-obtained by Marconi in dispensing with ground wires.
-
-
-
-
-INDEX.
-
-
- A
-
- Acid, Chromic, 189.
-
- " Sulphuric, 212.
-
- Air pump, Geissler, 142.
-
- " " Simple, 141.
-
- " " Sprengel, 143.
-
- " blast, 76.
-
- " wire, 262.
-
- Amalgamation, 180.
-
- Assembly of coil, 22.
-
- Attraction, Window, 154, 163.
-
- Automobile coil, 40.
-
- Automatic burners, 170.
-
- Automatic burners, Adjustment, 176.
-
-
- B
-
- Ballistic galvanometer, 99.
-
- Barium platino cyanide, 238.
-
- Base for coil, 30.
-
- Bath coil, 61.
-
- Battery, Bichromate, 180.
-
- " Champion, 179.
-
- " Daniell, 191.
-
- " Dun, 187.
-
- " Edison-Lalande, 195.
-
- " Fuller, 184.
-
- " Gas-lighting, 179.
-
- " Gethins, 193.
-
- " Gordon, 194.
-
- " Gravity, 191.
-
- " Grenet, 180.
-
- " Harrison, 219.
-
- " Monarch, 179.
-
- " Morisot, 188.
-
- " Novelty, 182.
-
- " Open circuit, 178.
-
- " Polarization, 179.
-
- " Samson, 179.
-
- " solutions, 185, 188, 189.
-
- " Standard dry, 196.
-
- " Storage, 200.
-
- " Storage, to charge, 208.
-
- " Storage, to make, 101.
-
- " Storage, to seal, 215.
-
- " U. S. storage, 218.
-
- Beeswax, 95.
-
- Brush, Electric, 128.
-
-
- C
-
- Capacity of condenser, 100.
-
- Carbons for battery, 182.
-
- Cements, 97.
-
- Charging condenser, 110.
-
- Chromic acid, 189.
-
- Closed magnetic circuit, 6.
-
- Coherer, Aluminium, 251.
-
- " Branly, 254.
-
- " Carbon, 256.
-
- " Steel ball, 258.
-
- Coil, Failure to work, 49.
-
- " for gas engine, 37.
-
- " general remarks, 42.
-
- " in series, 32.
-
- " Medical, 51.
-
- " Oil immersed, 33.
-
- " Output of, 46.
-
- " Primary, 7.
-
- " Resistance, 40.
-
- " Secondary, 10.
-
- " Table of dimensions, 50.
-
- " Tesla, 35.
-
- " Testing, 44.
-
- " To select, 46.
-
- " Winding, 20.
-
- Condensers, Aluminium, 115.
-
- " Adjustable, 117.
-
- " Charging, 110.
-
- " capacity, 100, 119.
-
- " Discharge of, 225.
-
- " Glass, 101.
-
- " Mica, 108.
-
- " Oil, 116.
-
- " Paper, 105, 107.
-
- " Rolled up, 115.
-
- " Series, 108.
-
- Cone vibrator, 88.
-
- Contact breaker, 26.
-
- " " Adjustable medical, 85.
-
- " " Adjustable cone, 88.
-
- " " Dessauer, 80.
-
- " " Electrolytic, 77.
-
- " " Highspeed, 69.
-
- " " in vacuo, 81.
-
- " " Polechanging, 73.
-
- " " Queen, 83.
-
- " " Queen, large form, 84.
-
- " " Steel ribbon, 80.
-
- Contacts, Care of, 90.
-
- Core, 4.
-
- " Iron filing, 46.
-
- Crookes tube, 241.
-
-
- D
-
- Dessauer contact breaker, 80.
-
- Dielectric, 104.
-
- Discharger, 26.
-
- Dry cell, 196.
-
- Dun cell, 187.
-
-
- E
-
- Eddy currents, 6.
-
- Edison-Lalande cell, 195.
-
- Electric sand, 189.
-
- Electrode, 190.
-
- Electrolyte, 213.
-
- Electrolytic interrupter, 77.
-
- Ends for coil, 25.
-
- Extra current, 3.
-
-
- F
-
- Farad, 100.
-
- Fluoroscope, 239.
-
- Fluorescence, 137.
-
- Foucault currents, 6.
-
- Frauenhofer lines, 135.
-
- Frontispiece, Notes on, 42, 47.
-
-
- G
-
- Galvanometer, 99.
-
- Gas burners, 170.
-
- " engine coil, 39.
-
- " from water, 44.
-
- " lighting, 164.
-
- Gassiot star, 153.
-
- Geissler tube, 159.
-
- Glass, To pierce, 130.
-
- Gordon battery, 194.
-
-
- H
-
- Harrison cell, 219.
-
- Hertz resonator, 226.
-
- Hydrometer, 211.
-
- Hysteresis, 6.
-
-
- I
-
- Induction, 1.
-
- " Self, 8.
-
- Insulations, 97.
-
-
- L
-
- Leyden jars, 99.
-
- Lighting gas, 164.
-
-
- M
-
- Magnetic circuit, Closed, 6.
-
- Medical coils, 51.
-
- " " Care of, 62.
-
- Mercury contact breaker, 71.
-
- Mica condenser, 61.
-
-
- N
-
- Noise of contact breaker, 63.
-
-
- O
-
- Oil, Capacity of, 119.
-
- " Coil immersion, 33.
-
- " for oscillator, 260.
-
- " Linseed, 93.
-
- " Resin, 96.
-
- " Spark through, 95.
-
- Oscillator, 258.
-
- " Clarkes, 259.
-
- " Triple, 259.
-
- Output of coil, 46.
-
-
- P
-
- Paper condenser, 107.
-
- Paraffin, 94.
-
- Phosphorus tube, 239.
-
- Photography, X-Ray, 245.
-
- Pocket coil, 89.
-
- Polarity tests, 45.
-
- Pole, 190.
-
- Polechanging switch, 32.
-
- Polechanging contact breaker, 73.
-
- Primary coil, 7.
-
-
- Q
-
- Queen contact breaker, 83.
-
- " Crookes tube, 241.
-
-
- R
-
- Radiography, 245.
-
- Reel ends, 25.
-
- Resistance coils, 40.
-
- Resonance, Electric, 226.
-
- Resonator, Hertz, 226.
-
- Rheotome, 2.
-
- Roentgen Ray apparatus, 236.
-
- Rotating wheel, 154.
-
-
- S
-
- Series, Coils in, 32.
-
- Selection of coil, 46.
-
- Shellac, 96.
-
- Signs, Battery, 190.
-
- Soda, Bichromate of, 183.
-
- Spark, Electric, 120.
-
- " Choice of, 47.
-
- Spectroscope, 132.
-
- Spectrum, Solar, 132.
-
- Standard dry cell, 196.
-
- Sulphating, 215.
-
- Switch, Polechanging, 32.
-
-
- T
-
- Table of cost, 191.
-
- Tesla coil, 35.
-
- " " disruptive, 36.
-
- Testing polarity, 46.
-
- Transformer, 5.
-
- Tube, Insulating, 9.
-
-
- U
-
- U. S. storage cell, 218.
-
-
- V
-
- Vacuum, Adjusting, 242.
-
- " Choice of, 243.
-
- " Contact breaker, 81.
-
- " To procure, 141.
-
- " pumps, 140.
-
-
- W
-
- Water, Decomposition of, 44.
-
- Wax, 95.
-
- Wehnelt interrupter, 77.
-
- Wheel, Rotating, 154.
-
- Winder, Coil, 16.
-
- Winding coils, 20.
-
- " Secondary, 10, 14.
-
- " Sectional, 11.
-
- Wire for secondary coil, 24.
-
- " " primary coil, 9.
-
- Wires, Air, 262.
-
- Wireless telegraphy, 248.
-
- Wireless telegraphy circuit, 250.
-
-
- X
-
- X-Ray apparatus, 236.
-
- " Remarks, 243.
-
- " photographs, 246.
-
-
-
-
-BIBLIOGRAPHY
-
-
-_GENERAL REFERENCE_
-
- =Electricity, Its Theory, Sources and Applications=, by JOHN T.
- SPRAGUE. 3rd edition.
-
- =Induction Coils and Coil Making=, by F. C. ALLSOP.
-
- =The Construction of Large Induction Coils=, a Workshop Handbook, by
- A. THARE. Illustrated.
-
- =A Manual of Electricity=, by H. M. NOAD, Ph.D. London, 1859.
- (_Scarce._)
-
- =Practical Electrics.=
-
- =Sloane's Electrical Dictionary.=
-
- =Houston's Electrical Dictionary.=
-
- =Electricity and Magnetism=, by PROF. SILVANUS P. THOMPSON.
-
-
-_BATTERIES_
-
- =Small Accumulators and How to Make Them=, by P. MARSHALL.
-
- =Primary Batteries=, by H. S. CARHART.
-
- =Practical Electrics.=
-
- =Electric Batteries, How to Make Them=, by P. MARSHALL.
-
-
-_WIRELESS TELEGRAPHY_
-
- =A History of Wireless Telegraphy=, by J. J. FAHIE.
-
- =Improvements in Magnetic Space Telegraphy, Telegraphing by Magnetic
- Induction, and Aetheric Telegraphy=, by SIR W. H. PREECE, S. EVERSHED,
- and OLIVER LODGE.
-
- =Science Abstracts, Physics and Electrical Engineering.=
-
- =The Model Engineer and Amateur Electrician.=
-
-
-
-
-Queen Instruments
-
-_Induction Coils_ capable of producing thick, heavy sparks from 60"
-to ¼" in length. Made in 15 different styles for either direct or
-alternating currents of any voltage.
-
-_X Ray Tubes_ which have an automatic vacuum regulating device by
-means of which rays of penetrating power can be obtained. Our tubes
-have large, clear bulbs with a great current capacity and sharp
-definition.
-
-_Fluoroscopes_ of Platino Barium Cyanide or Calcium Tungstate with
-removable screens. Permanent and brilliant.
-
-_Accessories_—such as Tube Stands, Independent Vibrators,
-Wehnelt Interrupters, Localization Apparatus, Protecting Screens,
-Radiographic Table, X Ray Plates, Storage Batteries, Motor
-Transformers, Archives of the Roentgen Ray—everything to make X Ray
-Work simple and successful.
-
-Electrical Testing Instruments, Meters, Photometric Apparatus
-
-Queen & Co. (Incorporated)
-
-J. G. GRAY, President
-
- 59 Fifth Avenue
- New York
-
- 1010 Chestnut Street
- Philadelphia, Pa.
-
- ——————————————————————
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-
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- The American Inventor,
- 1302 F. St., N.W., Washington, D.C., U.S.A.
-
- ——————————————————————
-
-The GAS-ENGINE HANDBOOK
-
-By E. W. ROBERTS, M.E.
-
-has established itself as a standard of reference in
-
-GAS ENGINERY.
-
-2,000 Copies sold in one year.
-
-The book contains 234 pages of just the kind of information you have
-been looking for on gas engines. It explains their principles of
-operation their faults and the remedies which apply, how to run them,
-how to design them and how to make a complete test. All rules and
-formulas are simple and easily understood by the average mechanic.
-
-"All the most essential information connected with the gas or gasoline
-engine."—_American Machinist._
-
-"The only practical book of its kind."—_Engineering and Mining Journal._
-
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-
-"Just the kind of information the buyer and the user of a gas engine
-wants and finds most difficult to obtain."—_Mines and Minerals._
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-it."—_The Automobile Review._
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-
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-
-No. 1. Harrison Cell
-
-THE MOST POWERFUL OPEN CIRCUIT CELL MADE.
-
- E. M. F.
- 2.5
- Volts.
-
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- Local
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-
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-
- Capacity
- 40
- Ampere
- Hours.
-
- No
- Creeping
- Salts.
-
-Highly recommended for all kinds of open circuit work such as
-telephones, gas engines, bells, auto gas lighting, and for medical
-outfits. Guaranteed to do all that is claimed for it.
-
- HARRISON BROS. & CO., Incorporated.
- PHILADELPHIA. CHICAGO. NEW YORK.
- J. H. LEHMAN,
- Manager of Electrical Department, 102 Times Building, New York.
-
- ——————————————————————
-
-Mesco Dry Battery
-
- [Illustration: The Battery]
-
-OVER 1,000,000 SOLD ANNUALLY
-
-Can be purchased in all cities and most towns in the United States of
-Electric Supply dealers. Price low as worthless dry batteries. We are
-the largest manufacturers of general electric supplies in this country.
-Catalogue issued yearly.
-
-Manhattan Electrical Supply Co.=====
-
-32 Cortlandt Street, New York
-
- ——————————————————————
-
-TO OUR READERS
-
- _ARE YOU IN THE MARKET FOR_
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-
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-
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-
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-
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-
- [Illustration: A Coil]
-
-MAGNET WINDING OF EVERY DESCRIPTION
-
-C. F. SPLITDORF, 17-27 Vandewater St., New York
-
- ——————————————————————
-
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- Engine Outfit Consisting
- of ...
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- New Standard "Autogas" Dry Battery, $5.00
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- " " Jump Spark Coil, 12.00
-
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-
- " " Double Porcelain Insulated Ignition Plug, 6.00
-
-If you are interested write for descriptive pamphlet.
-
-WILLIAM ROCHE, Inventor and Sole Mfr., 42 VESEY ST., NEW YORK CITY
-
-We also manufacture other good and useful appliances to be operated
-with dry cells.
-
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-Photography. 443 pages, 243 illus., cloth, $2.00.
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-Fifth Series.
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-Walking Sticks, Boat-Building. 440 pages, 373 illus., cloth, $2.00.
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-Cleaning and Scouring
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-A MANUAL FOR
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-DYERS AND LAUNDRESSES
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-And for Domestic Use.
-
-_BY S. CHRISTOPHER._
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-CONTENTS.
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- DRESSES.—Silk, Satin, Irish Poplin and Tabinet, Llama, Alpaca, Printed
- Muslin and Pique, Pique and Colored Muslin.
-
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-Price 20 cents, post-paid.
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- ——————————————————————
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-THEORETICAL AND PRACTICAL
-
-Ammonia Refrigeration
-
-_A Work of Reference for Engineers and others Employed in the
-Management of Ice and Refrigeration Machinery._
-
-By ILTYD I. REDWOOD
-
-CONTENTS
-
-B. T. U. Mechanical Equivalent of a Unit of Heat. Specific Heat.
-Latent Heat. Theory of Refrigeration. Freezing, by Compressed Air.
-Ammonia. Characteristics of Ammonia. The Compressor. Stuffing-Boxes.
-Lubrication. Suction and Discharge Valves. Separator. Condenser-Worm,
-Receiver. Refrigerator or Brine Tank. Size of Pipe and Area of
-Cooling Surface. Charging the Plant with Ammonia. Jacket-Water, for
-Compressor, for Separator. Quantity of Condensing Water Necessary.
-Loss due to Heating of Condensed Ammonia. Cause of Variation in Excess
-Pressure. Use of Condensing Pressure in Determining Loss of Ammonia
-by Leakage. Cooling Directly by Ammonia. Freezing Point of Brine.
-Making Brine. Specific Heat of Brine. Regulation of Brine Temperature.
-Indirect Effect of Condensing Water on Brine Temperature. Directions
-for Determining Refrigerating Efficiency. Equivalent of a Ton of Ice.
-Compressor Measurement of Ammonia Circulated. Loss of Well-Jacketed
-Compressors. Loss in Double-Acting Compressors. Distribution of Mercury
-Wells. Examination of Working Parts. Indicator Diagrams. Ammonia
-Figures—Effectual Displacement. Volume of Gas. Ammonia Circulated per
-Twenty-Four Hours. Refrigerating Efficiency. Brine Figures-Gallons
-Circulated. Pounds Circulated. Degrees Cooled. Total Degrees Extracted.
-Loss due to Heating of Ammonia Gas. Loss due to Heating of Liquid
-Ammonia. Calculation of the Maximum Capacity of a Machine. Preparation
-of Anhydrous Ammonia. Construction of Apparatus, etc., etc.
-
-150 pages, 15 illustrations, cloth, $1.00.
-
- ——————————————————————
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-LUBRICANTS,
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-OILS AND GREASES
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-Treated Theoretically and Giving Practical Information Regarding Their
-
-COMPOSITION, USES AND MANUFACTURE
-
-BY ILTYD I. REDWOOD
-
-CONTENTS
-
- INTRODUCTION.—Lubricants.
-
- THEORETICAL.—Chapter I. Mineral Oils: American and Russian;
- Hydrocarbons. Chapter II. Fatty Oils: Glycerides; Vegetable Oils; Fish
- Oils. Chapter III. Mineral Lubricants: Graphite; Plumbago. Chapter IV.
- Greases: Compounded; "Set" or Axle; "Boiled" or Cup. Chapter V. Tests
- of Oils: Mineral Oils. Fatty Oils.
-
- MANUFACTURE.—Chapter VI. Mineral Oil Lubricants: Compounded Oils;
- Debloomed Oils. Chapter VII. Greases: Compounded Greases; "Set" or
- Axle Greases; Boiled Greases; Engine Greases. Appendix. The Action of
- Oils on Various Metals. Index.
-
- TABLES.—I. Viscosity and Specific Gravity. II. Atomic Weights. III.
- Origin, Tests, Etc., of Oils. IV. Action of Oils on Metals.
-
- LIST OF PLATES.—I.—I. I. Redwood's Improved Set Measuring Apparatus.
- II. Section Grease Kettle. III. Diagram of the Action of Oils on
- Different Kinds of Metals.
-
-8vo, cloth, $1.50.
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- ——————————————————————
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-PRACTICAL HANDBOOK ON
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-Gas Engines
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-With Instructions for Care and Working of the Same.
-
-_BY G. LIECKFELD, C.E._
-
-Translated with permission of the Author by _GEORGE RICHMOND, M.E._
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-WITH A CHAPTER ON OIL ENGINES
-
-CONTENTS
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-Choosing and installing a gas engine. The construction of good gas
-engines. Examination as to workmanship, running, economy. Reliability
-and durability of gas engines. Proper erection of a gas engine.
-Foundation. Arrangement for gas pipes. Rubber bag. Locking devices.
-Exhaust pipes. Air pipes. Setting up gas engines. Brakes and their
-use in ascertaining the power of gas engines. Arrangement of a brake
-test. Distribution of heat in a gas engine. Attendance on gas engines.
-General remarks. Gas engine oil. Cylinder lubricators. Rules as to
-starting and stopping a gas engine. The cleaning of a gas engine.
-General observations and specific examination for defects. The engine
-refuses to work. Non-starting of the engine. Too much pressure on the
-gas. Water in the exhaust pot. Difficulty in starting the engine.
-Irregular running. Loss of power. Weak gas mixtures. Late ignition.
-Cracks in air inlet. Back firing. Knocking and pounding inside of
-engine. Dangers and precautionary measure in handling gas engines.
-Precautions when opening gas valves, removing piston from cylinder,
-examining with light openings of gas engines. Dangers in starting,
-cleaning, putting on belts. Oil Engines. Gas engines with producer
-gas. Gasoline and oil engines. Concluding remarks.
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-Mechanics, Young Engineers and Home Students
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-_BY W. PAGET HIGGS, M.A., D.Sc._
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-FOURTH EDITION
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-CONTENTS
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-Symbols and the signs of operation. The equation and the unknown
-quantity. Positive and negative quantities. Multiplication, involution,
-exponents, negative exponents, roots, and the use of exponents as
-logarithms. Logarithms. Tables of logarithms and proportional parts.
-Transportation of systems of logarithms. Common uses of common
-logarithms. Compound multiplication and the binomial theorem. Division,
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-
- ——————————————————————
-
-THE
-
-FIREMAN'S GUIDE
-
-A Handbook on the Care of Boilers
-
-_BY KARL P. DAHLSTROM, M.E._
-
-CONTENTS OF CHAPTERS
-
-I. Firing and Economy of Fuel.—Precautions before and after
-starting the fire, care of the fire, proper firing, draft, smoke,
-progress of firing, fuel on the grate, cleaning out, cleaning grate
-bars and ash pan, dampers, firing into two or more furnaces, dry fuel,
-loss of heat.
-
-II. Feed and Water Line.—Feeding, the water line, false water line,
-defective feeding apparatus, formation of scale, gauge cocks, glass
-gauge, the float, safety plug, alarm whistle.
-
-III. Low Water and Foaming or Priming.—Precautions when water is
-low, foaming, priming.
-
-IV. Steam Pressure.—Steam gauge, safety valves.
-
-V. Cleaning and Blowing Out.—Cleaning the boiler, to examine the
-state of the boiler, blowing out, refilling the boiler.
-
-VI. General Directions.—How to prevent accidents, repairs, the care
-of the boiler when not in use, testing boilers, trimming and cleaning
-outside. Summary of rules. Index.
-
-8vo, cloth, 50 cents.
-
- ——————————————————————
-
-THE CORLISS ENGINE.
-
-BY JOHN T. HENTHORN.
-
-AND
-
-MANAGEMENT OF THE CORLISS ENGINE.
-
-BY CHARLES D. THURBER.
-
-_Uniform in One Volume. Cloth Cover; Price, $1.00._
-
-Table of Contents.
-
-CHAPTER I.—Introductory and Historical; Steam Jacketing. CHAPTER
-II.—Indicator Cards. CHAPTER III.—Indicator Cards continued; the
-Governor. CHAPTER IV.—Valve Gear and Eccentric; Valve Setting.
-CHAPTER V.—Valve Setting continued, with diagrams of same; Table for
-laps of Steam Valve. CHAPTER VI.—Valve Setting continued. CHAPTER
-VII.—Lubrication with diagrams for same. CHAPTER VIII.—Discussion of
-the Air Pump and its Management. CHAPTER IX.—Care of Main Driving
-Gears; best Lubricator for same. CHAPTER X.—Heating of Mills by Exhaust
-Steam. CHAPTER XI.—Engine Foundations; diagrams and templets for same.
-CHAPTER XII.—Foundations continued; Materials for same, etc.
-
-Third Edition, with an Appendix.
-
- ——————————————————————
-
-HOW TO RUN
-
-Engines and Boilers
-
-Practical Instruction for Young Engineers and Steam Users.
-
-_BY EGBERT POMEROY WATSON_
-
-REVISED AND ENLARGED
-
-Synopsis of Contents
-
-Cleaning the boiler, removing scale, scale preventers, oil in boilers,
-braces and stays, mud drums and feed pipes, boiler fittings, grate
-bars and tubes, bridge walls, the slide valve, throttling engine, the
-piston, testing the slide valve with relation to the ports, defects
-of the slide valve, lap and lead, the pressure on a slide valve, stem
-connections to the valve, valves off their seats, valve stem guides,
-governors, running with the sun, eccentrics and connections, the
-crank pin, brass boxes, bearings on pins, adjustment of bearings, the
-valve and gearing, setting eccentrics, the actual operation, return
-crank motion, pounding, the connections, lining up engines, making
-joints, condensing engines, Torricelli's vacuum, proof of atmospheric
-pressure, pumps, no power in a vacuum, supporting a water column by the
-atmosphere, starting a new plant, the highest qualities demanded.
-
-Water tube boilers, fire tube boilers, why water tube boilers steam
-rapidly, torpedo boat boilers, management of water tube boilers,
-economy and maintenance of water tube boilers.
-
-150 pages, illustrated, 16mo, cloth, $1.00
-
- ——————————————————————
-
-GOOD AMERICAN PRACTICE.
-
-AN
-
-ELEMENTARY TEXT BOOK
-
-ON
-
- S_TEAM_ E_NGINES AND_
- B_OILERS_
-
-By J. H. KINEALY, M.E.
-
-A first class American Book for young Engineers and all those wishing
-to take a higher position.
-
-CONTENTS OF CHAPTERS.
-
-1. Elementary Thermodynamics. 2. Theory of the Steam Engine. 3, Types
-and details of Engines. 4. Admission of Steam by Valve. 5. Valve
-diagrams. 6. Indicator and indicator cards. 7. Compound Engines
-and condensers. 8. Heat and combustion of fuel. 9. Boilers, types,
-fittings, etc. 10. Chimneys. APPENDIX. Care of Boilers, Tables,
-Numerous Problems with answers.
-
-Third edition, (1901), thoroughly revised to date and considerably
-enlarged.
-
-259 pages, 108 illustrations, size 9¼ × 6¼.
-
-Cloth, $2.00‡
-
- ——————————————————————
-
-THE SLIDE VALVE
-
-SIMPLY EXPLAINED
-
-BY W. J. TENNANT, Asso. M.I.M.E.
-
-REVISED AND MUCH ENLARGED
-
-BY J. H. KINEALY, D.E.
-
-CONTENTS OF CHAPTERS:
-
- I. The Simple Slide.
-
- II. The Eccentric a Crank. Special Model to
- Give Quantitative Results.
-
- III. Advance of the Eccentric.
-
- IV. Dead Centre. Order of Cranks. Cushioning
- and Lead.
-
- V. Expansion—Inside and Outside Lap and
- Lead; Advance Affected Thereby.
- Compression.
-
- VI. Double-Ported and Piston Valves.
-
- VII. The Effect of Alterations to Valve and
- Eccentric.
-
- VIII. Note on Link Motions.
-
- IX. Note on Very Early Cut-Off, and on Reversing
- Gears in General.
-
- _88 Pages._ _41 Illustrations._ _12mo, Cloth, $1.00._
-
- ——————————————————————
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-QUICK AND EASY METHODS
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-OF
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-CALCULATING
-
-WITH THE SLIDE RULE
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-A SIMPLE EXPLANATION OF THE THEORY AND USE OF THE SLIDE RULE,
-LOGARITHMS, ETC.
-
-_With numerous examples worked out._
-
-BY R. G. BLAINE, M.E.
-
-A most reliable, practical and valuable work for the engineer.
-
- _144 Pages._ _Illustrated._ _12mo, Cloth, $1.00_
-
- ——————————————————————
-
-_The Design and Construction_
-
-OF
-
-OIL ENGINES
-
-_With full directions for_
-
-Erecting, Testing, Installing, Running and Repairing.
-
-Including descriptions of American and English
-
-KEROSENE OIL ENGINES.
-
-By A. H. GOLDINGHAM, M.E.
-
-_Synopsis of Contents of Chapters_:
-
-1. Introductory, Classification, Vaporizers, Spraying and Ignition
-Devices, etc. 2. Design and Construction, Cylinders, Cranks, Shafts,
-Pistons, Connecting Rods, Fly-Wheels, Air and Exhaust Cams, Valves,
-etc., Bearings, Engine Frames, Valve Mechanisms, Gearing, Oil Supply,
-Different Kinds of Engines, etc. 3. Testing the Engine, Faults and
-Remedies, etc. 4. Cooling Water Tanks, Exhaust Silencers, Starters.
-5. Oil Engine Driving Dynamo, Various Systems. 6. Oil Engine Driving
-Air Compressors. Water Pump, etc. 7. Full Instructions for Running Oil
-Engines. 8. Hints on Repairing. 9. Description of the Various English
-and American Oil Engines.
-
-Fully Illustrated, 12mo. Cloth, $2.00‡
-
- ——————————————————————
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-MECHANIC'S OWN BOOK,
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-A PRACTICAL MANUAL.
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-PRINCIPAL CONTENTS.
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- Mechanical Drawing. (13 pages).
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- Casting and Founding. (31 pages).
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- Forging and Finishing. (56 pages).
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- Soldering. (26 pages).
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- Sheet-Metal Working. (10 pages).
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-702 pages, half extra gilt and 1420 illustrations.
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-ON HEAVY PLATE PAPER
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-
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-It contains 26 pages of alphabets whose modifications are almost
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-
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-
- This little book will be appreciated by draughtsmen who wish to use
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- and useful to any one who has had no practice in lettering, as the
- easy method given for forming the letters will enable a person to
- form the letters correctly, and with a little practice to do so
- quickly.—_American Machinist._
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-Oblong, 8vo, cloth, 50 cents
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- EVERYONE'S GUIDE
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- TO
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- PHOTOGRAPHY
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- CONTAINING
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- INSTRUCTIONS FOR MAKING YOUR OWN APPLIANCES AND
- SIMPLE PRACTICAL DIRECTIONS FOR EVERY BRANCH
- OF PHOTOGRAPHIC WORK.
-
- BY
- E. J. WALL, F.R.P.S.
- Author of _The Dictionary of Photography_, etc., etc.
-
- SECOND EDITION
-
- [Illustration:Colophon]
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- NEW YORK:
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- 12 CORTLANDT STREET.
- 1892
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- SPON & CHAMBERLAIN, 12 Cortlandt St.,
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- ——————————————————————
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-Manual of Instruction in
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-WITH AN APPENDIX ON THE
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-Notes on Alloys and a Chapter on Soft Soldering
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-_BY HARVEY ROWELL_
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-The flame, lamp, charcoal, mats, blow-pipes, wash-bottle, binding wire,
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-to mend steel springs, sweating metals together, retaining work in
-position, making joints, applying heat, preventing the loss of heat,
-effect of sulphur lead and zinc, to preserve precious stones, annealing
-and hardening, burnt iron, to hard solder after soft solder. Tables
-of—specific gravity, tenacity, fusibility, alloys.
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-66 pages, illustrated, cloth, 75 cents.
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- For Soldering Receipts, Cements and Lutes, Pastes, Glues and such
- like, _see_ WORKSHOP RECEIPTS.
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- ——————————————————————
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-SMALL ACCUMULATORS
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-How Made and Used
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-_A Practical Handbook for Students and Young Electricians_
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-_EDITED BY PERCIVAL MARSHALL, A.I.M.E._
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-Contents of Chapters
-
-I.—The Theory of the Accumulator.
-
-II.—How to make a 4-Volt Pocket Accumulator.
-
-III.—How to make a 32-Ampere-Hour Accumulator.
-
-IV.—Types of Small Accumulators.
-
-V.—How to Charge and Use Accumulators.
-
-VI.—Applications of Small Accumulators, Electrical Novelties, etc.
-Useful Receipts. Glossary of Technical Terms.
-
-80 pages, 40 illustrations, 12mo, cloth, 50c.
-
- ——————————————————————
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-THE MAGNETO-TELEPHONE
-
-ITS CONSTRUCTION,
-
-Fitting Up and Adaptability to Every-Day Use
-
-_BY NORMAN HUGHES_
-
-CONTENTS OF CHAPTERS
-
-Some electrical considerations: I.—Introductory. II.—Construction.
-III.—Lines, Indoor Lines. IV.—Signalling Apparatus. V.—Batteries. Open
-Circuit Batteries. Closed Circuit Batteries. VI.—Practical Operations.
-Circuit with Magneto Bells and Lightning Arresters. How to Test the
-Line. Push-Button Magneto Circuit. Two Stations with Battery Bells.
-VII.—Battery Telephone. Battery Telephone Circuit. Three Instruments on
-one Line. VIII.—General remarks. Index.
-
-80 pages, 23 illustrations, 12mo, cloth, $1.00. In paper, 50c.
-
- ——————————————————————
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-EVERYBODY'S BOOK ON ELECTRICITY
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-PRACTICAL ELECTRICS
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-A UNIVERSAL HANDY-BOOK
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-ON
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-EVERYDAY ELECTRICAL MATTERS
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-FIFTH EDITION
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-CONTENTS:
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-_Alarms._—Doors and Windows; Cisterns; Low Water in Boilers; Time
-Signals; Clocks. _Batteries._—Making; Cells; Bichromate; Bunsen;
-Callan's; Copper-oxide; Cruikshank's; Daniel's; Granule carbon;
-Groves; Insulite; Leclanché; Lime Chromate; Silver Chloride; Smee;
-Thermo-electric. _Bells._—Annunciator System; Double System;
-and Telephone; Making; Magnet for; Bobbins or Coils; Trembling;
-Single Stroke; Continuous Ringing. _Connections._ _Carbons._
-_Coils._—Induction; Primary; Secondary; Contact-breakers; Resistance.
-_Intensity_ Coils.—Reel; Primary; Secondary; Core; Contact-breaker;
-Condenser; Pedestal; Commutator; Connections. _Dynamo-electric
-Machines._—Field-Magnets; Pole-pieces; Field-magnet Coils; Armature
-Cores and Coils; Commutator Collectors and Brushes; Relation of size
-to efficiency; Methods of exciting Field-Magnets; Magneto-Dynamos;
-Separately excited Dynamos; Shunt Dynamos; Field-Magnets; Armatures;
-Collectors; Brush Dynamo; Alternate Currents. _Fire Risks._—Wires;
-Lamps; Danger to persons. _Measuring._—Non-Registering Instruments;
-Registering Instruments. _Microphones._ _Motors._ _Phonographs._
-_Photophones._ _Storage._ _Telephones._—Forms; Circuits and Calls;
-Transmitter and Switch; Switch for Simplex; etc., etc.
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-<pre>
-
-The Project Gutenberg EBook of Induction Coils, How to Make, Use, and
-Repair Them., by H. S. Norrie
-
-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/license
-
-
-Title: Induction Coils, How to Make, Use, and Repair Them.
- Including Ruhmkorff, Tesla, and medical coils, Roentgen
- Radiography, etc. etc.
-
-Author: H. S. Norrie
-
-Release Date: February 22, 2017 [EBook #54221]
-
-Language: English
-
-Character set encoding: UTF-8
-
-*** START OF THIS PROJECT GUTENBERG EBOOK INDUCTION COILS ***
-
-
-
-
-Produced by Chris Curnow, Les Galloway and the Online
-Distributed Proofreading Team at http://www.pgdp.net (This
-file was produced from images generously made available
-by The Internet Archive)
-
-
-
-
-
-
-</pre>
-
-<hr class="chap" />
-
-<div class="figcenter">
-<img src="images/i_frontis.jpg" alt="" />
-<div class="caption"><span class="smcap">One of two Ruhmkorff Coils made by Queen &amp; Co. The output with about 650
-Watts of current in the primary was a torrent of sparks 45 inches in length.</span></div>
-</div>
-<div class="chapter"></div>
-
-<h1>INDUCTION COILS<br />
-
-<span class="smaller">How to Make, Use, and Repair Them</span></h1>
-
-<p class="center"><small>INCLUDING</small></p>
-
-<p class="center">RUHMKORFF, TESLA, AND MEDICAL COILS,<br />
-ROENTGEN RADIOGRAPHY, WIRELESS<br />
-TELEGRAPHY, AND PRACTICAL INFORMATION<br />
-ON PRIMARY AND<br />
-SECONDARY BATTERY</p>
-
-<p class="center spaced">
-<small>BY</small><br />
-H. S. NORRIE<br />
-<small>(NORMAN H. SCHNEIDER)</small></p>
-
-<p class="center"><i><small>SECOND EDITION, REVISED AND MUCH ENLARGED</small></i></p>
-
-<div class="figcenter" >
-<img src="images/colophon.jpg" alt="Colophon" />
-</div>
-
-
-<p class="center"><small>NEW YORK:</small><br />
-SPON &amp; CHAMBERLAIN, <span class="smcap"><small>12 Cortlandt St.</small></span></p>
-
-<p class="center"><small>LONDON:</small><br />
-E. &amp; F. N. SPON, Ltd., <span class="smcap"><small>125 Strand</small></span><br />
-
-<small>1901</small></p>
-<div class="chapter"></div>
-
-<p class="center spaced xs">
-Entered, according to Act of Congress, in the year 1896<br />
-Re-entered for Copyright in 1901<br />
-By SPON &amp; CHAMBERLAIN<br />
-in the office of the Librarian of Congress, Washington, D. C.</p>
-
-<p class="center xs">BURR PRINTING HOUSE,<br />
-NEW YORK, N. Y., U. S. A.</p>
-
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="half-title">ERRATA.</p>
-
-
-<p><span class="smcap">Page 55.</span> Should read, "Cords being attached
-to binding posts Nos. 1 and 2 are in circuit
-with the <i>Secondary</i> Coil only. When at
-Nos. 2 and 3 they receive the induced current
-or extra current in the <i>Primary</i>."</p>
-
-<p><span class="smcap">Index.</span> "Tesla coil, descriptive," should
-read "Tesla coil, <i>disruptive</i>."</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_iii">iii</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="PREFACE_TO_THE_SECOND_EDITION">PREFACE TO THE SECOND EDITION.</h2>
-</div>
-
-<p>The great favor with which the first
-edition of this little work has been received
-and the steadily growing interest in its
-subject, together with many valuable improvements
-and researches, may be given
-as the reasons for this new edition.</p>
-
-<p>The book has been thoroughly revised,
-partly rewritten, and considerable new matter,
-with twenty-six new illustrations, added.
-It has been brought up to date as far as electrical
-science has gone.</p>
-
-<p>To detail all that has been done is too
-great a task for a preface; we may briefly
-mention the following new matter:</p>
-
-<p>Coils for gas and automobile engines;
-medical coils, concise directions for operation
-and repairs; new forms of contact
-breakers, including electrolytic and mechani<span class="pagenum" id="Page_iv">iv</span>cal;
-gas-lighting apparatus; primary and
-secondary batteries.</p>
-
-<p>The chapter on X-Ray Apparatus has
-been entirely rewritten, and is thoroughly
-practical; and an entire chapter on Wireless
-Telegraphy has been added. In a book of
-this size it is not feasible to give specific
-directions and full dimensions for the manufacture
-of all the apparatus described.
-Indeed, much of the latter must be adapted
-to the particular purpose for which it is to
-be utilized. Again, the same amount of
-material will not always produce the same
-results. A little closer winding, greater
-pressure applied to the cooling wax of a
-condenser, and the output or capacity of
-either is changed.</p>
-
-<p>Matters purely of design or taste are to
-be governed by the creative faculty of the
-worker; but such general details and rules
-are given as will be sufficient to enable one
-possessing ordinary constructive ability to
-make his own apparatus.</p>
-
-<p>The whole process of coil-making does<span class="pagenum" id="Page_v">v</span>
-not require high mechanical skill, but chiefly
-patience and attention to details; and, perhaps
-best of all, but few tools are needed,
-all of a simple kind.</p>
-
-<p>We beg to acknowledge courtesies received
-from Messrs. Queen &amp; Co., the
-<i>Scientific American</i> for frontispiece and
-Fig. 13, Mr. Goldingham's book on Oil
-Engines for Fig. 12, and others who have
-been of assistance to the author. The best
-American and English practice has been
-adopted; the American standard gauges and
-sizes of wires are used, except where noted.</p>
-
-<p>A list of works, particularly of value to
-the coil worker, will be found following the
-index.</p>
-
-<p class="psig">
-<span class="smcap">H. S. Norrie</span><br />
-(Norman H. Schneider.)</p>
-<p><span class="smcap">April,</span> 1901.</p>
-
-<p><span class="pagenum" id="Page_vi">vi</span></p>
-<p><span class="pagenum" id="Page_vii">vii</span></p>
-<hr class="chap" />
-
-
-
-<div class="chapter">
-<h2 id="CONTENTS">CONTENTS.</h2>
-</div>
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_I">CHAPTER I</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">COIL CONSTRUCTION.</td>
-</tr>
-<tr>
- <td class="tdh">Construction of Ruhmkorff Coils. Sizes of
- Wires. Winding of Primary and Secondary. Assembling. Connecting
- Up. Insulation. Coils in Series. Oil Immersed Coils. "Tesla" Coil.
- Disruptive "Tesla" Coil. Coils for Gas Engines. Spark Coils.
- Resistance Coils. General Remarks on Coils. The Testing of a Coil
- for Polarity. Failure to Work. Medical Coils. Medical Coil with Tube
- Regulation. Medical Coil with Interchangeable Secondaries. Bath
- Coils</td>
- <td class="tdrb">1-64</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_II">CHAPTER II</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">CONTACT BREAKERS.</td>
-</tr>
-
-<tr>
-<td class="tdh">Construction of Contact Breakers. Various Forms of
-Simple Contact Breakers. The Mercury Vibrator. Polechanging
-<span class="pagenum" id="Page_viii">viii</span>
-Vibrator. Wehnelt Interrupter. Dessauer Contact Breaker. Steel Ribbon
-Interrupter. Contact Breakers in Vacuo. Queen Contact Breaker.
-Adjustable Contact Breaker for Medical Coils. The Queen Contact Breaker
-for Large Coils, Adjustable Cone Vibrator. Contacts</td>
- <td class="tdrb">65-91</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_III">CHAPTER III</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">INSULATIONS AND CEMENTS.</td>
-</tr>
-<tr>
-<td class="tdh">Selection of Insulating Materials. Mineral Oil.
-Paraffin Wax. Resin Oils. Beeswax. Shellac Varnishes. Silk. Insulating
-Compounds</td>
- <td class="tdrb">92-98</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_IV">CHAPTER IV</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">CONDENSERS.</td>
-</tr>
-<tr>
- <td class="tdh">Construction of Condensers. Leyden Jar.
-Glass Plate Condenser. Paper Condensers. Series Condenser. Rolled-Up
-Condensers. Adjustable Condensers. Application of Condensers</td>
- <td class="tdrb">99-119</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_V">CHAPTER V</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">EXPERIMENTS.</td>
-</tr>
-<tr>
-<td class="tdh">Luminous Effects Obtained by Means of a Ruhmkorff Coil.
-Materials Used. Spark Experiments. The Luminous Pane. Luminous Designs,
-etc.</td>
- <td class="tdrb">120-130<span class="pagenum" id="Page_ix">ix</span></td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_VI">CHAPTER VI</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">SPECTRUM ANALYSIS.</td>
-</tr>
-<tr>
-<td class="tdh">Color Produced by Burning Different Metals. The
-Spectroscope Shown in Connection with the Coil. The Screen. The Color
-Spaces in the Solar Spectrum. Color Values</td>
- <td class="tdrb">131-139</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_VII">CHAPTER VII</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">CURRENTS IN VACUO.</td>
-</tr>
-<tr>
-<td class="tdh">Different Forms of Mercury Air Pumps. Geissler Tubes.
-Discharges in Vacuo. Characteristic Colors of Different Gases in Tubes,
-etc.</td>
- <td class="tdrb">140-152</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_VIII">CHAPTER VIII</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">ROTATING EFFECTS.</td>
-</tr>
-<tr>
- <td class="tdh">Effects of Discharges in Rotating Tubes. Construction
-of Rotating Wheels. Arrangement of Tubes, etc.</td>
- <td class="tdrb">153-163</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_IX">CHAPTER IX</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">GAS LIGHTING.</td>
-</tr>
-<tr>
-<td class="tdh">The Application of the Ruhmkorff Coil for Lighting Gas.
-Gas Lighting in Series. Gas Lighting in Multiple. Gas Lighting Diagram.
-Jump Spark Burner. Automatic Burners</td>
- <td class="tdrb">164-177<span class="pagenum" id="Page_x">x</span></td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_X">CHAPTER X</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">BATTERIES FOR COILS.</td>
-</tr>
-<tr>
-<td class="tdh">The Selection of Suitable Batteries. Open Circuit
-Cells. Closed Circuit Cells. Description of Cells. Formulæ for
-Solutions for Different Kinds of Batteries. The Grenet Battery. Fuller
-Battery. Gravity Battery. Dun Cell. Gethins Cell. Gordon Battery. New
-Standard. Edison-Lalande Cell. Dry Batteries. Dry Cell Construction,
-etc.</td>
- <td class="tdrb">178-199</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_XI">CHAPTER XI</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">STORAGE OR SECONDARY CELL.</td>
-</tr>
-<tr>
-<td class="tdh">Construction of a Storage Cell. Connecting Up Cells.
-Charging Storage Batteries. Diagram for Charging from Dynamo Using
-a Rheostat. Diagram for Charging, using Lamp instead of Rheostat.
-Charging from. Primary Batteries. Testing Solutions. Setting Up the
-Storage Cell. The Harrison Cell. The "U. S." Storage Cell, etc.</td>
- <td class="tdrb">200-223</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_XII">CHAPTER XII</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">TESLA AND HERTZ EFFECTS.</td>
-</tr>
-<tr>
-<td class="tdh">Currents of High Frequency. Electric Resonator. The
-"Tesla" Effects. Coil Connected to Discharger. High Frequency Currents
-in Electro-Therapeutics, etc.</td>
- <td class="tdrb">224-234<span class="pagenum" id="Page_xi">xi</span></td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_XIII">CHAPTER XIII</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">THE "ROENTGEN" RAYS AND RADIOGRAPHY.</td>
-</tr>
-<tr>
-<td class="tdh">General Arrangement of Connections for Coil and Crookes
-Tube for Making X Ray Negatives. The Fluoroscope. Phosphorus Tube. The
-Queen Self-Adjusting Crookes Tube. General Remarks, etc.</td>
- <td class="tdrb">235-247</td>
-</tr>
-
-<tr>
- <td class="chpl" colspan="2"><a href="#CHAPTER_XIV">CHAPTER XIV</a>.</td>
-</tr>
-<tr>
- <td class="chps" colspan="2">WIRELESS TELEGRAPHY.</td>
-</tr>
-<tr>
-<td class="tdh">Arrangements of Simple Circuits of Coil and Coherer for
-Receiving and Sending Messages. The Coherer. Carbon Coherer. Coherer
-without Filings. Aluminum Coherer. Steel Ball Coherer. The Oscillator.
-Clarke's Oscillator. Triple Oscillator. The Coil. Translating Devices.
