summaryrefslogtreecommitdiff
path: root/old/14009.txt
diff options
context:
space:
mode:
Diffstat (limited to 'old/14009.txt')
-rw-r--r--old/14009.txt5136
1 files changed, 5136 insertions, 0 deletions
diff --git a/old/14009.txt b/old/14009.txt
new file mode 100644
index 0000000..c02884a
--- /dev/null
+++ b/old/14009.txt
@@ -0,0 +1,5136 @@
+The Project Gutenberg EBook of Scientific American Supplement, No. 787,
+January 31, 1891, by Various
+
+This eBook is for the use of anyone anywhere at no cost and with
+almost no restrictions whatsoever. You may copy it, give it away or
+re-use it under the terms of the Project Gutenberg License included
+with this eBook or online at www.gutenberg.org
+
+
+Title: Scientific American Supplement, No. 787, January 31, 1891
+
+Author: Various
+
+Release Date: November 10, 2004 [EBook #14009]
+
+Language: English
+
+Character set encoding: ASCII
+
+*** START OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN ***
+
+
+
+
+Produced by Victoria Woosley, Don Kretz, Juliet Sutherland, Charles
+Franks and the PG Distributed Proofreading Team
+
+
+
+
+
+[Illustration]
+
+
+
+
+SCIENTIFIC AMERICAN SUPPLEMENT NO. 787
+
+
+
+
+NEW YORK, January 31, 1891
+
+Scientific American Supplement. Vol. XXXI., No. 787.
+
+Scientific American established 1845
+
+Scientific American Supplement, $5 a year.
+
+Scientific American and Supplement, $7 a year.
+
+ * * * * *
+
+
+
+
+TABLE OF CONTENTS.
+
+
+I. BIOGRAPHY.--CHARLES GOODYEAR.--The life and discoveries of
+ the inventor of vulcanized India rubber, with portrait.--1
+ illustration
+
+II. BIOLOGY.--Can we Separate Animals from Plants?--By ANDREW
+ WILSON.--A debated point well discussed.--The bases on which
+ distinctions must be drawn
+
+III. ELECTRICITY.--A New Electric Ballistic Target.--A target
+ for investigations of the velocity of projectiles, now in use at
+ the United States Military Academy, West Point, N.Y.--1
+ illustration.
+
+ Electric Erygmascope.--An electric lighting apparatus for
+ examining earth strata in bore holes for geologists' and
+ prospectors' use.--1 illustration
+
+ The Electro-Magnet.--By Prof. SILVANUS THOMPSON.--Continuation
+ of this exhaustive treatise, giving further details on special
+ points of construction.--1 illustrations
+
+IV. ENTOMOLOGY.--Potash Salts.--The use of potash salts as
+ insecticides, with accounts of experiments
+
+ The Outlook for Applied Entomology.--By Dr. C.V. RILEY, U.S.
+ entomologist.--The conclusion of Prof. Riley's lecture, treating
+ of the branch of entomology with which his name is so honorably
+ associated
+
+V. INSURANCE.--The Expense Margin in Life Insurance.--Elaborate
+ review of the necessary expenses of conducting the insurance of
+ lives, with tables and calculations
+
+VI. MATHEMATICS.--The Trisection of Any Angle.--By FREDERIC R.
+ HONEY, Ph.B.--A very ingenious demonstration of this problem,
+ based on the properties of conjugate hyperbolas
+
+VII. METEOROLOGY.--Note on the Mt. Blanc Meteorological Station
+
+ The Flood at Karlsbad.--Account of the recent flood and of its
+ destructive effects.--1 illustration
+
+VIII. MECHANICAL ENGINEERING.--Station for Testing Agricultural
+ Machines.--A proposed establishment for applying dynamometer
+ tests to agricultural machines.--1 illustration
+
+ Steam Engine Valves.--By THOMAS HAWLEY.--A review of modern
+ slide valve practice, the lap, cut-off, and other points.--6
+ illustrations
+
+IX. MISCELLANEOUS.--Science in the Theater.--Curious examples of
+ stage effect in fictitious mesmerizing and hypnotizing.--4
+ illustrations
+
+ Theatrical Water Plays.--Recent episodes in real water plays at
+ Hengler's Circus, London.--2 illustrations
+
+X. NAVAL ENGINEERING.--The French Ironclad War Ship Colbert.--An
+ armored wood and iron ship, with central battery.--1
+ illustration
+
+XI. PHYSIOLOGY AND HYGIENE.--Newer Physiology and Pathology.--By
+ Prof. SAMUEL BELL. M.D.--An excellent presentation of modern
+ practice in the light of bacteriology
+
+ Test Card Hints.--How to test the eyes for selecting eyeglasses
+ and spectacles
+
+ The Composition of Koch's Lymph.--What Prof. Koch says it is and
+ what it can do.--The cabled account of the disclosure so long
+ waited for
+
+XII. TECHNOLOGY.--Firing Points of Various Explosives.--The
+ leading explosives, with the temperature of their exploding
+ points tabulated
+
+ The Recovery of Gold and Silver from Plating and Gilding
+ Solutions--A paper of interest to silver and gold platers, as
+ well as photographers
+
+ Water Softening and Purifying Apparatus.--An apparatus for
+ treatment of sewage, etc., chemically and by deposition.--1
+ illustration
+
+ * * * * *
+
+
+
+
+THE FRENCH IRONCLAD WAR SHIP COLBERT.
+
+
+The central battery ironclad Colbert is one of the ten ships of the
+French navy that constitute the group ranking next in importance to
+the squadron of great turret ships, of which the Formidable is the
+largest. The group consists of six types, as follows:
+
+ 1. The Ocean type; three vessels; the Marengo, Ocean, and Suffren.
+ 2. The Friedland type, of which no others are built.
+ 3. The Richelieu type, of which no others are built.
+ 4. The Colbert type, of which there are two; the Colbert and the
+ Trident.
+ 5. The Redoubtable type, of which no others are built.
+ 6. The Devastation type, of which no others are built.
+
+[Illustration: THE FRENCH IRONCLAD WAR SHIP COLBERT.]
+
+The Colbert was launched at Brest in 1875, and her sister ship, the
+Trident, in 1876. Both are of iron and wood, and the following are the
+principal dimensions of the Colbert, which apply very closely to the
+Trident: She is 321 ft. 6 in. long, 59 ft. 6 in. beam, and 29 ft. 6
+in. draught aft. Her displacement is 8,457 tons, her indicated horse
+power is 4,652, and her speed 14.4 knots. She has coal carrying
+capacity for 700 tons, and her crew numbers 706. The thickness of her
+armor belt is 8.66 in., that protecting the central battery is 6.29
+in. thick, which is also the thickness of the transverse armored
+bulkheads, while the deck is 0.43 in. in thickness. The armament of
+the Colbert consists of eight 10.63 in. guns, two 9.45 in., six 5.51
+in., two quick firing guns, and fourteen revolving and machine
+guns.--_Engineering._
+
+ * * * * *
+
+A compound locomotive, built by the Rhode Island Locomotive Works, has
+been tried on the Union Elevated Railroad, Brooklyn, N.Y. The engine
+can be run either single or compound. The economy in fuel was 37.7 per
+cent, and in water 23.8 per cent, over a simple engine which was
+tested at the same time. The smoothness of running and the stillness
+and comparative absence of cinders was fully demonstrated.
+
+ * * * * *
+
+
+
+
+STEAM ENGINE VALVES.
+
+[Footnote: Lecture delivered at Wells Memorial Institute, Boston, in
+the Lowell Free Course for Engineers. From report in the _Boston
+Journal of Commerce_.]
+
+By THOMAS HAWLEY.
+
+RIDING CUT-OFF VALVES--PECULIARITIES AND MERITS OF THE DIFFERENT
+STYLES.
+
+
+In considering the slide valve in its simple form with or without lap,
+we find there are certain limitations to its use as a valve that would
+give the best results. The limitation of most importance is that its
+construction will not allow of the proper cut off to obtain all the
+benefits of expansion without hindering the perfect action of the
+valve in other particulars. At this economical cut off the opening of
+the steam port is very little and very narrow, and although this is
+attempted to be overcome by exceedingly wide ports, sixteen inches in
+width in many cases in locomotive work, this great width adds largely
+to the unbalanced area of the valve. The exhausting functions of the
+valve are materially changed at the short cut off, and when much lap
+is added to overcome this defect, there usually takes place a choking
+of the exhaust port. You might inquire, why not make the port wider,
+but this would increase the minimum amount of load on the valve, and
+this must not be overlooked. Then the cut off is a fixed one, and we
+can govern only by throttling the pressure we have raised in the
+boiler or by using a cut off governor and the consequent wastes of an
+enormous clearance space. You will observe, therefore, that the plain
+slide valve engine gives the most general satisfaction at about
+two-thirds cut off and a very low economic result. The best of such
+engines will require forty-five to fifty pounds of steam per horse
+power per hour, and to generate this, assuming an evaporation of nine
+pounds of water to a pound of coal, would require between five and six
+pounds of coal per horse power per hour. And the only feature that the
+valve has specially to commend it is its extreme simplicity and the
+very little mechanism required to operate it.
+
+Yet this is of considerable importance, and in consideration of some
+special features at its latest cut off, the attempt has been many
+times made to take advantage of these features. For instance, at 90 deg.
+advance, the valve opens very rapidly indeed and fully satisfies our
+requirements of a perfect valve. This is one good point, and in this
+position also the exhaust and compression can be regulated very
+closely and as desired without much lap, and as the opening of the
+exhaust port comes with the eccentric at its most rapid movement the
+release is very quick and as we would have it. This is only possible
+at the most uneconomic position of the valve as regards cut off.
+
+The aim of many engineers has been to take advantage of these matters
+by using the valve with 90 deg. angular advance of eccentric ahead of
+crank, for the admission, release, and compression of the steam, and
+provide another means of cutting off, besides the one already referred
+to, viz., cutting off the supply of steam to the chest, and overcome
+the objection in this one of large clearance spaces. This is done by
+means of riding cut off valves, often called expansion valves, of
+which, perhaps, the most widely known types in this vicinity are the
+Kendall & Roberts engine and the Buckeye. The former is used in the
+simplest form of riding cut off, while the Buckeye has many peculiar
+features that engineers, I find, are too prone to overlook in a casual
+examination of the engine. In these uses of the slide valve, too,
+means are suggested and carried out of practically balancing the
+valve.
+
+The origin of the riding cut off is most generally attributed to
+Gonzenbach. His arrangement had two steam chests, the lower one
+provided with the ordinary slide valve of late cut off, and steam was
+cut off from this steam chest by the expansion valve covering the
+ports connecting with the upper steam chest. This had the old
+disadvantage that all the steam in the lower chest expanded with that
+in the cylinder, at a consequent considerable loss. This was further
+improved by causing the riding cut off to be upon the top of the main
+valve, instead of its chest, and resulted in a considerable reduction
+of the clearance space.
+
+This is the simplest form, and is shown in Fig. 1. The steam is
+supplied by a passage through the main valve which operates exactly as
+an ordinary slide valve would. That is, the inside edges of the steam
+passage are the same as the ordinary valve, the additional piece on
+each end, if I may so term it, being merely to provide a passage for
+the steam which can be closed, instead of allowing the steam to pass
+the edge. The eccentric of the main valve is fastened to the shaft to
+give the proper amount of lead, and the desired release and
+compression, and the expansion valve is operated by a separate
+eccentric fastened in line with or 180 deg. ahead of the crank. When the
+piston, therefore, commences to move from the crank end to open the
+port, D, the expansion valve is forced by its eccentric in the
+opposite direction, and is closing the steam port and would have
+closed it before the piston reached quarter stroke, thus allowing the
+steam then in the cylinder to do work by expansion. The eccentric
+operating this expansion valve may be set to close this steam port at
+any point in the stroke that is desired, the closing occurring when
+the expansion valve has covered the steam port. Continuing the
+movements of the valves, the two would move together until one or the
+other reached its dead center, when the movements would be in opposite
+directions.
+
+[Illustration: FIG. 1.]
+
+There are three ways of effecting the cut off in such engines, the
+main valve meanwhile being undisturbed, its eccentric fastened
+securely so as not to disturb the points of lead, release, and
+compression. All that is required is to cause the edge of the
+expansion valve to cover the steam port earlier in the stroke, and
+this can be done, first, by increasing the angular advance of the cut
+off eccentric; second, by adding lap to the cut off valve; and third
+by changing the throw of the eccentric. In all these instances the
+riding valve is caused to reach the edge of the steam port earlier in
+the stroke. We will take first, as the simplest, those methods by
+which the lap of the cut off valve is increased.
+
+It will be noted that there is but one edge of this valve that is
+required to do any work, and that is to close the valve. The
+eccentrics are so placed that the passage in the main valve is opened
+long before the main valve itself is ready to admit steam to the
+cylinder, so that only the outer edges are the ones to be considered,
+and it will be readily seen that the two valves traveling in opposite
+directions, any lap added to the working edge of the cut off valve
+will cause it to reach the edge and therefore close the port earlier
+than it would if there was less lap. And we might carry it to the
+extreme that we could add lap enough that the steam passage would not
+be opened at all.
+
+In Fig. 2 is shown the method by which this is accomplished, in what
+is called Meyer's valve, and such as is used in the Kendall & Roberts
+engine. We have only one point to look after, the cut off, so we can
+add all the lap we wish without disturbing anything else. In this
+engine the lap is changed by hand by means of a little hand wheel on a
+stem that extends out of the rear of the steam chest. The valve is in
+two sections, and when it is desired to cut off earlier, the hand
+wheel is turned in such a direction that the right and left hand
+screws controlling the cut off valve move one valve portion back and
+the other forward, which would, if they were one valve and they should
+be so considered, have the effect of lengthening them, or adding lap
+to them. The result would be that the riding valve would reach the
+edge of the steam port earlier in the stroke, bringing about an
+earlier cut off. If the cut off is desired to be later, the hand wheel
+is so turned that the right and left hand screws will bring the valve
+sections nearer together, thus practically taking off lap. Now this
+may be done by hand or it may be done by the action of a governor.
+
+[Illustration: FIG. 2.]
+
+In the latter case the governor at each change of load turns the right
+and left hand screws to add or take away lap, as the load demands an
+earlier or later cut off; in other cases the governor moves a rack in
+mesh with a gear by which the valve sections are brought closer
+together or are separated. The difficulty with the case where the hand
+wheel is turned by hand is that the cut off is fixed where you leave
+it, and governing can only be at the throttle. For this reason
+anywhere near full boiler pressure would not be obtained in the
+cylinder of the engine. If the load was a constant one, and the cut
+off could be fixed at about one-third, causing the throttle to open
+its widest, very good results would be obtained, but there is no
+margin left for governing.
+
+If the load should increase at such a time the governor could not
+control it under these conditions, and it would lead to a decrease in
+speed unless the lap was again changed to give a later cut off. On
+this account the general practice soon becomes to leave the cut off at
+the later point and give range to the throttle, and we come back once
+more to the plain slide valve cutting off at half stroke, and the only
+gain there is, is in a quick port opening and quick cut off. But these
+matters are more than offset by the wire drawing between the steam
+pipe and chest, through the throttle, and the fact that there is added
+to the friction of the engine the friction of this additional slide
+valve and a considerable liability to have a leaky valve.
+
+In the case where the governor changes the position of the cut off
+valve a greater decree of economy would result. In this engine, of
+which the Lambertville engine is a type, the main valve is a long D
+slide, with multiple ports at the ends through which the steam enters
+the cylinders. It is operated from an eccentric on the crank shaft in
+the usual manner. The cut off valve is also operated from the motion
+on an eccentric fixed upon the crank shaft. The rod or stem of the cut
+off valve passes through the main valve rod and slide. Upon the outer
+end of the cut off valve rod are tappets fastened to engage with
+tappets on the eccentric valve rod. Connection between the cut off
+eccentric, therefore, and the cut off valve is only by means of the
+engagement of these tappets. The eccentric rod is fastened to a rocker
+arm having motion swinging about a pin or bearing in the governor
+slide, which may be raised or lowered by a cam operated by the
+governor. The cut off slide is of cylindrical shape and incloses a
+spring and dash pot with disks attached by means of which the valve is
+closed. The motion for operating the valves is relatively in the same
+direction, the cut off eccentric having the greatest throw and greater
+angular advance to cause it to open earlier and quickly before the
+main valve is ready to admit steam. The cut off eccentric rod swinging
+the rocker arm, the tappets thereon engage with those upon the cut off
+valve rod and open the passages to the main valve, and in their
+movement compress the spring in the main valve. According as the speed
+of the engine, the rock arm will be raised or lowered so that the
+tappets upon the eccentric rod may keep in engagement a shorter or
+longer time before they disengage, thus allowing the spring that has
+been compressed by the movement of the cut off valve to close that
+valve quickly and the supply of steam to the engine, the cut off valve
+traveling with the main valve for the balance of the stroke. This
+device will give a remarkably quick opening and a quick cut off, but
+in view of the fact that the governor has so much to do, its delicacy
+is impaired and a quick response to the demands of the load changing
+not so likely to occur. The cut off cannot be as quick as in some
+other engines, because the valves are moving in opposite directions,
+and while this fact would help, so far as shortening the distance to
+be traveled before cut off, the resistance of the valves to travel in
+opposite directions, or rather the tendency of the valve to travel
+with the main valve, hinders its rapid action.
+
+[Illustration: FIG. 3.]
+
+This is one great objection to the rack and gear operated by the
+governor, that two flat valves riding upon each other and sliding in
+opposite directions at times require a considerable amount of force to
+move them, and as only a slight change in load is required by the
+load, the governor cannot handle the work as delicately as it should.
+It is too much for the governor to do well. To overcome this
+difficulty the Ryder cut-off, shown in Fig. 3, was made by the
+Delamater people, of New York. The main slide valve is hollowed in the
+back and the ports cut diagonally across the valve to form almost a
+letter V. The expansion valve is V-shaped, and circular to fit its
+circular-seat. The valve rod of the expansion valve has a sector upon
+it and operated by a gear upon the governor stem, which rotates the
+valve rod, and the edge of the valve rod is brought farther over the
+steam port, thus practically adding lap to the valve. Little movement
+is found necessary to make the ordinary change in cut-off, and it is
+found to be much easier to move the riding valve across the valve than
+in a direction directly opposite. It would require considerable force
+to move the upper valve by the governor faster than the lower, or in a
+direction opposite to that in which it is moving, but very little
+force applied sideways at the same time it is moving forward will give
+it a sideways motion. In this device the governor has only to exert
+this side pressure and therefore has less to do than if it were called
+upon to move the upper valve directly against the movement of the
+lower.
+
+Something similar is the valve of the Woodbury engine, of Rochester,
+N.Y. The cut-off valve is cylindrical, covering diagonal ports
+directly opposite, and is caused to be rotated by the action of the
+governor that operates a rack in mesh with a segment. Very little
+movement will effect a considerable change in the lappage of the
+valve, the valve turning about one-quarter a revolution for the
+extremes of cut off. The cut off valve rod works through a bracket and
+its end terminates in a ball in a socket on the end of the eccentric
+rod. In this case the governor has not as much to do as in other
+instances.
+
+[Illustration: FIG. 4.]
+
+Still another method of effecting this change in cut off, but hardly
+by increasing the lap of the valve, is shown in the next drawing, Fig.
+4. The cut off valve is held upon the main valve by the pressure of
+steam upon its back and rides with it until it comes in contact with
+the cut off wedge-shaped blocks, when its motion is arrested, and the
+main valve continuing its movement the steam port is closed by the
+main valve passing beneath the cut off valve. Thus the main valve
+travels and carries the cut off valve upon its back again until the
+cut off valve strikes the wedge on the other end and the cut off is
+effected. The relative positions of the blocks are determined by the
+governor, that will raise or lower them so that the cut off valve will
+engage with them earlier or later as desired. This device was designed
+specially as an inexpensive method of changing the common slide valve
+into an automatic cut off. The cut off would not be as quick as in
+other cases we have cited, depending here upon the movement of the
+lower valve alone, and that, too, is in its slowest movement; whereas
+in the other cases, the edges approaching each other, by the differing
+movement of the valves the cut off is very rapid, provided the
+distance to travel is not long. In this device considerable noise must
+result by the cut off valve striking the cut off blocks, and a
+considerable amount of leakage is likely to occur past this valve.
+
+But there is one great objection in the valve gears thus far cited,
+that the travel of the expansion valve upon the main valve is
+variable. I have in mind the case of a Kendall & Roberts engine, which
+had been run for a long time at no better economy than would be
+obtained from a plain slide valve engine, and when it was attempted to
+get an earlier cut off by separating the two cut off valves, they had
+worn so much in their old place on the valve that shoulders were found
+sufficient to cause a disagreeable noise and a leaky valve. This is
+very apt to occur, not only where the valve is run for a long time on
+one seat, but in cases of variation of the travel of the expansion
+valve. The result is that a change will bring about a leaky valve,
+something that every engineer abhors.
+
+The construction of the Buckeye engine, which is also of this type, is
+such that the travel of the valve on the back of the main valve is
+always the same, no matter what the cut off may be. Then this engine
+makes use of our second proposition as a means of effecting the cut
+off, viz., by advancing the eccentric. You will readily observe that
+anything that will cause the cut off valve to reach a certain point
+earlier in the stroke will bring about an earlier cut off as it
+hastens everything all around. This is the plan pursued in the
+Buckeye, in which the governor, of the shaft type, turns the eccentric
+forward or back according as the load demands. Then, in addition, the
+valve is balanced partially, the attempt not being made to produce an
+absolutely balanced valve, on the ground that there should be friction
+enough to keep the surfaces bright and to prevent leakage. The most
+perfect valve will, of course, be entirely balanced under all
+conditions of pressure so as to move with perfect ease. With the
+riding cut off valve in connection with the plain slide valve, this is
+not accomplished, and it does not matter whether it is partially
+unbalanced to prevent leakage or not, the fact that it is not entirely
+balanced prevents it reaching the ideal valve.
+
+[Illustration: Fig. 5]
+
+This valve, Fig. 5, differs from the others also in this particular,
+that the exhaust takes place at the end of the valve instead of under
+the arch. Two eccentrics are used, the one for the main valve being
+fastened to the shaft and the other riding loosely upon it and
+connected to the fly wheel governor, by which it may be turned forward
+or back as the load requires. The three points of lead, or admission
+and exhaust and compression, are fixed and independent of the changes
+and cut off. The motion of the main eccentric is given to a rocker
+arm, the pivot of which is at the bottom, and from the upper end the
+valve rod transfers the motion to the valve without reversing the
+motion, as is done sometimes in the slide valve to overcome the
+effects of the angularity of the connecting rod. The action of the
+rocker arm, therefore, so far as the main valve in the Buckeye is
+concerned, is no different than that which would occur if no rocker
+arm intervened. The motion of the cut off eccentric, through its
+eccentric rod, is given to a rocker rocking in a bearing in the center
+of the main rocker arm (see Fig. 6). The motion of this eccentric is
+reversed, so far as the cut off valve is concerned, and when the cut
+off eccentric is moving forward, the cut off valve is being pushed
+back. The main valve rod is hollow, and the cut off valve rod passes
+through it.
+
+[Illustration: Fig. 6]
+
+The cut off eccentric can be placed in any position to cause it to cut
+off as desired, and by drawing the valve forward, by increasing the
+angular advance of the eccentric, the cut off valve is caused to reach
+and cover the steam passage in the main valve earlier in the stroke.
+Instead of being ahead of the crank, the main eccentric in this
+arrangement follows the crank, on account of the exhaust and steam
+edges being exactly opposite from those in the ordinary slide. What is
+the steam edge of the common slide is in this the exhaust edge, and
+what is the exhaust edge in the common valve is the steam edge in this
+one. The valve, therefore, must be moved in the opposite direction
+from what is ordinarily the case, the main eccentric being not 90 deg.
+behind the crank. It has a rapid and full opening just the same, for
+it is at this point behind the crank, or ahead of it, that the
+eccentric gives to the valve its quickest movement, or between the
+eccentric dead centers. The cut off eccentric is considerably ahead of
+the main eccentric, and about even with the crank. If it was not for
+the reversal of motion of the cut off valve through the rocker arm
+this eccentric would be about in line with the crank, but on the other
+end. The movement of the cut off valve, therefore, at the time of port
+opening is very little, being about on its dead center, passing which,
+it immediately commences to close.
+
+The object of the peculiar construction of the rocker arm, and the
+pivot for the cut off rocker being placed thereon, is to provide equal
+travel on the back of the main valve, no matter what the cut off. I
+have already explained, in connection with the slide valve, that
+advancing the eccentric does not change the movement of the valve on
+its seat, but simply its relation to the movement of the piston. You
+will see that this is unchanged as using the main valve as a seat or
+any other seat. If the main valve was to remain stationary, and only
+the cut off valve to be operated by its eccentric, the movement of
+this cut off valve on a certain plane would be the same for all
+positions of the eccentric.
+
+Moving the main slide does not affect the matter in any way, for it
+moves at the same time the pivot of the cut off, and while the cut off
+seat has assumed a different position with reference to the engine, it
+is still as though stationary so far as the cut off valve is
+concerned. This is the object of this peculiar construction, and not,
+as some engineers suppose, simply to make an odd way of doing things.
+And the object of it all is to give at all cut offs the same amount of
+travel, so that there might be no unequal wear to bring about a leak,
+to prevent which a perfect balancing has been sacrificed.
+
+Referring to the valve and this engine as to how it will satisfy our
+requirements of a perfect valve gear, we find that the first
+requirement of a rapid and full opening is met, in that the opening
+occurs when the main eccentric is moving very rapidly, yet not its
+fastest, and while this opening will be very satisfactory, it is not
+so rapid an opening as is obtained in some other forms of valves and
+valve gears, but this could be overcome very readily by increasing the
+lead a trifle, and in my experience with these engines I find that the
+practice is very general by engineers and by builders themselves to
+give them a considerable amount of lead. As to the second requirement,
+the maintenance of initial pressure until cut off, giving a straight
+steam line, cards from this engine will not be found to show that the
+engine satisfies this requirement, and for this reason, that the
+cut-off valve commences to close the port immediately after the piston
+commences to move. The cut off eccentric you will remember is set to
+move with the crank or very nearly so, and the lighter the load, the
+greater will this fact appear. For the lightest loads the governor
+places the eccentric in advance of the crank, so that the cut off
+valve will commence to close the port before steam is admitted by the
+main valve to the engine. Now, the later the cut off, the less will
+this wire drawing appear at first, and the shorter the cut off, the
+amount of wire drawing increases sensibly. The operation of the valve,
+therefore, in this particular, cannot be considered as meeting our
+requirement that the port shall be held open full width until ready to
+be closed. Many men claim for this engine that the closing occurs when
+the cut off eccentric is moving its fastest. This is a fact, and if we
+consider the point of cut off only to be the point of absolute cut
+off, the cut off must be instantaneous, for there is an instantaneous
+point where the cut off is final only to be considered. The reasoning
+applied here would hold good also to a less extent on the slide valve,
+but is not the point of absolute cut off. We want to note how long it
+is from the time the valve commences to close at all until finally
+closed, and, as I have shown you, this is considerable in this engine.
+
+Referring to the point of cut off finally, it is determined upon by a
+governor of the fly wheel type. The eccentric is loose about the
+shaft, and arms projecting therefrom are connected by other arms to
+the extremity of an arm upon which is mounted a weight, and which is
+attached to the spokes of the fly wheel, or special governor wheel in
+this case, and which is fastened to the crank shaft. As the speed
+increases through throwing off a portion of the load the governor
+weights fly out, and this movement is transferred through the lever
+connections to the eccentric, causing it to be turned ahead, and the
+manner hastening the movement of the cut off valve on its seat and
+causing it to reach and cover the edge of the steam port earlier in
+the stroke. This engine was the pioneer in governors of this
+character, the advantage being, in addition to its necessity for the
+work of turning the eccentric ahead or back, that the liability of the
+engine to run away, as very often happens from the breaking of the
+governor belt or a similar cause, was not possible.
+
+The cut off valve has a travel considerably beyond the edge of the
+steam passage after the valve is closed, and this has one advantage,
+that the valve is less liable to leak, and to this must be added the
+loss from the friction of this moving valve, and moving too in
+opposition to the main valve. In our perfect valve, as we outlined it,
+the valve does not move after the port is closed. The exhausting
+functions of the valve are very good, giving a quick opening and a
+full opening, because this opening occurs when the eccentric is moving
+its fastest. The engine also possesses a distinct advantage in having
+remarkably small clearance spaces. The length of the steam passage is
+very small in comparison with any form of engine, and having but two
+ports instead of four, as in the Corliss and four valve type.
