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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. 446, July 19, 1884 + +Author: Various + +Release Date: March 1, 2004 [EBook #11385] + +Language: English + +Character set encoding: ISO-8859-1 + +*** START OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN SUPP. 446 *** + + + + +Produced by Jon Niehof, Don Kretz, Juliet Sutherland, Charles Franks +and the DP Team + + + + + + +</pre> + +<p class="ctr"><a href="./illustrations/1a.png"><img src= +"./illustrations/1a_th.jpg" alt=""></a></p> + +<h1>SCIENTIFIC AMERICAN SUPPLEMENT NO. 446</h1> + +<h2>NEW YORK, JULY 19, 1884</h2> + +<h4>Scientific American Supplement. Vol. XVIII, No. 446.</h4> + +<h4>Scientific American established 1845</h4> + +<h4>Scientific American Supplement, $5 a year.</h4> + +<h4>Scientific American and Supplement, $7 a year.</h4> + +<hr> +<table summary="Contents" border="0" cellspacing="5"> +<tr> +<th colspan="2">TABLE OF CONTENTS</th> +</tr> + +<tr> +<td valign="top">I.</td> +<td><a href="#1">CHEMISTRY.--Tin in Canned Foods.--By Prof. +ATTFIELU.--Small amount of tin found.--Whence come these small +particles.--No cause for alarm.</a></td> +</tr> + +<tr> +<td valign="top">II.</td> +<td><a href="#2">ENGINEERING AND MECHANICS.--The Windmill.--By +JAMES W. HILL.--The Eclipse wind.--Other wind mills.--Their +operation, use, etc.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#3">The Pneumatic Dynamite Gun.--With engraving of +pneumatic dynamite gun torpedo vessel.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#4">Rope Pulley Friction Brake.--3 figures.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#5">Wire Rope Towage.--Treating of the system of +towage by hauling in a submerged wire rope as used on the River +Rhine, boats employed, etc.--With engraving of wire rope tug +boat.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#6">Improved Hay Rope Machine.--With +engraving.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#7">The Anglesea Bridge, Cork.--With +engraving.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#8">Portable Railways.--By M DECAUVILLE.--Narrow gauge +roads in Great Britain.--M. Decauvilie's system.--Railways used at +the Panama Canal, in Tunis, etc.</a></td> +</tr> + +<tr> +<td valign="top">III.</td> +<td><a href="#9">TECHNOLOGY.--Improved Pneumatic Filtering Presses, +and the Processes in which they are employed.--2 +engravings.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#10">Pneumatic Malting.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#11">A New Form of Gas Washer.--Manner in which it is +used.--By A. BANDSEPT.--2 figures.</a></td> +</tr> + +<tr> +<td valign="top">IV.</td> +<td><a href="#12">ELECTRICITY, HEAT, ETC.--Gerard's Alternating +Current Machine.--2 engravings.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#13">Automatic Fast Speed Telegraphy.--By THEO. F. +TAYLOR.--Speed determined by resistance and static +capacity.--Experiments Taylor's system.--With diagram.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#14">Theory of the Action of the Carbon +Microphone.--What is it? --2 figures.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#15">The Dembinski Telephone Transmitter.--3 +figures.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#16">New Gas Lighters.--Electric lighters.--3 +engravings.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#17">Distribution of Heat which is developed by +Forging.</a></td> +</tr> + +<tr> +<td valign="top">V.</td> +<td><a href="#18">ARCHITECTURE, ART. ETC.--Villa at Dorking.--An +engraving.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#19">Arm Chair in the Louvre Collection.</a></td> +</tr> + +<tr> +<td valign="top">VI.</td> +<td><a href="#20">GEOLOGY.--The Deposition of Ores.--By J.S. +NEWBERRY.--Mineral Veins.--Bedded veins.--Theories of ore +deposit.--Leaching of igneous rocks.</a></td> +</tr> + +<tr> +<td valign="top">VII.</td> +<td><a href="#21">NATURAL HISTORY, ETC.--Habits of Burrowing +Crayfishes in the U.S.--Form and size of the burrows and +mounds.--Obtaining food.--Other species of crayfish.--3 +figures.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#22">Our Servants, the Microbes.--What is a +microbe?--Multiplication. --Formation of spores.--How they +live.--Different groups of bacteria.--Their services.</a></td> +</tr> + +<tr> +<td valign="top">VIII.</td> +<td><a href="#23">HORTICULTURE.--A New Stove +Climber.--<i>(Ipomæa thomsoniana)</i></a></td> +</tr> + +<tr> +<td></td> +<td><a href="#24">Sprouting of Palm Seeds.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#25">History of Wheat.</a></td> +</tr> + +<tr> +<td valign="top">IX.</td> +<td><a href="#26">MISCELLANEOUS.--Technical Education in +America.--Branches of study most prominent in schools of different +States.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#27">The Anæsthetics of Jugglers.--Fakirs of the +Indies.--Processes employed by them.--Anæsthetic +plants.</a></td> +</tr> + +<tr> +<td></td> +<td><a href="#28">Epitaphium Chymicum.--An epitaph written by Dr. +GODFREY.</a></td> +</tr> +</table> + +<hr> +<p><a name="9"></a></p> + +<h2>IMPROVED FILTER PRESSES.</h2> + +<p>Hitherto it has been found that of all the appliances and +methods for separating the liquid from the solid matters, whether +it is in the case of effluents from tanneries and other +manufactories, or the ocherous and muddy sludges taken from the +settling tanks in mines, some of which contain from 90 to 95 per +cent. of water, the filter press is the best and the most +economical, and it is to this particular process that Messrs. +Johnson's exhibits at the Health Exhibition, London, chiefly +relate. Our engravings are from <i>The Engineer</i>. A filter press +consists of a number of narrow cells of cast iron, shown in Figs. 3 +and 4, held together in a suitable frame, the interior frames being +provided with drainage surfaces communicating with outlets at the +bottom, and covered with a filtering medium, which is generally +cloth or paper. The interior of the cells so built up are in direct +communication with each other, or with a common channel for the +introduction of the matter to be filtered, and as the only exit is +through the cloth or paper, the solid portion is kept back while +the liquid passes through and escapes by the drainage surfaces to +the outlets. The cells are subjected to pressure, which increases +as the operation goes on, from the growing resistance offered by +the increasing deposit of solid matter on the cloths; and it is +therefore necessary that they should be provided with a jointing +strip around the outside, and be pressed together sufficiently to +prevent any escape of liquid. In ordinary working both sides of the +cell are exposed to the same pressure, but in some cases the feed +passages become choked, and destroy the equilibrium. This, in the +earlier machines, gave rise to considerable annoyance, as the +diaphragms, being thin, readily collapsed at even moderate +pressures; but recently all trouble on this head has been obviated +by introducing the three projections near the center, as shown in +the cuts, which bear upon each other and form a series of stays +from one end of the cells to the other, supporting the plates until +the obstruction is forced away. We give an illustration below +showing the arrangement of a pair of filter presses with pneumatic +pressure apparatus, which has been successfully applied for dealing +with sludge containing a large amount of fibrous matter and +rubbish, which could not be conveniently treated with by pumps in +the ordinary way. The sludge is allowed to gravitate into wrought +iron receivers placed below the floor, and of sufficient size to +receive one charge. From these vessels it is forced into the +presses by means of air compressed to from 100 lb. to 120 lb. per +square inch, the air being supplied by the horizontal pump shown in +the engraving. The press is thus almost instantaneously filled, and +the whole operation is completed in about an hour, the result being +a hard pressed cake containing about 45 per cent. of water, which +can be easily handled and disposed of as required. The same +arrangement is in use for dealing with sewage sludge, and the +advantages of the compressed air system over the ordinary pumps, as +well as the ready and cleanly method of separating the liquid, will +probably commend itself to many of our readers. We understand that +from careful experiments on a large scale, extending over a period +of two years, the cost of filtration, including all expenses, has +been found to be not more than about 6d. per ton of wet sludge. A +number of specimens of waste liquors from factories with the +residual matters pressed into cakes, and also of the purified +effluents, are exhibited. These will prove of interest to many, all +the more so since in some instances the waste products are +converted into materials of value, which, it is stated, will more +than repay for the outlay incurred.</p> + +<p class="ctr"><img src="./illustrations/1b.png" alt= +"Fig. 3. Fig 4."></p> + +<p class="ctr">Fig. 3. Fig 4.</p> + +<p>Another application of the filter press is in the Porter-Clark +process of softening water, which is shown in operation. We may +briefly state that the chief object is to precipitate the +bicarbonates of lime and magnesia held in solution by the water, +and so get rid of what is known as the temporary hardness. To +accomplish this, strong lime water is introduced in a clear state +to the water to be softened, the quantity being regulated according +to the amount of bicarbonates in solution. The immediate effect of +this is that a proportion of the carbonic acid of the latter +combines with the invisible lime of the clear lime water, forming a +chalky precipitate, while the loss of this proportion of carbonic +acid also reduces the invisible bicarbonates into visible +carbonates. The precipitates thus formed are in the state of an +impalpable powder, and in the original Clark process many hours +were required for their subsidence in large settling tanks, which +had to be in duplicate in order to permit of continuous working. By +Mr. Porter's process, however, this is obviated by the use of +filter presses, through which the chalky water is passed, the +precipitate being left behind, while, by means of a special +arrangement of cells, the softened and purified water is discharged +under pressure to the service tanks. Large quantities can thus be +dealt with, within small space, and in many cases no pumping is +required, as the resistance of the filtering medium being small, +the ordinary pressure in the main is but little reduced. One of the +apparatus exhibited is designed for use in private mansions, and +will soften and filter 750 gallons a day. In such a case, where it +would probably be inconvenient to apply the usual agitating +machinery, special arrangements have been made by which all the +milk of lime for a day's working is made at one time in a special +vessel agitated by hand, on the evening previous to the day on +which it is to be used. Time is thus given for the particles of +lime to settle during the night. The clear lime water is introduced +into the mixing vessel by means of a charge of air compressed in +the top of a receiver, by the action of water from the main, the +air being admitted to the milk of lime vessel through a suitable +regulating valve. A very small filter suffices for removing the +precipitate, and the clear, softened water can either be used at +once, or stored in the usual way. The advantages which would accrue +to the community at large from the general adoption of some cheap +method of reducing the hardness of water are too well known to need +much comment from us.</p> + +<hr> +<p><a name="10"></a></p> + +<h2>PNEUMATIC MALTING.</h2> + +<p>According to K. Lintner, the worst features of the present +system of malting are the inequalities of water and temperature in +the heaps and the irregular supplies of oxygen to, and removal of +carbonic acid from, the germinating grain. The importance of the +last two points is demonstrated by the facts that, when oxygen is +cut off, alcoholic fermentation--giving rise to the well-known odor +of apples--sets in in the cells, and that in an atmosphere with 20 +per cent. of carbonic acid, germination ceases. The open pneumatic +system, which consists in drawing warm air through the heaps spread +on a perforated floor, should yield better results. All the +processes are thoroughly controlled by the eye and by the +thermometer, great cleanliness is possible, and the space requisite +is only one-third of that required on the old plan. Since May, +1882, this method has been successfully worked at Puntigam, where +plant has been established sufficient for an annual output of 7,000 +qrs. of malt. The closed pneumatic system labors under the +disadvantages that from the form of the apparatus germination +cannot be thoroughly controlled, and cleanliness is very difficult +to maintain, while the supply of oxygen is, as a rule, more +irregular than with the open floors.</p> + +<p class="ctr"><a href="./illustrations/1c.png"><img src= +"./illustrations/1c_th.jpg" alt= +"IMPROVED PNEUMATIC FILTERING PRESSES."></a></p> + +<p class="ctr">IMPROVED PNEUMATIC FILTERING PRESSES.</p> + +<hr> +<p><a name="11"></a></p> + +<h2>A NEW FORM OF GAS WASHER.</h2> + +<h3>By A. BANDSEPT, of Brussels.</h3> + +<p>The washer is an appliance intended to condense and clean gas, +which, on leaving the hydraulic main, holds in suspension a great +many properties that are injurious to its illuminating power, and +cannot, if retained, be turned to profitable account. This cleaning +process is not difficult to carry out effectually; and most of the +appliances invented for the purpose would be highly efficacious if +they did not in other respects present certain very serious +inconveniences. The passage of the gas through a column of cold +water is, of course, sufficient to condense it, and clear it of +these injurious properties; but this operation has for its +immediate effect the presentation of an obstacle to the flow of the +gas, and consequently augmentation of pressure in the retorts. In +order to obviate this inconvenience (which exists notwithstanding +the use of the best washers), exhausters are employed to draw the +gas from the retorts and force it into the washers. There is, +however, another inconvenience which can only be remedied by the +use of a second exhauster, viz., the loss of pressure after the +passage of the gas through the washer--a loss resulting from the +obstacle presented by this appliance to the steady flow of the gas. +Now as, in the course of its passage through the remaining +apparatus, on its way to the holder, the gas will have to suffer a +considerable loss of pressure, it is of the greatest importance +that the washer should deprive it of as little as possible. It will +be obvious, therefore, that a washer which fulfills the best +conditions as far as regards the cleaning of the gas will be +absolutely perfect if it does not present any impediment to its +flow. Such an appliance is that which is shown in the illustration +on next page. Its object is, while allowing for the washing being +as vigorous and as long-continued as may be desired, to draw the +gas out of the retorts, and, having cleansed it perfectly from its +deleterious properties, to force it onward. The apparatus +consequently supplies the place of the exhauster and the +scrubber.</p> + +<p>The new washer consists of a rectangular box of cast iron, +having a half-cylindrical cover, in the upper part of which is +fixed a pipe to carry off the gas. In the box there is placed +horizontally a turbine, the hollow axis of which serves for the +conveyance of the gas into the vessel. For this purpose the axis is +perforated with a number of small holes, some of which are tapped, +so as to allow of there being screwed on to the axis, and +perpendicularly thereto, a series of brooms made of dog grass, and +having their handles threaded for the purpose. These brooms are +arranged in such a way as not to encounter too great resistance +from contact with the water contained in the vessel, and so that +the water cast up by them shall not be all thrown in the same +direction. To obviate these inconveniences they are fixed obliquely +to the axis of the central pipe, and are differently arranged in +regard to each other. A more symmetrical disposition of them could, +however, be adopted by placing them zigzag, or in such a way as to +form two helices, one of which would move in a particular +direction, and the other in a different way. The central pipe, +furnished with its brooms, being set in motion by means of a pulley +fixed upon its axis (which also carries a flywheel), the gas, drawn +in at the center, and escaping by the holes made in the pipe, is +forced to the circumference of the vessel, where it passes out.</p> + +<p>The effect of this washer is first, to break up the current of +gas, and then force it violently into the water; at the same time +sending into it the spray of water thrown up by the brooms. This +double operation is constantly going on, so that the gas, having +been saturated by the transfusion into it of a vigorous shower of +water (into the bulk of which it is subsequently immersed), is +forced, on leaving the water, to again undergo similar treatment. +The same quantity of gas is therefore several times submitted to +the washing process, till at length it finds its way to the outlet, +and makes its escape. The extent to which the washing of the gas is +carried is, consequently, only limited by the speed of the +apparatus, or rather by the ratio of the speed to the initial +pressure of the gas. This limit being determined, the operation may +be continued indefinitely, by making the gas pass into several +washers in succession. There is, therefore, no reason why the gas +should not, after undergoing this treatment, be absolutely freed of +all those properties which are susceptible of removal by water. In +fact, all that is requisite is to increase the dimensions of the +vessel, so as to compel the gas to remain longer therein, and thus +cause it to undergo more frequently the operation of washing. These +dimensions being fixed within reasonable limits, if the gas is not +sufficiently washed, the speed of the apparatus may be increased; +and the degree of washing will be thereby augmented. If this does +not suffice, the number of turbines may be increased, and the gas +passed from one to the other until the gas is perfectly clean. This +series of operations would, however, with any kind of washer, +result in thoroughly cleansing the gas. The only thing that makes +such a process practically impossible is the very considerable or +it may be even total loss of pressure which it entails. By the new +system, the loss of pressure is <i>nil</i>, inasmuch as each +turbine becomes in reality an exhauster. The gas, entering the +washer at the axis, is drawn to the circumference by the rotatory +motion of the brooms, which thus form a ventilator. It follows, +therefore, that on leaving the vessel the gas will have a greater +pressure than it had on entering it; and this increase of pressure +may be augmented to any desired extent by altering the speed of +rotation of the axis, precisely as in the case of an exhauster.</p> + +<p>Forcing the gas violently into water, and at the same time +dividing the current, is evidently the most simple, rational, and +efficient method of washing, especially when this operation is +effected by brooms fixed on a shaft and rotated with great speed. +Therefore, if there had not been this loss of pressure to deal +with--a fatal consequence of every violent operation--the question +of perfect washing would probably have been solved long ago. The +invention which I have now submitted consists of an arrangement +which enables all loss of pressure to be avoided, inasmuch as it +furnishes the apparatus with the greatest number of valuable +qualities, whether regarded from the point of view of washing or +that of condensation.