-Air Conductor, etc.</td>
- <td class="tdrb">248-265</td>
-</tr>
-
-<tr>
- <td class="tdh"><span class="smcap"><a href="#INDEX">Index</a></span></td>
- <td class="tdrb">266</td>
-</tr>
-
-<tr>
- <td class="tdh"><a href="#BIBLIOGRAPHY">Bibliography</a></td>
- <td class="tdrb">270</td>
-</tr>
-</table></div>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_xii">xii</span><br />
-<span class="pagenum" id="Page_xiii">xiii</span></p>
-
-
-
-
-<div class="chapter">
-<h2>CONTENTS OF TABLES.</h2>
-</div>
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td class="tdh"></td>
- <td class="tdrb"><small>PAGE</small></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Good Proportions of Core Lengths</span></td>
- <td class="tdrb"><a href="#Page_7">7</a></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Table of "Secondary" Windings</span></td>
- <td class="tdrb"><a href="#Page_24">24</a></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Polarity Tests</span></td>
- <td class="tdrb"><a href="#Page_45">45</a></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Dimensions for Different Spark Lengths</span></td>
- <td class="tdrb"><a href="#Page_50">50</a></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Table Showing Resistances and Feet per Pound of Copper and German Silver Wire</span></td>
- <td class="tdrb"><a href="#Page_64">64</a></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Specific Inductive Capacity</span></td>
- <td class="tdrb"><a href="#Page_119">119</a></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Wave Lengths and Temperatures</span></td>
- <td class="tdrb"><a href="#Page_138">138-139</a></td>
-</tr>
-<tr>
- <td class="tdh"><span class="smcap">Table of Relative Costs of Materials</span></td>
- <td class="tdrb"><a href="#Page_191">191</a></td>
-</tr>
-</table></div>
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_xiv">xiv</span></p>
-
-
-
-<div class="chapter">
-<h2>LIST OF ILLUSTRATIONS.</h2>
-</div>
-<p class="center">
-<span class="smcap"><small>Frontispiece, The Queen 45″ Spark Coil.</small></span></p>
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td align="right"><small>FIG</small>.</td>
- <td align="right"><small>PAGE</small></td>
-</tr>
-<tr>
- <td align="right"><a href="#fig1">1</a>.</td>
- <td align="left">Section of Coil</td>
- <td align="right">4</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig2">2</a>.</td>
- <td align="left">Insulating Tube Ends</td>
- <td align="right">10</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig3">3</a>.</td>
- <td align="left">Sectional Winding</td>
- <td align="right">11</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig4">4</a>.</td>
- <td align="left">Section <span class="ditto">"</span> First Method</td>
- <td align="right">12</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig5">5</a>.</td>
- <td align="left"> <span class="ditto">"</span><span class="ditto">"</span> Second Method</td>
- <td align="right">13</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig6">6</a>.</td>
- <td align="left">Proportional Diagram of Coil</td>
- <td align="right">15</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig7">7</a>.</td>
- <td align="left">Section Winder, End View</td>
- <td align="right">17</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig7">8</a>.</td>
- <td align="left"> <span class="ditto">"</span><span class="ditto">"</span> Face View</td>
- <td align="right">17</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig9">9</a>.</td>
- <td align="left">Assembly of Coils</td>
- <td align="right">18</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig10">10</a>.</td>
- <td align="left">Polechanging Switch</td>
- <td align="right">31</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig11">11</a>.</td>
- <td align="left">Disruptive Tesla Coil</td>
- <td align="right">35</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig12">12</a>.</td>
- <td align="left">Spark Coil for Gas Engine</td>
- <td align="right">38</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig13">13</a>.</td>
- <td align="left">Reproduction of a 32-inch Spark</td>
- <td align="right">47</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig14">14</a>.</td>
- <td align="left">Simple Medical Coil</td>
- <td align="right">53</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig15">15</a>.</td>
- <td align="left">Connections for Simple Medical Coil</td>
- <td align="right">55</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig16">16</a>.</td>
- <td align="left">Interchangeable Medical Coil</td>
- <td align="right">56</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig17">17</a>.</td>
- <td align="left">Vibrator for Medical Coil</td>
- <td align="right">60</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig18">18</a>.</td>
- <td align="left">Simple Contact Breaker</td>
- <td align="right">65</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig19">19</a>.</td>
- <td align="left">Imperfect Form of Contact Breaker</td>
- <td align="right">67</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig19">20</a>.</td>
- <td align="left">Superior Form of Contact Breaker</td>
- <td align="right">67</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig21">21</a>.</td>
- <td align="left">Spotteswoode Contact Breaker</td>
- <td align="right">69</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig22">22</a>.</td>
- <td align="left">Polechanging Contact Breaker</td>
- <td align="right">74</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig23">23</a>.</td>
- <td align="left">Wehnelt Interrupter</td>
- <td align="right">78</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig24">24</a>.</td>
- <td align="left">Ribbon Vibrator</td>
- <td align="right">81</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig25">25</a>.</td>
- <td align="left">Queen Contact Breaker</td>
- <td align="right">82<span class="pagenum" id="Page_xv">xv</span></td>
-</tr>
-<tr>
- <td align="right"><a href="#fig26">26</a>.</td>
- <td align="left">Adjustable Contact Breaker</td>
- <td align="right">86</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig27">27</a>.</td>
- <td align="left">Cone Contact Breaker</td>
- <td align="right">88</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig28">28</a>.</td>
- <td align="left">Coil Head Contact Breaker</td>
- <td align="right">89</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig29">29</a>.</td>
- <td align="left">Leyden Jar</td>
- <td align="right">101</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig30">30</a>.</td>
- <td align="left">Plate Condenser</td>
- <td align="right">102</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig31">31</a>.</td>
- <td align="left">Arrangement of Condenser Plates</td>
- <td align="right">104</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig32">32</a>.</td>
- <td align="left">Condenser Charging, First Method</td>
- <td align="right">110</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig33">33</a>.</td>
- <td align="left">Condenser Charging, Second Method</td>
- <td align="right">112</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig34">34</a>.</td>
- <td align="left">Adjustable Condenser</td>
- <td align="right">118</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig35">35</a>.</td>
- <td align="left">Spark between Balls</td>
- <td align="right">125</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig36">36</a>.</td>
- <td align="left">Short Spark between Balls</td>
- <td align="right">125</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig37">37</a>.</td>
- <td align="left">Sparkling Pane</td>
- <td align="right">125</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig38">38</a>.</td>
- <td align="left">Luminous Design</td>
- <td align="right">128</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig39">39</a>.</td>
- <td align="left">Electric Brush</td>
- <td align="right">128</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig40">40</a>.</td>
- <td align="left">Spectrum—Solar</td>
- <td align="right">132</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig41">41</a>.</td>
- <td align="left">Spectroscope and Coil</td>
- <td align="right">133</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig42">42</a>.</td>
- <td align="left">Simple Air Pump</td>
- <td align="right">141</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig43">43</a>.</td>
- <td align="left">Geissler Air Pump</td>
- <td align="right">144</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig43">44</a>.</td>
- <td align="left">Sprengel Air Pump</td>
- <td align="right">144</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig45">45</a>.</td>
- <td align="left">Solution Tube</td>
- <td align="right">150</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig46">46</a>.</td>
- <td align="left">Fluorescent Bulbs</td>
- <td align="right">150</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig47">47</a>.</td>
- <td align="left">Ruby Tube—Crookes</td>
- <td align="right">150</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig48">48</a>.</td>
- <td align="left">Iridio-platinum Tube—Crookes</td>
- <td align="right">151</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig49">49</a>.</td>
- <td align="left">Revolving Wheel</td>
- <td align="right">154</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig50">50</a>.</td>
- <td align="left">Tube Holder</td>
- <td align="right">157</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig50">51</a>.</td>
- <td align="left">Side View of Wheel</td>
- <td align="right">157</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig52">52</a>.</td>
- <td align="left">Geissler Tubes</td>
- <td align="right">160</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig53">53</a>.</td>
- <td align="left">Triangle on Disc</td>
- <td align="right">161</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig54">54</a>.</td>
- <td align="left">Maltese Cross on Disc</td>
- <td align="right">161</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig55">55</a>.</td>
- <td align="left">Gas Lighting Circuit</td>
- <td align="right">165</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig56">56</a>.</td>
- <td align="left">Connections for Gas Burners</td>
- <td align="right">169</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig57">57</a>.</td>
- <td align="left">Bartholdi Automatic Burner</td>
- <td align="right">172<span class="pagenum" id="Page_xvi">xvi</span></td>
-</tr>
-<tr>
- <td align="right"><a href="#fig58">58</a>.</td>
- <td align="left">Connections for Automatic Burner</td>
- <td align="right">174</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig59">59</a>.</td>
- <td align="left">The Grenet Cell</td>
- <td align="right">180</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig60">60</a>.</td>
- <td align="left">The Fuller Cell</td>
- <td align="right">184</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig61">61</a>.</td>
- <td align="left">The Gethins Cell</td>
- <td align="right">193</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig62">62</a>.</td>
- <td align="left">Lead Plate for Storage Cell</td>
- <td align="right">201</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig62">63</a>.</td>
- <td align="left">Wooden Separator</td>
- <td align="right">201</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig64">64</a>.</td>
- <td align="left">Charging with Rheostat</td>
- <td align="right">207</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig65">65</a>.</td>
- <td align="left">Charging with Lamps</td>
- <td align="right">207</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig66">66</a>.</td>
- <td align="left">Harrison Electrodes</td>
- <td align="right">211</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig67">67</a>.</td>
- <td align="left">Hydrometer</td>
- <td align="right">221</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig68">68</a>.</td>
- <td align="left">Hertz Resonator</td>
- <td align="right">227</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig69">69</a>.</td>
- <td align="left">Tesla Circuit</td>
- <td align="right">229</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig70">70</a>.</td>
- <td align="left">Tesla Cut Out</td>
- <td align="right">231</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig71">71</a>.</td>
- <td align="left">Tesla Cut Out, Top Plan</td>
- <td align="right">232</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig72">72</a>.</td>
- <td align="left">Circuit for X Ray Apparatus</td>
- <td align="right">237</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig73">73</a>.</td>
- <td align="left">Queen's Self-Regulating X Ray Tube</td>
- <td align="right">240</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig74">74</a>.</td>
- <td align="left">Transmitter for Wireless Telegraphy</td>
- <td align="right">250</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig75">75</a>.</td>
- <td align="left">Receiver for Wireless Telegraphy</td>
- <td align="right">252</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig76">76</a>.</td>
- <td align="left">The Branley Coherer</td>
- <td align="right">254</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig77">77</a>.</td>
- <td align="left">Clarke's Oscillator</td>
- <td align="right">259</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig77">78</a>.</td>
- <td align="left">Triple Oscillator</td>
- <td align="right">259</td>
-</tr>
-<tr>
- <td align="right"><a href="#fig79">79</a>.</td>
- <td align="left">Air Wire Insulators</td>
- <td align="right">263</td>
-</tr>
-</table></div>
-
-
-
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_1">1</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_I">CHAPTER I.<br />
-
-<small>COIL CONSTRUCTION.</small></h2>
-</div>
-
-<p>In commencing a description of the
-Ruhmkorff coil and its uses, a brief mention
-of the fundamental laws of induction
-directly bearing on its action will assist in
-obtaining an intelligent conception of the
-proper manner in which it should be constructed
-and handled.</p>
-
-<p>Any variation or cessation of a current
-of electricity flowing in one conductor will
-induce a momentary current in an adjacent
-conductor; and if the second conductor
-be an insulated wire coiled around
-the first conductor, also a coil of insulated
-wire, the effect is heightened. The intensity
-of the secondary or induced current
-increases with the number of turns of
-its conductor, the abruptness and com<span class="pagenum" id="Page_2">2</span>pleteness
-of the variation of current in the
-first or primary coil, and the proximity of
-the coils. And the insertion of a mass of
-soft iron within the primary coil by its
-consequent magnetization and demagnetization
-augments still further the inductive
-effect. There are other contributing
-causes which cannot be treated of here,
-but are of not so much importance as the
-foregoing.</p>
-
-<p>In the Ruhmkorff coil, which is an application
-of the above laws, the primary
-coil is of large wire and the secondary coil
-of extremely fine wire, of a length many
-thousand times greater than the wire of
-the primary coil. The current is abruptly
-broken in the primary circuit by a suitable
-device—the contact breaker or rheotome.
-The current induced in the secondary at
-the make of the circuit is in the opposite
-direction to that of the primary coil and
-battery, but the current at the break of
-the circuit is in the same direction as that
-of the primary. The effect of the current<span class="pagenum" id="Page_3">3</span>
-at the break of the circuit is more powerful
-than that at the make, which latter is
-also somewhat neutralized by the opposing
-battery current. A condenser or Leyden
-jar is connected across the contact
-breaker to absorb an <i>extra current</i> induced
-in the primary coil by the break of the circuit,
-which would tend to prolong the magnetization
-of the core beyond the desired
-limit.</p>
-
-<p>The whole apparatus is mounted on a
-wood base, having the condenser in a false
-bottom for the sake of compactness.</p>
-
-<p>It is not herein intended to describe all
-the minor operations in the construction
-of a Ruhmkorff coil. A sufficient description
-and review of the main points to be
-considered, however, will be given to enable
-a person fairly proficient in the use of simple
-tools to construct a serviceable instrument.</p>
-
-<p>The parts and their arrangement in relation
-to one another are shown in Fig. 1,
-but are not drawn strictly to scale, although
-very nearly so.</p>
-
-<p><span class="pagenum" id="Page_4">4</span></p>
-
-<div class="figcenter" > <a id="fig1"></a>
-<img src="images/i_004.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 1.</span></div>
-</div>
-
-<p><i>C</i> is the core, consisting of a bundle of
-soft iron wires as fine as can be obtained.
-The greater the subdivision of the core the
-quicker will it respond to the magnetizing<span class="pagenum" id="Page_5">5</span>
-current in the primary coil, and lose its
-magnetism when the current ceases. It
-has another advantage, in that the disadvantageous
-eddy, or Foucault currents,
-are lessened, which fact, however, is of
-not enough importance to need extended
-consideration.</p>
-
-<p>Many coil-makers saturate the core with
-paraffin or shellac, which is of slight benefit.
-This core is wrapped in an insulating
-layer of paraffined paper or enclosed in a
-rubber shell, there not being any great
-necessity to use more than ordinary insulation
-between the core and the primary
-coil.</p>
-
-<p>In the majority of induction coils or
-"transformers" used in the alternating
-current system of electric lighting, the
-iron cores form a closed magnetic circuit.
-A closed magnetic circuit in a Ruhmkorff
-coil could be obtained by extending the
-iron core at each end and then bending
-and securing the ends together, forming,
-as it were, a ring partly inside and partly<span class="pagenum" id="Page_6">6</span>
-outside the coil. But although the inductive
-effects would be heightened and less
-battery power required, the slowness of
-the circuit to demagnetize would alone be
-detrimental to rapid oscillations of current.</p>
-
-<p>There would also be a loss from a greater
-hysteresis (energy lost in the magnetization
-and demagnetization of iron). A
-core magnetizes quicker than it demagnetizes,
-and the latter is rarely complete;
-a certain amount of residual magnetism
-remains, hysteresis being strictly due to
-this retention of energy (Sprague). Hysteresis
-shows itself in heat, but must not
-be confounded with Foucault or eddy currents.
-The latter are corrected by subdividing
-the metal, but the former depends
-upon the quality of the metal, and increases
-with its length.</p>
-
-<p>Moreover, a coil with a closed magnetic
-circuit requires an independent contact
-breaker.</p>
-
-<p>In most of the alternating currents used
-in lighting their rapidity of alternation is<span class="pagenum" id="Page_7">7</span>
-but one hundred and twenty-five periods
-per second. As in the simple electromagnet,
-the proportions of diameter and
-length of the primary coil and core will
-determine its rapidity of action. A short
-fat coil and core will act much quicker
-than a long thin one. But on a short fat
-coil the outside turns would be too far
-removed from the intensest part of the
-primary field. A good proportion of core
-length is given in the following table:</p>
-
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <th>Spark Length &nbsp;<br />of Coil.</th><th>Iron Core.</th>
-</tr>
-<tr>
- <td>&nbsp; &nbsp;¼</td>
- <td align="left">&nbsp;4″ × ½″</td>
-</tr>
-<tr>
- <td>&nbsp; &nbsp;½</td>
- <td align="left">&nbsp;5″ ×
- <sup>10</sup>∕<sub>16</sub>″</td>
-</tr>
-<tr>
- <td>&nbsp; 1&nbsp;</td>
- <td align="left">&nbsp;7″ × ¾″</td>
-</tr>
-<tr>
- <td>&nbsp; 2&nbsp;</td>
- <td align="left">&nbsp;9″ × 1″</td>
-</tr>
-<tr>
- <td>&nbsp; 6&nbsp;</td>
- <td align="left">12″ × 1⅛″</td>
-</tr>
-<tr>
- <td>12&nbsp;</td>
- <td align="left">19″ × 1½″</td>
-</tr>
-</table></div>
-
-
-<p>The primary coil <i>P</i> consists of two or
-not more than three layers of insulated
-copper wire of large diameter, being required
-to carry a heavy current in a 2-inch
-spark coil, probably from 8 to 10 amperes.
-In designing the primary coil a great ad<span class="pagenum" id="Page_8">8</span>vantage
-arises from using comparatively
-few turns but of large wire. Each turn of
-wire in the primary has a choking effect
-upon its neighbor by what is termed self-induction.</p>
-
-<p>As the primary coil and core may be
-considered as an electro magnet, it may
-not be out of place to notice the rule governing
-such. Magnetization of an iron
-core is mainly dependent upon the ampere
-turns of the coil surrounding it—that is,
-one ampere carried around the core for
-one hundred turns (100 ampere-turns)
-would equal in effect ten amperes flowing
-through ten turns. Practically speaking,
-there would be certain variations to the
-rule, for one difficulty would arise in that
-the smaller wire used in conveying the
-smaller current would fit more compactly
-and allow more turns to be nearer the
-core, the active effect of the turns always
-decreasing with their distance from the
-core. And although a large current and
-few turns would not have so much self<span class="pagenum" id="Page_9">9</span>-induction,
-there would be trouble at the
-contact breaker, owing to the large current
-it would have to control.</p>
-
-<p>The most suitable sizes of wire for the
-primary coil are: No. 16 B. &amp; S. for
-coils up to 1 inch spark; No. 14 B. &amp; S.
-up to 4 inches of spark, and No. 12 B.
-&amp; S. for a 6-inch spark coil. The coil
-should be, say, one-twelfth of the core
-length shorter than the core.</p>
-
-<p><i>I</i> is the insulating tube between the primary
-coil and the secondary coil <i>S</i>. Here
-great precaution is necessary to prevent
-any liability of short circuiting or breaking
-through of sparks from the secondary coil.
-This danger cannot be underestimated,
-and the tube should be either of glass or
-hard rubber, free from flaws, varying in
-thickness with the dimensions of the coil.
-It should extend at least one-tenth of the
-total length of the primary coil beyond it
-at each end. The end of this tube can be
-turned down so as to allow of the hard
-rubber reel ends being slipped on and held<span class="pagenum" id="Page_10">10</span>
-in position by outside hard rubber rings
-(Fig. 2).</p>
-
-<div class="figcenter" ><a id="fig2"></a>
-<img src="images/i_010.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 2.</span></div>
-</div>
-
-<p>The secondary coil consists of many
-turns of fine insulated copper wire separated
-from the primary coil by the insulating
-tube and a liberal amount of insulating
-compound at each end. In coils giving
-under 1 inch of spark this coil may be
-wound in two or more sections.</p>
-
-<div class="figcenter" ><a id="fig3"></a>
-<img src="images/i_011.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 3.</span></div>
-</div>
-
-<p>The usual manner of constructing these<span class="pagenum" id="Page_11">11</span>
-sections is to divide up the space on the
-insulating tube by means of hard rubber
-rings placed at equal distances apart, in
-number according to the number of sections
-desired (Fig. 3). The space between
-each set of rings, or between the coil end
-and a ring, is wound with the wire selected,
-the filled sections constituting a number
-of complete coils, which are finally connected
-in series. The sectional method of
-winding prevents the liability of the spark
-jumping through a short circuit, but<span class="pagenum" id="Page_12">12</span>
-heightens its tendency to pass into the primary
-coil at the ends, where it must be
-therefore specially insulated from it.</p>
-
-<div class="figcenter" ><a id="fig4"></a>
-<img src="images/i_012.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 4.</span></div>
-</div>
-
-<p>In winding these sections there is a
-method now generally adopted which has
-many good points, although at first it may
-seem complicated. The old way of filling
-two sections was to wind both in the same<span class="pagenum" id="Page_13">13</span>
-direction as full as desired, then join the
-outside end of the left-hand coil to the inside
-end of the right-hand coil. This
-necessitated bringing the outside end
-down between two disks, or in a vertical
-hole in the sectional divider, and thereby
-rendered it liable to spark through into its
-own coil. This is shown in Fig. 4, <i>A</i> and
-<i>C</i> inside ends, <i>B</i> and <i>D</i> outside ends, the
-disk being between <i>B</i> and <i>C</i>.</p>
-
-<div class="figcenter" ><a id="fig5"></a>
-<img src="images/i_013.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 5.</span></div>
-</div>
-
-<p><span class="pagenum" id="Page_14">14</span></p>
-
-<p>Reference to Fig. 3 shows the new
-method, and Fig. 5 shows an enlarged
-diagram of sections 2 and 3 of Fig. 3.</p>
-
-<p>Sections 1 and 3, Fig. 3, are filled with
-as many turns as desired; the spool is
-then turned end for end, and sections 2
-and 4 are wound, being thus in the opposite
-direction of winding to sections 1
-and 3.</p>
-
-<p>The inside ends of 1 and 2 and 3 and 4
-are soldered together, and the outside
-ends of 2 and 3 are also soldered together.</p>
-
-<p>The outside ends of 1 and 4 serve as terminals
-for the coil.</p>
-
-<p>This method of connection leaves all the
-turns so joined that the current circulates
-in the same direction through them all, as
-will be seen by an examination of the enlarged
-diagram, Fig. 5.</p>
-
-<p>Sprague, in his "Electricity: Its Theory,
-Sources, and Application," recommends
-that the turns of wire in the secondary
-coil shall gradually increase in
-number until the middle of the spool is<span class="pagenum" id="Page_15">15</span>
-reached, and then decrease to the spool
-end, in order that the greatest number of
-turns be in the strongest part of the magnetic
-field (see Fig. 6). <i>D D D</i> are section
-dividers, <i>S</i> secondary windings, <i>P</i> primary
-coil. The selection of the size of wire to
-be used depends on the requirements as
-to the spark. If a short thick spark be
-desired, use a thick wire, say No. 34 B.
-&amp; S.; if a long thin one, use No. 36 to
-No. 40 B. &amp; S.</p>
-
-
-<div class="figcenter" ><a id="fig6"></a>
-<img src="images/i_015.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 6.</span></div>
-</div>
-
-<p>Although it is impossible to lay down<span class="pagenum" id="Page_16">16</span>
-rules for determining the exact amount of
-wire to be used to obtain a certain sized
-spark, yet a fair average is to allow
-1¼ pounds No. 36 B. &amp; S. per inch spark
-for small coils and slightly less for large
-ones.</p>
-
-<p>The most satisfactory and perhaps the
-easiest way for large coils is to wind the
-secondary in separate coils, made in a
-manner similar to that employed in winding
-coils for the Thompson reflecting galvanometer.
-This method, first described
-by Mr. F. C. Alsop in his treatise on
-"Induction Coils," is somewhat as follows:</p>
-
-
-<p>A special piece of apparatus (Figs. 7 and
-8) is necessary, but presents no great difficulty
-in manufacture. A metal disk, <i>D</i>, one-sixth
-of an inch thick and 7 inches in diameter,
-is mounted on the shaft <i>S</i>. A second
-disk is provided with a collar and set
-screw, <i>A</i>, in order that it may be adjusted
-on the shaft at any desired distance from
-the stationary one. When the diameter<span class="pagenum" id="Page_17">17</span>
-of the coil to be wound has been decided<span class="pagenum" id="Page_18">18</span>
-upon, a wooden collar, <i>W</i>, with a bevelled
-surface is slipped on the shaft, it corresponding
-in diameter with the desired
-diameter of the hole through the centre of
-the secondary coil. As these coils are
-going to be made as flat
-rings and slipped on over
-the insulating tube, a remark
-here becomes necessary
-on this diameter.
-Reference to Fig. 9 will
-show that it is intended
-that the coils near the
-reel ends shall fit very
-loosely on the tube <i>T</i>
-(Fig. 1)—in fact, that
-there shall be a clearance of possibly
-one-half inch in the extreme end, diminishing
-gradually to a fifteenth of an inch in
-the centre coils. Therefore it becomes
-necessary to provide a number of wooden
-rings equal to the desired diameter of the
-central hole in the coil. The thickness of<span class="pagenum" id="Page_19">19</span>
-the wood determining the width of the individual
-coil depends on the selection of
-the operator; but the rule may be laid
-down that the narrower the coils the better
-the insulation of the complete coil will
-be on completion.</p>
-
-<div class="figcenter" ><a id="fig7"></a>
-<img src="images/i_017.jpg" alt="" />
-<div class="caption"><span class="smcap gap10">Fig. 7.</span> <span class="smcap">Fig. 8.</span></div>
-</div>
-
-<div class="figleft" ><a id="fig9"></a>
-<img src="images/i_018.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 9.</span></div>
-</div>
-
-<p>One-sixteenth of an inch is a very fair
-average, and has been generally adopted
-by the writer.</p>
-
-<p>A quantity of paper rings are now cut
-out of stout writing paper which has been
-soaked in melted paraffin. If a block or
-pad of letter paper be soaked in paraffin
-and allowed to become cold under pressure,
-the ring may be scratched on the surface
-of it and the block cut through on a
-jig saw. The central apertures of course
-will vary in size with their position on the
-tube <i>T</i> (Fig. 9).</p>
-
-<p>The coil winder is now either mounted
-in a lathe or fixed in a hand magnet winder
-in such manner that it can be steadily and
-rapidly rotated. The wire to be wound
-comes on spools, which can be so threaded<span class="pagenum" id="Page_20">20</span>
-on a piece of metal rod that they turn
-readily. A metal dish containing melted
-paraffin is provided with a round rod,
-preferably of glass, fixed under the paraffin
-surface, so that it can rotate freely when
-the wire passes under it through the
-paraffin. Two paper rings are slipped on
-the winder that they may form, as it were,
-reel ends for the coil, and if the metal
-disks have been warmed it is an easy matter
-to lay them flat.</p>
-
-<p>The end of the wire is then passed
-through the paraffin under the glass rod
-and through the hole <i>H</i> in the metal disk
-for a distance of, say, 6 inches, and held to
-the disk outside with a dab of paraffin or
-beeswax. Then the winder is rotated
-and the space between the paper disks is
-filled with wire. The paraffin, being hot,
-will adhere to the wire, and cooling as the
-wire lays down on the winder, hold the
-turns together and at the same time insulate
-them from each other. It will not be
-possible to lay the wire in even layers, as<span class="pagenum" id="Page_21">21</span>
-would be necessary in winding a wider
-coil, but the spaces can be filled up, using
-ordinary care that no radical irregularity
-occurs—that is, that only adjacent layers
-are likely to commingle.</p>
-
-<p>When the space is filled up to the level
-of the paper disks and the paraffin is hard,
-loosen the set screw, and removing the
-outside disk, the coil can be slipped off, or
-a slight warming will loosen it. Any
-number of these coils can be made, and
-there are the advantages in this mode of
-construction that a bad coil will not spoil
-the whole secondary, and that the wire
-can be obtained in comparatively small
-quantities.</p>
-
-<p>As each coil will not be of very high resistance,
-the continuity of the wire can be
-readily tested by means of a few cells of
-battery, connecting one end of the coil to
-one pole of the battery, and the other pole
-of the battery and coil end touched to the
-tongue. If a burning sensation is experienced,
-the connection is not broken.<span class="pagenum" id="Page_22">22</span>
-Where possible the coils should be measured
-as to their resistance on a Wheatstone
-bridge.</p>
-
-<p>When the requisite number of coils has
-been prepared, they are assembled in the
-following manner (Fig. 9): The coils, having
-their aperture diameter graded, are
-placed in order, and starting with the one
-having the largest hole, it is slipped over
-the primary protection tube <i>T</i>, one end
-being brought out through a hole in the
-reel end drilled vertically or between the
-reel end and the coil. A couple of paper
-rings are then slipped on the tube, and another
-coil placed over them, having its
-ends connected as in Fig. 3. This process
-is continued until all the coils are in place.
-The annular space between the coils and
-the tube <i>T</i> (Fig. 9) is filled in with melted
-paraffin and the coils gently pressed together,
-so as to form a compact mass,
-paraffin being poured over the outside of
-the whole combination. Before winding
-any wire used in this work it must be per<span class="pagenum" id="Page_23">23</span>fectly
-dry, which end can be accomplished
-by subjecting the whole spool to a short
-period of baking in a moderately warm
-oven.</p>
-
-<p>The accompanying table gives the
-length of No. 36 silk-covered wire that
-will fill a linear space equal to one thickness
-of the wire in different-sized rings.
-This size wire wound tight will give 125
-turns per linear inch. Therefore on a ring
-having a middle aperture of 1½ inches and an
-outside diameter of 4 inches, there will be
-156 turns, or a total length of 1347 inches.
-This is obtained as follows: 1½ inches ×
-3.1416 = 4.7124 (or 4.712); 4 inches ×
-3.1416 = 12.5664 (or 12.56); (4.712 + 12.56)∕2
-= mean circumference—viz., 8.635 inches.</p>
-
-<p>This mean × number of turns in thickness
-of ring between the two circumferences—viz.,
-156 = 1347 inches.</p>
-<p><span class="pagenum" id="Page_24">24</span></p>
-
-<p class="center"><span class="smcap">Table of Secondary Windings.</span></p>
-<div class="center small">
-<table border="1" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <th align="left"><span class="smcap">No. 36 Silk-Covered Wire.
-125 Turns per Linear inch. 13,306 Feet per Pound</span></th>
- <th colspan="3">1½″ Aperture Diameter, 4.712″ Aperture Circumference.</th>
- <th colspan="3">2″ Aperture Diameter, 6.283″ Aperture Circumference.</th>
- <th colspan="3">2½″ Aperture Diameter, 7.854″ Aperture Circumference.</th>
-</tr>
-<tr>
- <td align="left">Outside diameter</td>
- <td align="center">4″</td>
- <td align="center">5″</td>
- <td align="center">6″</td>
- <td align="center">4″</td>
- <td align="center">5″</td>
- <td align="center">6″</td>
- <td align="center">5″</td>
- <td align="center">6″</td>
- <td align="center">7″</td>
-</tr>
-<tr>
- <td align="left">Outside circumference</td>
- <td align="center">12.56</td>
- <td align="center">15.70</td>
- <td align="center">18.84</td>
- <td align="center">12.56</td>
- <td align="center">15.70</td>
- <td align="center">18.84</td>
- <td align="center">15.70</td>
- <td align="center">18.84</td>
- <td align="center">21.99</td>
-</tr>
-<tr>
- <td align="left">Mean circumference</td>
- <td align="center">8.635</td>
- <td align="center">10.20</td>
- <td align="center">11.78</td>
- <td align="center">9.421</td>
- <td align="center">10.99</td>
- <td align="center">12.56</td>
- <td align="center">11.78</td>
- <td align="center">13.35</td>
- <td align="center">14.92</td>
-</tr>
-<tr>
- <td align="left">Turns between circumferences</td>
- <td align="center">156</td>
- <td align="center">219</td>
- <td align="center">282</td>
- <td align="center">125</td>
- <td align="center">188</td>
- <td align="center">250</td>
- <td align="center">156</td>
- <td align="center">219</td>
- <td align="center">282</td>
-</tr>
-<tr>
- <td align="left">Distance between aperture and outside, in inches</td>
- <td align="center">1.25</td>
- <td align="center">1.75</td>
- <td align="center">2.25</td>
- <td align="center">1</td>
- <td align="center">1.50</td>
- <td align="center">2</td>
- <td align="center">1.25</td>
- <td align="center">1.75</td>
- <td align="center">2.25</td>
-</tr>
-<tr>
- <td align="left">Length of wire, in inches</td>
- <td align="center">1347</td>
- <td align="center">2234</td>
- <td align="center">2650</td>
- <td align="center">1178</td>
- <td align="center">2066</td>
- <td align="center">3140</td>
- <td align="center">1838</td>
- <td align="center">2924</td>
- <td align="center">4207</td>
-</tr>
-</table></div>
-<p><span class="pagenum" id="Page_25">25</span></p>
-
-
-<p>To obtain the length of wire necessary
-for a ring occupying more than the space
-of one turn on the primary insulating tube,
-multiply the length before obtained by the
-number of turns in the space it occupies.
-Thus a flat ring one-tenth of an inch thick
-would equal 1347 inches × 12.5.</p>
-
-<p>This rule is necessarily only approximate,
-owing to the way the wires bed on
-each other from their cylindrical section.
-In actual practice, when the wire is run
-through the paraffin bath not more than
-50 per cent of the calculated wire will occupy
-the space. And the thickness of the
-paper rings must also be added when figuring
-the total length of the coil. In the
-iron-clad transformers or induction coils of
-highest efficiency used in the alternating
-current electric light system, the rule for
-determining the windings of the coils is
-based on the ratio of the turns of wire in
-the primary to the turns in the secondary,
-the electromotive force in the primary, and
-the lines of force cut by the windings.</p>
-
-<p>The secondary ends can be attached to
-<span class="pagenum" id="Page_26">26</span>binding posts mounted on the reel ends.
-Unless these reel ends be very high and
-clear the outside of the coil considerably,
-it is better to mount the binding posts on
-the top of the hard rubber pillars. A neat
-plan is to mount on the top of the coil a
-hard rubber plate reaching from reel end
-to reel end, and place the binding posts on
-that.</p>
-
-<p>A discharger consists of two sliding
-metal rods with insulated handles passing
-through pillars attached to the secondary
-coil. The inside ends of these rods is provided
-with screw threads for the ready
-attachment of the balls, points, etc., which
-are to be used. The substance to be acted
-upon is laid on a rubber or glass table
-midway between the rod pillars and
-slightly below the level of the rods.</p>
-
-<p>By hinging the rod pillars, or using a
-ball and socket joint, the discharger can
-be inclined so as to be better brought near
-the substance on the table.</p>
-
-<p>The next important part of the coil is
-<span class="pagenum" id="Page_27">27</span>the contact breaker.</p>
-
-<p>The armature <i>R</i> is a piece of soft iron
-carried at the end of a stiff spring, in about
-the middle of which, at <i>B</i>, is riveted a small
-platinum disk or stud. The adjusting
-screw <i>A</i> has its point also furnished with a
-piece of platinum, which is intended to
-touch the platinum on the spring when the
-latter is in its normal position. The core
-<i>C</i> of the coil serves as an electro-magnet.
-When the current flows from the battery
-(represented by the figure at <i>L</i>) through
-the primary coil and armature spring to
-the adjusting screw, it causes the armature
-to be drawn to the magnetized core, but
-thereby draws the platinum disk away
-from the adjusting screw. In so doing it
-breaks the circuit, the magnet loses its
-power, and the elasticity of the spring reasserting
-itself, carries the armature back,
-thereby reclosing the circuit. This is repeated
-many times in a second, the result
-being a continual vibration of the spring,
-<span class="pagenum" id="Page_28">28</span>and a consequent interruption to the current.</p>
-
-<p>The condenser or Leyden jar <i>J</i>, connected
-as in the diagram to the base of the vibrating
-spring at <i>K</i> and to the adjusting screw
-wire <i>M</i>, is constructed as follows: On a
-sheet of insulated paper is laid a smaller
-sheet of tinfoil, one edge of which projects
-an inch or so over one end of the paper.
-Another sheet of paper covering this carries
-a second sheet of tinfoil, one end of
-which projects as in the first sheet, but at
-the opposite end of the paper. Tinfoil
-and paper sheets are laid in this manner
-alternately until a sufficient number is attained.
-The projecting ends are then
-clamped together and the whole pile immersed
-in melted paraffin, as will be described
-in a subsequent chapter. Wires
-are affixed to these clamped ends which
-serve to connect the condenser with the
-contact breaker. The conventional sign
-for a condenser is that used at <i>J</i>, showing
-the two series of plates, the insulation or
-dielectric, as it is called, being understood.</p>
-
-<p><span class="pagenum" id="Page_29">29</span>The size of condenser to use with different-sized
-coils varies according to the
-winding of the primary and the battery
-used. A primary coil of few turns would
-not necessitate as large a condenser as one
-of a large number of turns. At the same
-time, a condenser may be made of too
-great a capacity, and thereby weaken the
-action of the coil.</p>
-
-<p>The base upon which the coil and its
-parts are mounted may be of dried polished
-wood. But where the coil is designed
-to give large sparks—over 2
-inches—it is an advantage to use hard rubber
-one quarter of an inch and upward in
-thickness. Glass, were it not for the difficulty
-of drilling it and its brittleness,
-would be a desirable material for a coil
-base in a dry atmosphere. Hard red or
-black fibre coated with shellac varnish is
-also serviceable, and, moreover, is extremely
-easy to work. Slate must never
-be used; there is too much liability of iron
-veins being found in it, which in such high
-<span class="pagenum" id="Page_30">30</span>tension experiments as will be described
-would seriously impair the usefulness of
-the apparatus. The material selected for
-the base must be one that will not absorb
-moisture. A paraffined surface collects
-moisture up to a certain point in isolated
-drops, whereas a glass and even a hard
-rubber surface condenses the moisture as
-a film, which latter is extremely undesirable.
-But unfortunately the fact that a
-paraffined surface does not present a
-pleasing appearance would probably result
-in its rejection. And lastly, by
-mounting the coil on hard rubber blocks,
-or extending the reel ends to raise the coil
-body, a high insulation can be obtained at
-the sacrifice perhaps of appearance or
-height. From the care taken to insulate
-the secondary coil, it may be considered a
-superfluous precaution to so carefully select
-a base, but practical work with the
-instrument at some important crisis will
-demonstrate the necessity of extreme care
-in the smallest details relating to insulation.
-<span class="pagenum" id="Page_31">31</span>It may be well to note here that
-hard rubber is acted upon by ozone, and
-is thereby impaired as an insulator.</p>
-
-<div class="figright" ><a id="fig10"></a>
-<img src="images/i_031.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 10.</span></div>
-</div>
-
-<p>The base forms the top of a flat box in
-which the condenser lies; but there are a
-few points worth considering right here.
-As the connections of the coil will probably
-be under the base,
-a sufficient space must
-intervene between the
-base and the top of the
-condenser. It is a good
-plan to lay the condenser
-at least one half inch below
-the top of this box,
-and fill up to, say, one
-eighth of an inch with
-melted paraffin, leaving
-the condenser wires projecting for attachment.
-The connections of the primary
-coil and contact breaker should
-by all means be soldered, not simply
-wires held under screw nuts. And,
-moreover, all wires under the base should
-<span class="pagenum" id="Page_32">32</span>be so run that they do not cross one another,
-which precaution only requires a
-little planning. Then, when the connections
-are all made and the base laid on top
-of the box, it can be pressed down if the
-paraffin be warm, so that the screw heads
-and wires mark out their own channels
-and cavities in which to lie.</p>
-
-<p>A commutator or pole-changing switch
-is often added to change the polarity of
-the battery current. The diagram of connection
-is shown in Fig. 10. When the
-levers are as in the figure, the circuit is
-broken and no current flows through the
-coil.</p>
-
-<h3><span class="smcap">Coils in Series.</span></h3>
-
-<p>Ruhmkorff coils can be connected in
-series, but it is not to be recommended.
-When it becomes necessary, however, the
-cores should be removed, and one long core
-inserted, extending through each primary.
-This will bring the time constants of each
-primary coil together and prevent the interference
-<span class="pagenum" id="Page_33">33</span>otherwise present. The primary
-coils and secondary coils are connected in
-series by assuming that they are but adjacent
-sections of one complete instrument. Of
-course, as the resistance of the primary is
-raised, the electromotive force of the battery
-must be raised also.</p>
-
-<h3><span class="smcap">Oil Immersed Coil.</span></h3>
-
-<p>A highly satisfactory induction coil can
-be made without much labor and few tools,
-and will prove useful in many experiments
-which would not warrant a more expensive
-instrument.</p>
-
-<p>Make a bundle of soft iron wires, No. 22
-B W G, for the core, ten inches in length and
-one inch or more in diameter. Wrap this
-with insulating tape or even ordinary tape
-to prevent the primary coil from coming in
-contact with the iron. Now, wind on a
-primary of two layers No. 14 B &amp; S gauge
-cotton-covered copper wire, and insert the
-coil into a hard rubber (or glass preferred)
-<span class="pagenum" id="Page_34">34</span>tube large enough to hold the coil tight and
-to project an inch or so beyond the core
-ends.</p>
-
-<p>A secondary coil of about one pound
-No. 36 cotton-covered magnet wire should
-now be made on a hard rubber spool, the
-hole through centre of this spool must be
-at least one inch larger in diameter than the
-diameter of the primary cover. This spool
-should not exceed four inches in length, and
-is to be slipped over the primary coil and
-held suspended by blocks of wood in such
-a manner that it does not touch the primary
-coil or cover. The whole outfit is now
-immersed in an earthenware or glass vessel
-filled with linseed or heavy paraffin oil.
-The contact breaker and condenser will be
-mounted independently; the condenser for
-the two-inch spark coil will be suitable (see
-Table on <a href="#Page_7">page—7</a>).</p>
-
-<h3><span class="smcap">"Tesla" Coil.</span></h3>
-
-<p>The coil just described, without contact
-breaker or iron core, can be connected up
-<span class="pagenum" id="Page_35">35</span>and used in place of a "Tesla coil," which
-it resembles. The coils used by Nikola
-Tesla are so many and varied that it becomes
-a difficult task to describe a mode of construction
-which will meet the wants of those
-who ask for "Tesla" coils. The <i>American
-Electrician</i> gives a description of one
-wherein a glass battery jar, 6 inches ×
-8 inches, is wound with 60 to 80 turns of
-No. 18 B &amp; S magnet wire. Into this is
-slipped a primary, consisting of 8 to 10
-turns of No. 6 B &amp; S wire, and the whole
-combination immersed in a vessel containing
-linseed or mineral oil.</p>
-
-<div class="figcenter" ><a id="fig11"></a>
-<img src="images/i_035.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 11.</span></div>
-</div>
-<p><span class="pagenum" id="Page_36">36</span></p>
-
-<h3><span class="smcap">Disruptive "Tesla" Coil.</span></h3>
-
-<p>For Fig. 11 the specification is as follows:
-Secondary, 300 turns of No. 30 B &amp; S silk-covered
-magnet wire, wound on rubber tube
-or rod, and the ends encased in glass or
-rubber tubes. This is inserted <i>into</i> the primary,
-which consists of two coils, each of
-20 turns No. 16 B &amp; S rubber-covered wire,
-wound separately on a long rubber tube not
-less than ⅛ inch thick. The last tube must
-be large enough to be very loose when the
-secondary coil is inserted in it, and it must
-project at least two inches over each end of
-the secondary. A hard rubber division must
-be placed between these primary coils. The
-four ends of the latter coils are connected
-<i>C C</i> to two condensers and <i>D D</i> to two discharger
-balls, the secondary wires going to
-the exhibitive apparatus. A further description
-of these connections is to be found in
-<a href="#CHAPTER_XII">Chapter XII</a>., also notes upon the use of the
-<span class="pagenum" id="Page_37">37</span>disruptive coil.</p>
-
-<p>
-<i>Coils for Gas Engines.</i></p>
-
-<p>These are either primary only or primary
-and secondary. Two to three pounds of
-No. 14 B &amp; S magnet wire are wound on an
-iron wire core eight to ten inches in length
-by one inch in diameter. The contact is
-made and broken in the igniter of the
-engine as at the wipe spring of a ratchet gas
-burner. Four to eight large cells of dry
-battery are used, or eight cells Edison-Lalande—iron-clad
-type. Number of cells
-varies with size of coil needed, some classes
-of engines require a heavier spark than
-others to ignite the vapor.</p>
-
-<p>When a primary and secondary are used,
-the primary should be made of two or three
-layers No. 14 B &amp; S magnet wire, and a
-secondary of one pound No. 34 B &amp; S
-magnet wire. There can be an independent
-contact breaker or the coil can be made up
-similar to a one-half inch spark Ruhmkorff
-coil (see Chapter I.).</p>
-
-<div class="figcenter" ><a id="fig12"></a>
-<img src="images/i_038.jpg" alt="" />
-<div class="caption"> <span class="smcap">Fig. 12.</span></div>
-</div>
-
-<p><span class="pagenum" id="Page_38">38</span>The method of connecting up a coil of the
-latter description is shown in Fig. 12, which
-is self-explanatory. It shows a form of
-cam-shaft switch which is operated by the
-engine, and which opens and closes the primary
-<span class="pagenum" id="Page_39">39</span>circuit of the induction coil, the sparks
-from the secondary winding passing between
-the points of the igniter in the engine
-cylinder. As shown in Fig. 12, the igniter
-or ignition plug is similar in operation to a
-coil discharger, the two terminals being,
-however, insulated from each other by the
-use of porcelain. To ensure a good insulation
-under the severe working conditions
-has been somewhat of a task, but it seems to
-have been attained in the types of igniters
-known as the Splitdorf and the Roche or
-New Standard.</p>
-
-<p>The Splitdorf gas-engine coil is the result
-of much experiment and careful design. It
-is built to stand hard usage, and the insulation
-used has been adopted only after exhaustive
-test. In automobile work, where a
-heavy strain is made upon the engine, as in
-climbing heavy grades, it has been found
-that a stronger spark gives surer results.
-This would indicate more battery current
-through the coil, and it is a wise precaution
-to have a few extra cells attached that can be
-<span class="pagenum" id="Page_40">40</span>switched on if necessary.</p>
-
-<p>In constructing spark coils for gas engines
-particular care must be given to the contact
-breaker. In most types of gas or oil vapor
-engines it is absolutely necessary to have
-the spark pass with uniform regularity, and
-immediately and surely when required. For
-automobiles or where the apparatus is subject
-to jar, a heavy iron vibrating armature
-would become unreliable by reason of its
-inertia and its responding to shock. At
-every jolt of the vehicle it would jar and
-get out of rhythm, and it certainly seems
-preferable to use a mechanical contact apparatus
-whenever feasible. In the older type
-of gas engine the spark is made by mechanism
-breaking contact right in the vapor.