+
+In these there must be included in the clearance, that to the exhaust
+port as well as the steam port, adding a considerable amount where the
+piston comes close to the head. As the engines leave the maker's hand
+the engines are provided with a considerable amount of lap to give
+plenty of compression, but are, of course, capable of having more
+added to increase compression, or some planed off to decrease it.
+
+One of the peculiar things about this engine is the failure to realize
+anywhere near boiler pressure, noticeable in every case that has come
+under my notice. The considerable lead gives it for an instant, but it
+soon falls away, indicating the steam chest pressure only by a peak at
+the junction of the admission and steam lines. This is probably due to
+the fact that the cut off valve commences closing the steam passage so
+soon after steam is admitted, and in this particular does not satisfy
+the requirements of a perfect valve. There is this about the engine,
+that above all others of this type there has come under my notice
+fewer engines of this type with a maladjustment of valves from
+tampering by incompetent engineers.
+
+ * * * * *
+
+
+
+
+FIRING POINTS OF VARIOUS EXPLOSIVES.
+
+
+An apparatus, devised by Horsley, was used, which consisted of an iron
+stand with a ring support holding a hemispherical iron vessel, in
+which paraffin or tin was put. Above this was another movable support,
+from which a thermometer was suspended and so adjusted that its bulb
+was immersed in molten material in the iron vessel. A thin copper
+cartridge case, 5/8 in. in diameter and 1-5/16 in. long, was suspended
+over the bath by means of a triangle, so that the end of the case was
+1 in. below the surface of the liquid. On beginning the experiment the
+material in the bath was heated to just above the melting point, the
+thermometer was inserted in it, and a minute quantity of the explosive
+was placed in the bottom of the cartridge case. The temperature marked
+by the thermometer was noted as the _initial temperature_, the
+cartridge case containing the explosive was inserted in the bath, and
+the temperature quickly raised until the explosive flashed off or
+exploded, when the temperature marked by the thermometer was again
+noted as the _firing point_. The tables given show the results of
+about six experiments with each explosive. The initial temperatures
+range from 65 deg. to 280 deg. C. in some cases, but as the firing points
+remained fairly constant, only the extremes of the latter are quoted
+in the following table:
+
+
+ --------------------------------+-----------------------
+ Description of Explosive. | Firing Point in deg. C.
+ --------------------------------+-----------------------
+ Compressed military gun-cotton. | 186 - 201
+ Air-dried military gun-cotton. | 179 - 186
+ " " " | 186 - 189
+ " " " | 137 - 139
+ " " " | 154 - 161
+ Gun-cotton dried at 65 deg. C. | 136 - 141
+ Air-dried collodion gun-cotton. | 186 - 191
+ " " " | 197 - 199
+ " " " | 193 - 195
+ Air-dried gun-cotton. | 192 - 197
+ " " | 194 - 199
+ Hydro-nitrocellulose. | 201 - 213
+ Nitroglycerin. | 203 - 205
+ Kieselghur dynamite. No. 1. | 197 - 200
+ Explosive gelatin. | 203 - 209
+ Explosive gelatin, camphorated. | 174 - 182
+ Mercury fulminate. | 175 - 181
+ Gunpowder. | 278 - 287
+ Hill's picric powder. | 273 - 283
+ " " " | 273 - 290
+ Forcite, No. 1. | 184 - 200
+ Atlas powder, 75 per cent. | 175 - 185
+ Emmensite, No. 1. | 167 - 184
+ Emmensite, No. 2. | 165 - 177
+ Emmensite, No. 5. | 205 - 217
+ --------------------------------+-----------------------
+ _--C.E. Munroe, J. Amer. Chem. Soc._
+
+
+ * * * * *
+
+
+
+
+STATION FOR TESTING AGRICULTURAL MACHINES.
+
+
+The minister of agriculture has recently established a special
+laboratory for testing agricultural _materiel_. This establishment,
+which is as yet but little known, is destined to render the greatest
+services to manufacturers and cultivators.
+
+In fact, agriculture now has recourse to physics and mechanics as well
+as to chemistry. Now, although there were agricultural laboratories
+whose mission it was to fix the choice of the cultivator upon such or
+such a seed or fertilizer, there was no official establishment
+designed to inform him as to the value of machines, the models of
+which are often very numerous. _Chemical_ advice was to be had, but
+_mechanical_ advice was wanting. It is such a want that has just been
+supplied. Upon the report presented by Mr. Tisserand, director of
+agriculture, a ministerial decree of the 24th of January, 1888,
+ordered the establishment of an experimental station. Mr. Ringelmann,
+professor of rural engineering at the school of Grignon, was put in
+charge of the installation of it, and was appointed its director. He
+immediately began to look around for a site, and on the 17th of
+December, 1888, the Municipal Council of Paris, taking into
+consideration the value of such an establishment to the city's
+industries, decided that a plot of ground of an area of 3,309 square
+meters, situated on Jenner Street, should be put at the disposal of
+the minister of agriculture for fifteen years for the establishment
+thereon of a trial station. This land, bordering on a very wide street
+and easy of access, opposite the municipal buildings, offers, through
+its area, its situation, and its neigborhood, indisputable advantages.
+A fence 70 meters in extent surrounds the station. An iron gate opens
+upon a paved path that ends at the station.
+
+The year 1889 was devoted to the installation, and the station is now
+in full operation. The tests that can be made here are many, and
+concern all kinds of apparatus, even those connected with the electric
+lighting that the agriculturist may employ to facilitate his
+exploitation. However, the tests that are oftenest made are (1) of
+rotary apparatus, such as mills, thrashing machines, etc.; (2) of
+traction machines, such as wagons, carts, plows, etc.; and (3) of
+lifting apparatus. It is possible, also, to make experiments on the
+resistance of materials.
+
+The experimental hall contains a 7 horse power gas motor, dynamometers
+with automatic registering apparatus, counters, balances, etc. A small
+machine shop contains a lathe, a forge, a drilling machine, etc. The
+main shaft is 12 meters in length and is 7 centimeters in diameter. It
+is supported at a distance of one meter from the floor by four pillow
+blocks, and is formed of three sections united by movable coupling
+boxes. Out of these 12 meters, 9 are in the hall and 3 extend beyond
+the hall to an annex, 14 meters in length and 4 in width, in which
+tests are made of machines whose operation creates dust. When the
+machines to be tested require more than the power of seven horses that
+the motor gives, the persons interested furnish a movable engine,
+which, placed under the annex, actuates the driving shaft. Alongside
+of the main building there is a ring for experimenting upon machines
+actuated by a horse whim. There will soon be erected in the center of
+the grounds an 18 meter tower for experiments on pumps. Platforms
+spaced 5 meters apart, a crane at the top, and some gauging apparatus
+will complete this hydraulic installation.
+
+The equipment of the hall is very complete, and is fitted for all
+kinds of experiments.
+
+[Illustration: STATION FOR TESTING AGRICULTURAL MACHINES--DYNAMOMETER
+ FOR TESTING ROTARY MACHINES.]
+
+The tests of rotary machines are made by means of a dynamometer (see
+figure). Two fast pulleys and one loose pulley are interposed between
+the machine to be tested and the motor. The pulley connected with the
+motor carries along the one connected with the machine, through the
+intermedium of spring plates, whose strength varies with the nature of
+the apparatus to be tested. The greater or less elongation of these
+plates gives the tangential stress exerted by the driving pulley to
+carry along the pulley that actuates the machine to be tested. This
+elongation is registered by means of a pencil connected with the
+spring plates, and which draws a diagram upon a sheet of paper. At the
+same time, a special totalizer gives the stress in kilogrammeters.
+Besides, the pulley shaft actuates a revolution counter, and a clock
+measures the time employed in the experiment. In order to obtain a
+simultaneous starting and stopping point for all these apparatus, they
+are connected electrically, and, through the maneuver of a commutator,
+are all controlled at once. The electric current is furnished by two
+series of bichromate batteries.
+
+The tests of traction machines are effected by means of a
+three-wheeled vehicle carrying a dynamometer. The front wheel is
+capable of turning freely in the horizontal plane, and the dynamometer
+is mounted upon a frame provided with a screw that permits of
+regulating its position according to the slope of the ground. The
+method of suspension of the dynamometer allows it to take
+automatically the inclination of the line of traction without any
+torsion of the plates. There are two models of this vehicle, one
+designed to be drawn by a man, and the other by a horse.
+
+The station is provided, in addition, with registering pressure
+gauges, a large double dynamometric indicator, a counter of
+electricity, balances of precision, etc.
+
+An apparatus designed for measuring the rendering of presses is now in
+course of construction.
+
+Although the station has been in operation only from the 1st of
+January, twenty-five machines have already been presented to be
+tested.--_Extract from Le Genie Civil_.
+
+ * * * * *
+
+
+
+
+WATER SOFTENING AND PURIFYING APPARATUS.
+
+
+We have recently had brought under our notice a system of water and
+sewage purification which appears to possess several substantial
+advantages. Chief among these are simplicity in construction and
+operation, economy in first cost and working and efficiency in action.
+This system is the invention of Messrs. Slack & Brownlow, of Canning
+Works, Upper Medlock Street, Manchester, and the apparatus adopted in
+carrying it out is here illustrated. It consists of an iron
+cylindrical tank having inside a series of plates arranged in a spiral
+direction around a fixed center, and sloping downward at a
+considerable angle outward. The water to be purified and softened
+flows through the large inlet tube to the bottom, mixing on its way
+with the necessary chemicals, and entering the apparatus at the
+bottom, rises to the top, passing spirally round the whole
+circumference, and depositing on the plates all solids and impurities.
+
+All that is needed in the way of attention, even when dealing with
+sewage, or the most polluted waters, is stated to be the mixing in the
+small tanks the necessary chemical reagents, at the commencement of
+the working day; and at the close of the day the opening of the mud
+cocks shown in our engraving, to remove the collected deposit upon the
+plates. For the past six months this system has been in operation at a
+dye works in Manchester, successfully purifying and softening the
+foul waters of the river Medlock. It is stated that 84,000 gallons per
+day can be easily purified by an apparatus 7 feet in diameter. The
+chemicals used are chiefly lime, soda, and alumina, and the cost of
+treatment is stated to vary from a farthing to twopence per 1,000
+gallons, according to the degree of impurity of the water or sewage
+treated.
+
+The results of working at Manchester show that all the visible filth
+is removed from the Medlock's inky waters, besides which the hardness
+of the water is reduced to about 6 deg. from a normal condition of about
+30 deg.. The effluent is fit for all the varied uses of a dye works, and
+is stated to be perfectly capable of sustaining fish life. With
+results such as these the system should have a promising future before
+it in respect of sewage treatment, as well as the purification and
+softening of water generally for industrial and manufacturing
+purposes.--_Iron._
+
+[Illustration: WATER SOFTENING AND PURIFYING APPARATUS.]
+
+ * * * * *
+
+
+
+
+THE TRISECTION OF ANY ANGLE.
+
+By FREDERIC R. HONEY, Ph.B., Yale University.
+
+
+The following analysis shows that with the aid of an hyperbola any
+arc, and therefore any angle, may be trisected.
+
+If the reader should not care to follow the analytical work, the
+construction is described in the last paragraph--referring to Fig. II.
+
+Let a b c d (Fig. I.) be the arc subtending a given angle. Draw the
+chord a d and bisect it at o. Through o draw e f perpendicular
+to a d.
+
+We wish to find the locus of a point c whose distance from a given
+straight line e f is one-half the distance from a given point d.
+
+In order to write the equation of this curve, refer it to the
+co-ordinate axes a d (axis of X) and e f (axis of Y), intersecting
+at the origin o.
+
+ Let g c = x
+
+Therefore, from the definition c d = 2x
+
+ Let o d = D
+ [Hence] h d = D-x
+
+ Let c h = y
+ [Hence] (2x) squared = y squared + (D-x) squared
+ or 4x squared = y squared + D squared-2Dx + x squared
+ [Hence] y squared-3x squared + D squared-2Dx = o [I.]
+
+This is the equation of an hyperbola whose center is on the axis of
+abscisses. In order to determine the position of the center, eliminate
+the x term, and find the distance from the origin o to a new origin
+o'.
+
+ Let E = distance from o to o'
+ [Hence] x = x' + E
+
+Substituting this value of x in equation I.
+
+ y squared-3(x' + E) squared + D squared-2D(x' + E) = o
+ or y squared-3x squared-6Ex'-3E squared + D squared-2Dx'-2DE = o [II.]
+
+In this equation the x' terms should disappear.
+
+ [Hence] -6Ex' - 2Dx' = o
+ [Hence] -E = - D/3
+
+That is, the distance from the origin o to the new origin or the
+center of the hyperbola o' is equal to one-third of the distance
+from o to d; and the minus sign indicates that the measurement
+should be laid off to the left of the origin o. Substituting this
+value of E in equation II., and omitting accents--
+
+ We have
+
+ y squared - 3x squared + 2Dx - D squared/3 + D squared - 2Dx + 2D squared/3 = o
+ [Hence] y squared - 3x squared = - 4D squared/3
+
+[Illustration: Fig I]
+
+[Illustration: Fig II]
+
+This is the equation of an hyperbola referred to its center o' as
+the origin of co-ordinates. To write it in the ordinary form, that is
+in terms of the transverse and conjugate axes, multiply each term by
+C, i.e.,
+ __
+ Let \/C = semi-transverse axis.
+
+[TEX: \sqrt{C} = \text{semi-transverse axis.}]
+
+ Thus Cy squared - 3Cx squared = - 4CD squared/3. [III.]
+
+When in this form the product of the coefficients of the x squared and y squared
+terms should be equal to the remaining term.
+
+That is
+
+ 3C squared = - 4CD squared/3.
+ [Hence] C = 4D squared/9.
+
+And equation III. becomes:
+
+
+ 4D squared 4D squared 16D^{4}
+ ----- y squared - ----- x squared = - ---------
+ 9 3 27
+
+[TEX: \frac{4D^2}{9} y^2 - \frac{4D^2}{3} x^2 = -\frac{16D^4}{27}]
+ ____
+ / 4D squared 2D
+ The semi-transverse axis = \/ ----- = ----
+ 9 3
+
+[TEX: \text{The semi-transverse axis} = \sqrt{\frac{4D^2}{9}}
+= \frac{2D}{3}]
+ ____
+ / 4D squared 2D
+ The semi-conjugate axis = \/ ----- = -----
+ 3 ___
+ \/ 3
+
+[TEX: \text{The semi-conjugate axis} = \sqrt{\frac{4D^2}{3}}
+= \frac{2D}{\sqrt{3}}]
+
+Since the distance from the center of the curve to either focus is
+equal to the square root of the sum of the squares of the semi-axes,
+the distance from o' to either focus
+
+ ____________
+ /4D squared 4D squared 4D
+ = /\ /----- + ----- = ----
+ \/ 9 3 3
+
+[TEX: \sqrt{\frac{4D^2}{9} + \frac{4D^2}{3}} = \frac{4D}{3}]
+
+We can therefore make the following construction (Fig. II.) Draw a d
+the chord of the arc a c d. Trisect a d at o' and k. Produce
+d a to l, making a l = a o' = o' k = k d. With a k as a
+transverse axis, and l and d as foci, construct the branch of the
+hyperbola k c c' c", which will intersect all arcs having the common
+chord a d at c, c', c", etc., making the arcs c d, c' d, c"
+d, etc., respectively, equal to one-third of the arcs a c d, a c' d,
+a c" d, etc.
+
+ * * * * *
+
+
+
+
+TEST CARD HINTS.
+
+By Dr. F. OGDEN STOUT.
+
+
+I know it is the custom with a great many if not the majority of
+opticians to fit a customer without knowing whether he has presbyopia,
+hypermetropia, or any of the other errors of refraction. Their method
+is first to try a convex, and if this does not improve, a concave,
+etc., until the proper one is found. This, of course, amounts to the
+same thing if the right glass is found. But in practice it will be
+found both time saving and more satisfactory to first decide with what
+error you have to deal. It is very simple, and, where you have no
+other means of diagnosing (such as the ophthalmoscope), it does away
+with the necessity of trying so many lenses before the proper one is
+found. You should have a distance test card placed at a distance of
+twenty feet from the person you are examining, and in a good light.
+
+A distance test card consists of letters of various sizes which it has
+been found can be seen at certain distances by people with good
+vision. Thus the largest letter is marked with a cc, meaning that this
+should be seen at two hundred feet, and another line, XX, at twenty
+feet, which is the proper distance for testing vision for distance,
+for the reason that a normal eye is at rest when looking at any object
+twenty feet from it or beyond, and the rays coming from it are
+parallel and come to a focus on the retina. You must also have a near
+vision test card with lines that should be seen by a normal eye from
+ten to seventy-two inches, and a card of radiating lines for
+astigmatism. With this preparation you are ready to proceed. To
+illustrate, the first customer comes and tells you that up to six
+months ago he had very good vision, but he finds now that, especially
+at night, he has trouble in reading or writing, and that he finds he
+can see better a little farther away. His head aches and eyes smart.
+You will of course say that this is a very simple case. It must be old
+sight (presbyopia). Probably it is if he is old enough (45), but you
+must prove this for yourself, without asking his age, which is
+embarrassing in the case of a lady. If you direct him to the distance
+card twenty feet away, and find that he can see every one down to and
+including the one marked XX, his vision is up to the standard for
+distance, and you know that he can have no astigmatism worth
+correcting, nor any near sight, as both of these affect vision for
+distance, but he may have far sight or old sight or both combined. You
+must find which it is.
+
+If, while he is still looking at the twenty-foot line, you place in
+front of the eyes a weak convex and he tells you he sees just as well
+with as without, it proves the existence of far-sight or
+hypermetropia, and the strongest convex that still leaves vision as
+good for distance as without any, corrects the manifest. But if the
+weak convex blurs it, it shows that there is some defect in focusing,
+if the near vision is below normal. You therefore know that you have a
+case of old sight or presbyopia, requiring the weakest convex to
+correct it, that will enable your customer to see the finest line on
+the near card at the required distance.
+
+The next customer that comes to be fitted with glasses can only see
+the line marked XL on the distance card at 20 feet or about one-half
+of what he should see, which leads you to think that there is no far
+sight, for vision for distance is good except in very high degrees of
+this error. Nor can there be old-sight, for vision for distance is
+good in old-sight until after the fifty-fifth year, but it can be near
+sight (myopia) or astigmatism, or both. We next try the near card and
+find that even the finest line can be seen clearly if held
+sufficiently close to the eyes. We now know that this is a case of
+near sight, and we must fit them with glasses for distance. The
+weakest concave that will enable him to see the line that should be
+seen on the distance card at 20 feet is the proper one to give him for
+use.--_The Optician._
+
+ * * * * *
+
+
+
+
+CHARLES GOODYEAR.
+
+
+CHARLES GOODYEAR was born in New Haven, December 29, 1800. He was the
+son of Amasa Goodyear, and the eldest among six children. His father
+was quite proud of being a descendant of Stephen Goodyear, one of the
+founders of the colony of New Haven in 1638.
+
+Amasa Goodyear owned a little farm on the neck of land in New Haven
+which is now known as Oyster Point, and it was here that Charles spent
+the earliest years of his life. When, however, he was quite young, his
+father secured an interest in a patent for the manufacture of ivory
+buttons, and looking for a convenient location for a small mill,
+settled at Naugatuck, Conn., where he made use of the valuable water
+power that is there. Aside from his manufacturing, the elder Goodyear
+ran a farm, and between the two lines of industry kept young Charles
+pretty busy.
+
+In 1816, Charles left his home and went to Philadelphia to learn the
+hardware business. He worked at this very industriously until he was
+twenty-one years old, and then, returning to Connecticut, entered into
+partnership with his father at the old stand in Naugatuck, where they
+manufactured not only ivory and metal buttons, but a variety of
+agricultural implements, which were just beginning to be appreciated
+by the farmers. In August of 1824 he was united in marriage with
+Clarissa Beecher, a woman of remarkable strength of character and
+kindness of disposition, and one who in after years was of the
+greatest assistance to the impulsive inventor. Two years later he
+removed again to Philadelphia, and there opened a hardware store. His
+specialties were the valuable agricultural implements that his firm
+had been manufacturing, and after the first distrust of home made
+goods had worn away--for all agricultural implements were imported
+from England at that time--he found himself established at the head of
+a successful business.
+
+This continued to increase until it seemed but a question of a few
+years until he would be a very wealthy man. Between 1829 and 1830 he
+suddenly broke down in health, being troubled with dyspepsia. At the
+same time came the failure of a number of business houses that
+seriously embarrassed his firm. They struggled on, however, for some
+time, but were finally obliged to fail. The ten years that followed
+this were full of the bitterest struggles and trials to Goodyear.
+Under the law that then existed he was imprisoned time after time for
+debts, even while he was trying to perfect inventions that should pay
+off his indebtedness.
+
+Between the years 1831 and 1832 he began to hear about gum elastic and
+very carefully examined every article that appeared in the newspapers
+relative to this new material. The Roxbury Rubber Company, of Boston,
+had been for some time experimenting with the gum, and believing that
+they had found means for manufacturing goods from it, had a large
+plant and were sending their goods all over the country. It was some
+of their goods that first attracted his attention. Soon after this
+Goodyear visited New York, and went at once to the store of the
+Roxbury Rubber Company. While there, he examined with considerable
+care some of their life preservers, and it struck him that the tube
+used for inflation was not very perfect. He, therefore, on his return
+to Philadelphia, made some tubes and brought them down to New York and
+showed them to the manager of the Roxbury Rubber Company.
+
+This gentlemen was so pleased with the ingenuity that Goodyear had
+shown in manufacturing these tubes, that he talked very freely with
+him and confessed to him that the business was on the verge of ruin,
+that the goods had to be tested for a year before they could tell
+whether they were perfect or not, and to their surprise, thousands of
+dollars worth of goods that they had supposed were all right were
+coming back to them, the gum having rotted and made them so offensive
+that it was necessary to bury them in the ground to get them out of
+the way.
+
+Goodyear at once made up his mind to experiment on this gum and see if
+he could not overcome its stickiness.
+
+He, therefore, returned to Philadelphia, and, as usual, met a
+creditor, who had him arrested and thrown into prison. While there, he
+tried his first experiments with India rubber. The gum was very cheap
+then, and by heating it and working it in his hands, he managed to
+incorporate in it a certain amount of magnesia which produced a
+beautiful white compound and appeared to take away the stickiness.
+
+He therefore thought he had discovered the secret, and through the
+kindness of friends was put in the way of further perfecting his
+invention at a little place in New Haven. The first thing that he made
+here was shoes, and he used his own house for grinding room, calender
+room, and vulcanizing department, and his wife and children helped to
+make up the goods. His compound at this time was India rubber,
+lampblack, and magnesia, the whole dissolved in turpentine and spread
+upon the flannel cloth which served as the lining for the shoes. It
+was not long, however, before he discovered that the gum, even treated
+this way, became sticky, and then those who had supplied the money for
+the furtherance of these experiments, completely discouraged, made up
+their minds that they could go no further, and so told the inventor.
+
+[Illustration: CHARLES GOODYEAR.]
+
+He, however, had no mind to stop here in his experiments, but, selling
+his furniture and placing his family in a quiet boarding place, he
+went to New York, and there, in an attic, helped by a friendly
+druggist, continued his experiments. His next step in this line was to
+compound the rubber with magnesia and then boil it in quicklime and
+water. This appeared to really solve the problem, and he made some
+beautiful goods. At once it was noised abroad that India rubber had
+been so treated that it lost its stickiness, and he received medals
+and testimonials and seemed on the high road to success, till one day
+he noticed that a drop of weak acid, falling on the cloth, neutralized
+the alkali, and immediately the rubber was soft again. To see this,
+with his knowledge of what rubber should do, proved to him at once
+that his process was not a successful one. He therefore continued
+experimenting, and after preparing his mixtures in his attic in New
+York, would walk three miles to the mill of a Mr. Pike, at Greenwich
+village, and there try various experiments.
+
+In the line of these, he discovered that rubber, dipped in nitric
+acid, formed a surface cure, and he made a great many goods with this
+acid cure which were spoken of, and which even received a letter of
+commendation from Andrew Jackson.
+
+The constant and varied experiments that Goodyear went through with
+affected his health more or less, and at one time he came very near
+being suffocated by gas generated in his laboratory. That he did not
+die then everybody knows, but he was thrown then into a fever by the
+accident and came very near losing his life.
+
+It was there that he formed an acquaintance with Dr. Bradshaw, who was
+very much pleased with the samples of rubber goods that he saw in
+Goodyear's room, and when the doctor went to Europe he took them with
+him, where they attracted a great deal of attention, but beyond that
+nothing was done about them. Now that he appeared to have success, he
+found no difficulty in obtaining a partner, and together the two
+gentlemen fitted up a factory and began to make clothing, life
+preservers, rubber shoes, and a great variety of rubber goods. They
+also had a large factory, with special machinery, built at Staten
+Island, where he removed his family and again had a home of his own.
+Just about this time, when everything looked bright, the great panic
+of 1836-1837 came, and swept away the entire fortune of his associate
+and left Goodyear without a cent, and no means of earning one.
+
+His next move was to go to Boston, where he became acquainted with J.
+Haskins, of the Roxbury Rubber Company, and found in him a firm
+friend, who loaned him money and stood by him when no one would have
+anything to do with the visionary inventor. Mr. Chaffee was also
+exceedingly kind and ever ready to lend a listening ear to his plans,
+and to also assist him in a pecuniary way. It was about this time that
+it occurred to Mr. Chaffee that much of the trouble that they had
+experienced in working India rubber might come from the solvent that
+was used. He therefore invented a huge machine for doing the mixing
+by mechanical means. The goods that were made in this way were
+beautiful to look at, and it appeared, as it had before, that all
+difficulties were overcome.
+
+Goodyear discovered a new method for making rubber shoes and got a
+patent on it, which he sold to the Providence Company, in Rhode
+Island.
+
+The secret of making the rubber so that it would stand heat and cold
+and acids, however, had not been discovered, and the goods were
+constantly growing sticky and decomposing and being returned.
+
+In 1838 he, for the first time, met Nathaniel Hayward, who was then
+running a factory in Woburn. Some time after this Goodyear himself
+moved to Woburn, all the time continuing his experiments. He was very
+much interested in Hayward's sulphur experiments for drying rubber,
+but it appears that neither of them at that time appreciated the fact
+that it needed heat to make the sulphur combine with the rubber and to
+vulcanize it.
+
+The circumstances attending the discovery of his celebrated process is
+thus described by Mr. Goodyear himself in his book, "Gum Elastic." It
+will be observed that he makes use of the third person in all
+references to himself:
+
+ "In the summer of 1838 he became acquainted with Mr. Nathaniel
+ Hayward, of Woburn, Mass., who had been employed as the foreman of
+ the Eagle Company at Woburn, where he had made use of sulphur by
+ impregnating the solvent with it. It was through him that the
+ writer (Charles Goodyear, who makes use all through his book of
+ the third person) received the first knowledge of the use of
+ sulphur as a drier of gum elastic.
+
+ "Mr. Hayward was left in possession of the factory which was
+ abandoned by the Eagle Company. Soon after this it was occupied by
+ the writer, who employed him for the purpose of manufacturing life
+ preservers and other articles by the acid gas process. At this
+ period he made many novel and useful applications of this
+ substance. Among other fancy articles he had newspapers printed on
+ the gum elastic drapery, and the improvement began to be highly
+ appreciated. He therefore now entered, as he thought, upon a
+ successful career for the future. A far different result awaited
+ him.
+
+ "It was supposed by others as well as himself that a change was
+ wrought through the mass of the goods acted upon by the acid gas,
+ and that the whole body of the article was made better than the
+ native gum. The surface of the goods really was so, but owing to
+ the eventual decomposition of the goods beneath the surface, the
+ process was pronounced by the public a complete failure. Thus
+ instead of realizing the large fortune which by all acquainted
+ with his prospects was considered certain, his whole invention
+ would not bring him a week's living.
+
+ "He was obliged for the want of means to discontinue
+ manufacturing, and Mr. Hayward left his employment. The inventor
+ now applied himself alone, with unabated ardor and diligence, to
+ detect the cause of his misfortune and if possible to retrieve the
+ lost reputation of his invention. On one occasion he made some
+ experiments to ascertain the effect of heat upon the same compound
+ that had decomposed in the articles previously manufactured, and
+ was surprised to find that the specimen, being carelessly brought
+ in contact with a hot stove, charred like leather. He endeavored
+ to call the attention of his brother as well as some other
+ individuals who were present, and who were acquainted with the
+ manufacture of gum elastic, to this effect as remarkable and
+ unlike any before known, since gum elastic always melted when
+ exposed to a high degree of heat. The occurrence did not at the
+ time appear to them to be worthy of notice. It was considered as
+ one of the frequent appeals that he was in the habit of making in
+ behalf of some new experiment. He, however, directly inferred that
+ if the process of charring could be stopped at the right point, it
+ might divest the gum of its native adhesiveness throughout, which
+ would make it better than the native gum.