</p> + +<p class="ctr"><img src="./illustrations/2a.png" alt= +"Longitudinal Section. Elevation. Transverse Section."></p> + +<p class="ctr">Longitudinal Section. Elevation. Transverse +Section.</p> + +<p>Referring to the illustration, the gas enters the washer by the +pipe, A, which terminates in the form of a [Symbol: inverted T]. +One end (a) of this pipe is bolted to the center of one of the +sides of the cylindrical portion of the case, in which there is a +hole of similar diameter to the pipe; the other (a') being formed +by the face-plate of a stuffing-box, B, through which passes the +central shaft, C, supported by the plummer-block, D, as shown. This +shaft has upon its opposite end a plate perforated with holes, E, +which is fixed upon the flange of a horizontal pipe, F. This pipe +is closed at the other end by means of a plate, E', furnished with +a spindle, supported by a stuffing-box, B', and carrying a +fly-wheel, G. The central pipe, F, is perforated with a number of +small holes. The gas entering by the pipe, A, makes its way into +the central pipe through the openings in the plate, E, and passes +into the cylindrical case through the small holes in the central +pipe, which carries the brooms, H. These are caused to rotate +rapidly by means of the pulley, I; and thus a constant shower of +water is projected into the cylindrical case. When the gas has been +several times subjected to the washing process, it passes off by +the pipe, K. Fresh cold water is supplied to the vessel by the +pipe, L; and M is the outlet for the tar.--<i>Journal of Gas +Lighting</i>.</p> + +<hr> +<p><a name="2"></a></p> + +<h2>THE WIND MILL.</h2> + +<p>[Footnote: A paper read before the Engineers' Club of St. Louis, +1884.]</p> + +<h3>By JAMES W. HILL.</h3> + +<p>In the history of the world the utilization of the wind as a +motive power antedates the use of both water and steam for the same +purpose.</p> + +<p>The advent of steam caused a cessation in the progress of wind +power, and it was comparatively neglected for many years. But more +recently attention has been again drawn to it, with the result of +developing improvements, so that it is now utilized in many +ways.</p> + +<p>The need in the West of a motive power where water power is rare +and fuel expensive has done much to develop and perfect wind +mills.</p> + +<p>Wind mills, as at present constructed in this country, are of +recent date.</p> + +<p>The mill known as the "Eclipse" was the first mill of its class +built. It is known as the "solid-wheel, self-regulating pattern," +and was invented about seventeen years ago. The wind wheel is of +the rosette type, built without any joints, which gives it the name +"solid wheel," in contradistinction to wheels made with loose +sections or fans hinged to the arms or spokes, and known as +"section wheel mills."</p> + +<p>The regulation of the Eclipse mill is accomplished by the use of +a small adjustable side vane, flexible or hinged rudder vane, and +weighted lever, as shown in Plate 1 (on the larger sizes of mills +iron balls attached to a chain are used in place of the weighted +lever). The side vane and weight on lever being adjustable, can be +set to run the mill at any desired speed.</p> + +<p>Now you will observe from the model that the action of the +governing mechanism is automatic. As the velocity of the wind +increases, the pressure on the side vane tends to carry the wind +wheel around edgewise to the wind and parallel to the rudder vane, +thereby changing the angle and reducing the area exposed to the +wind; at the same time the lever, with adjustable weight attached, +swings from a vertical toward a horizontal position, the resistance +increasing as it moves toward the latter position. This acts as a +counterbalance of varying resistance against the pressure of the +wind on the side vane, and holds the mill at an angle to the plane +of the wind, insuring thereby the number of revolutions per minute +required, according to the position to which the governing +mechanism has been set or adjusted.</p> + +<p>If the velocity of the wind is such that the pressure on the +side vane overcomes the resistance of the counter weight, then the +side vane is carried around parallel with the rudder vane, +presenting only the edge of the wind wheel or ends of the fans to +the wind, when the mill stops running.</p> + +<p>This type of mill presents more effective wind receiving or +working surface when in the wind, and less surface exposed to +storms when out of the wind, than any other type of mill. It is at +all times under the control of an operator on the ground.</p> + +<p>A 22-foot Eclipse mill presents 352 square feet of wind +receiving and working surface in the wind, and only 9½ +square feet of wind resisting surface when out of the wind.</p> + +<p>Solid-wheel mills are superseding all others in this country, +and are being exported largely to all parts of the world, in sizes +from 10 to 30 feet in diameter. Many of these mills have withstood +storms without injury, where substantial buildings in the immediate +vicinity have been badly damaged. I will refer to some results +accomplished with pumping mills:</p> + +<p>In the spring of 1881 there was erected for Arkansas City, +Kansas, a 14-foot diameter pumping wind mill; a 32,000-gallon water +tank, resting on a stone substructure 15 feet high, the ground on +which it stands being 4 feet higher than the main street of the +town. One thousand four hundred feet of 4-inch wood pipe was used +for mains, with 1,200 feet of 1½-inch wrought iron pipe. +Three 3-inch fire hydrants were placed on the main street. The wind +mill was located 1,100 feet from the tank, and forced the water +this distance, elevating it 50 feet. We estimate that this mill is +pumping from 18,000 to 20,000 gallons of water every twenty-four +hours. We learned that these works have saved two buildings from +burning, and that the water is being used for sprinkling the +streets, and being furnished to consumers at the following rates +per annum: Private houses, $5; stores, $5; hotels, $10; livery +stables, $15. At these very low rates, the city has an income of +$300 per annum. The approximate cost of the works was $2,000. This +gives 15 per cent. interest on the investment, not deducting +anything for repairs or maintenance, which has not cost $5 per +annum so far.</p> + +<p class="ctr"><a href="./illustrations/2b.png"><img src= +"./illustrations/2b_th.jpg" alt="Plate 2. THE ECLIPSE WIND MILL."> +</a></p> + +<p class="ctr">Plate 2. THE ECLIPSE WIND MILL.</p> + +<p>In June, 1883, a wind water works system was erected for the +city of McPherson, Kansas, consisting of a 22-foot diameter wind +mill on a 75-foot tower, which pumps the water out of a well 80 +feet deep, and delivers it into a 60,000-gallon tank resting on a +substructure 43 feet above the ground. Sixteen hundred feet of +6-inch and 300 feet of 4-inch cast iron pipe furnish the means of +distribution; eight 2½-inch double discharge fire hydrants +were located on the principal streets. A gate valve was placed in +the 6-inch main close to the elbow on lower end of the down pipe +from the tank. This pipe is attached to the bottom of the tank; +another pipe was run up through the bottom of tank 9 feet (the tank +being 18 feet deep), and carried down to a connection with the main +pipe just outside the gate valve. The operation of this arrangement +is as follows:</p> + +<p>The gate valve being closed, the water cannot be drawn below the +9-foot level in tank, which leaves about 35,000 gallons in store +for fire protection, and is at once available by opening the gate +valve referred to. The tank rests on ground about 5 feet above the +main streets, which gives a head of 57 feet when the tank is half +full. The distance from tank to the farthest hydrant being so +short, they get the pressure due to this head at the hydrant, when +playing 2-inch, or 1-1/8-inch streams, with short lines of +2½-inch hose; this gives fair fire streams for a town with +few if any buildings over two stories high. It is estimated that +this mill is pumping from 30,000 to 38,000 gallons on an average +every twenty-four hours. There is an automatic device attached to +this mill, which stops it when the tank is full, but as soon as the +water in the tank is lowered, it goes to pumping again. The cost of +these works complete to the city was a trifle over $6,000.</p> + +<p>In November last a wind mill 18 feet in diameter was erected +over a coal mine at Richmond, in this State. The conditions were as +follows:</p> + +<p>The mine produces 11,000 gallons of water every twenty-four +hours. The sump holds 11,000 gallons. Two entries that can be +dammed up give a storage of 16,500 gallons, making a total storage +capacity of 27,500 gallons. It takes sixty hours for the mine to +produce this quantity of water, which allows for days that the wind +does not blow. The average elevation that the water has to be +raised is 65 feet, measuring from center of sump to point of +delivery. A record of ninety days shows that this mill has kept the +mine free from water with the exception of 6,000 gallons, which was +raised in the boxes that the coal is raised in. The location is not +good for a wind mill, as it stands in a narrow ravine or valley a +short distance from its mouth, which terminates at the bottom lands +of the Missouri River. This, taken in connection with the fact that +the grit in the water cuts the pump plunger packing so fast that in +a short time the pump will not work up to its capacity, accounts +for the apparent small amount of power developed by this mill.</p> + +<p>There has been some discussion of late in regard to the horse +power of wind mills, one party claiming that they were capable of +doing large amounts of grinding and showing a development of power +that was surprising to the average person unacquainted with wind +mills, while the other party has maintained that they were not +capable of developing any great amount of power, and has cited +their performance in pumping water to sustain his argument. My +experience has has led me to the conclusion that pumping water with +a wind mill is not a fair test of the power that it is capable of +developing, for the following reasons:</p> + +<p>A pumping wind mill is ordinarily attached to a pump of suitable +size to allow the mill to run at a mean speed in an 8 to 10 mile +wind. Now, if the wind increases to a velocity of 16 to 20 miles +per hour, the mill will run up to its maximum speed and the +governor will begin to act, shortening sail before the wind attains +this velocity. Therefore, by a very liberal estimate, the pump will +not throw more than double the quantity that it did in the 8 to 10 +mile wind, while the power of the mill has quadrupled, and is +capable of running at least two pumps as large as the one to which +it is attached. As the velocity of the wind increases, this same +proportion of difference in power developed to work done holds +good.</p> + +<p>St. Louis is not considered a very windy place, therefore the +following table may be a surprise to some. This table was compiled +from the complete record of the year 1881, as recorded by the +anemometer of the United States Signal Office on the Mutual Life +Insurance Building, corner of Sixth and Locust streets, this city. +It gives the number of hours each month that the wind blew at each +velocity, from 6 to 20 miles per hour during the year; also the +maximum velocity attained each month.</p> + +<p><i>Complete Wind Record at St. Louis for the Year 1881.</i></p> + +<pre> +_______________________________________________________________________________ + |No. |No. |No. |No. |No. |No. |No. |No. | + |hours |hours |hours |hours |hours |hours |hours |hours |Maximum + |wind |wind |wind |wind |wind |wind |wind |wind |velocity +YEAR |blew 6 |blew 8 |blew 10|blew 12|blew 14|blew 16|blew 18|blew 20|during +1881. |miles |miles |miles |miles |miles |miles |miles |miles |each +MONTHS|or over|or over|or over|or over|or over|or over|or over|or over|month. +______|_______|_______|_______|_______|_______|_______|_______|_______|____ + |H. M.|H. M.|H. M.|H. M.|H. M.|H. M.| H. M.| H. M.| +Jan. | 545 45| 429 45| 289 00| 198 15| 131 30| 87 15| 56 00| 38 45| 31 +Feb. | 619 30| 533 15| 449 15| 374 15| 287 00| 207 15| 151 15| 110 30| 32 +March.| 604 15| 534 30| 449 45| 368 45| 296 30| 243 45| 191 00| 158 45| 37 +April.| 577 15| 468 45| 342 45| 359 30| 175 00| 121 00| 62 45| 36 00| 28 +May. | 553 00| 375 00| 226 15| 138 00| 74 45| 42 30| 23 45| 11 30| 31 +June. | 614 15| 463 45| 303 30| 215 15| 123 45| 76 30| 29 45| 17 45| 32 +July. | 556 45| 378 00| 228 15| 136 15| 55 30| 22 30| 6 00| 2 30| 22 +Aug. | 536 30| 345 00| 176 00| 80 30| 35 45| 22 15| 17 15| 15 00| 34 +Sept. | 564 15| 445 45| 326 45| 224 45| 145 30| 96 45| 70 00| 46 45| 30 +Oct. | 617 30| 501 45| 368 45| 363 00| 170 00| 93 45| 40 30| 27 45| 27 +Nov. | 642 45| 537 30| 428 45| 328 30| 226 00| 151 45| 100 30| 74 00| 30 +Dec. | 592 15| 516 30| 390 00| 308 45| 224 45| 167 45| 110 45| 67 00| 30 +------+-------+-------+-------+-------+-------+-------+-------+-------+----- +Totals|7,024 |5,529 |3,981 |2,995 |1,946 |1,335 | 868 | 606 | -- + | 00| 30| 00| 45| 00| 00| 30| 15| +Max. | | | | | | | | | +for | ----- | ----- | ----- | ----- | ----- | ----- | ----- | ----- | 37 +year | | | | | | | | | +______|_______|_______|_______|_______|_______|_______|_______|_______|____ +</pre> + +<p>The location of a mill has a great deal to do with the results +attained. Having had charge of the erection of a large number of +these mills for power purposes, I will refer to a few of them in +different States, giving the actual results accomplished, and +leaving you to form your own opinion as to the power developed.</p> + +<p>In 1877 a 25-foot diameter mill was erected at Dover, Kansas, a +few miles southwest of Topeka. It was built to do custom flour and +feed grinding, also corn shelling, and is in successful operation +at the present time. We have letters frequently from the owner; one +of recent date states that it has stood all of the "Kansas +zephyrs," never having been damaged as yet. On an average it shells +and grinds from 6 to 10 bushels of corn per hour, and runs a 14 +inch burr stone, grinding wheat at the same time. During strong +winds it has shelled and ground as high as 30 bushels of corn per +hour. Plate 2 is from a photograph of this mill and building as it +stands. One bevel pinion is all the repairs this mill has +required.</p> + +<p>In the spring of 1880 there was erected a 25-foot diameter mill +at Harvard, Clay County, Neb. After this mill had been running +nineteen months, we received the following report from the +owner:</p> + +<p>"During the nineteen months we have been running the wind mill, +it has cost us nothing for repairs. We run it with a two-hole corn +sheller, a set of 16-inch burr stones, and an elevator. We grind +all kinds of feed, also corn meal and Graham flour. We have ground +8,340 bushels, and would have ground much more if corn had not been +a very poor crop here for the past two seasons; besides, we have +our farm to attend to, and cannot keep it running all the time that +we have wind. We have not run a full day at any time, but have +ground 125 bushels in a day. When the burr is in good shape we can +grind 20 bushels an hour, and shell at the same time in the average +winds that we have. The mill has withstood storms without number, +even one that blew down a house near it, and another that blew down +many smaller mills. It is one of the best investments any one can +make."</p> + +<p>The writer saw this mill about sixty days ago, and it is in good +shape, and doing the work as stated. The only repairs that it has +required during four years was one bevel pinion put on this +spring.</p> + +<p>The owner of a 16-foot diameter mill, erected at Blue Springs. +Neb., says that "with a fair wind it grinds easily 15 bushels of +corn per hour with a No. 3 grinder, also runs a corn-sheller and +pump at the same time, and that it works smoothly and is entirely +self-regulating."</p> + +<p>The No. 3 grinder referred to has chilled iron burrs, and +requires from 3 to 4 horse-power to grind 15 bushels of corn per +hour. Of one of these 16-foot mills that has been running since +1875 in Northern Illinois, the owner writes: "In windy days I saw +cord-wood as fast as the wood can be handled, doing more work than +I used to accomplish with five horses."</p> + +<p>The owner of one of these mills, 20 feet in diameter, running in +the southwestern part of this State, writes that he has a +corn-sheller and two iron grinding mills with 8-inch burrs attached +to it; also a bolting device; that this mill is more profitable to +him than 80 acres of good corn land, and that it is easily handled +and has never been out of order. The following report on one of +these 16-foot mills, running in northern Illinois, may be of +interest: This mill stands between the house and barn. A connection +is made to a pump in a well-house 25 feet distant, and is also +arranged to operate a churn and washing machine. By means of +sheaves and wire cable, power is transmitted to a circular saw 35 +feet distant. In this same manner power is transmitted to the barn +200 feet distant, where connection is made to a thrasher, +corn-sheller, feed-cutter, and fanning-mill. The corn-sheller is a +three horse-power, with fan and sacker attached. Three hundred +bushels per day has been shelled, cleaned, and sacked. The +thrashing machine is a two horsepower with vibrating attachment for +separating straw from grain. One man has thrashed 300 bushels of +oats per day, and on windy days says the mill would run a thrasher +of double this capacity. The saw used is 18 inches diameter, and on +windy days saws as much wood as can be done by six horses working +on a sweep power. The owner furnishes the following approximate +cost of mill with the machinery attached and now in use on his +place:</p> + +<pre> + 1 16-foot power wind mill, shafting, and tower. $385 + 1 Two horse thrasher. 70 + 1 Three horse sheller. 38 + 1 Feed grinder. 50 + 1 18-inch saw, frame and arbor. 40 + 1 Fanning mill. 25 + 1 Force pump. 27 + 1 Churn. 5 + 1 Washing machine. 15 + Belting, cables, and pulleys. 45 + ---- + Total. $700 +</pre> + +<p>The following facts and figures furnished by the owner will give +a fair idea of the economic value of this system, as compared with +the usual methods of doing the same work. On the farm where it is +used, there are raised annually an average of sixty acres of oats, +fifty acres of corn, twenty acres of rye, ten acres of +buckwheat.</p> + +<pre> + Bushels. + The oats average, say 30 bushels per acre. 1,800 + Corn " 30 " " 1,500 + Rye " 20 " " 400 + Buckwheat " 20 " " 200 + Grinding for self and others. 1,000 +<br> + It will cost to thrash this grain, shell the corn, and + grind the feed with steam power. $285 + And sawing wood, 12½ cords. 18 + Pumping, one hour per day, 365 days. 36 + Churning, half hour per day, 200 days. 10 + Washing, half day per week, 26 days. 26 + ---- + Total. $375 +</pre> + +<p>This amount is saved, and more too, as one man, by the aid of +the wind mill, will do this work in connection with the chores of +the farm, and save enough in utilizing foul weather to more than +offset his extra labor, cost of oil, etc., for the machinery. The +amount saved each year is just about equal to the cost of a good +man. Cost of outfit, $700--just about equal to the cost of a good +man for two years, consequently, it will pay for itself in two +years. Fifteen years is a fair estimate for the lifetime of mill +with ordinary repairs.</p> + +<p>The solid-wheel wind mill has never been built larger than 30 +feet in diameter. For mills larger than this, the latest improved +American mill is the "Warwick" pattern.