-The actual arrangement of these devices is
-detailed and illustrated in the later works
-on gas and oil engines.</p>
-
-<h3><span class="smcap">Resistance Coils.</span></h3>
-
-<p>Although foreign to the title of this book,
-<span class="pagenum" id="Page_41">41</span>these coils will be mentioned, being often
-necessary as accessories to the operation of
-coils, wireless telegraphy, etc. These are
-coils of insulated German silver wire, wound
-to a specified resistance. The main feature
-about those designed for testing is that they
-are wound non-inductively—that is, the
-wire is wound double in such manner that
-the current flows both ways around the
-turns, and so neutralizes the inductive action.
-In cases where dynamo current is to be
-used, as in telegraphs operated from dynamo
-current, the coils are wound on tin tubes to
-make them fireproof and yet radiate the
-heat. As the resistance of German silver
-varies very largely, only approximate figures
-can be given. The table (<a href="#Page_64">page 64</a>) has
-been made up from the best averages obtainable.
-The carrying capacity of resistance
-coils varies with their construction, the
-better they can radiate heat, the more current
-<span class="pagenum" id="Page_42">42</span>they can safely carry.</p>
-
-<h3><span class="smcap">General Remarks on Coils, etc.</span></h3>
-
-<p>Ruhmkorff induction coils should always
-be fitted with a switch to open, close, or
-reverse the power circuit, a double throw,
-double pole, baby knife switch, mounted on
-a separate porcelain base, is very suitable.
-Such a switch is open when the handle is
-vertical, and it should always be left so when
-changing connections, fixing battery, etc.
-A large, well-finished coil will have the
-secondary wires brought in rubber tubes to
-binding posts mounted on hard rubber pillars,
-or to binding posts mounted considerably
-above the coil cover level. A very neat
-mode is shown in the frontispiece on the
-large 45-inch spark coil. Here the secondary
-wires go to hard rubber pillars, which also
-carry adjustable rod dischargers. These
-rods are movable towards or away from
-each other by means of the large hard rubber
-handle to which they are connected by a
-simple system of levers. In this coil the
-<span class="pagenum" id="Page_43">43</span>secondary is moulded on a flexible tube,
-which fits loosely over the primary tube in
-order to compensate for changes of temperature
-and consequent expansions and contractions.
-All well-designed coils should be
-so arranged that the primary coil and core
-can be readily removed from the secondary,
-or <i>vice versa</i>. It is sometimes desirable to
-use a different primary. This arrangement
-will greatly facilitate any necessary repairs.
-It must be always remembered that the
-working of a coil depends on the insulation
-between primary and secondary. <i>Spare no
-pains to have perfect insulation</i>; it is a
-hopeless task to reinsulate a broken-down
-secondary, although the sectional method
-of winding facilitates repairs. In large
-winding rooms it is customary to have a
-revolution counter connected to the spindle,
-so that the number of turns can be seen at
-all times. A bicycle cyclometer can be
-readily fitted up for this purpose, and will
-be found of considerable assistance where
-a number of sections are needed, each with
-<span class="pagenum" id="Page_44">44</span>a similar number of turns. In the commercial
-construction of telephone coils and
-magnet spools it is often the rule to specify
-only the number of turns of the requisite
-size wire, the ampere turns of the coils being
-thus regulated.</p>
-
-<h3><span class="smcap">The Testing of a Coil for Polarity.</span></h3>
-
-<p>This is often necessary, and may be done
-in a variety of ways. When the coil is working,
-and sparks be passed between fine wires
-mounted on the discharger, the positive wire
-tip will be cold, whereas the negative end
-will be quite hot. In vacuo, the positive
-shows a purple red when the negative glows
-with a bluish violet. The decomposition of
-water, which consists of oxygen and hydrogen
-in the formula H<sub>2</sub>O, is readily accomplished
-by the secondary current, and the
-greatest volume of gas (hydrogen) will be
-evolved at the <i>negative pole</i>. For ready
-reference a summary of these facts is given
-<span class="pagenum" id="Page_45">45</span>below:
-</p>
-
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <th class="thbr">Positive</th>
- <th>Negative</th>
-</tr>
-<tr>
- <td class="tdbr">Cold wire,</td>
- <td align="left">Hot wire,</td>
-</tr>
-<tr>
- <td class="tdbr">Anode,</td>
- <td align="left">Cathode,</td>
-</tr>
-<tr>
- <td class="tdbr">+ sign,</td>
- <td align="left">- sign,</td>
-</tr>
-<tr>
- <td class="tdbr">Purple red,</td>
- <td align="left">Bluish violet,</td>
-</tr>
-<tr>
- <td class="tdbr">Zinc plate,</td>
- <td align="left">Carbon plate,</td>
-</tr>
-<tr>
- <td class="tdbr">(Carbon) pole,</td>
- <td align="left">Zinc pole,</td>
-</tr>
-<tr>
- <td class="tdbr">Oxygen gas.</td>
- <td align="left">Hydrogen gas.</td>
-</tr>
-</table></div>
-
-
-<p>Although it is customary to use bundles
-of fine, soft iron wire for coil cores, very
-excellent results have been obtained with
-cores made up of soft iron filings. These
-filings should be tightly packed in the core
-tube and have a soft iron head at the contact
-breaker end. Filings demagnetize very
-quickly and prevent the formation of destructive
-eddy currents, which have been
-previously discussed (Chapter I.).</p>
-
-<p>Modern practice tends towards a lengthening
-of the core and primary, in some cases
-fully 20 per cent of the core length projects
-from each end of the coil. One result must
-be as in electromagnets, the longer the core,
-the longer it takes to magnetize or demag<span class="pagenum" id="Page_46">46</span>netize.
-But even here it is a matter of
-individual construction.</p>
-
-<p>The common practice is to make coils to
-be in a horizontal position; there is no reason
-why they cannot be made to stand on end.
-In fact, this position to an extent takes off
-some of the strain on the primary. It is
-mostly a matter of choice or convenience.</p>
-
-<p>As to the possible output of an induction
-coil, it depends upon design and construction;
-but S. P. Thompson gives the following
-law in his work on Electricity and
-Magnetism: The electromotive force generated
-in the secondary circuit is to that
-employed in the primary nearly in the same
-proportion as the relative turns of the two
-coils.<a id="FNanchor_1_1" href="#Footnote_1_1" class="fnanchor">1</a></p>
-
-<div class="footnotes">
-<div class="footnote">
-
-<p><a id="Footnote_1_1" href="#FNanchor_1_1" class="label">1</a>
-We do not attempt to reconcile this quotation with the enormous
-estimates of spark potential.</p></div></div>
-
-<p>In selecting a Ruhmkorff coil, it must be
-remembered that the rating in spark length
-is subject to question. Supposing two similar
-coils be operated, one with a rapid vibrator
-and the other with a slow vibrator,
-other things being equal, the slow vibrator
-will give the greatest spark length. Again,<span class="pagenum" id="Page_47">47</span>
-the appearance of the spark is of vast importance.
-Although two coils might be
-sparking across the same length air-gap, the
-one giving the whitest and thickest continuous
-succession of sparks is the better. Fig.
-13 shows a reproduction from a photograph
-of a spark 32 inches long, generated by the
-coil shown on the frontispiece.</p>
-
-<div class="figcenter" ><a id="fig13"></a>
-<img src="images/i_047.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 13.</span></div>
-</div>
-
-<p>It is easy to take a coil, and by snapping
-the vibrator contacts together a few times a
-spark of thin bluish character will jump<span class="pagenum" id="Page_48">48</span>
-across a gap, of length far exceeding the
-spark gap when vibrator is working at normal
-speed. But this spark only passes at
-irregular intervals, seemingly gathering
-strength for its forced leap. It must not be
-considered in rating the coil.</p>
-
-<p>In winding primary coils it is proposed
-to reduce the self-induction or inductance
-of its adjacent coils by means of similar
-methods used in winding electromagnets.
-The primary winding, instead of being composed
-of a number of turns of one large
-wire, is made up of a multiple winding of
-small wires, aggregating the conductivity
-of the large wire. This materially reduces
-sparking at the contact breaker, and certainly
-allows of a closer bedding of wire
-nearer the core, also giving a greater percentage
-of ampere turns. Another scheme
-which uses the Dessauer contact breaker
-provides two separate primary windings,
-opening one when the other closes. Such
-schemes as these come well within the scope
-of the experimenter, and it is highly possible<span class="pagenum" id="Page_49">49</span>
-that valuable improvements will be made in
-coil design during the coming years.</p>
-
-
-<h3><span class="smcap">Failure to Work.</span></h3>
-
-<p>The following are the commonest causes
-of coils not working to their best limit:
-Contact breaker contacts dirty, burned,
-stuck, too small, not in good parallel relation
-face to face of platinum.</p>
-
-<p>Secondary wires crossed outside coil,
-often happens that the secondary is quietly
-sparking away into or through some object
-touching it, particularly when long wire
-connections are run from secondary to place
-of desired sparking.</p>
-
-<p>Condenser too small, burned out, badly
-insulated (see other pages on this subject).</p>
-
-<p>Battery too small—too high internal
-resistance or wires leading from battery to
-coil too small—for ordinary coil work, distance
-of, perhaps, ten feet, use No. 10 to 12
-B &amp; S flexible lamp cord or solid wire.
-Ruhmkorff coils require plenty of current
-to produce large sparks.</p>
-
-<p><span class="pagenum" id="Page_50">50</span></p>
-
-
-<div class="center small">
-<table border="1" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <th align="center" colspan="6"><span class="smcap">Dimensions for Different Spark Lengths.</span></th>
-</tr>
-<tr>
- <th align="center"> &nbsp;</th>
- <th align="center">½ inch</th><th align="center">1 inch</th>
- <th align="center">2 inches</th><th align="center">6 inches</th>
- <th align="center">12 inches</th>
-</tr>
-<tr>
- <td align="left">Foil sheets</td>
- <td align="center">5½ × 4</td>
- <td align="center">6 × 4</td>
- <td align="center">6 × 6</td>
- <td align="center">10 × 5</td>
- <td align="center">12 × 8</td>
-</tr>
-<tr>
- <td align="left">Number</td>
- <td align="center">40</td>
- <td align="center">40</td>
- <td align="center">60</td>
- <td align="center">60</td>
- <td align="center">60</td>
-</tr>
-<tr>
- <td align="left">Paper sheets</td>
- <td align="center">6½ × 5</td>
- <td align="center">9 × 5</td>
- <td align="center">8½ × 7</td>
- <td align="center">12 × 7</td>
- <td align="center">14 × 10</td>
-</tr>
-<tr>
- <td align="left">Number</td>
- <td align="center">60</td>
- <td align="center">60</td>
- <td align="center">80</td>
- <td align="center">80</td>
- <td align="center">80</td>
-</tr>
-<tr>
- <td align="left">Core length</td>
- <td align="center">5</td>
- <td align="center">7</td>
- <td align="center">9</td>
- <td align="center">12</td>
- <td align="center">19</td>
-</tr>
-<tr>
- <td align="left">Core diameter</td>
- <td align="center">⅝</td>
- <td align="center">¾</td>
- <td align="center">1″</td>
- <td align="center">1⅛</td>
- <td align="center">1½</td>
-</tr>
-<tr>
- <td align="left">Primary size B &amp; S</td>
- <td align="center">16</td>
- <td align="center">14</td>
- <td align="center">14</td>
- <td align="center">12</td>
- <td align="center">10</td>
-</tr>
-<tr>
- <td align="left">Secondary size B &amp; S.</td>
- <td align="center">36</td>
- <td align="center">36</td>
- <td align="center">36</td>
- <td align="center">36</td>
- <td align="center">38</td>
-</tr>
-<tr>
- <td align="left">Core wire size B W G.</td>
- <td align="center">22</td>
- <td align="center">22</td>
- <td align="center">22</td>
- <td align="center">22</td>
- <td align="center">22</td>
-</tr>
-<tr>
- <td align="left">Quantity in pounds<br />of secondary wire</td>
- <td align="center">¾</td>
- <td align="center">1¼</td>
- <td align="center">2½</td>
- <td align="center">7</td>
- <td align="center">12</td>
-</tr>
-<tr>
- <td align="left">Layers of primary</td>
- <td align="center">3</td>
- <td align="center">3</td>
- <td align="center">2</td>
- <td align="center">2</td>
- <td align="center">2</td>
-</tr>
-<tr>
- <td align="left">Area of paper, sq. in.</td>
- <td align="center">2,000</td>
- <td align="center">2,700</td>
- <td align="center">4,800</td>
- <td align="center">6,600</td>
- <td align="center">11,000</td>
-</tr>
-<tr>
- <td align="left">Area of foil, sq. in.</td>
- <td align="center">880</td>
- <td align="center">960</td>
- <td align="center">2,100</td>
- <td align="center">3,000</td>
- <td align="center">5,760</td>
-</tr>
-</table></div>
-
-<p><span class="pagenum" id="Page_51">51</span></p>
-
-<p>As it is not always convenient to procure
-paper and foil in set sizes, the area of
-material needed for condensers is also given.
-The above table is approximate. It represents
-data collected from the best modern
-practice. The gauge above given for copper
-wire is that of Brown &amp; Sharpe, and is
-used throughout these pages.</p>
-
-
-<h3><span class="smcap">Medical Coils.</span></h3>
-
-<p>The main points of difference between
-coils for electrotherapeutics and Ruhmkorff
-coils is that the former are devoid of condensers,
-are rarely insulated to a high degree,
-and are arranged for current strength regulation.
-The modes of regulation are many,
-briefly the principal are: (<i>a</i>) In coils with
-independent circuit breakers, sliding both
-core and primary coil out of the secondary
-together or independently. (<i>b</i>) Moving a
-metal tube over or off the primary coil or
-core or both. Many combinations of these
-methods are practised. Attempts have been
-made to regulate battery current by rheostat,<span class="pagenum" id="Page_52">52</span>
-but it is not feasible, except in large stationary
-outfits. Cheap medical coils are wound
-with bare wire, with layers of thread between
-adjacent turns, or even only bedding
-the wire turns in paraffined paper. It is not
-intended to convey the idea that winding
-bare wire coils is a makeshift; far from it.
-This method is being very generally adopted
-in telephone work. But it requires special
-and delicate machinery, and is unsuited to
-amateur work, where slight differences of
-cost or labor are insignificant. Others for
-specific purposes consist of a primary coil
-only. The best and most complete made
-are so arranged that independent secondary
-coils of different sized wires can be used
-with the one primary, being readily slipped
-on or off as required. There is another
-scheme of regulation, where the coil is
-wound in sections and these sections cut in
-or out by means of a switch, but it is not
-desirable.</p>
-
-<p><span class="pagenum" id="Page_53">53</span></p>
-
-
-<h3><span class="smcap">Medical Coil with Tube Regulation.</span></h3>
-
-<div class="figcenter" ><a id="fig14"></a>
-<img src="images/i_053.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 14.</span></div>
-</div>
-
-<p>Figure 14 shows a coil with tube mode of
-regulation. The core <i>C</i> consists of a piece of
-iron tube, very thin, 4 inches long by ⅜ inch
-diameter, and filled with soft iron wires.
-One end of this core is firmly fixed in the
-left-hand bobbin head. The object of the
-iron tube is to prevent the sliding tube from
-catching in the iron wires, otherwise it can
-be dispensed with. Over this tube is slipped
-a brass tube <i>T</i>, ending in a handle <i>H</i> at the
-right-hand end; this must work easily over
-the core tube. The spool for the primary is
-now made up by fixing the other bobbin head
-on a paper or fibre tube and fastening its<span class="pagenum" id="Page_54">54</span>
-free end to the left-hand bobbin head, or the
-spool can be made in the usual way by
-glueing up two spool ends on a fibre or paper
-tube and securing the iron core firmly in one
-end, allowing room, of course, for the brass
-tube to slide in at the right-hand end. The
-primary winding is three or four layers of
-No. 20 B &amp; S gauge cotton-covered magnet
-wire, the ends being brought out for future
-connection. Over this is now laid a few
-layers of paraffined paper, and ten or twelve
-layers of No. 36 B &amp; S cotton-covered
-magnet wire is wound on for the secondary
-coil.</p>
-
-<p>The contact breaker <i>R</i> is in no way different
-from the simple form described in
-Chapter II. Its construction can be readily
-seen from the figure.</p>
-
-<p>A layer of cloth of the kind used in
-covering electromagnets is laid on over the
-secondary, and the coil is ready to be attached
-to the base. The base is seven inches
-long by three wide, and has little feet at its
-four corners to elevate it from the table and<span class="pagenum" id="Page_55">55</span>
-prevent abrasion of the connections underneath.</p>
-
-<div class="figcenter" ><a id="fig15"></a>
-<img src="images/i_055.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 15.</span></div>
-</div>
-
-<p>The connections are as given in Fig. 15.
-When in operation, the electrode cords
-being attached to binding posts, Nos. 1 and
-2 are in circuit with the secondary coil only.
-When at Nos. 2 and 3 they receive the
-induced current or extra current in the
-primary, caused by the break of the battery
-circuit (see page 3).</p>
-
-
-<p><span class="smcap">Medical Coil with Interchangeable
-Secondaries.</span></p>
-
-<p>This form of coil is the only one for
-practical medical work, and more space will<span class="pagenum" id="Page_56">56</span>
-be given to its construction than to the foregoing,<span class="pagenum" id="Page_57">57</span>
-which is suited only for limited use.</p>
-
-<div class="figcenter" ><a id="fig16"></a>
-<img src="images/i_056.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 16.</span></div>
-</div>
-
-<p>Fig. 16 shows side elevation of coil on
-base. The design can be largely varied, also
-it can be used either for a wall board, a
-cabinet top, or made to be carried in a case
-containing battery, electrodes, etc. <i>S</i> is one
-of the secondary coils, of which at least three
-should be provided. The dimensions are, of
-course, the same—namely, four inches long
-by 3½ inches wide over all. The spool ends
-are furnished with heel pieces, which slide
-under the brass track bar <i>T</i>. This accurately
-centres the coil and prevents it from working
-loose.</p>
-
-
-<h3><span class="smcap">Windings for Secondary.</span></h3>
-
-<p>The following windings for removable or
-interchangeable secondary coils are those
-most in use.</p>
-
-<p>Coil No. 1. 4500 feet (.375 pound)
-No. 36 B &amp; S, approximating 1800 ohms.
-This may be led out in three divisions by
-means of switch on coil head. First divi<span class="pagenum" id="Page_58">58</span>sion,
-4500 feet; second division, 3000 feet;
-third division, 1500 feet.</p>
-
-<p>Coil No. 2. 2400 feet (.6 pound) No. 31
-B &amp; S, about 350 ohms, divided into 2400
-feet, 1500 feet, and 900 feet.</p>
-
-<p>Coil No. 3. 750 feet (1 pound) No. 22
-B &amp; S in one coil, or two divisions of 500
-and 750 feet, respectively; approximate resistance
-of wire, 125 ohms.</p>
-
-<p>Coil No. 4. It may be necessary to obtain
-currents of extremely high tension, in which
-case a coil may be prepared of 5000 feet
-No. 38 B &amp; S, or No. 40 B &amp; S preferably.</p>
-
-<p>The finer the wire, the less current and
-the most sedative effect; the coarser the
-wire, the more current with corresponding
-increased painful action.</p>
-
-<p>The spools, in fact as much of the framework
-as possible, should be made of hard
-rubber, to which a fine finish can be given,
-although mahogany, rosewood, or even
-stained oak can be used. On each side of
-the right-hand spool heads a flat brass spring
-is screwed, making the contact for the sec<span class="pagenum" id="Page_59">59</span>ondary
-wires on brass strips screwed on top
-of the track rods. These secondary connections
-can be made by means of flexible cords
-to binding posts, but the sliding contact is
-preferable. The primary coil <i>P</i> is firmly
-held in the left spool head, and consists of
-a core of No. 22 B W G soft iron wires,
-insulated and wound with three layers of
-No. 20 B &amp; S magnet wire. The outside of
-this coil is neatly enclosed in a hard rubber
-tube to permit of the secondary coils sliding
-freely upon it. It is better, however, for
-the secondary coils not to touch the primary
-tube. The vibrator, or contact breaker,
-should be of the adjustable form shown in
-Fig. 17. The adjusting screw for the contact
-breaker can be mounted in a brass lug
-carried by the spool head.</p>
-
-<p>Connections of this coil are substantially
-the same as those of the first-described
-medical coil. This apparatus is well worthy
-of elaboration; it should be fitted with a
-ribbon vibrator as well as an adjustable
-speed slow vibrator, a switch controlling<span class="pagenum" id="Page_60">60</span>
-either. A great variety of secondary coils
-can be made, those of coarse wire taking
-the place of the current from the contact
-breaker. The vibrators should be operated
-from an independent battery, although in
-the last coil described the magnet may be
-wound with the same size wire as the primary
-and then be in series with it. The
-secondary spools can be made of stained
-hard wood ends fitted on to fibre tube, which
-latter is easily procurable. Particular attention
-should always be paid to the spools and
-heads; if not properly made, they may come
-apart, and a disastrous unravelling of the
-wires ensues.</p>
-
-<div class="figcenter" ><a id="fig17"></a>
-<img src="images/i_060.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 17.</span></div>
-</div>
-
-<p><span class="pagenum" id="Page_61">61</span></p>
-
-
-<h3><span class="smcap">Bath Coils.</span></h3>
-
-<p>A coil much used for electric baths has
-a primary winding only, regulated by the
-sliding in and out of the iron core, which
-necessitates the use of an independent
-vibrator, or else by varying the current
-strength with a rheostat. The general
-directions given before will answer in the
-present case, the only data necessary being
-the size of wire, which should be about six
-to ten layers of No. 20 B &amp; S. The coil
-with movable secondaries here comes into
-service. Strong currents are needed for
-bath work, and any variety of winding can
-be used with this make of coil. There are so
-many descriptions of bath and small medical
-coils in the electrical magazines published
-for amateur workers, that it is hardly necessary
-here to give more than a mention of
-the principal ones.</p>
-
-<p><span class="pagenum" id="Page_62">62</span></p>
-
-
-<h3><span class="smcap">Hints in Caring for Medical Coils.</span></h3>
-
-<p>A few remarks on medical coils and their
-diseases may not be amiss; often a very little
-defect, if remedied in time, will prevent
-costly repairs.</p>
-
-<p>The main care in medical electrical apparatus
-is the battery (see Chapter X. for
-descriptions of coil batteries and their operation).
-Clean, fresh solutions and clean
-contacts are essential. Keep zincs well
-amalgamated, remove wires from binding
-posts, and scrape bright the metal where the
-wires make connection; see no fluid is
-splashed on contacts, clean all contact
-springs periodically. The Edison-Lalande
-battery is probably the best for medical use,
-but even this requires occasional attention
-as to contacts, new zincs, fresh solution, etc.</p>
-
-<p>Poor adjustment at contact breaker, dirty
-or corroded contacts, loose wires, loose
-binding posts, corroded binding posts, are
-often the only trouble in a coil refusing to
-work.</p>
-
-<p><span class="pagenum" id="Page_63">63</span></p>
-
-<p>Flexible cords are fruitful of trouble:
-the tinsel breaks, and there is no circuit; gets
-wet and crosses or causes a leak; cord tips
-get loose and alternately open and close a
-contact; one minute all is well, next minute
-no current can be obtained. Another trouble
-in acid batteries is caused by leaving the
-zincs in the fluid. It is easy to do it in most
-cases, although the ingenuity of the leading
-medical electrical apparatus makers to-day
-is directed to this point. Cleanliness and
-careful inspection of all contacts is well
-repaid; carelessness surely brings its evils.</p>
-
-<p>It is very desirable in medical work to
-eliminate the noise attendant upon the working
-of the coil vibrator. This jarring or
-humming is often in itself a source of irritation
-to a nervous patient. The sound can be
-deadened in various ways, for instance, by
-placing over the vibrator a temporary wood
-cover, lined with felt, resting upon a soft
-rubber gasket; or in any other manner that
-may suggest itself to the operator.</p>
-
-<p><span class="pagenum" id="Page_64">64</span></p>
-
-<p class="center"><span class="smcap">Table Showing Resistances and Feet Per Pound
-of Copper and German Silver Wires.</span></p>
-
-
-
-<div class="center small">
-<table border="1" cellpadding="6" cellspacing="0" summary="">
-<tr><th rowspan="3">Gauge,<br />Browne<br />&amp;<br /> Sharpe.</th>
-<th rowspan="3">Diameter.</th>
-<th rowspan="3">Feet<br />per lb.</th>
-<th><span class="smcap">Copper.</span></th>
-<th><span class="smcap">German<br />Silver.</span></th>
-</tr>
-<tr>
-<th rowspan="2">Ohms<br />per 1,000 ft.</th>
-<th>ONLY<br /> APPROXIMATE</th>
-</tr>
-<tr><th>Ohms<br />per 1,000 ft.</th>
-</tr>
-<tr>
- <td align="right"> 8</td>
- <td align="right">.1285 &nbsp;</td>
- <td align="right">20</td>
- <td align="right">.62881</td>
- <td align="right">11.77</td>
-</tr>
-<tr>
- <td align="right"> 9</td>
- <td align="right">.1144 &nbsp;</td>
- <td align="right">25</td>
- <td align="right">.79281</td>
- <td align="right">11.83</td>
-</tr>
-<tr>
- <td align="right"> 10</td>
- <td align="right">.1019 &nbsp;</td>
- <td align="right">32</td>
- <td align="right">1 &nbsp; &nbsp; &nbsp; &nbsp; &nbsp;</td>
- <td align="right">18.72</td>
-</tr>
-<tr>
- <td align="right"> 11</td>
- <td align="right">.09074</td>
- <td align="right">40</td>
- <td align="right">1.2607&nbsp;</td>
- <td align="right">25.59</td>
-</tr>
-<tr>
- <td align="right"> 12</td>
- <td align="right">.08081</td>
- <td align="right">51</td>
- <td align="right">1.5898&nbsp;</td>
- <td align="right">29.75</td>
-</tr>
-<tr>
- <td align="right"> 13</td>
- <td align="right">.07196</td>
- <td align="right">64</td>
- <td align="right">1.995&nbsp; &nbsp;</td>
- <td align="right">37.51</td>
-</tr>
-<tr>
- <td align="right"> 14</td>
- <td align="right">.06408</td>
- <td align="right">81</td>
- <td align="right">2.504&nbsp; &nbsp;</td>
- <td align="right">47.30</td>
-</tr>
-<tr>
- <td align="right"> 15</td>
- <td align="right">.05707</td>
- <td align="right">102</td>
- <td align="right">3.172&nbsp; &nbsp;</td>
- <td align="right">59.65</td>
-</tr>
-<tr>
- <td align="right"> 16</td>
- <td align="right">.05082</td>
- <td align="right">129</td>
- <td align="right">4.001&nbsp; &nbsp;</td>
- <td align="right">75.22</td>
-</tr>
-<tr>
- <td align="right"> 17</td>
- <td align="right">.04525</td>
- <td align="right">162</td>
- <td align="right">5.04&nbsp; &nbsp; &nbsp;</td>
- <td align="right">94.84</td>
-</tr>
-<tr>
- <td align="right"> 18</td>
- <td align="right">.0403 &nbsp;</td>
- <td align="right">204</td>
- <td align="right">6.36&nbsp; &nbsp; &nbsp;</td>
- <td align="right">119.61</td>
-</tr>
-<tr>
- <td align="right"> 19</td>
- <td align="right">.03539</td>
- <td align="right">264</td>
- <td align="right">8.25&nbsp; &nbsp; &nbsp;</td>
- <td align="right">155.10</td>
-</tr>
-<tr>
- <td align="right"> 20</td>
- <td align="right">.03196</td>
- <td align="right">325</td>
- <td align="right">10.12&nbsp; &nbsp; &nbsp;</td>
- <td align="right">190.18</td>
-</tr>
-<tr>
- <td align="right"> 21</td>
- <td align="right">.02846</td>
- <td align="right">409</td>
- <td align="right">12.76&nbsp; &nbsp; &nbsp;</td>
- <td align="right">239.81</td>
-</tr>
-<tr>
- <td align="right"> 22</td>
- <td align="right">.02535</td>
- <td align="right">517</td>
- <td align="right">16.25&nbsp; &nbsp; &nbsp;</td>
- <td align="right">302.38</td>
-</tr>
-<tr>
- <td align="right"> 23</td>
- <td align="right">.02257</td>
- <td align="right">660</td>
- <td align="right">20.30&nbsp; &nbsp; &nbsp;</td>
- <td align="right">381.33</td>
-</tr>
-<tr>
- <td align="right"> 24</td>
- <td align="right">.0201 &nbsp;</td>
- <td align="right">823</td>
- <td align="right">25.60&nbsp; &nbsp; &nbsp;</td>
- <td align="right">480.83</td>
-</tr>
-<tr>
- <td align="right"> 25</td>
- <td align="right">.0179 &nbsp;</td>
- <td align="right">1039</td>
- <td align="right">32.20&nbsp; &nbsp; &nbsp;</td>
- <td align="right">606.31</td>
-</tr>
-<tr>
- <td align="right"> 26</td>
- <td align="right">.01594</td>
- <td align="right">1310</td>
- <td align="right">40.70&nbsp; &nbsp; &nbsp;</td>
- <td align="right">764.59</td>
-</tr>
-<tr>
- <td align="right"> 27</td>
- <td align="right">.01419</td>
- <td align="right">1650</td>
- <td align="right">51.30&nbsp; &nbsp; &nbsp;</td>
- <td align="right">964.13</td>
-</tr>
-<tr>
- <td align="right"> 28</td>
- <td align="right">.01264</td>
- <td align="right">2082</td>
- <td align="right">64.80&nbsp; &nbsp; &nbsp;</td>
- <td align="right">1215.76</td>
-</tr>
-<tr>
- <td align="right"> 29</td>
- <td align="right">.01126</td>
- <td align="right">2623</td>
- <td align="right">81.60&nbsp; &nbsp; &nbsp;</td>
- <td align="right">1533.06</td>
-</tr>
-<tr>
- <td align="right"> 30</td>
- <td align="right">.01002</td>
- <td align="right">3311</td>
- <td align="left">&nbsp; 103</td>
- <td align="right">1933.03</td>
-</tr>
-<tr>
- <td align="right"> 31</td>
- <td align="right">.00893</td>
- <td align="right">4165</td>
- <td align="left">&nbsp; 130</td>
- <td align="right">2437.23</td>
-</tr>
-<tr>
- <td align="right"> 32</td>
- <td align="right">.00795</td>
- <td align="right">5263</td>
- <td align="left">&nbsp; 164</td>
- <td align="right">3073.77</td>
-</tr>
-<tr>
- <td align="right"> 33</td>
- <td align="right">.00708</td>
- <td align="right">6636</td>
- <td align="left">&nbsp; 206</td>
- <td align="right">3875.61</td>
-</tr>
-<tr>
- <td align="right"> 34</td>
- <td align="right">.0063 &nbsp;</td>
- <td align="right">8381</td>
- <td align="left">&nbsp; 260</td>
- <td align="right">4888.49</td>
-</tr>
-<tr>
- <td align="right"> 35</td>
- <td align="right">.00561</td>
- <td align="right">10560</td>
- <td align="left">&nbsp; 328</td>
- <td align="right">6163.97</td>
-</tr>
-<tr>
- <td align="right"> 36</td>
- <td align="right">.005 &nbsp; &nbsp;</td>
- <td align="right">13306</td>
- <td align="left">&nbsp; 414</td>
- <td align="right">7770.81</td>
-</tr>
-</table></div>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_65">65</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_II">CHAPTER II.<br />
-
-<small>CONTACT BREAKERS.</small></h2>
-</div>
-<div class="figright" ><a id="fig18"></a>
-<img src="images/i_065.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 18.</span></div>
-</div>
-
-<p>The simple form of contact breaker already
-described is useful up to a certain
-point, but it has
-disadvantages.
-Its rate of vibration
-is only variable
-through narrow
-limits, and it
-is not suitable for
-very heavy currents.
-But as it
-stands it has done
-long service, and
-will be used probably
-wherever
-the requirements from it are not exacting.
-The most desirable form of this<span class="pagenum" id="Page_66">66</span>
-simple spring break is shown in Fig.
-18. <i>R</i> is the soft iron armature; <i>S</i>, the
-spring; <i>C</i>, check-nut which holds the adjusting
-screw <i>A</i> from becoming loose; <i>T</i>, a
-second adjusting screw used to tighten
-the spring and so raise its rate of vibration;
-<i>K</i> is the base to which one wire of
-the coil is attached; <i>L</i>, base of adjusting
-device to which battery wire runs at <i>I</i>.
-Where tightening screw T passes through
-the pillar of the adjusting screw, the hole
-therein is bushed with rubber to prevent
-accidental contact. Both <i>A</i> and <i>T</i> are provided
-with insulating heads of rubber or
-ivory. At <i>B</i> are the platinum contacts,
-which should be fully ⅛ inch in diameter.</p>
-
-<p>One serious defect in the action of the
-simple spring vibrator (Fig. 19) is the
-tendency of the spring to vibrate, as it
-were, sinusoidally. This causes an irregularity
-in the rate of the vibrations, which
-affects the discharge of the coil very considerably.
-By far the better plan is to use
-a very short thick spring riveted to an<span class="pagenum" id="Page_67">67</span>
-arm carrying the armature at its end (Fig.
-20). <i>R</i> is the armature, <i>S</i> the piece of
-spring, and <i>K</i> the point of attachment to
-the base. The actual width of the portion
-of the spring which vibrates—the hinge
-portion, it might be called—should not be
-over ⅛ inch.</p>
-
-<div class="figcenter" ><a id="fig19"></a>
-<img src="images/i_067.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 19.</span> <span class="smcap">Fig. 20.</span></div>
-</div>
-
-<p>The rate of motion is high; but an
-erroneous notion has been taken of its
-performance by many persons in the
-knowledge of the writer. The rate of
-vibration is <i>not</i> wholly dependent on the<span class="pagenum" id="Page_68">68</span>
-size, or, rather, smallness of its spring;
-the arm and armature considerably alter
-this, although they are not pliable, by reason
-of their mass and the momentum consequent
-on their mass.</p>
-
-<p>A word here on the size of the armature.
-It should be somewhat larger than
-the face of the electro-magnet core, and
-should be thick—that is, in a circular
-form—say one half its diameter. Of
-course this does not apply to the steel
-lever armature before mentioned. It is
-impossible to lay down arbitrary rules
-where the conditions are not determined,
-but a very small amount of experimenting
-will demonstrate the correct lines on
-which to build.</p>
-
-<p>When in action, all rapid rheotomes
-give out a definite musical note whereby
-the rate of vibration can be determined.
-Reference to any work on acoustics will
-show a table of the number of vibrations
-necessary to produce any stated musical
-note. The foregoing style of rheotome<span class="pagenum" id="Page_69">69</span>
-forms the basis of very nearly all those
-which are in use. The shorter and stouter
-a spring the more rapidly will it vibrate,
-and <i>vice-versa</i>. Carrying out this rule,
-we can manufacture an instrument which
-will give as high as 2500 vibrations per
-second (Fig. 21).</p>
-
-<div class="figcenter" ><a id="fig21"></a>
-<img src="images/i_069.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 21.</span></div>
-</div>
-
-<p>The armature <i>A</i> is a piece of flat hard
-steel bar ¼ × ½ inch, held rigidly on the
-metal support <i>S</i> and just clearing the up<span class="pagenum" id="Page_70">70</span>per
-surfaces of the magnet cores <i>C</i>. The
-adjusting screw <i>P</i> should be provided with
-an arm, <i>B B</i>, whereby the rotation of it can
-be delicately varied. This screw must
-also be firmly held or the high speed of
-the armature will jar it loose. A check-nut
-on each side of the frame carrying it
-should be provided in every case. The
-necessary platinum contact can be hammered
-into a hole drilled before the armature
-is hardened. The proper place for
-this contact is about one fourth of the total
-length of the armature from its support,
-although in the simple contact breaker it can
-be placed at the distance of one third if desired.
-The reason is that the concussion
-of the adjusting screw dampens the free
-vibration, and the amplitude thereof is lessened
-in addition to the counter vibrations
-of the screw disturbing the regular vibrationary
-series.</p>
-
-<p>Owing to the fact that the amplitude of
-the armature vibration is so small, a very
-delicate adjustment is necessary. The ad<span class="pagenum" id="Page_71">71</span>justing
-screw can be placed nearer the
-free end, but for the reasons given it is not
-to be desired. The metal bridge should
-be a solid casting, and the armature
-clamped by more than one screw.</p>
-
-<p>The mercury vibrator, which is applied
-to almost every large coil, is as follows:</p>
-
-<p>A pivoted arm carries on one end a
-soft iron armature, which is attracted by
-the coil core. The other end is provided
-with a platinum point adjustable by a set
-screw. This platinum point dips into a
-mercury cup—a glass cup containing mercury,
-with a thin layer of spirits of turpentine.
-The object of the spirits of turpentine,
-which is a non-conductor, is to help
-choke off the spark which would ensue
-whenever the platinum point was raised
-from the mercury.</p>
-
-<p>A form of contact breaker which will
-admit of great variation of speed, and
-which is adapted to carry large currents,
-is the wheel-break, constructed in the following
-manner:</p>
-
-<p><span class="pagenum" id="Page_72">72</span></p>
-
-<p>A brass or copper disk 3 inches or more
-in diameter and upward of ½ inch thick
-has its periphery divided by a number of
-saw cuts, which divisions are often filled
-in with plugs of hard rubber or fibre.
-This disk is mounted on a shaft, which latter
-is either the shaft of an electro-motor,
-or is provided with a pulley by which it
-can be rapidly rotated. A strip of spring
-copper on each side of the disk presses
-upon the toothed surface, one strip being
-connected to the coil and the other to the
-battery or other current source. It will
-now be seen that when the disk rotates the
-slits or pieces of hard rubber cause the
-break in the circuit through the brushes or
-copper strips, the rapidity of the breaks
-depending upon the rate of rotation of the
-disk, and the number of slits in the wheel.</p>
-
-<p>The slits or rubber pieces should be one-half
-the width of the intervening brass,
-but must be at least one sixteenth of an
-inch in width, especially where a high
-voltage is used in the primary coil.</p>
-
-<p><span class="pagenum" id="Page_73">73</span></p>
-
-<p>The shaft of the machine may serve as
-one point of connection in place of one of
-the copper brushes; but in this event
-either a wide journal must be used, or else
-some conducting substance, as plumbago,
-replace the lubricating oil in the bearings.</p>
-
-
-<h3><span class="smcap">Pole Changing Breaker.</span></h3>
-
-<p>Fig. 22 shows a diagram of a pole
-changing contact breaker which will allow
-of rapid alternations of current. It is operated
-by an electric motor by preference,
-although any motive power can be applied
-to it.</p>
-
-<div class="figcenter" ><a id="fig22"></a>
-<img src="images/i_074.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 22.</span></div>
-</div>
-
-<p><i>W a W b</i> are two brass wheels, the peripheries
-of which are broken by the insertion
-of insulating blocks <i>I I</i>, shown black
-in the sketch. <i>S S</i> are the shafts on which
-the wheels are mounted, the two wheels
-being necessarily insulated from each
-other. 1, 2, 3, 4 are four brushes of copper
-pressing on the rim of the wheel and
-leading in the current from the battery <i>B</i>.<span class="pagenum" id="Page_74">74</span>
-The primary coil is attached to the brass<span class="pagenum" id="Page_75">75</span>
-body of the wheel or to the shafts. When
-the wheel is in the position shown, the coil
-and battery are on an open circuit; but on
-the wheel commencing to revolve, the
-brushes 1 and 2 bear on the brass, and the
-current flows from the positive pole of the
-battery to 2 through the wheel <i>W a</i> to the
-coil <i>P</i>, up through wheel <i>W b</i> and out at
-1 back to the battery. The next position
-of the brushes 1 and 2 will be on the insulations,
-and 3 and 4 will come into action.
-Then the positive current will reach <i>W b</i>
-by means of brush 3, and after traversing
-the primary coil and wheel <i>W a</i>, emerge at
-4 to the battery, thus reversing the current
-through <i>P</i> as many times as there are sets
-of segments, which latter can be multiplied
-according to requirements. The
-main point to be considered after that of
-good connections is that the brushes 1 and
-3 and 2 and 4 do not at any time touch
-any part of the brass wheel at the same
-time, as this would short circuit the bat<span class="pagenum" id="Page_76">76</span>tery.
-This is avoided by making the insulating
-space longer than the brass surface,
-and adjusting the brushes as in the sketch,
-that each pair of them is a fraction further
-apart than the length of the brass tooth.</p>
-
-<p>Accordingly, a wheel may be constructed
-with many segments and rotated at a
-high speed and rapid reversals of current
-produced, the uses of which are manifold.</p>
-
-<p>As will be described in the notes on the
-Tesla effects, an electro-magnet, the poles
-of which are brought near the sparking
-point of the contact breaker, will help wipe
-out the spark, and so assist the suddenness
-of the break.</p>
-
-<p>An extremely successful expedient in
-operating contact breakers is to employ a
-high-pressure air blast directed point blank
-against the contact point. The effect of
-this air blast when the contact is made is
-of course null, but on the platinum surfaces
-becoming separated, the high air
-pressure produced forms a path of extremely
-high resistance, and tends to blow<span class="pagenum" id="Page_77">77</span>
-off the spark as soon as it is generated.
-The stream of air should issue from an insulated
-nozzle of glass or rubber, and should
-not contain moisture.</p>
-
-
-<h3><span class="smcap">Wehnelt Interrupter.</span></h3>
-
-<p>One of the most important inventions in
-coil work is the electrolytic interrupter of
-Wehnelt. Briefly, the apparatus consists of
-a vessel containing a solution of acid, into
-which dip two electrodes connected in series
-with the source of power and the primary of
-the coil. Upon passing a current through
-the combination the fluid becomes agitated
-at the electrodes and a rapid make and break
-of the current ensues (Fig. 23).</p>
-
-<div class="figcenter" ><a id="fig23"></a>
-<img src="images/i_078.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 23.</span></div>
-</div>
-
-<p>It requires considerable electromotive
-force for operation, a minimum of 40 volts
-being desirable. Its rapidity of action varies
-up to and at times exceeding 4000 interruptions
-per second. A Wehnelt interrupter
-can be made as follows: Procure a glass jar
-<i>J</i> holding about one quart or a little less, also<span class="pagenum" id="Page_78">78</span>
-a cover for same <i>C</i>, a piece of sheet lead <i>L</i>
-large enough to fit loosely across the jar and
-yet not touch the bottom, eight inches of
-one-quarter-inch glass tube <i>M</i>, a few inches
-of No. 20 platinum wire <i>P</i>, and two ounces
-of mercury. Heat the end of the glass tube
-in a gas flame, and bend an inch or less at
-a right angle; at the same time seal in the
-platinum wire by means of a blowpipe, so
-that the tip just projects from the bent end<span class="pagenum" id="Page_79">79</span>
-of the tube. This sealing can be accomplished
-readily by one unused to working
-glass, but almost any philosophical instrument
-maker will have it done at small cost.
-Holes being bored through the cover, the
-lead plate and the glass tube are fitted in, the
-platinum point almost touching the lead.
-Adjustment is, however, easy, as the tube,
-being turned, will retract or advance the
-platinum point from or towards the lead
-electrode. Nearly fill the jar with a solution
-composed of one part sulphuric acid to
-eight parts water, and fill up the glass tube
-with mercury. The connections can then
-be made by means of a clamp on the lead
-and a wire dipping into the mercury. Connect
-the lead plate <i>L</i> to one pole of the
-battery or source of energy, and the platinum-mercury
-electrode <i>F</i> to one post of
-primary. The other side of battery and coil
-being closed, the apparatus will begin to
-work. No condenser is needed with this
-interrupter.</p>
-
-<p><span class="pagenum" id="Page_80">80</span></p>
-
-
-<h3><span class="smcap">Dessauer Contact Breaker.</span></h3>
-
-<p>This is a modification of the spring
-hammer-head type, but has a platinum contact
-on both sides of the spring. It thus
-obtains double vibrations, but is liable to
-stick. The elasticity of the spring normally
-prevents the circuit remaining closed on the
-forward movement of the hammer head, but
-this combination requires attention.</p>
-
-
-<h3><span class="smcap">Steel Ribbon Interrupter.</span></h3>
-
-<p>For light currents and rapid vibrations,
-such as are employed in electrotherapy, the
-steel ribbon interrupter is suitable. It consists
-of a steel ribbon <i>V</i> one-half inch wide
-by six or eight inches long and the thickness
-of a stout visiting-card. Near the end is
-riveted a platinum contact. One end of the
-ribbon is held by a brass upright <i>R</i>, to which
-connection is made to circuit; the other end
-is riveted to a threaded rod, which passes
-through a brass pillar, and is held by a<span class="pagenum" id="Page_81">81</span>
-thumb-screw and check nut <i>S</i>. Turning the
-thumb-screw either way tightens or loosens
-the ribbon and so raises or lowers the rate
-of vibration (Fig. 24).</p>
-
-
-<h3><span class="smcap">Contact Breakers in Vacuo.</span></h3>
-
-<p>Contact breakers in vacuo, as applied to
-Ruhmkorff coils, are by no means of recent
-date. Poggendorff made use of such prior
-to 1859, and noted the diminished sparking
-at the contact breaker and increased effect
-in the secondary circuit.</p>
-
-<div class="figcenter" ><a id="fig24"></a>
-<img src="images/i_081.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 24.</span></div>
-</div>
-
-<div class="figcenter" ><a id="fig25"></a>
-<img src="images/i_082.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 25.</span></div>
-</div>
-
-<p>Mr. D. McFarlan Moore, whose experi<span class="pagenum" id="Page_82">82</span>ments
-in vacuum tube lighting have proven
-so interesting, was granted patents upon
-various forms of contact breakers, in which<span class="pagenum" id="Page_83">83</span>
-the chief merit was that the contacts were
-broken in a vacuum. The sparking was
-almost eliminated, and the suddenness of
-the break of contact so accentuated as to
-materially improve the output of an induction
-coil. A perusal of his patents, copies
-of which may be procured through almost
-any bookseller, will prove profitable to the
-coil constructor.</p>
-
-
-<h3><span class="smcap">Queen Contact Breaker.</span></h3>
-
-<p>The most important advantage of this
-arrangement is the abrupt break, owing to
-a collar in the vibrator striking a movable
-contact while at full speed. Reference to
-Fig. 25 will show that the movable platinum
-contact is carried on a small vertical spring
-behind the vibrator spring, and projects
-through a collar on the vibrator spring.