+
+ "He made another trial of heating a similar fabric, before an open
+ fire. The same effect, that of charring the gum, followed, but
+ there were further and very satisfactory indications of ultimate
+ success in producing the desired result, as upon the edge of the
+ charred portions of the fabric there appeared a line, or border,
+ that was not charred, but perfectly cured.
+
+ "These facts have been stated precisely as they occurred in
+ reference to the acid gas, as well as the vulcanizing process.
+
+ "The incidents attending the discovery of both have a strong
+ resemblance, so much so they may be considered parallel cases. It
+ being now known that the results of the vulcanizing process are
+ produced by means and in a manner which would not have been
+ anticipated from any reasoning on the subject, and that they have
+ not yet been satisfactorily accounted for, it has been sometimes
+ asked, how the inventor came to make the discovery? The answer has
+ already been given. It may be added that he was many years seeking
+ to accomplish this object, and that he allowed nothing to escape
+ his notice that related to the subject. Like the falling of an
+ apple, it was suggestive of an important fact to one whose mind
+ was previously prepared to draw an inference from any occurrence
+ which might favor the object of his research. While the inventor
+ admits that these discoveries were not the results of scientific
+ chemical investigations, _he is not willing to admit that they
+ were the result of what is commonly termed accident_; he claims
+ them to be the result of the closest application and observation.
+
+ "The discoloring and charring of the specimens proved nothing and
+ discovered nothing of value, but quite the contrary, for in the
+ first instance, as stated in the acid gas improvement, the
+ specimen acted upon was thrown away as worthless and left for some
+ time; in the latter instance, the specimen that was charred was in
+ like manner disregarded by others.
+
+ "It may, therefore, be considered as one of those cases where the
+ leading of the Creator providentially aids his creatures, by what
+ are termed 'accidents,' to attain those things which are not
+ attainable by the powers of reasoning he has conferred on them."
+
+Now that Goodyear was sure that he had the key to the intricate puzzle
+that he had worked over for so many years, he began at once to tell
+his friends about it and to try to secure capital, but they had
+listened to their sorrow so many times that his efforts were futile.
+For a number of years be struggled and experimented and worked along
+in a small way, his family suffering with himself the pangs of the
+extremest poverty. At last he went to New York and showed some of his
+samples to William Ryder, who, with his brother Emory, at once
+appreciated the value of the discovery and started in to
+manufacturing. Even here Goodyear's bad luck seemed to follow him, for
+the Ryder Bros. failed and it was impossible to continue the business.
+
+He had, however, started a small factory at Springfield, Mass., and
+his brother-in-law, Mr. De Forest, who was a wealthy woolen
+manufacturer, took Ryder's place, and the work of making the invention
+practical was continued. In 1844 it was so far perfected that Goodyear
+felt it safe to take out a patent. The factory at Springfield was run
+by his brothers, Nelson and Henry.
+
+In 1843 Henry started one in Naugatuck, and in 1844 introduced
+mechanical mixing in place of the mixture by the use of solvents.
+
+In the year 1852 Goodyear went to Europe, a trip that he had long
+planned, and saw Hancock, then in the employ of Charles Macintosh &
+Co. Hancock admitted in evidence that the first piece of vulcanized
+rubber he ever saw came from America, but claimed to have reinvented
+vulcanization and secured patents in Great Britain, but it is _a
+remarkable fact_ that Charles Goodyear's French patent was the first
+publication in Europe of this discovery.
+
+In 1852 a French company were licensed by Mr. Goodyear to make shoes,
+and a great deal of interest was felt in the new business. In 1855 the
+French emperor gave to Charles Goodyear the grand medal of honor and
+decorated him with the cross of the legion of honor in recognition of
+his services as a public benefactor, but the French courts
+subsequently set aside his French patents on the ground of the
+importation of vulcanized goods from America by licenses under the
+United States patents. He died July 1, 1860, at the Fifth Avenue
+Hotel, New York City.--_India Rubber World_.
+
+ * * * * *
+
+[Continued from SUPPLEMENT, No. 786, page 12558.]
+
+
+
+
+THE ELECTROMAGNET.
+
+[Footnote: Lectures delivered before the Society of Arts, London,
+1890. From the Journal of the Society.]
+
+BY PROFESSOR SILVANUS P. THOMPSON, D. SC., B.A., M.I.E.E.
+
+III.
+
+RESEARCHES OF PROFESSOR HUGHES.
+
+
+[Illustration: FIG. 51.--HUGHES' ELECTROMAGNET.]
+
+His object was to find out the best form of electromagnet, the best
+distance between the poles, and the best form of armature for the
+rapid work required in Hughes' printing telegraphs. One word about
+Hughes' magnets. This diagram (Fig. 51) shows the form of the well
+known Hughes' electromagnet. I feel almost ashamed to say those words
+"well known," because on the Continent everybody knows what you mean
+by a Hughes' electromagnet. In England scarcely anyone knows what you
+mean. Englishmen do not even know that Professor Hughes has invented a
+special form of electromagnet. Hughes' special form is this: A
+permanent steel magnet, generally a compound one, having soft iron
+pole pieces, and a couple of coils on the pole pieces only. As I have
+to speak of Hughes' special contrivance among the mechanisms that will
+occupy our attention later on, I only now refer to this magnet in one
+particular. If you wish a magnet to work rapidly, you will secure the
+most rapid action, not when the coils are distributed all along, but
+when they are heaped up near, not necessarily entirely on, the poles.
+Hughes made a number of researches to find out what the right length
+and thickness of these pole pieces should be. It was found an
+advantage not to use too thin pole pieces, otherwise the magnetism
+from the permanent magnet did not pass through the iron without
+considerable reluctance, being choked by insufficiency of section:
+also not to use too thick pieces, otherwise they presented too much
+surface for leakage across from one to the other. Eventually a
+particular length was settled upon, in proportion about six times the
+diameter, or rather longer. In the further researches that Hughes made
+he used a magnet of shorter form, not shown here, more like those
+employed in relays, and with an armature from 2 to 3 millimeters
+thick, 1 centimeter wide and 5 centimeters long. The poles were turned
+over at the top toward one another. Hughes tried whether there was any
+advantage in making those poles approach one another, and whether
+there was any advantage in having as long an armature as 5
+centimeters. He tried all the different kinds, and plotted out the
+results of observations in curves, which could be compared and
+studied. His object was to ascertain the conditions which would give
+the strongest pull, not with a steady current, but with such currents
+as were required for operating his printing telegraph instruments;
+currents which lasted but one to twenty hundredths of a second. He
+found it was decidedly an advantage to shorten the length of the
+armature, so that it did not protrude far over the poles. In fact, he
+got a sufficient magnetic circuit to secure all the attractive power
+that he needed, without allowing as much chance of leakage as there
+would have been had the armature extended a longer distance over the
+poles. He also tried various forms of armature having very various
+cross sections.
+
+
+POSITION AND FORM OF ARMATURE.
+
+In one of Du Moncel's papers on electromagnets[1] you will also find a
+discussion on armatures, and the best forms for working in different
+positions. Among other things in Du Moncel you will find this paradox:
+that whereas using a horseshoe magnet with fat poles, and a flat piece
+of soft iron for armature, it sticks on far tighter when put on
+edgeways; on the other hand, if you are going to work at a distance,
+across air, the attraction is far greater when it is set flatways. I
+explained the advantage of narrowing the surfaces of contact by the
+law of traction, B squared, coming in. Why should we have for action at a
+distance the greater advantage from placing the armature flatway to
+the poles? It is simply that you thereby reduce the reluctance offered
+by the air gap to the flow of the magnetic lines. Du Moncel also tried
+the difference between round armatures and flat ones, and found that a
+cylindrical armature was only attracted about half as strongly as a
+prismatic armature having the same surface when at the same distance.
+Let us examine this fact in the light of the magnetic circuit. The
+poles are flat. You have at a certain distance away a round armature;
+there is a certain distance between its nearest side and the polar
+surfaces. If you have at the same distance away a flat armature having
+the same surface, and, therefore, about the same tendency to leak, why
+do you get a greater pull in this case than in that? I think it is
+clear that if they are at the same distance away, giving the same
+range of motion, there is a greater magnetic reluctance in the case of
+the round armature, although there is the same periphery, because,
+though the nearest part of the surface is at the prescribed distance,
+the rest of the under surface is farther away; so that the gain found
+in substituting an armature with a flat surface is a gain resulting
+from the diminution in the resistance offered by the air gap.
+
+[Footnote 1: "La Lumiere Electrique," vol. ii.]
+
+
+POLE PIECES ON HORSESHOE MAGNETS.
+
+Another of Du Moncel's researches[2] relates to the effect of polar
+projections or shoes--movable pole pieces, if you like--upon a
+horseshoe electromagnet. The core of this magnet was of round iron 4
+centimeters in diameter, and the parallel limbs were 10 centimeters
+long and 6 centimeters apart. The shoes consisted of two flat pieces
+of iron slotted out at one end, so that they could be slid along over
+the poles and brought nearer together. The attraction exerted on a
+flat armature across air gaps 2 millimeters thick was measured by
+counterpoising. Exciting this electromagnet with a certain battery, it
+was found that the attraction was greatest when the shoes were pushed
+to about 15 millimeters, or about one-quarter of the interpolar
+distance, apart. The numbers were as follows:
+
+ Distance between
+ shoes. Attraction,
+ Millimeters. in grammes.
+
+ 2 900
+ 10 1,012
+ 15 1,025
+ 25 965
+ 40 890
+ 60 550
+
+[Footnote 2: "La Lumiere Electrique," vol. iv., p. 129.]
+
+With a stronger battery the magnet without shoes had an attraction of
+885 grammes, but with the shoes 15 millimeters apart, 1,195 grammes.
+When one pole only was employed, the attraction, which was 88 grammes
+without a shoe, was _diminished_ by adding a shoe to 39 grammes!
+
+
+CONTRAST BETWEEN ELECTROMAGNETS AND PERMANENT MAGNETS.
+
+Now I want particularly to ask you to guard against the idea that all
+these results obtained from electromagnets are equally applicable to
+permanent magnets of steel; they are not, for this simple reason. With
+an electromagnet, when you put the armature near, and make the
+magnetic circuit better, you not only get more magnetic lines going
+through that armature, but you get more magnetic lines going through
+the whole of the iron. You get more magnetic lines round the bend when
+you put an armature on to the poles, because you have a magnetic
+circuit of less reluctance with the same external magnetizing power in
+the coils acting around it. Therefore, in that case, you will have a
+greater magnetic flux all the way round. The data obtained with the
+electromagnet (Fig. 42), with the exploring coil, C, on the bend of
+the core, where the armature was in contact, and when it was removed
+are most significant. When the armature was present it multiplied the
+total magnetic flow tenfold for weak currents and nearly threefold for
+strong currents. But with a steel horseshoe, magnetized once for all,
+the magnetic lines that flow around the bend of the steel are a fixed
+quantity, and, however much you diminish the reluctance of the
+magnetic circuit, you do not create or evoke any more. When the
+armature is away the magnetic lines arch across, not at the ends of
+the horseshoe only, but from its flanks; the whole of the magnetic
+lines leaking somehow across the space. Where you have put the
+armature on, these lines, instead of arching out into space as freely
+as they did, pass for the most part along the steel limbs and through
+the iron armature. You may still have a considerable amount of
+leakage, but you have not made one line more go through the bent part.
+You have absolutely the same number going through the bend with the
+armature off as with the armature on. You do not add to the total
+number by reducing the magnetic reluctance, because you are not
+working under the influence of a constantly impressed magnetizing
+force. By putting the armature on to a steel horseshoe magnet you
+only _collect_ the magnetic lines, you do not _multiply_ them. This is
+not a matter of conjecture. A group of my students have been making
+experiments in the following way: They took this large steel horseshoe
+magnet (Fig. 52), the length of which, from end to end, through the
+steel, is 421/2 inches. A light, narrow frame was constructed so that it
+could be slipped on over the magnet, and on it were wound 30 turns of
+fine wire, to serve as an exploring coil. The ends of this coil were
+carried to a distant part of the laboratory, and connected to a
+sensitive ballistic galvanometer. The mode of experimenting is as
+follows:
+
+The coil is slipped on over the magnet (or over its armature) to any
+desired position. The armature of the magnet is placed gently upon the
+poles, and time enough is allowed to elapse for the galvanometer
+needle to settle to zero. The armature is then suddenly detached. The
+first swing measures the change, due to removing the armature, in the
+number of magnetic lines that pass through the coil in the particular
+position.
+
+[Illustration: FIG. 52.--EXPERIMENT WITH PERMANENT MAGNET.]
+
+I will roughly repeat the experiment before you: The spot of light on
+the screen is reflected from my galvanometer at the far end of the
+table. I place the exploring coil just over the pole, and slide on the
+armature; then close the galvanometer circuit. Now I detach the
+armature, and you observe the large swing. I shift the exploring coil,
+right up to the bend; replace the armature; wait until the spot of
+light is brought to rest at the zero of the scale. Now, on detaching
+the armature, the movement of the spot of light is quite
+imperceptible. In our careful laboratory experiments, the effect was
+noticed inch by inch all along the magnet. The effect when the
+exploring coil was over the bend was not as great as 1-3000th part of
+the effect when the coil was hard up to the pole. We are, therefore,
+justified in saying that the number of magnetic lines in a permanently
+magnetized steel horseshoe magnet is not altered by the presence or
+absence of the armature.
+
+You will have noticed that I always put on the armature gently. It
+does not do to slam on the armature; every time you do so, you knock
+some of the so-called permanent magnetism out of it. But you may pull
+off the armature as suddenly as you like. It does the magnet good
+rather than harm. There is a popular superstition that you ought never
+to pull off the keeper of a magnet suddenly. On investigation, it is
+found that the facts are just the other way. You may pull off the
+keeper as suddenly as you like, but you should never slam it on.
+
+From these experimental results I pass to the special design of
+electromagnets for special purposes.
+
+
+ELECTROMAGNETS FOR MAXIMUM TRACTION.
+
+These have already been dealt with in the preceding lecture; the
+characteristic feature of all the forms suitable for traction being
+the compact magnetic circuit.
+
+Several times it has been proposed to increase the power of
+electromagnets by constructing them with intermediate masses of iron
+between the central core and the outside, between the layers of
+windings. All these constructions are founded on fallacies. Such iron
+is far better placed either right inside the coils or right outside
+them, so that it may properly constitute a part of the magnetic
+circuit. The constructions known as Camacho's and Cance's, and one
+patented by Mr. S.A. Varley, in 1877, belonging to this delusive order
+of ideas, are now entirely obsolete.
+
+Another construction which is periodically brought forward as a
+novelty is the use of iron windings of wire or strip in place of
+copper winding. The lower electric conductivity of iron, as compared
+with copper, makes such a construction wasteful of exciting power. To
+apply equal magnetizing power by means of an iron coil implies the
+expenditure of about six times as many watts as need be expended if
+the coil is of copper.
+
+
+ELECTROMAGNETS FOR MAXIMUM RANGE OF ATTRACTION.
+
+We have already laid down the principle which will enable us to design
+electromagnets to act at a distance. We want our magnet to project, as
+it were, its force across the greatest length of air gap. Clearly,
+then, such a magnet must have a very large magnetizing power, with
+many ampere turns upon it, to be able to make the required number of
+magnetic lines pass across the air resistance. Also it is clear that
+the poles must not be too close together for its work, otherwise the
+magnetic lines at one pole will be likely to curl round and take short
+cuts to the other pole. There must be a wider width between the poles
+than is desirable in electromagnets for traction.
+
+
+ELECTROMAGNETS OF MINIMUM WEIGHT.
+
+In designing an apparatus to put on board a boat or a balloon, where
+weight is a consideration of primary importance, there is again a
+difference. There are three things that come into play--iron, copper,
+and electric current. The current weighs nothing, therefore, if you
+are going to sacrifice everything else to weight, you may have
+comparatively little iron, but you must have enough copper to be able
+to carry the electric current; and under such circumstances you must
+not mind heating your wires nearly red hot to pass the biggest
+possible current. Provide as little copper as you conveniently can,
+sacrificing economy in that case to the attainment of your object;
+but, of course, you must use fireproof material, such as asbestos, for
+insulating, instead of cotton or silk.
+
+
+A USEFUL GUIDING PRINCIPLE.
+
+In all cases of design there is one leading principle which will be
+found of great assistance, namely, that a magnet always tends so to
+act as though it tried to diminish the length of its magnetic circuit.
+It tries to grow more compact. This is the reverse of that which holds
+good with an electric current. The electric circuit always tries to
+enlarge itself, so as to inclose as much space as possible, but the
+magnetic circuit always tries to make itself as compact as possible.
+Armatures are drawn in as near as can be, to close up the magnetic
+circuit. Many two-pole electromagnets show a tendency to bend together
+when the current is turned on. One form in particular, which was
+devised by Ruhmkorff for the purpose of repeating Faraday's celebrated
+experiment on the magnetic rotation of polarized light, is liable to
+this defect. Indeed, this form of electromagnet is often designed very
+badly, the yoke being too thin, both mechanically and magnetically,
+for the purpose which it has to fulfill.
+
+Here is a small electric bell, constructed by Wagener, of Wiesbaden,
+the construction of which illustrates this principle. The
+electromagnet, a horseshoe, lies horizontally; its poles are provided
+with protruding curved pins of brass. Through the armature are drilled
+two holes, so that it can be hung upon the two brass pins; and when so
+hung up it touches the ends of the iron cores just at one edge, being
+held from more perfect contact by a spring. There is no complete gap,
+therefore, in the magnetic circuit. When the current comes and applies
+a magnetizing power, it finds the magnetic circuit already complete in
+the sense that there are no absolute gaps. But the circuit can be
+bettered by tilting the armature to bring it flat against the polar
+ends, that being indeed the mode of motion. This is a most reliable
+and sensitive pattern of bell.
+
+[Illustration: FIG. 53.--ELECTROMAGNETIC POP-GUN.]
+
+_Electromagnetic Pop-gun._--Here is another curious illustration of
+the tendency to complete the magnetic circuit. Here is a tubular
+electromagnet (Fig. 53), consisting of a small bobbin, the core of
+which is an iron tube about two inches long. There is nothing very
+unusual about it; it will stick on, as you see, to pieces of iron when
+the current is turned on. It clearly is an ordinary electromagnet in
+that respect. Now suppose I take a little round rod of iron, about an
+inch long, and put it into the end of the tube, what will happen when
+I turn on my current? In this apparatus as it stands, the magnetic
+circuit consists of a short length of iron, and then all the rest is
+air. The magnetic circuit will try to complete itself, not by
+shortening the iron, but by _lengthening_ it; by pushing the piece of
+iron out so as to afford more surface for leakage. That is exactly
+what happens; for, as you see, when I turn on the current, the little
+piece of iron shoots out and drops down. You see that little piece of
+iron shoot out with considerable force. It becomes a sort of magnetic
+popgun. This is an experiment which has been twice discovered. I found
+it first described by Count Du Moncel, in the pages of _La Lumiere
+Electrique_, under the name of the "pistolet electromagnetique;" and
+Mr. Shelford Bidwell invented it independently. I am indebted to him
+for the use of this apparatus. He gave an account of it to the
+Physical Society, in 1885, but the reporter missed it, I suppose, as
+there is no record in the society's proceedings.
+
+
+ELECTROMAGNETS FOR USE WITH ALTERNATING CURRENTS.
+
+When you are designing electromagnets for use with alternating
+currents, it is necessary to make a change in one respect, namely, you
+must so laminate the iron that internal eddy currents shall not occur;
+indeed, for all rapid-acting electromagnetic apparatus it is a good
+rule that the iron must not be solid. It is not usual with telegraphic
+instruments to laminate them by making up the core of bundles of iron
+plates or wires, but they are often made with tubular cores, that is
+to say, the cylindrical iron core is drilled with a hole down the
+middle, and the tube so formed is slit with a saw cut to prevent the
+circulation of currents in the substance of the tube. Now when
+electromagnets are to be employed with rapidly alternating currents,
+such as are used for electric lighting, the frequency of the
+alternations being usually about 100 periods per second, slitting the
+cores is insufficient to guard against eddy currents; nothing short of
+completely laminating the cores is a satisfactory remedy. I have here,
+thanks to the Brush Electric Engineering Company, an electromagnet of
+the special form that is used in the Brush arc lamp when required for
+the purpose of working in an alternating current circuit. It has two
+bobbins that are screwed up against the top of an iron box at the head
+of the lamp. The iron slab serves as a kind of yoke to carry the
+magnetism across the top. There are no fixed cores In the bobbins,
+which are entered by the ends of a pair of yoked plungers. Now in the
+ordinary Brush lamp for use with a steady current, the plungers are
+simply two round pieces of iron tapped into a common yoke; but for
+alternate current working this construction must not be used, and
+instead a U-shaped double plunger is used, made up of laminated iron,
+riveted together. Of course it is no novelty to use a laminated core;
+that device, first used by Joule, and then by Cowper, has been
+repatented rather too often during the past fifty years to be
+considered as a recent invention.
+
+The alternate rapid reversals of the magnetism in the magnetic field
+of an electromagnet, when excited by alternating electric currents,
+sets up eddy currents in every piece of undivided metal within range.
+All frames, bobbin tubes, bobbin ends, and the like, must be most
+carefully slit, otherwise they will overheat. If a domestic flat iron
+is placed on the top of the poles of a properly laminated
+electromagnet, supplied with alternating currents, the flat iron is
+speedily heated up by the eddy currents that are generated internally
+within it. The eddy currents set up by induction in neighboring masses
+of metal, especially in good conducting metals such as copper, give
+rise to many curious phenomena. For example, a copper disk or copper
+ring placed over the pole of a straight electromagnet so excited is
+violently repelled. These remarkable phenomena have been recently
+investigated by Professor Elihu Thomson, with whose beautiful and
+elaborate researches we have lately been made conversant in the pages
+of the technical journals. He rightly attributes many of the repulsion
+phenomena to the lag in phase of the alternating currents thus induced
+in the conducting metal. The electromagnetic inertia, or
+self-inductive property of the electric circuit, causes the currents
+to rise and fall later in time than the electromotive forces by which
+they are occasioned. In all such cases the impedance which the circuit
+offers is made up of two things--resistance and inductance. Both these
+causes tend to diminish the amount of current that flows, and the
+inductance also tends to delay the flow.
+
+
+ELECTROMAGNETS FOR QUICKEST ACTION.
+
+I have already mentioned Hughes' researches on the form of
+electromagnet best adapted for rapid signaling. I have also
+incidentally mentioned the fact that where rapidly varying currents
+are employed, the strength of the electric current that a given
+battery can yield is determined not so much by the resistance of the
+electric circuit as by its electric inertia. It is not a very easy
+task to explain precisely what happens to an electric circuit when the
+current is turned on suddenly. The current does not suddenly rise to
+its full value, being retarded by inertia. The ordinary law of Ohm in
+its simple form no longer applies; one needs to apply that other law
+which bears the name of the law of Helmholtz, the use of which is to
+give us an expression, not for the final value of the current, but for
+its value at any short time, t, after the current has been turned on.
+The strength of the current after a lapse of a short time, t, cannot
+be calculated by the simple process of taking the electromotive force
+and dividing it by the resistance, as you would calculate steady
+currents.
+
+In symbols, Helmholtz's law is:
+
+ i_{t} = E/R ( 1 - e^{-(R/L)t} )
+
+In this formula i_{t} means the strength of the current after the
+lapse of a short time t; E is the electromotive force; R, the
+resistance of the whole circuit; L, its coefficient of self-induction;
+and _e_ the number 2.7183, which is the base of the Napierian
+logarithms. Let us look at this formula; in its general form it
+resembles Ohm's law, but with a new factor, namely, the expression
+contained within the brackets. The factor is necessarily a fractional
+quantity, for it consists of unity less a certain negative
+exponential, which we will presently further consider. If the factor
+within brackets is a quantity less than unity, that signifies that
+i_{t} will be less than E / R. Now the exponential of negative sign,
+and with negative fractional index, is rather a troublesome thing to
+deal with in a popular lecture. Our best way is to calculate some
+values, and then plot it out as a curve. When once you have got it
+into the form of a curve, you can begin to think about it, for the
+curve gives you a mental picture of the facts that the long formula
+expresses in the abstract. Accordingly we will take the following
+case. Let E = 2 volts; R = 1 ohm; and let us take a relatively large
+self-induction, so as to exaggerate the effect; say let L = 10 quads.
+This gives us the following:
+
+ ________________________________________
+ | | | |
+ | t_{(sec.)} | e^{+(R/L)t} | i_{t} |
+ --------------+--------------+---------|
+ | 0 | 1 | 0 |
+ | 1 | 1.105 | 0.950 |
+ | 2 | 1.221 | 1.810 |
+ | 5 | 1.649 | 3.936 |
+ | 10 | 2.718 | 6.343 |
+ | 20 | 7.389 | 8.646 |
+ | 30 | 20.08 | 9.501 |
+ | 60 | 403.4 | 9.975 |
+ | 120 | 16200.0 | 9.999 |
+ ----------------------------------------
+
+In this case the value of the steady current as calculated by Ohm's
+law is 10 amperes, but Helmholtz's law shows us that with the great
+self-induction which we have assumed to be present, the current, even
+at the end of 30 seconds, has only risen up to within 5 percent. of
+its final value; and only at the end of two minutes has practically
+attained full strength. These values are set out in the highest curve
+in Fig. 54, in which, however, the further supposition is made that
+the number of spirals, S, in the coils of the electromagnet is 100, so
+that when the current attains its full value of 10 amperes, the full
+magnetizing power will be Si = 1000. It will be noticed that the
+curve rises from zero at first steeply and nearly in a straight line,
+then bends over, and then becomes nearly straight again, as it
+gradually rises to its limiting value. The first part of the
+curve--that relating to the strength of the current after _very small_
+interval of time--is the period within which the strength of the
+current is governed by inertia (i.e., the self-induction) rather than
+by resistance. In reality the current is not governed either by the
+self-induction or by the resistance alone, but by the ratio of the
+two. This ratio is sometimes called the "time constant" of the
+circuit, for it represents _the time_ which the current takes in that
+circuit to rise to a definite fraction of its final value.
+
+ E = 10
+ r = 1
+ R = 100
+ L = 10
+
+ Si
+ 1000 + _..-------------------------------
+ | . _ _---------
+ | . .----
+ | . .- 2 IN SERIES
+ | . .-
+ | -
+ | .: - :
+ | .: . :
+ 500 | . : __- -:---------------------------
+ | . : _.- - : 2 IN PARALLEL
+ | . :. - :
+ | . / : - :
+ | . / - :
+ |. / - : :
+ |./. : :
+ |/_____:_____________:____________________________ t
+ 10 20 40 60 80 100 120
+
+ FIG. 54.--CURVES OF RISE OF CURRENTS.
+
+This definite fraction is the fraction (e - 1)/e; or in decimals,
+0.634. All curves of rise of current are alike in general shape, they
+differ only in scale, that is to say, they differ only in the height
+to which they will ultimately rise, and in the time they will take to
+attain this fraction of their final value.
+
+_Example (1)._--Suppose E = 10; R = 200 ohms; L = 8. The final value
+of the current will be 0.025 amp. or 25 milliamperes. Then the time
+constant will be 8 / 400 = 1-50th sec.
+
+_Example (2)._--The P.O. Standard "A" relay has R = 400 ohms; L =
+3.25. It works with 0.5 milliampere current, and therefore will work
+with 5 Daniell cells through a line of 9,600 ohms. Under these
+circumstances the time constant of the instrument on short circuit is
+0.0081 sec.
+
+It will be noted that the time constant of a circuit can be reduced
+either by diminishing the self-induction or by increasing the
+resistance. In Fig. 54 the position of the time constant for the top
+curve is shown by the vertical dotted line at 10 seconds. The current
+will take 10 seconds to rise to 0.634 of its final value. This
+retardation of the rise of current is simply due to the presence of
+coils and electromagnets in the circuit; the current as it grows being
+retarded because it has to create magnetic fields in these coils, and
+so sets up opposing electromotive forces that prevent it from growing
+all at once to its full strength. Many electricians, unacquainted with
+Helmholtz's law, have been in the habit of accounting for this by
+saying that there is a lag in the iron of the electromagnet cores.