</p> + +<p>A 30-foot mill of this pattern, erected in 1880, in northwestern +Iowa, gave the following results, as reported by the owner:</p> + +<p>"Attachments as follows: One 22-inch burr; one No. 4 iron +feed-mill; one 26-inch circular saw; one two-hole corn-sheller; one +grain elevater; a bolting apparatus for fine meal, buckwheat and +graham, all of which are run at the same time in good winds, except +the saw or the iron mill; they being run from the same pulley can +run but one at a time. With all attached and working up to their +full capacity, the sails are often thrown out of the wind by the +governors, which shows an immense power. The machines are so +arranged that I can attach all or separately, according to the +wind. With the burr alone I have ground 500 bushels in 48 +consecutive hours, 100 bushels of it being fine meal. I have also +ground 24 full bushels of fine meal for table use in two hours. +This last was my own, consequently was not tolled. This was before +I bought the iron mill, and now I can nearly double that amount. I +saw my fire wood for three fires; all my fence posts, etc. My wood +is taken to the mill from 12 to 15 feet long, and as large as the +saw will cut by turning the stick, consequently the saw requires +about the same power as the burrs. With a good sailing breeze I +have all the power I need, and can run all the machinery with ease. +Last winter I ground double the amount of any water mill in this +vicinity. I have no better property than the mill."</p> + +<p>A 40-foot mill, erected at Fowler, Indiana, in 1881, is running +the following machinery:</p> + +<p>"I have a universal wood worker, four side, one 34-inch planer, +jig saw, and lathe, also a No. 4 American grinder, and with a good, +fair wind I can run all the machines at one time. I can work about +four days and nights each week. It is easy to control in high +winds."</p> + +<p>A 60-foot diameter mill of similar pattern was erected in Steel +County, Minnesota, in 1867. The owner gives the following history +of this mill:</p> + +<p>"I have run this wind flouring mill since 1867 with excellent +success. It runs 3 sets of burrs, one 4 feet, one 3½ feet, +and one 33 inches. Also 2 smutters, 2 bolts, and all the necessary +machinery to make the mill complete. A 15-mile wind runs everything +in good shape. One wind wheel was broken by a tornado in 1870, and +another in 1881 from same cause. Aside from these two, which cost +$250 each, and a month's lost time, the power did not cost over $10 +a year for repairs. In July, 1833, a cyclone passed over this +section, wrecking my will as well as everything else in its track, +and having (out of the profits of the wind mill) purchased a large +water and steam flouring mill here, I last fall moved the wind mill +out to Dakota, where I have it running in first-class shape and +doing a good business. The few tornado wrecks make me think none +the less of wind mills, as my water power has cost me four times as +much in 6 years as the wind power has in 16 years."</p> + +<p>There are very few of these large mills in use in this country, +but there are a great many from 14 to 30 feet in diameter in use, +and their numbers are rapidly increasing as their merits become +known. The field for the use of wind mills is almost unlimited, and +embraces pumping water, drainage, irrigation, elevating, grinding, +shelling, and cleaning grain, ginning cotton, sawing wood, +churning, running stamp mills, and charging electrical +accumulators. This last may be the solution of the St. Louis gas +question.</p> + +<p>In the writer's opinion the settlement of the great tableland +lying between the Mississippi Valley and the Rocky Mountains, and +extending from the Gulf of Mexico to the Red River of the North, +would be greatly retarded, if not entirely impracticable, in large +sections where no water is found at less than 100 to 500 feet below +the surface, if it were not for the American wind mill; large +cattle ranges without any surface water have been made available by +the use of wind mills. Water pumped out of the ground remains about +the same temperature during the year, and is much better for cattle +than surface water. It yet remains in the future to determine what +the wind mill will not do with the improvements that are being made +from to time.</p> + +<hr> +<p><a name="3"></a></p> + +<h2>THE PNEUMATIC DYNAMITE GUN.</h2> + +<p>It is here shown as mounted on a torpedo launch and ready for +action. The shell or projectile is fired by compressed air, +admitted from an air reservoir underneath by a simple pressure of +the gunner's finger over the valve. The air passes up through the +center of the base, the pipe connecting with one of the hollow +trunnions. The valve is a continuation of the breech of the gun. +The smaller cuts illustrate Lieutenant Zalinski's plan for mounting +the gun on each side of the launch, by which plan the gun after +being charged may have the breech containing the dynamite +depressed, and protected from shots of the enemy by its complete +immersion alongside the launch; and, if necessary, may be +discharged from this protected position. The gun is a seamless +brass tube of about forty feet in length, manipulated by the +artillerist in the manner of an ordinary cannon. Its noiseless +discharge sends the missile with great force, conveying the +powerful explosive within it, which is itself discharged internally +upon contact with the deck of a vessel or other object upon which +it strikes, through the explosion of a percussion fuse in the point +of the projectile. A great degree of accuracy has been obtained by +the peculiar form of the projectile.</p> + +<p class="ctr"><a href="./illustrations/3a.png"><img src= +"./illustrations/3a_th.jpg" alt= +"PNEUMATIC DYNAMITE GUN TORPEDO VESSEL."></a></p> + +<p class="ctr">PNEUMATIC DYNAMITE GUN TORPEDO VESSEL.</p> + +<p>The projectile consists of a thin metal tube, into which the +charge is inserted, and a wooden sabot which closes it at the rear +and flares out until its diameter equals that of the bore of the +gun. The forward end of the tube is pointed with some soft +material, in which is embedded the firing pin, a conical cap +closing the end. A cushion of air is interposed at the rear end of +the dynamite charge, to lessen the shock of the discharge and +prevent explosion, until the impact of the projectile forces the +firing pin in upon the dynamite and explodes it. Many charges have +been successfully fired at Fort Hamilton, N.Y. As the center of +gravity is forward of the center of figure in the projectile, a +side wind acting upon the lighter rear part would tend to turn the +head into the wind and thus keep it in the line of its trajectory. +A range of 1¼ miles has been attained with the two inch gun, +with a pressure of 420 lb. to the square inch, and one of three +miles is hoped for with the larger gun and a pressure of 2,000 +lb.</p> + +<hr> +<p><a name="4"></a></p> + +<h2>ROPE PULLEY FRICTION BRAKE.</h2> + +<p>A novel device in connection with rope pulley blocks is +illustrated in the annexed engravings, the object of the appliance +being to render it possible to leave a weight suspended from a +block without making the tail of the rope fast to some neighboring +object. By this arrangement the danger of the rope slipping loose +is avoided, and absolute security is attained, without the +necessity of lowering the weight to the ground. The device itself +is a friction brake, constructed in the form of a clip with holes +in it for the three ropes to pass through. It is made to span the +block, and is secured partly by the pin or bolt upon which the +sheaves run, and partly by the bottom bolt, which unites the cheeks +of the block. Thus the brake is readily attachable to existing +blocks. The inner half of the clip or brake is fixed solidly to the +block, while the outer half is carried by two screws, geared +together by spur-wheels, and so cut that although rotating in +opposite directions, their movements are equal and similar. One of +the screws carries a light rope-wheel, by which it can be rotated, +the motion being communicated to the second screw by the toothed +wheels. When the wheel is rotated in the right direction the loose +half of the clip is forced toward the other half, and grips the +ropes passing between the two so powerfully that any weight the +blocks are capable of lifting is instantly made secure, and is held +until the brake is released.</p> + +<p>A light spiral spring is placed on each of the screws, in order +to free the brake from the rope the moment the pressure is +released. The hand rope has a turn and a half round the pulley, and +this obviates the need of holding both ends of it, and thus leaves +one hand free to guide the descending weight, or to hold the rope +of the pulley blocks. <i>Engineering</i> says these brakes are very +useful in raising heavy weights, as the lift can be secured at each +pull, allowing the men to move hands for another pull, and as they +are made very light they do not cause any inconvenience in moving +or carrying the blocks about. Manufactured by Andrew Bell & +Co., Manchester.</p> + +<hr> +<p><a name="5"></a></p> + +<h2>WIRE ROPE TOWAGE.</h2> + +<p>We have from time to time given accounts in this journal of the +system of towage by hauling on a submerged wire rope, first +experimented upon by Baron O. De Mesnil and Mr. Max Eyth. On the +river Rhine the system has been for many years in successful +operation; it has also been used for several years on the Erie +Canal in this State. We publish from <i>Engineering</i> a view of +one of the wire rope tug boats of the latest pattern adopted for +use on the Rhine.</p> + +<p>The Cologne Central Towing Company (Central Actien-Gesellschaft +für Tauerei und Schleppschifffahrt), by whom the wire rope +towage on the Rhine is now carried on, was formed in 1876, by an +amalgamation of the Rührorter und Mulheimer +Dampfschleppshifffahrt Gesellschaft and the Central +Actien-Gesellschaft fur Tauerei, and in 1877 it owned eight wire +rope tugs (which it still owns) and seventeen paddle tugs. The +company so arranges its work that the wire rope tugs do the haulage +up the rapid portion of the Rhine, from Bonn to Bingen, while the +paddle tugs are employed on the quieter portion of the river +extending from Rotterdam to Bonn, and from Bingen to Mannheim.</p> + +<p class="ctr"><img src="./illustrations/4a.png" alt= +"ROPE PULLEY FRICTION BRAKE."></p> + +<p class="ctr">ROPE PULLEY FRICTION BRAKE.</p> + +<p>The leading dimensions of the eight wire rope tugs now worked by +the company are as follows:</p> + +<pre> + Tugs No. I. to Tugs No. V. to + IV. VIII. + Meters. ft. in. Meters. ft. in. + Length between + perpendiculars 39 = 126 0 42 = 137 10 + Length over all 42.75 = 140 3 45.75 = 150 1 + Extreme breadth 7.2 = 28 8 7.5 = 24 5 + Height of sides 2.38 = 7 11 2.38 = 7 11 + Depth of keel 0.12 = 0 5 0.15 = 0 6 +</pre> + +<p>All the boats are fitted with twin screws, 1.2 meters (3 feet +11¼ inches) in diameter, these being used on the downstream +journey, and also for assisting in steering while passing awkward +places during the journey up stream. They are also provided with +water ballast tanks, and under ordinary circumstances they have a +draught of 1.3 to 1.4 meters (4 feet 3 inches to 4 feet 7 inches), +this draught being necessary to give proper immersion to the +screws. When the water in the Rhine is very low, however, the water +ballast is pumped out and the tugs are then run with a draught of 1 +meter (3 feet 3 3/8 inches), it being thus possible to keep them at +work when all other towing steamers on the Rhine are stopped. This +happened in the spring of 1882.</p> + +<p>Referring to our engraving, it will be seen that the wire rope +rising from the bed of the river passes first over a large guide +pulley, the axis of which is carried by a substantial wrought iron +swinging bracket, this bracket being so pivoted that while the +pulley is free to swing into the line on which the rope is +approached by the vessel, yet the rope on leaving the pulley is +delivered in a line which is tangential to a second guide pulley +placed further aft and at a lower level. This last named guide +pulley does not swing, and from it the rope is delivered to the +clip drum, over which it passes. From the clip drum the rope passes +under a third guide pulley; this pulley swings on a bracket having +a vertical axis. This third pulley projects down below the keel of +the tug boat, so that the rope on leaving it can pass under the +vessel without fouling. Suitable recesses are formed in the side of +the tug boat to accommodate the swinging pulleys, while the bow of +the boat is sloped downward nearly to the water line, as shown, so +as to allow of the rising part of the rope swinging over it if +necessary.</p> + +<p>The hauling gear with which the tug is fitted consists of a pair +of condensing engines with cylinders 14.17 inches in diameter and +23.62 inches stroke, the crankshaft carrying a pinion which gears +into a spur wheel on an intermediate shaft, this shaft again +carrying a pinion which gears into a large spur wheel fixed on the +shaft which carries the clip drum. In the arrangement of hauling +gear above described the ratio of the gear is 1:8.44, in the case +of tugs Nos. I. to IV.; while in tugs Nos. V. to VIII. the +proportion has been made 1:11.82. In tugs I. to IV. the diameter of +the clip drum is 2.743 meters (9 feet), while in the remaining tugs +it is 3.056 meters (10 feet).</p> + +<p>From some interesting data which have been placed at our +disposal by Mr. Thomas Schwarz, the manager of the Central +Actien-Gesellschaft fur Tauerei und Schleppschifffahrt, we learn +that in the tugs Nos. I. to IV. the hauling machine develops on an +average 150 indicated horse, while in the tugs No. V. to VIII. the +power developed averages 180 indicated horse power. The tugs +forming the first named group haul on an average 2,200 tons of +cargo, contained in four wooden barges, at a speed of 4½ +kilometers (2.8 miles) per hour, against a stream running at the +rate of 6½ kilometers (4.05 miles) per hour, while the tugs +Nos. V. to VIII. will take a load of 2,600 tons of cargo in the +same number of wooden barges at the same speed and against the same +current. In iron barges, about one and a half times the quantity of +useful load can be drawn by a slightly less expenditure of +power.</p> + +<p>The average consumption of coal per hour is, for tugs Nos. I. to +IV., 5 cwt, and for tugs Nos. V. to VIII., 6 cwt.; and of this fuel +a small fraction (about one-sixth) is consumed by the occasional +working of the screw propellers at sharp bends. The fuel +consumption of the wire rope tugs contrasts most favorably with +that of the paddle and screw tugs employed on the Rhine, the best +paddle tugs (with compound engines, patent wheels, etc.) burning +three and a half times as much; the older paddle tugs (with low +pressure non-compound engines), four and a half times as much; and +the latest screw tugs, two and a half times as much coal as the +wire rope tugs when doing the same work under the same +circumstances. The screw tugs just mentioned have a draught of +2½ meters (8 feet 2½ inches), and are fitted with +engines of 560 indicated horse power.</p> + +<p>During the years 1879, 1880, and 1881, the company had in use +fourteen paddle tugs and ten eight-wire rope tugs, both classes +being--owing to the state of trade--about equally short of work. +The results of the working during these years were as follows:</p> + +<pre> + ================================================================ + | | Freight | Cost of | Degree + | | hauled | haulage in | of + Class of tugs. | Year. | in | pence per | occupation. + | | ton-miles. | ton-mile. | + ---------------------------------------------------------------- + Paddle | 1879 | 31,862,858 | 0.1272 | 0.686 + " | 1880 | 31,467,422 | 0.1305 | 0.638 + " | 1881 | 28,627,049 | 0.1245 | 0.537 + Wire Rope | 1879 | 15,407,935 | 0.1167 | 0.614 + " | 1880 | 17,289,706 | 0.1056 | 0.615 + " | 1881 | 17,593,181 | 0.0893 | 0.536 + ================================================================ +</pre> + +<p>The last column in the above tabular statement, headed "Degree +of Occupation," may require some explanation. It is calculated on +the assumption that a tug could do 3,000 hours of work per annum, +and this is taken as the unit, the time of actual haulage being +counted as full time, and of stoppages as half time. The expenses +included in the statement of cost of haulage include all working +expenses, repairs, general management, and depreciation. The +accounts for 1882, which are not completely available at the time +we are writing, show much better results than above recorded, there +being a considerable reduction of cost, while the freight hauled +amounted to a total of 54,921,965 ton-miles.</p> + +<p class="ctr"><a href="./illustrations/4b.png"><img src= +"./illustrations/4b_th.jpg" alt="WIRE ROPE TUG BOAT, RIVER RHINE."> +</a></p> + +<p class="ctr">WIRE ROPE TUG BOAT, RIVER RHINE.</p> + +<p>As regards the wear of the rope, we may state that the relaying +of the first rope between St. Goar and Bingen was taken in hand in +September, 1879, while that between Obercassel and Bingen was +partially renewed the same year, the renewal being completed in +May, 1880, after the rope had been in use since the beginning of +1876. The second rope between Bonn and Bingen, a length of +74¾ miles, is of galvanized wire, has now been 2¾ +years in use, during which time there have been but three +fractures. The first rope laid was not galvanized, and it suffered +nine fractures during the first three years of its use. The first +rope, we may mention, was laid in lengths of about a mile spliced +together, while the present rope was supplied in long lengths of +7½ miles each, so that the number of splices is greatly +reduced. According to the report of the company for the year 1880, +the old rope when raised realizes about 16 per cent. of its +original value, and allowing for this, it is calculated that an +allowance of 18.7 per cent. per annum will cover the cost of rope +depreciation and renewals. Altogether the results obtained on the +Rhine show that in a rapid stream the economic performances of wire +rope tugs compare most favorably with those of either paddle or +screw tug boats, the more rapid the current to be contended against +the greater being the advantage of the wire rope haulage.</p> + +<hr> +<p><a name="6"></a></p> + +<h2>IMPROVED HAY-ROPE MACHINE.</h2> + +<p>Hay-ropes are used for many purposes, their principal use being +in the foundry for core-making; but they also find a large +application for packing ironmongery and furniture. The inventor is +James Pollard, of the Atlas Foundry, Burnley.</p> + +<p class="ctr"><a href="./illustrations/5a.png"><img src= +"./illustrations/5a_th.jpg" alt="HAY ROPE MACHINE."></a></p> + +<p class="ctr">HAY ROPE MACHINE.</p> + +<p>The chief part of the mechanism is carried in an open frame, +having journals attached to its two ends, which revolve in +bearings. The frame is driven by the rope pulley. The journal at +the left hand is hollow; the pinion upon it is stationary, being +fixed to the bracket of bearing. The pinion gearing into it is +therefore revolved by the revolution of the frame, and through the +medium of bevel wheels actuates a transverse shaft, parallel to +which rollers, and driven by wheels off it, is a double screw, +which traverses a "builder" to and fro across the width of frame. +The builder is merely the eye through which the band passes, and +its office is to lay the band properly on the bobbin. The latter is +turned to coil on the band by a pitch chain from the builder screw, +the motion being given through a friction clutch, to allow for slip +as the bobbin or coil gets larger, for obviously the bobbin as it +gets larger is not required to turn so fast to coil up the band +produced as when it is smaller. If the action is studied, it will +be seen that the twist is put in between the bobbin and the hollow +journal, and every revolution of the frame puts in one turn for the +twist. The hay is fed to the machine through the hollow journal +already mentioned. By suitably proportioning the speed of +feed-rollers and the revolutions of the frame, which is easily +accomplished by varying the wheels on the left hand of frame, bands +of any degree of hardness or softness may be produced. The machine +appears to be simple and not liable to get deranged. It may be +after a little practice attended to by a laborer, and is claimed by +its maker to be able to produce 400 yards of band per hour. The +frame makes about 180 revolutions per minute, that is, this is the +number of turns put into the twist in this time. The machine can +make a bundle about 200 yards long, which can be removed off the +bobbin without unwinding with the greatest facility.