-When the contact is made, the movement of
-the vibrator is not arrested, but continues at
-its full amplitude, thus allowing a long
-"make." The vibrator is kept moving at<span class="pagenum" id="Page_84">84</span>
-a constant amplitude by means of the small
-coil shown in the illustration, which is in
-shunt with the main circuit. In the old
-forms there has always been a liability of
-the platinum contacts sticking (or welding
-together). In the new form, as the break is
-made when the vibrator is in the middle of
-its swing, the sudden blow with the entire
-momentum of the iron hammer head is
-always sufficient to break the platinums
-apart. This form of contact breaker is very
-efficient on electric-light circuits, and operates
-with the utmost regularity.</p>
-
-
-<h3><span class="smcap">The Queen Contact Breaker for Large
-Coils.</span></h3>
-
-<p>This is a device where the actual break
-is made in alcohol between large studs of
-platinum nearly one-quarter inch in diameter.
-The bottom contact can be raised or
-lowered by means of an adjusting screw.
-The top contact is secured into the bottom
-end of a rod passing down a guide tube into<span class="pagenum" id="Page_85">85</span>
-the alcohol to meet the lower contact. By
-means of an electric motor and a cam
-motion, the top contact and plunger are made
-to work up and down in the alcohol, thus
-making and breaking the current flow. One
-of the commendable features of this contact
-breaker is that the platinum studs are caused
-to revolve while in operation, thus presenting
-new faces to each other after each blow.
-The apparatus is not adapted for rapid
-action, but for the handling of heavy currents.</p>
-
-
-<p><span class="smcap">Adjustable Contact Breaker for
-Medical Coils.</span></p>
-
-<p>An adjustable contact breaker for medical
-coils is shown in Fig. 26. <i>M M</i> are the
-magnet coils, <i>A</i> is the armature, carrying
-a platinum contact, which vibrates against
-the adjusting screw <i>P</i>. The armature is
-pivoted at <i>J</i>, but is held at a distance from
-the magnets by the springs <i>S S</i>. The other
-end of the armature carries a ball <i>B</i>, which<span class="pagenum" id="Page_86">86</span>
-can be slid up and down on the rod and set
-at any point by a set-screw. When the ball
-is at the end of the armature rod most
-remote from the magnets, the vibrations are
-slowest; when moved towards the magnets,
-the vibrations become more rapid. Adjustment
-of the two springs <i>S S</i> at <i>R R</i> enables
-the contact breaker to operate on varying
-current strength, and also tends to lessen
-the jerkiness of gravity contact breakers.
-A flat spring, however, can be substituted<span class="pagenum" id="Page_87">87</span>
-for the spiral springs, in which case the pivot
-would be dispensed with and the spring
-riveted, as in the hammer form of vibrator.
-The illustration shows this arranged for
-a wall board, but it can readily be adapted
-for table work.</p>
-
-<div class="figcenter" ><a id="fig26"></a>
-<img src="images/i_086.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 26.</span></div>
-</div>
-
-<h3><span class="smcap">Adjustable Cone Vibrator.</span></h3>
-
-<p>Fig. 27 shows a form of contact breaker
-much used in portable medical coils for slow
-speeds. It consists of a cone of iron <i>H</i>,
-mounted on the vibrator spring, and furnished
-with adjustable contact spring and
-screw <i>A</i>. Its amplitude of vibration is
-limited by the two pins mounted on the
-disc, between which the cone vibrates. The
-disc is turned by hand, thus moving the
-pins, and so varying the travel of the cone <i>H</i>
-to and from the core <i>C</i>. It does not give
-good results from the fact that the rhythmical
-movements are disturbed every time
-the cone strikes against the pins, also at the
-contact spring striking the contact screw.<span class="pagenum" id="Page_88">88</span>
-As we showed before, a really satisfactory
-contact breaker should have a spring, which
-allows of no sinusoidal movement. Where
-a pivoted armature is governed by a spiral
-spring, the result is a series of steady,
-rhythmical shocks, provided the adjustments
-are satisfactory.</p>
-
-<div class="figcenter" ><a id="fig27"></a>
-<img src="images/i_088.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 27.</span></div>
-</div>
-
-
-<h3><span class="smcap">Coil Head Contact Breaker.</span></h3>
-
-<p>Fig. 28 shows the details of a contact
-breaker to be attached to the coil head direct.<span class="pagenum" id="Page_89">89</span>
-It is often used on very small coils, which,
-together with a miniature dry cell, is slipped
-into a pocket case. An important detail in
-small coils is to use a contact breaker of sufficient
-size. Most of them are not large
-enough to stand ordinary usage, the adjusting
-screw is not of sufficient diameter and
-the thread soon strips. There is no reason
-why the adjusting screw, its platinum tip,
-and the pillar or lug which holds it should
-not be solidly built, it would certainly require
-less adjustment. Either single or
-double check-nuts can be fitted to the adjust<span class="pagenum" id="Page_90">90</span>ment
-screws of nearly all the forms of contact
-breakers described.</p>
-
-<div class="figcenter" ><a id="fig28"></a>
-<img src="images/i_089.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 28.</span></div>
-</div>
-
-<h3><span class="smcap">Contacts.</span></h3>
-
-<p>It is absolutely essential that the <i>diameter</i>
-of contacts for all contact breakers should
-be as large as possible and their faces filed
-truly parallel to enable them to easily carry
-all the current required. One of the main
-causes of failure of coil is burning of the
-platinum point and platinum burr, the current
-being then materially reduced. Large
-sparks at point of rupture are often indications
-that the condenser is not working
-properly—perhaps has broken down or is
-not large enough. The contacts will sometimes
-fuse together; at any rate, the excessive
-sparking is an evidence of waste as
-much as in a dynamo generator.</p>
-
-<p>The adjustable method of arranging condensers
-(see Chapter IV.) is here of great
-value, but it is easy to attach more condenser<span class="pagenum" id="Page_91">91</span>
-sections to the contact screw pillar and
-vibrator pillar and notice result. In the construction
-of Ruhmkorff coils it is a good plan
-to make all connections possible on the coil
-base, instead of inside the condenser chamber.
-This is done either by means of rubber-covered
-wires or neat strips of brass, screwed
-down on the base from points of connection,
-and, of course, carefully bent over or well
-insulated from all other leads which they
-have to cross.</p>
-
-<p>The best makers of induction coils construct
-their instruments so that they can be
-readily taken apart with as little detachment
-of connections as possible.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_92">92</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_III">CHAPTER III.<br />
-
-<small>INSULATIONS AND CEMENTS.</small></h2>
-</div>
-
-<p>In selecting an insulating compound for
-apparatus designed to be under the influence
-of high tension currents, a glance at
-some of the peculiarities of such currents
-will not be out of place. Mineral oil is
-used in many of the converters employed
-to transform the high voltage currents on
-the mains of the alternating electric-light
-systems to the comparatively low voltage
-used at the points of consumption. Professor
-Elihu Thomson, in a series of experiments,
-noticed some interesting facts
-in the sparking distances of high potentials
-in oils.</p>
-
-<p>He found that discharges of low frequencies,
-as 125 alternations per second,
-were capable of puncturing mineral oils at<span class="pagenum" id="Page_93">93</span>
-one third to one half the thickness of an
-air layer sufficient to just resist punctures
-by the same discharge; but with frequencies
-of 50,000 to 100,000 per second, an oil
-thickness of one thirtieth to one sixtieth
-was a sufficient barrier.</p>
-
-<p>At a frequency of 125 per second, a half-inch
-spark in the air penetrated one third
-to one fourth inch of oil; but at frequencies
-of 50,000 to 100,000 per second, a
-layer of oil one fourth of an inch successfully
-resisted the passage of a spark which
-freely passed through 8 inches of air.</p>
-
-<p>The effect of drying an oil improved its
-insulating qualities. (Tesla uses boiled-out
-linseed-oil.)</p>
-
-<p>He also noted that pointed electrodes
-could be brought nearer together under
-oil than balls without allowing a discharge.
-Flat plates allowed of still greater sparking
-distances. Tesla notes that oil through
-which sparks have passed must be discarded,
-probably owing to particles of carbon
-being formed.</p>
-
-<p><span class="pagenum" id="Page_94">94</span></p>
-
-<p>Paraffin wax has a higher resistance than
-oil, providing it has not been heated over
-135° C. It will stand alternate heating up
-to 100° C. and cooling, being of lower resistance
-when hot than when cold. But
-a serious permanent deterioration takes
-place when it has been heated over 100°C.;
-its color, from the normal pure white,
-changes to a yellowish tint when its insulation
-is impaired. Paraffin also undergoes
-a deterioration when heated for a
-long time even at 100° C., and should
-never be used for fine work when it is at
-all yellow. It is always best to melt it in
-a hot-water bath, not permitting, however,
-any steam or moisture to come near
-it. In this climate (United States) it is
-not so necessary to mix in any tallow to
-obviate brittleness, the average temperature
-of most workshops being sufficiently
-high to keep it from becoming brittle.</p>
-
-<p>Resin oils do not suffer permanent injury
-from being heated, as does paraffin,
-but their insulating properties diminish<span class="pagenum" id="Page_95">95</span>
-much more rapidly on becoming even
-warm, the initial resistance of resin oils
-being lower than that of paraffin.</p>
-
-<p>Paraffin has a fault—its tendency to absorb
-a slight degree of moisture. It has
-been found in telephone and telegraph
-cables saturated with paraffin that this is a
-very important cause of their deterioration.
-In Ruhmkorff coils, however, which
-are intended for operation in enclosed
-places free from damp atmospheres, the
-absorption of moisture would be probably
-reduced to its minimum.</p>
-
-<p>There is one substance which, were it not
-for its cost, would be far preferable to
-paraffin for coil work, and that is beeswax.
-Its cost, however, is generally five
-times that of paraffin, even when purchased
-in quantities. It never becomes brittle
-enough to be damaged in careful handling,
-its melting point is low, and it does not
-absorb moisture. But it must be unquestionably
-pure and clear.</p>
-
-<p>In foreign practice a variety of resinous<span class="pagenum" id="Page_96">96</span>
-mixtures are used to insulate the turns of
-the wire in Ruhmkorff coils.</p>
-
-<p>Equal parts of resin and beeswax used
-hot, paraffin, resin and tallow, and shellac
-and resin are employed.</p>
-
-<p>Shellac—that is, the yellow lac—is
-much used as a varnish for electrical instruments,
-being dissolved in alcohol to
-saturation. For dynamo armatures and
-similar apparatus the shellac varnish is of
-great service, and many good compounds
-of shellac, such as insullac and armalac,
-have been prepared for ready use. But
-(excluding beeswax) for our purposes paraffin
-stands pre-eminently at the head of
-the list.</p>
-
-<p>In using shellac varnish, in high tension
-work more particularly, care must be
-taken that the moisture has entirely evaporated.
-Although a piece of shellacked apparatus
-may appear perfectly dry, yet
-when the current is allowed to flow unlooked-for
-results may appear—it takes
-hours in a dry atmosphere for shellac var<span class="pagenum" id="Page_97">97</span>nish
-to dry. Baking the apparatus in a
-warm oven is a necessary expedient
-whenever feasible, care being taken not
-to burn or decompose the shellac. The
-proportions most generally used are 1
-ounce shellac to 5 ounces alcohol. Stand
-the vessel containing the mixture in
-a warm place, and shake it frequently;
-filtration improves the varnish somewhat.</p>
-
-<p>A ready and efficient varnish for silk is
-prepared by mixing 6 ounces of boiled linseed-oil
-and 2 ounces of rectified spirits of
-turpentine. For paper, 1 part of Canada
-balsam and 2 parts of spirits of turpentine
-dissolved in a warm place and filtered before
-being used. A good insulating cement
-for Leyden jars and insulating stands is
-prepared from sulphur, 100 parts; tallow, 2
-parts, and resin, 2 parts, melted together
-until of the consistence of syrup, and sufficient
-powdered glass added to make a
-paste. To be heated when applied, this
-will resist most acids. The resin and<span class="pagenum" id="Page_98">98</span>
-beeswax compound is handy when making
-experimental mercurial air pumps of glass
-tubes, as it has a fair tenacity, is not too
-brittle, and is easily used.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_99">99</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_IV">CHAPTER IV.<br />
-
-<small>CONDENSERS.</small></h2>
-</div>
-
-<p>A condenser is an apparatus whereby
-a charge of electrical energy may be temporarily
-stored, the amount of energy it
-will hold determining its "capacity."
-The capacity of a condenser is measured
-in micro-farads, the commercial unit representing
-one millionth of a farad. A
-farad equals the capacity of a body raised
-to the potential of one volt by a charge of
-one ampere for one second at one volt—<i>i.e.</i>
-= one coulomb.</p>
-
-<p>The measurement of the capacity of a
-condenser is accomplished by the use of a
-ballistic galvanometer. The latter instrument
-has a bell-shaped magnet suspended
-in a coil of fine wire. When a momentary
-current is passed through this coil the<span class="pagenum" id="Page_100">100</span>
-magnet hardly commences to rotate until
-the current has practically ceased. A
-beam of light is reflected from a mirror
-fixed to the magnet on to a scale. The degree
-of deflection is compared with that
-obtained by the discharge of a condenser
-of known capacity, and the capacity of the
-condenser being measured is deduced by a
-simple rule. The farad, which is the unit
-of capacity requiring a condenser of an
-immense size, is replaced by a commercial
-unit, the micro-farad—that is, one millionth
-of a farad.</p>
-
-<p>The original form of the condenser was
-the Leyden jar, which owes its name from
-the town of Leyden in Europe.</p>
-
-<div class="figleft" ><a id="fig29"></a>
-<img src="images/i_101.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 29.</span></div>
-</div>
-
-
-<p>The Leyden jar is made as follows (Fig.
-29): A clean uncracked glass jar with a
-wide mouth is coated on the inside and
-outside with tinfoil; sometimes loose tinfoil
-is filled inside, the tinfoil, however,
-not reaching more than two thirds of the
-jar's length from the bottom. A cork is
-fitted, and through the middle of it a wire<span class="pagenum" id="Page_101">101</span>
-is passed touching the inside coating of
-tinfoil and terminating in a metal sphere
-outside. A simple Leyden
-jar can be made in a
-few moments by half filling
-a glass bottle with
-water and wetting the
-lower half of the outside;
-a wire run through the
-cork into the water finishes
-the job. But this
-is at least only a makeshift,
-although a fair
-amount of current has
-been collected from a
-leather engine belt in
-motion in one thus made.</p>
-
-<p>A condenser can be easily made as follows
-(Fig. 30):</p>
-
-<div class="figright" ><a id="fig30"></a>
-<img src="images/i_102.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 30.</span></div>
-</div>
-<p>Procure a clear glass plate, <i>G</i>, free from
-flaws, 11 inches square by 3/3<sup>3</sup>∕<sub>32</sub> inch thick.
-Give this a good coating of shellac varnish
-all over, sides and edges. Cut out of
-smooth tinfoil two sheets, <i>T</i>, 8 inches square,<span class="pagenum" id="Page_102">102</span>
-and round off the corners with a pair of
-shears. There must be no sharp corners,
-projections, or angles to
-induce leakage. Lay
-the glass plate on a
-sheet of paper, and mark
-its outline thereon with
-a pencil; then remove it
-and substitute a sheet of
-the tinfoil, and mark that. This will enable
-you to centre the foil. Give one side
-of the glass plate another coat of varnish,
-and so lay it on the paper that its outline
-coincides with the pencil outline. When
-the varnish has partly dried take a sheet
-of the trimmed foil, and by observing the
-pencilled marks you can lay it on the varnished
-plate exactly in the centre. Lay
-down the top edge first along this line, and
-carefully deposit the remainder of the foil
-in place. Next, with a flat brush full of
-varnish go over the plate, pressing out any
-air bubbles, and ensuring both a flat and a
-well-varnished surface. When this is dry,<span class="pagenum" id="Page_103">103</span>
-turn over the plate and repeat the operation
-on the other side.</p>
-
-<p>If desired, a metal hemisphere of at least
-an inch in diameter may be attached with
-varnish, first scraping the foil to make a
-contact. The whole plate can be swung in
-a cradle of two silk threads, laid on a glass
-tumbler, or mounted on end in a shellacked
-block of wood.</p>
-
-<p>A strip of tinfoil, <i>S</i>, attached at the corner
-can be used as a connector. The
-plates must be joined in the following
-manner when two or more are used in
-conjunction, and a quantity of current is
-desired. They should be placed so the
-connecting strips project alternately from
-each side (Fig. 31), and all on each side
-joined so as to leave two terminals, one to
-the 1, 3, 5 plates, the other to the 2, 4, 6
-plates, and so on, which, when joined, will
-have the same effect as would result from
-the use of two large plates of the same
-total area. The nearer the plates are together
-the greater capacity they will have,<span class="pagenum" id="Page_104">104</span>
-always supposing the insulation is good,
-the insulation being known as the dielectric.
-Another good
-method, when a high
-quality of glass can be
-procured, is to lay the
-tinfoil on the plates
-without varnish, piling
-one on top of the other,
-tinfoil and glass alternately,
-and clamping the
-whole securely, laying a piece of cloth top
-and bottom to avoid cracking the glass from
-the pressure. This must be kept from
-moisture; a strip of paraffined paper stuck
-along the edges and extra paraffin run on
-will answer very well.</p>
-
-<div class="figright" ><a id="fig31"></a>
-<img src="images/i_104.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 31.</span></div>
-</div>
-
-<p>In constructing these glass condensers,
-they must be designed to correspond with
-the coil with which they are to be charged.
-In the foregoing description we have allowed
-a margin of 1½ inches of glass
-around the foil coatings. This will make
-3 inches as the maximum distance between<span class="pagenum" id="Page_105">105</span>
-the coatings. Although a 2-inch spark
-from the coil would not jump this interval,
-a certain discharge will take place, and the
-less this occurs, the more serviceable the
-condenser will be. Therefore a greater
-margin should be allowed for a longer
-spark than 2 inches.</p>
-
-<p>In the commercial condenser for telephone
-and telegraph use, paraffin and
-paper are substituted for glass, as will be
-described later. Heavy paraffin oil gives
-excellent results, but its fluidity is disadvantageous.</p>
-
-<p>There is no valid reason why paraffin
-could not be used on the glass plate condensers,
-care being observed that it is free
-from dirt and metallic chips. In fact, the
-space between the glass plates of the multiplate
-condenser may be filled in with
-paraffin, and thereby exclude the air. Only
-a condenser so built up is not convenient
-to take apart for experimental purposes.</p>
-
-<p>The foregoing description of a glass in<span class="pagenum" id="Page_106">106</span>sulated
-condenser was written with the
-assumption that a good quality of glass be
-used. But the ordinary window glass is
-generally useless, and paraffined paper is
-preferable. The quality of glass known as
-"hard flint glass" is best, the superior
-qualities being imported from Europe.
-This latter is used in the manufacture of
-the standard Leyden jar for lecture purposes.</p>
-
-<p>Were it not for its cost, the finest dielectric
-we could use would be sheet mica.
-Unfortunately sheet mica over 3 inches
-square is expensive, and becomes rapidly
-more so as it becomes larger.</p>
-
-<p>Standard condensers for testing are
-made with mica carefully selected, and retain
-the charge for the maximum length of
-time. The built-up mica condenser is
-immersed in molten paraffin until the same
-has permeated the sheets, and then the
-complete mass is put under a pressure
-until the paraffin is well set.</p>
-
-<p><span class="pagenum" id="Page_107">107</span></p>
-
-
-<h3><span class="smcap">Paper Condenser.</span></h3>
-
-<p>The paper used in the manufacture of
-the commercial form is a special thin,
-tough linen paper carefully selected, sheet
-by sheet, to avoid pin-holes or flaws, and
-kept in an oven until used to ensure absolute
-dryness.</p>
-
-<p>When this cannot be procured, use thin
-unsized writing paper of a good quality,
-well dried, and absolutely clean. As an
-example of the necessity of cleanliness,
-a light lead-pencil mark would serve
-to conduct the current entirely from a
-charged sheet to wherever it terminated,
-and if suitably located, utterly destroy
-the usefulness of the apparatus. Ink,
-which most generally contains iron, will
-cause trouble, and although some cheap
-foreign condensers are built up of old
-ledger pages, yet their efficiency is very
-uncertain.</p>
-
-<p>The paper used in commercial condensers
-is from four to seven thousandths
-of an inch in thickness.</p>
-
-<p><span class="pagenum" id="Page_108">108</span></p>
-
-
-<h3><span class="smcap">Series.</span></h3>
-
-<p>The smaller the amount of surface the
-less will be the capacity, but the quicker
-the discharge. The apparatus heretofore
-mentioned has had the alternate plates
-connected together in two series, presenting
-a large surface and rendering a large
-amount of current. A condenser so made
-will have a low voltage or potential, but is
-not so liable to leakage as one made to
-render a high potential. The multiple
-condenser of a large capacity will hardly
-discharge and spark over an air gap requiring
-a contact of the two electrodes.
-But a smaller one, consisting only of a
-single pair of small plates, will spark
-across quite a considerable air gap.</p>
-
-<p>A number of charged condensers may
-be put in series, and the resultant potential
-thereby increased. Cut a number of
-pieces of paper of the desired size, say 6
-inches square, and a number of sheets of
-foil 3 inches square. Round off the corners
-of the foil and build up first a sheet<span class="pagenum" id="Page_109">109</span>
-of paper, then a sheet of foil in its centre,
-then another paper and another foil sheet,
-and so on. There is to be no connection
-from sheet to sheet, only the inductive
-action of one on its neighbor. The foil
-must be considerably smaller than the
-paper in this construction, owing to the
-greater tendency to discharge round the
-edges of the sheets, owing to the greater
-potential of the current.</p>
-
-<p>When the requisite number of sheets
-have been built up, leave a sheet of foil top
-and bottom for connection, tie between
-two pieces of stout card or board, and immerse
-in the molten paraffin. When thoroughly
-soaked, remove and put under
-pressure until cold. It will be found undesirable
-to make these with more than a
-dozen pairs of sheets, but to make a number
-of blocks of that number for ready
-service.</p>
-
-<div class="figcenter" ><a id="fig32"></a>
-<img src="images/i_110.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 32.</span></div>
-</div>
-
-<p>Fig. 32 shows the arrangement of the
-apparatus to charge a Leyden jar, the
-plate form being connected in a similar<span class="pagenum" id="Page_110">110</span>
-manner. The jar is stood upon an insulating
-support—a dry tumbler will answer—with
-the ball <i>B</i> connected to one pole of
-the coil. From the outside tinfoil coating<span class="pagenum" id="Page_111">111</span>
-<i>T</i> a wire runs to the discharger <i>D D</i>, which
-is in circuit with the secondary coil, <i>S</i>.
-The discharger balls <i>D D</i> are carefully approximated
-until the spark just passes, this
-latter point being of great importance.
-Were the discharger balls too near the
-spark would probably pierce the dielectric
-of the condenser, therefore the balls should
-be carefully <i>brought near</i> to each other
-until the exact distance is found. Even if
-the insulation of the condenser were not
-pierced, yet a path would probably be
-opened through which some succeeding
-discharge would pass, and ruin the instrument.</p>
-
-<p>Another method of charging is to leave
-an air gap at <i>B</i>; then there is not much
-liability of the condenser discharging back
-through the coil—an undesirable event, as
-it would most likely perforate the insulation
-of the coil.</p>
-
-<div class="figcenter" ><a id="fig33"></a>
-<img src="images/i_112.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 33.</span></div>
-</div>
-
-<p>In designing or using any apparatus intended
-to hold a charge of high potential, it
-must be kept in mind how readily points or<span class="pagenum" id="Page_112">112</span>
-sharp edges serve to allow the current to<span class="pagenum" id="Page_113">113</span>
-pass off—we might almost say evaporate.
-Given two bodies, one a globe and the
-other a rectangular block, each well insulated
-from the earth or any other large
-body, and the globe would be found to
-hold its charge long after the block had
-dissipated all trace of the charge given to
-it. Therefore round off every edge and
-angle, projection or point.</p>
-
-<p>In making handles, supports, or any
-work requiring an intervening high insulation,
-hard rubber is preferable to glass
-where there is liability to moisture. When
-the apparatus is as shown in Fig. 33, the
-condenser is alternately charged and discharged
-with a loud noise, the vivid sparks
-passing across the discharger balls <i>D D</i>
-possessing great deflagratory powers.</p>
-
-<p>In experimenting with a Ruhmkorff coil
-it is not advisable to leave the instrument
-working while the secondary terminals are
-beyond sparking distance, as there is a
-great strain on the secondary insulation.<span class="pagenum" id="Page_114">114</span>
-Nor is it wise to use only one electrode in
-an experiment, unless the other is connected
-to some apparatus of an approximate capacity
-to that at the other, for the foregoing
-reason.</p>
-
-
-<h3><span class="smcap">Rolled-Up Condensers.</span></h3>
-
-<p>Now that the condenser has become so
-important a factor in telephone work, many
-schemes for cheapening and facilitating
-their manufacture have been devised. One
-in particular merits description, the "rolled-up"
-condenser having come largely into
-use. The tin-foil is supplied in rolls containing
-many yards of foil of the requisite width
-for the condenser to be made. Likewise rolls
-of paper are provided, exceeding in width,
-however, those of tin-foil. These rolls are
-arranged upon horizontal spindles in front
-of an empty spindle, or mandrel, upon which
-the condenser is to be formed. A few turns
-of the paper ribbon are made around the
-mandrel, then the foil is brought forward<span class="pagenum" id="Page_115">115</span>
-and a few turns made, then follows a turn of
-paper ribbon and another of foil, and finally
-a paper layer; and the mandrel being rotated,
-the alternate layers of foil and paper are
-laid on and rolled around each other on the
-mandrel until the requisite quantity is obtained.
-It then becomes an easy matter to
-cut the paper ends so no contact is possible
-between the layers of foil. The whole thing
-is slipped off the mandrel, secured by a
-rubber band or two, placed in a hot paraffin
-bath, and left to become saturated while
-still warm and before the paraffin has time
-to harden; the cylinder is put under a press
-and squeezed flat, driving out excess paraffin,
-and leaving the condenser in a convenient
-shape to handle. Connections are then made
-to the foil leaves, and a case of wood or
-metal completes the work.</p>
-
-<p>There is no reason why aluminum foil or
-lead foil, or, in fact, any thin sheet metal
-should not be used in condensers. In telephone
-work, paper covered with gilt paint
-was tried, and worked fairly well, but was<span class="pagenum" id="Page_116">116</span>
-ultimately rejected in favor of tin-foil. In
-some cases, when it is desired to construct
-a condenser for high potential work, the
-oil-tank apparatus can be used. This is
-readily made of any desired dimensions, as
-follows: Procure a square glass jar, such
-as is made for storage batteries, a few pieces
-of sheet metal cut to fit loosely in the jar,
-some glass rods and sufficient clean "transformer
-oil" or heavy paraffin oil to nearly
-fill the jar. The sheets of metal can then be
-hung from the glass rods into the jar, being
-separated one-half inch, and the oil poured
-in. Two plates, about 8 inches by 6 inches,
-will hang nicely into a type D<sup>3</sup> Chloride
-Battery jar, which is 7⅞ inches long by 9½
-inches high by 3¼ inches wide. Altering the
-relative distances between the plates will
-give considerable adjustment to this simple
-condenser, or, if desired, more plates may be
-inserted and connected up, as in the tin-foil
-condensers. This type can be made portable,
-but it is not to be recommended unless no<span class="pagenum" id="Page_117">117</span>
-objection is had to emptying and refilling
-the jar with oil.</p>
-
-
-<h3><span class="smcap">Adjustable Condensers.</span></h3>
-
-<p>In operating large coils, it is convenient
-to be able to vary the capacity of the condenser
-on the primary circuit. To make
-an adjustable condenser presents no more
-difficulty than a non-adjustable one, simply
-more labor. For example, the large condenser
-used with the 6-inch spark coil might
-be divided into four sections, containing
-2000 square inches, 500 square inches, 300
-square inches, and 200 square inches of
-surface (see Fig. 34). Wires leading from
-the ends of the foil sheets <i>C C</i> are to be
-brought to the brass plates <i>G G</i>. The brass
-rods <i>B B</i> are connected by binding posts to
-the coil, each strip being well insulated from
-its neighbor. Any combination is possible
-by the insertion of brass plugs in holes
-drilled between the strips. The plugs must
-be fully large enough to make good contact
-on each of the two strips between which<span class="pagenum" id="Page_118">118</span>
-they are inserted, and should be turned
-taper. With the largest coils the condenser
-and contact breaker are generally mounted
-separately, and are fully adjustable.</p>
-
-<div class="figcenter" ><a id="fig34"></a>
-<img src="images/i_118.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 34.</span></div>
-</div>
-
-<p><span class="pagenum" id="Page_119">119</span></p>
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr><th colspan="2"><span class="smcap">Specific Inductive Capacity.</span></th></tr>
-<tr>
- <td align="left">Dry air</td>
- <td align="left">1.000</td>
-</tr>
-<tr>
- <td align="left">Sulphur</td>
- <td align="left">2.590</td>
-</tr>
-<tr>
- <td align="left">Hard rubber</td>
- <td align="left">2.290</td>
-</tr>
-<tr>
- <td align="left">Paraffin</td>
- <td align="left">1.996</td>
-</tr>
-<tr>
- <td align="left">Shellac</td>
- <td align="left">2.750</td>
-</tr>
-<tr>
- <td align="left">Kerosene</td>
- <td align="left">2.225</td>
-</tr>
-<tr>
- <td align="left">Paraffin oil</td>
- <td align="left">2.710</td>
-</tr>
-<tr>
- <td align="left">Castor oil</td>
- <td align="left">4.962</td>
-</tr>
-<tr>
- <td align="left">Olive oil</td>
- <td align="left">3.575</td>
-</tr>
-</table></div>
-
-<p>Condensers made with dielectric of high
-inductive capacity (insulation being equal)
-will retain greater charge than those made
-with dielectrics of low inductive capacity.
-Thus, one made with shellac would be nearly
-half as great again as with paraffin.</p>
-
-<p>Capacity of a condenser increases with
-area of foil surface, with diminished distance
-between foil plates and with increase
-of insulation.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_120">120</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_V">CHAPTER V.<br />
-
-<small>EXPERIMENTS.</small></h2>
-</div>
-
-<p>The luminous effects that can be obtained
-by means of a Ruhmkorff coil are
-exceedingly beautiful and instructive.
-The simplest experiment of this nature is
-the production of the spark consequent on
-the approximation of the electrodes attached
-to the secondary coil. This spark
-can be varied in both length, intensity, or
-shape by the form and nature of the substances
-between which it is permitted to
-pass. Attach to each end of the discharger
-a fine steel needle, and bring them
-together until the spark jumps from one
-to the other. A long thin snapping spark
-will pass, which, however, appears to be
-trying to take any but a straight path
-across the air gap. The peculiar crooked<span class="pagenum" id="Page_121">121</span>ness
-of this, as in a lightning flash, is credited
-to the fact of particles of matter floating
-in the air conducting the current better
-than the pure air. The curious odor
-noticed in these discharges, as, in fact, in
-the working of all high-tension apparatus,
-is ozone—O<sub>3</sub>, triatomic oxygen. This gas,
-so noticeable after a thunderstorm, has a
-powerful effect on the mucous membranes
-of the throat and nasal passages, and must
-be inhaled with caution. It is being used
-by the medical profession for the destruction
-of germs and for general therapeutic
-service.</p>
-
-<p>Substitute pieces of fine iron wire for
-the needles, and bring the ends together
-about one quarter the distance through
-which the normal spark will pass. The
-spark will be found to have changed its
-appearance, now being thick and redder,
-or, rather, of a deep yellow, and to possess
-vast heating qualities.</p>
-
-<p>The iron wire will melt at one electrode,
-and if the other be examined it will be per<span class="pagenum" id="Page_122">122</span>ceived
-that it has not even become warm.
-The cold wire will be the one connected
-to the positive pole of the coil.</p>
-
-<p>Connecting the poles together with a
-piece of very fine iron wire will result in
-the deflagration of the wire in a vivid
-light.</p>
-
-<p>The short thick spark is termed the
-calorific spark, and believed to possess its
-yellow color from the combustion of the
-sodium in the air. This spark will easily
-ignite a piece of paper held in its path.</p>
-
-<p>Take a sheet of hard rubber and breathe
-on its surface; lay a wire from each pole of
-the secondary to points on the sheet, about
-twice as far apart as the spark would pass
-over in the air. The electric current will
-strive to complete its circuit; streams of
-violet light forming a perfect network will
-issue from each pole, until, provided the
-rubber is sufficiently damp, they will unite
-in a spark far exceeding its normal length
-in the air. It is curious to watch how the
-streams branch out from these two points,<span class="pagenum" id="Page_123">123</span>
-and how persistently they strive to meet
-each other. Scatter some finely powdered
-carbon on this sheet (crushed lead-pencil
-or electric light carbon is good material).
-The points may now be removed to still
-further distant places, and yet the current
-will work across. Each particle of carbon
-seems to be provided with innumerable
-scintillating diamonds, so sparkling is this
-effect.</p>
-
-<p>Hard rubber is not absolutely necessary
-for these experiments; glass will do, but
-the black background of the rubber intensifies
-the luminosity of the discharges.
-Take a teaspoonful of powdered carbon
-and scatter it between the points on the
-rubber, so that the spark can find a ready
-path, evidenced by but little visible light.
-It will be seen that this powder is blown
-away from one electrode after a few minutes,
-leaving the latter in the centre of a
-clear space, but at the other electrode not
-much disturbed.</p>
-
-<p>Bring the points so close to one another<span class="pagenum" id="Page_124">124</span>
-that the spark becomes short and fat; soon
-the carbon will commence to burn, forming
-a veritable arc light. Take two pointed
-lead-pencils and wrap a few turns of wire
-from the electrodes round the blunt ends
-of them; bring the pointed ends together,
-and an arc will soon be established; but
-at various points where the wire is wrapped
-the current will burn through the wood,
-and a number of incandescent points will
-ensue.</p>
-
-<p>In these experiments on the rubber sheet
-it will be noticed that the spark acts as it
-does in the air, inasmuch as it does not take
-a direct path, but jumps in an irregular
-track from point to point.</p>
-
-<p>If two small metal balls be substituted
-(Fig. 35) for the points between which the
-sparks be passing, it will be noted that the
-sparks do not pass through so great an air
-gap as before, or even as rapidly.</p>
-
-<p>The spark between two balls is much
-noisier than that passing between points,
-and if the balls be of about 1 inch in<span class="pagenum" id="Page_125">125</span>
-diameter, a curious effect ensues on the
-passage of the current (Fig. 36). This
-effect has been likened to a stream of
-water issuing from a horizontal nozzle into
-a cavity when the nozzle is moved up and
-down slowly in the space of a few inches.</p>
-
-<div class="figleft" ><a id="fig35"></a>
-<img src="images/i_125.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 35.</span></div>
-</div>
-<div class="figright" ><a id="fig36"></a>
-<img src="images/i_125b.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 36.</span></div>
-</div>
-
-<h3><span class="smcap">The Luminous Pane.</span></h3>
-
-<div class="figright" ><a id="fig37"></a>
-<img src="images/i_125c.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 37.</span></div>
-</div>
-<p>This easily made exhibit (Fig. 37) is one
-that is susceptible of quite a number of applications.
-In its simple
-form it is but an enlarged
-version of the rubber
-sheet scattered with carbon
-dust. The old way
-to make it was to take
-a plate of glass and cement
-on one face of it a sheet of tinfoil,
-using shellac varnish preferably. When
-dry, the tinfoil was scored across and<span class="pagenum" id="Page_126">126</span>
-across in such manner as to divide it up
-into little squares or diamonds. When
-the current was applied to each end of the
-plate, the spark divided into innumerable
-little ones; between each bit of tinfoil and
-its neighbors there would be many little
-sparks, and the effect was very pretty,
-somewhat as was described before when
-the carbon dust was strewn between the
-electrodes. It is more easily and quickly
-prepared by giving a sheet of glass a coating
-of shellac varnish, and then sparingly
-dusting any powdered conductor over its
-surface, using perhaps carbon dust or
-filings of metal. By cutting out a stencil
-from a piece of thin card and laying it over
-the sparkling plate, the design shows out
-very strikingly, and various designs in stencils
-can be prepared, different powdered
-conductors giving different colored sparks.</p>
-
-<p>A long glass tube moistened inside with
-mucilage or shellac varnish and then having
-some conducting dust shaken through
-will also give quite a pleasing effect.</p>
-
-<p><span class="pagenum" id="Page_127">127</span></p>
-
-
-<h3><span class="smcap">Luminous Designs.</span></h3>
-
-<p>Coat one side of a glass plate with tinfoil,
-leaving an attached strip for connection.
-Shellac a piece of paper of a size corresponding
-to the design to be rendered
-luminous. When the shellac has dried so
-far as to become "tacky," lay a sheet of
-foil on it and press it down evenly all over.</p>
-
-<p>Then draw on the paper a design that
-can be readily cut out. Use a pair of scissors
-or a very sharp knife. If the latter,
-lay the sheet on a piece of glass; but
-there is a greater tendency to tear the design
-when a knife is used if an unpractised
-hand wields it.</p>
-
-<p>This design may either be stuck on to
-the plain side of the glass plate with varnish
-or simply laid on (Fig. 38). Connect
-one secondary wire to the foil coating of
-the plate and the other to the design.
-This must be shown in the dark, and the
-luminosity will not be strikingly apparent
-until the eyes become accustomed to the<span class="pagenum" id="Page_128">128</span>
-darkness—that is, when the room has
-been previously lighted.</p>
-
-<p>One of the most beautiful and easily obtained
-phenomena of the high-tension discharge
-is the "electric brush" (Fig. 39).
-This occurs when the secondary electrodes
-of the coil are too far apart to allow of the
-free passage of the spark, and can only be
-seen at its best in a perfectly dark place.
-The ball tips before mentioned show this
-brush very plainly, or two sheets of tinfoil
-in circuit hung far enough apart to prevent
-vivid sparking will cause this so-called
-"silent" discharge. This latter arrangement
-should not be used for over fifteen
-minutes, as the ozone which is liberated in
-large quantities will affect those persons in
-the vicinity.</p>
-
-<div class="figleft" ><a id="fig38"></a>
-<img src="images/i_128.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 38.</span></div>
-</div>
-<div class="figright" ><a id="fig39"></a>
-<img src="images/i_128b.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 39.</span></div>
-</div>
-
-<p><span class="pagenum" id="Page_129">129</span></p>
-
-<p>In fact, when a rapid vibrator is being
-used with the coil, the leading wires from
-the secondary terminals present this brush
-appearance, the curious threads of light
-resembling luminous hairs waving in the
-air. The more rapid the vibrations the
-more prominent the brush effect, as will
-be seen in the Tesla coils. The positive
-ball of the discharger shows the brush as
-a spreading mass of luminous threads
-reaching out toward the negative ball,
-which latter resembles a star, as in the
-figure.</p>
-
-<p>The intensely disruptive power of the
-long spark is readily shown by its power
-to perforate substances, but great care
-must be taken that the secondary wires of
-a coil are led away from the body of the
-coil. A good plan is to hang two silk
-cords or stout threads from the ceiling, to
-which the secondary wires may be attached
-and kept in sight when experimenting
-at any distance from the coil.</p>
-
-<p>To pierce a piece of thin glass, take two<span class="pagenum" id="Page_130">130</span>
-lumps of paraffin about the size of a walnut,
-and, warming them and the glass
-sheet, stick them on opposite sides of
-the glass facing each other. Then warm
-the ends of the two pointed wires and
-thrust them into the lumps of paraffin, that
-they terminate on the glass surface directly
-opposite each other. On connecting
-these to the secondary coil a few impulses
-to the contact breaker will start an electric
-discharge sufficient to pierce the glass
-if the thickness be proportioned to the
-power of the apparatus. The great
-Spottiswood coil pierced a block of glass
-6 inches in thickness.</p>
-
-<p>There is, however, a certain element of
-danger to the secondary insulation in performing
-this experiment.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_131">131</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_VI">CHAPTER VI.<br />
-
-<small>SPECTRUM ANALYSIS.</small></h2>
-</div>
-
-<p>If a metal or the salt of a metal be
-burned in a flame it imparts to the flame a
-distinctive color; table salt thrown into
-the fire burns with a yellowish flame, denoting
-the presence of sodium, and a
-greenish tint, indicating the combustion
-of chlorine. Violet flames accompany the
-burning of the salts of potassium, and
-barium burns green. Lithium and strontium
-give a red hue. But to be ordinarily
-perceptible, the salts require for the most
-part to be present in considerable quantities.
-By the use of the spectroscope,
-however, extremely small proportions of
-these metals and salts can be readily detected
-and classified.</p>
-
-<div class="figcenter" ><a id="fig40"></a>
-<img src="images/i_132.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 40.</span></div>
-</div>
-
-<p>If a beam of light be transmitted<span class="pagenum" id="Page_132">132</span>
-through a prism of glass the rays are decomposed,
-and what is known as a spectrum
-is formed (Fig. 40). The most generally
-observed spectrum is the rainbow.
-When the light from a flame in which is
-burning some suitable substance be transmitted
-through the prism, the color which
-predominates in the flame will predominate
-in its spectrum. The combination of
-a prism and tubes for observing these
-effects is a spectroscope (Fig. 41). The
-short fat spark from the Ruhmkorff coil is
-most useful in this work. The electrodes<span class="pagenum" id="Page_133">133</span>
-are provided with a portion of the substance
-to be examined, and the spark is
-passed and viewed through the spectroscope.</p>
-
-<div class="figcenter" ><a id="fig41"></a>
-<img src="images/i_133.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 41.</span></div>
-</div>
-
-<p>The spectroscope is shown in connection
-with the coil in Fig. 41. <i>A</i> is the<span class="pagenum" id="Page_134">134</span>
-aperture in the screen through which the
-rays from the metal burning at the discharger
-balls <i>D D</i> passes. The lens at <i>L</i>
-is used to view these rays after they have
-been decomposed by the prism <i>P</i>, which,
-as well as the lens, can be rotated. <i>I</i> is
-the coil, <i>P P</i> the primary and <i>S S</i> the secondary
-wires, <i>C</i> being a condenser bridged
-across the circuit.</p>
-
-<p>The screen should be pierced by a very
-narrow aperture, <i>A</i>, and be placed at a
-considerable distance from the prism <i>P</i>,
-that the rays issuing through the aperture
-may not strike the prism until they have
-widely diverged and become separated
-from each other. The aperture is practically
-formed of perfectly parallel knife
-edges, forming a slit not exceeding one
-hundredth of an inch in width.</p>
-
-<p>The colored spaces in the solar spectrum
-do not occupy an equal extent of
-area; the violet is the most extended, the
-orange the least. The proportion is in
-three hundred parts: Violet, 80; green,<span class="pagenum" id="Page_135">135</span>
-60; yellow, 48; red, 45; indigo, 40;
-orange, 27.</p>
-
-<p>The solar rays exhibit on careful examination
-dark lines crossing the spectrum at
-right angles to the order of the colors, and
-always occupying the same relative positions.
-These are called Fraunhofer's
-lines.</p>
-
-<p>If, however, the spectra of metals,
-gases, and other elements be examined
-they will be found to present certain characteristic
-<i>bright</i> lines, the body of the spectrum
-being often feeble or entirely dark.
-The spectrum of hydrogen gives two very
-bright lines of red and orange.</p>
-
-<p>An extremely minute quantity of an element
-is necessary to give distinct lines.
-Sodium gives a single or double line of
-yellow light in a position agreeing with
-that of the orange rays in the solar spectrum.</p>
-
-<p>Potassium gives a red line in the red
-end and a violet line in the violet end of
-the solar spectrum. Strontium presents<span class="pagenum" id="Page_136">136</span>
-eight bright lines; calcium gives mainly
-one broad green band and one bright
-orange band.</p>
-
-<p>In practical work with the spectroscope
-a solar spectrum is often arranged that it
-can be used as a comparison with the spectrum
-being investigated, one spectrum
-being formed above the other, and the observation
-made as to which lines coincide.