+They tell you that an iron core cannot be magnetized suddenly, that it
+takes time to acquire its magnetism. They think it is one of the
+properties of iron. But we know that the only true time lag in the
+magnetization of iron, that which is properly termed "viscous
+hysteresis," does not amount to any great percentage of the whole
+amount of magnetization, takes comparatively a long time to show
+itself, and cannot therefore be the cause of the retardation which we
+are considering. There are also electricians who will tell you that
+when magnetization is suddenly evoked in an iron bar, there are
+induction currents set up in the iron which oppose and delay its
+magnetization. That they oppose the magnetization is perfectly true,
+but if you carefully laminate the iron so as to eliminate eddy
+currents, you will find, strangely enough, that the magnetism rises
+still more slowly to its final value. For by laminating the iron you
+have virtually increased the self-inductive action, and increased the
+time constant of the circuit, so that the currents rise more slowly
+than before. The lag is not in the iron, but in the magnetizing
+current, and the current being retarded, the magnetization is of
+course retarded also.
+
+
+CONNECTING COILS FOR QUICKEST ACTION.
+
+Now let us apply these most important though rather intricate
+considerations to the practical problems of the quick working of the
+electromagnet. Take the case of an electromagnet forming some part of
+the receiving apparatus of a telegraph system in which it is desired
+to secure very rapid working. Suppose the two coils that are wound
+upon the horseshoe core are connected together in series. The
+coefficient of self-induction for these two is four times as great as
+that of either separately; coefficients of self-induction being
+proportional to the square of the number of turns of wire that
+surround a given core. Now if the two coils instead of being put in
+series are put in parallel, the coefficient of self-induction will be
+reduced to the same value as if there were only one coil, because half
+the line current (which is practically unaltered) will go through each
+coil. Hence the time constant of the circuit when the coils are in
+parallel will be a quarter of that which it is when the coils are in
+series; on the other hand, for a given line current, the final
+magnetizing power of the two coils in parallel is only half what it
+would be with the coil in series. The two lower curves in Fig. 54
+illustrate this, from which it is at once plain that the magnetizing
+power for very brief currents is greater when the two coils are put in
+parallel with one another than when they are joined in series.
+
+Now this circumstance has been known for some time to telegraph
+engineers. It has been patented several times over. It has formed the
+theme of scientific papers, which have been read both in France and in
+England. The explanation generally given of the advantage of uniting
+the coils in parallel is, I think, fallacious; namely that the "extra
+currents" (i.e., currents due to self-induction) set up in the two
+coils are induced in such directions as tend to help one another when
+the coils are in series, and to neutralize one another when they are
+in parallel. It is a fallacy, because in neither case do they
+neutralize one another. Whichever way the current flows to make the
+magnetism, it is opposed in the coils while the current is rising,
+and helped in the coils while the current is falling, by the so-called
+extra currents. If the current is rising in both coils at the same
+moment, then, whether the coils are in series or in parallel, the
+effect of self-induction is to retard the rise of the current. The
+advantage of parallel grouping is simply that it reduces the time
+constant.
+
+
+BATTERY GROUPING FOR QUICKEST ACTION.
+
+One may consider the question of grouping the battery cells from the
+same point of view. How does the need for rapid working, and the
+question of time constant, affect the best mode of grouping the
+battery cells? The amateur's rule, which tells you to so arrange your
+battery that its internal resistance should be equal to the external
+resistance, gives you a result wholly wrong for rapid working. The
+supposed best arrangement will not give you (at the expense even of
+economy) the best result that might be got out of the given number of
+cells. Let us take an example and calculate it out, and place the
+results graphically before our eyes in the form of curves. Suppose the
+line and electromagnet have together a resistance of 6 ohms, and that
+we have 24 small Daniell cells, each of electromotive force say 1 volt,
+and of internal resistance 4 ohms. Also let the coefficient of
+self-induction of the electromagnet and circuit be 6 quadrants. When
+all the cells are in series, the resistance of the battery will be 96
+ohms, the total resistance of the circuit 102 ohms, and the full value
+of the current 0.235 ampere. When all the cells are in parallel, the
+resistance of the battery will be 0.133 ohm, the total resistance
+6.133 ohms, and the full value of the current 0.162 ampere. According
+to the amateur rule of grouping cells so that internal resistance
+equals external, we must arrange the cells in 4 parallels, each having
+6 cells in series, so that the internal resistance of the battery will
+be 6 ohms, total resistance of circuit 12 ohms, full value of current
+0.5 ampere. Now the corresponding time constants of the circuit in the
+three cases (calculated by dividing the coefficient of self-induction
+by the total resistance) will be respectively--in series, 0.06 sec.;
+in parallel, 0.5 sec.; grouped for maximum steady current, 0.96 sec.
+From these data we may now draw the three curves, as in Fig. 55,
+wherein the abscissae are the values of time in seconds and the
+ordinates the current. The faint vertical dotted lines mark the time
+constants in the three cases. It will be seen that when rapid working
+is required the magnetizing current will rise, during short intervals
+of time, more rapidly if all the cells are put in series than it will
+do if the cells are grouped according to the amateur rule.
+
+ |
+ 5| .
+ | .
+ | .
+ 4| MAXIMUM .
+ | OUTPUT \ .
+ | .
+ 3| .
+ | . : ALL IN SERIES
+ | _-------------------:------------------------------
+ 2| .- - :
+ | - - :
+ | -: - :
+ 1| / : - : ALL IN PARALLEL
+ |. : . : _________--------
+ |- :__ : ----------
+ +-----------------------------:-------------------------------
+ 0 1 2 3 4 5 6 7 8 9 10
+
+FIG. 55.--CURVES OF RISE OF CURRENT WITH DIFFERENT GROUPINGS OF BATTERY.
+
+When they are all put in series, so that the battery has a much
+greater resistance than the rest of the circuit, the current rises
+much more rapidly, because of the smallness of the time constant,
+although it never attains the same ultimate maximum as when grouped in
+the other way. That is to say, if there is self-induction as well as
+resistance in the circuit, the amateur rule does not tell you the best
+way of arranging the battery. There is another mode of regarding the
+matter which is helpful. Self-induction, while the current is growing,
+acts as if there were a sort of spurious addition to the resistance of
+the circuit; and while the current is dying away it acts of course in
+the other way, as if there were a subtraction from the resistance.
+Therefore you ought to arrange the battery so that the internal
+resistance is equal to the real resistance of the circuit, plus the
+spurious resistance during that time. But how much is the spurious
+resistance during that time? It is a resistance proportional to the
+time that has elapsed since the current was turned on. So then it
+comes to a question of the length of time for which you want to work
+it. What fraction of a second do you require your signal to be given
+in? What is the rate of the vibrator of your electric bell? Suppose
+you have settled that point, and that the short time during which the
+current is required to rise is called t; then the apparent resistance
+at time t after the current is turned on is given by the formula:
+
+ R_{t} = R x e^{(R/L)t} + ( e^{(R/L)t} - 1 )
+
+
+TIME CONSTANTS OF ELECTROMAGNETS.
+
+I may here refer to some determinations made by M. Vaschy,[1]
+respecting the coefficients of self-induction of the electromagnets of
+a number of pieces of telegraphic apparatus. Of these I must only
+quote one result, which is very significant. It relates to the
+electromagnet of a Morse receiver of the pattern habitually used on
+the French telegraph lines.
+
+ L, in quadrants.
+ Bobbins, separately, without iron cores. 0.233 and 0.265
+ Bobbins, separately, with iron cores. 1.65 and 1.71
+ Bobbins, with cores joined by yoke,
+ coils in series 6.37
+ Bobbins, with armature resting on poles. 10.68
+
+[Footnote 1: "Bulletin de la Societe Internationale des Electriciens,"
+1886.]
+
+It is interesting to note how the perfecting of the magnetic circuit
+increases the self-induction.
+
+Thanks to the kindness of Mr. Preece, I have been furnished with some
+most valuable information about the coefficients of self-induction,
+and the resistance of the standard pattern of relays, and other
+instruments which are used in the British postal telegraph service,
+from which data one is able to say exactly what the time constants of
+those instruments will be on a given circuit, and how long in their
+case the current will take to rise to any given fraction of its final
+value. Here let me refer to a very capital paper by Mr. Preece in an
+old number of the "Journal of the Society of Telegraph Engineers," a
+paper "On Shunts," in which he treats this question, not as perfectly
+as it could now be treated with the fuller knowledge we have in 1890
+about the coefficients of self-induction, but in a very useful and
+practical way. He showed most completely that the more perfect the
+magnetic circuit is--though of course you are getting more magnetism
+from your current--the more is that current retarded. Mr. Preece'e
+mode of experiment was extremely simple. He observed the throw of the
+galvanometer when the circuit which contained the battery and the
+electromagnet was opened by a key which at the same moment connected
+the electromagnet wires to the galvanometer. The throw of the
+galvanometer was assumed to represent the extra current which flowed
+out. Fig. 56 represents a few of the results of Mr. Preece's paper.
+
+ +==========+
+ |=| |=| |=| |=| |=|
+ \======= \======= =======/ ======= =======
+ | | | | | | | | | |
+ | | | | | | | | | |
+ | | | |--| | | | | |
+ ======= ======= ======= /======= =======\
+ |=| |=| |=| |=| |=|
+
+ +===========+ +==========+ +===== ======+
+ |=| |=| |=| |=| |=| |=|
+ ======= =======/ B\======= =======/A A\======= =======/B
+ | | | | | | | | | | | |
+ | | | | | | | | | | | |
+ | |--| | | | | | | | | |
+ ======= ======= A======= =======B =======B =======A
+ |=| |=| |=| |=| |=| |=|
+ +==========+ +==========+ +====== =====+
+
+ FIG. 56.--ELECTROMAGNETS OF RELAY, AND THEIR EFFECTS.
+
+Take from an ordinary relay a coil, with its iron core, half the
+electromagnet, so to speak, without any yoke or armature. Connect it
+up as described, and observe the throw given to the galvanometer. The
+amount of throw obtained from the single coil was taken as unity, and
+all others were compared with it. If you join up two such coils as
+they are usually joined, in series, but without any iron yoke across
+the cores, the throw was 17. Putting the iron yoke across the cores,
+to constitute a horseshoe form, 496 was the throw; that is to say, the
+tendency of this electromagnet to retard the current was 496 times as
+great as that of the simple coil. But when an armature was put over
+the top, the effect ran up to 2,238. By the mere device of putting the
+coils in parallel, instead of in series, the 2,238 came down to 502, a
+little less than the quarter value which would have been expected.
+Lastly, when the armature and yoke were both of them split in the
+middle, as is done in fact in all the standard patterns of the British
+postal telegraph relays, the throw of the galvanometer was brought
+down from 502 to 26. Relays so constructed will work excessively
+rapidly. Mr. Preece states that with the old pattern of relay having
+so much self-induction as to give a galvanometer throw of 1,688, the
+speed of signaling was only from 50 to 60 words per minute, whereas,
+with the standard relays constructed on the new plan, the speed of
+signaling is from 400 to 450 words per minute. It is a very
+interesting and beautiful result to arrive at from the experimental
+study of these magnetic circuits.
+
+
+SHORT CORES _versus_ LONG CORES.
+
+In considering the forms that are best for rapid action, it ought to
+be mentioned that the effects of hysteresis in retarding changes in
+the magnetization of iron cores are much more noticeable in the case
+of nearly closed magnetic circuits than in short pieces.
+Electromagnets with iron armatures in contact across their poles will
+retain, after the current has been cut off, a very large part of their
+magnetism, even if the cores be of the softest of iron. But so soon as
+the armature is wrenched off, the magnetism disappears. An air gap in
+a magnetic circuit always tends to hasten demagnetizing. A magnetic
+circuit composed of a long air path and a short iron path demagnetizes
+itself much more rapidly than one composed of a short air path and a
+long iron path. In long pieces of iron the mutual action of the
+various parts tends to keep in them any magnetization that they may
+possess; hence they are less readily demagnetized. In short pieces,
+where these mutual actions are feeble or almost absent, the
+magnetization is less stable, and disappears almost instantly on the
+cessation of the magnetizing force. Short bits and small spheres of
+iron have no magnetic memory. Hence the cause of the commonly received
+opinion among telegraph engineers that for rapid work electromagnets
+must have short cores. As we have seen, the only reason for employing
+long cores is to afford the requisite length for winding the wire
+which is necessary for carrying the needful circulation of current to
+force the magnetism across the air gaps. If, for the sake of rapidity
+of action, length has to be sacrificed, then the coils must be heaped
+up more thickly on the short cores. The electromagnets in American
+patterns of telegraphic apparatus usually have shorter cores, and a
+relatively greater thickness of winding upon them, than those of
+European patterns.
+
+ * * * * *
+
+
+
+
+ELECTRIC ERYGMASCOPE.
+
+
+The erygmascope is the name of an electric lighting apparatus designed
+for the examination of the strata of earth traversed by boring
+apparatus.
+
+It consists of a very powerful incandescent lamp inclosed in a
+metallic cylinder. One of the two semi-cylindrical sides constitutes
+the reflector, and the other, which is of thick glass, allows of the
+passage of the luminous rays, which thus illuminate with great
+brilliancy the strata of earth traversed by the instrument. The base,
+which is inclined at an angle of 45 deg., is an elliptical mirror, and the
+top, of straight section, is open in order to permit the observer
+standing at the mouth of the well, and provided with a powerful
+spyglass, to see in the mirror the image of the earth. The lamp is so
+mounted that its upwardly emitted rays are intercepted.
+
+The whole apparatus is suspended from a long cable, formed of two
+conducting wires, which winds around a windlass with metallic
+journals which are electrically insulated. These journals communicate,
+through the intermedium of two friction springs, with the conductors
+on the one hand and, on the other, with the poles of an automatic and
+portable battery.
+
+[Illustration: THE TROUVE ERYGMASCOPE.]
+
+This permits of lowering and raising the apparatus at will, without
+derangement, and without its being necessary to interrupt the light
+and the observation.--_Revue Industrielle._
+
+ * * * * *
+
+
+
+
+A NEW ELECTRIC BALLISTIC TARGET.
+
+
+The electrical target usually employed in determining velocities of
+projectiles consists of a wooden frame on which is strung a copper
+wire so as to make a continuous circuit arranged in parallel vertical
+lines about one inch or one and one half inches apart.
+
+It frequently happens that a projectile will pass through this target
+without breaking the circuit, either by squeezing between the wires or
+because, when last repaired, the target was short-circuited unnoticed,
+so that the cutting of the wires did not break the circuit. The repair
+of this target takes considerable time.
+
+ _______________________________________________________
+ | {
+ | +-------------__ --------------__---------------- }
+ | | _ // \\ // \\ } {
+ | | |_| || C_{0} || A || || || A { }
+ | | P \\ // \\ // } {
+ | +------------- --------------- ---------------- }
+ | F {
+ |_______________________________________________________}
+
+ Plan.
+ P C
+ =|= _________
+ |===| ========= A A
+ ========| | S |========\_______/=================
+ |spring | | |
+ | | | | |
+ |S_ | __| |__ __|
+ ||| | |
+ ___________|||______________| |_____________________
+ |
+ | Section.
+ H /
+ \+/
+ |
+ |
+ |
+ |
+ |
+ |
+ _____+_____
+ | |
+ | W |
+ | |
+ |___________|
+
+
+Besides these objections to this target, another and more serious one
+is the irregularity in the manner of breaking the circuit. It has been
+proved that times required for a flat headed and an ogival headed
+projectile to rupture the current are very different.
+
+To remedy these defects a new and very ingenious target has been
+devised and used with great success at the United States Military
+Academy at West Point. The top of the target is a wooden strip, F, on
+the upper side of which are screwed strips of copper, A A, about 1/2
+in. wide, and 1/8 in. thick. The connection between two adjoining
+strips is made by a copper cartridge, C, which is dropped in a hole in
+the frame bored to receive it. This cartridge is the one used in the
+Springfield rifle. Inside the cartridge is a spiral spring, S, which,
+acting on the bottom of the hole and the head of the cartridge, tends
+to make the latter spring up, and so break the circuit.
+
+To the hook, H, which is attached to the cartridge, is suspended, by
+means of a string, the lead weight, W, thus drawing down the cartridge
+and making the circuit between A and A'. All the weights being
+suspended the current comes in through the post, P, passes along the
+copper strips and out of the corresponding post on the other end.
+
+On firing the projectile cuts a string, and the spring at once causes
+the cartridge to spring up, thus breaking the circuit.
+
+It is not possible for the projectile to squeeze between the strings
+and not break the current, for in so doing the cartridge is tipped
+slightly, which is sufficient, as it breaks the current on one side.
+
+This target is used in connection with the Boulenge chronograph. Two
+targets are established at a known distance apart, say 50 ft., and the
+time required for the projectile to pass over this distance is
+determined by finding the difference in the time of cutting of the two
+targets, by finding the difference in the time of falling of the two
+rods, caused by the demagnetization of two electromagnets in the same
+circuit with the targets.
+
+By means of a disjunctor both rods are dropped at the same time, the
+shorter one releasing a knife blade which makes a cut on the longer
+one. Now both rods are hung from the magnets again and the gun is
+fired.
+
+The projectile passes through the first target, breaks the circuit,
+demagnetizes the magnet of the longer rod, and it begins to fall. On
+passing through the second target, the projectile causes the shorter
+rod to fall. This releases the knife blade, and a second cut is made.
+The time corresponding to the distance between these cuts is the time
+the longer rod was falling before the second rod began to fall or the
+time between the cutting of the two targets by the projectile.
+
+The distance between the cuts is measured, and the time corresponding
+to it can easily be found. Then the velocity of the projectile is
+equal to 50/t.
+
+To repair this target, strings are prepared in advance of suitable
+length and looped at both ends, so that by placing the hook of the
+cartridge in one loop and that of the weight in the other the repair
+is quickly made.
+
+This target has been used on the West Point proving ground to
+determine velocities over distances of 100 ft. interval to distances
+of only 9 ft. interval, and has given most satisfactory results.
+
+ * * * * *
+
+[Continued from SUPPLEMENT, No. 786, page 12566.]
+
+
+
+
+THE OUTLOOK FOR APPLIED ENTOMOLOGY.
+
+[Footnote: Address of Dr. C.V. Riley at the annual meeting of the
+Association of Economic Entomologists, Champaign, Ills., November 11
+to 14, 1890.]
+
+LEGISLATION.
+
+
+The amount of legislation in different countries that has of late
+years been deemed necessary or sufficiently important, in view of
+injurious insects, is a striking evidence of the increased attention
+paid to applied entomology; and while modern legislation of this kind
+has been, on the whole, far more intelligent than similar efforts in
+years gone by, many of the laws passed have nevertheless been unwise,
+futile, and impracticable, and even unnecessarily oppressive to other
+interests. The chief danger here is the intervention of politics or
+political methods. Expert counsel should guide our legislators and the
+steps taken should be thorough in order to be effective. We have had
+of late years in Germany very good evidence of the excellent results
+flowing from thorough methods, and the recent legislation in
+Massachusetts against the gypsy moth (_Ocneria dispar_), which at one
+time threatened to become farcical, has, fortunately, proved more than
+usually successful; the commission appointed to deal with the subject
+having worked with energy and followed competent advice.
+
+
+PUBLICATION.
+
+On the question of publication of the results of our labors it is
+perhaps premature to dwell at length. Each of the experiment stations
+is publishing its own bulletins and reports quite independently of the
+others, but after a uniform plan recommended by the association with
+which we meet here; and with but one exception that has come to my
+notice, another important recommendation of the same association--that
+these publications shall be void of all personal matter--has been kept
+in mind. The National Bureau of Experiment Stations at Washington is
+doing what it can with the means at command to further the general
+work by issuing the Experiment Station Record, devoted chiefly to
+digests of the State station bulletins. There is a serious question in
+my mind as to the utility of State digests by the national department
+of results already published extensively by the different States and
+distributed under government frank to all similar institutions and to
+whomsoever is interested enough to ask for them.
+
+Such digests may or may not be intelligently made, and, even under the
+most favorable circumstances, will hardly serve any other purpose than
+helping to the reference to the original articles, and this could
+undoubtedly be done more satisfactorily to the stations and to the
+people at large by general and classified indices to all the State
+documents, made as full as possible and issued at stated intervals.
+Only a small proportion of the bulletins have been so far noticed by
+digest in this record, with no particular rule, so far as I can see,
+in the selection. In point of fact, those will be most apt to be
+noticed whose authors can find time to themselves send or make for the
+purpose their own abstracts. This is, perhaps, inevitable under
+present arrangements. Complete and satisfactory digests of all, if
+intelligent and critical, imply a far greater force than is at present
+at Prof. Atwater's command.
+
+Under these circumstances, it would seem wiser to devote all the
+energies of the bureau to digests of the similar literature of other
+countries, which would be of immense advantage to our people and to
+the different station workers. Judging from the recommendations and
+resolutions of the general association, this is the view very
+generally held, but except in chemistry and special industries like
+that of beet sugar, very little of that kind of work has yet been
+attempted.
+
+What is true of the station publications in general is equally true of
+special publications. As entomologist of the department, I have been
+urged to bring together, at stated intervals, digests of the
+entomological publications of the different stations. Such digests to
+be of any value, however, should also be critical, and it were a
+thankless task for any one to be critic or censor even of that which
+needs correction or criticism. Moreover, to do this work intelligently
+would require increase of the divisional force, which at present is
+more advantageously employed, for, as already intimated, I should have
+great doubts of the utility of these digests.
+
+I believe, however, that the division should strive for such increase
+of means as would justify the periodic publication, either
+independently or as a part of the department record, of general and
+classified indices to the entomological matter of the station
+bulletins, and should work more and more toward giving results from
+other parts of the world. This could, perhaps, best be done by titles
+of subject and of author so spaced and printed on stout paper that
+they could be cut and used in the ordinary card catalogue. The
+recipient could cut and systematically place the titles as fast as
+received.
+
+As to the character of the matter of the entomological bulletins, it
+will inevitably be influenced by the needs and demands of the people
+of the respective States, and while originality should be kept in
+mind, there must needs be in the earlier years of the work much
+restatement of what is already well known. That some results have been
+published of work which reflects no particular credit upon our calling
+is a mere incident of the new positions created. Yet we may expect
+marked improvement from year to year in this direction, and without
+being invidious, I would cite those of Prof. Gillette's on his
+spraying experiments and on the plum curculio and plum gouger, as
+models of what such bulletins should be.
+
+Although the resolution offered at our last meeting by Prof. Cook, to
+the effect that purely descriptive matter should be excluded from the
+station bulletins, met with no favor, but was laid on the table, by
+the general association, I am in full sympathy with this position and
+am strongly of the opinion that in the ordinary bulletins such purely
+technical and descriptive matter should be reduced to the necessary
+minimum consistent with clearness of statement and accuracy, and that
+if it is desired, on the part of the station entomologists, to issue
+technical and descriptive papers, a separate series of bulletins were
+better instituted for this class of matter.
+
+Finally, for results which it is desired to promptly get before the
+people, the agricultural press is at our disposal, and so far as the
+entomological work of the department of agriculture is concerned, the
+periodical bulletin, _Insect Life_, was established for this purpose.
+Its columns are open to all station workers, and I would here appeal
+to the members of the association to help make it, as far as possible,
+national, by sending brief notes and digests of their work as it
+progresses. Hitherto we have been unable to make as much effort in
+this direction as we desired, but in future it is our hope to make the
+bulletin, as far as possible, a national medium through which the
+results of work done in all parts of the country may quickly be put on
+record and distributed, not only to all parts of our own country, but
+to all parts of the world.
+
+The rapid growth and development of the national department and the
+multiplication of its divisions have necessitated special modes of
+publication and rendered the annual report almost an anachronism so
+far as it pretends to be what it at one time was--a pretty complete
+report of the scientific and other work of the department. The
+attempts which I have made through the proper authorities to get
+Congress to order more pretentious monographic works in quarto volume
+similar to those issued by other departments of the government have
+not met with encouragement, and in this direction many of the stations
+will, let us hope, be able to do better.
+
+
+CO-OPERATION.
+
+Every other subject that might be considered on this occasion must be
+subordinate to the one great question of co-operation. With the large
+increase of actual workers in our favorite field, distributed all over
+the country, the necessity for some co-operation and co-ordination
+must be apparent to every one. Just how this should be brought about
+or in what direction we may work toward it, will be for this
+association in its deliberations to decide. Nor will I venture to
+anticipate the deliberations and conclusions of the special committee
+appointed to take the matter into consideration, beyond the statement
+that there are many directions in which we can adopt plans for mutual
+benefit. Take, for instance, the introduction and dissemination of
+parasites. How much greater will be the chance of success in any
+particular case if we have all the different station entomologists
+interested in some specific plan to be carried out in co-operation
+with the national department, which ought to have better facilities of
+introducing specimens to foreign countries or to different sections of
+our own country than any of the State stations.
+
+Let us suppose that the fruit growers of one section of the country,
+comprising several States in area, need the benefit in their warfare
+against any particularly injurious insect of such natural enemy or
+enemies as are known to help the fruit growers of some other section.
+There will certainly be much greater chances of success in the
+carrying out of any scheme of introduction if all the workers in the
+one section may be called upon through some central or national body
+to help in the introduction and disposition of the desired material
+into the other section. Or, take the case of the boll worm
+investigation already alluded to. The chances of success would be much
+greater if the entomologists in all the States interested were to give
+some attention to such lepidopterous larvae as are found to be affected
+with contagious diseases and to follow out some specific plan of
+cultivating and transmitting them to the party or parties with whom
+the actual trials are intrusted. The argument applies with still
+greater force to any international efforts. I need hardly multiply
+instances. There is, it is true, nothing to prevent any individual
+station entomologist from requesting co-operation of the other
+stations, nor is there anything to prevent the national department
+from doing likewise; but in all organization results are more apt to
+flow from the power to direct rather than from mere liberty to request
+or to plead. The station entomologist may be engrossed in some line of
+research which he deems of more importance to the people of his State,
+and may resent being called upon to divert his energies; and with no
+central or national power to decide upon plans of co-operation for the
+common weal, we are left to voluntary methods, mutually devised, and
+it is here that this association can, it seems to me, most fully
+justify its organization. And this brings me to the question of
+
+
+THE DEPARTMENT AND THE STATIONS.
+
+Immediately connected with the question of co-operation is the
+relation of the National Department of Agriculture and the State
+experiment stations. The relation, instead of being vital and
+authoritative, is, in reality, a subordinate one. Many persons
+interested in the advancement of agriculture foresaw the advantage of
+having experiment stations attached to the State agricultural colleges
+founded under the Morrill act of 1862; but I think that in the minds
+of most persons the establishment of these stations implied some such
+connection with the national department as that outlined in an address
+on Agricultural Advancement in the United States, which I had the
+honor to deliver in 1879 before the National Agricultural Congress, at
+Rochester, and in which the following language was used:
+
+ "In the light of the past history of the German experimental
+ stations and their work, or of that in our own State of
+ Connecticut, the expediency of purchasing an experimental farm of
+ large dimensions in the vicinity of Washington is very
+ questionable. There can be no doubt, however, of the value of a
+ good experimental station there that shall have its branches in
+ every State of the Union. The results to flow from such stations
+ will not depend upon the number of acres at command, and it will
+ be far wiser and more economical for the commissioner to make each
+ agricultural college that accepted the government endowment
+ auxiliary to the national bureau, so that the experimental farm
+ that is now, or should be, connected with each of these
+ institutions might be at its service and under the general
+ management of the superintendent of the main station. There is
+ reason to believe that the directors of these colleges would
+ cheerfully have them constituted as experimental stations under
+ the direction of the department, and thus help to make it really
+ national--the head of a vast system that should ramify through all
+ parts of the land....
+
+ "With the different State agricultural colleges, and the State
+ agricultural societies, or boards, we have every advantage for
+ building up a national bureau of agriculture worthy of the country
+ and its vast productive interests, and on a thoroughly economical
+ basis, such as that of Prussia, for instance."
+
+In short, the view in mind was something in the nature of that which
+has since been adopted by our neighbors of the North, where there is a
+central or national station or farm at Ottawa and sub-stations or
+branch farms at Nappan, Nova Scotia, Brandon, Manitoba, Indian Head,
+N.W.T., and Agassiz, British Columbia, all under the able direction of
+Mr. William Saunders, one of our esteemed fellow workers. It was my
+privilege to be a good deal with Mr. Saunders when he was in Europe
+studying the experience of other countries in this matter, and the
+policy finally adopted in Canada as a result of his labors is an
+eminently wise one, preventing some of the difficulties and dangers
+which beset our plan, whether as between State and nation or college
+and station.