--<i>Mech. +World.</i></p> + +<hr> +<p><a name="7"></a></p> + +<h2>THE ANGLESEA BRIDGE, CORK.</h2> + +<p>The river Lee flows through the city of Cork in two branches, +which diverge just above the city, and are reunited at the Custom +House, the central portion of the city being situated upon an +island between the two arms of the river, both of which are +navigable for a short distance above the Custom House, and are +lined with quays on each side for the accommodation of the shipping +of the port.</p> + +<p>The Anglesea bridge crosses the south arm of the river about a +quarter of a mile above its junction with the northern branch, and +forms the chief line of communication from the northern and central +portions of the city to the railway termini and deep-water quays on +the southern side of the river.</p> + +<p class="ctr"><a href="./illustrations/5b.png"><img src= +"./illustrations/5b_th.jpg" alt="THE NEW ANGLESEA BRIDGE, CORK."> +</a></p> + +<p class="ctr">THE NEW ANGLESEA BRIDGE, CORK.</p> + +<p>The new swing bridge occupies the site of an older structure +which had been found inadequate to the requirements of the heavy +and increasing traffic, and the foundations of the old piers having +fallen into an insecure condition, the construction of a new +opening bridge was taken in hand jointly by the Corporation and +Harbor Commissioners of Cork.</p> + +<p>The new bridge, which has recently been completed, is of a +somewhat novel design, and the arrangement of the swing-span in +particular presents some original and interesting features, which +appear to have been dictated by a careful consideration of the +existing local conditions and requirements.</p> + +<p>On each side of the river, both above and below the bridge, the +quays are ordinarily lined with vessels berthed alongside each of +the quays, and as the river is rather narrow at this point, the +line of fairway for vessels passing through the bridge is confined +nearly to the center of the river. This consideration, together +with some others connected with the proposed future deepening of +the fairway, rendered it very desirable to locate the opening span +nearly in the center of the river, as shown in the general plan of +the situation, which we publish herewith. At the same time it was +necessary to avoid any encroachment upon the width of the existing +quays, which form important lines of communication for vehicular +and passenger traffic along each side of the river, and to and from +the railway stations. Again, it was necessary to preserve the full +existing width of waterway in the river itself, which is sometimes +subjected to heavy floods.</p> + +<p>These considerations evidently precluded the construction of a +central pier and double-armed swing bridge, and on the other hand +they also precluded the construction of any solid masonry +substructure for the turntable, either upon the quay or projected +into the river. To meet these several conditions the bridge has +been designed in the form of a three-span bridge, that is to say, +it is only supported by the two abutments and two intermediate +piers, each consisting of a pair of cast-iron cylinders or columns, +as shown by the dotted circles upon the general plan.</p> + +<p>The central opening is that which serves for the passage of +vessels. The swing bridge extends over two openings, or from the +north abutment to the southern pier, its center of revolution being +situated over the center of the northern span, and revolves upon a +turntable, which is carried upon a lower platform or frame of +girders extending across the northern span of the bridge. The +southern opening is spanned by an ordinary pair of lattice girders +in line with the girders and superstructure of the swing +bridge.</p> + +<p>We propose at an early date to publish further details of this +bridge, and the hydraulic machinery by which it is worked.</p> + +<p>We present a perspective view of the bridge as seen from the +entrance to the exhibition building, which is situated in close +proximity to the southern end of the +bridge.--<i>Engineering</i>.</p> + +<hr> +<p><a name="8"></a></p> + +<h2>PORTABLE RAILWAYS.</h2> + +<p>[Footnote: Paper read before the Institution of Mechanical +Engineers.]</p> + +<h3>By M. DECAUVILLE, Aîne, of Petit-Bourg (Seine and Oise), +France.</h3> + +<p>Narrow gauge railways have been known for a very long time in +Great Britain. The most familiar lines of this description are in +Wales, and it is enough to instance the Festiniog Railway (2 feet +gauge), which has been used for the carriage of passengers and +goods for nearly half a century. The prosperous condition of this +railway, which has been so successfully improved by Mr. James +Spooner and his son, Mr. Charles Spooner, affords sufficient proof +that narrow gauge railways are not only of great utility, but may +be also very remunerative.</p> + +<p>In Wales the first narrow gauge railway dates from 1832. It was +constructed merely for the carriage of slates from Festiniog to +Port-Madoc, and some years later another was built from the slate +quarries at Penrhyn to the port of Bangor. As the tract of country +traversed by the railways became richer by degrees, the idea was +conceived of substituting locomotives for horses, and of adapting +the line to the carriage of goods of all sorts, and finally of +passengers also.</p> + +<p>But these railways, although very economical, are at the same +time very complicated in construction. Their arrangements are based +upon the same principles as railways of the ordinary gauge, and are +not by any means capable of being adapted to agriculture, to public +works, or to any other purpose where the tracks are constantly +liable to removal. These permanent narrow gauge lines, the laying +of which demands the service of engineers, and the maintenance of +which entails considerable expense, suggested to M. Decauville, +Aîne, farmer and distiller at Petit-Bourg, near Paris, the +idea of forming a system of railways composed entirely of metal, +and capable of being readily laid. Cultivating one of the largest +farms in the neighborhood of Paris, he contemplated at first +nothing further than a farm railroad; and he contrived an extremely +portable plant, adapted for clearing the land of beetroot, for +spreading manure, and for the other needs of his farm.</p> + +<p>From the beginning in his first railroads, the use of timber +materials was rigidly rejected by him; and all parts, whether the +straight or curved rails, crossings, turntables, etc., were formed +of a single piece, and did not require any special workman to lay +them down. By degrees he developed his system, and erected special +workshops for the construction of his portable plant; making use of +his farm, and some quarries of which he is possessed in the +neighborhood, as experimental areas. At the present time this +system of portable railways serves all the purposes of agriculture, +of commerce, of manufactures, and even those of war.</p> + +<p>Within so limited a space it would be impossible to give a +detailed description of the rails and fastenings used in all these +different modes of application. The object of this paper is rather +to direct the attention of mechanical engineers to the various uses +to which narrow gauge portable railways may be put, to the +important saving of labor which is effected by their adoption, and +to the ease with which they are worked.</p> + +<p>The success of the Decauville railway has been so rapid and so +great that many inventors have entered the same field, but they +have almost all formed the idea of constructing the portable track +with detachable sleepers. There are thus, at present, two systems +of portable tracks: those in which the sleepers are capable of +being detached, and those in which they are not so capable.</p> + +<p>The portable track of the Decauville system is not capable of so +coming apart. The steel rails and sleepers are riveted together, +and form only one piece. The chief advantage of these railways is +their great firmness; besides this, since the line has only to be +laid on the surface just as it stands, there are not those costs of +maintenance which become unavoidable with lines of which the +sleepers are fixed by means of bolts, clamps, or other adjuncts, +only too liable to be lost. Moreover, tracks which are not capable +of separation are lighter and therefore more portable than those in +which the sleepers are detachable.</p> + +<p>With regard to sleepers, a distinction must be drawn between +those which project beyond the rails and those which do not so +project. M. Decauville has adopted the latter system, because it +offers sufficient strength, while the lines are lighter and less +cumbersome. Where at first he used flat iron sleepers, he now fits +his lines with dished steel sleepers, in accordance with Figs. 1 +and 2.</p> + +<p class="ctr"><img src="./illustrations/6a.png" alt= +"Fig. 1. Fig. 2."></p> + +<p class="ctr">Fig. 1. Fig. 2.</p> + +<p>This sleeper presents very great stiffness, at the same time +preserving its lightness; and the feature which specially +distinguishes this railway from others of the same class is not +only its extreme strength, but above all its solidity, which +results from its bearing equally upon the ground by means of the +rail base and of the sleepers.</p> + +<p>In special cases, M. Decauville provides also railroads with +projecting sleepers, whether of flat steel beaten out and rounded, +or of channel iron; but the sleeper and the rail are always +inseparable, so as not to lessen the strength, and also to +facilitate the laying of the line. If the ground is too soft, the +railway is supported by bowl sleepers of dished steel, Figs. 3 and +4, especially at the curves; but the necessity for using these is +but seldom experienced. The sleepers are riveted cold. The rivets +are of soft steel, and the pressure with which this riveting is +effected is so intense that the sleepers cannot be separated from +the rails, even after cutting off both heads of the rivets, unless +by heavy blows of the hammer, the rivets being driven so thoroughly +into the holes made in the rails and sleepers that they fill them +up completely.</p> + +<p>The jointing of the rails is excessively simple. The rail to the +right hand is furnished with two fish-plates; that to the left with +a small steel plate riveted underneath the rail and projecting +1¼ in. beyond it. It is only necessary to lay the lengths +end to end with one another, making the rail which is furnished +with the small plate lie between the two fish-plates, and the +junction can at once be effected by fish-bolts. A single fish-bolt, +passing through the holes in the fish-plates, and through an oval +hole in the rail end, is sufficient for the purpose.</p> + +<p>With this description of railway it does not matter whether the +curves are to the right or to the left. The pair of rails are +curved to a suitable radius, and can only need turning end for end +to form a curve in the direction required. The rails weigh 9 lb., +14 lb., 19 lb., and 24 lb. per running yard, and are very similar +to the rails used on the main railways of France, except that their +base has a proportionally greater width. As to the strength of the +rail, it is much greater in proportion to the load than would at +first sight be thought; all narrow-gauge railways being formed on +the principle of distributing the load over a large number of +axles, and so reducing the amount on each wheel. For instance, the +9 lb. rail used for the portable railway easily bears a weight of +half a ton for each pair of wheels.</p> + +<p>The distance between the rails differs according to the purpose +for which they are intended. The most usual gauges are 16in., 20 +in., and 24in. The line of 16 in. gauge, with 9 lb. rails, although +extremely light, is used very successfully in farming, and in the +interior of workshops.</p> + +<p class="ctr"><img src="./illustrations/6b.png" alt= +"Fig. 3. Fig. 4. Fig. 5."></p> + +<p class="ctr">Fig. 3. Fig. 4. Fig. 5.</p> + +<p>A length of 16 ft. 5 in. of 9 lb. steel rail, to 16 in. gauge, +with sleepers, etc., scarcely weighs more than 1 cwt., and may +therefore be readily carried by a man placing himself in the middle +and taking a rail in each hand.</p> + +<p>Those members of the Institution who recently visited the new +port of Antwerp will recollect having seen there the portable +railway which Messrs. Couvreux and Hersetit had in use; and as it +was these works at the port of Antwerp that gave rise to the idea +of this paper, it will be well to begin with a description of this +style of contractor's plant.</p> + +<p>The earth in such works may be shifted by hand, horsepower, or +locomotive. For small works the railway of 16 in. gauge, with the 9 +lb. rails, is commonly used, and the trucks carry double +equilibrium tipping-boxes, containing 9 to 11 cubic feet. These +wagons, having tipping-boxes without any mechanical appliances, are +very serviceable; since the box, having neither door nor hinge, is +not liable to need repairs.</p> + +<p>This box keeps perfectly in equilibrium upon the most broken up +roads. To tip it up to the right or the left, it must simply be +pushed from the opposite side, and the contents are at once emptied +clean out. In order that the bodies of the wagons may not touch at +the top, when several are coupled together, each end of the wagon +is furnished with a buffer, composed of a flat iron bar cranked, +and furnished with a hanging hook.</p> + +<p>Plant of this description is now being used in an important +English undertaking at the port of Newhaven, where it is employed +not only on the earthworks, but also for transporting the concrete +manufactured with Mr. Carey's special concrete machine.</p> + +<p>These little wagons, of from 9 to 11 cubic feet capacity, run +along with the greatest ease, and a lad could propel one of them +with its load for 300 yards at a cost of 3d. per cube yard. In +earthworks the saving over the wheel-barrow is 80 per cent., for +the cost of wagons propelled by hand comes to 0.1d. per cube yard, +carried 10 yards, and to go this distance with a barrow costs +½d. A horse draws without difficulty, walking by the side of +the line, a train of from eight to ten trucks on the level, or five +on an incline of 7 per cent. (1 in 14).</p> + +<p>One mile of this railway, 16 in. gauge and 9 lb. steel rail, +with sixteen wagons, each having a double equilibrium tipping box +containing 11 cubic feet, and all accessories, represents a weight +of 20 tons--a very light weight, if it is considered that all the +materials are entirely of metal. Its net cost price per mile is +450<i>l</i>., the wagons included.</p> + +<p>Large contracts for earthwork with horse haulage are carried on +to the greatest advantage with the railway of 20 in. gauge and 14 +lb. rails. The length of 16 ft. 5 in. of this railway weighs 170 +lb., and so can easily be carried by two men, one placing himself +at each end. The wagons most in use for these works are those with +double equilibrium tipping boxes, holding 18 cubic feet. These are +at present employed in one of the greatest undertakings of the age, +namely, the cutting of the Panama Canal, where there are used +upward of 2,700 such wagons, and more than 35 miles of track.</p> + +<p>A mile of these rails of 20 in. gauge with 14 lb. rails, +together with sixteen wagons of 18 cubic feet capacity, with +appurtenances, costs about 660<i>1</i>., and represents a total +weight of 33 tons.</p> + +<p>This description of material is used for all contracts exceeding +20,000 cubic yards.</p> + +<p>A very curious and interesting use of the narrow-gauge line, and +the wagons with double equilibrium tipping-box, was made by the +Societe des Chemins de Fer Sous-Marins on the proposed tunnel +between France and England. The line used is that of 16 in. gauge, +with 9 lb. rails.</p> + +<p>The first level of the tunnel, which was constructed by means of +a special machine by Colonel Beaumont, had only a diameter of 2.13 +m. (7 ft.); the tipping boxes have therefore a breadth of only 2 +ft., and contain 7¼ cubic feet. The boxes are perfectly +balanced, and are most easily emptied. The wagons run on two lines, +the one being for the loaded trains, and the other for the empty +trains.</p> + +<p>The engineers and inspectors, in the discharge of their duties, +make use of the Liliputian carriages. The feet of the travelers go +between the wheels, and are nearly on a level with the rails; +nevertheless, they are tolerably comfortable. They are certainly +the smallest carriages for passengers that have ever been built; +and the builder even prophesies that these will be the first to +enter into England through the Channel Tunnel.</p> + +<p>One of the most important uses to which a narrow gauge line can +be put is that of a military railway. The Dutch, Russian, and +French Governments have tried it for the transporting of +provisions, of war material, and of the wounded in their recent +campaigns. In Sumatra, in Turkestan, and in Tunis these military +railroads have excited much interest, and have so fully established +their value that this paper may confine itself to a short +description.</p> + +<p>The campaign of the Russians against the Turcomans presented two +great difficulties; these were the questions of crossing districts +in which water was extremely scarce or failed entirely, and of +victualing the expeditionary forces. This latter object was +completely effected by means of 67 miles of railway, 20 in. gauge, +14 lb. steel rails, with 500 carriages for food, water, and +passengers. The rails were laid simply on the sand, so that small +locomotives could not be used, and were obliged to be replaced by +Kirghiz horses, which drew with ease from 1,800 lb. to 2,200 lb. +weight for 25 miles per day.</p> + +<p>In the Tunisian war this railroad of 20 in. gauge, 14 lb. rail, +was replaced by that of two ft. gauge, with 14 lb. and 19 lb. +rails. There were quite as great difficulties as in the Turcoman +campaign, and the country to be crossed was entirely unknown. The +observations made before the war spoke of a flat and sandy country. +In reality a more uneven country could not be imagined; alternating +slopes of about 1 in 10 continually succeeded each other; and +before reaching Kairouan 7½ miles of swamp had to be +crossed. Nevertheless the horses harnessed to the railway carriages +did on an average twelve to seventeen times the work of those +working ordinary carriages. In that campaign also, on account of +the steep ascents, the use of locomotives had to be given up. The +track served not only for the conveying of victuals, war material, +and cannon, but also of the wounded; and a large number of the +survivors of this campaign owe their lives to this railway, which +supplied the means of their speedy removal without great suffering +from the temporary hospitals, and of carrying the wounded to places +where more care could be bestowed upon them.</p> + +<p>The carriages which did duty in this campaign are wagons with a +platform entirely of metal, resting upon eight wheels. The platform +is 13 ft. 1 in. in length, and 3 ft. 11 in. in width. The total +length with buffers is 14 ft. 9 in. This carriage may be at will +turned into a goods wagon or a passenger carriage for sixteen +persons, with seats back to back, or an ambulance wagon for eight +wounded persons.</p> + +<p>For the transport of cannon the French military engineers have +adopted small trucks. A complete equipage, capable of carrying guns +weighing from 3 to 9 tons, is composed of trucks with two or three +axles, each being fitted with a pivot support, by means of which it +is made possible to turn the trucks, with the heaviest pieces of +ordnance, on turntables, and to push them forward without going off +the rails at the curves.