-Iron gives nearly sixty bright lines coinciding
-with the same number of dark lines
-of the solar spectrum.</p>
-
-<p>The violet rays of the solar spectrum
-are the rays which possess the maximum
-chemical action, the yellow the maximum
-light effect, the red the maximum heating
-effect. Beyond the violet band of the
-spectrum exist certain rays termed the invisible
-rays or ultra-violet rays, which in
-themselves are not luminous. Their vibratory
-rate is higher and their wave length
-shorter than the violet rays, according to
-the most generally accepted theory of
-light. These rays, when passed through<span class="pagenum" id="Page_137">137</span>
-certain substances, suffer a change and become
-visible in a luminous state of the substance,
-which luminosity is termed fluorescence.</p>
-
-<p>The bright yellow line of sodium in the
-orange rays is found in nearly all spectra,
-owing to its extensive diffusion in the atmosphere.</p>
-
-<p>Tesla has succeeded in producing electric
-waves of length approximating to
-those of white light, which appear to have
-very little heat. The ideal light is that
-which shows no heat and does not liberate
-noxious gases in the air, and were it not for
-its feeble luminosity, the light of the electric
-spark passing through a carbonic acid vacuum
-would approximate this most nearly.</p>
-
-<p>The present mode of obtaining light—that
-of raising to a high temperature some
-substance or collection of particles—seems
-certainly somewhat antiquated. The following
-notes may be of interest and assistance
-in researches bearing on the lighting
-question.</p>
-
-<p><span class="pagenum" id="Page_138">138</span></p>
-
-<p>Solid bodies, when heated, show a red
-glow in daylight at an elevation of temperature
-corresponding to 1000° Fahr.</p>
-
-
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr><th><small>Temperature,<br /> degrees F.</small></th><th colspan="2"><small>Color of&nbsp; &nbsp;<br /> Substance.&nbsp; &nbsp;</small></th></tr>
-<tr>
- <td>1000</td>
- <td>&nbsp; &nbsp; &nbsp; &nbsp; </td>
- <td align="left">Red.</td>
-</tr>
-<tr>
- <td>1200</td>
- <td></td>
- <td align="left">Orange.</td>
-</tr>
-<tr>
- <td>1300</td>
- <td></td>
- <td align="left">Yellow.</td>
-</tr>
-<tr>
- <td>1500</td>
- <td></td>
- <td align="left">Blue.</td>
-</tr>
-<tr>
- <td>1700</td>
- <td></td>
- <td align="left">Indigo.</td>
-</tr>
-<tr>
- <td>2000</td>
- <td></td>
- <td align="left">Violet.</td>
-</tr>
-<tr>
- <td>2130</td>
- <td></td>
- <td align="left">All colors—<i>i.e.</i>, white.</td>
-</tr>
-</table></div>
-
-<p>The number of vibrations per second
-necessary for the production of light, and
-the velocity of light being determined, the
-calculation of the wave lengths of the colored
-rays becomes possible.</p>
-
-<p>The following table (Sprague) shows
-this in ten-millionths of a millimetre (a
-millimetre = .039 inch) measured in the
-dark lines of the solar spectrum, from red
-to violet:</p>
-
-
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td align="left">Orange =</td>
- <td align="left">6.88</td>
-</tr>
-<tr>
- <td align="left">Orange, Higher = &nbsp; &nbsp;</td>
- <td align="left">6.56<span class="pagenum" id="Page_139">139</span></td>
-</tr>
-<tr>
- <td align="left">Yellow =</td>
- <td align="left">5.89</td>
-</tr>
-<tr>
- <td align="left">Green =</td>
- <td align="left">5.26</td>
-</tr>
-<tr>
- <td align="left">Blue =</td>
- <td align="left">4.84</td>
-</tr>
-<tr>
- <td align="left">Blue, Higher =</td>
- <td align="left">4.29</td>
-</tr>
-<tr>
- <td align="left">Violet =</td>
- <td align="left">3.93</td>
-</tr>
-</table></div>
-
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_140">140</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_VII">CHAPTER VII.<br />
-
-<small>CURRENTS IN VACUO.</small></h2>
-</div>
-
-<p>Notwithstanding it requires an intensely
-high potential to enable the current
-to jump an air gap of 1 inch, the
-same potential will produce a luminous
-discharge through exhausted glass tubes
-aggregating 8 feet or even more.</p>
-
-<p>But the exhaustion can be carried so far
-that there is no apparent discharge; and,
-on the contrary, air at as high a pressure
-as 600 pounds per square inch will resist
-the passage of the spark over an extremely
-short space. If the tubes be filled with
-various gases and then partially exhausted,
-the length of tube through which the
-luminous discharge will pass varies with
-the gas, becoming shorter in the following<span class="pagenum" id="Page_141">141</span>
-order: Hydrogen, nitrogen, air, oxygen,
-and carbonic acid—the shortest.</p>
-
-<div class="figright" ><a id="fig42"></a>
-<img src="images/i_141.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 42.</span></div>
-</div>
-<p>Before detailing some
-of the more striking phenomena
-connected with
-high-tension discharges in
-vacuo, a description of
-a few forms of simple mercurial
-air pumps will be
-serviceable.</p>
-
-<p>Fig. 42: If a glass tube,
-<i>F</i>, stopped at one end, 3
-feet long or over, be filled
-with mercury and the
-open end immersed in a
-vessel of mercury, <i>T</i>, the
-column of metal in the
-tube will sink until it attains
-a height, <i>M</i>, of about
-30 inches, varying according
-to the condition of the atmosphere.</p>
-
-<p>The space between the mercury column
-and the top of the tube will be a fairly
-good vacuum. This fact was noted many<span class="pagenum" id="Page_142">142</span>
-years ago, and the gradual evolution of
-the mercurial air-pump based on this result
-can be followed in the articles on the
-mercurial air-pump by Silvanus P. Thompson,
-read before the Society of Arts, England,
-some years ago.</p>
-
-<p>Geissler, the first manufacturer of the
-"Geissler" or vacuum tube for electrical
-research, seeing the inconvenience of the
-above-described operation and the meagre
-results obtained, invented the pump called
-by his name (Fig. 43).</p>
-
-<p><i>F E</i> is a stout glass tube some 3 feet
-long, having a bulb, <i>B</i>, at its upper extremity,
-and a rubber tube, <i>S</i>, attached to the
-curved end. A reservoir of mercury, <i>R</i>,
-connects with this rubber tube, and a special
-glass tap is fixed in the upper end of
-the glass tube at <i>E</i>, beyond which tap
-being the point of attachment for the object
-to be exhausted. The operation is as
-follows: On turning the tap a part of the
-way it allows a passage between the tube
-<i>F E</i> and the atmosphere. The reservoir<span class="pagenum" id="Page_143">143</span>
-<i>R</i> is then raised until the mercury flows
-into the bulb and up the tube to the tap.
-The tap is then turned a fraction, and the
-communication with the air is shut off and
-opened between the object to be exhausted
-and the tube <i>F E</i>. The reservoir is
-then lowered and the mercury falls, drawing
-down the air from the object into the
-tube. The tap is then turned as in the
-first place, and the reservoir <i>R</i> raised,
-when the air drawn into the tube is forced
-out by the rising column of metal. This
-operation being repeated many times,
-withdraws nearly all the air from the object—in
-fact, makes a fairly good vacuum.
-This pump has been much modified from
-the simple form described.</p>
-
-<p>The form of pump most used in the
-United States lamp factories is based on
-the application of the piston-like action of
-a quantity of mercury dropping down a
-tube. This is known as the Sprengel
-pump, after the inventor.</p>
-
-<div class="figcenter"><a id="fig43"></a>
-<img src="images/i_144.jpg" alt="" />
-<div class="caption"><span class="smcap gap10">Fig. 43.</span> <span class="smcap">Fig. 44.</span></div>
-</div>
-<p>Fig. 44: <i>F</i> is a stout glass tube about<span class="pagenum" id="Page_144">144</span>
-40 inches long by one-twelfth of an inch<span class="pagenum" id="Page_145">145</span>
-internal diameter, carrying the reservoir
-funnel <i>R</i> at the top, a piece of soft rubber
-tubing, <i>S</i>, nipped by a pinch-cock being
-interposed to admit of the regulation of
-the mercurial drops. The lower end of
-this "fall tube," as it is called, is immersed
-in mercury contained in a suitable
-vessel, <i>V</i>, a branch tube being blown or
-cemented into the fall tube to admit of the
-connection of the object to be exhausted
-at <i>E</i>. <i>S</i> is another piece of rubber tubing
-with a pinch-cock regulation. The point
-<i>H</i> is the normal barometric height of the
-mercury—about 30 inches. On attaching
-a bulb, for example, at <i>E</i>, and regulating
-the pinch-cock at the top of the fall tube <i>F</i>,
-a succession of drops of mercury falls
-down the tube, each drop acting as a piston
-to drive the air before it, sucking the
-same from the bulb, and forcing it down
-through the tube and vessel out into the
-atmosphere.</p>
-
-<p>On its first being set into operation, the<span class="pagenum" id="Page_146">146</span>
-cushions of air between the drops silence
-their fall; but as a higher degree of rarefaction
-occurs, the air cushions become
-insufficient, and the drops fall with a sharp
-click on the top of the barometric column.</p>
-
-<p>One great disadvantage in this form of
-pump is the tendency to fracture of the
-glass tube that is manifested by the concussion
-of the drops of mercury at the
-barometric height. However, this has to
-a certain extent been obviated in later
-forms of this useful and efficient pump.</p>
-
-<p>For many electrical experiments, the
-simple exhaust tube (Fig. 42) mentioned
-at the beginning of the article will be found
-very satisfactory. The top end need not
-necessarily be sealed off with glass, a cork
-having a wire, <i>W</i>, run through for connection
-being driven in, and a coat of paraffin
-or one of the cements mentioned in a later
-chapter be laid on.</p>
-
-<p>The second electrical connection is made
-by a wire dipping in the tumbler of mercury.</p>
-
-<p><span class="pagenum" id="Page_147">147</span></p>
-
-
-<h3><span class="smcap">Discharges in Vacuo.</span></h3>
-
-<p>In a simple glass tube having two wires
-carrying balls inserted through its ends,
-from which the air has been partially exhausted,
-the study of the changes shown
-by the passage of the spark is extremely
-interesting. Before the commencement
-of exhaustion no luminous effect can be
-discerned; at a low degree of exhaustion
-a luminosity appears between the ends of
-the wires, the negative pole being surrounded
-by a violet glow and a larger
-pear-shaped red discharge from the positive.
-An interval near the negative electrode
-is in darkness, widening as the exhaustion
-progresses. When the degree of
-exhaustion is very high, a series of arches
-concentric with the positive ball appear
-and become broader and more distinct as
-the rarefaction progresses. The arches or
-bands are called striæ, and are most distinct
-when the tube is made in the form of
-a narrow cylinder, with a bulb at each end.<span class="pagenum" id="Page_148">148</span>
-Carbonic acid gas vacua give the best results.
-If the finger be placed on the bulb
-at either end a luminous spot appears, and
-by using a very rapid contact breaker in
-the primary circuit, the luminous discharges
-become highly sensitive, being
-diverted from their regular path on the
-approach of the hand, a magnet, or a
-grounded wire. An extended treatment
-of these phenomena would be out of place
-here, but can be found in nearly all comprehensive
-works on electricity.</p>
-
-<p>If an incandescent-lamp bulb be held in
-the hand and one end be brought near to
-a terminal of the coil, a beautiful bluish
-light appears.<a id="FNanchor_2_2" href="#Footnote_2_2" class="fnanchor">2</a> The carbon filament, if
-long, and not held by its loop, becomes
-electrified and oscillates, often giving out
-a clear, high, bell-like sound as it strikes
-the glass. Particles of carbon deposited
-on the glass during the burning of the
-lamp, shown in daylight as a blackening
-deposit, generally show little sparks, like
-stars scattered over the inside of the globe.</p>
-
-<div class="footnotes">
-<div class="footnote">
-
-<p><a id="Footnote_2_2" href="#FNanchor_2_2" class="label">2</a>
-This depends on the degree of exhaustion.</p></div></div>
-
-<p><span class="pagenum" id="Page_149">149</span></p>
-
-<p>A vacuum tube will phosphoresce if
-held in the hand near a secondary terminal,
-or even if laid on the table near the
-coil, and will light quite brilliantly if one
-end be held against a terminal. This latter
-method, however, is generally inconvenient,
-as a certain amount of physical
-pain ensues from the discharge into the
-skin.</p>
-
-<p>Different gases in the tubes give characteristic
-colors. In carbonic acid gas the
-whitish green hue prevails; in hydrogen,
-white and red; in nitrogen, orange yellow.
-The characteristic spectra are given
-by the gases in the tubes, and can be
-readily examined in the spectroscope.
-But there is sometimes a slight variation
-in these colors, dependent upon changes in
-the current.</p>
-
-<p>In many Geissler tubes, a portion of the
-bulbs is made of uranium glass. On the
-passage of the spark in the tube this glass
-glows with a magnificent emerald green
-hue. Other tubes are constructed with<span class="pagenum" id="Page_150">150</span>
-an outside enveloping glass tube fitted
-with a corked orifice into which can be
-poured different solutions.</p>
-
-<div class="figcenter" ><a id="fig45"></a>
-<img src="images/i_150a.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 45.</span></div>
-</div>
-
-<div class="figcenter" ><a id="fig46"></a>
-<img src="images/i_150b.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 46.</span></div>
-</div>
-
-<div class="figcenter" ><a id="fig47"></a>
-<img src="images/i_150c.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 47.</span></div>
-</div>
-
-<p>Fig. 45 shows a solution tube to be filled
-with solution of sulphate of quinine, etc.</p>
-
-<p>Fig. 46 shows three exhausted tubes arranged
-in series.</p>
-
-<p><span class="pagenum" id="Page_151">151</span></p>
-
-<p><i>A</i> is of uranium glass, and glows dark
-green; <i>B</i> of English glass, showing a blue
-hue, and <i>C</i> of soft German glass, glowing
-with a bright apple-green
-tint.</p>
-
-<div class="figright" ><a id="fig48"></a>
-<img src="images/i_151.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 48.</span></div>
-</div>
-
-<p>Crystals of nitrate
-of calcium, nitrate
-of silver, benzoic
-acid, tungstate of
-calcium, lithia benzoate,
-sodium salicylate,
-zinc sulphide,
-and acetate of zinc
-fluoresce.</p>
-
-<p>Fig. 47 is a highly
-exhausted tube, having
-at its lowest part
-a few pieces of ruby.
-When the secondary
-current is turned on
-at <i>P</i> and <i>N</i> the rubies
-shine with a brilliant rich red, as if they
-were glowing hot.</p>
-
-<p>Fig. 48 shows the tube to exhibit the<span class="pagenum" id="Page_152">152</span>
-effect resulting from focussing the electric
-rays on a piece of iridio-platinum at <i>B</i>.</p>
-
-<p>The cup <i>A</i> forms the negative pole; the
-metal disk <i>C</i>, the positive.</p>
-
-<p>On increasing the intensity of the spark,
-the metal at <i>B</i> glows with extreme brilliancy,
-and melts if the intensity be carried
-too far.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_153">153</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_VIII">CHAPTER VIII.<br />
-
-<small>ROTATING EFFECTS.</small></h2>
-</div>
-
-<p>Although the luminous discharges in
-the exhausted tubes are extremely beautiful,
-yet the effect is indescribably enhanced
-when the tubes are rotated. Gassiot's star
-was the name given to the earliest exhibit
-of a rotating tube carrying a luminous discharge,
-owing to the curious phenomenon
-ensuing from the interruptions of the spark.
-As the human retina is only capable of retaining
-an impression for a fraction of a
-second, and as the tube is only momentarily
-luminous during the passage of the
-spark, the effect of the revolving tube is
-that of a series of such arranged as the
-radii of a circle, the number apparent,
-being governed by the rapidity of rotation
-and the rate of interruption of the current.</p>
-
-<p><span class="pagenum" id="Page_154">154</span></p>
-
-<div class="figcenter" ><a id="fig49"></a>
-<img src="images/i_154.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 49.</span></div>
-</div>
-
-<p>Fig. 49 represents a form of rotating
-wheel which is easily made, and yet susceptible
-of many novel and attractive
-effects. Such a wheel, placed in a store
-window, would undoubtedly attract many
-persons by the beautiful variations of col<span class="pagenum" id="Page_155">155</span>ored
-figures which it presents while in
-motion. And once a crowd is collected
-and its attention attracted to one spot, the
-capabilities of advertising the goods on
-sale are apparent.</p>
-
-<p>A pasteboard or light wooden disk <i>D</i>,
-3 feet in diameter or over, is mounted on
-a shaft, <i>S</i>, operated by an electric motor
-or such power as may be attainable. Upon
-its surface are mounted the tube-holders
-<i>T T T T</i>, connected, as shown, by wires
-leading from the secondary of the Ruhmkorff
-coil. Starting at the shaft <i>S</i>, the circuit
-runs to the first tube-holder, where
-the continuity of the wire is broken to
-allow of the attachment of the vacuum
-tube. From the first tube-holder the wire
-runs in turn to each of the other three
-tube-holders, terminating at <i>R</i>, where it
-passes through a hole to a metal ring on
-the back of the disk shown by the dotted
-circle. This ring and the shaft are in connection
-with the secondary coil, by reason
-of its electrodes being attached to two<span class="pagenum" id="Page_156">156</span>
-brushes or strips of metal pressing, one on
-the ring, the other on the shaft; or the
-bearing in which the shaft turns may displace
-one of the brushes. <i>W W</i> are two
-counterbalance weights, that the wheel
-may run smoothly and be not affected by
-the irregular distribution of the tubes or
-its surface. <i>E E</i> are elastic bands, looped
-over the wire and through rings in the
-disk, that the wires may not be liable to
-touch or short circuit.</p>
-
-<p>At Fig. 50 is an enlarged view of a tube-holder,
-although, as it is meant only as a
-diagram, considerable variation of design
-is permissible. The springs at <i>H H</i>, to
-which the wires run, being bent back, the
-metal pins <i>P P</i> may be thrust through the
-rings on the ends of the tube, and the elasticity
-and pressure of the spring will hold
-it in place and make the necessary contact.
-A wooden block, <i>B</i>, secured to the
-face of the disk, is provided with a thumb-screw,
-<i>S</i>, securing the tube-holder to it,
-by means of which the tube-holders may<span class="pagenum" id="Page_157">157</span>
-be turned a trifle upon their axes and so
-vary the effect of the wheel.</p>
-
-<div class="figcenter" ><a id="fig50"></a>
-<img src="images/i_157.jpg" alt="" />
-<div class="caption"><span class="smcap gap10">Fig. 50.</span> <span class="smcap">Fig. 51.</span></div>
-</div>
-
-<p>Fig. 51 is a side view of the wheel, showing
-one manner of mounting the disk and<span class="pagenum" id="Page_158">158</span>
-its connections. The same figures apply
-to the parts as in the preceding figure.
-<i>M N</i> are the wires leading to the coil, <i>P</i> is
-a pulley on the shaft whereby the rotary
-power may be applied. The wires on the
-face of the disk are not shown, as they
-would impair the clearness of the diagram
-unnecessarily.</p>
-
-<p>The greatest danger in the operation of
-such a piece of apparatus will be the tendency
-of the high tension spark to wander
-where it is not wanted, and to take short
-but forbidden paths back to the coil. However,
-care and perhaps experiment will
-prove the remedy. It will be noticed by
-reference to Fig. 49 that a circle has been
-drawn almost bisecting two of the tube-holders.
-This circle represents a circle of
-danger, and where a thin material has been
-used for the disk, the disk may very well
-be reinforced by a piece of stouter card
-cemented on its face.</p>
-
-<p>The disk, whether of wood or of pasteboard,
-must have a liberal coating of in<span class="pagenum" id="Page_159">159</span>sulation,
-either shellac varnish, paraffin,
-or beeswax, and be absolutely free from
-unnecessary holes. Moreover, the ring <i>R</i>
-must be of such a distance from the support
-<i>F</i>, if the latter be metal, as will preclude
-any jumping of the spark. A Ruhmkorff
-coil giving upward of three quarters
-of an inch of spark will be large enough
-to operate a wheel carrying four 8-inch
-tubes.</p>
-
-<p>The wheel may be set back in a window
-and surrounded by dark fabrics, or built
-in, as it were, in a cave of such. The
-judicious use of pieces of looking-glass scattered
-on the sides of the cave, in such
-manner as to reflect the light of the tubes,
-will enhance the effect. There is no danger
-of fire where ordinary care is used, as
-the <i>long</i> spark necessary to the production
-of the luminosity will hardly ignite anything
-but gas, unless specially arranged to
-do so.</p>
-
-<p>Fig. 52 is a triangle formed of three
-Geissler tubes, and intended for rotation<span class="pagenum" id="Page_160">160</span>
-as a whole. <i>M M</i> are two pieces of mica
-or glass, to prevent any possibility of the
-spark jumping and short circuiting, in
-which event the tubes would fail to light.</p>
-
-<div class="figcenter" ><a id="fig52"></a>
-<img src="images/i_160.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 52.</span></div>
-</div>
-
-<p>This triangle is shown diagrammatically
-at <i>A B C</i>, Fig. 53, mounted on an insulated
-rotating disk. Before commencement of
-rotation, and upon the current being turned
-on to the tubes, a simple triangle will result,
-but at a certain stage of rotation the
-Maltese cross shown is formed. A still
-higher rate of rotation will produce the<span class="pagenum" id="Page_161">161</span>
-double star, Fig. 54, and as the rotation and
-rate of vibration of the coil contact-breaker
-is varied, an apparently endless succession
-of stars or triangles appears to grow out
-into view.</p>
-
-<div class="figleft" ><a id="fig53"></a>
-<img src="images/i_161a.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 53.</span></div>
-</div>
-<div class="figright" ><a id="fig54"></a>
-<img src="images/i_161b.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 54.</span></div>
-</div>
-
-<p>Although Figs. 53 and 54 serve to illustrate
-a triangle of tubes and its variations,
-a very pretty and simple effect can
-be obtained with it as follows: Three
-strips of looking-glass are cut and scratched
-across their silvered surface, as described
-for the luminous pane, Fig. 37. The current
-then being allowed to pass, and the
-wheel being rotated, the triangle acts as<span class="pagenum" id="Page_162">162</span>
-in the preceding paragraphs, multiplying
-and forming figures, which are extremely
-interesting to watch.</p>
-
-<p>While treating on the subject of store-window
-attractions, a few suggestions on
-a display of stationary Geissler tubes may
-be made. Starting with the assumption
-that the platform on which the goods
-would be displayed is of wood, a very
-small amount of preparation is necessary.
-The platform is covered with a dark material
-free from gloss, such as canton flannel,
-on which the tubes are laid in any fancy
-pattern, or may be scattered haphazard.
-Fine bare wire (No. 36 B. &amp; S. is not any
-too small) is run from tube to tube, using
-care that it does not touch itself in such
-manner as to short circuit the current.
-There is not much necessity to cover the
-wires, unless the rate of vibration of the
-contact be so rapid as to show the brush
-discharge from the wire strands. In a
-jewelry store the cylindrical portions of
-the tubes may be covered with strips of<span class="pagenum" id="Page_163">163</span>
-dark cloth, concealing all but the bulbs.
-The Uranium bulbs will resemble emeralds;
-the yellow bulbs, topaz; and the blue,
-turquoise—certainly a very striking collection
-of gems. A few diamond-shaped
-pieces of the foil-coated glass scratched
-across, by the whiteness of the tiny sparks
-will aid to set off the whole. The outfit is
-not expensive: a coil giving a one half inch
-spark will light from four to six tubes to
-great brilliancy. Cloths with metallic
-threads woven in them must not be used,
-nor any of the metallic powders known in
-the trade as "glitters."</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_164">164</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_IX">CHAPTER IX.<br />
-
-<small>GAS LIGHTING.</small></h2>
-</div>
-
-<p>When it is desired to light clusters of
-gas jets situated in inaccessible places, or
-a number of them simultaneously, this
-method finds ready application. It operates
-in the division of a long spark among
-a number of burners, the gas being turned
-on at the main and the primary circuit of a
-Ruhmkorff coil closed and opened until the
-succession of sparks ignites the gas, Fig. 55.
-There are various commercial forms of
-these burners, prominent among which is
-the "Smith jump spark" burner.</p>
-
-<div class="figcenter" ><a id="fig55"></a>
-<img src="images/i_165.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 55.</span></div>
-</div>
-
-<p>A lava tip is provided with a mica or
-isinglass flange midway between the tip
-and the lower end of the burner. This
-flange isolates the electrodes from any possibility
-of the spark straying away to the<span class="pagenum" id="Page_165">165</span>
-metallic pillar in which the burner is inserted.
-The multiple lava tip burner is intended
-for use where a very short burner is
-needed, also for flash rings multiple lights.
-Here the tips are placed close enough together
-to ignite by contagion. In this
-case one of the common tips is removed
-from the ring and a multiple lava tip substituted.
-It is customary to allow sixteen
-burners to one inch of spark. Any num<span class="pagenum" id="Page_166">166</span>ber
-of series can be operated alternately
-by means of a suitable switch.</p>
-
-<p>The wire used to connect the burners is
-generally bare copper, and as small in
-diameter as will sustain its own weight
-without injury, the amount of the current
-being infinitesimal. It is supported on
-porcelain or glass knobs screwed to the
-wall or ceiling, being carefully planned to
-avoid any metallic substances to which
-the spark might be tempted to escape. In
-wiring chandeliers, the wire is run through
-glass tubes wherever there is any liability
-of its coming near the metal pipes. There
-is a very great danger of this jumping of
-the spark where it is not wanted, and the
-utmost care must be taken in planning the
-course the wires shall take. Even a damp
-wall will cause trouble or a gilt cornice,
-although the latter may be entirely insulated
-from the ground. The switch
-bases for the groups of circuits must be of
-hard rubber, and the switch points and
-levers be placed so far apart that there is<span class="pagenum" id="Page_167">167</span>
-no liability of the spark jumping, which
-it certainly will do if it gets a chance.
-Ordinary insulated wires are ineffectually
-protected by the rubber compounds used.
-Glass, mica, and better still, a large air
-gap are the only insulations that will serve,
-for the tremendous potential or voltage of
-the current must be carefully considered
-whenever insulation is necessary. The coil
-is better provided with a spring key in the
-primary circuit than a vibrator, it gives
-better control of the circuit and probably
-a larger and better spark.</p>
-
-
-<h3><span class="smcap">Gas Lighting in Multiple.</span></h3>
-
-<p>The spark which occurs at the contact
-breaker of a Ruhmkorff coil is held in check
-by the condenser; were no condenser used,
-it would possess considerable powers of
-combustion. Using a large primary coil
-and a few cells of open circuit battery, this
-spark is made to pass across the path of
-a gas jet, which it instantly ignites. The<span class="pagenum" id="Page_168">168</span>
-contact breaker consists of a platinum point,
-fixed on the gas tip, and a German silver
-spring, carried on a lever, which latter is
-pulled across the tip so as to make and break
-the circuit at the burner orifice. Some
-burners are provided with a ratchet arrangement,
-by which pulling the lever once turns
-on and lights the gas, pulling again turns
-it off; others require the gas to be turned
-on first.</p>
-
-<div class="figcenter" ><a id="fig56"></a>
-<img src="images/i_169.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 56.</span></div>
-</div>
-
-<p>Reference to Fig. 56 will show the
-connections to two burners <i>P P</i> and an
-automatic burner <i>A</i>, to be described later.
-The coil <i>C</i> is a core of soft iron, about
-¾ inch diameter and eight to ten inches long,
-wound with from two to four pounds of
-magnet wire, Nos. 12 or 14 B &amp; S. One
-side of the battery goes to ground or to the
-gas pipe, thus forming the return circuit.
-The wiring on the fixtures is done with
-No. 20 to 24 B &amp; S gas fixture wire, insulated
-with four windings of silk or cotton.
-This is fastened to the lacquered brass work
-by means of thick shellac varnish, it being<span class="pagenum" id="Page_169">169</span>
-tied on first with thread, which can readily
-be removed when shellac is dry and hard.
-The wire is held on the insulated collar of
-the burner by a small nut and screw, and<span class="pagenum" id="Page_170">170</span>
-great care must be taken to ensure no
-grounding. The setting up of a gas-lighting
-outfit is extremely simple, but it often fails
-for want of care. There must be the best
-possible insulation between wire and metal
-work.</p>
-
-
-<h3><span class="smcap">Automatic Burners.</span></h3>
-
-<p>There are several forms of these burners,
-but the principle of all is the same. A gas
-burner protrudes from the top of a brass
-case which encloses the actuating mechanism.
-This mechanism consists of two
-electromagnets, the armature of one opening
-a valve and allowing the gas to flow, at
-the same time vibrating a platinum-tipped
-rod, which produces a series of sparks at the
-burner tip. These sparks ignite the gas, and
-a second magnet is provided to shut off the
-flow of gas, thus extinguishing the light.
-Some devices use one electromagnet for
-both lighting or extinguishing, but the
-majority are with double magnets. The<span class="pagenum" id="Page_171">171</span>
-circuit is worked from a push button situated
-at any desired location, and having a
-white and black button, one for lighting
-and the other for extinguishing. The principal
-automatic burners are the Holtzer, the
-Boston, and the Bartholdi, between which
-there lies little choice, so admirably are they
-constructed.</p>
-
-
-<h3><span class="smcap">Bartholdi Automatic Burner.</span></h3>
-
-<p>Instead of a rotating stop-cock, as in
-other automatics, a gravity valve is employed
-in the Bartholdi, which is held to its
-seat by the weight of the armature and
-connecting stem, as shown in Fig. 57. When
-the gas is turned off the valve rests upon
-its seat, as indicated in the cut. By a closure
-of the electric circuit at the turn-on button,
-two of the helices <i>M P</i> are energized, causing
-the armature <i>J</i> to be lifted, thus, by
-means of the stem <i>H</i>, raising the valve <i>G</i>
-from its seat into the dotted position, and
-opening the gas way so that the gas may<span class="pagenum" id="Page_172">172</span>
-issue to the tip, as shown by the arrows.
-At the same time, the top of the valve strikes
-against the end of the lever <i>W</i>, causing the
-circuit to be broken at the spark points <i>T U</i>,
-resulting in a continuous sparking as long
-as the finger presses the button. The magnet<span class="pagenum" id="Page_173">173</span>
-when raising the armature has also twisted
-or partially revolved it, so as to bring the
-notch <i>d</i> in the armature over the end of the
-hook <i>e</i>, as shown in dotted lines. When
-the circuit is broken by lifting the finger
-from the button the notch falls into the
-hook and the valve is locked open.</p>
-
-<div class="figcenter" ><a id="fig57"></a>
-<img src="images/i_172.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 57.</span></div>
-</div>
-<p>To extinguish the flame the turn-off
-button is pressed, when a second magnet
-(not shown in cut) lifts the armature
-and twists it in the opposite direction, so
-that when the circuit is broken the armature
-falls free to its normal position, closing the
-valve.</p>
-
-<div class="figcenter" ><a id="fig58"></a>
-<img src="images/i_174.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 58.</span></div>
-</div>
-
-<p>In wiring up an automatic burner it is
-necessary to run two wires to it, one from
-the white button and another from black
-button on push plate <i>S</i>. Reference to Fig. 58
-will make this clear. Most burners are
-provided with two binding posts inside the
-brass case, and the wires are run through
-a rubber-bushed hole in the base. If the
-push has already been set in position and
-wired up, as per Fig. 58, have the buttons<span class="pagenum" id="Page_174">174</span>
-pressed alternately, when on touching the
-binding posts on automatic with the wires,
-the lighting or extinguishing connection is<span class="pagenum" id="Page_175">175</span>
-easily selected. The lighting armature in
-most automatic burners buzzes violently,
-while the extinguishing one only strikes once
-on contact being made. Fig. 58 shows how
-to connect up two pushes to one automatic,
-one push, perhaps, being located downstairs
-and the other upstairs in the case of a
-hall lamp. In setting up these burners care
-must be taken not to bend contacts or
-alter adjustment, and absolute precaution
-is necessary that no crosses or weakly insulated
-places are in circuit. After burning
-for some time it often happens that the
-burner refuses to light, only buzzing feebly
-or not at all. If feebly, the trouble is in
-battery, which should consist of, at least,
-four or six cells of open circuit battery with
-low internal resistance, such as Samson-Law
-carbon cylinder, or for occasional use large,
-dry cells.</p>
-
-<p>If no click is heard on pressing white
-button, examine all connections; if still no
-trouble is found, examine the platinum
-break. The platinum tip may be bent<span class="pagenum" id="Page_176">176</span>
-by the continual hammering against the
-platinum tip on vibrating rod, preventing
-contact on collar, or that soot has formed
-there. These are the commonest maladies
-of automatic burners, and can be easily
-remedied by readjusting platinum tip and
-cleaning. Contacts here must be clean. In
-general wiring use waterproof office wire or,
-better still, rubber-covered wire; for fixtures
-use the fixture wire before described. When
-shellacking the wire to the fixture don't
-attempt to connect up batteries until the
-shellac is dry and hard, say for half a day.
-Electric gas-lighting is fruitful of trouble
-if the work is not well done. Another cause
-of trouble may arise from a dirty burner not
-allowing the gas to strike near the contact
-(clean the burner), or the collar carrying
-contact may have shifted, perhaps short-circuited;
-it should be insulated with a thin
-strip of asbestos. Although white lead at
-the joints makes a fairly good contact, some
-persons prefer to use tin-foil, a piece of foil
-being worked around screw thread and the<span class="pagenum" id="Page_177">177</span>
-burner screwed on; it prevents leaks as well
-as lead if well done, and makes better contact.
-As a short circuit on the wires will
-cause all the burners to fail, many devices
-have been invented to open the circuit upon
-such an occurrence. These will be found described
-in the catalogues of electrical stores;
-they do not come within the province of this
-book for description.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_178">178</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_X">CHAPTER X.<br />
-
-<small>BATTERIES FOR COILS.</small></h2>
-</div>
-
-<p>In selecting a battery to operate the
-coil, one is needed which will supply a
-large steady current for a considerable
-period. Although the primary circuit is
-opened and closed rapidly, yet the class
-known as open circuit cells is not suitable,
-even though they have a low internal resistance,
-and thereby render a large current.
-Such cells are only suitable for the
-uses for which they are mostly designed,
-bell-ringing or annunciator work. There
-is one case, however, where an open circuit
-cell may be used with an induction
-coil, and that is in gas lighting as previously
-described; but here a dozen or so
-impulses of current are generally sufficient,
-followed by long periods of rest. For the<span class="pagenum" id="Page_179">179</span>
-latter work the cells in common use are
-the Samson, Champion, and Monarch, all
-of which are of low internal resistance and
-great recuperative power.</p>
-
-<p>The reason that such cells will not work
-for long periods, is that they polarize.
-This latter action takes place in these open
-circuit cells, which are of the Leclanché
-type as follows: A positive plate of zinc
-is immersed in a solution of ammonium
-chloride (or salammoniac), and a negative
-plate of carbon and peroxide of manganese,
-contained either in a porous cup or
-compressed into a block also stands in the
-solution. Care is taken that these two
-plates do not touch each other. When the
-outside circuit is closed the zinc combines
-with the chlorine of the solution liberating
-free hydrogen and ammonia. The hydrogen
-appears at the negative plate, where
-it is acted upon by the oxygen of the peroxide
-of manganese to form water.</p>
-
-<p>But when the circuit is of too low resistance,
-the oxidizing action of the peroxide<span class="pagenum" id="Page_180">180</span>
-of manganese is not rapid enough, and a
-film of hydrogen, which is a poor conductor,
-forms over the negative plate, increasing
-the internal resistance of the cell and
-setting up local action.
-In the best class of these
-open circuit cells, this
-hydrogen is absorbed
-after a rest, and the battery
-recuperates and is
-ready for work again.
-The circuit of the Ruhmkorff
-coil is low, and
-this polarization always
-occurs a few minutes
-after the contact-breaker
-is started.</p>
-
-<div class="figleft" ><a id="fig59"></a>
-<img src="images/i_180.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 59.</span></div>
-</div>
-
-<p>In the class of closed
-circuit cells, chosen for
-the present purpose, the Grenet or bottle
-bichromate is one of the handiest
-for occasional use. A glass bottle-shaped
-jar, <i>J</i>, Fig. 59, is provided with a hard
-rubber cap, <i>G</i>, on which are mounted the<span class="pagenum" id="Page_181">181</span>
-binding posts <i>A B</i>. To the underside of
-this cap are attached two carbon plates
-<i>C C</i>, which reach nearly to the bottom of
-the jar, being connected together on the
-cap by a varnished copper strip, the latter
-being in turn connected to one binding
-post. Through the centre of the cap
-passes a brass rod, <i>R</i>, having attached to
-its lower end a piece of sheet zinc, <i>Z</i>, well
-amalgamated with mercury. This process
-of amalgamation consists in cleaning the
-zinc, then rubbing its surface with a rag
-dipped in dilute sulphuric acid, and pouring
-a few drops of mercury on the wet
-zinc. The mercury will spread readily
-over the zinc, provided it has been well
-cleaned, and if properly done should give
-the zinc plate a bright, shining appearance.</p>
-
-<p>When the cell is not in use, the zinc is
-drawn up into the neck of the bottle and
-clamped by a set screw against the brass
-rod. A copper spring pressing on the rod
-serves to carry the current to the second
-binding post.</p>
-
-<p><span class="pagenum" id="Page_182">182</span></p>
-
-<p>This cell originated in France, whence
-its name, but a cheaper form is now made
-in the United States known as the Novelty
-Grenet. The shape of the jar is somewhat
-different, and the carbon is moulded,
-whereas the French carbon is sawed from
-the carbon deposited in the gas retort;
-but the American form is practically of as
-great utility as the French, and the cost
-recommends it.</p>
-
-<p>The bichromate solutions are affected by
-light, and deteriorate less it kept in stoneware
-jugs. The Grenet battery can very
-well be fitted into a neat wood case, which
-will serve the further purpose of preventing
-chance knocks from fracturing the
-glass jar.</p>
-
-<p>Carbons which are used in batteries containing
-the foregoing solution should be
-well washed in warm water whenever the
-solution is changed, and especially when
-it is intended to put the battery out of
-active service. When the solution acquires
-a decidedly green hue it should be re<span class="pagenum" id="Page_183">183</span>placed
-with fresh. The electromotive
-force of this cell varies from 1.90 to 2
-volts, and the amperage is dependent on
-the size of the plates, running from 5 amperes
-upward.</p>
-
-<p>The glass jar is filled up to the commencement
-of the neck with a solution of
-bichromate of potash or sodium, called
-electropoion fluid, and prepared as follows:
-To 1 gallon of water add 1 pound
-of bichromate of sodium, mixing in a stoneware
-vessel. When dissolved add 3 pounds
-of sulphuric acid in a thin stream, stirring
-slowly. As the mixture heats on the introduction
-of the acid, care must be used
-to pour in the latter slowly. This solution
-should not be used until quite cold.</p>
-
-<p>The sodium salt is preferable to the
-potassium, owing to its not forming the
-crystals of chrome alum, and also on account
-of its lower cost and greater solubility,
-the latter being four times greater
-than that of the potassium salt. The commercial
-acid used should contain at least<span class="pagenum" id="Page_184">184</span>
-90 per cent pure acid and should be free
-from impurities. On filling the battery
-use utmost care not to splash the solution
-on any of the metal work, or it will cause
-corrosion. Although the salts in the solution
-will most likely make a stain, the corrosive
-action of the acid can be arrested
-if the solution be
-splashed on the
-clothes by the prompt
-application of ammonia
-solution.</p>
-
-<div class="figleft" ><a id="fig60"></a>
-<img src="images/i_184.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 60.</span></div>
-</div>
-
-<p>The "Fuller" cell,
-Fig. 60, which is another
-type of the bichromate
-cell, is one
-from which a steady
-current can be obtained for a longer interval
-than from the Grenet, but the current
-is less. The electromotive force is
-the same, but the current is only 3 amperes,
-except in certain modifications.</p>
-
-<p>In the porous cup is a cone-shaped zinc
-having a stout copper wire cast in. This<span class="pagenum" id="Page_185">185</span>
-wire is occasionally covered with rubber
-insulation, but, as a rule, is bare. The
-porous cup is of unglazed porcelain, thick,
-but very porous. This sets in the glass
-jar, a wooden cover fitting <i>loosely</i> over the
-whole to exclude dust. Through this
-cover passes the wire leading from the
-zinc, and also the carbon plate carrying a
-machine screw and check nuts for connection.
-The cover is dipped in melted paraffin,
-as is also the upper end of the carbon
-and the rim of the glass jar. This is to
-prevent the creeping of the salts in the
-solutions and the corrosion of the brass
-work.</p>
-
-<p>Into the porous cup is poured a solution
-composed of 18 parts by weight of common
-salt and 72 parts by weight of water.
-Electropoion fluid is held by the glass jar,
-the two solutions reaching a level of two
-thirds the height of the jar. One ounce
-of mercury is added to the porous cup
-solution to ensure the complete and continuous
-amalgamation of the zinc. The<span class="pagenum" id="Page_186">186</span>
-salt can be more readily dissolved in warm
-water, but <i>all</i> solutions must be used <i>cold</i>.
-It is not always necessary to renew the
-solutions when the battery fails to give
-out its accustomed strength, but several
-ounces of water can be substituted for a
-similar amount of fluid in the porous cup.
-Stir the solution by moving the zinc up
-and down, and a temporary improvement
-will be noticed.</p>
-
-<p>To obtain a greater current from this
-cell, use a larger zinc, such as a well-amalgamated
-zinc plate, and add a teaspoonful
-of sulphuric acid to clean water for the
-porous cup solution. Additional carbon
-plates connected together and placed
-round the porous cup will lower the resistance
-of the cell and increase the current,
-and also tend to keep down the polarization.</p>
-
-<p>A new form of this battery was described
-by M. Morisot a short time ago.</p>
-
-<p>The positive pole is of retort carbon in
-the outer cell in a depolarizing mixture<span class="pagenum" id="Page_187">187</span>
-made of 1 part sulphuric acid, 3 parts saturated
-solution bichromate of potash, crystals
-of the latter salt being suspended in
-the cell to keep up the saturation. A porous
-cup contains a solution of caustic soda.
-The zinc is in a second porous cup placed
-within the first, which holds a caustic soda
-solution of greater density. The electromotive
-force is 2½ volts when the cell is
-first placed in circuit, and will remain at
-2.4 for some hours. The internal resistance
-is low, but varies with the thickness
-of the porous cups. This cell is not suitable
-for any but use for a few hours at one
-time.</p>
-
-<p>The Dun cell has a negative electrode of
-a carbon porous cup filled with broken
-carbon. The zinc is in the form of a heavy
-ring, and hangs at the top of the solution
-in the outer jar. Permanganate of potash
-crystals are placed in the porous cup, and
-the entire cell filled with a solution of caustic
-potash 1 part to water 5 parts. The
-voltage is 1.8, and the internal resist<span class="pagenum" id="Page_188">188</span>ance
-being low the resultant current is
-large.</p>
-
-<p>A cell with an electrode of aluminum in
-a solution of caustic potash and carbon in
-strong nitric acid in porous cup is claimed
-to have an electromotive force of 2.8, but
-the nitric acid is not a desirable acid to
-handle.</p>
-
-<p>Metallic magnesium in a salammoniac
-solution with a copper plate in a hydrochloric
-acid and sulphate of copper mixture
-is of high voltage, nearly 3 volts
-being obtained, and the current is large,
-but it is a new combination and has not as
-yet stood the test of time.</p>
-
-<p>There are other formulæ for solutions to
-be used in Fuller or Grenet cells which
-may be useful to the experimenter.
-Trouvé's is as follows: Water, 36 parts;
-bichromate of potash, 3 parts; sulphuric
-acid, 15 parts, all by weight. Bottone's:
-Chromic acid, 6 parts; water, 20 parts;
-chlorate of potassium (increases electromotive
-force), ⅓ part; sulphuric acid, 3<span class="pagenum" id="Page_189">189</span>½
-parts, all by weight. A convenient "red
-salt" or "electric sand": Sulphate of
-soda, 14 parts; sulphuric acid, 68 parts;
-bichromate of potash, 29 parts; soda dissolved
-in heated acid, and potash stirred
-in slowly. When cold can be broken up
-and prepared when required by dissolving
-in five times its weight of water.</p>
-
-<p>The chromic acid used in Bottone's solution
-is very soluble in water, it being possible
-to dissolve five or six times the
-amount in the same quantity of water as
-of bichromate of potash. The simple solution
-of chromic acid is 1 pound to 1 pint
-of water, to which is added 6 ounces of
-sulphuric acid.</p>
-
-<p>When it becomes necessary to cut zinc
-plates, it may be readily done by making a
-deep scratch on the surface, filling the
-scratch first with dilute sulphuric acid,
-and then with mercury. The mercury
-will quickly eat into the metal, and the
-plate may be easily broken across or cut
-with a saw. Zinc plates can be bent into<span class="pagenum" id="Page_190">190</span>
-shape by the application of heat. Hold
-the plate in front of a hot fire until it cannot
-be touched by the bare hand: it will
-be found that it has softened so that it can
-be bent around a suitable wooden form.
-As zinc plates are most attacked at the
-surface of the acid solution, it is advisable
-to coat the extreme upper portion of them
-with varnish or paraffin. Rolled zinc is
-always preferable to cast, especially so
-when immersed in acid solutions.</p>
-
-<p>To avoid confusion, it may be stated
-here that it is the rule to speak of the zinc
-element as the positive plate and the negative
-electrode or pole, and the carbon <i>vice
-versa</i>. The portion of the element immersed
-in the solution is the plate, the part
-outside, the pole or electrode. In diagrams
-and also in formulæ positive is
-shown by a + (plus) sign and negative by
-a-(minus) sign.</p>
-
-<p>The relation of cost of the materials most
-used is shown in the subjoined table, which
-cost, however, varies with the market:</p>
-
-<p><span class="pagenum" id="Page_191">191</span></p>
-
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td align="left">Sulphuric acid, chemically pure</td>
- <td align="left">18</td>
-</tr>
-<tr>
- <td align="left"><span class="ditto">"</span><span class="ditto">"</span>commercial</td>
- <td align="left">1.5</td>
-</tr>
-<tr>
- <td align="left">Muriatic<span class="ditto">"</span></td>
- <td align="left">1.12</td>
-</tr>
-<tr>
- <td align="left">Nitric <span class="ditto">"</span></td>
- <td align="left">3.5</td>
-</tr>
-<tr>
- <td align="left">Electropoion fluid</td>
- <td align="left">2</td>
-</tr>
-<tr>
- <td align="left">Bichromate of potash</td>
- <td align="left">10.5</td>
-</tr>
-<tr>
- <td align="left"><span class="ditto">"</span><span class="ditto">"</span>soda</td>
- <td align="left">8.5</td>
-</tr>
-<tr>
- <td align="left">Caustic soda</td>
- <td align="left">9</td>
-</tr>
-<tr>
- <td align="left">Salammoniac</td>
- <td align="left">7</td>
-</tr>
-<tr>
- <td align="left">Chromic acid</td>
- <td align="left">19</td>
-</tr>
-<tr>
- <td align="left">Blue vitriol</td>
- <td align="left">4</td>
-</tr>
-<tr>
- <td align="left">Litharge</td>
- <td align="left">5.75</td>
-</tr>
-<tr>
- <td align="left">Mercury bisulphate</td>
- <td align="left">94</td>
-</tr>
-<tr>
- <td align="left">Paraffin</td>
- <td align="left">9</td>
-</tr>
-<tr>
- <td align="left">Beeswax</td>
- <td align="left">35 to 45</td>
-</tr>
-<tr>
- <td align="left">Shellac varnish</td>
- <td align="left">87</td>
-</tr>
-<tr>
- <td align="left">Tinfoil</td>
- <td align="left">35</td>
-</tr>
-</table></div>
-
-
-<h3><span class="smcap">Gravity Battery.</span></h3>
-
-<p>A cheap modification of the Daniell cell.