+
+Under the present laws and with the vast influence which the
+Association of Agricultural Colleges and Experiment Stations will
+wield, both in Congress and in the different States, there is great
+danger of transposition, in this agricultural body politic, of those
+parts which in the animal body are denominated head and tail, and the
+old saw to the effect that "the dog wags the tail because the tail
+cannot wag the dog," will find another application. So far as the law
+goes, the national department, which should hold a truly national
+position toward State agricultural institutions depending on federal
+support, can do little except by suggestion, whether in the line of
+directing plans or in any way co-ordinating or controlling the work of
+the different stations throughout the country. The men who influenced
+and shaped the legislation which resulted in the Hatch bill were
+careful that the department's function should be to indicate, not to
+dictate; to advise and assist, not to govern or regulate. We have,
+therefore, to depend on such relationships and such plans of
+co-operation as will appear advantageous to all concerned, and these
+can best be brought about through such associations as are now in
+convention here.
+
+Without such plans there is great danger of such waste of energy and
+means and duplication of results as will bring the work into popular
+disfavor and invite disintegration, for already there is a growing
+feeling that agricultural experiment is and will be subordinated to
+the ordinary college work in the disposition of the federal
+appropriations.
+
+What is true of the national department as a whole in its connection
+with the State stations is true in a greater or less degree of the
+different divisions of the department in connection with the different
+specialists of the stations. With the multiplicity of workers in any
+given direction in the different States, the necessity for national
+work lessens. A favorite scheme of mine in the past, for instance (and
+one I am glad to say fully indorsed by Prof. Willits), was to endeavor
+to have a permanent agent located in every section of the country that
+was sufficiently distinctive in its agricultural resources and
+climate, or, as a yet further elaboration of the same plan, one in
+each of the more important agricultural States. The necessity for such
+State agents has been lessened, if not obviated, by the Hatch bill,
+and the subsequent modifications looking to permanent appropriations
+to the State stations or colleges, which give no central power at
+Washington. The question then arises, What function shall the national
+department perform? Its influence and field for usefulness have been
+lessened rather than augmented in the lines of actual investigation in
+very many directions. Many a State is already far better equipped both
+as to valuable surrounding land, laboratory and library facilities,
+more liberal salaries, and greater freedom from red tape,
+administrative routine, and restrictions as to expenditures, than we
+are at Washington; and, except as a directing agent and a useful
+servant, I cannot see where the future growth of the department's
+influence is to be outside of those federal functions which are
+executive. Just what that directing influence is to be is the question
+of the hour, not only in the broader but in the special sense. The
+same question, in a narrower sense, had arisen in the case of the few
+States which employed State entomologists. In the event, for instance,
+of an outbreak of some injurious insect, or in the event of any
+particular economic entomological question within the limits of the
+State having such an officer, the United States entomologist would
+naturally feel that any effort on his part would be unnecessary, or
+might even be looked upon as an interference. He would feel that there
+was always danger of mere duplication of observation or experiment,
+except where appealed to for aid or co-operation. This is, perhaps,
+true only of insects which are local or sectional, and is rather a
+narrow view of the matter, but it is one brought home from experience,
+and is certainly to be considered in our future plans. The favor with
+which the museum work of the national division was viewed by you at
+the meeting last November and the amount of material sent on for
+determination would indicate that the building up of a grand national
+reference collection will be most useful to the station workers. But
+to do this satisfactorily we need your co-operation, and I appeal to
+all entomologists to aid in this effort by sending duplicates of their
+types to Washington, and thus more fully insuring against ultimate
+loss thereof.
+
+
+STATUS OF OUR SOCIETY.
+
+This train of thought brings up the question of the status of our
+society with the station entomologists as represented by the committee
+of the general association. Those of us who had desired a national
+association for the various purposes for which such associations are
+formed, felt, I believe, if I may speak for them, that the creation of
+the different experimental stations rendered such an organization
+feasible. Your organization at Toronto and the constitution adopted
+and amended at the meeting at Washington all indicate that the chief
+object was the advancement of our chosen work and that the strength of
+the association would come from the experiment station entomologists.
+There was then no other organization of the kind, nor any intimation
+that such a one would be founded. Some of us therefore were surprised
+to learn from the circular sent out by Prof. Forbes, its chairman,
+that the committee appointed by the association of agricultural
+colleges and experiment stations, and through which we had hoped to
+communicate and co-operate with that association, was not in the
+proper sense a committee, but a section which has prepared (and in
+fact was required by the executive committee and the rules of the
+superior body to prepare) a programme of papers and discussions for
+the meeting to be held at the same time and place with our own. I
+cannot but feel that this is in some respects a misfortune, and it
+will devolve upon you to decide upon several questions of importance
+that will materially affect our future existence. That there is not
+room for two national organizations having the same objects in view
+and meeting at the same time and place goes, I think, without saying;
+and if the committee of the general association is to be anything more
+than a committee in the proper sense of the word, or if it is to
+assume with or without formal constitution the functions of our own
+association, then our own must necessarily be crippled, and to do any
+good at all must meet at a different time and a different place. A
+committee or section, or whatever it may be called, of the general
+association with which we meet, would preclude active membership of
+any but those who come within the constitution of that body. Our
+Canadian friends and many others who have identified themselves with
+applied entomology, and do not belong to any of our State or
+government institutions, would be debarred from active representation,
+however liberal the association may have been in inviting such to
+participate, without power to vote in its deliberations. Our own
+association has, or should have, no such limitations. Some of us who
+are entitled to membership in both bodies may feel indifferent as to
+the course finally decided upon, and that it will not make any
+difference whether we have an outside and independent organization, as
+that of the association of official chemists, or whether we do, as did
+the botanists and horticulturists, waive independence in favor of more
+direct connection with the general association, provided there is some
+way whereby the committees of the general association are given
+sufficient latitude and time to properly present their papers and
+deliberate; but there are others who feel more sensitive as to their
+action and are more immediately influenced by the feelings of the main
+body. I hope that whatever action be taken at this meeting, the
+general good and the promotion of economic entomology will be kept in
+mind and that no sectional or personal feeling will be allowed to
+influence our deliberations.
+
+
+SUGGESTION AND COMMENT.
+
+You will, I know, pardon me if, before concluding these remarks, I
+venture to make a few comments which, though not altogether agreeable,
+are made in all sincerity and in the hope of doing good. The question
+as to how far purely technical and especially descriptive and
+monographic work should be done by the different stations or by the
+national department is one which I have already alluded to and upon
+which we shall probably hold differing opinions, and which will be
+settled according to the views of the authorities at the different
+stations. Individually, I have ever felt that one ostensibly engaged
+in applied entomology and paid by the State or national government to
+the end that he may benefit the agricultural community can be true to
+his trust only by largely overcoming the pleasure of entomological
+work having no practical bearing. I would, therefore, draw the line at
+descriptive work except where it is incidental to the economic work
+and for the purpose of giving accuracy to the popular and economic
+statements. This would make our work essentially biological, for all
+biologic investigation would be justified, not only because the life
+habits of any insect, once ascertained, throw light on those of
+species which are closely related to it, but because we can never know
+when a species at present harmless may subsequently prove harmful, and
+have to be classed among the species injurious to agriculture.
+
+On the question of credit to their original sources of results already
+on record, it is hardly necessary for me to advise, because good sense
+and the consensus of opinion will in the end justify or condemn a
+writer according as he prove just and conscientious in this regard.
+
+There is one principle that should guide every careful writer, viz.,
+that in any publications whatever, where facts or opinions are put
+forth, it should always be made clear as to which are based upon the
+author's personal experience and which are compiled or stated upon the
+authority of others. We should have no patience with a very common
+tendency to set forth facts, even those relating to the most common
+and best known species, without the indications to which I have
+referred. The tendency belittles our calling and is generally
+misleading and confusing, especially for bibliographic work, and
+cannot be too strongly deprecated.
+
+On this point there will hardly be any difference of opinion, but I
+will allude to another question of credit upon which there prevails a
+good deal of loose opinion and custom. It is the habit of using
+illustrations of other authors without any indication of their
+original source.
+
+This is an equally vicious custom and one to be condemned, though I
+know that some have fallen into the habit, without appreciation of its
+evil effect. It is, in my judgment, almost as blameworthy as to use
+the language or the facts of another without citing the authority.
+
+Every member of this association who has due appreciation of the time
+and labor and special knowledge required to produce a good and true
+illustration of the transformations and chief characteristics of an
+insect will appreciate this criticism. However pardonable in fugitive
+newspaper articles in respect of cuts which, from repeated use, have
+become common or which have no individuality, the habit inevitably
+gives a certain spurious character to more serious and official
+publications, for assumption of originality, whether intended or not,
+goes with uncredited matter whether of text or figure. Nor is mere
+acknowledgment of loan or purchase to the publisher, institution or
+individual who may own the block or stone what I refer to. But that
+acknowledgment to the author of the figure or the work in which it
+first appears which is part of conscientious writing, and often a
+valuable index as to the reliability of the figure.
+
+It were supererogation to point out to a body of this kind the value
+of the most careful and thorough work in connection with life
+histories and habits, often involving as it does much microscopic
+study of structure. The officers of our institutions who control the
+funds, and more or less fully our conduct, are apt to be somewhat
+impatient and inappreciative of the time given to anatomic work, and
+where it is given for the purpose of describing species and of
+synopsizing or monographing higher groups, without reference to
+agriculture, I am firmly of the belief that it diverts one from
+economic work, but where pursued for a definite economic purpose it
+cannot be too careful or too thorough and I know of no instances
+better calculated to appeal to and modify the views of those inclined
+to belittle such structural study than Phylloxera and Icerya. On the
+careful comparison of the European and American specimens of
+_Phylloxera vastatrix_, involving the most minute structures and
+details, depended originally those important economic questions which
+have resulted in legislation by many different nations and the
+regeneration of the affected vineyards of Europe, of our own Pacific
+coast, and of other parts of the world by the use of American
+resistant stocks. In the case of _Icerya purchasi_ the possibilities
+of success in checking it by its natural enemies hung at one time upon
+a question of specific difference between it and the _Icerya sacchari_
+of Signoret--a question of minute structure which the descriptions
+left unsettled and which could only be settled by the most careful
+structural study and the comparison of the types, involving a trip to
+Europe.
+
+
+CONCLUSION.
+
+I have thus touched, gentlemen, upon a few of the many subjects that
+crowd upon the mind for consideration on an occasion like this--a few
+gleanings from a field which is passing rich in promise and
+possibility. It is a field that some of us have cultivated for many
+years and yet have only scratched the surface, and if I have ventured
+to suggest or admonish, it is with the feeling that my own labors in
+this field are ere long about to end and that I may not have another
+occasion.
+
+At no time in the history of the world has there, I trow, been
+gathered together such a body of devoted and capable workers in
+applied entomology. It marks an era in our calling and, looking back
+at the progress of the past fifteen years, we may well ponder the
+possibilities of the next fifteen. They will be fruitful of grand
+results in proportion as we persistently and combinedly pursue the yet
+unsolved problems and are not tempted to the immediate presentation of
+separate facts, which are so innumerable and so easily observed that
+their very wealth becomes an element of weakness. Epoch-making
+discoveries result only from this power of following up unswervingly
+any given problem, or any fixed ideal. The kerosene emulsion, the
+Cyclone nozzle, the history of _Phylloxera vastatrix_, of _Phorodon
+humuli_, of _Vedalia cardinalis_, are illustrations in point, and
+while we may not expect frequent results as striking or of as wide
+application as these, there is no end of important problems yet to be
+solved and from the solution of which we may look for similar
+beneficial results. Applied entomology is often considered a sordid
+pursuit, but it only becomes so when the object is sordid. When
+pursued with unselfish enthusiasm born of the love of investigation
+and the delight in benefiting our fellow men, it is inspiring, and
+there are few pursuits more deservedly so, considering the vast losses
+to our farmers from insect injury and the pressing need that the
+distressed husbandman has for every aid that can be given him. Our
+work is elevating in its sympathies for the struggles and suffering of
+others. Our standard should be high--the pursuit of knowledge for the
+advancement of agriculture. No official entomologist should lower it
+by sordid aims.
+
+During the recent political campaign the farmer must have been sorely
+puzzled to know whether his interests needed protection or not. On the
+abstract question of tariff protection to his products we, as
+entomologists, may no more agree than do the politicians or than does
+the farmer himself. But ours is a case of protection from injurious
+insects, and upon that there can nowhere be division of opinion. It is
+our duty to see that he gets it with as little tax for the means as
+possible.
+
+ * * * * *
+
+
+
+
+POTASH SALTS.
+
+[Footnote: By John B. Smith, entomologist. Potash as an insecticide is
+not entirely new, but has never been brought out with the prominence I
+think it deserves.--_N.J. Ag. Col. Exp. St., Bulletin 75._]
+
+
+My attention was attracted to potash salts as an insecticide, by the
+casual remark of an intelligent farmer, that washing his young pear
+trees with a muriate of potash solution cleared them of scales. The
+value of this substance for insecticide purposes, should its powers be
+sufficient, struck me at once, and I began investigation. It was
+unluckily too late in the season for field experiments of the nature
+desired; but it is the uniform testimony of farmers who have used
+either the muriate or the kainit in the cornfields, that they have
+there no trouble with grubs or cut worms. Mr. E.B. Voorhees, the
+senior chemist of the station, assures me that on his father's farm
+the fields were badly infested, and replanting cornhills killed by
+grubs or wire worms was a recognized part of the programme. Since
+using the potash salts, however, they have had absolutely no trouble,
+and even their previously worst-infested fields show no further trace
+of injury. The same testimony comes from others, and I feel safe in
+recommending these salts, preferably kainit, to those who are troubled
+with cut worms or wire worms in corn.
+
+
+EXPERIMENTS.
+
+A lot of wire worms (_Iulus_ sp.) brought in from potato hills were
+put into a tin can with about three inches of soil and some potato
+cuttings, and the soil was thoroughly moistened with kainit, one ounce
+to one pint of water. Next morning all the specimens were dead. A
+check lot in another can, moistened with water only, were healthy and
+lived for some days afterward.
+
+A number of cabbage maggots placed on the soil impregnated with the
+solution died within twelve hours.
+
+To test its actual killing power, used the solution, one ounce kainit
+to one pint water, to spray a rose bush badly infested with plant
+lice. Effect, all the lice dead ten hours later; the younger forms
+were dropping within an hour.
+
+Sprayed several heads of wheat with the solution, and within three
+hours all the aphides infesting them were dead.
+
+Some experiments on hairy caterpillars resulted unsatisfactorily, the
+hair serving as a perfect protection against the spray, even from the
+atomizer.
+
+To test its effect on the foliage, sprayed some tender shoots of rose
+and grape leaves, blossoms, and clusters of young fruit. No bad effect
+observable 24 hours later. There was on some of the leaves a fine
+glaze of salt crystals, and a decided salt taste was manifest on all.
+
+Muriate of potash of the same strength was tested as follows: Sprayed
+on some greenhouse camellias badly infested by mealy bugs, it killed
+nearly all within three hours, and six hours later not a living insect
+was found. The plants were entirely uninjured by the application.
+
+Thoroughly sprayed some rose bushes badly infested with aphides, and
+carried off some of the worst branches. On these the lice were dead
+next morning; but on the bushes the effect was not so satisfactory,
+most of the winged forms and many mature wingless specimens were
+unaffected, while the terminal shoots and very young leaves were
+drooping as though frosted. All, however, recovered later.
+
+The same experiment repeated on other, hardier roses, resulted
+similarly so far as the effect on the aphides was concerned, but there
+was no injury to the plant.
+
+Used this same mixture on the caterpillars of _Orgyia leucostigma_
+with unsatisfactory effect, and with the same results used it on a
+number of other larvae. Used on the rose leaf roller, _Cacaecia
+rosaceana_, it was promptly effective.
+
+Tested for injury to plants, it injured the foliage and flowers of
+wisteria, the younger leaves of maple and grape, and the finer kinds
+of roses.
+
+From these few experiments kainit seems preferable to the muriate, as
+acting more effectively on insects and not injuriously on plants. For
+general use on plants it is not to be recommended. It is otherwise on
+underground species, where the soil will be penetrated by the salts
+and where the moisture evaporates but slowly, and the salt has a
+longer and better chance to act. The best method of application would
+be a broadcasting in fertilizing quantity before or during a rain, so
+as to carry the material into the soil at once. In cornfields infested
+with grubs or wire worms, the application should be made before
+planting. Where it is to be used to reach root lice, it should be used
+when the injury is beginning. When strawberry beds are infested by the
+white grub, the application should be made when cultivating or before
+setting out.
+
+The potash salts have a high value as fertilizers, and any application
+made will act as a stimulant as well as insecticide, thus enabling the
+plants to overcome the insect injury as well as destroying the insect.
+
+In speaking on this subject in Salem county, I learned from farmers
+present that those using potash were not troubled with the corn root
+louse to any extent, and also that young peach trees have been
+successfully grown in old lice-infested orchards, where previously all
+died, by first treating the soil with kainit of potash.
+
+ * * * * *
+
+
+A meteorological station has been built on Mont Blanc, at an elevation
+of 13,300 feet, under the direction of M. Vallot. It required six
+weeks to deliver the materials. The instruments are self-registering
+and are to be visited in summer every fifteen days if possible, the
+instruments being left to register between the visits. In the winter
+the observatory will be entirely inaccessible. This is the highest
+scientific station in Europe, but is 847 feet lower than the Pike's
+Peak station in Colorado.
+
+ * * * * *
+
+
+
+
+THE EXPENSE MARGIN IN LIFE INSURANCE.
+
+
+The principle of mutuality requires that the burden of expense in life
+insurance should be borne by all the members equally; but, even with
+the most careful adjustment, the allowance usually made is
+considerably in excess of what is needed in the regular companies
+doing business on the "level premium" plan.
+
+It is customary in these companies to add to the net premium a
+percentage thereof to cover the expense account. This practice, though
+in harmony with the "commission system," is so clearly defective and
+so far removed from the spirit of life insurance mathematics, that it
+scarcely deserves even this passing notice.
+
+It is generally understood that these corporations combine the
+functions of the savings bank and life insurance company, and it is
+only by separating the two in our minds as far as possible that we can
+obtain a clear conception of the laws that should govern the
+apportionment of the expenses among the great variety of policies.
+
+While it is a comparatively simple matter to state the amount of
+either the insurance or savings bank element in a single policy, it is
+by no means easy, as things go, to classify the company's actual
+expenses on this basis.
+
+Fortunately, we can pretty accurately determine what these amounts
+should be in any particular case.
+
+In the first place, there are institutions in our midst devoted solely
+to receiving and conserving small sums of money; doing, in fact,
+exactly what our insurance companies are undertaking to do with the
+reserve and contributions thereto. These savings banks are required by
+law to make returns to the State commissioner, from whose official
+report we can get a very good idea of the expense attendant on doing
+this business.
+
+Confining ourselves to the city banks, where the conditions more
+nearly resemble those of the insurance companies, we find in
+thirty-eight combined institutions for saving in the State of
+Massachusetts a deposit in 1888 of $192,174,566, taken care of at an
+aggregate cost of $455,387, or about 24-100 of one per cent.
+
+The same ratio carried out for all the savings banks in Massachusetts
+gives a trifle over 25-100 of one per cent.; we may, therefore,
+consider 1/4 of one per cent. as expressing pretty nearly the cost of
+receiving, paying out, and investing the savings of the people.
+
+We must remember in this connection that in the popular estimation,
+the savings bank is an important factor in the public welfare, and in
+the towns and smaller cities there are often found public spirited men
+willing to give their services to encourage this mode of saving; but
+public sentiment has not yet given to life insurance the place which
+it is destined, sooner or later, to occupy by the side of the savings
+bank. Hence the services of able managers can only be obtained by a
+liberal outlay of the corporate funds. A satisfactory adjustment of
+the matter of expenses will, perhaps, do more than anything else to
+bring about this recognition on the part of the public.
+
+In the case of the savings bank it is safe to say that for double the
+present outlay a liberal salary could be paid to all the officers.
+Following the analogy, we are led to infer that if this be the case in
+savings banks, then 1/2 of one per cent. of the reserve should be an
+ample allowance for the special labor required in the purely banking
+portion of the business.
+
+In this we have the concurrence of the late Elizur Wright. In an essay
+on this subject he says:
+
+ "The expenses of the five largest savings banks in Boston, in
+ 1869, did not exceed 4-10 of one per cent. on $28,000,000
+ deposited in them. They certainly had twice as many transactions,
+ in proportion to the deposits, as any life insurance company could
+ have with the same amount of reserve, so that 1/2 of one per cent.
+ on the reserve seems to be ample for all working expenses save
+ those of maintaining the agencies and collecting the premiums."
+
+This need hardly be looked upon as an admission that it costs twice as
+much to care for the funds of a life insurance company as for those of
+a savings bank. A liberal expense allowance must be made at the
+outset, seeing that an error in this particular cannot easily be
+rectified after the policy is issued. The dividend, or, to speak more
+correctly, the annual return of surplus, will correct any overpayment
+on this account.
+
+There is another expense which seems inevitable. This is the
+government tax on insurance companies, amounting in the aggregate to
+nearly 1/3 of one per cent. on the reserve.
+
+When we consider that these institutions are intended to encourage
+thrift and to relieve the community from the care of numberless widows
+and orphans, it seems a clear violation of the principles of political
+economy to levy a tax on this business; still, whatever our opinion
+may be as to the justice or injustice of the imposition, the tax is
+maintained and must be provided for. Consequently a further allowance
+of 1/2 of one per cent. must be added to the net premium to cover the
+same, making a total of 1 per cent. of the reserve for banking
+expenses and taxes. Considering this point as settled for the time
+being, let us proceed to investigate the insurance expenses.
+
+Here, again, we are fortunate in being able to refer to the official
+reports of a class of corporations doing nearly, if not quite pure
+insurance.
+
+The assessment societies, outside of the fraternal and benevolent,
+reporting in 1889 to the insurance commissioner of Massachusetts, show
+outstanding risks amounting to $733,515,366. Losses to the amount of
+$7,270,238 were paid during the year at a cost for transacting the
+business of $2,403,053, which includes among other items "agency
+expenses and commissions," which amount to about $1,203,000, or 17 per
+cent. of the cost value of the insurance actually done. It would seem
+as if an allowance of 20 per cent. would be a liberal one in the case
+of the regular companies, which surely have as good facilities for
+doing business as the assessment societies.
+
+As far as insurance is concerned, there is less difference between
+regular and co-operative companies than is generally supposed. Regular
+companies assess each policy in advance for a year's insurance at a
+time, while co-operative societies furnish insurance only from one
+assessment to another. The difficulty in the way of collecting the
+assessment in the latter case would seem to be greater than in the
+former, owing to the more permanent nature of the regular insurance
+contract.
+
+In compensating agents the assessment companies naturally pay in
+proportion to the insurance obtained, inasmuch as there is no other
+basis to go upon, but regular companies usually pay the agent a
+percentage of the premium _which includes a considerable trust fund_
+over and above the assessment for actual insurance. It is easily seen
+that by the last method the agent's compensation increases in
+proportion to the amount of savings bank business forced upon the
+company.
+
+To realize how far we are from anything like a scientific, not to say
+common sense basis for insurance expenses, we have but to examine the
+following list, which gives the ratios between the expenditures for
+general expenses in 1889, and those for the extension of the business.
+For every $100 used in a general way, the different companies spend
+for commissions and agency expenses: $37, $66, $67, $78, $91, $106,
+$110, $113, $120, $140, $157, $161, $173, $175, $186, $189, $200,
+$202, $222, $264, $311, $346.
+
+It will doubtless be said that I am taking a very advanced position
+when I say that in the ideal life insurance scheme there is no place
+for the commission system. Solicitors will be a necessity only so long
+as they are in the field, but fifty years of life insurance has taught
+our community its true value and, thanks to the modern press, the
+institution it is no more likely to fall into desuetude than is
+Christianity or the moral law.
+
+For the convenience of bringing the company to the individual, the
+latter should be willing to pay a fee. The man who renders another a
+service or puts his superior knowledge at another's disposal should
+look to the party benefited for his remuneration. Any compensation
+given for such service to a go-between by a mutual company is paid by
+all, and the question arises, Is the advantage to the company of
+sufficient importance to warrant the imposition of this tax upon all
+its members promiscuously? The following, from the Massachusetts
+Insurance Commissioner's Report for 1885, leaves no doubt as to the
+convictions of the writer on this important matter:
+
+ "The expensiveness of the life insurance policy is not because the
+ level net premium is too high, for the premium is absolutely just,
+ and the policy holder gets full value; but the complaint justly
+ applies to the excessive expense charge. A person who wants
+ insurance, life or fire or other, should be able to buy it at
+ first cost without paying tribute of profits to middlemen. To that
+ complexion the matter will finally be brought by the force of
+ intelligent opinion, whatever resistance may be opposed by persons
+ whose thrift lies in the perpetuation of the expensive system now
+ in fashion."
+
+It requires but a slight degree of prophetic vision to predict that in
+a very few years the companies in self defense will be obliged to
+change their method of compensating agents.
+
+Several companies have already begun the reform by grading
+commissions; granting a percentage proportional to the amount of
+insurance likely to be done on the policy. Other companies have simply
+reduced the amount of the commission rate, thus virtually withdrawing
+from active competition.
+
+This will, in a certain degree, explain the wide variation in the
+figures given above, where it is noticed that, in five companies out
+of twenty-two, the total agency expenditures amount to less than the
+general expenses, while in six cases the companies spend more than
+double as much on the former as on the latter. In either class we find
+representatives of the five largest companies in the country.
+
+On applying the foregoing ratios to the business of the existing
+companies we find that, calling the theoretical expenses $100, the
+actual expenditures for 1889 were as follows: $112.67, $118.34,
+$150.40, $194.48, $208.16, $208.53, $228.66, $235.89, $248.44,
+$250.79, $258.33, $258.57, $265.14, $267.19, $267.92, $274.47,
+$294.17, $314.96, $335.70, $377.94, $616.70.
+
+In this discouraging exhibit there is one ray of comfort. The combined
+assets of the two companies heading the list amount to over
+$100,000,000. There is no question as to their financial standing, and
+both show a large increase in membership over the previous year. I may
+also say here that it is a difficult matter to get at the actual "cost
+of insurance" in the various companies. Many of them, on their own
+acknowledgment, do not compute the advance cost of carrying their
+"amount at risk," and others, for reasons of their own, do not care to
+state the figures. In cases where the correct figures were not
+obtainable, I have assumed the cost to have been 1-1/3 per cent. of
+the mean amount at risk.
+
+If we should, in our comparison, omit the actual agency expenses and
+commissions, the ratios would stand as follows:
+
+Where I would allow $100 the companies actually used: $43.17, $55.90,
+$65.21, $77.21, $82.39, $88.34, $91.99. $91.98. $92.19, $94.65,
+$97.15. $99.55. $99.11. $102.86, $109.35, $125.05, $133.03, $141.92,
+$195.90, $207.06, $287.72.
+
+As might be supposed, the first two ratios are those companies before
+alluded to. These companies might have doubled their advertising
+account and expended $300,000 between them on agents' salaries, and
+still have kept within my allowance.
+
+Admitting, for the present at least, the reasonableness of the
+proposed allowance for the expenses of the banking and insurance
+departments of the business, we have before us the problem how to
+equitably adjust the burden among the great variety of policies.
+
+In the first place, _there should be no policy in the company that
+does not contribute its proportionate share of the expense allowance
+during every year of its life_. I make a special point of this, for at
+present the policies which have become paid up, either by the payment
+of a single premium at the outset or by the completion of a stipulated
+number of payments, contribute practically nothing to the expense
+account after the premium payments cease.
+
+The following plan, I think, complies with all the requirements of the
+problem. By the proposed method every policy, at all stages of its
+existence, contributes its exact share to the expense fund, whatever
+its plan of payment may be.
+
+Let us, as an illustration, examine the case of a ten year endowment
+policy, taken out at age 30, and consider it under three aspects,
+first, as paid for in advance by a single payment, second, as paid by
+five annual payments, and third, as paid for annually throughout the
+term. I have used this short term endowment policy simply for
+convenience, the rule applying equally to policies of longer term or
+to the ordinary life policy, which is, in fact, an endowment policy
+payable at death or age 100.[1]
+
+[Footnote 1: The expense allowance on a plain life policy for $1,000,
+taken at age 33, would be about $5.29; net premium (com. ex. 4 per
+cent.), $18.04; total office premium, $23.33; present rate $24.10.]