</p> + +<p>The trucks which have been adopted for the service of the new +forts in Paris are drawn by six men, three of whom are stationed at +each end of the gun, and these are capable of moving with the +greatest ease guns weighing 9 tons.</p> + +<p>The narrow-gauge railway was tested during the war in Tunis more +than in any preceding campaign, and the military authorities +decided, after peace had been restored in that country, to continue +maintaining the narrow-gauge railways permanently; this is a +satisfactory proof of their having rendered good service. The line +from Sousse to Kairouan is still open to regular traffic. In +January, 1883, an express was established, which leaves Sousse +every morning and arrives at Kairouan--a distance of forty +miles--in five hours, by means of regularly organized relays. The +number of carriages and trucks for the transport of passengers and +goods is 118.</p> + +<p>The success thus attained by the narrow-gauge line goes far to +prove how unfounded is the judgment pronounced by those who hold +that light railways will never suffice for continuous traffic. +These opinions are based on certain cases in the colonies, where it +was thought fit to adopt a light rail weighing about 18 lb. to 27 +lb. per yard, and keeping the old normal gauge. It is nevertheless +evident that it is impossible to construct cheap railways on the +normal gauge system, as the maintenance of such would-be light +railways is in proportion far more costly than that of standard +railways.</p> + +<p>The narrow gauge is entirely in its right place in countries +where, as notably in the case of the colonies, the traffic is not +sufficiently extensive to warrant the capitalization of the +expenses of construction of a normal gauge railway.</p> + +<p>Quite recently the Eastern Railway Company of the province of +Buenos Ayres have adopted the narrow gauge for connecting two of +their stations, the gauge being 24 in. and the weight of the rails +19 lb. per yard. This company have constructed altogether six miles +of narrow-gauge road, with a rolling stock of thirty passenger +carriages and goods trucks and two engines, at a net cost price of +7,500l., the engines included. This line works as regularly as the +main line with which it is connected. The composite carriages in +use leave nothing to be desired with regard to their appearance and +the comforts they offer. Third-class carriages, covered and open, +and covered goods wagons, are also employed.</p> + +<p>All these carriages are constructed according to the model of +those of the Festiniog Railway. The engines weigh 4 tons, and run +at 12½ miles per hour for express trains with a live load of +16 tons; while for goods trains carrying 35 tons the rate is +7½ miles an hour.</p> + +<p>Another purpose for which the narrow-gauge road is of the +highest importance in colonial commerce is the transport of sugar +cane. There are two systems in use for the service of sugar +plantations:</p> + +<p>1. Traction by horses, mules, or oxen.</p> + +<p>2. Traction by steam-engine.</p> + +<p>In the former case, the narrow gauge, 20 in. with 14 lb. rails, +is used, with platform trucks and iron baskets 3 ft. 3 in. +long.</p> + +<p>The use of these wagons is particularly advantageous for +clearing away the sugar cane from the fields, because, as the crop +to be carried off is followed by another harvest, it is important +to prevent the destructive action of the wheels of heavily laden +wagons. The baskets may be made to contain as much as 1,300 lb. of +cane for animal traction, and 2,000 lb. for steam traction. In +those colonies where the cane is not cut up into pieces, long +platform wagons are used entirely made of metal, and on eight +wheels. When the traction is effected by horses or mules, a chain +14½ ft. long is used, and the animals are driven alongside +the road. Oxen are harnessed to a yoke, longer by 20 in. to 24 in. +than the ordinary yoke, and they are driven along on each side of +the road.</p> + +<p>On plantations where it is desirable to have passenger +carriages, or where it is to be foreseen that the narrow-gauge line +maybe required for the regular transport of passengers and goods, +the 20 in. line is replaced by one of 24 in.</p> + +<p>The transport of the refuse of sugar cane is effected by means +of tilting basket carts; the lower part of which consists of plate +iron as in earthwork wagons, while the upper part consists of an +open grating, offering thus a very great holding capacity without +being excessively heavy. The content of these wagons is 90 cubic +feet (2,500 liters). To use it for the transport of earth, sand, or +rubbish, the grating has merely to be taken off. In the case of the +transport of sugar cane having to be effected by steam power, the +most suitable width of road is 24 in., with 19 lb. rails; and this +line should be laid down and ballasted most carefully. The cost of +one mile of the 20 in. gauge road, with 14 lb. rails, thirty basket +wagons, and accessories for the transport of sugar cane, is 700l., +and the total weight of this plant amounts to 35 tons.</p> + +<p>Owing to the great lightness of the portable railways, and the +facility with which they can be worked, the attention of explorers +has repeatedly been attracted by them. The expedition of the Ogowe +in October, 1880, that of the Upper Congo in November, 1881, and +the Congo mission under Savorgnan de Brazza, have all made use of +the Decauville narrow-gauge railway system.</p> + +<p>During these expeditions to Central Africa, one of the greatest +obstacles to be surmounted was the transport of boats where the +river ceased to be navigable; for it was then necessary to employ a +great number of negroes for carrying both the boats and the +luggage. The explorers were, more or less, left to the mercy of the +natives, and but very slow progress could be made.</p> + +<p>On returning from one of these expeditions in Africa, Dr. Balay +and M. Mizon conceived the idea of applying to M. Decauville for +advice as to whether the narrow-gauge line might not be profitably +adapted for the expedition. M. Decauville proposed to them to +transport their boats without taking them to pieces, or unloading +them, by placing them on two pivot trollies, in the same manner as +the guns are transported in fortifications and in the field. The +first experiments were made at Petit-Bourg with a pleasure yacht. +The hull, weighing 4 tons, was placed on two gun trollies, and was +moved about easily across country by means of a portable line of 20 +in. gauge, with 14 lb. rails. The length of the hull was about 45 +ft., depth 6 ft. 7 in., and breadth of beam 8 ft. 2 in., that is to +say, five times the width of the narrow-gauge, and notwithstanding +all this the wheels never came off the line. The sections of line +were taken up and replaced as the boat advanced, and a speed of +1,100 yards per hour was attained. Dr. Balay and M. Mizon declared +that the result obtained exceeded by far their most sanguine hopes, +because during their last voyage, the passage of the rapids had +sometimes required a whole week for 1,100 yards (1 kilometer), and +they considered themselves very lucky indeed if they could attain a +speed of one kilometer per day. The same narrow gauge system has +since been three times adopted by African explorers, on which +occasions it was found that the 20 in. line, with 9 lb. or 14 lb. +rails, was the most suitable for scientific expeditions of this +nature.</p> + +<p>The trucks used are of the kind usually employed for military +purposes, with wheels, axles, and pivot bearings of steel; on being +dismounted the bodies of the two trucks form a chest, which is +bolted together and contains the wheels, axles, and other +accessories. The total weight of the 135 yards of road used by Dr. +Balay and M. Mizon during their first voyage was 2,900 lb., and the +wagons weighed 5,000 lb. Hence the expedition had to carry a +supplementary weight of 3½ tons; but at any given moment the +material forming this burden became the means of transporting, in +its turn, seven boats, representing a total weight of 20 tons.</p> + +<p>It is impossible to enumerate in this paper all the various +kinds of wagons and trucks suitable for the service of iron works, +shipyards, mines, quarries, forests, and many other kinds of works; +and we therefore limit ourselves to mentioning only a few instances +which suffice to show that the narrow gauge can be applied to works +of the most varied nature and under the most adverse circumstances +possible.</p> + +<p>It therefore only remains to mention the various accessories +which have been invented for the purpose of completing the system. +They consist of off-railers, crossings, turntables, etc.</p> + +<p>The off railer is used for establishing a portable line, at any +point, diverging to the right or left of a permanent line, and for +transferring traffic to it without interruption. It consists of a +miniature inclined plane, of the same height at one end as the +rail, tapering off regularly by degrees toward the other end. It is +only necessary to place the off-railer (which, like all the lengths +of rail of this system, forms but one piece with its sleepers and +fish-plates) on the fixed line, adding a curve in the direction it +is intended to go, and push the wagons on to the off-railer, when +they will gradually leave the fixed line and pass on the new +track.</p> + +<p>The switches consist of a rail-end 49 in. in length, which +serves as a movable tongue, placed in front of a complete crossing, +the rails of which have a radius of 4, 6, or 8 meters; a push with +the foot suffices to alter the switch. There are four different +models of crossings constructed for each radius, viz.:</p> + +<p>1. For two tracks with symmetrical divergence.</p> + +<p>2. For a curve to the right and a straight track.</p> + +<p>3. For a curve to the left and a straight track.</p> + +<p>4. For a meeting of three tracks.</p> + +<p>When a fixed line is used, it is better to replace the movable +switch by a fixed cast-iron switch, and to let the workmen who +drive the wagon push it in the direction required. Planed switch +tongues are also used, having the shape of those employed on the +normal tracks, especially for the passage of small engines; the +switches are, in this case, completed by the application of a hand +lever.</p> + +<p>The portable turntable consists of two faced plates laid over +the other, one of thick sheet iron, and the other of cast iron. The +sheet-iron plate is fitted with a pivot, around which the cast iron +one is made to revolve; these plates may either be smooth, or +grooved for the wheels. The former are used chiefly when it is +required to turn wagons or trucks of light burden, or, in the case +of earthworks, for trucks of moderate weight. These plates are +quite portable; their weight for the 16 in. gauge does not exceed +200 lb. For engineering works a turntable plate with variable width +of track has been designed, admitting of different tracks being +used over the same turntable.</p> + +<p>When turntables are required for permanent lines, and to sustain +heavy burdens, turntables with a cast iron box are required, +constructed on the principle of the turntables of ordinary +railways. The heaviest wagons may be placed on these box +turntables, without any portion suffering damage or disturbing the +level of the ground. In the case of coal mines, paper mills, cow +houses with permanent lines, etc., fixed plates are employed. Such +plates need only be applied where the line is always wet, or in +workshops where the use of turntables is not of frequent +occurrence. This fixed plate is most useful in farmers' stables, as +it does not present any projection which might hurt the feet of the +cattle, and is easy to clean.</p> + +<p>The only accident that can happen to the track is the breaking +of a fish-plate. It happens often that the fish-plates get twisted, +owing to rough handling on the part of the workmen, and break in +the act of being straightened. In order to facilitate as much as +possible the repairs in such cases, the fish-plates are not riveted +by machinery, but by hand; and it is only necessary to cut the +rivets with which the fish-plate is fastened, and remove it if +broken: A drill passed through the two holes of the rail removes +all burrs that may be in the way of the new rivet. No vises are +required for this operation; the track to be repaired is held by +two workmen at a height of about 28 in. above the ground, care +being taken to let the end under repair rest on a portable anvil, +which is supplied with the necessary appliances. The two +fish-plates are put in their place at the same time, the second +rivet being held in place with one finger, while the first is being +riveted with a hammer; if it is not kept in its place in this +manner it may be impossible to put it in afterward, as the blows of +the hammer often cause the fish-plate to shift, and the holes in +the rail are pierced with great precision to prevent there being +too much clearance. No other accident need be feared with this +line, and the breakage described above can easily be repaired in a +few minutes without requiring any skilled workman.</p> + +<p>The narrow-gauge system, which has recently received so great a +development on the Continent, since its usefulness has been +demonstrated, and the facility with which it can be applied to the +most varied purposes, has not yet met in England with the same +universal acceptance; and those members of this Institution who +crossed the sea to go to Belgium were, perhaps, surprised to see so +large a number of portable railways employed for agricultural and +building purposes and for contractors' works. But in the hands of +so practical a people it may be expected that the portable narrow +gauge railway will soon be applied even to a larger number of +purposes than is the case elsewhere.</p> + +<hr> +<p><a name="12"></a></p> + +<h2>GERARD'S ALTERNATING CURRENT MACHINE.</h2> + +<p>The machine represented in the annexed engravings consists of a +movable inductor, whose alternate poles pass in front of an +armature composed of a double number of oblong and flat bobbins, +that are affixed to a circle firmly connected with the frame. There +is a similar circle on each side of the inductor. The armature is +stationary, and the wires that start from the bobbins are connected +with terminals placed upon a wooden support that surmounts the +machine.</p> + +<p class="ctr"><a href="./illustrations/7b.png"><img src= +"./illustrations/7b_th.jpg" alt= +"GERARD'S ALTERNATING ELECTRIC MACHINE."></a></p> + +<p class="ctr">GERARD'S ALTERNATING ELECTRIC MACHINE.</p> + +<p>This arrangement allows of every possible grouping of the +currents according to requirements. Thus, the armature may be +divided into two currents, so as to allow of carbons 30 mm. in +diameter being burned, or else so as to have four, eight, twelve, +twenty-four, or even forty-eight distinct circuits capable of being +used altogether or in part.</p> + +<p>This machine has been studied with a view of rendering the lamps +independent; and there may be produced with it, for example, a +voltaic arc of an intensity of from 250 to 600 carcels for the +lighting of a courtyard, or it may be used for producing arcs of +less intensity for shops, or for supplying incandescent lamps. As +each of the circuits is independent, it becomes easy to light or +extinguish any one of the lamps at will. Since the conductors are +formed of ordinary simple wires, the cost attending the +installation of 12 or 24 lamps amounts to just about the same as it +would in the case of a single cable.</p> + +<p class="ctr"><a href="./illustrations/7a.png"><img src= +"./illustrations/7a_th.jpg" alt= +"GERARD'S 250 H.P. DIRECT CONNECTION ALTERNATING CURRENT STEAM DYNAMO-ELECTRIC MACHINE."> +</a></p> + +<p class="ctr">GERARD'S 250 H.P. DIRECT CONNECTION ALTERNATING +CURRENT STEAM DYNAMO-ELECTRIC MACHINE.</p> + +<p>One of the annexed cuts represents a Corliss steam engine +connected directly with an alternating current machine of the +system under consideration. According to the inventor, this machine +is capable of supplying 1,000 lamps of a special kind, called +"slide lamps," and a larger number of incandescent ones.--<i>Revue +Industrielle</i>.</p> + +<hr> +<p><a name="13"></a></p> + +<h2>AUTOMATIC FAST SPEED TELEGRAPHY.</h2> + +<h3>By THEO. F. TAYLOR.</h3> + +<p>Since 1838 much has been done toward increasing the carrying +capacity of a single wire. In response to your invitation I will +relate my experience upon the Postal's large coppered wire, in an +effort to transmit 800 words per minute over a 1,000 mile circuit, +and add my mite to the vast sum of knowledge already possessed by +electricians.</p> + +<p>As an introduction, I shall mention a few historical facts, but +do not propose to write in this article even a short account of the +different automatic systems, and I must assume that my readers are +familiar with modern automatic machines and appliances.</p> + +<p>In 1870, upon the completion of the Automatic Company's 7 ohm +wire between New York and Washington, it happened that Prof. Moses +G. Farmer was in the Washington office when the first message was +about to be sent, and upon being requested, he turned the "crank" +and transmitted the message to New York, at the rate of 217 words +per minute.</p> + +<p>Upon his return to New York he co-operated with Mr. Prescott in +experiments on W.U. wires, their object being to determine what +could be done on iron wires with the Bain system. A good No. 8 wire +running from New York to Boston was selected, reinsulated, well +trimmed, and put in first-class electrical condition, previous to +the test. The "Little" chemical paper was used.</p> + +<p>The maximum speed attained on this wire was 65 words per +minute.</p> + +<p>About the same time George H. Grace used an electro magnet on +the automatic line with such good effect that the speed on the New +York-Washington circuit was increased to 450 words per minute.</p> + +<p>Then a platina stylus or pen was substituted for the iron pen in +connection with iodide paper, and the speed increased to 900 words +per minute.</p> + +<p>In 1880, upon the completion of the Rapid Company's 6 ohm wire, +between New York and Boston, 1,200 words per minute were +transmitted between the cities above named.</p> + +<p>In 1882, I was employed by the Postal Telegraph Company to put +the Leggo automatic system into practical shape, and, if possible, +transmit 800 words per minute between New York and Chicago.</p> + +<p>It was proposed to string a steel-copper wire, the copper on +which was to weigh 500 lb. to the mile.</p> + +<p>When complete, the wire was rather larger than No. 3, English +gauge, but varied in diameter, some being as large as No. 1, and it +averaged 525 lb. of copper per mile and = 1.5 ohms. The surface of +this wire was, however, large.</p> + +<p>Dr. Muirhead estimated its static capacity at about 10 M.F., +which subsequent tests proved to be nearly correct.</p> + +<p>It will be understood that this static capacity stood in the way +of fast transmission.</p> + +<p>Resistance and static capacity are the two factors that +determine speed of signaling.</p> + +<p>The duration of the variable state is in proportion to the +square of the length of the conductor, so that the difficulties +increase very greatly as the wire is extended beyond ordinary +limits. According to Prescott, "The duration of the variable +condition in a wire of 500 miles is 250,000 times as long as in a +wire of 1 mile."</p> + +<p>In other words, a long line <i>retains a charge</i>, and time +must be allowed for at least a falling off of the charge to a point +indicated by the receiving instrument as zero.</p> + +<p>In the construction of the line care was taken to insure the +<i>lowest possible resistance</i> through the circuit, even to the +furnishing of the river cables with conductors weighing 500 lb. per +mile.