-A glass jar has at the bottom a copper
-plate consisting of 4 to 6 leaves of thin
-sheet copper, set on their edges in a starlike
-shape, a copper wire being attached
-to the copper rivet which holds the leaves
-together. A mass of crystals of sulphate
-of copper is filled in and laid on the top of<span class="pagenum" id="Page_192">192</span>
-the copper electrode an inch or so above
-its top. The negative plate is a variously
-shaped plate of cast zinc hung from the
-edge of the jar and reaching about 2 inches
-from the top into the fluid. Water is
-poured in until it covers the zinc, and the
-battery is complete. The sulphate of copper
-deposits its metallic copper on the
-copper leaves and liberates sulphuric acid,
-which rises and attacks the zinc, setting
-free sulphate of zinc. The sulphate of
-zinc solution being of greater density remains
-near the bottom, and the sulphate
-of zinc solution stays near the zinc. When
-the cell is left too long on an open circuit
-the two solutions tend to mix, and copper
-is deposited on the zinc. The sulphate of
-zinc finally saturates the top solution,
-which has to be partly drawn off and replaced
-by fresh water and crystals of sulphate
-of copper dropped into the jar to
-take the place of that which has been decomposed.
-Electromotive force 1 volt,
-current from <sup>3</sup>∕<sub>10</sub> to <sup>5</sup>∕<sub>10</sub> of an ampere. The<span class="pagenum" id="Page_193">193</span>
-practical working of this cell will be treated
-of later on in these pages.</p>
-
-<div class="figright" ><a id="fig61"></a>
-<img src="images/i_193.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 61.</span></div>
-</div>
-
-<p>The Gethins (Fig. 61) and the Hussey
-bluestone cells both have the zincs standing
-in porous cups (shown by dotted lines),
-which in turn are supported
-half-way down the
-jar, generally resting on
-the copper strip acting as
-a porous partition between
-the fluids. The
-zinc stands in a solution
-of zinc sulphate, or a weak
-sulphuric acid solution.
-The internal resistance is
-low, and the current large,
-being from 1 to 5 amperes.
-These cells are the
-ideal bluestone cells for charging storage
-batteries requiring very little attention.
-The special Gethins cell shown in the figure
-has the copper made with a collar,
-which encircles the porous cup, and thereby
-lowers the internal resistance of the<span class="pagenum" id="Page_194">194</span>
-battery. The voltage not being over 1 volt,
-however, renders these cells hardly suitable
-for direct connection. Five cells connected
-in multiple would give all of 10 amperes of
-current, and 1 volt, and a number of these
-multiple groups could be connected in series
-for a higher voltage.</p>
-
-
-<h3><span class="smcap">Gordon Battery</span></h3>
-
-<p>is similar in operation to the Edison-Lalande,
-but differs in details of construction. The
-zinc is a heavy ring suspended outside, but
-not touching a perforated tin cylinder closed
-at the bottom, containing the oxide of copper
-in flakes. Its internal resistance is slightly
-higher than the Edison-Lalande cell, otherwise
-there is little choice. The 6 × 8 size
-is excellent for coil work, giving 250 actual
-ampere hours and remaining on open circuit
-for long periods without deterioration.</p>
-
-<p><span class="pagenum" id="Page_195">195</span></p>
-
-
-<h3><span class="smcap">Edison-Lalande Cell.</span></h3>
-
-<p>This is a practical form of the old
-Lalande-Chaperon cell, and gives a steady,
-large current, being of low internal resistance,
-but is of low electromotive force, being
-less than .70 volt on closed circuit of medium
-resistance. Being of low internal resistance,
-however, its output is large—three cells of
-the type <i>S</i>; internal resistance, 0.025 ohm.
-Capacity, 300 ampere hours, will about equal
-one cell type E 5 of the Chloride Storage
-Battery. The elements of this cell consist
-of positive plates of amalgamated zinc, suspended
-on each side of negative plates of
-the black oxide of copper in an electrolyte
-solution of caustic potash. In action the
-decomposition of water forms an oxide of
-zinc from the positive element, which with
-the potash in combination leaves a soluble
-salt of zinc and potash. The hydrogen of
-the water acts on the oxide plates to form
-metallic copper, thus really reducing, instead
-of increasing, the internal resistance of<span class="pagenum" id="Page_196">196</span>
-the cell. A layer of heavy paraffin oil is
-poured on top of the solution to prevent the
-action of air.</p>
-
-
-<h3><span class="smcap">New Standard</span>,</h3>
-
-<p>or Roche dry cell. This cell possesses
-remarkable recuperative powers and low
-internal resistance. Made in many sizes, the
-best suited for medical coils is No. 2; dimensions,
-5<sup>7</sup>∕<sub>8</sub> × 2<sup>7</sup>∕<sub>16</sub> inches. For heavier work
-the No. 5, 6 × 2<sup>9</sup>∕<sub>16</sub> inches, and known as
-the Navy Standard, is recommended. A
-convenient size for portable medical coils is
-No. 3, 3¾ × 1⅞ inches, taking up very little
-room, yet giving a large output. Two of
-these latter cells enclosed in the coil case
-will give with a suitably wound primary
-(No. 18 to 20 B &amp; S) as strong a current
-as can be used in electrotherapy. For
-Ruhmkorff coils cells Nos. 6 and 7 (6 × 3
-inches and 7 × 3 inches) furnish a most
-desirable battery for all work not needing
-the constant operation of the contact breaker,<span class="pagenum" id="Page_197">197</span>
-such as wireless telegraphy, gas-lighting,
-etc. They will do service on X-ray work,
-but the writer prefers a storage cell or the
-copper oxide types. The E. M. F. of the
-above cells is one and six-tenths volts, and
-current from 9 amperes to the No. 7 size,
-which gives 24 amperes on short circuit.</p>
-
-
-<h3><span class="smcap">Dry-Cell Construction.</span></h3>
-
-<p>As a matter of practice, there is no really
-dry cell; all so-called cells contain liquid
-held in suspension, and their output is
-limited to the amount of fluid. One of this
-type can easily be made in the following
-manner: A containing jar is made up of
-first-quality sheet zinc, the edges being
-joined by a turned seam and then soldered,
-the bottom of zinc being also soldered in.
-In soldering here, as actually in all such
-operations, be <i>absolutely sure</i> the edges of
-the metal are clean. The jar is partially filled
-with the following composition: Oxide of
-zinc, 1 part; sal ammoniac, 1 part; plaster<span class="pagenum" id="Page_198">198</span>
-of paris, 3 parts; chloride of zinc, 1 part;
-water, 2 parts, all by weight; or sal ammoniac,
-1 part; chloride of calcium, 5 parts;
-calcined magnesia, 5 parts; water, 2 parts,
-or enough water to make a thin paste. A
-brass binding post is soldered to the zinc
-case and a carbon plate having a binding
-post is inserted in the centre of the cell, care
-being taken that it does not touch the zinc.
-A small disc of wood laid in the bottom of
-the cell will prevent contact at the bottom.
-Molten pitch or a composition of pitch and
-rosin in the proportion of 6 to 1 is poured
-on top, so as to seal the cell. As gas is
-generated in the cell, a safety valve should
-be provided, either a piece of porous cane
-or a short length of hard rubber tube, inside
-of which have been placed a few strands of
-woollen thread. This class of cell is so
-cheap and so many forms are available for
-choice that it is rarely desirable to make
-one's own. They will not do for steady
-current, but only for intermittent work. The
-large sizes being of low internal resistance,<span class="pagenum" id="Page_199">199</span>
-can be used for signalling in wireless telegraphy,
-where it is not possible to use wet
-(or free fluid) cells. The principal dry cells
-on the market are the Mesco, the O. K., the
-Nungesser, and the Samson semi-dry cell.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_200">200</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_XI">CHAPTER XI.<br />
-
-<small>STORAGE OR SECONDARY CELL.</small></h2>
-</div>
-
-<p>The development of the storage or secondary
-cell has been one of the most important
-electrical advances of the century.
-For purposes of experiment or work, where
-a large or steady current is required from
-compact and readily tended apparatus,
-the storage cell proves its utility. The
-simplest form was that used by the early
-experimenters, and as it is easy to make,
-a form of it may very well be described.</p>
-
-
-<div class="figcenter" ><a id="fig62"></a>
-<img src="images/i_201.jpg" alt="" />
-<div class="caption"><span class="smcap gap10">Fig. 62.</span> <span class="smcap">Fig. 63.</span></div>
-</div>
-
-<p>From a sheet of lead ⅛ inch thick two or
-more pieces are cut of the requisite size,
-say, 5 inches square. In making these
-plates, they should be cut so as to leave a
-strip 1 inch wide and 3 inches long, projecting
-from one corner, <i>A</i> (Fig. 62), for
-the purpose of connection. This is for<span class="pagenum" id="Page_201">201</span>
-the reason that the fumes of the sulphuric
-acid solution would quickly corrode any
-wires or screws in the plates, and also to
-give a better connection. The number of
-plates cut must be an odd one, as it is
-general to make the two outside plates of
-the same polarity—viz., negative. These
-plates are then scored with a steel point
-across and across on both sides to perhaps
-a depth of <sup>1</sup>∕<sub>64</sub> of an inch. This scoring is
-not absolutely necessary; it somewhat
-hastens the formation of the plates. The<span class="pagenum" id="Page_202">202</span>
-plates are then laid face to face, being
-separated by pieces of wood, rubber, or,
-still better, by a piece of grooved wood,
-Fig. 63 having a thin piece of asbestos on
-each side. These grooves are to carry off
-the gas, and should run up and down the
-board, as in the figure. The wood is ⅛ of
-an inch thick or thereabouts, and preferably
-perforated with holes ¼ of an inch or
-larger. When laid together, a few strong
-rubber bands hold the plates from coming
-apart. To prevent lateral motion, a few
-rubber pins may be thrust through the
-plates. The alternate strips are to be connected
-together in two series, as in a condenser,
-and the complete series placed in
-a jar containing a mixture of seven parts
-of water to one of sulphuric acid. The
-terminal of the strips connected to the
-smallest number of plates is to be marked
-<i>P</i> or +, for positive.</p>
-
-<p>This terminal is now to be connected to
-a charging current (not over 1 ampere), as
-described in the directions for charging<span class="pagenum" id="Page_203">203</span>
-batteries, for eight hours, and then discharged
-at a rate not over 1 ampere for
-six hours. Then the connections are to
-be reversed and the cell charged backward,
-as it were, and discharged. This
-has to be repeated for a long period, perhaps
-a month, before the cell is in good
-condition; on the final charge it is to be
-connected positive to positive of charging
-source. This operation is called "forming,"
-and the result is to change the metallic
-lead of the positive plate into red-brown
-peroxide of lead, and the lead negative
-plates into spongy lead.</p>
-
-<p>In modern commercial cells this operation
-is no longer pursued, the plates are
-variously constructed of lead frameworks
-holding plugs of litharge or lead oxide,
-which is "formed" with great facility.
-For many purposes other than operating
-Ruhmkorff coils, a few simple cells made,
-as described, are handy to have and easy
-to make. In sealing the cells up for portability,
-care must always be taken to leave<span class="pagenum" id="Page_204">204</span>
-a small hole in the cover for the escape of
-the sulphurous acid gas.</p>
-
-
-<h3><span class="smcap">Charging Storage Batteries.</span></h3>
-
-<p>Although the charging of a storage or
-secondary battery is by no means a difficult
-operation, yet it requires care, and
-one unaccustomed to the work will meet
-many slight difficulties which may seriously
-affect the results. Pre-eminently the
-best charging source is a direct current,
-constant potential electric-light circuit.
-The amount of current required varies according
-to the type and make of the cell,
-but we will select one of a capacity of 50
-ampere hours for illustration.</p>
-
-<p>By 50 ampere hours is meant a delivery
-of 1 ampere per hour for fifty hours, or a
-rate of discharge equal to the above, as
-2 amperes per hour for twenty-five hours.
-In practice a secondary cell will not be
-found to act exactly as above, the total
-amount of current decreasing as the discharge
-is greater. Each cell is constructed<span class="pagenum" id="Page_205">205</span>
-to discharge at a certain rate, above which
-it is not safe to go. Five amperes per
-hour is a suitable rate for a fifty-hour cell,
-and should not be greatly exceeded. The
-Chloride type, however, is one which can
-be discharged at a higher rate than normal
-without any serious results, the latter
-being generally a bulging or "buckling,"
-as it is called, of the plates whereby they
-short circuit or fall apart. The voltage of
-the charging source should be at least 10
-per cent over that of the battery when
-fully charged. The voltage of a cell of
-storage battery varies from about 2.3 at
-commencement of discharge to 1.7, at
-which latter voltage discharge must be
-stopped and charging recommenced.</p>
-
-<p>Fig. 64 shows the connections to charge
-a storage battery from an electric-light circuit.
-The latter must be direct current
-and of low tension. The circuit from the
-negative lead runs to the rheostat handle
-<i>R</i>, thence through as many coils as are in
-circuit (varied by moving the handle over<span class="pagenum" id="Page_206">206</span>
-the contact pieces in connection with the
-resistance coils). The positive of the cell is
-connected to the positive main.</p>
-
-<p>In connecting storage cells to the mains
-the utmost care must be taken that the terminals
-are correctly attached. It happens in
-isolated plants that some change is made in
-the wiring or the switchboard, which reverses
-the current without warning being
-given to the battery charger. It is the
-safest way to test the polarity of the terminals
-of <i>both</i> battery and mains each time
-charging is commenced. For polarity tests
-see Chapter I. It is immaterial on which
-side of the battery the rheostat or similar
-device is placed.</p>
-
-<div class="figcenter" ><a id="fig64"></a>
-<img src="images/i_207a.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 64.</span></div>
-</div>
-
-<div class="figcenter" ><a id="fig65"></a>
-<img src="images/i_207b.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 65.</span></div>
-</div>
-
-<p>Fig. 65 shows the employment of lamps
-instead of the rheostat. The lamps <i>L L</i>
-regulate the current flow by the manner
-in which the circuit is arranged. If only
-one lamp be turned on, the current necessary
-for only one lamp circulates through<span class="pagenum" id="Page_207">207</span>
-the battery. Each additional lighted lamp<span class="pagenum" id="Page_208">208</span>
-adds to the current by decreasing the resistance
-of the circuit. <i>S</i> is a switch which
-must always be left open when the dynamos
-are to be stopped.</p>
-
-
-<h3><span class="smcap">Charging from Primary Battery.</span></h3>
-
-<p>In many instances an electric-light circuit
-is not available for charging purposes,
-in which event recourse must be made to
-a primary battery. The one most suited
-for the work is the modified Daniell, or
-copper and zinc combination in solutions
-of sulphate of copper (bluestone) and sulphate
-of zinc respectively.</p>
-
-<p>There are many good forms of this cell
-on the market, chief of which are the simple
-gravity, the Gethins, and the Hussey,
-which have been previously described.
-An example will now be described of the
-operations necessary with the gravity cell,
-charging one 50-ampere hour storage cell.
-At least six cells of gravity will be required,
-as the voltage of each cell is never<span class="pagenum" id="Page_209">209</span>
-over 1 volt, and is dependent on the resistance
-in the external circuit falling as the
-resistance is lowered. Place the six clean
-glass jars on a firm foundation, where there
-is no liability of shaking and no dust likely
-to settle. Unfold the copper strips into
-the form of a star, bending the corners for
-half an inch so as to give an anchorage in
-the bluestone. Place them into the bottom
-of the jars and pour in water enough
-to cover them at least 3 inches below the
-surface. Now carefully drop in 4 pounds
-of clean bluestone, which will fill in the
-angles between the copper wings, at the
-same time holding the element down to
-the bottom of the jar. Hang the zincs
-from the top edge of the jar, and fill up
-with water to 1 inch from the top. The
-addition of 5 ounces of sulphate of zinc
-per cell will render the cells immediately
-available, and for the further hastening of
-the chemical action, the copper wire from
-each copper may be inserted in the binding
-post-hole of the zinc belonging to its<span class="pagenum" id="Page_210">210</span>
-own cell and screwed tight for a few
-hours; or the cells may be connected together
-in series, and the wire from the last
-copper be screwed to the zinc of the first,
-thus putting the whole series on short circuit.
-The only advantage of the first
-method being a saving of time when a
-number of cells is being set up. This saving
-of time is often of consequence, as the
-longer the newly set-up cell is on open
-circuit, the more copper will be deposited
-on the zinc, which is highly undesirable.
-This is shown by the blackening of the
-zinc as soon as it is put in the solution,
-which blackening it is hard to prevent entirely.
-When the cell is working satisfactorily
-it will show a clearly defined line
-between the colorless solution above and
-the deep blue solution beneath.</p>
-
-<p>Gravity cells should never be moved.
-If no sulphate of zinc is available, half a
-teaspoonful of sulphuric acid may be
-poured in over the zinc, which will tend
-to form the sulphate of zinc. Without<span class="pagenum" id="Page_211">211</span>
-any of these helps the cell will take at
-least twenty-four hours on a short circuit
-before it will give its normal current. This
-current should be from <sup>4</sup>∕<sub>10</sub> to <sup>5</sup>∕<sub>10</sub> of an
-ampere. Five cells set up by the writer
-varied after the addition of the
-zinc sulphate from 200 milli-amperes
-(thousandths of an ampere)
-to 300 milli-amperes, although
-they were apparently
-all set up alike; but after twelve
-hours' short circuiting they all
-gave a fairly uniform current of
-from 470 to 500 milli-amperes.</p>
-
-<div class="figright" ><a id="fig66"></a>
-<img src="images/i_211.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 66.</span></div>
-</div>
-<p>From time to time on storage
-battery work, say, every week,
-the specific gravity of the top
-solution must be tested with a
-hydrometer (see Fig. 66), which
-should be put into the solution and allowed
-to come to rest. The indicated number at
-the level of the liquid should be 25°. If
-the number is higher some solution should
-be drawn off and clear water added, until<span class="pagenum" id="Page_212">212</span>
-the hydrometer settles down to 25° or
-thereabouts. The inside of the glass jar
-for 1 inch from the top may be greased to
-prevent the salts of zinc creeping over the
-edge, or half an inch of heavy paraffin oil
-be poured on the top to prevent evaporation
-and creeping. When the zinc gets
-very much coated with the dark deposit it
-must be taken out and scraped and washed.
-When the bluestone needs replenishing,
-drop in carefully and be sure none lodges
-on the zinc element.</p>
-
-
-<h3><span class="smcap">Setting up the Storage Cell.</span></h3>
-
-<p>Each manufacturer of storage cells issues
-specific directions for the charging of his
-own make, but generally the method is as
-follows: The acid solution is prepared by
-mixing one volume of sulphuric acid to
-from four to seven volumes of water, according
-to the make of the cell. The sulphuric
-acid should have a specific gravity
-of 1.82 and be chemically pure. <i>The acid
-must always be poured into the water, and<span class="pagenum" id="Page_213">213</span>
-slowly, stirring all the time, then set aside
-for the mixture to cool.</i> It is best to mix
-the solution in a separate earthenware vessel,
-and when two or more cells are to be
-set up, to mix all the solution at one time,
-to ensure the same strength, unless a
-hydrometer is used to determine this.</p>
-
-<p>A good method to ascertain the exact
-quantity of solution required is to place
-the elements in the jar and cover 1 inch
-deep at least with water, then remove the
-elements and pour off the volume of water
-corresponding to the proportion of acid
-to be added, and lastly pouring the remaining
-water into the mixing vessel, prepare
-the solution, or electrolyte, as it is called.
-New elements should be wetted with pure
-water before being immersed in the solution.
-An ordinary charge of the electrolyte
-requires from six to ten hours to cool
-thoroughly, as considerable heat is evolved
-in the mixing.</p>
-
-<p>Having now prepared the storage battery
-solution and set up the primary cells,<span class="pagenum" id="Page_214">214</span>
-the charging can be proceeded with. The
-current must be turned on the storage cell
-immediately the elements are placed in
-the acid. Connect the wire from the zinc
-of the primary battery to the negative of
-the storage cell and the copper wire to
-the positive. As the current from a gravity
-cell is but small, it will take quite a
-time to charge a storage cell of 50 ampere
-hours' capacity fully; it is a good scheme
-to get the cell charged up from a dynamo
-source, and use the gravity cells to keep
-it charged; but this cannot always be
-done, and the gravity battery will do the
-work in time. As the best storage cells
-render but 90 per cent of the current put
-into them, they must be charged over the
-number of hours for which they are required
-to deliver current.</p>
-
-<p>When the cell is fully charged the solution
-will become milky and give off gas
-freely. This gas in large quantities is detrimental
-to health, and on no account
-should a storage cell be <i>charged</i> in a sleep<span class="pagenum" id="Page_215">215</span>ing
-apartment. It affects the throat and
-lungs, and renders them susceptible to
-take cold under suitable circumstances.
-The average voltage of storage cells, when
-tested with the charging current on, is 2.4
-volts, and the lowest they should be allowed
-to reach is 1.9 volts, unless otherwise
-specified by the manufacturers.</p>
-
-<p>Cells in poor condition are liable to form
-a <i>white</i> deposit of sulphate of lead, this
-fault being known as "sulphating." This
-trouble requires much careful nursing,
-and the cells must be charged for a long
-time at a very low rate until the plates of
-the positive element regain their normal
-gray color. Chips of straw or excelsior,
-etc., falling in between the plates will carbonize
-and cause trouble.</p>
-
-<p>Most portable cells are sealed, but all
-cells can be easily sealed with paraffin wax
-for amateur use. Cover the elements fully
-½ inch above the normal height of the electrolyte
-with water before pouring in the
-electrolyte. Melt some paraffin in an<span class="pagenum" id="Page_216">216</span>
-earthenware jar and pour it on top of the
-water, about the middle of the surface,
-when it will spread, and care having been
-taken to have the jar sides dry, will cake
-solid and form a good seal. Then bore a
-hole with a brace and bit or some such
-tool through the wax and pour out the
-water. The cell can then be set up as
-usual, the hole being only partly closed to
-allow of the escape of the generated gas.
-A glass or rubber tube can be sealed into
-the hole in the wax, and makes a more
-finished job.</p>
-
-<p>While on the subject of primary batteries
-for charging storage cells, a few remarks
-on their electromotive force may
-not be amiss. Although the specifications
-issued by the manufacturers specify an excess
-charging voltage of 10 per cent over
-the total voltage of the storage cells, this
-does not apply to primary cells in its entirety.
-The voltage of five gravity cells
-in series would aggregate 5 volts, and the
-voltage of one storage cell but 2 volts, but<span class="pagenum" id="Page_217">217</span>
-there would not be 5 volts available to force
-the charging current through the latter. In
-the first place there is the counter electromotive
-force of the storage cell working
-against the gravity battery. Simple subtraction
-would show only 3 volts excess in
-favor of the primary electromotive force;
-but the working voltage of a galvanic cell
-varies according to external resistance of
-the cell and the external resistance of the
-circuit. When the internal resistance is
-high, as in the gravity cell, and the circuit
-resistance is low, in this case being the
-storage cell, the available electromotive
-force of the primary is low also.</p>
-
-<p>In many cases it is desired to operate a
-Ruhmkorff coil from an electric-light main
-direct. This can readily be done if the circuit
-be of the constant potential class—that
-is, one constructed to furnish current
-for incandescent lamps in multiple. With
-the direct current, such as the Edison, all
-that is necessary is either to interpose a
-rheostat, as in Fig. 64, or to use the lamps,<span class="pagenum" id="Page_218">218</span>
-as in Fig. 65. The manner of connecting
-up is the same as if the storage cell B be
-replaced by the coil. Using the formula
-<i>C</i> = <i>E</i>/<i>R</i>, for example, if the circuit be at
-110 volts and the coil require 10 amperes,
-a resistance of 11 ohms will be required.
-Or using the lamps in the diagram, Fig.
-65, about 20 lamps are to be put in circuit.
-If the current be an alternating one,
-the contact-breaker will have to be screwed
-down or short circuited.</p>
-
-
-<h3><span class="smcap">The "U. S." Storage Cell.</span></h3>
-
-<p>This cell is of the lead-zinc type, being
-the practical form of the Reynier cell. It
-is to be recommended for working Ruhmkorff
-coils, its output weight for weight
-being far in excess of the lead-lead types.
-This cell is readily portable and easy of
-operation, the zinc electrode being the only
-one needing renewal, and that at very infrequent
-intervals.</p>
-
-<p><span class="pagenum" id="Page_219">219</span></p>
-
-<p>The lead electrode consists of plates of
-peroxide clamped together, and presents
-quite a large surface. The zinc in most
-types is of the circular sheet form, and
-encloses the lead block, being kept amalgamated
-by mercury lying in the bottom of
-the cell. The E. M. F. on open circuit is
-about 2.5 volts, which is higher than any
-lead-lead combination. On closed-circuit
-work this drops to from 2.35 volts downwards.
-During action, when a large amount
-of current is being drawn from the cell, a
-white sulphate appears, but this disappears
-upon the cell being recharged or even left
-to rest. Bubbles of gas, which sometimes
-form under the peroxide block, should be
-removed by gently tilting the cell or hitting
-the table or shelf upon which it stands a
-smart blow. The large type No. 3 is suitable
-for X-ray work, and a still larger cell is
-made, which is preferable for heavy or
-continuous discharges of current.</p>
-
-<p><span class="pagenum" id="Page_220">220</span></p>
-
-
-<h3><span class="smcap">Harrison Cell.</span></h3>
-
-<p>The No. 1 cell recently put upon the
-market has given excellent results for open
-circuit work. It consists of a negative element
-with lead peroxide as a depolarizer.
-The positive element is self-amalgamating
-zinc, which is free from local action. The
-electrolyte is dilute pure sulphuric acid.
-The potential is high, being 2.5 volts, and
-the internal resistance is 0.14 ohm. This
-cell belongs to a group which is midway
-between primary and storage, or secondary
-cells. Its construction is similar to the lead-zinc
-secondary cell, in place of which it may
-be used, it being easy to recharge an exhausted
-cell by passing a weak current
-through it in reverse direction, thus recharging
-the peroxide of lead grid and renewing
-the zinc and electrolyte.</p>
-
-<p>The large size, or type No. 3, which the
-manufacturers are producing, differs from
-the No. 1 cell in that it has a larger negative<span class="pagenum" id="Page_221">221</span>
-element, or grid, and has two zincs, instead
-of one; consequently, it has a lower internal
-resistance—0.07 ohm—and a higher discharge
-rate with a capacity of 150 ampere
-hours. The potential is 2.5 volts. It is
-suitable for coil work or for sparking gas
-engines, and for ease of manipulation and
-convenience is to be highly recommended.</p>
-
-<div class="figcenter" ><a id="fig67"></a>
-<img src="images/i_221.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 67.</span></div>
-</div>
-
-<p>The elements are shown in Fig. 67, lead
-grid <i>L</i>, which is filled in with paste of
-peroxide of lead, and which neither buckles
-nor disintegrates. The zinc <i>Z</i>, however,<span class="pagenum" id="Page_222">222</span>
-possesses a novel feature. A cavity is cast
-in the zinc element and filled with an amalgam
-of mercury, the copper electrode passing
-through this amalgam into the solid zinc, as
-shown in the cut. As the action of the
-battery proceeds, this amalgam forces its
-way into the pores of the element and keeps
-up so good an amalgamation of both copper
-rod and zinc that zincs can be used up to
-a point when the rising internal resistance
-makes it economy to throw them away, and
-absolutely no perceptible local action takes
-place in the cell upon continued open circuit.
-A preparation is furnished if desired, which
-forms a jelly of the electrolyte, making the
-cell readily portable. Like all of these combinations,
-its electromotive force exceeds
-two volts, and its internal resistance is low
-enough to advise its employment in coil
-work.</p>
-
-<p>When a storage battery is to remain unused
-for a long time it must first be fully
-charged, and then every week or so the charging
-current passed through it until it bubbles.<span class="pagenum" id="Page_223">223</span>
-Where it is to be laid away for a long period
-of time, and weekly charging is not feasible,
-the following operations are necessary:
-First, fully charge battery, remove electrolyte,
-and replace by water immediately.
-Discharge at normal rate until voltage runs
-down to 1.7 per cell. Gradually decrease
-resistance until battery is almost on short
-circuit. Let it stand for a day, then pour
-off the water, and keep elements in a dry,
-clean place.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_224">224</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_XII">CHAPTER XII.<br />
-
-<small>TESLA AND HERTZ EFFECTS.</small></h2>
-</div>
-
-<p>The currents of high frequency used by
-Tesla in his researches are produced by
-electrical rather than mechanical means.
-The alternating current dynamo used by
-him renders a current of 10,000 alternations
-per second, but the actual current
-necessary to the performance of the luminous
-effects has a frequency of millions of
-oscillations per second, produced by the
-discharge of Leyden jars or condensers.</p>
-
-<p>Dr. Oliver J. Lodge, in his "Modern
-Views of Electricity," shows that the discharge
-of the Leyden jar is in general oscillatory,
-the apparently single and momentary
-spark, when analyzed in a very rapidly
-rotating mirror, is shown to consist of a
-series of alternating flashes, rapidly suc<span class="pagenum" id="Page_225">225</span>ceeding
-one another and lasting individually
-less than one hundred thousandth of
-a second. The capacity of the condenser
-and inertia of the circuit regulate the
-rapidity of these oscillations. A 1 microfarad
-condenser discharging through a
-coil of large self-induction, such as one
-having an iron core, may oscillate only a
-few hundred times per second. On the
-other hand, a Leyden jar of the 1 pint size
-discharging through a short circuit will
-set up oscillations, perhaps ten million per
-second; and a still smaller jar would give
-oscillations away up in the billions. But
-these small jars are quickly discharged,
-and require a constant replenishing.</p>
-
-<p>The discharge actually consists of a principal
-discharge in one direction, and then
-several reflex actions back and forth, becoming
-feebler until their cessation. In
-their vibration they generate waves in the
-surrounding medium, similar in many respects
-to sound waves, but of infinitely
-higher velocity. Their length depends on<span class="pagenum" id="Page_226">226</span>
-the rate of vibration of the source and
-their velocity. The microfarad discharge
-before mentioned will have a wave length
-of perhaps 1200 miles, the small jar not
-over 70 feet; and yet the true light wave
-has only an average length of one fifty
-thousandth of 1 inch. These waves travel
-into space until they either die out from
-exhaustion or are absorbed by some suitable
-body; but they possess the quality of
-resonance in a degree like those of sound.
-Two tuning forks of the same pitch will
-influence one another—that is, one on
-being vibrated will start the other in vibration,
-even at a considerable distance, but
-the electric waves far surpass them in this
-respect.</p>
-
-<div class="figcenter" ><a id="fig68"></a>
-<img src="images/i_227.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 68.</span></div>
-</div>
-
-<p>Dr. Hertz made the first practical experiments
-in this direction with his electric
-resonator (Fig. 68). This apparatus
-consisted of a 3-inch spark induction coil,
-<i>I</i>, the secondary wires <i>S S</i> being connected
-to the copper rods <i>R R</i>, provided with
-metal balls <i>B B</i>, nearly 11 inches in diam<span class="pagenum" id="Page_227">227</span>eter.
-The discharging balls <i>D D</i> were approximated
-until a satisfactory discharge
-passed between them. A large wire ring
-having a spark gap in its circuit was so
-influenced by the resonance as to show
-minute sparks passing across this gap even
-when the ring was situated in a distant
-room. In many experiments with a rapidly
-vibrating induction coil current, a
-sparking has been noticed in metallic objects
-in the same room, in one instance it<span class="pagenum" id="Page_228">228</span>
-being discovered in the metallic designs
-on a wall-paper.</p>
-
-
-<h3><span class="smcap">The "Tesla" Effects.</span></h3>
-
-<p>In exploring the comparatively new field
-opened up by Professor Crookes, Nikola
-Tesla has stimulated research into the mysteries
-of high tension and frequency currents
-and their effects. In the majority of
-his experiments Tesla uses alternating currents
-generated by machinery of his own
-design, but in a large number of cases his
-effects can be duplicated with an induction
-coil suitably energized. In the latter case
-the apparatus consists of a battery, a
-Ruhmkorff coil, two condensers, and a
-second specially constructed induction or
-disruptive coil, with some few subsidiary
-implements. The contact-breaker or rheotome
-must be one giving interruptions of
-very rapid sequence.</p>
-
-<div class="figcenter" ><a id="fig69"></a>
-<img src="images/i_229.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 69.</span></div>
-</div>
-
-<p>Fig. 69 shows a diagram of the Tesla
-arrangement with a Ruhmkorff coil. The
-terminals of the secondary coil of the<span class="pagenum" id="Page_229">229</span>
-Ruhmkorff coil <i>I</i> terminate at the condensers<span class="pagenum" id="Page_230">230</span>
-<i>C C</i>. Bridged across the wires
-before they reach the condensers is the
-discharger <i>D</i>. The second terminals of
-the condensers are led through the split
-primary of the disruptive coil, terminating
-at the points <i>B B</i> of the second discharger.
-The secondary of the disruptive coil is
-either outside or inside the primary coil.
-The condensers are of special design, being
-small, but of high insulation. They each
-consist of two plates of metal a few inches
-square immersed in oil and arranged so
-they can be brought nearer together or
-further apart, as necessary. Within limits,
-the smaller these plates are the more
-frequent will be the oscillations of their
-discharge. They also fulfil another purpose,
-they help nullify the high self-induction
-of the secondary coil by adding capacity
-to it.</p>
-
-<div class="figcenter" ><a id="fig70"></a>
-<img src="images/i_231.jpg" alt="" />
-<div class="caption"> <span class="smcap">Fig. 70.</span></div>
-</div>
-
-<p>The discharger tips are preferably metal
-balls under 1 inch in diameter. Tesla uses
-various forms of dischargers, but for ex<span class="pagenum" id="Page_231">231</span>perimental
-purposes the two metal balls
-will answer. They are adjusted when the
-whole apparatus is working according to
-the results desired. The mica plates serve
-to establish an air current up through the
-gap, making the discharge more abrupt, an
-air blast being also used at times for the
-furtherance of this object. The device
-(Fig. 70) consists of an electro-magnet, <i>C</i>,<span class="pagenum" id="Page_232">232</span>
-set with its poles <i>P</i> across the air gap,
-helping to wipe out the spark, as in a well-known
-form of lightning arrester. This
-form, described by Tesla, has the pole
-pieces <i>P</i> shielded by mica plates <i>M</i>, to prevent
-the sparks jumping into the magnets.
-Fig. 70 is an elevation and Fig. 71 a plan
-of this device.</p>
-
-<div class="figcenter" ><a id="fig71"></a>
-<img src="images/i_232.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 71.</span></div>
-</div>
-
-<p>The resonance effects obtained during<span class="pagenum" id="Page_233">233</span>
-the operation of a Tesla coil are very
-marked, and their study may lead to the
-solution of the problems of communication
-between distant points without the use of
-other conducting media than the atmosphere.
-But the main use to which the
-Tesla currents have been put is that of artificial
-illumination. These currents have
-enabled experimenters to obtain a high
-luminosity in vacua by the aid of only one
-conducting wire—in fact, in some cases
-without the utilization of any conductor
-than the air. An ordinary incandescent
-lamp connected to one terminal of the coil
-will show in a fair degree some of the luminescent
-phenomena. The brush effects
-from the terminals of the secondary coil
-are extremely marked and interesting;
-but to detail the experiments that can be
-performed with the Tesla disruptive coil
-would be an impossibility here. Reference
-is recommended to the published
-works of Nikola Tesla, which happily are
-readily procurable.</p>
-
-<p><span class="pagenum" id="Page_234">234</span></p>
-
-<p>These currents of high frequency have
-of late been turned to account in electrotherapeutics,
-principally for the stimulation
-they exert on the nutritive process.
-They also exert a very great influence on
-the vasomotor centres, as is evidenced by
-the reddening of the skin and exudation
-of perspiration. This result is readily obtainable
-by placing the patient in connection
-with one electrode on an insulating
-stool, and terminating the other electrode
-at a large metal plate situated a few feet
-distant; or the patient may be surrounded
-by a coil of wire in connection with the
-coil of sufficient diameter, however, to
-prevent contact.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_235">235</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_XIII">CHAPTER XIII.<br />
-
-<small>THE "ROENTGEN" RAYS AND RADIOGRAPHY.</small></h2>
-</div>
-
-<p>Although the remarkable discovery
-that it was possible by electrical means to
-depict an image of an object on a photographic
-sensitized plate, despite the intervention
-of solid bodies, was first given to
-the world at large by Professor Roentgen,
-yet he was undoubtedly led to the results
-by consideration of the works of previous
-experimenters in electrical discharges
-through vacua.</p>
-
-<p>It is not intended here to trace the previous
-work of Professor Crookes, the inventor
-of the radiometer, which is actuated
-by the heat rays of light, nor of
-Hertz, who found that gold leaf was transparent
-to rays emanating from certain<span class="pagenum" id="Page_236">236</span>
-vacuum tubes carrying a luminous electrical
-discharge. It is mainly the purpose of
-these pages to give directions for practical
-work, and not deal in theories, interesting
-though they be. At the beginning of X-ray
-investigation many claims were made which
-have since been disproven, but the fundamental
-operations remain the same. A
-Crookes tube of special design is energized
-from a coil or similar electrical distributor,
-and by means of the resultant rays otherwise
-opaque objects appear partially transparent,
-their shadows being cast upon the
-screen of a fluoroscope, or these shadows
-are allowed to act upon a sensitized photographic
-plate, and subsequent development
-reveals outlines or shadowgraphs. The
-general arrangement of apparatus is shown
-in Fig. 72. <i>C</i> is a Ruhmkorff coil, giving
-not less than 2 inches of spark; <i>B</i> the battery
-operating same; <i>T</i> the modified form of
-Crookes tube used most generally; <i>X</i> the
-object under observation; <i>F</i> the fluoroscope
-or the sensitized photographic plate. The<span class="pagenum" id="Page_238">238</span>
-usual precautions are taken to avoid the
-leakage of current from the secondary wires,
-the tube <i>T</i> being best mounted in a wooden
-stand (Fig. 72), and the wire connections
-brought to it as direct as possible. No
-condenser, stand, etc., are shown in drawing,
-to avoid unnecessary complication.</p>
-
-<div class="figcenter" ><a id="fig72"></a>
-<img src="images/i_237.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 72.</span></div>
-</div>
-<p><span class="pagenum" id="Page_237">237</span></p>
-
-
-<h3><span class="smcap">The Fluoroscope.</span></h3>
-
-<p>This is a funnel-shaped cardboard box
-with an opening at the smaller end for the
-eyes and a piece of card across the larger
-end. The inside surface of this card is
-covered with crystals of barium platino
-cyanide, the most satisfactory fluorescent
-substance obtainable. The earlier fluoroscopes
-were made with tungstate of calcium,
-but the above salt has proven far more
-satisfactory. The operation of the fluoroscope
-is simple. It is held in the hand by a
-convenient handle, the open end pressed
-close to the eyes, so as to exclude outside<span class="pagenum" id="Page_239">239</span>
-light, and with the hand or other object held
-against the outside of the big end, or screen,
-it is directed towards the Crookes tube.
-The screen then appears to glow with a
-bluish light, and the shadow of the object
-is distinctly seen on the screen. Different
-adjustments of the coil give results which
-will be treated upon later.</p>
-
-
-<h3><span class="smcap">Phosphorus Tube.</span></h3>
-
-<p>Messrs. Siemens and Halske manufactured
-a tube which allowed of a slight
-variation of vacuum by using the vapor of
-phosphorus. An auxiliary tube containing
-phosphorus was added to the main tube, and
-upon heat being applied to it by means of
-a lamp, vapor is given off, which materially
-reduces the vacuum of the main tube. When
-the opposite result is desired part of the
-current is diverted through the auxiliary
-tube, and the vapor is caused to solidify itself
-upon the walls of the tube.</p>
-
-<p><span class="pagenum" id="Page_240">240</span></p>
-
-<div class="figcenter" ><a id="fig73"></a>
-<img src="images/i_240.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 73.</span></div>
-</div>
-<p><span class="pagenum" id="Page_241">241</span></p>
-
-
-<h3><span class="smcap">The Crookes Tube.</span></h3>
-
-<p>The most satisfactory tube for X-ray
-work is one where the vacuum is readily
-adjustable. Reference to Fig. 73 shows the
-Queen form. A small bulb, containing a
-chemical which gives off vapor when heated
-and reabsorbs it when cooled, is directly
-connected to the main tube and surrounded
-by an auxiliary tube, which is exhausted to
-a low vacuum. In the auxiliary tube the
-cathode is opposite to the above-mentioned
-bulb, so that any discharge through it will
-heat the bulb by the bombardment of the
-cathode rays. The cathode is connected to
-a spark point, which can be adjusted to any
-distance from the cathode of the main tube.
-The anode of the small tube is directly connected
-to that of the main tube. When the
-tube is put into operation the vacuum and,
-consequently, the resistance of the main tube
-being high, the current preferably passes
-by the spark point and auxiliary tube, heat<span class="pagenum" id="Page_242">242</span>ing
-the chemical for a few seconds until
-sufficient vapor has been driven into the
-main tube to permit the current to pass
-through the latter. After this only an occasional
-spark will jump across the gap to
-counteract the tendency of the reabsorption
-of the vapor and consequent raising in
-resistance of the main tube.</p>
-
-<p>This device presents easy means of adjusting
-the vacuum in the main tube. With the
-spark point at a considerable distance from
-cathode the vacuum will be high. When the
-spark gap is short the vacuum will become
-low. The main bulb is about 4½ inches in
-diameter, and at the place where the X-rays
-pass only <sup>1</sup>∕<sub>64</sub> of an inch in thickness. The
-cathode is of aluminum, the anode of platinum.
-In starting this tube, it is best to
-make the spark gap about one inch in width.
-When connected up and working properly
-the main bulb will be filled with a green
-striated luminosity between anode and
-cathode, and the tip of the chemical bulb
-will have the shadow of the little platinum<span class="pagenum" id="Page_243">243</span>
-tip thrown upon it. The green light is not
-always brilliant; at times it is quite weak,
-but yet does its work well. A brilliant green
-light is often one of the signs of wrong
-connection, and particularly so when the
-little shadow on the chemical bulb is absent.
-Never run these or any other tubes backwards,
-but be sure the current is flowing
-in correct direction at first operation.</p>
-
-<p>Other forms of Crookes tubes differ only
-in form, or are devoid of adjustment, and
-the connections of coil, tube, etc., are the
-same.</p>
-
-
-<h3><span class="smcap">General Remarks.</span></h3>
-
-<p>A high vacuum gives greater penetrative
-power than a low vacuum. Where the
-operator has not an adjustable tube it is
-imperative that he have at least two tubes,
-one high and one low. It is the contrasts
-which render the X-ray practical, and these
-contrasts are largely governed by the
-vacuum. In locating a metallic substance
-in the human body a high vacuum tube<span class="pagenum" id="Page_244">244</span>
-would be needed, that the bones and dense
-tissue be rendered more transparent. On
-the other hand, to make a radiograph of the
-bones, a lower vacuum is necessary in order
-to get a contrast between the bones and the
-tissues. In general, a high vacuum is best
-for fluoroscope work and a low vacuum for
-making pictures on a photographic plate.
-Short exposures in radiography are obtained
-by powerful rays and consequently by coils
-operating at considerable energy. In extended
-examinations or where a subject is
-under the X-rays for more than a minute
-or so, a screen should be interposed between
-the subject and the tube to avoid the burning
-effect which is often noticeable. This screen
-consists of a piece of cardboard well covered
-with gold leaf, and should be grounded—that
-is, a connection be run from the gold
-surface to a water-pipe or other ground
-connection. Sheet lead is an efficient screen
-to the rays, and, if desired, a lead screen can
-be made, partially enclosing the apparatus,
-to protect the operator. But it must be large<span class="pagenum" id="Page_245">245</span>
-enough and far enough distant from the
-coil and tube to avoid any possibility of
-leakage of current or even inductive influence.
-In operating X-ray machines never
-attempt to alter connections or make adjustments
-other than at coil platinum screw or
-Crookes tube spark gap without first shutting
-off current. Remember that a very
-unpleasant shock can be easily obtained from
-touching the apparatus with only one hand.
-It is often advisable to remove one's watch,
-particularly when using Ruhmkorff coils of
-large size.</p>
-
-<p>The tube may be worked until it shows
-a slight redness in the centre of the platinum,
-but care must then be taken not to increase
-current, or the platinum will melt. Never
-allow the tube to come in contact with any
-object other than its stand and connections
-while working, and be sure the wires from
-secondary do not come near tube until they
-reach places of attachment, or they may
-spark through glass and ruin the tube.</p>
-
-<p>In making radiographs on sensitized<span class="pagenum" id="Page_246">246</span>
-plates the unused plates should be kept at
-a considerable distance from the coil while
-working. Better still if they are in another
-room. Plates for X-ray work are made by
-most photographic supply dealers; in fact,
-almost any good brand of sensitized plates
-or even films will answer. When making
-a radiograph, the plate can either be left in
-the holder or well wrapped in black paper,
-but current should never be turned on coil
-before the plate and subject are in position.
-In photographing the chest, neck, etc., the
-plate can be strapped on to the part; but the
-subject must remain absolutely still. The
-time of exposure varies considerably with the
-size of coil, thickness of object, etc. Radiographs
-of the hand have been taken by
-simply laying the hand on top of the plateholder
-and operating tube for 100 seconds.
-But, as a rule, longer exposures are necessary.