+
+Taking the case of the single premium endowment policy for $1,000, we
+find that the following sums are required, each year to provide for
+the care of the reserve and to pay the government fees (1 per cent. of
+reserve):
+
+ 1st year $6.9982 | 6th year $8.4136
+ 2d " 7.2560 | 7th " 8.7381
+ 3d " 7.5258 | 8th " 9.0781
+ 4th " 7.8082 | 9th " 9.4346
+ 5th " 8.1039 | 10th " 9.8086
+
+The insurance expenses should be covered by the 20 per cent. allowance
+given below:
+
+ 1st year $ .4422 | 6th year $ .2566
+ 2d " .4100 | 7th " .2076
+ 3d " .3762 | 8th " .1556
+ 4th " .3402 | 9th " .0988
+ 5th " .2996 | 10th " .0344
+
+Consequently the total contribution required from this policy each
+year is:
+
+ 1st year $7.4404 | 6th year $8.6702
+ 2d " 7.6660 | 7th " 8.9457
+ 3d " 7.9020 | 8th " 9.2337
+ 4th " 8.1484 | 9th " 9.5334
+ 5th " 8.4034 | 10th " 9.8430
+
+The present value of all these contributions is found to be, at 4 per
+cent. interest, $71.6394; in other words, this sum paid at the outset,
+provides a fund from which we may deduct the current expenses of each
+year in advance, and by accumulating the balance at the assumed rate
+of interest from year to year, we shall have enough to pay the
+anticipated expenses, leaving nothing over.
+
+In the above case the sums in hand at the beginning of the year are as
+follows:
+
+ 1st year $71.3694 | 6th year $42.6981
+ 2d " 66.7669 | 7th " 35.3890
+ 3d " 61.4650 | 8th " 27.5009
+ 4th " 55.7055 | 9th " 18.9979
+ 5th " 49.4594 | 10th " 9.8430
+
+We find a somewhat different condition existing during the first years
+of a 5-year endowment policy. As there is more insurance and less
+banking, the requirements are as follows:
+
+ ------------+----------+-----------+--------+---------+
+ | 1 P. Ct. | 20 P. Ct. | | |
+ | on | on | Total. | Initial |
+ | Reserve. | Cost. | | Fund. |
+ ------------+----------+-----------+--------+---------+
+ 1st year | $1.5038 | $1.2572 |$2.7610 |$12.9769 |
+ 2d " | 3.0406 | 1.0216 | 4.0622 | 23.6015 |
+ 3d " | 4.6503 | .7852 | 5.4355 | 33.2979 |
+ 4th " | 6.3367 | .5378 | 6.8745 | 41.9538 |
+ 5th " | 8.1039 | .2996 | 8.4035 | 49.4594 |
+ 6th " | 8.4136 | .2566 | 8.6702 | 42.6981 |
+ 7th " | 8.7381 | .2076 | 8.9257 | 35.3890 |
+ 8th " | 9.0781 | .1556 | 9.2337 | 27.5009 |
+ 9th " | 9.4346 | .0988 | 9.5334 | 18.9979 |
+ 10th " | 9.8086 | .0344 | 9.8430 | 9.8430 |
+ ------------+----------+-----------+--------+---------+
+
+As the premium payments extend over only five years, the expense
+contributions must all be paid during that time and are most
+conveniently made by a uniform addition to the net premium.
+
+The present value of the amounts in column 3 is $60.0819, and the
+equivalent annuity for five years is $12.9769. This amount, received
+for five consecutive years, will put the company in funds to pay
+current expenses and leave a reserve of $42.6981 at the beginning of
+the sixth year, which, as we have seen in the analysis of the
+single-premium policy, is the sum required for future expenses on the
+paid up basis.
+
+In like manner we find that the 10-year annuity equivalent to the
+present value of the annual contributions in the case of an
+annual-payment policy is $5.534, thus:
+
+ ------------+----------+-----------+--------+---------+
+ | 1 P. Ct. | 20 P. Ct. | | |
+ | on | on | Total. | Initial |
+ | Reserve. | Cost. | | Fund. |
+ ------------+----------+-----------+--------+---------+
+ 1st year | $.8234 | $1.3514 |$2.1748 |$ 5.5340 |
+ 2d " | 1.6473 | 1.2478 | 2.8951 | 9.0275 |
+ 3d " | 2.5096 | 1.1388 | 3.6484 | 11.9116 |
+ 4th " | 3.4124 | 1.0210 | 4.4334 | 14.1277 |
+ 5th " | 4.3572 | .8916 | 5.2488 | 15.6161 |
+ 6th " | 5.3479 | .7534 | 6.1013 | 16.3160 |
+ 7th " | 6.3853 | .5966 | 6.9819 | 16.1572 |
+ 8th " | 7.4726 | .4270 | 7.8996 | 15.0763 |
+ 9th " | 8.6127 | .2418 | 8.8545 | 12.9977 |
+ 10th " | 9.8086 | .0344 | 9.8430 | 9.8430 |
+ ------------+----------+-----------+--------+---------+
+
+The present value of the ten yearly expense items given in the "total"
+column above is $46.6812, which is equal to a ten-year annuity of
+$5.534. The several premiums stand now as follows:
+
+ ENDOWMENT: $1,000, AGE 30, PAYABLE AT DEATH OR 40
+
+ Net Prem.[2] Margin. Total.
+
+At single premium. $687.228 $71.6394 $758.8674
+At five premiums. 150.615 12.9769 163.5939
+At annual premiums. 84.172 5.5340 89.7060
+
+[Footnote 2: Thirty American offices. Discount from middle of year,
+Vx-1/2 or (M x 1.01961) / Dx.]
+
+By the actuaries' rate we have, with the customary loading for
+expense:
+
+ Single premium: $721.66 (loaded, $34.36). Five premiums, $188.70
+ (loaded $37.78). Annual premium, $105.65 (loaded $21.11).
+
+Admitting the correctness of the new method, we must conclude that the
+present single premium is not sufficiently loaded to cover its own
+expenses, while the annual payment policy pays more than its just
+share. A prominent and thoroughly informed life insurance president
+says in this connection: "Many of the policies, particularly the short
+term endowments, are charged with too high a percentage of expenses to
+prove a good investment at maturity or profitable to the insured in
+case of surrender." This is not to be wondered at when the applicant
+for a 10-year endowment policy sees at a glance that he must pay, in
+the gross, more than is returned unless he should die in the interim,
+in which case a plain "life" or "term" policy would have answered the
+purpose. Under the new system of assessing expenses one form is as
+desirable as another, from the standpoint of the insured or the
+company.
+
+The new premium for the 10-year endowment policy, $89.71, commends
+itself at once to the applicant, who can easily see that his total
+outlay must fall short of the amount ultimately to be realized, of
+course, disregarding interest and probable dividends in both cases.
+
+In discounting the future expense contributions I have not taken the
+chances of dying into account. Hence the expense reserve in any
+instance applies only to that individual case, and, in the event of
+death or surrender before the maturity of the policy, the amount of
+the expense fund not used would naturally revert to the insured.
+
+The scheme of expense assessment outlined above will doubtless be
+pronounced impracticable by the majority of insurance men.
+
+Such a far reaching reform is too much to hope for, at least in the
+immediate future.
+
+No well informed life insurance expert will deny that there are
+opportunities for improvement in the business, but to graft new
+methods on old companies is a hopeless undertaking.
+
+It is well, however, to have new methods well matured in advance of
+the public demand, and I feel convinced that the ideas here set forth
+are in the line of the reform which, before long, must be instituted
+by the companies if they would retain the confidence and patronage of
+the community.
+
+Doubtless many insurance presidents could tell of suggestions which
+have impressed them favorably and which they would gladly have adopted
+were it not for the injustice done thereby to older members and the
+changes necessary to bring existing contracts into conformity with the
+new system. Similar objections may be urged against the ideas here
+advanced, and I must confess I hardly see a way by which the present
+suggestions can be utilized by existing companies. We can only hope
+that sooner or later some of the new theories may be practically
+tested. Meanwhile the companies at present in the field are doing a
+great work for the good of humanity, even though their methods may be,
+in some particulars, more practical than scientific.
+
+Winchester, Mass. FRANK J. WILLS.
+
+ * * * * *
+
+
+
+
+THE FLOOD AT KARLSBAD.
+
+
+During the flood which occurred in Germany and Bohemia, the last week
+of November, Karlsbad was especially unfortunate; it suffered such an
+inundation as had never before been known in the "Sprudelstadt." On
+the evening of November 23, the Tepl was very much swollen by the
+rain, which had continued for several days, but it was supposed that
+there was no danger of a flood, as the bed of the river had been put
+in proper condition. During the forenoon of November 24, the water
+suddenly began to rise with such astonishing rapidity that within half
+an hour all the lower streets were like turbulent rivers and the Alte
+and Neue Wiese were transformed into a lake. The stores on the Alte
+Wiese were under water to the roofs, and the proprietors, who were
+trying to save their goods, were surprised by the water and had to
+take refuge in the trees. They were rescued by having ropes thrown to
+them, and during this work a catastrophe occurred which was a great
+misfortune to all classes of citizens. The beloved burgermeister of
+Karlsbad, Dr. Rudolf Knoll, who had just recovered from a severe
+illness, was, with others, directing the work from the balcony of one
+of the houses, when a rope by which a man was being drawn through the
+water broke, and the man was carried off by the waves. The fright and
+excitement of the scene gave the burgermeister a shock which caused
+his instant death, but the man who was in danger was brought safely
+out of the water.
+
+The water was 9 ft. in Marienbaderstrasse, the Marktplatz,
+Muhlbadgasse, the Sprudelgasse, Kreuzgasse, Kaiserstrasse, and
+Egerstrasse, and flooded the quay, causing great destruction. All
+places of business were flooded, the doors and iron shutters were
+pushed in by the force of the water and the goods were carried away or
+ruined.
+
+The house called "Zum Kaffeebaum" was undermined and part of it fell
+to the ground; the same fate was feared for other buildings. The
+Sophien and Curhaus bridges were carried away. Other bridges were
+greatly damaged, and the masonry along the banks of the river was
+partially destroyed. The Sprudelgasse was completely washed out, and
+the condition of the Muhlbadgasse was almost as bad. The fire
+department with its apparatus had great difficulty in saving the
+inhabitants and guests, as there were very few boats or pontoons at
+their command, and the soldiers (Pionniere) from Prague and the
+firemen from the neighboring towns did not arrive until evening.
+Fortunately the water began to fall in the night, and the next day it
+had gone down so that it left its terrible work visible. The Sprudel
+and the mineral springs were not injured, but, on the other hand, the
+water pipes of the bathing establishments and the gas pipes were
+completely destroyed.--_Illustrirte Zeitung._
+
+ * * * * *
+
+
+
+
+THEATRICAL WATER PLAYS.
+
+
+In one of the plays at Hengler's Circus in London a water scene is
+introduced, for which purpose the main ring is flooded with water in a
+manner which is both striking and interesting.
+
+[Illustration: FLOODING A CIRCUS RING.]
+
+The ring is entirely lined with stout macintosh sheeting, and into
+this, from two large conduits. 23,000 gallons of water are poured, the
+tank being filled to a depth of some 2 ft. in the remarkably short
+time of 35 seconds. A steamboat and other small craft are then
+launched and the adventures of the heroine then proceed. She falls
+overboard, we believe, but is saved after desperate and amusing
+struggles. Our engravings, which are from the _Graphic_, illustrate
+the mode of filling the ring with water, and the steamboat launch.
+
+[Illustration: A THEATRICAL STEAMBOAT.]
+
+ * * * * *
+
+
+
+
+SCIENCE IN THE THEATER.
+
+
+In the pretty little hall of the Boulevard des Italiens, at Paris, a
+striking exhibition of simulated hypnotism is given every evening.
+
+This entertainment, which has met with much success, was devised by
+Mr. Melies, director of the establishment, which was founded many
+years ago by the celebrated prestidigitator whose popular name (Robert
+Houdin) it still bears. This performance carries instruction with it,
+for it shows how easily the most surprising phenomena of the
+pathologic state can be imitated. To this effect, several exhibitions
+are given every evening.
+
+Mr. Harmington, a convinced disciple of Mesmer, asks for a subject,
+and finds one in the hall. A young artist named Marius presents
+himself. Mr. Harmington makes him perform all sorts of extravagant
+acts, accompanied with a continuous round of pantomimes that are
+rendered the more striking by the supposed state of somnipathy of the
+subject. At the moment at which Marius is finishing his most
+extraordinary exercises, a policeman suddenly breaks in upon the stage
+in order to execute the recent orders relative to hypnotism. But he
+himself is subjugated by Mr. Harmington and thrown down by the
+vibrations of which the encephalus of this terrible magnetizer is the
+center. When the curtain falls, the representative of authority is
+struggling against the catalepsy that is overcoming him.
+
+All the phenomena of induced sleep are successively simulated with
+much naturalness by Mr. Jules David, who plays the part of Marius in
+this pleasing little performance.
+
+At a certain moment, after skillfully simulated passes made by the
+magnetizer, Mr. David suddenly becomes as rigid as a stick of wood,
+and falls in pivoting on his heels (Fig. 1). Did not Mr. Harmington
+run to his assistance, he would inevitably crack his skull upon the
+floor, but the magnetizer stands just behind him in order to receive
+him in his arms. Then he lifts him, and places him upon two chairs
+just as he would do with a simple board. He places the head of the
+subject upon the seat of one of the chairs and the heels upon that of
+the other. Mr. David then remains in a state of perfect immobility.
+Not a muscle is seen to relax, and not a motion betrays the
+persistence of life in him. The simulation is perfect.
+
+[Illustration: FIG. 1.--CATALEPTIC RIGIDITY.]
+
+In order to complete the astonishment of the spectators, Mr.
+Harmington seats himself triumphantly upon the abdomen of the subject
+and slowly raises his feet and holds them suspended in the air to show
+that it is the subject only that supports him, without the need of
+any other point of support than the two chairs (Fig. 2).
+
+[Illustration: FIG. 2.--EXPERIMENT ON THE SAME SUBJECT.]
+
+Usually, there are plenty of persons ingenuous enough to think that
+Mr. David is actually in a cataleptic sleep, one of the characters of
+which is cadaveric rigidity.
+
+As Mr. David's neck is entirely bare, it is not possible to suppose
+that the simulator of catalepsy wears an iron corset concealed beneath
+his clothing. He has performed a feat of strength and skill rendered
+easy by the exercise that he has given to the muscles occupying the
+_colliciae_ of his vertebral column. This part of the muscular system
+is greatly developed in the weakest and least hardy persons. In fact,
+in order that man may keep a vertical position and execute an infinite
+multitude of motions in which stability is involved, nature has had to
+give him a large number of different organs. The muscles of the back
+are arranged upon several superposed layers, the vertebral column is
+doubly recurved in order that it may have more strength, and, finally,
+rachidion nerves issue from each vertebra in order to regulate the
+contraction of each muscular fasciculus according to the requirements
+of equilibrium. The trick is so easy that we have seen youths
+belonging to the Ligue d'Education Physique immediately imitate Mr.
+David after seeing him operate but once.
+
+For the sake of those who would like to perform it, we shall add that
+Mr. David takes care to bend his body in the form of an arch in such a
+way that the convexity shall be beneath. As Mr. Harmington never fails
+to place himself in the center of the line that joins Mr. David's head
+and heels, his weight is divided into two parts, that is to say, 88
+pounds on each side of the point of support. The result is that the
+stress necessary is less than that of a strong man of the Halle
+lifting a bag of wheat to his shoulder or of an athlete supporting a
+human pyramid. The force of contraction of the muscular fibers brought
+into play in this experiment is much greater than is commonly
+believed. In his lectures on physiology, Milne-Edwards cites some
+facts that prove that it may exceed 600 pounds per square inch of
+section.
+
+[Illustration: FIG. 3.--THE PERFORATE ARM.]
+
+The experiment on cadaveric rigidity is followed by others in
+insensibility. Mr. David, without wincing, allows a poignard to be
+thrust into his arm, which Mr. Harmington has previously
+"cataleptized" (Fig. 3). This trick is performed by means of a blade
+divided into two parts that are connected by a semicircle. This
+process is well known to prestidigitators, but it might be executed in
+a genuine manner. In fact, on replacing the poignard by one of the
+gold needles used by physicians for acupuncture, it would be possible
+to dispense with prestidigitation. Under such conditions it is
+possible to transpierce a person's arm. The pain is supportable, and
+consists in the sensation of a prick produced in the passage of the
+needle through the skin. As for the muscular flesh, that is of itself
+perfectly insensible. The needle, upon the necessary antiseptic
+precautions being taken, may traverse the veins and arteries with
+impunity, provided that it is not allowed to remain long enough to
+bring about the formation of a clot of coagulated blood (Fig. 4).
+
+[Illustration: FIG. 4.--AN ARM TRANSPIERCED BY A NEEDLE.]
+
+We think it of interest to add that it is necessary that the
+experiment be performed by a practitioner if one desires to
+demonstrate upon himself a very curious physiological fact that has
+been known from the remotest antiquity. It has been employed for
+several thousand years in Chinese medicine, for opening a passage for
+the bad spirits that produce diseases. For some years past a much more
+serious use has been made of it in European medicine for introducing
+electric currents into the interior of the organism. In this case the
+perimeter of the needle is insulated, and the electricity flows into
+the organism through the point. We have several times had these
+operations performed upon ourselves, and this permits us to assert
+that the above mentioned facts are absolutely true.--_La Nature._
+
+ * * * * *
+
+
+
+
+NEWER PHYSIOLOGY AND PATHOLOGY.
+
+By Prof. SAMUEL BELL, M.D.
+
+
+Physiology has for many decades been a science founded on experiment,
+and pathology has been rapidly pressing forward in the same direction.
+To read the accounts of how certain conclusions have been arrived at
+in the laboratory, by ingenious devices and by skillful manipulations,
+is as fascinating as any tale of adventure.
+
+When the microscope began its work, how discouraging was the vastness
+and complexity of the discoveries which it brought to light; how many
+years has it been diligently used, and how uncertain are we still
+about many of its revelations! But what a happy conjecture of man, and
+as proper environment takes place we may reach better results! Let me
+give an illustration:
+
+Some thirty years ago, Virchow began his studies and lectures upon
+cellular pathology. The enthusiasm which he awakened spread over the
+whole medical world. The wonderful attention to detail, the broad
+philosophy which signalized his observations, were alike remarkable.
+His class room was packed with students from every country, who
+thought it no hardship to struggle for a seat at eight o'clock in the
+morning. With his blackboard behind him and specimens of pathology
+before him, and microscopes coursing upon railway tracks around the
+tables which filled the room, he was the embodiment of the teacher;
+his highest honor was as discoverer. The life and importance of the
+cell, both in health and disease, it has been his work to discover and
+to teach. The point of view from which he has classified tumors is
+founded on this basis, and remains the accepted method. The light
+which he cast upon the nature of inflammation has not yet been
+obscured, and while other phenomena appear, the multiplication of
+cells and nuclei and the formation of connective tissue in the process
+of inflammation will always call to mind his labors.
+
+To one of Virchow's pupils, Prof. Recklinghausen, we chiefly owe our
+knowledge of the phenomena of diapedesis as a part of the inflammatory
+activity. How incredible it seems that masses of living matter can
+make their way through the walls of blood vessels which do not rupture
+and which have no visible apertures!
+
+Virchow fixed his attention upon the forms and activities of the
+cells, their multiplication and degradation, and how they build up
+tissues, both healthy and morbid.
+
+To another matter with which, both literally and metaphorically, the
+air is filled, we must also make allusion. The existence of
+micro-organisms in countless numbers is no new fact, but the influence
+they may exert over living tissues has only lately become the subject
+of earnest attention. So long as they were not known to have any
+practical bearing upon human welfare, they interested almost nobody,
+but when, however, it was shown that putrefaction of meat is due to
+the agency of the _bacterium termo_, and the decomposition of albumen
+to the _bacillus subtilis_; when anthrax in cattle and sheep was found
+to depend on the _bacillus anthracis_, and that in human beings it
+caused malignant pustules; when suppuration of wounds was found to be
+associated with micrococci; and when it was announced that by a
+process of inoculation cattle could be protected against anthrax, and
+that by carbolic spray and other well known precautions the
+suppuration of wounds could be prevented--all the world lent its ears
+and investigation at once began.
+
+Because labors in bacteriology promised to be fruitful in practical
+results, the workers speedily became innumerable, and we are
+accumulating a wondrous store of facts. How long now is the list of
+diseases in which germs make their appearance--in pneumonia, in
+endocarditis, in erysipelas, in pyaemia, in tuberculosis, and so on and
+so on. One of the most striking illustrations is the gonococcus of
+gonorrhoea, whose presence in and around gives to the pus cells
+their virulent properties, and when transferred to the eye works such
+lamentable mischief. Without their existence the inoculation of pus in
+the healthy eye is harmless; pus bearing the gonococci excites the
+most intense inflammation. Similar suppurative action in the cornea is
+often caused by infection of cocci. The proof of causation may be
+found in the fact that the most effective cure now practiced for such
+suppuration is to sterilize them by the actual cautery. Rosenbach says
+that he knows six distinct microbes which are capable of exciting
+suppuration in man. Their activity may be productive of a poison, or
+putrefactive alkaloid, which is absorbed.
+
+There are at present two prominent theories in regard to the
+infections which produce disease. The first is based upon chemical
+processes, the second upon the multiplication of living organisms. The
+chemical theory maintains that after the infectious element has been
+received into the body it acts as a ferment, and gives rise to certain
+morbid processes, upon the principle of catalysis. The theory of
+organisms, or the germ theory, maintains that the infectious elements
+are living organisms, which, being received into the system, are
+reproduced indefinitely, and excite morbid processes which are
+characteristic of certain types of disease. This latter theory so
+readily explains many of the facts connected with the development and
+reproduction of infectious diseases, that it has been unqualifiedly
+adopted by a large number of investigators. The proofs of this theory
+had not, however, advanced beyond the demonstrations of the presence
+of certain forms of bacteria in the pathological changes of a very
+limited number of infectious diseases, until February, 1882, when Koch
+announced his discovery of the tubercle bacillus, since which time
+nearly every disease has its supposed microbe, and the race is,
+indeed, swift in which the would-be discoverers press forward with new
+germs for public favor.
+
+The term bacteria or microbe refers to particles of matter,
+microscopic in size, which belong to the vegetable kingdom, where they
+are known as fungi. If we examine a drop of stagnant water under the
+microscope, amplifying say four hundred diameters, we see it loaded
+with minute bodies, some mere points, others slightly elongated into
+rods, all actively in motion and in various positions, a countless
+confusion. If evaporation now takes place, all is still. If we now
+apply moisture, the dried-up granules will show activity, as though
+they had not been disturbed.
+
+All these different organisms have become familiar to us under the
+generic term bacteria, which is a very unfortunate application, as it
+really applies to only a single class of fungi. Cohn calls them
+schizomycetes, and makes the following classifications:
+
+ 1. _Sphero-bacteria_, or microbes.
+ 2. _Micro-bacteria_, or bacteria.
+ 3. _Desmo-bacteria_, or bacilli.
+ 4. _Spiroteria_, or spirillae.
+
+The _spiro-bacteria_, or micrococci, are the simplest of the fungi,
+and appear as minute organisms of spherical form. They multiply by
+fission, a single coccus forming two, these two producing four, and so
+on. They present a variety of appearances under the microscope. From
+single isolated specimens (which under the highest magnifying power
+present nothing beyond minute points) you will observe them in pairs,
+again in fours, or in clusters of hundreds (forming zooeglea) and still
+adhering together, forming chains. When a given specimen is about to
+divide, it is seen to elongate slightly, then a constriction is
+formed, which deepens until complete fission ensues.
+
+Micrococci possess no visible structure. They consist of a minute
+droplet of protoplasm (mycroprotein) surrounded by a delicate cell
+membrane. Certain forms are embedded in a capsule (diameter 0.0008 to
+0.0001 millimeter).
+
+These little organisms, when observed in a fluid like blood, sputum,
+etc., are found to present very active movements, although provided
+with no organs of locomotion.
+
+This Brownian motion is possessed by almost every minute particle of
+matter, organic and inorganic, and is not due to any inherent power of
+the individual. They are almost omnipresent, abounding in the air, the
+earth, the water, are always found in millions where moist organic
+matter is undergoing decomposition, and are associated with the
+processes of fermentation--in fact, they are essential to it. The
+souring of milk succeeds the multiplication of these germs. Certain
+varieties are pigmented, and we observe colonies of chromogenic cocci
+multiplying upon slices of boiled potato, eggs, etc., presenting all
+the colors of the rainbow. All of these germs are not the cause of
+disease. Certain species, however (termed pathogenic), are always
+associated with certain diseased conditions.
+
+The _bacteria-termo_--micro-bacteria--are slightly elongated, and
+inasmuch as they multiply by division, frequently appear coupled
+together, linked in pairs, and in chains. They are generally found in
+putrefying liquids, especially infusions of vegetable matter. They
+possess mobility to a remarkable degree. Observing a field of
+bacteria-termo under the microscope, they may be seen actively engaged
+in twining and twisting. A flagellum has been demonstrated as attached
+to one or both extremities. This is too minute to be generally
+resolved, even if it is a common appendage.
+
+_Desmo-bacteria_ (or bacilli) are rod-like organisms, occurring of
+various lengths and different thicknesses. In a slide of the bacillus
+of tuberculosis and anthrax, we notice at intervals dots which
+represent the spores from which, as the rods break up, future bacilli
+are developed.
+
+Then we have _spiro-bacteria,_ the spirilla and the spirochetae; the
+former having short open spirals, the latter long and closely wound
+spirals. The _spirillum, volutans_ is often found in drinking water,
+and in common with some other specimens of this class is provided with
+flagellae, sometimes at both extremities, which furnish the means of
+rapid locomotion. The spiro-bacteria multiply by spores, although
+little is at present known of their life history. They frequently are
+attached together at their extremities, forming zigzag chains.
+
+We have seen that bacteria differ greatly in appearance from the
+elongated dot of the bacterium proper, to the elongated rod or
+cylinder of the bacillus, and the long spirals of spiro-bacteria. It
+is unfortunate that they are not sufficiently constant in habit to
+always attach themselves to one or the other of these genera. The
+micrococcus has a habit of elongating at times until it is impossible
+to recognize him except as a bacterium; while bacilli, again, break up
+until their particles exactly resemble micrococci.
+
+Bacteria cannot exist without water; certain forms require oxygen,
+while others thrive equally well without it; some thrive in solution
+of simple salts, while others require albuminoid material.
+
+Bacteriology, with its relation to the science of medicine, is of
+importance to every investigating physician; it covers our knowledge
+of the relation of these minute organisms to the aetiology of disease.
+What has been gained as to practical application in the treatment of
+disease? This question is not infrequently asked in a sneering manner.
+We can, in reply, say that the results are not all in the future. It
+is encouraging that results have been attained which have had a very
+important practical bearing, and that these complaints come generally
+from individuals least acquainted with scientific investigations in
+bacteriology.
+
+In the study of the relation of a given bacterium to a certain
+disease, it becomes necessary to attend carefully to three different
+operations: First, the organism supposed to cause the disease must be
+found and isolated. Second, it must be cultivated through several
+generations in order that absolute purity may be secured. Lastly, the
+germ must be again introduced into a healthy living being. If the
+preceding steps be carried out, and the original disease be
+communicated by inoculation, and the germs be again found in the
+diseased body, we have no alternative; we must conclude that we have
+ascertained the cause of the disease. The importance of being familiar
+with the aetiology of the disease before we can expect to combat it
+with any well-grounded hope of success is evident.
+
+If the sputum of a phthisical patient be submitted to the skilled
+microscopist, he is nearly always able to demonstrate bacilli, but
+this goes for very little. Because bacilli are found in phthisis, it
+is no more certain that they are the cause of phthisis than it is
+certain that cheese mites are the cause of cheese. Well, suppose we
+were to inject sputum from a phthisical person into the lower animal
+and tuberculosis follows, and then announce to the profession that we
+have demonstrated the relation of the cause and effect between bacilli
+and phthisis? Why we would start such an uproar of objections as would
+speedily convince us that there was much work yet in the domain of
+bacteriology.
+
+The scientific investigators would say you have injected with the
+sputum into the blood of your unfortunate patient, pus, morphological
+elements, and perhaps half a dozen other forms of bacteria, any one of
+which is just as likely to produce the disease as the bacillus you
+have selected.
+
+The first important step is, first isolate your bacillus. If I were to
+take a glass plate, one side of which is coated with a thick solution
+of peptonized gelatin, and allow the water to collect, the gelatinous
+matter will become solid. If now, with a wire dipped in some
+tuberculous matter, I draw a line along the gelatin, I have deposited
+at intervals along this line, specimens of tubercle bacilli. If this
+plate be now kept at a proper temperature, after a few days, wherever
+the bacilli have been caught, a grayish spot will appear, which,
+easily seen with the naked eye, gradually spreads and becomes larger.
+These spots are colonies containing thousands of bacilli. Let us
+return to our gelatin plate.