</p> + +<p>Ground wires were placed on every tenth pole.</p> + +<p>When the first 100 miles of wire had been strung, I was much +encouraged to find that we could telegraph without any difficulty +past the average provincial "ground," provided the terminal grounds +were good.</p> + +<p>When the western end of this remarkable wire reached Olean, +N.Y., 400 miles from New York, my assistant, Mr. S.K. Dingle, +proceeded to that town with a receiving instrument, and we made the +first test.</p> + +<p>I found that 800 words, or 20,000 impulses, per minute, could be +transmitted in Morse characters over that circuit <i>without +compensation</i> for static.</p> + +<p>In other words, the old Bain method was competent to telegraph +800 words per minute on the 400 miles of 1.5 ohm wire.</p> + +<p>The trouble began, however, when the wire reached Cleveland, O., +about 700 miles from New York.</p> + +<p>Upon making a test at Cleveland, I found the signals made a +continuous black line upon the chemical paper. I then placed both +ends of the wire to earth through 3,000 ohms resistance, and +introduced a small auxiliary battery between the chemical paper and +earth.</p> + +<p>The auxiliary or opposing battery was placed in the same circuit +with the transmitting battery, and the currents which were +transmitted from the latter through the receiving instrument +reached the earth by passing directly through the opposing +battery.</p> + +<p>The circuit of the opposing battery was permanently completed, +independently of the transmitting apparatus, through both branch +conductors and artificial resistances.</p> + +<p>The auxiliary battery at the receiving station normally +maintained upon the main line a continuous electric current of a +negative polarity, which did not produce a mark upon the chemical +paper.</p> + +<p>When the transmitting battery was applied thereto, the excessive +electro-motive force of the latter overpowered the current from the +auxiliary battery and exerted, by means of a positive current, an +electro-chemical action upon the chemical receiving paper, +producing a mark.</p> + +<p>Immediately upon the interruption of the circuit of the +transmitting battery, the unopposed current from the auxiliary +battery at the receiving station flowed back through the paper and +into the main line, thereby both neutralizing the residual or +inductive current, which tended to flow through the receiving +instrument, and serving to clear the main line from electro-static +charge.</p> + +<p>The following diagram illustrates my method:</p> + +<p>Referring to this diagram, A and B respectively represent a +transmitting and a receiving station of an automatic telegraph. +These stations are united in the usual manner by a main line, L. At +the transmitting station, A, is placed a transmitting battery, E, +having its positive pole connected by a conductor, 2, with the +metallic transmitting drum, T. The negative pole of the battery, E, +is connected with the earth at G by a conductor, 1. A metallic +transmitting stylus, t, rests upon the surface of the drum, T, and +any well known or suitable mechanism may be employed for causing an +automatic transmitting pattern slip, P, to pass between the stylus +and the drum. The transmitting or pattern slip, P, is perforated +with groups of apertures of varying lengths and intervals as +required to represent the dispatch which it is desired to transmit, +by an arbitrary system of signs, such, for example, as the Morse +telegraphic code.</p> + +<p>At the receiving station, B, is placed a recording apparatus, M, +of any suitable or well known construction. A strip of chemically +prepared paper, N, is caused to pass rapidly and uniformly between +the drum, M', and the stylus, m, of this instrument in a well known +manner. The drum, M', is connected with the earth by conductors, 4 +and 3, between which is placed the auxiliary battery, E, the +positive or marking pole of this battery being connected with the +drum and the negative pole with the earth. The electro-motive force +of the battery, E', is preferably made about one-third as great as +that of the battery, E.</p> + +<p class="ctr"><img src="./illustrations/8a.png" alt=""></p> + +<p>Extending from a point, o, in the main line, near the +transmitting station, to the earth at G, is a branch conductor, l, +containing an adjustable artificial resistance, R. A similar +conductor, ll, extends from a point, o', near the receiving +terminal of the line, L, to the conductor, 3, in which an +artificial resistance, R', is also included, this resistance being +preferably approximately equal to the resistance, R. The +proportions of the resistance of the main line and the artificial +resistances which I prefer to employ may be approximately indicated +as follows: Assuming the resistance of the main line to be 900 +ohms, the resistance, R, and R', should be each about 3,000 ohms. +The main battery, E, should then comprise about 90 cells, and the +auxiliary battery, E', 30 cells.</p> + +<p>The operation of my improved system is as follows: While the +apparatus is at rest a constant current from the battery, E', +traverses the line, L, and the branch conductors, l, and ll, +dividing itself between them, in inverse proportion to their +respective resistances, in accordance with the well-known law of +Ohm. When the transmitting pattern strip, P, is caused to pass +between the roller, T, and the stylus, t, electric impulses will be +transmitted upon the line, L, from the positive pole of the +battery, E, which will traverse the main line, L, the two branch +lines, l, and ll, and their included resistances, and also the +receiving instrument, M. The greater portion of this current will, +however, on account of the less resistance offered, traverse the +receiving instrument, M, and the auxilary battery, E'. The current +from the last-named battery will thus be neutralized and +overpowered, and the excess of current from the main battery, E, +will act upon the chemically prepared paper and record in the form +of dots and dashes or like arbitrary characters the impulses which +are transmitted.</p> + +<p>Immediately on the cessation of each impulse, the auxiliary +battery, E', again acts to send an impulse of positive polarity +through the receiving paper and stylus in the reverse direction and +through the line, L, which returns to the negative pole of the +battery by way of the artificial resistances, R and R'. Such an +impulse, following immediately upon the interruption of the circuit +of the transmitting battery, acts to destroy the effect of the +"tailing" or static discharge of the line, L, upon the receiving +instrument, and also to neutralize the same throughout the line. By +thus opposing the discharge of the line by a reverse current +transmitted directly through the chemical paper, a sharply defined +record will in all cases be obtained; and by transmitting the +opposing impulse through the line, the latter will be placed in a +condition to receive the next succeeding impulse and to record the +same as a sharply defined character.</p> + +<p>This arrangement was made on the New York-Cleveland circuit, and +the characters were then clearly defined and of uniform +distinctness. The speed of transmission on this circuit was from +1,000 to 2,000 words per minute.</p> + +<p>Upon the completion of the wire to Chicago, total distance 1,050 +miles, including six miles of No. 8 iron wire through the city, the +maximum speed was found to be 1,200 words per minute, and to my +surprise the speed was not affected by the substitution of an +underground conductor for the overhead wire.</p> + +<p>The underground conductor was a No. 16 copper wire weighing 67 +pounds per mile, in a Patterson cable laid through an iron +pipe.</p> + +<p>I used 150 cells of large Fuller battery on the New York-Chicago +circuit, and afterward with 200 cells in first class condition, +transmitted 1,500 words, or 37,000 impulses, per minute from 49 +Broadway, New York, to our test office at Thirty-ninth Street, +Chicago.</p> + +<p>The matter was always carefully counted, and the utmost care +taken to obtain correct figures.</p> + +<p>It may be mentioned as a curious fact that we not only send +1,200 words per minute through 1,050 miles of overhead wire and +five miles of underground cable, but also through a second +conductor in No. 2 cable back to Thirty-ninth Street, and then +connected to a third underground conductor in No. 1 cable back to +Chicago main office, in all about fifteen miles of underground, +through which we sent 1,200 words per minute and had a splendid +margin.--<i>Electrical World</i>.</p> + +<hr> +<p>[ELECTRICAL REVIEW].</p> + +<p><a name="14"></a></p> + +<h2>THEORY OF THE ACTION OF THE CARBON MICROPHONE--WHAT IS IT?</h2> + +<p>A careful examination of the opinions of scientific men given in +the telephone cases--before Lord McLaren in Edinburgh and before +Mr. Justice Fry in London--leads me to the conclusion that +scientific men, at least those whose opinions I shall quote, are +not agreed as to what is the action of the carbon microphone.</p> + +<p>In the Edinburgh case, Sir Frederick Bramwell said: "The +variations of the currents are effected so as to produce with +remarkable fidelity the varied changes which occur, according as +the carbon is compressed or relieved from compression by the gentle +impacts of the air set in motion by the voice."</p> + +<p>"The most prominent quality of carbon is its capability, under +the most minute differences of pressure, to enormously increase or +decrease the resistances of the circuit." "That the varying +pressure of the black tension-regulator (Edison's) is sufficient to +cause a change in the conducting power." Sir Frederick also said +"he could not believe that the resistance was varied by a jolting +motion; could not conceive a jolting motion producing variation and +difference of pressure, and such an instrument could not be relied +on, and therefore would be practically useless."</p> + +<p>Sir William Thomson, in the same case, said: "The function of +the carbon is to give rise to diminished resistance by pressure; it +possesses the quality of, under slight degrees of pressure, +decreasing the resistance to the passage of the electric current;" +and, also, "the jolting motion would be a make-and-break, and the +articulate sounds would be impaired. There can be no virtue in a +speaking telephone having a jolting motion." "Delicacy of contact +is a virtue; looseness of contact is a vice." "Looseness of contact +is a great virtue in Hughes' microphone;" and "the elements which +work advantages in Hughes' are detrimental to the good working of +the articulating instrument."</p> + +<p class="ctr"><img src="./illustrations/8b.png" alt="Fig. 1."></p> + +<p class="ctr">Fig. 1.</p> + +<p>Mr. Falconer King said: "There would be no advantage in having a +jolting motion; the jolting motion would break the circuit and be a +defect in the speaking telephone," and "you must have pressure and +partially conducting substances."</p> + +<p>Professor Fleeming Jenkin said, "The pressure of the carbons is +what favors the transmission of sound."</p> + +<p>All the above named scientific men agree that variations of a +current passing through a carbon microphone are produced by +<i>pressure</i> of the carbons against one another, and they also +agree that a jolting motion could not be relied upon to reproduce +articulate speech.</p> + +<p>Mr. Conrad Cooke said, "The first and most striking principle of +Hughes' microphone is a shaking and variable contact between the +two parts constituting the microphone." "The shaking and variable +contact is produced by the movable portion being effected by +sound." "Under Hughes' system, where gas carbon was used, the +instruments could not possibly work upon the principle of +pressure." "I am satisfied that it is not pressure in the sense of +producing a change of resistance." "I do not think pressure has +anything to do with it."</p> + +<p>Professor Blyth said: "The Hughes microphone depends essentially +upon the looseness or delicacy of contact." "I have heard +articulate speech with such an instrument without a diaphragm." +"There is no doubt that to a certain extent there must be a change +in the number of points of surface contact when the pencil is +moved." "The action of the Hughes microphone depends more or less +upon the looseness or delicacy of the contact and upon the changes +in the number of points of surface contact when the pencil is +moved."</p> + +<p>Mr. Oliver Heaviside, in <i>The Electrician</i> of 10th February +last, writes: "There should be no jolting or scraping." "Contacts, +though light, should not be loose."</p> + +<p class="ctr"><img src="./illustrations/8c.png" alt="Fig. 2."></p> + +<p class="ctr">Fig. 2.</p> + +<p>A writer, who signs "W.E.H.," in <i>The Electrician</i> of 24th +February last, says: "The variation of current arises from a +variation of conductivity between the electrodes, consequent upon +the variation of the closeness or pressure of contact;" and also, +"there must be a variation of pressure between the electrodes when +the transmitter is in action."</p> + +<p>It seems, then, that some scientific men agree that variation of +pressure is required to produce action in a microphone, and some of +them admit that a microphone with loose contacts will transmit +articulate speech, while others deny it, and some admit that a +jolting or shaking motion of the parts of the microphone does not +interfere with articulate speech, while others say such motion +would break the circuit, and cannot be relied on.</p> + +<p>I will now describe two microphones in which there is a shaking +or jolting motion, and loose contacts, and no variation of pressure +of the carbons against one another, and both of these microphones +when used with an induction coil and battery give most excellent +articulation. One of these microphones is made as follows: Two flat +plates of carbon are secured to a block of cork, insulated from +each other; into a hole of each carbon a pin of carbon fits +loosely, projecting above the carbons; another flat piece of +carbon, having two holes in it, bridges over the two lower carbons, +being kept in its place by the pins of carbon which fit loosely in +the holes in it, the bottom carbons being connected with the +battery; a block of cork has a flat side of it cut out so as when +secured to the lower cork the carbons will not come in contact with +it, yet be close enough to it to keep the carbons from falling +apart. The cork covering the carbons forms a dome.</p> + +<p>Any good telephone receiver when used in connection with this +microphone, reproduces articulate speech with remarkable +distinctness, especially hissing sounds, and with a loud and full +tone.</p> + +<p>A description of this microphone was published in <i>La Lumiere +Electrique</i>, of 15th April, 1882, and a drawing thereof on 29th +April of same year.</p> + +<p>Another form of microphone is made as follows: Two blocks of gas +carbon, C, B, each about one and a half inches long and one inch +square, having each a circular hole one and a quarter inches deep +and half inch in diameter; these two blocks are embedded in a block +of cork, C, about one-quarter of an inch apart, these holes facing +each other, each block forming a terminal of the battery and +induction coil; a pencil of carbon, C, P, about three-eighths of an +inch in diameter, and two inches long, having a ring of ebonite, V, +fixed around its center, is placed in the holes of the two fixed +blocks; the ebonite ring fitting loosely in between the two blocks +so as to prevent the pencil from touching the bottom of the holes +in the blocks. The space between the blocks is closed with wax, W, +to exclude the air, but not to touch the ring on the pencil. A +block of cork fitting close to the carbon blocks on all sides is +then firmly secured to the other block of cork. The microphone +should lie horizontally or at a slight angle.</p> + +<p>This microphone produces in any good telephone perfect +articulation in a loud and full tone. In these microphones there is +certainly "looseness and delicacy of contact," and there is a +"jolting or shaking motion," and it does not seem possible that +there can be any "pressure of one carbon against another."</p> + +<p>I repeat the question I asked at the beginning of this +communication, and hope that it may elicit from you, or some of our +scientific men, an explanation of the theory of the action of this +form of microphone.</p> + +<p>W.C. BARNEY.</p> + +<hr> +<p><a name="15"></a></p> + +<h2>THE DEMBINSKI MICROPHONIC TELEPHONE TRANSMITTER.</h2> + +<p>This apparatus, which is shown by Figs. 1, 2, and 3, consists of +a wooden case, A, of oblong shape, closed by a lid fixed by hinges +to the top or one side of the case. The lid is actually a frame for +holding a piece of wire gauze, L L, through which the sound waves +from the voice can pass. In the case a flat shallow box, E F (or +several boxes), is placed, on the lid of which the carbon +microphone, D C (Figs. 1 and 3), which is of the ordinary +construction, is placed. The box is of thin wood, coated inside +with petroleum lamp black, for the purpose of increasing the +resonance. It is secured in two lateral slides, fixed to the case. +The bottom of the box is pierced with two openings, resembling +those in a violin (Fig. 2). Lengthwise across the bottom are +stretched a series of brass spiral springs, G G G, which are tuned +to a chromatic scale. On the bottom of the case a similar series of +springs, not shown, are secured. The apparatus is provided with an +induction coil, J, which is connected to the microphone, battery, +and telephone receiver (which may be of any known description) in +the usual manner.</p> + +<p class="ctr"><img src="./illustrations/9a.png" alt="Fig. 1."></p> + +<p class="ctr">Fig. 1.</p> + +<p>The inventors claim that the use of the vibrating springs give +to the transmitter an increased power over those at present in use. +They state that the instrument has given very satisfactory results +between Ostende and Arlon, a distance of 314 kilometers (about 200 +miles). It does not appear, however, that microphones of the +ordinary Gower-Bell type, for example, were tried in competition +with the new invention, and in the absence of such tests the mere +fact that very satisfactory results were obtained over a length of +200 miles proves very little. With reference to a statement that +whistling could be very clearly heard, we may remark that +experience has many times proved that the most indifferent form of +transmitter will almost always respond well and even powerfully to +such forms of vibration.--<i>Electrical Review</i>.</p> + +<p class="ctr"><img src="./illustrations/9b.png" alt="Fig. 2."></p> + +<p class="ctr">Fig. 2.</p> + +<p class="ctr"><img src="./illustrations/9c.png" alt="Fig. 3."></p> + +<p class="ctr">Fig. 3.</p> + +<hr> +<p><a name="16"></a></p> + +<h2>NEW GAS LIGHTERS.</h2> + +<p>We are going to make known to our readers two new styles of +electric lighters whose operation is sure and quick, and the use of +which is just as economical as that of those quasi-incombustible +little pieces of wood that we have been using for some years under +the name of matches.</p> + +<p class="ctr"><img src="./illustrations/9d.png" alt= +"Fig. 1.--MODE OF USING THE GAS LIGHTER."></p> + +<p class="ctr">Fig. 1.--MODE OF USING THE GAS LIGHTER.