-Most radiographs will generally
-require that the plate be "intensified" and
-a developer used that gives great detail, such
-as metol quinol, etc. At any rate, great care<span class="pagenum" id="Page_247">247</span>
-should be exercised in developing the plate,
-as many a good radiograph has been spoiled
-by undue haste.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_248">248</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="CHAPTER_XIV">CHAPTER XIV.<br />
-
-<small>WIRELESS TELEGRAPHY.</small></h2>
-</div>
-
-<p>In Chapter XII. we showed how Dr.
-Hertz caused electric waves to pass through
-space and become visible by sparks across
-an air gap in a wire ring situated at a distance
-from the source of energy. The
-apparatus used, and termed an electric
-resonator, is in principle similar to that of
-the wireless telegraph. The minute sparks
-instead of idly passing across the air gap
-are made to traverse a "coherer" (to be
-afterwards more fully described). This
-"coherer" substantially consists of a resistance,
-preferably metal filings placed in series,
-with a battery and relay. Normally, the
-resistance is so adjusted that the battery
-current is not strong enough to operate the<span class="pagenum" id="Page_249">249</span>
-relay. A wire is led from one side of this
-coherer up into the air to intercept the
-Hertzian waves, the other side of the coherer
-is put to earth, or "grounded." When a
-wave strikes the air wire it sends a current
-through the coherer to ground (as before it
-sent a spark across the air gap), and this
-wave acts on the filings in its passage
-through them; in effect, to lower their resistance,
-so that the current is increased through
-the relay circuit and the relay armature is
-attracted to its magnet. The relay makes
-contact in the usual manner at the platinum
-points, and in its turn causes the local
-circuit, sounder, bell, or pen register to
-record the wave (or signal). After each
-wave the filings are in such state that to
-restore them to their former high resistance
-it is necessary to give the coherer a smart
-tap. This is generally accomplished automatically
-by means of an arm extending
-from the sounder lever, which strikes against
-the coherer each time the sounder armature
-is moved.</p>
-
-<p><span class="pagenum" id="Page_250">250</span></p>
-
-<div class="figcenter" ><a id="fig74"></a>
-<img src="images/i_250.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 74.</span></div>
-</div>
-<p><span class="pagenum" id="Page_251">251</span></p>
-
-<p>Figures 74 and 75 are diagrams of a
-simple circuit, Fig. 74 being the transmitting
-apparatus and Fig. 75 the receiving apparatus.</p>
-
-<p>In Fig. 74 <i>P P</i> and <i>S S</i> are the primary
-and secondary of a Ruhmkorff coil, <i>D</i> two
-brass balls on the discharger, <i>B</i> the battery,
-<i>K</i> a key, in place of the usual contact
-breaker, which is either absent or screwed
-down; <i>V</i> a wire leading from one arm of
-the discharger up into the air, of a height
-varying with the results desired; <i>G</i> a ground
-plate in connection with the other discharger
-arm.</p>
-
-<p>The coil condenser is left out of the diagram
-for sake of clearness; but, of course,
-is necessary to the operation of the apparatus.</p>
-
-<p>In Fig. 75, <i>C</i> is the coherer, also called
-the Branly tube, or radio conductor; <i>S</i>
-a telegraph sounder, or electric bell; <i>R</i> a
-relay; <i>R B</i> and <i>L B</i> the relay battery and
-local battery, respectively; <i>G</i> a ground connection;
-<i>M</i> a resistance, or choke coil, and<span class="pagenum" id="Page_252">252</span>
-<i>V</i> a vertical wire, as in the transmitter; in<span class="pagenum" id="Page_253">253</span>
-fact, in the station set the same vertical wire
-answers for both transmitter and receiver.</p>
-
-<div class="figcenter" ><a id="fig75"></a>
-<img src="images/i_252.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 75.</span></div>
-</div>
-
-<p>The coil to be used may be from two
-inches of spark upwards, dependent upon
-the distance the signals have to travel. The
-relay battery may be two cells of dry battery,
-the local battery as much as is desired to
-operate the bell, sounder, or pen register
-receiving the signals. Presuming the apparatus
-set up and adjusted, and designating
-the transmitter as Station A and the receiver
-as Station B, the operation will be as follows:
-A pressure and release of key <i>K</i> sends
-an impulse of current through the primary
-<i>P</i>, inducing a current in <i>S</i>, which manifests
-itself by a spark between the discharger balls
-at <i>D</i>. An electric wave is released, which,
-starting from <i>V</i>, Station A, meets in its
-passage <i>V</i> of Station B. Travelling along
-this wire to the ground, it finds two paths—through
-<i>C</i> or <i>R</i>. As the choke coil deters it
-from passing through the relay, it finds
-passage through <i>C</i> and so to ground.</p>
-
-<p><span class="pagenum" id="Page_254">254</span></p>
-
-
-<h3><span class="smcap">The Coherer.</span></h3>
-
-<p>Many forms of this apparatus are in use,
-but as yet no definite design can be recommended
-for specific purposes. The most
-general mode of construction is that of the
-Branley Coherer, as shown in Fig. 76.</p>
-
-<div class="figcenter" ><a id="fig76"></a>
-<img src="images/i_254.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 76.</span></div>
-</div>
-
-<p>It consists of a glass tube, 2 inches long
-by ¼ inch inside diameter, furnished with
-well-fitted metal plugs at each end, to which
-connections are made. These plugs can be
-slid in and out of tube for adjustment, the
-gap between them being loosely filled with<span class="pagenum" id="Page_255">255</span>
-fine metal filings. The metal used varies,
-according to the operator's preference, the
-most generally adopted being pure nickel
-for both plugs and filings. Another mode
-of construction for purely experimental use
-is to merely cork the ends of the tube and
-pass the wires through these corks into the
-filings, ensuring, however, good contact
-between wires and filings. Marconi's favorite
-form is a glass tube two inches long with
-silver plugs, each one-quarter inch long, in
-each end, intervening space being partially
-filled with a mixture of nickel and silver
-filings. These plugs are then adjusted to
-as close as one-twenty-fifth of an inch, and
-the whole apparatus exhausted of air either
-by means of a leading-in tube or by placing
-coherer in a vessel from which the air can
-be drawn. As a rule, coherers containing
-air become less sensitive after continued
-use.</p>
-
-<p><span class="pagenum" id="Page_256">256</span></p>
-
-
-<h3><span class="smcap">Carbon Coherer.</span></h3>
-
-<p>Pointed carbon rods can be inserted in
-the tube instead of metal, and carbon dust
-substituted for the metal filings; but this
-form is suitable only for special purposes.
-It is very delicate in its action, but somewhat
-uncertain.</p>
-
-
-<h3><span class="smcap">Coherer without Filings.</span></h3>
-
-<p>Were it not for reasons, such as difficulty
-of decoherence, the metal filings might be
-dispensed with and two rods of metal placed
-in light contact. The construction of the
-coherer reminds one very much of the microphone,
-a satisfactory coherer having been
-made out of the old "nail microphone," four
-wire nails being placed crossing one another
-in the battery circuit, in one case acting as
-a sound transmitter, whence the name; in
-the other as a coherer.</p>
-
-<p><span class="pagenum" id="Page_257">257</span></p>
-
-
-<h3><span class="smcap">Aluminium Coherer.</span></h3>
-
-<p>Aluminium, a metal which has steadily
-grown into favor, and which is now readily
-obtainable, can be made to serve in the
-present apparatus in place of nickel both as
-to electrodes and filings. It is advisable,
-however, to use aluminium electrodes of
-slightly larger diameter than those of other
-metals.</p>
-
-
-<h3><span class="smcap">Steel Ball Coherer.</span></h3>
-
-<p>A recent writer has recommended the use
-of balls of steel, such as are used in ball
-bearings, such, however, not to exceed
-⅜ inch diameter. Such a coherer would take
-the form of an upright glass tube, with
-electrodes exerting pressure on a series of
-four or more steel balls. Decoherence here
-becomes difficult, and mention is but made
-of it to show the variety of forms which
-this important little article may assume.</p>
-
-<p>Coherers are adjusted by advancing or<span class="pagenum" id="Page_258">258</span>
-receding the electrodes, altering the quantity
-of the filings, etc. There exists but little
-difficulty in operating coherers; considerable
-latitude is permissible as to adjustment, size,
-character, etc. There does not seem so much
-difficulty in obtaining sensitiveness as in
-guarding against external electrical disturbances.
-Wings or vanes of thin sheet metal
-are sometimes attached to the metal ends or
-electrodes of the coherer for purposes of
-adjustment, their size and capacity being
-determined by experiment. It is best that
-they present no sharp angles, but be of a disc,
-or spherical, form, the better not to dissipate
-energy.</p>
-
-
-<h3><span class="smcap">The Oscillator.</span></h3>
-
-<p>This is the name given the contrivance at
-the ends of the discharger, <i>D</i> being the point
-at which the electrical oscillations, or waves,
-are radiated.</p>
-
-<p><span class="pagenum" id="Page_259">259</span></p>
-
-
-<h3><span class="smcap">Clarke's Oscillator.</span></h3>
-
-<p>This consists of two brass spheres, generally
-3 inches in diameter, and mounted on
-a stand or sometimes on top of the induction
-coil. The distance between the balls is
-readily adjustable by either attaching the
-balls on the ends of two sliding rods, or
-causing the balls themselves to slide on the
-rods (Fig. 77).</p>
-
-<div class="figcenter" ><a id="fig77"></a>
-<img src="images/i_259.jpg" alt="" />
-<div class="caption"><span class="smcap gap10">Fig. 77.</span> <span class="smcap">Fig. 78.</span></div>
-</div>
-
-
-<h3><span class="smcap">Triple Oscillator.</span></h3>
-
-<p>Here three balls are used, two outside ones
-connected to the circuit, being one-half inch<span class="pagenum" id="Page_260">260</span>
-diameter, and the middle one, isolated from
-all connection, of three inches in diameter.
-This form is best mounted on a separate
-stand, the balls either being on glass or hard
-rubber legs (Fig. 78). Connecting wires
-from the secondary of the coil must in all
-cases be run with the greatest precautions
-against crosses, as directed in Chapter V.</p>
-
-<p>It is possible to make many different
-designs in oscillators. Some experimenters
-use the simple Clarke form, others prefer
-the triple balls; yet, again, others vary the
-sizes and the relative sizes of the balls. One
-form of oscillator prescribes the balls to be
-immersed in oil or vaseline. Such methods
-all have their adherents. Even the plain
-points of an induction coil discharger will
-serve for short-distance work.</p>
-
-<p>Oscillators are adjusted by altering their
-proximity to one another, and should have
-care given to keep the spheres bright. It is
-easy to alter capacity of an oscillator by
-connecting its spheres to other insulated
-spheres.</p>
-
-<p><span class="pagenum" id="Page_261">261</span></p>
-
-
-<h3><span class="smcap">The Coil.</span></h3>
-
-<p>The coil for wireless telegraphy does not
-differ from the regular Ruhmkorff, except
-that in place of the contact breaker a signal
-or Morse telegraph key is substituted. Of
-course, the contact breaker can be made to
-perform the same duty by retracting the
-adjusting screw out of reach of the platinum
-on spring, and then operating the hammer
-and spring in same manner as key.</p>
-
-
-<h3><span class="smcap">Translating Devices.</span></h3>
-
-<p>Under this head are included relay
-sounder, bell, or register, which are at receiving
-set. They do not differ from the
-regular telegraphic apparatus. The sounder
-may be of the Western Union pattern,
-wound to 4 ohms; the relay also Western
-Union pattern, and wound to 150 or 250
-ohms, as best suits the individual case.</p>
-
-<p>In order to protect the receiver from the
-action of the transmitter belonging to the<span class="pagenum" id="Page_262">262</span>
-same set of instruments, particularly when
-powerful waves are generated, it has been
-found at times necessary to enclose the
-receiver in a metal case. Marconi has patents
-on such devices, particularly on a
-movable shutter in the case, which opens
-when the transmitter is not in operation.
-Edouard Branly placed his receiving set in
-a metal case with a vertical slit eight inches
-by one-tenth of an inch.</p>
-
-
-<h3><span class="smcap">Air Conductor.</span></h3>
-
-<p>The vertical wire extending from the
-coherer up into the air must be insulated
-from all other objects in the best possible
-manner. A bare copper wire of No. 14
-B &amp; S gauge can be suspended from porcelain
-insulating knobs, which in turn can be
-strung from each other by means of stout
-silk cord or even wire. There is a special
-form of insulator used in electric construction
-work, and known as a circuit breaker,
-which will answer and which is easy of<span class="pagenum" id="Page_263">263</span>
-attachment; reference to Fig. 79 will show
-manner of using.</p>
-
-<div class="figleft" ><a id="fig79"></a>
-<img src="images/i_263.jpg" alt="" />
-<div class="caption"><span class="smcap">Fig. 79.</span></div>
-</div>
-<p>Temporary grounds can be made to water
-pipes, but it is better to use regular
-telephone copper ground-plates sunk
-deep in moist earth.</p>
-
-<p>At South Foreland, England, a
-mast has been erected, 150 feet in
-height for transmission across Channel,
-a distance of nearly thirty miles.
-At Notre Dame University, Illinois,
-Professor Green used a wire 150 feet
-in length, suspended from top of a
-high church tower, but was unable
-to transmit much over three miles,
-owing, presumably, to fact that the
-intervening country was well supplied
-with overhead wires, which
-probably intercepted the waves.</p>
-
-<p>It has been claimed that earthed or
-grounded air wires are necessary, but
-balls or similar "capacities" are not of service
-on the top of the wire. A theory has been
-advanced that the currents do not pass from<span class="pagenum" id="Page_264">264</span>
-air wire tip to air wire tip, but are conducted
-by the varying strata of the earth. No
-general confirmation is obtainable, however,
-and the experimental reader will find a wide
-field for research in this direction. Marconi,
-on the other hand, has accomplished much
-with zinc cylinders under six feet high, <i>not
-grounded in any respect</i>, indeed, and he also
-finds it impossible to assume a proportion
-between distance of effect and height of air
-wire. The following investigations and
-experiments are of interest in this connection:</p>
-
-<p>At a meeting of the Institution of Electrical
-Engineers, in December, 1898, Dr.
-Oliver Lodge showed that there must be
-a certain relative position between the receiving
-and transmitting circuits.</p>
-
-<p>He placed on one side of a room a box,
-containing a battery, bell, relay, and coherer
-properly connected up. On the other side
-he had an induction coil and pair of parallel
-discharger rods, with a spark gap to transmit
-waves across the room. When the rods<span class="pagenum" id="Page_265">265</span>
-of the receiver and transmitter were placed
-parallel to each other the receiving bell was
-operated; when the receiving rods of the
-transmitter were at right angles to those of
-the receiver the bell either failed to work,
-or weakened very considerably. He also
-told of an experiment made to determine the
-influence of different methods of grounding
-the apparatus. He found that when the
-apparatus was connected by a wire laid on
-the ground, there was the required response
-at the receiving station; but when the two
-stations were situated each side of a lake,
-and the ground wires immersed in the
-water, the receiving instrument failed to
-work. It seemed to him that the conductivity
-and power absorption of ether wave energy
-by water was too great to allow of the
-transmission of Hertz waves. This would
-seem to bear out the results obtained by
-Marconi in dispensing with ground wires.</p>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_266">266</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="INDEX">INDEX.</h2>
-</div>
-
-<div class="index">
-<ul class="index">
-<li class="ifrst">A</li>
-
-<li class="indx">Acid, Chromic, <a href='#Page_189'>189</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Sulphuric, <a href='#Page_212'>212</a>.</li>
-
-<li class="indx">Air pump, Geissler, <a href='#Page_142'>142</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Simple, <a href='#Page_141'>141</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Sprengel, <a href='#Page_143'>143</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> blast, <a href='#Page_76'>76</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> wire, <a href='#Page_262'>262</a>.</li>
-
-<li class="indx">Amalgamation, <a href='#Page_180'>180</a>.</li>
-
-<li class="indx">Assembly of coil, <a href='#Page_22'>22</a>.</li>
-
-<li class="indx">Attraction, Window, 154, <a href='#Page_163'>163</a>.</li>
-
-<li class="indx">Automobile coil, <a href='#Page_40'>40</a>.</li>
-
-<li class="indx">Automatic burners, <a href='#Page_170'>170</a>.</li>
-
-<li class="indx">Automatic burners, Adjustment, <a href='#Page_176'>176</a>.</li>
-
-
-<li class="ifrst">B</li>
-
-<li class="indx">Ballistic galvanometer, <a href='#Page_99'>99</a>.</li>
-
-<li class="indx">Barium platino cyanide, <a href='#Page_238'>238</a>.</li>
-
-<li class="indx">Base for coil, <a href='#Page_30'>30</a>.</li>
-
-<li class="indx">Bath coil, <a href='#Page_61'>61</a>.</li>
-
-<li class="indx">Battery, Bichromate, <a href='#Page_180'>180</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Champion, <a href='#Page_179'>179</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Daniell, <a href='#Page_191'>191</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Dun, <a href='#Page_187'>187</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Edison-Lalande, <a href='#Page_195'>195</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Fuller, <a href='#Page_184'>184</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Gas-lighting, <a href='#Page_179'>179</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Gethins, <a href='#Page_193'>193</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Gordon, <a href='#Page_194'>194</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Gravity, <a href='#Page_191'>191</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Grenet, <a href='#Page_180'>180</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Harrison, <a href='#Page_219'>219</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Monarch, <a href='#Page_179'>179</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Morisot, <a href='#Page_188'>188</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Novelty, <a href='#Page_182'>182</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Open circuit, <a href='#Page_178'>178</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Polarization, <a href='#Page_179'>179</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Samson, <a href='#Page_179'>179</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> solutions, <a href='#Page_185'>185</a>, <a href='#Page_188'>188</a>, <a href='#Page_189'>189</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Standard dry, <a href='#Page_196'>196</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Storage, <a href='#Page_200'>200</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Storage, to charge, <a href='#Page_208'>208</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Storage, to make, <a href='#Page_101'>101</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Storage, to seal, <a href='#Page_215'>215</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> U. S. storage, <a href='#Page_218'>218</a>.</li>
-
-<li class="indx">Beeswax, <a href='#Page_95'>95</a>.</li>
-
-<li class="indx">Brush, Electric, <a href='#Page_128'>128</a>.</li>
-
-
-<li class="ifrst">C</li>
-
-<li class="indx">Capacity of condenser, <a href='#Page_100'>100</a>.</li>
-
-<li class="indx">Carbons for battery, <a href='#Page_182'>182</a>.</li>
-
-<li class="indx">Cements, <a href='#Page_97'>97</a>.</li>
-
-<li class="indx">Charging condenser, <a href='#Page_110'>110</a>.</li>
-
-<li class="indx">Chromic acid, <a href='#Page_189'>189</a>.</li>
-
-<li class="indx">Closed magnetic circuit, <a href='#Page_6'>6</a>.</li>
-
-<li class="indx">Coherer, Aluminium, <a href='#Page_251'>251</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Branly, <a href='#Page_254'>254</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Carbon, <a href='#Page_256'>256</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Steel ball, <a href='#Page_258'>258</a>.</li>
-
-<li class="indx">Coil, Failure to work, <a href='#Page_49'>49</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> for gas engine, <a href='#Page_37'>37</a>.</li>
-
-<li class="indx"><span class="pagenum" id="Page_267">267</span><span class="ditto">"</span> general remarks, <a href='#Page_42'>42</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> in series, <a href='#Page_32'>32</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Medical, <a href='#Page_51'>51</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Oil immersed, <a href='#Page_33'>33</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Output of, <a href='#Page_46'>46</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Primary, <a href='#Page_7'>7</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Resistance, <a href='#Page_40'>40</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Secondary, <a href='#Page_10'>10</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Table of dimensions, <a href='#Page_50'>50</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Tesla, <a href='#Page_35'>35</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Testing, <a href='#Page_44'>44</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> To select, <a href='#Page_46'>46</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Winding, <a href='#Page_20'>20</a>.</li>
-
-<li class="indx">Condensers, Aluminium, <a href='#Page_115'>115</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Adjustable, <a href='#Page_117'>117</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Charging, <a href='#Page_110'>110</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> capacity, 100, <a href='#Page_119'>119</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Discharge of, <a href='#Page_225'>225</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Glass, <a href='#Page_101'>101</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Mica, <a href='#Page_108'>108</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Oil, <a href='#Page_116'>116</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Paper, 105, <a href='#Page_107'>107</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Rolled up, <a href='#Page_115'>115</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Series, <a href='#Page_108'>108</a>.</li>
-
-<li class="indx">Cone vibrator, <a href='#Page_88'>88</a>.</li>
-
-<li class="indx">Contact breaker, <a href='#Page_26'>26</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Adjustable medical, <a href='#Page_85'>85</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Adjustable cone, <a href='#Page_88'>88</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Dessauer, <a href='#Page_80'>80</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Electrolytic, <a href='#Page_77'>77</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Highspeed, <a href='#Page_69'>69</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> in vacuo, <a href='#Page_81'>81</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Polechanging, <a href='#Page_73'>73</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Queen, <a href='#Page_83'>83</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Queen, large form, <a href='#Page_84'>84</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Steel ribbon, <a href='#Page_80'>80</a>.</li>
-
-<li class="indx">Contacts, Care of, <a href='#Page_90'>90</a>.</li>
-
-<li class="indx">Core, <a href='#Page_4'>4</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Iron filing, <a href='#Page_46'>46</a>.</li>
-
-<li class="indx">Crookes tube, <a href='#Page_241'>241</a>.</li>
-
-
-<li class="ifrst">D</li>
-
-<li class="indx">Dessauer contact breaker, <a href='#Page_80'>80</a>.</li>
-
-<li class="indx">Dielectric, <a href='#Page_104'>104</a>.</li>
-
-<li class="indx">Discharger, <a href='#Page_26'>26</a>.</li>
-
-<li class="indx">Dry cell, <a href='#Page_196'>196</a>.</li>
-
-<li class="indx">Dun cell, <a href='#Page_187'>187</a>.</li>
-
-
-<li class="ifrst">E</li>
-
-<li class="indx">Eddy currents, <a href='#Page_6'>6</a>.</li>
-
-<li class="indx">Edison-Lalande cell, <a href='#Page_195'>195</a>.</li>
-
-<li class="indx">Electric sand, <a href='#Page_189'>189</a>.</li>
-
-<li class="indx">Electrode, <a href='#Page_190'>190</a>.</li>
-
-<li class="indx">Electrolyte, <a href='#Page_213'>213</a>.</li>
-
-<li class="indx">Electrolytic interrupter, <a href='#Page_77'>77</a>.</li>
-
-<li class="indx">Ends for coil, <a href='#Page_25'>25</a>.</li>
-
-<li class="indx">Extra current, <a href='#Page_3'>3</a>.</li>
-
-
-<li class="ifrst">F</li>
-
-<li class="indx">Farad, <a href='#Page_100'>100</a>.</li>
-
-<li class="indx">Fluoroscope, <a href='#Page_239'>239</a>.</li>
-
-<li class="indx">Fluorescence, <a href='#Page_137'>137</a>.</li>
-
-<li class="indx">Foucault currents, <a href='#Page_6'>6</a>.</li>
-
-<li class="indx">Frauenhofer lines, <a href='#Page_135'>135</a>.</li>
-
-<li class="indx">Frontispiece, Notes on, <a href='#Page_42'>42</a>, <a href='#Page_47'>47</a>.</li>
-
-
-<li class="ifrst">G</li>
-
-<li class="indx">Galvanometer, <a href='#Page_99'>99</a>.</li>
-
-<li class="indx">Gas burners, <a href='#Page_170'>170</a>.</li>
-
-<li class="indx"><span class="pagenum" id="Page_268">268</span><span class="ditto">"</span> engine coil, <a href='#Page_39'>39</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> from water, <a href='#Page_44'>44</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> lighting, <a href='#Page_164'>164</a>.</li>
-
-<li class="indx">Gassiot star, <a href='#Page_153'>153</a>.</li>
-
-<li class="indx">Geissler tube, <a href='#Page_159'>159</a>.</li>
-
-<li class="indx">Glass, To pierce, <a href='#Page_130'>130</a>.</li>
-
-<li class="indx">Gordon battery, <a href='#Page_194'>194</a>.</li>
-
-
-<li class="ifrst">H</li>
-
-<li class="indx">Harrison cell, <a href='#Page_219'>219</a>.</li>
-
-<li class="indx">Hertz resonator, <a href='#Page_226'>226</a>.</li>
-
-<li class="indx">Hydrometer, <a href='#Page_211'>211</a>.</li>
-
-<li class="indx">Hysteresis, <a href='#Page_6'>6</a>.</li>
-
-
-<li class="ifrst">I</li>
-
-<li class="indx">Induction, <a href='#Page_1'>1</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Self, <a href='#Page_8'>8</a>.</li>
-
-<li class="indx">Insulations, <a href='#Page_97'>97</a>.</li>
-
-
-<li class="ifrst">L</li>
-
-<li class="indx">Leyden jars, <a href='#Page_99'>99</a>.</li>
-
-<li class="indx">Lighting gas, <a href='#Page_164'>164</a>.</li>
-
-
-<li class="ifrst">M</li>
-
-<li class="indx">Magnetic circuit, Closed, <a href='#Page_6'>6</a>.</li>
-
-<li class="indx">Medical coils, <a href='#Page_51'>51</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> Care of, <a href='#Page_62'>62</a>.</li>
-
-<li class="indx">Mercury contact breaker, <a href='#Page_71'>71</a>.</li>
-
-<li class="indx">Mica condenser, <a href='#Page_61'>61</a>.</li>
-
-
-<li class="ifrst">N</li>
-
-<li class="indx">Noise of contact breaker, <a href='#Page_63'>63</a>.</li>
-
-
-<li class="ifrst">O</li>
-
-<li class="indx">Oil, Capacity of, <a href='#Page_119'>119</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Coil immersion, <a href='#Page_33'>33</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> for oscillator, <a href='#Page_260'>260</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Linseed, <a href='#Page_93'>93</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Resin, <a href='#Page_96'>96</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Spark through, <a href='#Page_95'>95</a>.</li>
-
-<li class="indx">Oscillator, <a href='#Page_258'>258</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Clarkes, <a href='#Page_259'>259</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Triple, <a href='#Page_259'>259</a>.</li>
-
-<li class="indx">Output of coil, <a href='#Page_46'>46</a>.</li>
-
-
-<li class="ifrst">P</li>
-
-<li class="indx">Paper condenser, <a href='#Page_107'>107</a>.</li>
-
-<li class="indx">Paraffin, <a href='#Page_94'>94</a>.</li>
-
-<li class="indx">Phosphorus tube, <a href='#Page_239'>239</a>.</li>
-
-<li class="indx">Photography, X-Ray, <a href='#Page_245'>245</a>.</li>
-
-<li class="indx">Pocket coil, <a href='#Page_89'>89</a>.</li>
-
-<li class="indx">Polarity tests, <a href='#Page_45'>45</a>.</li>
-
-<li class="indx">Pole, <a href='#Page_190'>190</a>.</li>
-
-<li class="indx">Polechanging switch, <a href='#Page_32'>32</a>.</li>
-
-<li class="indx">Polechanging contact breaker, <a href='#Page_73'>73</a>.</li>
-
-<li class="indx">Primary coil, <a href='#Page_7'>7</a>.</li>
-
-
-<li class="ifrst">Q</li>
-
-<li class="indx">Queen contact breaker, <a href='#Page_83'>83</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Crookes tube, <a href='#Page_241'>241</a>.</li>
-
-
-<li class="ifrst">R</li>
-
-<li class="indx">Radiography, <a href='#Page_245'>245</a>.</li>
-
-<li class="indx">Reel ends, <a href='#Page_25'>25</a>.</li>
-
-<li class="indx">Resistance coils, <a href='#Page_40'>40</a>.</li>
-
-<li class="indx">Resonance, Electric, <a href='#Page_226'>226</a>.</li>
-
-<li class="indx">Resonator, Hertz, <a href='#Page_226'>226</a>.</li>
-
-<li class="indx">Rheotome, <a href='#Page_2'>2</a>.</li>
-
-<li class="indx">Roentgen Ray apparatus, <a href='#Page_236'>236</a>.</li>
-
-<li class="indx">Rotating wheel, <a href='#Page_154'>154</a>.</li>
-
-
-<li class="ifrst">S</li>
-
-<li class="indx">Series, Coils in, <a href='#Page_32'>32</a>.</li>
-
-<li class="indx">Selection of coil, <a href='#Page_46'>46</a>.</li>
-
-<li class="indx">Shellac, <a href='#Page_96'>96</a>.</li>
-
-<li class="indx">Signs, Battery, <a href='#Page_190'>190</a>.</li>
-
-<li class="indx">Soda, Bichromate of, <a href='#Page_183'>183</a>.</li>
-
-<li class="indx">Spark, Electric, <a href='#Page_120'>120</a>.</li>
-
-<li class="indx"><span class="pagenum" id="Page_269">269</span><span class="ditto">"</span> Choice of, <a href='#Page_47'>47</a>.</li>
-
-<li class="indx">Spectroscope, <a href='#Page_132'>132</a>.</li>
-
-<li class="indx">Spectrum, Solar, <a href='#Page_132'>132</a>.</li>
-
-<li class="indx">Standard dry cell, <a href='#Page_196'>196</a>.</li>
-
-<li class="indx">Sulphating, <a href='#Page_215'>215</a>.</li>
-
-<li class="indx">Switch, Polechanging, <a href='#Page_32'>32</a>.</li>
-
-
-<li class="ifrst">T</li>
-
-<li class="indx">Table of cost, <a href='#Page_191'>191</a>.</li>
-
-<li class="indx">Tesla coil, <a href='#Page_35'>35</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> <span class="ditto">"</span> disruptive, <a href='#Page_36'>36</a>.</li>
-
-<li class="indx">Testing polarity, <a href='#Page_46'>46</a>.</li>
-
-<li class="indx">Transformer, <a href='#Page_5'>5</a>.</li>
-
-<li class="indx">Tube, Insulating, <a href='#Page_9'>9</a>.</li>
-
-
-<li class="ifrst">U</li>
-
-<li class="indx">U. S. storage cell, <a href='#Page_218'>218</a>.</li>
-
-
-<li class="ifrst">V</li>
-
-<li class="indx">Vacuum, Adjusting, <a href='#Page_242'>242</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Choice of, <a href='#Page_243'>243</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Contact breaker, <a href='#Page_81'>81</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> To procure, <a href='#Page_141'>141</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> pumps, <a href='#Page_140'>140</a>.</li>
-
-
-<li class="ifrst">W</li>
-
-<li class="indx">Water, Decomposition of, <a href='#Page_44'>44</a>.</li>
-
-<li class="indx">Wax, <a href='#Page_95'>95</a>.</li>
-
-<li class="indx">Wehnelt interrupter, <a href='#Page_77'>77</a>.</li>
-
-<li class="indx">Wheel, Rotating, <a href='#Page_154'>154</a>.</li>
-
-<li class="indx">Winder, Coil, <a href='#Page_16'>16</a>.</li>
-
-<li class="indx">Winding coils, <a href='#Page_20'>20</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Secondary, 10, <a href='#Page_14'>14</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Sectional, <a href='#Page_11'>11</a>.</li>
-
-<li class="indx">Wire for secondary coil, <a href='#Page_24'>24</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> "&nbsp; primary coil, <a href='#Page_9'>9</a>.</li>
-
-<li class="indx">Wires, Air, <a href='#Page_262'>262</a>.</li>
-
-<li class="indx">Wireless telegraphy, <a href='#Page_248'>248</a>.</li>
-
-<li class="indx">Wireless telegraphy circuit, <a href='#Page_250'>250</a>.</li>
-
-
-<li class="ifrst">X</li>
-
-<li class="indx">X-Ray apparatus, <a href='#Page_236'>236</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> Remarks, <a href='#Page_243'>243</a>.</li>
-
-<li class="indx"><span class="ditto">"</span> photographs, <a href='#Page_246'>246</a>.</li>
-</ul></div>
-
-<hr class="chap" />
-
-<p><span class="pagenum" id="Page_270">270</span></p>
-
-
-
-
-<div class="chapter">
-<h2 id="BIBLIOGRAPHY">BIBLIOGRAPHY</h2>
-</div>
-
-<p class="center"><i>GENERAL REFERENCE</i></p>
-
-<div class="hang">
-
-<p>Electricity, Its Theory, Sources and Applications,
-<small>by <span class="smcap">John T. Sprague</span>. 3rd edition.</small></p>
-
-<p>Induction Coils and Coil Making,<small> by <span class="smcap">F. C. Allsop</span>.</small></p>
-
-<p>The Construction of Large Induction Coils,
-<small>a Workshop Handbook, by <span class="smcap">A. Thare</span>. Illustrated.</small></p>
-
-<p>A Manual of Electricity,<small> by <span class="smcap">H. M. Noad</span>, Ph.D.
-London, 1859. (<i>Scarce.</i>)</small></p>
-
-<p>Practical Electrics.</p>
-
-<p>Sloane's Electrical Dictionary.</p>
-
-<p>Houston's Electrical Dictionary.</p>
-
-<p>Electricity and Magnetism,<small> by <span class="smcap">Prof. Silvanus P.
-Thompson</span>.</small></p>
-
-
-<p class="center"><i>BATTERIES</i></p>
-
-<p>Small Accumulators and How to Make Them,<small> by
-<span class="smcap">P. Marshall</span></small>.</p>
-
-<p>Primary Batteries, <small>by <span class="smcap">H. S. Carhart</span></small>.</p>
-
-<p>Practical Electrics.</p>
-
-<p>Electric Batteries, How to Make Them,<small> by <span class="smcap">P.
-Marshall</span>.</small></p>
-
-
-<p class="center"><i>WIRELESS TELEGRAPHY</i></p>
-
-<p>A History of Wireless Telegraphy, <small>by <span class="smcap">J. J. Fahie</span></small>.</p>
-
-<p>Improvements in Magnetic Space Telegraphy,
-Telegraphing by Magnetic Induction, and
-Aetheric Telegraphy, <small>by <span class="smcap">Sir W. H. Preece</span>,
-<span class="smcap">S. Evershed</span>, and <span class="smcap">Oliver Lodge</span></small>.</p>
-
-<p>Science Abstracts, Physics and Electrical Engineering.</p>
-
-<p>The Model Engineer and Amateur Electrician.</p>
-</div>
-<hr class="chap" />
-<div class="chapter"></div>
-
-<div class="narrow">
-<p class="center xxl">Queen Instruments</p>
-
-
-<p><span class="xl u">Induction Coils</span> capable of producing thick,
-heavy sparks from 60" to
-¼" in length. Made in 15
-different styles for either direct or alternating currents
-of any voltage.</p>
-
-<p><span class="xl u">X Ray Tubes</span> which have an automatic
-vacuum regulating device
-by means of which rays of
-penetrating power can be obtained. Our tubes have
-large, clear bulbs with a great current capacity and
-sharp definition.</p>
-
-<p><span class="xl">Fluoroscopes</span> of Platino Barium Cyanide
-or Calcium Tungstate with
-removable screens. Permanent
-and brilliant.</p>
-
-<p><span class="xl u">Accessories</span>—such as <b>Tube Stands</b>, <b>Independent
-Vibrators</b>, <b>Wehnelt
-Interrupters</b>, <b>Localization Apparatus</b>,
-<b>Protecting Screens</b>, <b>Radiographic Table</b>, <b>X Ray
-Plates</b>, <b>Storage Batteries</b>, <b>Motor Transformers</b>, <b>Archives of
-the Roentgen Ray</b>—everything to make X Ray Work
-simple and successful.</p>
-
-
-<p class="center"><big>Electrical Testing Instruments, Meters,
-Photometric Apparatus</big></p>
-
-
-<p class="center"><span class="xl">Queen &amp; Co.</span> (Incorporated)<br />
-
-J. G. GRAY, President</p>
-
-<p>
-1010 Chestnut Street<br />
-Philadelphia, Pa.</p>
-<p>59 Fifth Avenue<br />
-New York</p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<table border="0" cellpadding="4" cellspacing="1" summary="">
-<tr>
- <td class="tdba">
- <span class="u"><big>The</big></span><br />
- <span class="xxl">&nbsp; American &nbsp;<br />
- &nbsp; Inventor. &nbsp;</span></td>
- <td class="tdba">
- <small>PUBLISHED AT<br />
- 1302<br />
- F. Street, N. W.<br />
- Washington, D. C.<br />
- The first and fifteenth<br />
- of every<br />
- month.</small></td>
-</tr>
-
-<tr>
- <td class= "tdbtrl" colspan="2">
- <div class="small">
-
- <p class="center">Is the recognized medium between<br />
- Capital and Industry.</p>
-
- <p><span class="u">It reaches</span></p>
-
- <div class="center">
- <table border="0" cellpadding="4" cellspacing="0" summary="">
- <tr>
- <td align="left">THE MANUFACTURER,</td>
- <td align="left">THE ARCHITECT,</td>
- </tr>
- <tr>
- <td align="left">THE CAPITALIST,</td>
- <td align="left">THE CONTRACTOR,</td>
- </tr>
- <tr>
- <td align="left">THE PROMOTOR,</td>
- <td align="left">THE INVENTOR,</td>
- </tr>
- </table></div></div>
- </td>
-</tr>
-
-<tr>
-<td class="tdbbrl" colspan="2">
- <p class="center small">THE PEOPLE WHO HAVE MONEY TO SPEND.<br />
- THE PEOPLE WHO SPEND IT.</p>
-
- <p class="hang xs">Subscription price $1.00 a year ($2.00 foreign), and agents
- wanted on liberal commission in all sections of the country
- and Europe. Send for sample copy. Advertising rates, as
- per published card, furnished on application.</p></td>
-</tr>
-<tr>
- <td class="tdba" colspan="2">
- Address<br />
- The American Inventor,<br />
- 1302 F. St., N.W., &nbsp; Washington, D.C., U.S.A.</td>
-</tr>
-</table>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center">The <span class="smcap xl">Gas-Engine Handbook</span></p>
-
-<p class="center"><b>By E. W. ROBERTS, M.E.</b></p>
-
-<p class="center small">has established itself as a standard of reference in</p>
-
-<p class="center">GAS ENGINERY.</p>
-<div class="small">
-<p class="center"><b>2,000 Copies sold in one year.</b></p>
-
-
-<p>The book contains 234 pages of just the kind of
-information you have been looking for on gas engines.
-It explains their principles of operation their
-faults and the remedies which apply, how to run
-them, how to design them and how to make a complete
-test. All rules and formulas are simple and
-easily understood by the average mechanic.</p>
-
-<p>"All the most essential information connected
-with the gas or gasoline engine."—<i>American Machinist.</i></p>
-
-<p>"The only practical book of its kind."—<i>Engineering
-and Mining Journal.</i></p>
-
-<p>"Eminently practical in character."—<i>American
-Electrician.</i></p>
-
-<p>"Just the kind of information the buyer and the
-user of a gas engine wants and finds most difficult to
-obtain."—<i>Mines and Minerals.</i></p>
-
-<p>"It discusses almost every phase of the subject."—<i>The
-Engineer.</i></p>
-
-<p>"All of the essentials of construction and operation
-are to be found in it."—<i>The Automobile Review.</i></p>
-
-<p>The book is published in handy pocket size 3½ × 5½
-inches and is handsomely bound in flexible leather.</p>
-
-<p class="center"><b>Sent prepaid to any address for $1.50</b></p></div>
-
-
-<p class="center"><big>The Gas Engine Publishing Co</big>.</p>
-
-<p class="center"><small>ALSO PUBLISHERS OF</small></p>
-
-<p class="center">THE GAS ENGINE MAGAZINE,</p>
-
-<p class="center">
-<span class="gap10">330 West Ninth St.,</span> CINCINNATI, O.
-</p>
-
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<div class="bbox">
-<p class="center"><span class="xl">No. 1. Harrison Cell</span></p>
-
-<p class="center">THE MOST POWERFUL OPEN CIRCUIT
-CELL MADE.</p>
-
-
-<div class="center">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td>E. M. F.</td>
- <td rowspan="8"><img src="images/i_274.jpg" alt="The Cell" /></td>
-<td>Capacity</td>
-</tr>
-<tr>
- <td>2.5</td>
- <td>40</td>
-</tr>
-<tr>
- <td>Volts.</td>
- <td>Ampere</td>
-</tr>
-<tr>
- <td></td>
- <td>Hours.</td>
-</tr>
-<tr>
- <td></td>
- <td></td>
-</tr>
-<tr>
- <td>No</td>
- <td>No</td>
-</tr>
-<tr>
- <td>Local</td>
- <td>Creeping</td>
-</tr>
-<tr>
- <td>Action.</td>
- <td>Salts.</td>
-</tr>
-</table></div>
-
-<p>Highly recommended for all kinds of open circuit work
-such as telephones, gas engines, bells, auto gas lighting,
-and for medical outfits. Guaranteed to do all that is
-claimed for it.</p>
-
-
-<p class="center">
-<big>HARRISON BROS. &amp; CO., Incorporated</big>.<br />
-<span class="gap5">PHILADELPHIA.</span> <span class="gap5">CHICAGO.</span> NEW YORK.<br />
-<small>J. H. LEHMAN,<br />
-<span class="gap5">Manager of Electrical Department,</span> 102 Times Building, New York.</small></p>
-</div>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><span class="u"><big>Mesco Dry Battery</big></span></p>
-
-<div class="figleft" >
-<img src="images/i_275a.jpg" alt="The battery" />
-</div>
-<p><big>OVER 1,000,000
-SOLD ANNUALLY</big></p>
-<div class="small">
-<p>Can be purchased in all cities
-and most towns in the United
-States of Electric Supply dealers.
-Price low as worthless dry batteries.
-We are the largest manufacturers
-of general electric supplies
-in this country. Catalogue issued
-yearly.</p>
-
-<p>Manhattan Electrical
-Supply Co.==========</p>
-
-<p>32 Cortlandt Street, New York</p></div>
-<hr class="full" />
-
-<p class="center"><big>TO OUR READERS</big></p>
-
-<p class="hang"><i>ARE YOU IN THE MARKET FOR</i><br />
-COILS, X-RAY TUBES, BATTERIES, OR
-ANY ELECTRICAL APPARATUS?</p>
-
-<p class="hang"><i>IF SO</i><br />
-Send to our advertisers for their catalogues
-and prices before buying.</p>
-<hr class="full" />
-
-
-<div class="center">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td align="left">X-Ray Coils</td>
-<td align="center" rowspan="4"><img src="images/i_275.jpg" alt="A coil" /></td>
-</tr>
-<tr>
- <td align="left">&nbsp; Telephone Coils</td>
-</tr>
-<tr>
- <td align="left">Medical Coils</td>
-</tr>
-<tr>
- <td align="left">&nbsp; &nbsp;Spark Coils</td>
-</tr>
-</table></div>
-
-<p class="center"><small>MAGNET WINDING OF EVERY DESCRIPTION</small><br />
-
-C. F. SPLITDORF, 17-27 Vandewater St., New York</p>
-
-<hr class="chap" />
-<p class="center">
-<big>New Standard Oil, Gas and Gasoline<br />
-Engine Outfit</big> <small>Consisting of</small> ...
-</p>
-<div class="small">
-<div class="center">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr>
- <td align="left">New Standard</td>
- <td align="left"> "Autogas" Dry Battery,</td>
- <td align="right">$5.00</td>
-</tr>
-<tr>
- <td align="left">&nbsp; " &nbsp; &nbsp; &nbsp; "</td>
- <td align="left">Jump Spark Coil,</td>
- <td align="right">12.00</td>
-</tr>
-<tr>
- <td align="left">&nbsp; " &nbsp; &nbsp; &nbsp; "</td>
- <td align="left">Insulated Cam-Contact Key,</td>
- <td align="right">3.50</td>
-</tr>
-<tr>
- <td align="left">&nbsp; " &nbsp; &nbsp; &nbsp; "</td>
- <td align="left">Double Porcelain Insulated Ignition Plug,</td>
- <td align="right">6.00</td>
-</tr>
-</table></div>
-
-<p class="center"><small>If you are interested write for descriptive pamphlet</small>.</p>
-
-<p class="center">WILLIAM ROCHE, Inventor and Sole Mfr., 42 VESEY ST., NEW YORK CITY</p>
-
-<p class="center"><small>We also manufacture other good and useful appliances to be operated with dry cells</small>.</p>
-</div>
-<hr class="full" />
-<p class="center"><span class="xl"><i>GOOD BOOKS</i></span></p>
-
-<div class="hang">
-
-<p><b>The French Polishers Manual</b>, <small>full directions for polishing
-by a French Polisher. Paper, - 20 cts.</small></p>
-
-<p><b>The A. B. C. of Dynamo Design</b>, <small>by <span class="smcap">Alfred H. Avery</span>,
-with drawings and illustrations. 12mo, cloth, - 40 cts.</small></p>
-
-<p><b>Electric Batteries, How to make and Use Them</b>, <small>by <span class="smcap">P.
-Marshall</span>. 12mo, illustrated. Paper, - 25 cts.</small></p>
-
-<p><b>Metal Turning.</b> <small>Practical lessons in Metal Turning.
-A handbook for young engineers and amateurs, by
-<span class="smcap">P. Marshall</span>. Fully illustrated, cloth, - 80 cts.</small></p>
-
-<p><b>The A. B. C. of Electricity</b>, <small>by <span class="smcap">W. H. Meadowcroft</span>.
-Fully illustrated, 12mo, cloth, - 50 cts.</small></p>
-
-<p><b>Magnetism and Electricity</b>, <small>by <span class="smcap">John Cook</span>. A good
-book for beginners. Illustrated, 16mo, cloth, - 40 cts.</small></p>
-
-<p><b>Lightning Protection</b>,<small> a practical treatise on, by <span class="smcap">H. W.