+
+We find a spot which answers to the description of a colony of
+tubercle bacilli. We now take a minute particle from this colony on a
+wire and convey it to the surface of some hardened blood serum in a
+test tube. We plug the tube so that no air germs may drop in, and
+place it in an incubator at the proper temperature. After several
+days, if no contamination be present, a colony of bacilli will appear
+around the spot where we sowed the spores. Let us repeat the process.
+
+Take a particle from this colony, and transfer it to another tube.
+This is our second culture. This must be repeated until we are
+satisfied that we have secured a _pure_ culture. If this be carried to
+the twenty-fifth generation, we may be assured that there remains no
+pus, no ptomaines, nothing but the desired bacilli.
+
+It is a proper material now for inoculation, and if we inoculate some
+of the lower animals, for instance the monkey, we produce a disease
+identical with phthisis pulmpnalis. Bacteria also afford peculiar
+chemical reactions. For example, nitric acid will discharge all the
+color from all bacilli artificially dyed with anilin, except those of
+tubercle and anthrax. One species is stained readily with a dye that
+leaves another unaltered. Thus we are enabled in the laboratory to
+determine whether the bacilli found in sputum, for example, are from
+tubercle or are the bacteria of decomposition.
+
+From what I have said of the tubercle bacillus, it would seem
+thoroughly demonstrated that it is the cause of tubercle in these
+animals. But we must walk cautiously here. These are not human beings,
+who know that like results would follow their inoculation. The animals
+used by Koch are animals very subject to tubercle.
+
+We must, from the very nature of our environment, be constantly
+inhaling these germs as we pass through the wards of our hospitals;
+yes, they are floating in the air of our streets and dwellings. It
+becomes necessary then for us to inquire: If bacteria cause disease,
+in what manner do they produce it? The healthy organism is always
+beset with a multitude of non-pathogenic bacteria. They occupy the
+natural cavities, especially the alimentary canal. They feed on the
+substances lying in their neighborhood, whether brought into the body
+or secreted by the tissues. In so doing they set up chemical changes
+in their substances. Where the organs are acting normally these fungi
+work no mischief. The products of decomposition thus set up are
+harmless, or are conveyed out of the body before they begin to be
+active.
+
+If bacteria develop to an inordinate degree, if the contents of organs
+are not frequently discharged, fermentative processes may be set up,
+which result in disease. Bacteria must always multiply and exist at
+the expense of the body which they infest, and the more weakened the
+vital forces become, the more favorable is the soil for their
+development.
+
+Septicaemia is caused by the absorption of the products of
+putrefaction, induced before bacteria can multiply inside or outside
+the body. Bacteria must find a congenial soil. The so-called cholera
+bacillus must gain access to the intestinal tract before it finds
+conditions suitable to colonization. It does not seem to multiply in
+the stomach or in the blood, but once injected into the duodenum
+develops with astonishing rapidity, and the delicate epithelial cells
+of the villi become swollen, soften and break down, exposing the
+mucosa.
+
+It has been shown that _bouillon_ in which Loeffler's diphtheria
+bacillus has grown, and which has been passed through unglazed
+porcelain filters, shows the presence of a poison which is capable of
+producing the same results upon inoculation as the pure culture of the
+bacillus itself. Zarniko, working upon the same organism, obtained a
+number of positive results that led him to declare this bacillus is
+the cause of epidemic diphtheria, in spite of many assertions to the
+contrary. Chantmesse and Widal record the results of their work as to
+what will most easily and effectively destroy the bacillus of
+diphtheria.
+
+The only three substances that actually checked and destroyed its
+vitality were phenic acid (5 per cent.), camphor (20 per cent.), olive
+oil (25 per cent.), in combination. For the last I substitute
+glycerine, because this allows the mixture to penetrate farther into
+the mucous membrane than oil, the latter favoring a tendency to pass
+over the surface. This mixture when heated separates into two layers,
+the upper one viscid and forming a sort of "glycerol," the lower
+clear. The latter will completely sterilize a thread dipped in a pure
+culture of the diphtheria bacillus. Corrosive sublimate was not
+examined because in strong enough doses it would be dangerous and in
+weaker ones it would be useless.
+
+The facts obtained in regards to the streptococcus of erysipelas are
+reported as follows: That both chemical and experimental evidence
+teach the extreme ease of a renewed attack of the disease; that it is
+possible to kill guinea pigs by an intoxication when they are immune
+to an inoculation of the culture in ordinary quantities. And this
+latter fact should warn experimenters trying to obtain immunity in man
+by the inoculation of non-pathogenic bacteria, because the same
+results may be reached.
+
+A new theory in regard to fevers and the relation of micro-organisms
+is suggested by Roussy, viz.: That it is a fermentation produced by a
+diastase or soluble ferment found in all micro-organisms and cells,
+and which they use in attacking and transforming matter, either inside
+their substance or without it.
+
+The resemblance of the malaria parasite to that of recurrent fever is
+noted in the work of Sacharoff. He states that there exists in the
+blood of those suffering from recurrent fever a haematozoon, which is
+most prominent after the fever has begun to fall, when it is of
+enormous proportions, twenty or more diameters of a red blood
+corpuscle, although smaller ones may still be found. The parasite
+consists of a delicate amoeboid body containing a multitude of dark,
+round, uniform, sharply outlined, movable granules. Besides these, the
+protoplasm contains a generally grayish homogeneous nucleus as large
+as one or two red blood corpuscles. The protoplasm sends out
+pseudopodia (with granules), which sometimes separate and appear as
+small delicate pieces of protoplasm. They vary in size, and are often
+swallowed by the red blood corpuscles in which they grow, and finally
+develop into the above mentioned amoeboid bodies.
+
+Prof. J. Lewis Smith has made a great many autopsies of children dead
+from cholera infantum, and almost invariably found the stomach and
+liver in a comparatively healthy condition. Ganghen, who has given
+this subject considerable study, denies the existence of any specific
+germ in the summer diarrhea of infants, but claims to have found three
+different germs in the intestines of children suffering from cholera
+infantum, each producing a chemical poison which is capable of
+producing vomiting, purging, and even death. A great variety of germs
+are found in drinking water, and no doubt countless numbers are taken
+into the digestive tract, and the principal reason why pathological
+conditions do not occur more frequently is on account of the
+germicidal qualities of the gastric juice.
+
+The comma bacillus of Koch, and the typhoid fever germ of Eberth, are
+especially destroyed in normal gastric juice. When the germs are very
+numerous, they run the gauntlet of the stomach (as the gastric juice
+is secreted only during digestion); and once in the alkaline
+intestinal canal they are capable of setting up disease, other
+conditions contributing--ill health, deranged digestion, etc.
+
+Mittnam has made a study of bacteria beneath the nails, and reports,
+after examining persons following different occupations, having found
+numerous varieties of micro-organisms; which are interesting from a
+scientific standpoint relative to the importance of thoroughly
+cleansing the hands before undertaking any surgical procedure. He
+found, out of twenty-five experiments, 78 varieties of bacteria, of
+which 36 were classed as micrococci, 21 diplococci, 18 rods, 3
+sarcinae, and 1 yeast. Cooks, barbers, waiters, etc., were examined.
+
+The blood, defibrinated and freshly drawn, has marked germicidal
+action; for bacteria its action is decidedly deadly, even hours after
+it has been drawn from the body. Especially were anti-germic qualities
+noticed upon pathogenic bacteria. Buchner put the bacilli of anthrax
+in a quantity of blood, and in two hours the number was reduced from
+4,800 to 56, and in three hours only 3 living bacteria remained. Other
+bacteria were experimented upon in blood with similar results, but the
+destruction of the organism from putrefaction was much less marked,
+and on some varieties the blood had little or no action.
+
+It is not the object of these remarks to even give a _resume_ of the
+_status praesens_ of bacteriology, but simply to stimulate thought in
+that direction. The claims of some of the ultra-bacteriologists may
+never be realized, but enough has been accomplished to revolutionize
+the treatment of certain diseases, and the observing student will do
+well to keep his eye on the microbe, as it seems from the latest
+investigations that its star is in the ascendant. And who can
+prognosticate but that in the next decade an entire revolution in the
+aetiology and treatment of many diseases may take place?
+
+Detroit, Mich.
+
+ * * * * *
+
+
+
+
+THE COMPOSITION OF KOCH'S LYMPH.
+
+WHAT PROFESSOR KOCH SAYS IT IS, AND WHAT IT CAN DO.
+
+(By Cable to the _Medical Record_.)
+
+BERLIN, January 15, 1891.
+
+
+The curiosity to know the composition of the famous lymph has been
+gratified by the publication to-day of an article by Professor Koch on
+the subject. In the following, as will be seen, he reaffirms his
+original convictions and acknowledges the valuable assistance he has
+received from those who have used his fluid, and thus helped him in
+the accumulation of experience.
+
+Professor Koch says: Two months ago I published the results of my
+experiments with the new remedy for tuberculosis, since which time
+many physicians who received the preparation have been enabled to
+become acquainted with its properties through their own experiments.
+So far as I have been able to review the statements published and the
+communications received by letter, my predictions have been fully and
+completely confirmed. The general consensus of opinion is that the
+remedy has a specific action upon tubercular tissues, and is,
+therefore, applicable as a very delicate and sure reagent for
+discovering latent and diagnosing doubtful tuberculous processes.
+Regarding the curative effects of the remedy, most reports agree that,
+despite the comparatively short duration of its application, many
+patients have shown more or less pronounced improvement. It has been
+affirmed that in not a few cases even a cure has been established.
+Standing quite by itself is the assertion that the remedy may not only
+be dangerous in cases which have advanced too far--a fact which may
+forthwith be conceded--but also that it actually promotes the
+tuberculous process, being therefore injurious.
+
+During the past six weeks I myself have had opportunity to bring
+together further experiences touching the curative effects and
+diagnostic application of the remedy in the cases of about one hundred
+and fifty sufferers from tuberculosis of the most varied types in this
+city and in the Moabit Hospital.
+
+I can only say that everything I have latterly seen accords with my
+previous observations. There has been nothing to modify in what I
+before reported. As long as it was only a question of proving the
+accuracy of my indications, it was needless for any one to know what
+the remedy contained or whence it was derived. On the contrary,
+subsequent testing would necessarily be more unbiased, the less people
+knew of the remedy itself. Now, after sufficient confirmatory testing,
+the importance of the remedy is proved, my next task is to extend my
+study of the remedy beyond the field where it has hitherto been
+applied, and if possible to apply the principle underlying the
+discovery to other diseases.
+
+This task naturally demands a full knowledge of the remedy. I
+therefore consider that the time has arrived when the requisite
+indications in this direction shall be made. This is done in what
+follows.
+
+Before going into the remedy itself, I deem it necessary for the
+better understanding of its mode of operation to state briefly the way
+by which I arrived at the discovery. If a healthy guinea pig be
+inoculated with the pure cultivation of German Kultur of tubercle
+bacilli, the wound caused by the inoculation mostly closes over with a
+sticky matter, and appears in its early days to heal. Only after ten
+to fourteen days a hard nodule presents itself, which, soon breaking,
+forms an ulcerating sore, which continues until the animal dies. Quite
+a different condition of things occurs when a guinea pig already
+suffering from tuberculosis is inoculated. An animal successfully
+inoculated from four to six weeks before is best adapted for this
+purpose. In such an animal the small indentation assumes the same
+sticky covering at the beginning, but no nodules form. On the
+contrary, on the day following, or the second day after the
+inoculation, the place where the lymph is injected shows a strange
+change. It becomes hard and assumes a darker coloring, which is not
+confined to the inoculation spot, but spreads to the neighboring parts
+until it attains a diameter of from 0.05 to 1 cm.
+
+In a few days it becomes more and more manifest that the skin thus
+changed is necrotic, finally falling off, leaving a flat ulceration
+which usually heals rapidly and permanently without any involvement of
+the adjacent lymphatic glands. Thus the injected tubercular bacilli
+quite differently affect the skin of a healthy guinea pig from one
+affected with tuberculosis. This effect is not exclusively produced
+with living tubercular bacilli, but is also observed with the dead
+bacilli, the result being the same whether, as I discovered by
+experiments at the outset, the bacilli are killed by a somewhat
+prolonged application of a low temperature or boiling heat or by means
+of certain chemicals. This peculiar fact I followed up in all
+directions, and this further result was obtained--that killed pure
+cultivations of tubercular bacilli, after rinsing in water, might be
+injected in great quantities under healthy guinea pig's skin without
+anything occurring beyond local suppuration. Such injections belong to
+the simplest and surest means of producing suppurations free from
+living bacteria.
+
+Tuberculous guinea pigs, on the other hand, are killed by the
+injection of very small quantities of such diluted cultivations. In
+fact, within six to forty-eight hours, according to the strength of
+the dose, an injection which is not sufficient to produce the death of
+the animal may cause extended necrosis to the skin in the vicinity of
+the place of injection. If the dilution is still further diluted until
+it is scarcely visibly clouded, the animals inoculated remain alive
+and a noticeable improvement in their condition soon supervenes. If
+the injections are continued at intervals of from one to two days, the
+ulcerating inoculation wound becomes smaller and finally scars over,
+which otherwise it never does; the size of the swollen lymphatic
+glands is reduced, the body becomes better nourished, and the morbid
+process ceases, unless it has gone too far, in which case the animal
+perishes from exhaustion. By this means the basis of a curative
+process against tuberculosis was established.
+
+Against the practical application of such dilutions of dead tubercle
+bacilli there presented itself the fact that the tubercle bacilli are
+not absorbed at the inoculation points, nor do they disappear in
+another way, but for a long time remain unchanged, and engender
+greater or smaller suppurative foci. Anything, therefore, intended to
+exercise a healing effect on the tuberculous process must be a soluble
+substance which would be liberated to a certain extent by the fluids
+of the body floating around the tubercle bacilli, and be transferred
+in a fairly rapid manner to the juices of the body; while the
+substance producing suppuration apparently remains behind in the
+tubercular bacilli, or dissolves but very slowly. The only important
+point was, therefore, to induce outside the body the process going on
+inside, if possible, and to extract from the tubercular bacilli alone
+the curative substance. This demanded time and toil, until I finally
+succeeded, with the aid of a forty to fifty per cent. solution of
+glycerine, in obtaining an effective substance from the tubercular
+bacilli. With the fluid so obtained I made further experiments on
+animals, and finally on human beings. These fluids were given to other
+physicians to enable them to repeat the experiments.
+
+The remedy which is used in the new treatment consists of a glycerine
+extract, derived from the pure cultivation of tubercle bacilli. Into
+the simple extract there naturally passes from the tubercular bacilli,
+besides the effective substance, all the other matter soluble in fifty
+per cent. glycerine.
+
+Consequently, it contains a certain quantity of mineral salts,
+coloring substances, and other unknown extractive matters. Some of
+these substances can be removed from it tolerably easily. The
+effective substance is insoluble in absolute alcohol. It can be
+precipitated by it, though not, indeed, in a pure condition, but still
+combined with the other extractive matter. It is likewise insoluble in
+alcohol. The coloring matter may also be removed, rendering it
+possible to obtain from the extract a colorless, dry substance
+containing the effective principle in a much more concentrated form
+than the original glycerine solution. For application in practice this
+purification of the glycerine extract offers no advantage, because the
+substances so eliminated are unessential for the human organism. The
+process of purification would make the cost of the remedy
+unnecessarily high.
+
+Regarding the constitution of the more effective substances, only
+surmises may for the present be expressed. It appears to me to be
+derivative from albuminous bodies, having a close affinity to them. It
+does not belong to the group of so-called toxalbumins, because it
+bears high temperatures, and in the dialyzer goes easily and quickly
+through the membrane. The proportion of the substance in the extract
+to all appearance is very small. It is estimated at fractions of one
+per cent., which, if correct, we should have to do with a matter whose
+effects upon organisms attacked with tuberculosis go far beyond what
+is known to us of the strongest drugs.
+
+Regarding the manner in which the specific action of the remedy on
+tuberculous tissue is to be represented, various hypotheses may
+naturally be put forward. Without wishing to affirm that my view
+affords the best explanation, I represent the process myself in the
+following manner:
+
+The tubercle bacilli produced when growing in living tissues, the same
+as in artificial cultivations, contain substances which variously and
+notably unfavorably influence living elements in their vicinity. Among
+these is a substance which in a certain degree of concentration kills
+or so alters living protoplasm that it passes into a condition that
+Weigert describes as coagulation necrosis. In tissue thus become
+necrotic the bacillus finds such unfavorable conditions of nourishment
+that it can grow no more and sometimes dies.
+
+This explains the remarkable phenomenon that in organs newly attacked
+with tuberculosis, for instance in guinea pigs' spleen and liver,
+which then are covered with gray nodules, numbers of bacilli are
+found, whereas they are rare or wholly absent when the enormously
+enlarged spleen consists almost entirely of whitish substance in a
+condition of coagulation necrosis, such as is often found in cases of
+natural death in tuberculous guinea pigs. The single bacillus cannot,
+therefore, induce necrosis at a great distance, for as soon as
+necrosis attains a certain extension the growth of the bacillus
+subsides, and therewith the production of the necrotizing substance. A
+kind of reciprocal compensation thus occurs, causing the vegetation of
+isolated bacilli to remain so extraordinarily restricted, as, for
+instance, in lupus and scrofulous glands.
+
+In such cases the necrosis generally extends only to a part of the
+cells, which then, with further growth, assume the peculiar form of
+riesen zelle, or giant cells. Thus, in this interpretation, follow
+first the explanation Weigert gives of the production of giant cells.
+
+If now one increased artificially in the vicinity of the bacillus the
+amount of necrotizing substance in the tissue, the necrosis would
+spread a greater distance. The conditions of nourishment for the
+bacillus would thereby become more unfavorable than usual.
+
+In the first place the tissue which had become necrotic over a large
+extent would decay and detach itself, and where such were possible
+would carry off the inclosed bacilli and eject them outwardly, so far
+disturbing their vegetation that they would much more speedily be
+killed than under ordinary circumstances.
+
+It is just in looking at such changes that the effect of the remedy
+appears to consist. It contains a certain quantity of necrotizing
+substance, a correspondingly large dose of which injures certain
+tissue elements even in a healthy person, and perhaps the white blood
+corpuscles or adjacent cells, thereby producing fever and a
+complication of symptoms, whereas with tuberculous patients a much
+smaller quantity suffices to induce at certain places, namely, where
+tubercle bacilli are vegetating and have already impregnated the
+adjacent region with the same necrotizing matter, more or less
+extensive necrosis of the cells, with the phenomena in the whole
+organism which result from and are connected with it.
+
+For the present, at least, it is impossible to explain the specific
+influence which the remedy, in accurately defined doses, exercises
+upon tuberculous tissue, and the possibility of increasing the doses
+with such remarkable rapidity, and the remedial effects which have
+unquestionably been produced under not too favorable circumstances.
+
+Of the consumptive patients whom he described as temporarily cured,
+two have been returned to the Moabit Hospital for further observation.
+
+No bacilli have appeared in their sputum for the past three months,
+and their phthisical symptoms have gradually and completely
+disappeared.
+
+ * * * * *
+
+
+
+
+CAN WE SEPARATE ANIMALS FROM PLANTS?
+
+By ANDREW WILSON.
+
+
+One of the plainest points connected with the study of living things
+is the power we apparently possess of separating animals from plants.
+So self-evident appears this power that the popular notion scoffs at
+the idea of science modestly disclaiming its ability to separate the
+one group of living beings from the other. Is there any danger of
+confusing a bird with the tree amid the foliage of which it builds its
+nest, or of mistaking a cow for the grass it eats? These queries are,
+of course, answerable in one way only. Unfortunately (for the
+querists), however, they do not include or comprehend the whole
+difficulty. They merely assert, what is perfectly true, that we are
+able, without trouble, to mark off the higher animals from the higher
+plants. What science inquires is, whether we are able to separate
+_all_ animals from _all_ plants, and to fix a definite boundary line,
+so as to say that all the organisms on the one side of the line are
+assuredly animals, while all the others on the opposite side of the
+line may be declared to be truly plants. It is exactly this task which
+science declares to be among the impossibilities of knowledge. Away
+down in the depths of existence and among the groundlings of life the
+identity of living things becomes of a nature which is worse than
+confusing, and which renders it a futile task to attempt to separate
+the two worlds of life. The hopelessness of the task, indeed, has
+struck some observers so forcibly that they have proposed to
+constitute a third kingdom--the _Regnum Protisticum_--between the
+animal and the plant worlds, for the reception of the host of doubtful
+organisms. This third kingdom would resemble the casual ward of a
+workhouse, in that it would receive the waifs and strays of life which
+could not find a refuge anywhere else.
+
+A very slight incursion into biological fields may serve to show forth
+the difficulties of naturalists when the task of separating animals
+from plants is mooted for discussion. To begin with, if we suppose our
+popular disbeliever to assert that animals and plants are always to be
+distinguished by shape and form, it is easy enough to show him that
+here, as elsewhere, appearances are deceptive. What are we to say of a
+sponge, or a sea anemone, of corals, of zoophytes growing rooted from
+oyster shells, of sea squirts, and of sea mats? These, each and all of
+them, are true animals, but they are so plant-like that, as a matter
+of fact, they are often mistaken by seaside visitors for plants. This
+last remark holds especially true of the zoophytes and the sea mats.
+Then, on the other hand, we can point to hundreds of lower plants,
+from the yeast plant onward, which show none of the ordinary features
+of plant life at all. They possess neither roots, stems, branches,
+leaves, nor flowers, so that on this first count of the indictment the
+naturalist gains the day.
+
+Power of movement, to which the popular doubter is certain to appeal,
+is an equally baseless ground of separation. For all the animals I
+have above named are rooted and fixed, while many true plants of lower
+grade are never rooted at all. The yeast plant, the _Algae_ that swarm
+in our ponds, and the diatoms that crowd the waters, exemplify plants
+that are as free as animals; and many of them, besides, in their young
+state especially (e.g., the seaweeds), swim about freely in the water
+as if they were roving animalcules. On the second count, also, science
+gains the day; power of motion is no legitimate ground at all for
+distinguishing one living being as an animal, while absence of
+movement is similarly no reason for assuming that the fixed organism
+must of necessity be a plant. Then comes the microscopic evidence.
+What can this wonder glass do in the way of drawing boundary lines
+betwixt the living worlds? The reply again is disappointing to the
+doubter; for the microscope teaches us that the tissues of animals and
+plants are built upon kindred lines. We meet with cells and fibers in
+both. The cell is in each case the primitive expression of the whole
+organism. Beyond cells and fibers we see the wonderful living
+substance, _protoplasm_, which is alike to our senses in the two
+kingdoms, although, indeed, differing much here and there in the
+results of its work. On purely microscopic grounds, we cannot separate
+animals from plants. There is no justification for rigidly assuming
+that this is a plant or that an animal on account of anything the
+microscope can disclose. A still more important point in connection
+with this protoplasm question consists in the fact that as we go
+backward to the beginnings of life, both in animals and plants, we
+seem to approach nearer and nearer to an identity of substance which
+baffles the microscope with all its powers of discernment. Every
+animal and every plant begins existence as a mere speck of this living
+jelly. The germ of each is a protoplasm particle, which, whatever
+traces of structure it may exhibit, is practically unrecognizable as
+being definitely animal or plant in respect of its nature. Later on,
+as we know, the egg or germ shows traces of structure in the case of
+the higher animals and plants; while even lowly forms of life exhibit
+more or less characteristic phases when they reach their adult stage.
+But, of life's beginnings, the microscope is as futile as a kind
+scientific touchstone for distinguishing animals from plants as is
+power of movement, or shape, or form.
+
+A fourth point of appeal in the matter is found within the domain of
+the chemist. Chemistry, with its subtile powers of analysis, with its
+many-sided possibilities of discovering the composition of things, and
+with its ability to analyze for us even the light of the far distant
+stars, only complicates the difficulties of the biologist. For, while
+of old it was assumed that a particular element, nitrogen, was
+peculiar to animals, and that carbon was an element peculiar to
+plants, we now know that both elements are found in animals, just as
+both occur in plants. The chemistry of living things, moreover, when
+it did grow to become a staple part of science, revealed other and
+greater anomalies than these. It showed that certain substances which
+were supposed to be peculiar to plants, and to be made and
+manufactured by them alone, were also found in animals. Chlorophyl is
+the green coloring matter of plants, and is, of course, a typical
+product of the vegetable world; yet it is made by such animals as the
+hydra of the brooks and ponds, and by many animalcules and some worms.
+Starch is surely a typical plant product, yet it is undoubtedly
+manufactured, or at least stored up, by animals--a work illustrated by
+the liver of man himself, which occasionally produces sugar out of its
+starch.
+
+Again, there is a substance called _cellulose_, found well nigh
+universally in plants. Of this substance, which is akin to starch, the
+walls or envelopes of the cells of plant tissues are composed. Yet we
+find those curious animals, the sea squirts, found on rocks and stones
+at low-water mark, manufacturing cellulose to form part and parcel of
+the outer covering of their sac-like bodies. Here it is as if the
+animal, like a dishonest manufacturer, had infringed the patent rights
+of the plant. On the fourth count, then--that of chemical
+composition--the verdict is that nothing that chemistry can teach us
+may serve definitely, clearly, and exactly to set a boundary line or
+to erect a partition wall between the two worlds of life. There yet
+remains for us to consider a fifth head--that of the food.
+
+In the matter of the feeding of the two great living worlds we might
+perchance light upon some adequate grounds for making up the one
+kingdom from the other. What the consideration of form, movement,
+chemical composition, and microscopic structure could not effect for
+us in this way, it might be supposed the investigation of the diet of
+animals and plants would render clear. Our hopes of distinguishing the
+one group from the other by reference to the food on which animals and
+plants subsist are, however, dashed to the ground; and the diet
+question leaves us, therefore, when it has been discussed, in the same
+quandary as before.
+
+Nevertheless, it is an interesting story, this of the nutrition of
+animals and plants. A large amount of scientific information is to be
+gleaned from such a study, which may very well be commenced by our
+having regard to the matters on which a _green_ plant feeds. I
+emphasize the word "green," because it so happens that when a plant
+has no chlorophyl (as green color is named in the plant world) its
+feeding is of diverse kind to that which a green plant exhibits. The
+mushroom or other fungus may be taken as an illustration of a plant
+which represents the non-green race, while every common plant, from a
+bit of grass to an oak tree, exemplifies the green-bearing order of
+the vegetable tribes.
+
+Suppose we were to invite a green plant to dinner, the _menu_ would
+have to be very differently arranged from that which would satisfy a
+human or other animal guest. The soup would be represented for the
+plant's delectation by water, the fish by minerals, the joint by
+carbonic acid gas, and the dessert by ammonia. On these four items a
+green plant feeds, out of them it builds up its living frame. Note
+that its diet is of inorganic or non-living matter. It derives its
+sustenance from soil and air, yet out of these lifeless matters the
+green plant elaborates and manufactures its living matter, or
+protoplasm. It is a more wonderful organism than the animal, for while
+the latter can only make new protoplasm when living matter is included
+in its food supply, the green plant, by the exercise of its vital
+chemistry, can transform that which is not living into that which is
+life-possessing.
+
+The green plant in other words, raises non-living into living matter,
+while the animal can only transform living matters into its like. This
+is why the plant is called a constructive organism, while the animal
+is, contrariwise, named a destructive one. The result of the plant's
+existence is to build up, that of the animal's life is to break down
+its substance, as the result of its work, into non-living matter. The
+animal's body is, in fact, breaking down into the very things on which
+the green plant feeds. We ourselves are perpetually dissipating our
+substance in our acts of life and work into the carbonic acid, water,
+ammonia, and minerals on which plants feed. We "die daily" in as true
+a sense as that in which the apostle used the term. And out of the
+debris of the animal frame the green plant builds up leaf and flower,
+stein and branch, and all the other tokens of its beauty and its life.
+
+If, then, an animal can only live upon living matter--that is to say
+on the bodies of other animals or of plants--with water, minerals and
+oxygen gas from the air thrown in to boot, we might be tempted to hold
+that in such distinctive ways and works we had at last found a means
+of separating animals from plants. Unfortunately, this view may be
+legitimately disputed and rendered null and void, on two grounds.
+First of all, the mushrooms and their friends and neighbors, all true
+plants, do not feed as do the green tribes. And secondly, many of the
+green plants themselves can be shown to have taken very kindly to an
+animal mode of diet.
+
+A mushroom, thus, because it has no green color, lives upon water,
+oxygen, minerals, and organic matter. You can only grow mushrooms
+where there is plenty of animal matter in a state of decay, and as for
+the oxygen, they habitually inhale that gas as if they were animals.