</p> + +<p>The first of these is a portable apparatus designed for lighting +gas burners, and is based upon the calorific properties of the +electric spark produced by the induction bobbin. Its internal +arrangement is such as to permit of its being used with a pile of +very limited power and dimensions. The apparatus has the form of a +rod of a length that may be varied at will, according to the height +of the burner to be lighted, and which terminates at its lower part +in an ebonite handle about 4 centimeters in width by 20 in length +(Fig. 1). This handle is divided into two parts, which are shown +isolatedly in Fig. 2, and contains the pile and bobbin. The +arrangement of the pile, A, is kept secret, and all that we can say +of it is that zinc and chloride of silver are employed as a +depolarizer. It is hermetically closed, and carries at one of its +extremities a disk, B, and a brass ring, C, attached to its poles +and designed to establish a communication between the pile and +bobbin when the two parts of the apparatus are screwed together. To +this end, two elastic pieces, D and E, fit against B and C and +establish a contact. It is asserted that the pile is capable of +being used 25,000 times before it is necessary to recharge it. H is +an ebonite tube that incloses and protects the induction bobbin, K, +whose induced wire communicates on the one hand with the brass +tube, L, and on the other with an insulated central conductor, M, +which terminates at a point very near the extremity of the brass +tube. The currents induced in this wire produce a series of sparks +between the tube, L, and the rod, M, which light the gas when the +extremity of the apparatus is placed in proximity with the +burner.</p> + +<p class="ctr"><a href="./illustrations/9e.png"><img src= +"./illustrations/9e_th.jpg" alt= +"Fig. 2. MECHANISM OR THE INDUCTION SPARK GAS LIGHTER."></a></p> + +<p class="ctr">Fig. 2. MECHANISM OR THE INDUCTION SPARK GAS +LIGHTER.</p> + +<p>The ingenious and new part of the system lies in the mode of +exciting the induced currents. When the extremity of the tube, L, +is brought near the gas burner that is to be lighted, it is only +necessary to shove the botton, F, from left to right in order to +produce a <i>limited</i> number of sparks sufficient to effect the +lighting. The motion of the button has not for effect, as might be +believed, the closing of the circuit of the pile upon the inducting +circuit of the bobbin. In fact in its normal position, the vibrator +is distant from its contact, and the closing of the circuit would +produce no action. The motion of F produces a <i>mechanical</i> +motion of the spring of the vibrator, which latter acts for a few +instants and produces a certain number of contacts that give rise +to an equal number of sparks. Owing to this arrangement, the +expenditure of electric energy required by each lighting is +limited; and, an another hand, the vibrator, which would be +incapable of operating if it had to be set in motion by the direct +current from the pile, can be actuated <i>mechanically</i>. As the +motion of the vibrator is derived from the hand of the operator, +and not from the pile, it will be comprehended that the latter can, +everything being equal, produce a larger number of lightings than +an ordinary bobbin and vibrator.</p> + +<p class="ctr"><img src="./illustrations/9f.png" alt= +"Fig. 3.--INCANDESCENT GAS LIGHTER."></p> + +<p class="ctr">Fig. 3.--INCANDESCENT GAS LIGHTER.</p> + +<p>Dr. Naret's <i>Fiat Lux</i> (Fig. 3) is simpler in its +operation, and cheaper of application, since it takes its current +from the ordinary piles that supply domestic call-bells. It +consists essentially of a fine platinum wire supported by a tilting +device in connection with the two poles of a pile composed of three +Leclanche elements. Upon exerting a vertical pressure on the button +placed to the left of the apparatus, either directly or by means of +a cord, we at the same time turn the cock and cause the platinum +spiral to approach, and the latter then becomes incandescent as a +consequence of the closing of the circuit of the pile. After the +burner is lighted it is only necessary to leave the apparatus to +itself. The cock remains open, the spiral recedes from the burner, +the circuit opens anew, and the burner remains lighted until the +gas is turned off. This device, then, is particularly appropriate +in all cases where there is a pressing need of light, for a single +maneuver suffices to open the cock and effect a lighting of the +burner.--<i>La Nature</i>.</p> + +<hr> +<p><a name="17"></a></p> + +<h2>DISTRIBUTION OF HEAT WHICH IS DEVELOPED BY FORGING.</h2> + +<p>On the 8th of June. 1874, Tresca presented to the French Academy +some considerations respecting the distribution of heat in forging +a bar of platinum, and stated the principal reasons which rendered +that metal especially suitable for the purpose. He subsequently +experimented, in a similar way, with other metals, and finally +adopted Senarmont's method for the study of conductibility. A steel +or copper bar was carefully polished on its lateral faces, and the +polished portion covered with a thin coat of wax. The bar thus +prepared was placed under a ram, of known weight, P, which was +raised to a height, H, where it was automatically released so as to +expend upon the bar the whole quantity of work <i>T=PH,</i> between +the two equal faces of the ram and the anvil. A single shock +sufficed to melt the wax upon a certain zone and thus to limit, +with great sharpness, the part of the lateral faces which had been +raised during the shock to the temperature of melting wax. +Generally the zone of fusion imitates the area comprised between +the two branches of an equilateral hyperbola, but the fall can be +so graduated as to restrict this zone, which then takes other +forms, somewhat different, but always symmetrical. If A is the area +of this zone, b the breadth of the bar, d the density of the metal, +c its capacity for heat, and t-t<sub>0</sub> the excess of the +melting temperature of wax over the surrounding temperature, it is +evident that, if we consider A as the base of a horizontal prism +which is raised to the temperature t, the calorific effect may be +expressed by:</p> + +<p> + Ab x d x C(t-t<sub>0</sub>); +</p> + +<p>and on multiplying this quantity of heat by 425 we find, for the +value of its equivalent in work,</p> + +<p> + T' = 425 AbdC(t-t<sub>0</sub>). +</p> + +<p>On comparing T' to T we may consider the experiment as a +mechanical operation, having a minimum of:</p> + +<p> + T'/T = (425/PH)AbdC(t-t<sub>0</sub>). +</p> + +<p>After giving diagrams and tables to illustrate the geometrical +disposition of the areas of fusion, Tresca feels justified in +concluding that the development of heat depends upon the form of +the faces and the intensity of the shock; that the points of +greatest heat correspond to the points of greatest flow of the +metal, and that this flow is really the mechanical phenomenon which +gives rise to the calorific phenomenon; that for action +sufficiently energetic and for bars of sufficient dimensions, about +0.8 of the labor expended on the blow may be found again in the +heat; that the figures formed in the melted wax for shocks of less +intensity furnish a kind of diagram of the distribution of the heat +and of the deformation in the interior of the bar, but that the +calculation of the coefficient of efficiency does not yield +satisfactory results in the case of moderate blows.--<i>Comptes +Rendus</i>.</p> + +<hr> +<p><a name="1"></a></p> + +<h2>TIN IN CANNED FOODS.</h2> + +<p>[Footnote: Read at an evening meeting of the Pharmaceutical +Society, March 5, 1884.]</p> + +<h3>By PROFESSOR ATTFIELD, F.R.S., ETC.</h3> + +<p>From time to time, during the past twelve years, paragraphs have +appeared in newspapers and other periodicals tending in effect to +warn the public at least against the indiscriminate use of canned +foods. And whenever there has been any foundation in fact for such +cautions, it has commonly rested on the alleged presence and +harmfulness of tin in the food. At the worst, the amount of tin +present has been absurdly small, affording an opportunity for one +literary representative of medicine to state that before a man +could be seriously affected by the tin, even if it occurred in the +form of a compound of the metal, he would have to consume at a meal +ten pounds of the food containing the largest amount of tin ever +detected.</p> + +<p>But the greatest proportions of tin thus referred to are, +according to my experiments, far beyond those ever likely to be +actually present in the food itself in the form of a compound of +tin; present, that is to say, on account of the action of the +fluids or juices of the food on the tin of the can. Such action and +such consequent solution of the tin, and consequent admixture of a +possibly assimilable compound of tin with the food, in my opinion +never occurs to an extent which in relation to health has any +significance whatever. The occurrence of tin, not as a compound, +but as the metal itself, is, if possible, still less important.</p> + +<p>During the last fifteen years I have frequently examined canned +foods, not only with respect to the food itself as food, and to the +process of canning, but with regard to the relation of the food to, +or the influence if any of the metal of, the can itself. So lately +as within the past two or three months I have examined sixteen +varieties of canned food for metals, with the following +results:</p> + +<pre> + Decimal parts of + a grain of tin + (or other foreign + metal) present in + Name of article a quarter of a lb. + examined. +<br> + Salmon none. + Lobsters none. + Oysters 0.004 + Sardines none. + Lobster paste none. + Salmon paste none. + Bloater paste 0.002 + Potted beef none. + Potted tongue none. + Potted "Strasbourg" none. + Potted ham 0.002 + Luncheon tongue 0.003 + Apricots 0.007 + Pears 0.003 + Tomatoes 0.007 + Peaches 0.004 +</pre> + +<p>These proportions of metal are, I say, undeserving of serious +notice. I question whether they represent more than the amounts of +tin we periodically wear off tin saucepans in preparing food--a +month ago I found a trace of tin in water which had been boiled in +a tin kettle--or the silver we wear off our forks and spoons. There +can be little doubt that we annually pass through our systems a +sensible amount of such metals, metallic compounds, and other +substances that do not come under the denomination of food; but +there is no evidence that they ever did or are ever likely to do +harm or occasion us the slightest inconvenience. Harm is far more +likely to come to us from noxious gases in the air we breathe than +from foreign substances in the food we eat.</p> + +<p>But whence come the much less minute amounts of tin--still +harmless, be it remembered--which have been stated to be +occasionally present in canned foods? They come from the minute +particles of metal chipped off from the tin sheets in the +operations of cutting, bending, or hammering the parts of the can, +or possibly melted off in the operations necessary for the +soldering together of the joints of the can. Some may, perhaps, be +cut, off by the knife in opening a can. At all events I not +unfrequently find such minute particles of metal on carefully +washing the external surfaces of a mass of meat just removed from a +can, or on otherwise properly treating canned food with the object +of detecting such particles. The published processes for the +detection of tin in canned food will not reveal more than the +amounts stated in the table, or about those amounts; that is to +say, a few thousandths or perhaps two or three hundredths of a +grain, if this precaution be adopted. If such care be not observed, +the less minute amounts may be found. I did not detect any metallic +particles in the twelve samples of canned food just mentioned, but +during the past few years I have occasionally found small pieces of +metal, perhaps amounting in some of the cases to a few tenths of a +grain per pound. Now and then small shot-like pieces of tin, or +possibly solder, may be met with; but no one has ever found, to my +knowledge, such a quantity of actual metallic tin, tinned iron, or +solder as, from the point of view of health, can have any +significance whatever.</p> + +<p>The largest amount of tin I ever detected in actual solution in +food was in some canned soup, containing a good deal of lemon +juice. It amounted to only three-hundredths of a grain in a half +pint of the soup as sent to table. Now, Christison says that +quantities of 18 to 44 grains of the very soluble chloride of tin +were required to kill dogs in from one to four days. Orfila says +that several persons on one occasion dressed their dinner with +chloride of tin, mistaking it for salt. One person would thus take +not less than 20 to 30 grains of this soluble compound of tin. Yet +only a little gastric and bowel disturbance followed, and from this +all recovered in a few days. Pereira says that the dose of chloride +of tin as an antispasmodic and stimulant is from 1/16 to ½ a +grain repeated two or three times daily. Probably no article of +canned food, not even the most acid fruit, if in a condition in +which it can be eaten, has ever contained, in an ordinary table +portion, as much of a soluble salt of tin as would amount to a +harmless or useful medicinal dose.</p> + +<p>Metallic particles of tin are without any effect on man. A +thousand times the quantity ever found in a can of tinned food +would do no harm.</p> + +<p>Food as acid as say ordinary pickles would dissolve tin. Some +manufacturers once proposed using tin stoppers to their bottles of +pickles. But the tin was slowly dissolved by the acid of the +vinegar. These pickles, however, had a distinctly nasty "metallic" +flavor. The idea was abandoned. Probably any article of food +containing enough tin to disagree with the system would be too +nasty to eat. Purchasers of food may rest assured that the action +taken by this firm would be that usually followed. It is not to the +interest of manufacturers or other venders to offend the senses of +purchasers, still less to do them actual harm, even if no higher +motive comes into force.</p> + +<p>In the early days of canning, it is just possible that the use +of "spirits of salt" in soldering may have resulted in the presence +of a little stannous, plumbous, or other chloride in canned food; +but such a fault would soon be detected and corrected, and as a +matter of fact, resin-soldering is to my knowledge more generally +employed--indeed, for anything I know to the contrary, is +exclusively employed--in canning food. Any resin that trained +access would be perfectly harmless. It is just possible, also, that +formerly the tin itself may have contained lead, but I have not +found any lead in the sheet tin used for canning of late years.</p> + +<p>In conclusion: 1. I have never been able to satisfy myself that +a can of ordinary tinned food contains even a useful medicinal dose +of such a true soluble <i>compound</i> of tin as is likely to have +any effect on man. 2. As for the metal itself, that is the filings +or actual metallic particles or fragments, one ounce is a common +dose as a vermifuge; harmless even in that quantity to man, and not +always so harmful as could be desired to the parasites for whose +disestablishment it is administered. One ounce might be contained +in about four hundredweight of canned food. 3. If a possibly +harmful quantity of a soluble compound, of tin be placed in a +portion of canned food, the latter will be so nasty and so unlike +any ordinary nasty flavor, so "metallic," in fact, that no sane +person will eat it. 4. Respecting the globules of solder (lead and +tin) that are occasionally met with in canned food, I believe most +persons detect them in the mouth and remove them, as they would +shots in game. But if swallowed, they do no harm. Pereira says that +metallic lead is probably inert, and that nearly a quarter of a +pound has been administered to a dog without any obvious effects. +He goes on to say that as it becomes oxidized it occasionally +acquires activity, quoting Paulini's statement that colic was +produced in a patient who had swallowed a leaden bullet. To allay +alarm in the minds of those who fear they might swallow pellets of +solder, I may add that Pereira cites Proust for the assurance that +an alloy of tin and lead is less easily oxidized than pure lead. 5. +Unsoundness in meat does not appear to promote the corrosion or +solution of tin. I have kept salmon in cans till it was putrid, +testing it occasionally for tin. No trace of tin was detected. +Nevertheless, food should not be allowed to remain for a few days, +or even hours, in saucepans, metal baking pans, or opened tins or +cans, otherwise it <i>may</i> taste metallic. 6. Unsound food, +canned or uncanned, may, of course, injure health, and where canned +food really has done harm, the harm has in all probability been due +to the food and not to the can. 7. What has been termed +idiosyncrasy must also be borne in mind. I know a man to whom +oatmeal is a poison. Some people cannot eat lobsters, either fresh +or tinned. Serious results have followed the eating of not only +oatmeal or shell fish, but salmon and mutton; <i>hydrate</i> +(misreported <i>nitrate</i>) of tin being gratuitously suggested as +being contained in the salmon in one case. Possibly there were +cases of idiosyncrasy in the eater, possibly the food was unsound, +possibly other causes altogether led to the results, but certainly, +to my mind, the tin had nothing whatever to do with the matter.</p> + +<p>In my opinion, given after well weighing all evidence hitherto +forthcoming, the public have not the faintest cause for alarm +respecting the occurrence of tin, lead, or any other metal in +canned foods.--<i>Phar. Jour, and Trans., March 8, 1884, p. +719</i>.</p> + +<p>[In reference to Prof. Attfield's statement contained in the +closing paragraph, we remark: It is well known that mercury is an +ingredient of the solder used in some canning concerns, as it makes +an easier melting and flowing solder. In THE SCIENTIFIC AMERICAN +for May 27, 1876, in a report of the proceedings of the New York +Academy of Science, will be seen the statement of Prof. Falke, who +found metallic mercury in a can of preserved corn beef, together +with a considerable quantity of albuminate of mercury.--EDS. +S.A.]</p> + +<hr> +<p><a name="18"></a></p> + +<h2>VILLA AT DORKING.</h2> + +<p>The house shown in the illustration was lately erected from the +designs of Mr. Charles Bell, F.R.I.B.A. Although sufficiently +commodious, the cost has been only about 1,050<i>l</i>.--<i>The +Architect</i>.</p> + +<p class="ctr"><a href="./illustrations/10a.png"><img src= +"./illustrations/10a_th.jpg" alt= +"SUGGESTIONS IN ARCHTECTURE.--AN ENGLISH COTTAGE. COST, $5,250."> +</a></p> + +<p class="ctr">SUGGESTIONS IN ARCHTECTURE.--AN ENGLISH COTTAGE. +COST, $5,250.</p> + +<hr> +<p>Valerianate of cerium in the vomiting of pregnancy is +recommended by Dr. Blondeau in a communication to the <i>Societe de +Therapeutique</i>. He gives it in doses of 10 centigrammes three +times a day.--<i>Medical Record</i>.</p> + +<hr> +<p><a name="19"></a></p> + +<p class="ctr"><a href="./illustrations/11a.png"><img src= +"./illustrations/11a_th.jpg" alt= +"ARM CHAIR IN THE LOUVRE COLLECTION, PARIS; FLENISH RENAISSANCE.--From The Workshop."> +</a></p> + +<p class="ctr">ARM CHAIR IN THE LOUVRE COLLECTION, PARIS; FLENISH +RENAISSANCE.--<i>From The Workshop.</i></p> + +<hr> +<p><a name="26"></a></p> + +<h2>TECHNICAL EDUCATION IN AMERICA.</h2> + +<p>If there is one point more than another in which the exuberant +youth and vitality of the American nation is visible it is in that +of education, the provision for which is on a most generous scale, +carried out with a determination at which the older countries of +the Eastern Hemisphere have only arrived by slow degrees and +painful experience. Of course the Americans, being young, and +having come to the fore, so to speak, full-fledged, have been able +to profit by the lessons which they have derived from their +neighbors--though it is none the less to their credit that they +have profited so well and so quickly. Technical and industrial +education has received a more general recognition, and been +developed more rapidly, than the general education of the country, +partly for the reason that there is no uniform system of the latter +throughout the States, but that each individual State and Territory +does that which is right in its own eyes. The principal reason, +however, is that to possess the knowledge, how to work is the first +creed of the American, who considers that the right to obtain that +knowledge is the birthright of every citizen, and especially when +the manual labor has to be supplemented by a vigorous use of +brains. The Americans as a rule do not like heavy or coarse manual +labor, thinking it beneath them; and, indeed, when they can get +Irish and Chinese to do it for them, perhaps they are not far +wrong. But the idea of idleness and loafing is very far from the +spirit of the country, and this is why we see the necessity for +industrial education so vigorously recognized, both as a national +duty, and by private individuals or communities of individuals.