-Spang</span>. Illustrated, 12mo, cloth, - 75 cts.</small></p>
-</div>
-
-
-<p class="center"><span class="xs"><i>We will mail copies of any book, postpaid, on receipt of price.</i></span></p>
-
-<p class="center"><i><span class="xl">SPON &amp; CHAMBERLAIN</span>, Publishers</i></p>
-
-<p class="center"><i>12 Cortlandt Street, New York, U. S. A.</i></p>
-
-<p class="center"><span class="xs">When writing to advertisers please mention <span class="smcap">Norrie's Coils</span>.</span></p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center">Published Monthly.</p>
-
-<p class="center xl">SCIENCE ABSTRACTS.</p>
-
-<p class="center"><span class="smcap">Physics and Electrical Engineering.</span></p>
-
-<hr class="full" />
-<div class="small">
-<p>The object of this magazine is to make abstracts of
-all important papers read before the various Scientific
-Societies or published in the different Proceedings
-or Transactions of such societies, and also of all
-important papers and articles printed in American
-and foreign Technical Journals and Scientific Periodicals
-and to classify and index the same.</p>
-
-<p><b>Science Abstracts</b> will thus keep abreast of
-the times and place before the librarian, the busy
-engineer or the scientist in a compact and handy
-form, a complete digest of all the latest information on</p>
-
-<p>
-General Physics, Light, Heat,<br />
-Sound, Electricity, Electro-Chemistry<br />
-and Chemical Physics, General Electrical<br />
-Engineering, Dynamos, Motors<br />
-and Transformers, Power Distribution,<br />
-Traction and Lighting, Telegraphy and<br />
-Telephony, Steam Plants, Gas Engines,<br />
-Oil Engines and Motor Cars of all kinds.<br />
-</p>
-
-<p class="center">With Index to Abstracts, Index to Authors.</p>
-</div>
-<p class="center">Annual Subscription, $6.00, Post-paid.</p>
-
-<hr class="small" />
-<p class="center"><big>SPON &amp; CHAMBERLAIN</big>,<br />
-
-<small>Sole American Agents,</small><br />
-
-12 Cortlandt Street, New York, U. S. A.</p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><i>SAMPLE COPIES MAILED TO ANY ADDRESS
-ON RECEIPT OF 8 CENTS.</i></p>
-
-<div class="figcenter" >
-<img src="images/i_278.jpg" alt="" />
-</div>
-
-<p class="center">
-THE<br />
-MODEL ENGINEER<br />
-AND<br />
-AMATEUR ELECTRICIAN<br />
-<br />
-<span class="smcap">A Journal of Mechanics and<br />
-Electricity <sup>for</sup> Amateurs <sup>and</sup> Students</span><br />
-</p>
-
-
-<p class="center"><span class="smcap xs">Edited by</span> PERCIVAL MARSHALL</p>
-
-
-<p>ITS GOOD POINTS.</p>
-<div class="small"> <p>Better than any paper of its kind ever published.</p>
-
-<p>The articles are original and practical.</p>
-
-<p>The articles are so clearly and simply written and everything
-made so plain that it will be found easy to follow the
-directions and duplicate the articles described.</p>
-
-<p>Special articles on Model engines and boilers for yachts,
-torpedo-boats and war-ships.</p>
-
-<p>Designing and building of model yachts and boats.</p>
-
-<p>Making small tools for model work.</p>
-
-<p>The building of small gas engines.</p>
-
-<p>Building screw-cutting and turning lathes.</p>
-
-<p>Building all kinds of model stationary and locomotive
-steam engines and boilers.</p>
-
-<p>Model engineers and their work.</p>
-
-<p>Building of all kinds of electrical machines, apparatus,
-coils, batteries, telephones, microphones, phonographs, novelties.</p>
-
-<p>The articles are fully illustrated, principally with detail
-drawings to scale.</p>
-
-<p>New Books, Notes and Queries, Workshop Notes and
-Hints, Tools and Supplies,, etc.</p>
-
-<p class="center">ANNUAL SUBSCRIPTION, $1.50 POSTPAID.</p>
-
-<p><i>Send in your subscription and get your friends to subscribe.
-Unused postage stamps will be accepted (not revenue.) Address
-all communications to</i></p></div>
-
-<p class="center"><big>SPON &amp; CHAMBERLAIN</big>,</p>
-
-<p class="center">
-<span class="gap10">12 Cortlandt Street,</span> NEW YORK.<br />
-</p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><big>USEFUL BOOKS</big></p>
-
-<hr class="small" />
-
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-
-<tr>
- <td class="tdh"><b>Barometer.</b>—The barometrical determination
-of heights. A practical method of barometrical
-levelling and hypsometry, for
-surveyors and mountain climbers. By Dr.
-F. J. B. Cordeiro, U. S. N. 12mo, leather,</td>
-
-<td class="tdrb">$1.00</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Dynamo.</b>—Notes on the design of small
-dynamo, with complete set of drawings to
-scale. By G. Halliday. 79 pages, illustrated,
-8vo, cloth,</td>
-
-<td class="tdrb">1.00‡</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Electric Bells.</b>—A treatise on the construction
-of electric bells, indicators and similar apparatus.
-By F. C. Allsop. 131 pages, 177
-illustrations, 12mo, cloth,</td>
-
-<td class="tdrb">1.25</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Electric Bells.</b>—Practical electric bell fitting.
-A treatise on the fitting up and maintenance
-of electric bells and all their necessary apparatus.
-By F. C. Allsop. 170 pages,
-186 illustrations, 12mo, cloth,</td>
-
-<td class="tdrb">1.25</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Electrical Notes.</b>—Practical electrical notes
-and definitions, for the use of engineering
-students and practical men. By W. Perren
-Maycock, E.E. 286 pages, illustrated,
-32mo, cloth,</td>
-
-<td class="tdrb">.75</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Electricity.</b>—Comparisons between the different
-systems of distributing electricity. By
-Prof. Henry Robinson. 8vo, paper,</td>
-
-<td class="tdrb">.80</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Galvanometer.</b>—A series of lectures on the
-galvanometer and its uses, delivered by
-Prof. E. L. Nicols, and used by him in his
-class at Cornell University. 112 pages, 76
-illustrations, 8vo, paper,</td>
-
-<td class="tdrb">1.00</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Induction Coils</b>, and coil making. A treatise
-on the construction and working of shock,
-medical, and spark coils. By F. C. Allsop.
-172 Pages, 124 illustrations, 12mo, cloth,</td>
-
-<td class="tdrb">1.25</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Measurements.</b>—A systematic treatise on electrical
-measurements. By H. C. Parker.
-120 pages, 96 illustrations, 8vo, cloth,</td>
-
-<td class="tdrb">1.00‡</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Phonograph.</b>—The phonograph and how to
-construct it, and a chapter on sound, with
-full set of working drawings. 12mo, cloth,</td>
-
-<td class="tdrb">2.00</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Transformer.</b>—History of the transformer,
-translated from the German. By F. Uppenborn.
-60 pages, 31 illustrations, 12mo,</td>
-
-<td class="tdrb">.75</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Transformer.</b>—Transformer design, a treatise
-on their design, construction and use. By
-G. Adams. In the work the author has
-avoided as much as possible all historical
-matter and unnecessary mathematical problems,
-and has confined himself to practical
-experience. The work contains much information
-that will prove of value to the
-draughtsman, designer and electrical student.
-Second edition. 75 pages, 34 illustrations,
-12mo, cloth,</td>
-
-<td class="tdrb">1.50‡</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Telephones, etc.</b>—Their construction and fitting.
-A practical treatise on the fitting-up
-and maintenance of telephones and the
-auxiliary apparatus. By F. C. Allsop. 5th
-edition, 184 pages, 13 folding plates and 124
-illustrations, 12mo, cloth,</td>
-
-<td class="tdrb">1.25</td>
-</tr>
-
-<tr>
- <td class="tdh"><b>Magnets</b> and electric currents. An elementary
-treatise for the use of electricians and beginners.
-By J. A. Fleming, M.A., D.Sc.,
-F.R.S., 408 pages, illustrated, 12mo, cloth,</td>
-
-<td class="tdrb">3.00</td>
-</tr>
-</table></div>
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><span class="xxl">Workshop Receipts.</span></p>
-
-<p class="center"><small>THE MOST COMPLETE</small></p>
-
-<p class="center"><big>Technical Cyclopedia in 5 Vols.</big></p>
-<hr class="small" />
-<div class="small">
-<p><b><big>First Series.</big> Principal Contents.</b>—Bronzes, Cements,
-Dyeing, Electro-metallurgy,
-Enamels, Etchings, Fireworks, Fluxes, Fulminates, Gilding,
-Gums, Japanning, Lacquers, Marble Working, Nitro-Glycerine,
-Photography, Pottery, Varnishes. 420 pages, 103 illus.,
-cloth, $2.00.</p>
-
-<p><b><big>Second Series.</big> Principal Contents.</b>—Acidimetry,
-Albumen, Alcohol, Alkaloids,
-Bitters, Bleaching, Boiler Incrustations, Cleansing,
-Confectionery, Copying, Disinfectants, Essences, Extracts,
-Fire-proofing, Glycerine, Gut, Iodine, Ivory Substitutes,
-Leather, Matches, Pigments, Paint, Paper, Parchment. 485
-pages, 16 illus., cloth, $2.00.</p>
-
-<p><b><big>Third Series.</big> Principal Contents.</b>—Alloys, Aluminium,
-Antimony, Copper, Electrics,
-Enamels, Glass, Gold, Iron, Steel, Liquors, Lead, Lubricants,
-Magnesium, Manganese, Mercury, Mica, Nickel,
-Platinum, Silver, Slag, Tin, Uranium, Zinc. 480 pages, 183
-illus., cloth, $2.00.</p>
-
-<p><b><big>Fourth Series.</big> Principal Contents.</b>—Water-proofing,
-Packing, Stowing,
-Embalming, Preserving, Leather Polishes, Cooling Air and
-Water, Pumps and Siphons, Dessicating, Distilling, Emulsifying,
-Evaporating, Filtering, Percolating, Macerating,
-Electrotyping, Stereotyping, Book-binding, Straw-plaiting,
-Musical Instruments, Clock and Watch Mending, Photography.
-443 pages, 243 illus., cloth, $2.00.</p>
-
-<p><b><big>Fifth Series.</big> Principal Contents.</b>—Diamond Cutting,
-Laboratory Apparatus, Filtering,
-Magic Lanterns, Metal Work, Percolation, Illuminating
-Agents, Tobacco Pipes, Taps, Tying and Splicing Tackle,
-Repairing Books, Netting, Walking Sticks, Boat-Building.
-440 pages, 373 illus., cloth, $2.00.</p>
-</div>
-
-<p class="center"><b>EACH SERIES has its own Contents
-and Index and is complete in itself.</b></p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center xl">Cleaning and Scouring</p>
-
-<p class="center"><small>A MANUAL FOR</small></p>
-
-<p class="center"><big>DYERS AND LAUNDRESSES</big></p>
-
-<p class="center"><small>And for Domestic Use.</small></p>
-
-<p class="center"><i>BY S. CHRISTOPHER.</i></p>
-<hr class="small" />
-
-<p class="center">CONTENTS.</p>
-
-<div class="hang small">
-
-<p><span class="smcap">Dresses.</span>—Silk, Satin, Irish Poplin and Tabinet, Llama, Alpaca,
-Printed Muslin and Pique, Pique and Colored Muslin.</p>
-
-<p><span class="smcap">Shawls and Scarves.</span>—China Crape, Brocaded or Printed
-Silk, and Woolen.</p>
-
-<p><span class="smcap">Silk Handkerchiefs, Ribbons, Mantles, Fancy Waistcoats,
-and Lace. Gloves.</span>—Kid, Washleather.</p>
-
-<p><span class="smcap">Feathers.</span>—White, Colored; to purify—for Beds, &amp;c.</p>
-
-<p><span class="smcap">Bonnets.</span>—Chip, Straw, and Leghorn. <span class="smcap">Ancient Tapestry.</span></p>
-
-<p><span class="smcap">Curtains, Bed Furniture, &amp;c.</span>—Chintz, Damask, Worsted-and-cotton
-Damask, French Damask—Silk-and-worsted
-Moreen, Tabaret or Tabbarea, Satin, Tammy Lining,
-Fringes—Bullion and worsted, Lace and Gimp—Bullion.</p>
-
-<p><span class="smcap">Table Covers.</span>—Silk-and-worsted, Cotton-and-worsted, and
-Printed Cloth.</p>
-
-<p><span class="smcap">Carpets.</span>—Dry Cleaning, thorough Cleaning.</p>
-
-<p><span class="smcap">Hearthrugs, Sheepskin Rugs and Mats.</span></p>
-
-<p><span class="smcap">To Remove Various Stains from Linen and Cotton.</span>—Fruit
-Stains, Grease Spots, Ink Stains, Marking Ink, Mildew,
-Paint or Varnish, Wine Stains.</p>
-
-<p><span class="smcap">Recipes for general Domestic Use.</span>—Oilcloth, Paint,
-Floors, Marble, Iron and Steel, Brass or Copper, Silver
-Plate, Furniture, Gilt Frames, Ivory Ornaments, Mirrors,
-Wall-paper, Stone Steps.</p>
-
-<p><span class="smcap">Definitions, &amp;c.</span>—Boards, &amp;c., for French Cleaning, Camphine,
-Common Sour, Drying, Frame, French Board, Hot
-Stove, Irons, Parchment Size, Pegs, Puncher, Size, Soap,
-Starch, To Handle, To Sheet-up, Water.</p>
-
-<p class="center"><b>Price 20 cents, post-paid.</b></p></div>
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center xs"><small>THEORETICAL AND PRACTICAL</small></p>
-
-<p class="center xl">Ammonia Refrigeration</p>
-
-<p class="center"><i>A Work of Reference for Engineers and others Employed in the
-Management of Ice and Refrigeration Machinery.</i></p>
-
-<p class="center">By ILTYD I. REDWOOD</p>
-
-<div class="small">
-<p class="center">CONTENTS</p>
-
-<p>B. T. U. Mechanical Equivalent of a Unit of Heat.
-Specific Heat. Latent Heat. Theory of Refrigeration.
-Freezing, by Compressed Air. Ammonia. Characteristics
-of Ammonia. The Compressor. Stuffing-Boxes.
-Lubrication. Suction and Discharge Valves.
-Separator. Condenser-Worm, Receiver. Refrigerator
-or Brine Tank. Size of Pipe and Area of Cooling
-Surface. Charging the Plant with Ammonia. Jacket-Water,
-for Compressor, for Separator. Quantity of
-Condensing Water Necessary. Loss due to Heating
-of Condensed Ammonia. Cause of Variation in Excess
-Pressure. Use of Condensing Pressure in Determining
-Loss of Ammonia by Leakage. Cooling Directly
-by Ammonia. Freezing Point of Brine. Making
-Brine. Specific Heat of Brine. Regulation of
-Brine Temperature. Indirect Effect of Condensing
-Water on Brine Temperature. Directions for Determining
-Refrigerating Efficiency. Equivalent of a Ton
-of Ice. Compressor Measurement of Ammonia Circulated.
-Loss of Well-Jacketed Compressors. Loss in
-Double-Acting Compressors. Distribution of Mercury
-Wells. Examination of Working Parts. Indicator
-Diagrams. Ammonia Figures—Effectual Displacement.
-Volume of Gas. Ammonia Circulated per
-Twenty-Four Hours. Refrigerating Efficiency. Brine
-Figures-Gallons Circulated. Pounds Circulated. Degrees
-Cooled. Total Degrees Extracted. Loss due to
-Heating of Ammonia Gas. Loss due to Heating of
-Liquid Ammonia. Calculation of the Maximum Capacity
-of a Machine. Preparation of Anhydrous Ammonia.
-Construction of Apparatus, etc., etc.</p>
-
-
-<p class="center"><b>150 pages, 15 illustrations, cloth, $1.00.</b></p>
-</div>
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center xxl">LUBRICANTS,</p>
-
-<p class="center xl">OILS AND GREASES</p>
-
-<p class="center xs">Treated Theoretically and Giving Practical Information
-Regarding Their</p>
-
-<p class="center"><big>COMPOSITION, USES AND MANUFACTURE</big></p>
-
-<p class="center">BY ILTYD I. REDWOOD</p>
-<hr class="small" />
-
-<p class="center">CONTENTS</p>
-
-<div class="hang small">
-
-<p><span class="smcap">Introduction.</span>—Lubricants.</p>
-
-<p><span class="smcap">Theoretical.</span>—Chapter I. Mineral Oils: American
-and Russian; Hydrocarbons. Chapter II. Fatty
-Oils: Glycerides; Vegetable Oils; Fish Oils.
-Chapter III. Mineral Lubricants: Graphite;
-Plumbago. Chapter IV. Greases: Compounded;
-"Set" or Axle; "Boiled" or Cup. Chapter V.
-Tests of Oils: Mineral Oils. Fatty Oils.</p>
-
-<p><span class="smcap">Manufacture.</span>—Chapter VI. Mineral Oil Lubricants:
-Compounded Oils; Debloomed Oils.
-Chapter VII. Greases: Compounded Greases;
-"Set" or Axle Greases; Boiled Greases; Engine
-Greases. Appendix. The Action of Oils on
-Various Metals. Index.</p>
-
-<p><span class="smcap">Tables.</span>—I. Viscosity and Specific Gravity. II.
-Atomic Weights. III. Origin, Tests, Etc., of
-Oils. IV. Action of Oils on Metals.</p>
-
-<p><span class="smcap">List of Plates.</span>—I.—I. I. Redwood's Improved
-Set Measuring Apparatus. II. Section Grease
-Kettle. III. Diagram of the Action of Oils on
-Different Kinds of Metals.</p>
-</div>
-
-<p class="center"><small><b>8vo, cloth, $1.50.</b></small></p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center">PRACTICAL HANDBOOK ON</p>
-
-<p class="center xxl">Gas Engines</p>
-
-<p class="center">With Instructions for Care and Working of the Same.<br />
-
-<i>BY G. LIECKFELD, C.E.</i><br />
-
-<small>Translated with permission of the Author by<br />
-<i>GEORGE RICHMOND, M.E.</i></small><br />
-
-WITH A CHAPTER ON OIL ENGINES</p>
-
-<hr class="small" />
-<p class="center">CONTENTS</p>
-<div class="small">
-<p>Choosing and installing a gas engine. The construction
-of good gas engines. Examination as to
-workmanship, running, economy. Reliability and
-durability of gas engines. Proper erection of a
-gas engine. Foundation. Arrangement for gas pipes.
-Rubber bag. Locking devices. Exhaust pipes. Air
-pipes. Setting up gas engines. Brakes and their
-use in ascertaining the power of gas engines. Arrangement
-of a brake test. Distribution of heat in a
-gas engine. Attendance on gas engines. General
-remarks. Gas engine oil. Cylinder lubricators.
-Rules as to starting and stopping a gas engine. The
-cleaning of a gas engine. General observations and
-specific examination for defects. The engine refuses
-to work. Non-starting of the engine. Too much
-pressure on the gas. Water in the exhaust pot.
-Difficulty in starting the engine. Irregular running.
-Loss of power. Weak gas mixtures. Late ignition.
-Cracks in air inlet. Back firing. Knocking and
-pounding inside of engine. Dangers and precautionary
-measure in handling gas engines. Precautions
-when opening gas valves, removing piston from
-cylinder, examining with light openings of gas
-engines. Dangers in starting, cleaning, putting on
-belts. <b>Oil Engines.</b> Gas engines with producer gas.
-Gasoline and oil engines. Concluding remarks.</p>
-
-
-<p class="center"><b>120 pages, illustrated, 12mo, cloth, $1.00.</b></p>
-</div>
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><big>The Best and Cheapest in the Market</big></p>
-<hr class="small" />
-<p class="center xxl">ALGEBRA SELF-TAUGHT</p>
-
-<p class="center"><small>FOR THE USE OF</small><br />
-
-Mechanics, Young Engineers and Home Students</p>
-<hr class="small" />
-<p class="center"><i>BY W. PAGET HIGGS, M.A., D.Sc.</i></p>
-<hr class="small" />
-<p class="center">FOURTH EDITION</p>
-<hr class="small" />
-
-<p class="center">CONTENTS</p>
-<div class="small">
-<p>Symbols and the signs of operation. The equation
-and the unknown quantity. Positive and negative
-quantities. Multiplication, involution, exponents,
-negative exponents, roots, and the use of exponents
-as logarithms. Logarithms. Tables of logarithms
-and proportional parts. Transportation of systems
-of logarithms. Common uses of common logarithms.
-Compound multiplication and the binomial theorem.
-Division, fractions and ratio. Rules for division.
-Rules for fractions. Continued proportion, the series
-and the summation of the series. Examples. Geometrical
-means. Limit of series. Equations. Appendix.
-Index. 104 pages, 12mo, cloth, 60c.</p>
-<hr class="small" />
-
-<p><i>See also</i> <b>Algebraic Signs</b>, Spons' Dictionary of
-Engineering, No. 2. 40 cts.</p>
-
-<p><i>See also</i> <b>Calculus</b>, Supplement to Spons' Dictionary,
-No. 5. 75 cts.</p>
-</div>
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center">THE</p>
-
-<p class="center xxl">FIREMAN'S GUIDE</p>
-
-<p class="center">A Handbook on the Care of Boilers</p>
-
-<p class="center"><i>BY KARL P. DAHLSTROM, M.E.</i></p>
-
-<hr class="small" />
-<p class="center">CONTENTS OF CHAPTERS</p>
-<div class="small">
-<p><b>I. Firing and Economy of Fuel.</b>—Precautions
-before and after starting the fire, care of the fire,
-proper firing, draft, smoke, progress of firing, fuel on
-the grate, cleaning out, cleaning grate bars and ash
-pan, dampers, firing into two or more furnaces, dry
-fuel, loss of heat.</p>
-
-<p><b>II. Feed and Water Line.</b>—Feeding, the water
-line, false water line, defective feeding apparatus,
-formation of scale, gauge cocks, glass gauge, the
-float, safety plug, alarm whistle.</p>
-
-<p><b>III. Low Water and Foaming or Priming.</b>—Precautions
-when water is low, foaming, priming.</p>
-
-<p><b>IV. Steam Pressure.</b>—Steam gauge, safety valves.</p>
-
-<p><b>V. Cleaning and Blowing Out.</b>—Cleaning the
-boiler, to examine the state of the boiler, blowing
-out, refilling the boiler.</p>
-
-<p><b>VI. General Directions.</b>—How to prevent accidents,
-repairs, the care of the boiler when not in use,
-testing boilers, trimming and cleaning outside.
-Summary of rules. Index.</p>
-
-
-<p class="center">8vo, cloth, 50 cents.</p>
-</div>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center xl">THE CORLISS ENGINE.</p>
-
-<p class="center"><span class="smcap"><small>By John T. Henthorn.</small></span></p>
-
-<p class="center">AND</p>
-
-<p class="center"><big>MANAGEMENT OF THE CORLISS ENGINE.</big></p>
-
-<p class="center"><span class="smcap"><small>By Charles D. Thurber.</small></span></p>
-
-<p class="center"><i><small>Uniform in One Volume. Cloth Cover; Price, $1.00.</small></i></p>
-
-<hr class="small" />
-<p class="center">Table of Contents.</p>
-<div class="small">
-<p><span class="smcap">Chapter I.</span>—Introductory and Historical; Steam Jacketing.
-<span class="smcap">Chapter II.</span>—Indicator Cards. <span class="smcap">Chapter III.</span>—Indicator
-Cards continued; the Governor. <span class="smcap">Chapter IV.</span>—Valve
-Gear and Eccentric; Valve Setting. <span class="smcap">Chapter V.</span>—Valve
-Setting continued, with diagrams of same; Table
-for laps of Steam Valve. <span class="smcap">Chapter VI.</span>—Valve Setting
-continued. <span class="smcap">Chapter VII.</span>—Lubrication with diagrams
-for same. <span class="smcap">Chapter VIII.</span>—Discussion of the Air Pump
-and its Management. <span class="smcap">Chapter IX.</span>—Care of Main Driving
-Gears; best Lubricator for same. <span class="smcap">Chapter X.</span>—Heating
-of Mills by Exhaust Steam. <span class="smcap">Chapter XI.</span>—Engine
-Foundations; diagrams and templets for same. <span class="smcap">Chapter
-XII.</span>—Foundations continued; Materials for same, etc.</p>
-
-<hr class="small" />
-<p class="center">Third Edition, with an Appendix.</p>
-</div>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center">HOW TO RUN</p>
-
-<p class="center xxl">Engines and Boilers</p>
-
-<p class="center"><small>Practical Instruction for Young Engineers and
-Steam Users.</small></p>
-
-<p class="center"><i>BY EGBERT POMEROY WATSON</i></p>
-<hr class="small" />
-<p class="center">REVISED AND ENLARGED</p>
-<hr class="small" />
-<div class="small">
-<p class="center"><b>Synopsis of Contents</b></p>
-
-<p>Cleaning the boiler, removing scale, scale preventers,
-oil in boilers, braces and stays, mud drums
-and feed pipes, boiler fittings, grate bars and tubes,
-bridge walls, the slide valve, throttling engine, the
-piston, testing the slide valve with relation to the
-ports, defects of the slide valve, lap and lead, the
-pressure on a slide valve, stem connections to the
-valve, valves off their seats, valve stem guides, governors,
-running with the sun, eccentrics and connections,
-the crank pin, brass boxes, bearings on pins,
-adjustment of bearings, the valve and gearing, setting
-eccentrics, the actual operation, return crank
-motion, pounding, the connections, lining up engines,
-making joints, condensing engines, Torricelli's
-vacuum, proof of atmospheric pressure, pumps, no
-power in a vacuum, supporting a water column by
-the atmosphere, starting a new plant, the highest
-qualities demanded.</p>
-
-<p>Water tube boilers, fire tube boilers, why water
-tube boilers steam rapidly, torpedo boat boilers,
-management of water tube boilers, economy and
-maintenance of water tube boilers.</p>
-
-<p class="center"><b>150 pages, illustrated, 16mo, cloth, $1.00</b></p>
-</div>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center"><span class="u">GOOD AMERICAN PRACTICE.</span></p>
-
-<p class="center">AN</p>
-
-<p class="center">ELEMENTARY TEXT BOOK</p>
-
-<p class="center">ON</p>
-
-<p class="center">
-<span class="xxl">S</span><span class="u xl">TEAM</span> <span class="xl">E</span><span class="u"><big>NGINES</big> AND</span><br />
-<span class="xl">B</span><span class="u"><big>OILERS</big></span><br />
-</p>
-
-<p class="center">By J. H. KINEALY, M.E.</p>
-<div class="small">
-<p>A first class <b>American</b> Book for young Engineers
-and all those wishing to take a higher position.</p>
-
-
-<p class="center">CONTENTS OF CHAPTERS.</p>
-
-<p>1. Elementary Thermodynamics. 2. Theory of the
-Steam Engine. 3, Types and details of Engines. 4.
-Admission of Steam by Valve. 5. Valve diagrams.
-6. Indicator and indicator cards. 7. Compound Engines
-and condensers. 8. Heat and combustion of
-fuel. 9. Boilers, types, fittings, etc. 10. Chimneys.
-<span class="smcap">Appendix.</span> Care of Boilers, Tables, Numerous Problems
-with answers.</p>
-
-<p><b>Third</b> edition, (1901), thoroughly revised to date
-and considerably enlarged.</p>
-
-
-<p class="center">259 pages, 108 illustrations, size 9¼ × 6¼.<br />
-
-Cloth, $2.00‡</p>
-</div>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><span class="xl">THE SLIDE VALVE</span><br />
-
-<big>SIMPLY EXPLAINED</big><br />
-
-<span class="smcap">By</span> W. J. TENNANT, Asso. M.I.M.E.</p>
-
-<p class="center"><small>REVISED AND MUCH ENLARGED</small><br />
-
-<span class="smcap">By</span> J. H. KINEALY, D.E.</p>
-<hr class="small" />
-
-
-<div class="center small">
-<table border="0" cellpadding="4" cellspacing="0" summary="">
-<tr><th colspan="2">CONTENTS OF CHAPTERS:</th></tr>
-<tr>
- <td class="tdrt">I.</td>
- <td class="hang">The Simple Slide.</td>
-</tr>
-
-<tr>
- <td class="tdrt">II.</td>
- <td class="hang">The Eccentric a Crank. Special Model to<br />
-Give Quantitative Results.</td>
-</tr>
-<tr>
- <td class="tdrt">III.</td>
- <td class="hang">Advance of the Eccentric.</td>
-</tr>
-<tr>
- <td class="tdrt">IV.</td>
- <td class="hang">Dead Centre. Order of Cranks. Cushioning</td>
-</tr>
-
-<tr>
- <td class="tdrt">V.</td>
- <td class="hang">Expansion—Inside and Outside Lap and
-Lead; Advance Affected Thereby. Compression.</td>
-</tr>
-<tr>
- <td class="tdrt">VI.</td>
- <td class="hang">Double-Ported and Piston Valves.</td>
-</tr>
-<tr>
- <td class="tdrt">VII.</td>
- <td class="hang">The Effect of Alterations to Valve and
-Eccentric.</td>
-</tr>
-<tr>
- <td class="tdrt">VIII.</td>
- <td class="hang">Note on Link Motions.</td>
-</tr>
-<tr>
- <td class="tdrt">IX.</td>
- <td class="hang">Note on Very Early Cut-Off, and on Reversing
-Gears in General.</td>
-</tr>
-</table></div>
-
-<p class="center">
-<small><i>88 Pages.</i> &nbsp; <i>41 Illustrations.</i> &nbsp; <i>12mo, Cloth, $1.00.</i></small>
-</p>
-<hr class="full" />
-
-<p class="center">QUICK AND EASY METHODS</p>
-
-<p class="center"><small>OF</small></p>
-
-<p class="center"><span class="xl smcap">Calculating<br />
-
-With the Slide Rule</span></p>
-
-<p class="center"><small><span class="smcap">A Simple Explanation of the Theory and
-Use of the Slide Rule, Logarithms, Etc.</span></small></p>
-
-<p class="center"><small><i>With numerous examples worked out.</i></small></p>
-
-<p class="center"><span class="smcap">By</span> R. G. BLAINE, M.E.</p>
-<hr class="small" />
-<p class="center"><small>A most reliable, practical and valuable work for the engineer.</small></p>
-<hr class="small" />
-<p class="center">
-<small><i>144 Pages.</i> &nbsp; <i>Illustrated.</i> &nbsp; <i>12mo, Cloth, $1.00</i></small>
-</p>
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><i>The Design and Construction</i><br />
-
-<small>OF</small><br />
-
-<span class="xl">OIL ENGINES</span></p>
-
-<p class="center"><small><i>With full directions for</i></small></p>
-
-<p class="center"><b>Erecting, Testing, Installing, Running and
-Repairing.</b></p>
-
-<p class="center xs">Including descriptions of American and English<br />
-
-<big>KEROSENE OIL ENGINES</big>.</p>
-<hr class="small" />
-<p class="center"><b>By A. H. GOLDINGHAM, M.E.</b></p>
-<hr class="small" />
-
-<p class="center"><i>Synopsis of Contents of Chapters</i>:</p>
-<div class="small">
-<p>1. Introductory, Classification, Vaporizers, Spraying
-and Ignition Devices, etc. 2. Design and
-Construction, Cylinders, Cranks, Shafts, Pistons,
-Connecting Rods, Fly-Wheels, Air and Exhaust
-Cams, Valves, etc., Bearings, Engine Frames, Valve
-Mechanisms, Gearing, Oil Supply, Different Kinds of
-Engines, etc. 3. Testing the Engine, Faults and
-Remedies, etc. 4. Cooling Water Tanks, Exhaust
-Silencers, Starters. 5. Oil Engine Driving Dynamo,
-Various Systems. 6. Oil Engine Driving Air Compressors.
-Water Pump, etc. 7. Full Instructions for
-Running Oil Engines. 8. Hints on Repairing. 9.
-Description of the Various English and American
-Oil Engines.</p>
-
-
-<p class="center"><b>Fully Illustrated, 12mo. Cloth, $2.00‡</b></p>
-</div>
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center"><span class="xxl">
-S</span><span class="u xl gap5">PONS'</span><span class="xxl">$2.</span><span class="xl u">50</span></p>
-
-<p class="center xl">MECHANIC'S OWN BOOK,</p>
-
-<p class="center"><big>A PRACTICAL MANUAL</big>.</p>
-
-
-<p class="center"><span class="smcap">Principal Contents.</span></p>
-
-<div class="hang small">
-
-<p>Mechanical Drawing. (13 pages).</p>
-
-<p>Casting and Founding. (31 pages).</p>
-
-<p>Forging and Finishing. (56 pages).</p>
-
-<p>Soldering. (26 pages).</p>
-
-<p>Sheet-Metal Working. (10 pages).</p>
-
-<p>Carpentry, Woods, Tools etc. (224 pages).</p>
-
-<p>Cabinet Making. (36 pages).</p>
-
-<p>Carving and Fretwork. (13 pages).</p>
-
-<p>Upholstery. (6 pages).</p>
-
-<p>Painting, Graining and Marbling. (28 pages).</p>
-
-<p>Staining, and Gilding. (16 pages).</p>
-
-<p>Polishing. Varnishing. (26 pages).</p>
-
-<p>Mechanical Movements. (56 pages).</p>
-
-<p>Turning and Lathe work. (30 pages).</p>
-
-<p>Masonry, Stonework, Brickwork, Concrete, etc. (45
-pages).</p>
-
-<p>Plastering, Whitewashing, Paperhanging. (13 pages).</p>
-
-<p>Roofing, Glazing. (14 pages).</p>
-
-<p>Bell hanging, Gas fitting. (8 pages).</p>
-
-<p>Lighting, Ventilation, Warming. (21 pages).</p>
-
-<p>Foundations, Roads and Bridges, Banks, Hedges,
-Ditches and Drains, Water Supply and Sanitation.
-House Construction, etc. Size of book 6¾ in. by 8¾.</p></div>
-
-
-<p class="center"><small><b>702 pages, half extra gilt and 1420 illustrations.</b></small></p>
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center">NEW<br />
-
-<span class="xl">EDITION "DE LUXE"</span><br />
-
-<small>ON HEAVY PLATE PAPER</small></p>
-
-<div class="figcenter">
-<img src="images/i_294.jpg" alt="" />
-</div>
-
-<p class="center small">A SYSTEM OF<br />
-
-EASY LETTERING.<br />
-BY<br />
-J. H. CROMWELL.</p>
-
-
-
-<p class="center"><b>ITS GOOD POINTS.</b></p>
-<div class="small">
-<p>Very easy to learn.</p>
-
-<p>A rapid method to become a good letterer with a
-little practice.</p>
-
-<p>Very easy to lay out a line of words in <span class="smcap">Strict
-Proportion</span>, whether it be on a fence 500 yards long
-or on a drawing only a few inches across.</p>
-
-<p>Good for draughtsmen who prefer neat lettering,
-yet something out of the ordinary.</p>
-
-<p>It contains 26 pages of alphabets whose modifications
-are almost limitless.</p>
-
-<p>One of the cheapest in the market.</p></div>
-
-<p class="xs">This little book will be appreciated by draughtsmen who wish to
-use plain letters (and yet somewhat different from the ordinary run of
-letters) for the titles on drawings. The book will also be valuable
-and useful to any one who has had no practice in lettering, as the
-easy method given for forming the letters will enable a person to
-form the letters correctly, and with a little practice to do so quickly.—<i>American
-Machinist.</i></p>
-
-
-<p class="center"><small><b>Oblong, 8vo, cloth, 50 cents</b></small></p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center"><big>EVERYONE'S GUIDE</big><br />
-TO<br />
-
-<span class="xl">PHOTOGRAPHY</span></p>
-<p class="center">CONTAINING<br />
-
-<span class="xs">INSTRUCTIONS FOR MAKING YOUR OWN APPLIANCES AND<br />
-SIMPLE PRACTICAL DIRECTIONS FOR EVERY BRANCH<br />
-OF PHOTOGRAPHIC WORK.</span></p>
-
-<p class="center"><small>BY</small><br />
-E. J. WALL, F.R.P.S.<br />
-<span class="xs">Author of <i>The Dictionary of Photography</i>, etc., etc.</span></p>
-
-<p class="center"><small>SECOND EDITION</small></p>
-
-<div class="figcenter">
-<img src="images/colophon.jpg" alt="Colophon" />
-</div>
-
-<p class="center"><span class="smcap"><small>New York</small></span>:<br />
-SPON &amp; CHAMBERLAIN,<br />
-<span class="smcap"><small>12 Cortlandt Street</small></span>.<br />
-<br />
-<small>1892</small><br />
-</p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center xl">CROSS SECTION PAPER.</p>
-<hr class="small" />
-
-<p class="center">THE HANDY SKETCHING PAD.</p>
-
-<p><small>Printed on one side, in blue ink, all the lines being
-of equal thickness, with useful tables. Size 8 × 10
-inches. Price, 25c. each. Per dozen pads, $2.50.</small></p>
-
-<p class="center">THE HANDY SKETCHING BOOK.</p>
-
-<p><small>Made from this paper but printed on both sides.
-Size of book 5 × 8 inches, stiff board covers. Price,
-25c. each; per dozen books, $2.50.</small></p>
-<hr class="small" />
-
-<p class="center">SCALE EIGHT TO ONE INCH.</p>
-
-<p><small>A large sheet with heavy inch lines and half inch
-lines, printed in blue ink. Size of sheet, 17 × 22 inches.
-Per quire (24 sheets), 75c.</small></p>
-<hr class="small" />
-
-<p class="center">SCALE TEN TO ONE INCH.</p>
-
-<p><small>Size 17 x 22 inches, printed in blue ink, with heavy
-inch lines and half inch lines. Per quire (24 sheets), 75c.</small></p>
-
-<p class="center">THE ELECTRICIAN'S SKETCHING PAD.</p>
-
-<p><small>Size 8 × 10. Scale 10 to 1 in. Price 25c. each. Per
-dozen, $2.50.</small></p>
-
-<p class="center">THE ELECTRICIAN'S SKETCHING BOOK.</p>
-
-<p><small>Made from this paper. Scale 10 to 1 inch. Size of
-book 5 × 8 inches, with stiff board covers. Price, 25c.
-each; per dozen, $2.50.</small></p>
-
-
-<p class="center"><small>Any quantity mailed to any part of the world on receipt
-of price.<br />
-
-Or Books and Pads Assorted, per dozen, $2.50</small></p>
-
-<p class="center"><small>This paper is <i>not ruled</i>. Try it and you will find it<br />
-GOOD, ACCURATE AND CHEAP.</small></p>
-
-<p class="center">
-<big>SPON &amp; CHAMBERLAIN,</big> <small>12 Cortlandt St</small>.,<br />
-NEW YORK.<br />
-</p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center"><big><b>Manual of Instruction in</b></big></p>
-
-<p class="center"><span class="xxl"><b>Hard Soldering</b></span></p>
-
-<p class="center"><small>WITH AN APPENDIX ON THE</small><br />
-
-<big><b>Repair of Bicycle Frames</b></big></p>
-
-<p class="center"><b>Notes on Alloys and a Chapter on Soft Soldering</b></p>
-
-<p class="center"><i>BY HARVEY ROWELL</i></p>
-
-<div class="small">
-<p>The flame, lamp, charcoal, mats, blow-pipes,
-wash-bottle, binding wire, chemicals, borax, spelter,
-silver solder, gold solder, oxidation of metals, fluxes,
-anti-oxidisers, oxidation of cases, the cone, oxidising
-flame, reducing flame, heat transmission, conduction,
-capacity of metals, radiation, application, the work
-table, the joint, applying solder, applying heat, the
-use of the blow-pipe, joints, making a ferrule, to repair
-a spoon, to repair a watch case, hard soldering
-with a forge or hearth, hard soldering with tongs,
-preserving thin edges, silversmith's pickle, restoring
-color to gold, chromic acid, to mend steel springs,
-sweating metals together, retaining work in position,
-making joints, applying heat, preventing the loss of
-heat, effect of sulphur lead and zinc, to preserve
-precious stones, annealing and hardening, burnt iron,
-to hard solder after soft solder. Tables of—specific
-gravity, tenacity, fusibility, alloys.</p>
-
-
-<p class="center"><b>66 pages, illustrated, cloth, 75 cents.</b></p></div>
-
-<hr class="small" />
-
-<p class="xs">For Soldering Receipts, Cements and Lutes, Pastes, Glues
-and such like, <i>see</i> <span class="smcap">Workshop Receipts</span>.</p>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-
-<p class="center xl">SMALL ACCUMULATORS</p>
-<div class="small">
-<p class="center">How Made and Used</p>
-
-<p class="center"><i>A Practical Handbook for Students and Young
-Electricians</i></p>
-
-<p class="center"><i>EDITED BY PERCIVAL MARSHALL, A.I.M.E.</i></p>
-
-
-<p class="center">Contents of Chapters</p>
-
-<p>I.—The Theory of the Accumulator.</p>
-
-<p>II.—How to make a 4-Volt Pocket Accumulator.</p>
-
-<p>III.—How to make a 32-Ampere-Hour Accumulator.</p>
-
-<p>IV.—Types of Small Accumulators.</p>
-
-<p>V.—How to Charge and Use Accumulators.</p>
-
-<p>VI.—Applications of Small Accumulators, Electrical Novelties,
-etc. Useful Receipts. Glossary of Technical Terms.</p>
-
-<p class="center"><b>80 pages, 40 illustrations, 12mo, cloth, 50c.</b></p>
-</div>
-
-<hr class="full" />
-
-<p class="center xl">THE MAGNETO-TELEPHONE<br />
-
-<small>ITS CONSTRUCTION,</small></p>
-
-<p class="center">Fitting Up and Adaptability to Every-Day Use</p>
-
-<p class="center"><i>BY NORMAN HUGHES</i></p>
-
-
-<p class="center">CONTENTS OF CHAPTERS</p>
-<div class="small">
-<p>Some electrical considerations: I.—Introductory. II.—Construction.
-III.—Lines, Indoor Lines. IV.—Signalling
-Apparatus. V.—Batteries. Open Circuit Batteries. Closed
-Circuit Batteries. VI.—Practical Operations. Circuit with
-Magneto Bells and Lightning Arresters. How to Test the
-Line. Push-Button Magneto Circuit. Two Stations with
-Battery Bells. VII.—Battery Telephone. Battery Telephone
-Circuit. Three Instruments on one Line. VIII.—General
-remarks. Index.</p>
-
-<p class="center"><b>80 pages, 23 illustrations, 12mo, cloth, $1.00. In paper, 50c.</b></p>
-</div>
-
-<hr class="chap" />
-<div class="chapter"></div>
-
-<p class="center"><span class="u">EVERYBODY'S BOOK ON ELECTRICITY</span><br />
-
-<span class="xl">PRACTICAL ELECTRICS</span></p>
-
-<p class="center">A UNIVERSAL HANDY-BOOK<br />
-
-ON<br />
-
-EVERYDAY ELECTRICAL MATTERS</p>
-
-<hr class="small" />
-
-<p class="center">FIFTH EDITION</p>
-
-<hr class="small" />
-<div class="small">
-<p class="center">CONTENTS:</p>
-
-<p><i>Alarms.</i>—Doors and Windows; Cisterns; Low Water in
-Boilers; Time Signals; Clocks. <i>Batteries.</i>—Making; Cells;
-Bichromate; Bunsen; Callan's; Copper-oxide; Cruikshank's;
-Daniel's; Granule carbon; Groves; Insulite; Leclanché;
-Lime Chromate; Silver Chloride; Smee; Thermo-electric.
-<i>Bells.</i>—Annunciator System; Double System; and Telephone;
-Making; Magnet for; Bobbins or Coils; Trembling; Single
-Stroke; Continuous Ringing. <i>Connections.</i> <i>Carbons.</i> <i>Coils.</i>—Induction;
-Primary; Secondary; Contact-breakers; Resistance.
-<i>Intensity</i> Coils.—Reel; Primary; Secondary; Core;
-Contact-breaker; Condenser; Pedestal; Commutator; Connections.
-<i>Dynamo-electric Machines.</i>—Field-Magnets; Pole-pieces;
-Field-magnet Coils; Armature Cores and Coils;
-Commutator Collectors and Brushes; Relation of size to
-efficiency; Methods of exciting Field-Magnets; Magneto-Dynamos;
-Separately excited Dynamos; Shunt Dynamos;
-Field-Magnets; Armatures; Collectors; Brush Dynamo;
-Alternate Currents. <i>Fire Risks.</i>—Wires; Lamps; Danger to
-persons. <i>Measuring.</i>—Non-Registering Instruments; Registering
-Instruments. <i>Microphones.</i> <i>Motors.</i> <i>Phonographs.</i>
-<i>Photophones.</i> <i>Storage.</i> <i>Telephones.</i>—Forms; Circuits and
-Calls; Transmitter and Switch; Switch for Simplex; etc., etc.</p>
-
-<p class="center">
-<b>135 PAGES. &nbsp; 126 ILLUSTRATIONS. &nbsp; 8VO.<br />
-Cloth, 75 cents</b>
-</p></div>
-
-<hr class="chap" />
-<div class="chapter"></div>
-<p class="center"><b>VEST POCKET SERIES.<br />
-
-<small>ACTUAL SIZE</small></b>.</p>
-
-<div class="figcenter" >
-<img src="images/i_300a.jpg" alt="Spons' Engineers Tables" />
-</div>
-<p class="center xs">Bound in roan, round corners, gilt edges in celluloid case, 50c.</p>
-
-<div class="figcenter" >
-<img src="images/i_300.jpg" alt="Thompson's Electric Tables and Memoranda" />
-</div>
-<p class="center xs">Bound in roan, round corners, gilt edges, in celluloid case, 50c.<br />
-
-
-<i>Copies mailed post-paid on receipt of price.</i></p>
-</div>
-
-<div class="transnote">
-<h3>Transcriber's Notes</h3>
-
-<p>The Errata have been implemented.</p>
-
-<p>Obvious typographical errors have been silently corrected. All other
-spelling, hyphenation and punctuation remains unchanged.</p>
-
-<p>The highly varied decorative typography of the book catalogue has
-not been reproduced but every effort has been made to maintain the
-general appearance and effect of the original.</p>
-</div>
-
-
-
-
-
-
-
-
-<pre>
-
-
-
-
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