+Non-green plants thus want a most characteristic action of their green
+neighbors. For the latter in daylight take in the carbonic acid gas,
+which is composed of carbon and oxygen. Under the combined influence
+of the green color and the light, they split up the gas into its two
+elements, retaining the carbon for food and allowing the oxygen to
+escape to the atmosphere. Alas! however, in the dark our green plant
+becomes essentially like an animal as regards its gas food, for then
+it is an absorber of oxygen, while it gives off carbonic acid. If to
+take in carbonic acid and to give out oxygen be held to be a feature
+characteristic of a plant, it is one, as has been well said, which
+disappears with the daylight in green plants, and which is not
+witnessed at all in plants that have no green color.
+
+So far, we have seen that not even the food of plants and animals can
+separate the one kingdom of life from the other. The mushroom bars the
+way and the green plant's curious behavior by night and by day
+respectively, in the matter of its gas food, once more assimilates
+animal life and plant life in a remarkable manner. Still more
+interesting is the fact, already noticed, that even among the green
+tribes there are to be found many and various lapses from the stated
+rules of their feeding. Thus what are we to say of the parasitic
+mistletoe, which, while it has grown leaves of its own, and can,
+therefore, obtain so much carbon food from the air on its own account,
+nevertheless drinks up the sap of the oak or apple which forms its
+host, and thus illustrates the spectacle of a green plant feeding like
+an animal, on living matter? Or, what may we think of such plants as
+the sundew, the Venus' fly trap, the pitcher plants, the side saddle
+plants, the butterworts and bladderworts, and others of their kind,
+which not only capture insects, often by ingenious and complex lures,
+but also digest the animal food thus captured? A sundew thus spreads
+out its lure in the shape of its leaf studded with sensitive
+tentacles, each capped by a glistening drop of gummy secretion.
+Entangled in this secretion, the fly is further fixed to the leaf by
+the tentacles which bend over it and inclose it in their fold. Then is
+poured out upon the insect's body a digestive acid fluid, and the
+substance of the dissolved and digested animal is duly absorbed by the
+plant. So also the Venus' fly trap captures insects by means of its
+leaf, which closes upon the prey when certain sensitive hairs have
+given the signal that the animal has been trapped. Within the leaf the
+insect is duly digested as before, and its substance applied to the
+nutrition of the plant. Such plants, moreover, cannot flourish
+perfectly unless duly supplied with their animal food. Such
+illustrations of exceptions to the rule of green plant feeding simply
+have the effect of abolishing the distinctions which the diet question
+might be supposed to raise between animals and plants. We may return
+to the sundews and other insect catchers; meanwhile, I have said
+enough to show that to the question, "Can we separate animals from
+plants?" a very decided negative reply must be given. Life everywhere
+exhibits too many points of contact to admit of any boundary line
+being drawn between the two great groups which make up the sum total
+of organic existence.--_Illustrated London News._
+
+ * * * * *
+
+
+
+
+THE RECOVERY OF SILVER AND GOLD FROM PLATING AND GILDING SOLUTIONS.
+
+
+In view of the rapid development and extension of the methods of
+electro-plating with silver and gold, and of the large amount of spent
+liquors containing silver or gold thus produced, it has long been
+desirable to find methods by which these metals can be recovered from
+the spent liquors. The processes hitherto adopted generally
+necessitate the tedious and unpleasant evaporation of the cyanide
+liquors, or else involve a series of chemical operations which are
+somewhat difficult to carry out, so that actually the used-up baths
+are sold to some firm which undertakes this recovery as a particular
+branch of its business.
+
+A process invented by Stockmuir and Fleischmann, and worked out by
+them in the chemical laboratory of the Bavarian Industrial Museum, is,
+however, exceedingly simple, and is employed in many establishments.
+
+In order to remove silver from a potassium cyanide silver solution, it
+is only necessary to allow a clean piece of plate zinc to remain in
+the liquid for two days; even better results are obtained by the use
+of iron conjointly with the zinc. In the first case, the silver often
+adheres firmly to the zinc, while in the second it always separates
+out as a powder. It is then only necessary to wash the precipitated
+powder, which usually contains copper (since spent silver solutions
+always contain copper), dry it, and then dissolve it in hot
+concentrated sulphuric acid, water being added, and the dissolved
+silver precipitated by strips of copper. The silver thus obtained is
+perfectly pure. If the amount of copper present is only small, it can
+usually be removed by fusing the precipitated powder with a little
+niter and borax.
+
+In this way a spent silver bath was found to contain per liter
+
+ 1st experiment 1.5706 grms.
+ 2d " 1.5694 "
+ ------
+ Mean 1.5700 "
+
+The presence of silver could not be qualitatively ascertained in the
+residual liquor.
+
+Although sheet zinc, or zinc and iron sheets, serve so well for the
+precipitation of silver, they cannot be employed for the recovery of
+gold. The latter separates out in such a case very incompletely and as
+a firmly adhering lustrous film in the zinc. On the other hand, finely
+divided zinc, the so-called zinc dust, is an excellent substance to
+employ for precipitating gold quantitatively and in the form of powder
+from spent cyanide liquors. When zinc dust is added to a spent gold
+bath and the liquid periodically stirred or shaken, all the gold is
+precipitated in two or three days. The amount of zinc to be added
+naturally depends on the quantity of gold present. Freshly prepared
+gold baths for gilding in the cold contain on the average 3.5 grms.
+gold per liter, while those used for the hot process contain 10.75
+grms. To precipitate all the gold in the original bath, 1.74 grms. or
+0.37-0.5 grms. zinc dust would be necessary, and, of course, a much
+smaller quantity would be sufficient for the spent liquors. Since the
+precipitation takes place more rapidly when an excess of zinc dust is
+present, it is generally advisable to add 1/4 or at the most 1/2 kilo, of
+zinc dust to every 100 liters of solution.
+
+The precipitated gold, which contains zinc dust and usually silver and
+copper, is washed, freed from zinc by hydrochloric acid, and then from
+silver and copper by nitric acid and thus obtained pure.
+
+A spent bath treated in this way gave the following amounts of gold
+per liter:
+
+ 1st experiment 0.2626
+ 2d " 0.2634
+ Mean 0.2630 grms.
+
+The presence of gold in the residual cyanide solution could not be
+qualitatively detected. The potassium cyanide of the solutions
+obtained by this process should be converted into ferrocyanide by
+heating with ferrous sulphate and milk of lime, since this substance
+is not poisonous and can therefore be got rid of without danger. It
+would, however, be more economical and, considering the large amount
+of cyanide present, more profitable to work it up into Prussian blue.
+
+ * * * * *
+
+
+A NEW CATALOGUE OF VALUABLE PAPERS
+
+Contained in SCIENTIFIC AMERICAN SUPPLEMENT during the past ten years,
+sent _free of charge_ to any address. MUNN & CO., 361 Broadway, New
+York.
+
+ * * * * *
+
+
+THE SCIENTIFIC AMERICAN
+
+ARCHITECTS AND BUILDERS EDITION
+
+$2.50 A YEAR. SINGLE COPIES, 25 CTS.
+
+This is a Special Edition of the SCIENTIFIC AMERICAN, issued
+monthly--on the first day of the month. Each number contains about
+forty large quarto pages, equal to about two hundred ordinary book
+pages, forming, practically, a large and splendid Magazine of
+Architecture, richly adorned with _elegant platen in colors_ and with
+fine engravings, illustrating the most interesting examples of modern
+Architectural Construction and allied subjects.
+
+A special feature is the presentation in each number of a variety of
+the latest and best plans for private residences, city and country,
+including those of very moderate cost as well as the more expensive.
+Drawings in perspective and in color are given, together with full
+Plans, Specifications, Costs, Bills of Estimate, and Sheets of
+Details.
+
+No other building paper contains so many plans, details, and
+specifications regularly presented as the SCIENTIFIC AMERICAN.
+Hundreds of dwellings have already been erected on the various plans
+we have issued during the past year, and many others are in process of
+construction.
+
+Architects, Builders, and Owners will find this work valuable in
+furnishing fresh and useful suggestions. All who contemplate building
+or improving homes, or erecting structures of any kind, have before
+them in this work an almost _endless series of the latest and best
+examples_ from which to make selections, thus saving time and money.
+
+Many other subjects, including Sewerage, Piping, Lighting, Warming,
+Ventilating, Decorating, Laying out of Grounds, etc., are illustrated.
+An extensive Compendium of Manufacturers' Announcements is also given,
+in which the most reliable and approved Building Materials, Goods,
+Machines, Tools, and Appliances are described and illustrated, with
+addresses of the makers, etc.
+
+The fullness, richness, cheapness, and convenience of this work have
+won for it the Largest Circulation of any Architectural publication in
+the world.
+
+A Catalogue of valuable books on Architecture, Building, Carpentry,
+Masonry, Heating, Warming, Lighting, Ventilation, and all branches of
+industry pertaining to the art of Building, is supplied free of
+charge, sent to any address.
+
+MUNN & CO., Publishers,
+
+361 Broadway, New York.
+
+ * * * * *
+
+
+BUILDING PLANS AND SPECIFICATIONS.
+
+In connection with the publication of the BUILDING EDITION of the
+SCIENTIFIC AMERICAN, Messrs. Munn & Co. furnish plans and
+specifications for buildings of every kind, including Churches,
+Schools, Stores, Dwellings, Carriage Houses, Barns, etc.
+
+In this work they are assisted by able and experienced architects.
+Full plans, details, and specifications for the various buildings
+illustrated in this paper can be supplied.
+
+Those who contemplate building, or who wish to alter, improve, extend,
+or add to existing buildings, whether wings, porches, bay windows, or
+attic rooms, are invited to communicate with the undersigned. Our work
+extends to all parts of the country. Estimates, plans, and drawings
+promptly prepared. Terms moderate. Address
+
+MUNN & CO., 361 BROADWAY, NEW YORK.
+
+ * * * * *
+
+
+SCIENTIFIC AMERICAN SUPPLEMENT.
+
+PUBLISHED WEEKLY.
+
+Terms of Subscription, $5 a year.
+
+Sent by mail, postage prepaid, to subscribers in any part of the
+United States or Canada. Six dollars a year, sent, prepaid, to any
+foreign country.
+
+All the back numbers of THE SUPPLEMENT, from the commencement, January
+1, 1876, can be had. Price, 10 cents each.
+
+All the back volumes of THE SUPPLEMENT can likewise be supplied. Two
+volumes are issued yearly. Price of each volume, $2.50 stitched in
+paper, or $3.50 bound in stiff covers.
+
+COMBINED RATES.--One copy of SCIENTIFIC AMERICAN and one copy of
+SCIENTIFIC AMERICAN SUPPLEMENT, one year, postpaid, $7.00.
+
+A liberal discount to booksellers, news agents, and canvassers.
+
+MUNN & CO., Publishers,
+361 Broadway, New York, N.Y.
+
+ * * * * *
+
+
+USEFUL ENGINEERING BOOKS
+
+Manufacturers, Agriculturists, Chemists, Engineers, Mechanics,
+Builders, men of leisure, and professional men, of all classes, need
+good books in the line of their respective callings. Our post office
+department permits the transmission of books through the mails at very
+small cost. A comprehensive catalogue of useful books by different
+authors, on more than fifty different subjects, has recently been
+published, for free circulation, at the office of this paper. Subjects
+classified with names of author. Persons desiring a copy have only to
+ask for it, and it will be mailed to them. Address, MUNN & CO., 361
+Broadway, New York.
+
+ * * * * *
+
+
+PATENTS.
+
+In connection with the Scientific American, Messrs. MUNN & Co. are
+solicitors of American and Foreign Patents, have had 42 years'
+experience, and now have the largest establishment in the world.
+Patents are obtained on the best terms.
+
+A special notice is made in the Scientific American of all inventions
+patented through this Agency, with the name and residence of the
+Patentee. By the immense circulation thus given, public attention is
+directed to the merits of the new patent, and sales or introduction
+often easily effected.
+
+Any person who has made a new discovery or invention can ascertain,
+free of charge, whether a patent can probably be obtained, by writing
+to MUNN & Co. We also send free our Hand Book about the Patent Laws,
+Patents, Caveats, Trade Marks, their costs and how procured. Address
+
+MUNN & Co.,
+ 361 Broadway, New York.
+Branch Office, 622 and 624 F St., Washington, D.C.
+
+
+
+
+
+
+
+End of the Project Gutenberg EBook of Scientific American Supplement, No.
+787, January 31, 1891, by Various
+
+*** END OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN ***
+
+***** This file should be named 14009.txt or 14009.zip *****
+This and all associated files of various formats will be found in:
+ https://www.gutenberg.org/1/4/0/0/14009/
+
+Produced by Victoria Woosley, Don Kretz, Juliet Sutherland, Charles
+Franks and the PG Distributed Proofreading Team
+
+
+Updated editions will replace the previous one--the old editions
+will be renamed.
+
+Creating the works from public domain print editions means that no
+one owns a United States copyright in these works, so the Foundation
+(and you!) can copy and distribute it in the United States without
+permission and without paying copyright royalties. Special rules,
+set forth in the General Terms of Use part of this license, apply to
+copying and distributing Project Gutenberg-tm electronic works to
+protect the PROJECT GUTENBERG-tm concept and trademark. Project
+Gutenberg is a registered trademark, and may not be used if you
+charge for the eBooks, unless you receive specific permission. If you
+do not charge anything for copies of this eBook, complying with the
+rules is very easy. You may use this eBook for nearly any purpose
+such as creation of derivative works, reports, performances and
+research. They may be modified and printed and given away--you may do
+practically ANYTHING with public domain eBooks. Redistribution is
+subject to the trademark license, especially commercial
+redistribution.
+
+
+
+*** START: FULL LICENSE ***
+
+THE FULL PROJECT GUTENBERG LICENSE
+PLEASE READ THIS BEFORE YOU DISTRIBUTE OR USE THIS WORK
+
+To protect the Project Gutenberg-tm mission of promoting the free
+distribution of electronic works, by using or distributing this work
+(or any other work associated in any way with the phrase "Project
+Gutenberg"), you agree to comply with all the terms of the Full Project
+Gutenberg-tm License (available with this file or online at
+https://gutenberg.org/license).
+
+
+Section 1. General Terms of Use and Redistributing Project Gutenberg-tm
+electronic works
+
+1.A. By reading or using any part of this Project Gutenberg-tm
+electronic work, you indicate that you have read, understand, agree to
+and accept all the terms of this license and intellectual property
+(trademark/copyright) agreement. If you do not agree to abide by all
+the terms of this agreement, you must cease using and return or destroy
+all copies of Project Gutenberg-tm electronic works in your possession.
+If you paid a fee for obtaining a copy of or access to a Project
+Gutenberg-tm electronic work and you do not agree to be bound by the
+terms of this agreement, you may obtain a refund from the person or
+entity to whom you paid the fee as set forth in paragraph 1.E.8.
+
+1.B. "Project Gutenberg" is a registered trademark. It may only be
+used on or associated in any way with an electronic work by people who
+agree to be bound by the terms of this agreement. There are a few
+things that you can do with most Project Gutenberg-tm electronic works
+even without complying with the full terms of this agreement. See
+paragraph 1.C below. There are a lot of things you can do with Project
+Gutenberg-tm electronic works if you follow the terms of this agreement
+and help preserve free future access to Project Gutenberg-tm electronic
+works. See paragraph 1.E below.
+
+1.C. The Project Gutenberg Literary Archive Foundation ("the Foundation"
+or PGLAF), owns a compilation copyright in the collection of Project
+Gutenberg-tm electronic works. Nearly all the individual works in the
+collection are in the public domain in the United States. If an
+individual work is in the public domain in the United States and you are
+located in the United States, we do not claim a right to prevent you from
+copying, distributing, performing, displaying or creating derivative
+works based on the work as long as all references to Project Gutenberg
+are removed. Of course, we hope that you will support the Project
+Gutenberg-tm mission of promoting free access to electronic works by
+freely sharing Project Gutenberg-tm works in compliance with the terms of
+this agreement for keeping the Project Gutenberg-tm name associated with
+the work. You can easily comply with the terms of this agreement by
+keeping this work in the same format with its attached full Project
+Gutenberg-tm License when you share it without charge with others.
+
+1.D. The copyright laws of the place where you are located also govern
+what you can do with this work. Copyright laws in most countries are in
+a constant state of change. If you are outside the United States, check
+the laws of your country in addition to the terms of this agreement
+before downloading, copying, displaying, performing, distributing or
+creating derivative works based on this work or any other Project
+Gutenberg-tm work. The Foundation makes no representations concerning
+the copyright status of any work in any country outside the United
+States.
+
+1.E. Unless you have removed all references to Project Gutenberg:
+
+1.E.1. The following sentence, with active links to, or other immediate
+access to, the full Project Gutenberg-tm License must appear prominently
+whenever any copy of a Project Gutenberg-tm work (any work on which the
+phrase "Project Gutenberg" appears, or with which the phrase "Project
+Gutenberg" is associated) is accessed, displayed, performed, viewed,
+copied or distributed:
+
+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
+
+1.E.2. If an individual Project Gutenberg-tm electronic work is derived
+from the public domain (does not contain a notice indicating that it is
+posted with permission of the copyright holder), the work can be copied
+and distributed to anyone in the United States without paying any fees
+or charges. If you are redistributing or providing access to a work
+with the phrase "Project Gutenberg" associated with or appearing on the
+work, you must comply either with the requirements of paragraphs 1.E.1
+through 1.E.7 or obtain permission for the use of the work and the
+Project Gutenberg-tm trademark as set forth in paragraphs 1.E.8 or
+1.E.9.
+
+1.E.3. If an individual Project Gutenberg-tm electronic work is posted
+with the permission of the copyright holder, your use and distribution
+must comply with both paragraphs 1.E.1 through 1.E.7 and any additional
+terms imposed by the copyright holder. Additional terms will be linked
+to the Project Gutenberg-tm License for all works posted with the
+permission of the copyright holder found at the beginning of this work.
+
+1.E.4. Do not unlink or detach or remove the full Project Gutenberg-tm
+License terms from this work, or any files containing a part of this
+work or any other work associated with Project Gutenberg-tm.
+
+1.E.5. Do not copy, display, perform, distribute or redistribute this
+electronic work, or any part of this electronic work, without
+prominently displaying the sentence set forth in paragraph 1.E.1 with
+active links or immediate access to the full terms of the Project
+Gutenberg-tm License.
+
+1.E.6. You may convert to and distribute this work in any binary,
+compressed, marked up, nonproprietary or proprietary form, including any
+word processing or hypertext form. However, if you provide access to or
+distribute copies of a Project Gutenberg-tm work in a format other than
+"Plain Vanilla ASCII" or other format used in the official version
+posted on the official Project Gutenberg-tm web site (www.gutenberg.org),
+you must, at no additional cost, fee or expense to the user, provide a
+copy, a means of exporting a copy, or a means of obtaining a copy upon
+request, of the work in its original "Plain Vanilla ASCII" or other
+form. Any alternate format must include the full Project Gutenberg-tm
+License as specified in paragraph 1.E.1.
+
+1.E.7. Do not charge a fee for access to, viewing, displaying,
+performing, copying or distributing any Project Gutenberg-tm works
+unless you comply with paragraph 1.E.8 or 1.E.9.
+
+1.E.8. You may charge a reasonable fee for copies of or providing
+access to or distributing Project Gutenberg-tm electronic works provided
+that
+
+- You pay a royalty fee of 20% of the gross profits you derive from
+ the use of Project Gutenberg-tm works calculated using the method
+ you already use to calculate your applicable taxes. The fee is
+ owed to the owner of the Project Gutenberg-tm trademark, but he
+ has agreed to donate royalties under this paragraph to the
+ Project Gutenberg Literary Archive Foundation. Royalty payments
+ must be paid within 60 days following each date on which you
+ prepare (or are legally required to prepare) your periodic tax
+ returns. Royalty payments should be clearly marked as such and
+ sent to the Project Gutenberg Literary Archive Foundation at the
+ address specified in Section 4, "Information about donations to
+ the Project Gutenberg Literary Archive Foundation."
+
+- You provide a full refund of any money paid by a user who notifies
+ you in writing (or by e-mail) within 30 days of receipt that s/he
+ does not agree to the terms of the full Project Gutenberg-tm
+ License. You must require such a user to return or
+ destroy all copies of the works possessed in a physical medium
+ and discontinue all use of and all access to other copies of
+ Project Gutenberg-tm works.
+
+- You provide, in accordance with paragraph 1.F.3, a full refund of any
+ money paid for a work or a replacement copy, if a defect in the
+ electronic work is discovered and reported to you within 90 days
+ of receipt of the work.
+
+- You comply with all other terms of this agreement for free
+ distribution of Project Gutenberg-tm works.
+
+1.E.9. If you wish to charge a fee or distribute a Project Gutenberg-tm
+electronic work or group of works on different terms than are set
+forth in this agreement, you must obtain permission in writing from
+both the Project Gutenberg Literary Archive Foundation and Michael
+Hart, the owner of the Project Gutenberg-tm trademark. Contact the
+Foundation as set forth in Section 3 below.
+
+1.F.
+
+1.F.1. Project Gutenberg volunteers and employees expend considerable
+effort to identify, do copyright research on, transcribe and proofread
+public domain works in creating the Project Gutenberg-tm
+collection. Despite these efforts, Project Gutenberg-tm electronic
+works, and the medium on which they may be stored, may contain
+"Defects," such as, but not limited to, incomplete, inaccurate or
+corrupt data, transcription errors, a copyright or other intellectual
+property infringement, a defective or damaged disk or other medium, a
+computer virus, or computer codes that damage or cannot be read by
+your equipment.
+
+1.F.2. LIMITED WARRANTY, DISCLAIMER OF DAMAGES - Except for the "Right
+of Replacement or Refund" described in paragraph 1.F.3, the Project
+Gutenberg Literary Archive Foundation, the owner of the Project
+Gutenberg-tm trademark, and any other party distributing a Project
+Gutenberg-tm electronic work under this agreement, disclaim all
+liability to you for damages, costs and expenses, including legal
+fees. YOU AGREE THAT YOU HAVE NO REMEDIES FOR NEGLIGENCE, STRICT
+LIABILITY, BREACH OF WARRANTY OR BREACH OF CONTRACT EXCEPT THOSE
+PROVIDED IN PARAGRAPH F3. YOU AGREE THAT THE FOUNDATION, THE
+TRADEMARK OWNER, AND ANY DISTRIBUTOR UNDER THIS AGREEMENT WILL NOT BE
+LIABLE TO YOU FOR ACTUAL, DIRECT, INDIRECT, CONSEQUENTIAL, PUNITIVE OR
+INCIDENTAL DAMAGES EVEN IF YOU GIVE NOTICE OF THE POSSIBILITY OF SUCH
+DAMAGE.
+
+1.F.3. LIMITED RIGHT OF REPLACEMENT OR REFUND - If you discover a
+defect in this electronic work within 90 days of receiving it, you can
+receive a refund of the money (if any) you paid for it by sending a
+written explanation to the person you received the work from. If you
+received the work on a physical medium, you must return the medium with
+your written explanation. The person or entity that provided you with
+the defective work may elect to provide a replacement copy in lieu of a
+refund. If you received the work electronically, the person or entity
+providing it to you may choose to give you a second opportunity to
+receive the work electronically in lieu of a refund. If the second copy
+is also defective, you may demand a refund in writing without further
+opportunities to fix the problem.
+
+1.F.4. Except for the limited right of replacement or refund set forth
+in paragraph 1.F.3, this work is provided to you 'AS-IS' WITH NO OTHER
+WARRANTIES OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO
+WARRANTIES OF MERCHANTIBILITY OR FITNESS FOR ANY PURPOSE.
+
+1.F.5. Some states do not allow disclaimers of certain implied
+warranties or the exclusion or limitation of certain types of damages.
+If any disclaimer or limitation set forth in this agreement violates the
+law of the state applicable to this agreement, the agreement shall be
+interpreted to make the maximum disclaimer or limitation permitted by
+the applicable state law. The invalidity or unenforceability of any
+provision of this agreement shall not void the remaining provisions.
+
+1.F.6. INDEMNITY - You agree to indemnify and hold the Foundation, the
+trademark owner, any agent or employee of the Foundation, anyone
+providing copies of Project Gutenberg-tm electronic works in accordance
+with this agreement, and any volunteers associated with the production,
+promotion and distribution of Project Gutenberg-tm electronic works,
+harmless from all liability, costs and expenses, including legal fees,
+that arise directly or indirectly from any of the following which you do
+or cause to occur: (a) distribution of this or any Project Gutenberg-tm
+work, (b) alteration, modification, or additions or deletions to any
+Project Gutenberg-tm work, and (c) any Defect you cause.
+
+
+Section 2. Information about the Mission of Project Gutenberg-tm
+
+Project Gutenberg-tm is synonymous with the free distribution of
+electronic works in formats readable by the widest variety of computers
+including obsolete, old, middle-aged and new computers. It exists
+because of the efforts of hundreds of volunteers and donations from
+people in all walks of life.
+
+Volunteers and financial support to provide volunteers with the
+assistance they need, is critical to reaching Project Gutenberg-tm's
+goals and ensuring that the Project Gutenberg-tm collection will
+remain freely available for generations to come. In 2001, the Project
+Gutenberg Literary Archive Foundation was created to provide a secure
+and permanent future for Project Gutenberg-tm and future generations.
+To learn more about the Project Gutenberg Literary Archive Foundation
+and how your efforts and donations can help, see Sections 3 and 4
+and the Foundation web page at https://www.pglaf.org.
+
+
+Section 3. Information about the Project Gutenberg Literary Archive
+Foundation
+
+The Project Gutenberg Literary Archive Foundation is a non profit
+501(c)(3) educational corporation organized under the laws of the
+state of Mississippi and granted tax exempt status by the Internal
+Revenue Service. The Foundation's EIN or federal tax identification
+number is 64-6221541. Its 501(c)(3) letter is posted at
+https://pglaf.org/fundraising. Contributions to the Project Gutenberg
+Literary Archive Foundation are tax deductible to the full extent
+permitted by U.S. federal laws and your state's laws.
+
+The Foundation's principal office is located at 4557 Melan Dr. S.
+Fairbanks, AK, 99712., but its volunteers and employees are scattered
+throughout numerous locations. Its business office is located at
+809 North 1500 West, Salt Lake City, UT 84116, (801) 596-1887, email
+business@pglaf.org. Email contact links and up to date contact
+information can be found at the Foundation's web site and official
+page at https://pglaf.org
+
+For additional contact information:
+ Dr. Gregory B. Newby
+ Chief Executive and Director
+ gbnewby@pglaf.org
+
+
+Section 4. Information about Donations to the Project Gutenberg
+Literary Archive Foundation
+
+Project Gutenberg-tm depends upon and cannot survive without wide
+spread public support and donations to carry out its mission of
+increasing the number of public domain and licensed works that can be
+freely distributed in machine readable form accessible by the widest
+array of equipment including outdated equipment. Many small donations
+($1 to $5,000) are particularly important to maintaining tax exempt
+status with the IRS.
+
+The Foundation is committed to complying with the laws regulating
+charities and charitable donations in all 50 states of the United
+States. Compliance requirements are not uniform and it takes a
+considerable effort, much paperwork and many fees to meet and keep up
+with these requirements. We do not solicit donations in locations
+where we have not received written confirmation of compliance. To
+SEND DONATIONS or determine the status of compliance for any
+particular state visit https://pglaf.org
+
+While we cannot and do not solicit contributions from states where we
+have not met the solicitation requirements, we know of no prohibition
+against accepting unsolicited donations from donors in such states who
+approach us with offers to donate.
+
+International donations are gratefully accepted, but we cannot make
+any statements concerning tax treatment of donations received from
+outside the United States. U.S. laws alone swamp our small staff.
+
+Please check the Project Gutenberg Web pages for current donation
+methods and addresses. Donations are accepted in a number of other
+ways including including checks, online payments and credit card
+donations. To donate, please visit: https://pglaf.org/donate
+
+
+Section 5. General Information About Project Gutenberg-tm electronic
+works.
+
+Professor Michael S. Hart was the originator of the Project Gutenberg-tm
+concept of a library of electronic works that could be freely shared
+with anyone. For thirty years, he produced and distributed Project
+Gutenberg-tm eBooks with only a loose network of volunteer support.
+
+
+Project Gutenberg-tm eBooks are often created from several printed
+editions, all of which are confirmed as Public Domain in the U.S.
+unless a copyright notice is included. Thus, we do not necessarily
+keep eBooks in compliance with any particular paper edition.
+
+
+Most people start at our Web site which has the main PG search facility:
+
+ https://www.gutenberg.org
+
+This Web site includes information about Project Gutenberg-tm,
+including how to make donations to the Project Gutenberg Literary
+Archive Foundation, how to help produce our new eBooks, and how to
+subscribe to our email newsletter to hear about new eBooks.
generated by cgit v1.2.3 (git 2.25.1) at 2026-05-24 17:51:45 +0000