</p> + +<p>From whatever source it is provided, technical education in the +United States comes mainly within the scope of two classes of +institutions, viz., agricultural and mechanical colleges; although +the two are, as often as not, combined under one establishment, and +particularly it forms the subject of a national grant. Indeed, it +may be said that the scope of industrial education embraces three +classes: the farmer, the mechanic, and the housekeeper; and in the +far West we find that provision is made for the education of these +three classes in the same schools, it being an accepted idea in the +newer States that man and woman (the housekeeper) are coworkers, +and are, therefore, entitled to equal and similar educational +privileges. On the other hand, in the more conservative East and +South, we find that the sexes are educated distinct from each +other. In the East, there is generally, also, a separation of +subjects. In Massachusetts, for instance, the colleges of +agriculture and mechanics are separate affairs, the students being +taught in different institutions, viz., the agricultural college +and the institute of technology. In Missouri the separation is less +defined, the School of Mines and Metallurgy being the, only part +that is distinct from the other departments of the University.</p> + +<p>One of the chief reasons for the necessity for hastening the +extension of technical education in America was the almost entire +disappearance of the apprenticeship system, which, in itself, is +mainly due to the subdivision of labor so prevalent in the +manufacture of everything, from pins to locomotives. The increased +use of machinery, the character of which is such as often to put an +end to small enterprises, has promoted this subdivision by +accumulating workmen in large groups. The beginner, confining +himself to one department, is soon able to earn wages, and so he +usually continues as he begins. Mr. C.B. Stetson has written on +this subject with great force and earnestness, and it will not be +amiss to quote a sentence as to the advantages enjoyed by the +technically workman. He says that "it is the rude or dexterous +workman, rather than the really skilled one, who is supplanted by +machinery. Skilled labor requires thinking; but a machine never +thinks, never judges, never discriminates. Though its employment +does, indeed, enable rude laborers to do many things now which +formerly could only be done by dexterous workmen, it is clear that +its use has decidedly increased the relative demand for skilled +labor as compared with unskilled, and there is abundant room for an +additional increase, if it is true, as declared by the most eminent +authority, that the power now expended can be readily made to yield +three or four times its present results, and ultimately ten or +twenty times, when masters and workmen can be had with sufficient +intelligence and skill for the direction and manipulation of the +tools and machinery that would be invented."</p> + +<p>The establishment of colleges and universities by the aid of +national grants has depended very much for their character upon the +industrial tendencies of the respective States, it being understood +that the land grants have principally been given to those of the +newer States and Territories which required development, although +some of the institutions of the older States on the Atlantic +seaboard have also been recipients of the same fund, which in +itself only dates from an act of Congress in 1862. In California +and Missouri, both States abounding in mineral resources, there are +courses in mining and metallurgy provided in the institutions +receiving national aid. In the great grain-producing sections of +the Mississippi Valley the colleges are principally devoted to +agriculture, whereas the characteristic feature of the Iowa and +Kansas schools is the prominence given to industries.</p> + +<p>We need not devote attention to the aims and arrangements of the +agricultural colleges proper, but will pass at once to those which +deal with the mechanical arts, dealing first of all with those that +are assisted by the national land grant. Taking them +alphabetically, we have first the State Agricultural College of +Colorado, in the mechanical and drawing department of which shops +for bench work in wood and iron and for forging have been recently +erected, this institution being one of the newest in America. In +the Illinois Industrial University the student of mechanical +engineering receives practice in five shops devoted to +pattern-making, blacksmithing, moulding and founding, benchwork for +iron, and machine tool-work for iron. In the first shop the +practice consists of planing, chiseling, turning, and the +preparation of patterns for casting. The ordinary blacksmithing +operations take place in the second shop, and those of casting in +the third. In the fourth there is, first of all, a course of +freehand benchwork, and afterward the fitting of parts is +undertaken. In the fifth shop all the fundamental operations on +iron by machinery are practiced, the actual work being carefully +outlined beforehand by drawings. This department of the University +consists, in point of fact, of three separate schools, destined to +qualify the student for every kind of engineering--mining, railway, +mechanical, and architectural. In addition to the shops and machine +rooms, there are well furnished cabinets of geological and +mineralogical specimens, chemical laboratories for assaying and +metallurgy, stamp mill, furnaces, etc., and, in fact, every known +vehicle for practical instruction. The school of architecture +prepares students for the building profession. Among the subjects +in this branch are office work and shop practice, constructing +joints in carpentry and joinery, cabinet making and turning, +together with modeling in clay. The courses in mathematics, +mechanics and physics are the same as those in the engineering +school; but the technical studies embrace drawing from casts, wood, +stone, brick, and iron construction, turners' work, slating, +plastering, painting, and plumbing, architectural drawing and +designing, the history and aesthetics of architecture, estimates, +agreements specification, heating, lighting, draining, and +ventilation. The student's work from scale drawing occupies three +terms, carpentry and joinery being taught in the first year, +turning and cabinet making in the second, metal and stone work in +the third. A more condensed course, known as the builder's course, +is given to those who can only stop one year. The machine shop has +a steam engine of 16 horse power, two engines and three plain +lathes, a planer, a large drill press, a pattern shop, a +blacksmith's shop, all of the machinery having been built on the +spot. The carpenter's shop is likewise supplied with necessary +machine tools, such as saws, planers, tenoning machine, whittlers, +etc., the power being furnished by the machine shop. At the date of +the last University report, there were 41 students in the courses +of mechanical engineering, 41 in those of civil engineering, 3 in +mining engineering, and 14 in architecture. Tuition is free in all +the University classes, though each student has to pay a +matriculation fee of $10, and the incidental expenses amount to +about $23 annually. He is charged for material used or apparatus +broken, but not for the ordinary wear and tear of instruments. It +should be mentioned that the endowment of the Illinois Industrial +University is from scrip received from the Government for 480,000 +acres of land, of which 454,460 have been sold for $319,178. The +real estate of the University, partly made up by donations and +partly by appropriations made in successive sessions by the State +of Illinois, is estimated at $450,000.</p> + +<p>The Purdue University in Indiana, named after its founder, who +gave $150,000, which was supplemented by another $50,000 from the +State and a bond grant of 390,000 acres, also provides a very +complete mechanical course, with shop instruction, divided as +follows:</p> + +<pre> + Bench working in wood for 12 weeks, or 120 hours. + Wood-turning " 4 " " 40 " + Pattern-making " 12 " " 120 " + Vise-work in iron " 10 " " 100 " + Forging in iron and steel " 18 " " 180 " + Machine tool-work in iron " 20 " " 200 " +</pre> + +<p>The course in carpentry and joinery embraces: 1. Exercising in +sawing and planing to dimensions. 2 Application, or box nailed +together. 3 Mortise and tenon joints; a plain mortise and tenon; an +open dovetailed mortise and tenon (dovetailed halving); a +dovetailed keyed mortise and tenon. 4. Splices. 5. Common +dovetailing. 6. Lap dovetailing and rabbeting. 7. Blind or secret +dovetail. 8. Miter-box. 9. Carpenter's trestle. 10. Panel door. 11. +Roof truss. 12. Section of king-post truss roof. 13. Drawing +model.</p> + +<p>The course in wood turning includes: 1. Elementary principles: +first, straight turning; second, cutting in; third, convex curves +with the chisel; fourth, compound curves formed with the gouge. 2. +File and chisel handles. 3. Mallets. 4. Picture frames (chuck +work). 5. Card receiver (chuck work). 6. Watch safe (chuck work). +7. Ball.</p> + +<p>In the pattern-making course the student is supposed to have +some skill in bench and lathe work, which will be increased; the +direct object being to teach what forms of pattern are in general +necessary, and how they must be constructed in order to get a +perfect mould from them. The character of the work differs each +year. For instance, for the last year, besides simpler patterns +easily drawn from the sand, such as glands, ball-cranks, etc., +there were a series of flanged pipe-joints for 2½ in. pipes, +including the necessary core boxes; also pulley patterns from 6 in. +to 10 in. diameter, built in segments for strength, and to prevent +warping and shrinkage; and, lastly, a complete set of patterns for +a three horse-power horizontal steam engine, all made from drawings +of the finished piece. In the vise work in iron, the chief +requirements are these: 1, given a block of cast iron 4 in. by 2 +in. by 1½ in. in thickness, to reduce the thickness ¼ +in. by chipping, and then finishing with the file; 2, to file a +round hole square; 3, to file a round hole into elliptical; 4, +given a 3 in. cube of wrought iron, to cut a spline 3 in. by 3/8 +in. by ¼ in., and second, when the under side is a one half +round hollow--these two cuts involve the use of the cope chisel and +the round nose chisel, and are examples of very difficult chipping; +5, round tiling or hand-vise work; 6, scraping; 7, special examples +of fitting. In the forging classes are elementary processes, +driving, bending, and upsetting; courses in welding; miscellaneous +forging; steel forging, including hardening and tempering in all +its details.</p> + +<p>It is worth mentioning that in the industrial art school of the +Purdue University there were 13 of the fair sex as students, +besides one in the chemical school, and two going through the +mechanical courses just detailed, showing that the scope of woman's +industry is less limited in America than in England. The Iowa State +Agricultural College has also two departments of mechanical and +civil engineering, the former including a special course of +architecture. The workshop practice, which occupies three forenoons +of 2½ hours each per week, is, however, of more general +character, and is not pursued with such a regard to any special +calling as in the case of the Purdue University.</p> + +<p>The Kansas State Agricultural College has a course of carpentry, +though designed rather more to meet the everyday necessities of a +farmer's life. In fact, all the students are obliged to attend +these classes, and take the same first lessons in sawing, planing, +lumber dressing, making mortises, tenons, and joints, and in +general use of tools--just the kind of instruction that every +English lad should have before he is shipped off to the Colonies. +This farmer's course in the Kansas College provides for a general +training in mechanical handiwork, but facilities are given also to +those who wish to follow out the trade, and special instruction is +provided in the whole range of work, from framing to +stair-building, as also in iron work, such as ordinary forging, +filing, tempering, etc. Of the students attending this college, 75 +percent, are from farmers' homes, and the majority of the remainder +from the families of mechanics and tradesmen.</p> + +<p>The State College of Maine provides courses for both civil and +mechanical engineers, and has two shops equipped according to the +Russian system. Forge and vise work are taught in them, though it +is not the object of the college so much to teach the details of +any one trade as to qualify students by general knowledge to +undertake any of them afterward. A much more complete and thorough +technical education is given in the Massachusetts Institute of +Technology at Boston, where there are distinct classes for civil, +mechanical, mining, geological, and architectural engineering. The +following are the particulars of the instruction in the +architectural branch, which commences in the student's second year, +with Greek, Roman, and Mediæval architectural history, the +Orders and their applications, drawing, sketching, and tracing, +analytic geometry, differential calculus, physics, descriptive +geometry, botany, and physical geography. In the third year the +course is extended to the theory of decoration, color, form, and +proportion; conventionalism, symbolism, the decorative arts, +stained glass, fresco painting, tiles, terra-cotta, original +designs, specifications, integral calculus, strength of materials, +dynamics, bridges and roofs, stereotomy. In the fourth year the +student is turned out a finished architect, after a course of the +history of ornament, the theory of architecture, stability of +structure, flow of gases, shopwork (carpentry), etc.</p> + +<p>The number of students in this very comprehensive Institute of +Technology was, by the latest report, 390, of whom 138 were +undergoing special courses, 39 were in the schools of mechanical +art, and 49 in the Lowell School of Practical Design. Tuition is +charged at the rate of 200 dols. for the institute proper, and 150 +dols. for the mechanical schools, the average expenses per student +being about 254 dols. There are 10 free scholarships, of which two +are given for mechanical art. The Lowell School has been +established by the trustee of the Lowell Institute to afford free +technical education, under the auspices of the Institute of +Technology, to both sexes--a large number of young women availing +themselves of it in connection with their factory work at Lowell. +The courses include practical designs for manufactures, and the art +of making patterns for prints, delaines, silks, paperhangings, +carpets, oilcloth, etc., and the school is amply provided with +pattern looms. Indeed, the whole of the appliances for practical +teaching at the Institute are on such a complete scale that at the +risk of being a little tedious it is as well to enumerate them. +They comprise laboratories devoted to chemistry, mineralogy, +metallurgy, and industrial chemistry; there are also microscopic, +spectroscopic, and organic laboratories. In other branches there +are laboratories and museums of steam engineering, mining, and +metallurgy, biology and architecture, together with an observatory, +much used in connection with geodesy and practical astronomy. The +steam engineering laboratory provides practice in testing, +adjusting, and managing steam machinery. The appliances in +connection with mining and metallurgy include a five-stamp battery, +Blake crusher, automatic machine jigs, an engine pulverizer, a Root +and a Sturtevant blower, with blast reverberating, wasting, +cupellation, and fusion furnaces, and all other means for reducing +ores. The architectural museum contains many thousand casts, +models, photographs, and drawings. The shops for handwork are large +and well arranged, and include a vise-shop, forge shop, machine, +tool, and lathe shops, foundry, rooms for pattern making, weaving, +and other industrial institutions. The vise-shop contains four +heavy benches, with 32 vises attached, giving a capacity for +teaching 128 students the course every ten weeks, or 640 in a year +of fifty weeks. The forge-shop has eight forges. The foundry has 16 +moulding benches, an oven for core baking, and a blast furnace of +one-half ton capacity. The pattern-weaving room is provided with +five looms, one of them in 20-harness, and 4-shuttle looms, and +another an improved Jacquard pattern loom. It may safely be said +that there is nor an establishment in the world better equipped for +industrial and technical education than this Institute of +Massachusetts.--<i>London Building News</i>.</p> + +<hr> +<p>IVORY GETTING SCARCE.--The stock of ivory in London is estimated +at about forty tons in dealers' private warehouses, whereas +formerly they usually held about one hundred tons. One fourth of +all imported into England goes to the Sheffield cutlers. No really +satisfactory substitute for ivory has been found, and millions +await the discoverer of one. The existing substitutes will not take +the needed polish.</p> + +<hr> +<p><a name="27"></a></p> + +<h2>THE ANAESTHETICS OF JUGGLERS.</h2> + +<p>Fakirs are religious mendicants who, for the purpose of exciting +the charity of the public, assume positions in which it would seem +impossible that they could remain, submit themselves to fearful +tortures, or else, by their mode of living, their abstinence, and +their indifference to inclement weather and to external things, try +to make believe that, owing to their sanctity, they are of a +species superior to that of common mortals.</p> + +<p>In the Indies, these fakirs visit all the great markets, all +religious fetes, and usually all kinds of assemblages, in order to +exhibit, themselves. If one of them exhibits some new peculiarity, +some curious deformity, a strange posture, or, finally, any +physiological curiosity whatever that surpasses those of his +confreres, he becomes the attraction of the fete, and the crowd +surrounds him, and small coin and rupees begin to fall into his +bowl.</p> + +<p>Fakirs, like all persons who voluntarily torture themselves, are +curious examples of the modifications that will, patience, and, so +to speak, "art" can introduce into human nature, and into the +sensitiveness and functions of the organs. If these latter are +capable of being improved, of having their functions developed and +of acquiring more strength (as, for example, the muscles of boxers, +the breast of foot racers, the voice of singers, etc.), these same +organs, on the contrary, can be atrophied or modified, and their +functions be changed in nature. It is in such degradation and such +degeneration of human nature that fakirs excel, and it is from such +a point of view that they are worth studying.</p> + +<p>We may, so to speak, class these individuals according to the +grades of punishments that they inflict upon themselves, or +according to the deformities that they have caused themselves to +undergo. But, as we have already said, the number of both of these +is extremely varied, each fakir striving in this respect to eclipse +his fellows. It is only necessary to open a book of Indian travel +to find descriptions of fakirs in abundance; and such descriptions +might seem exaggerated or unlikely were they not so concordant. The +following are a few examples:</p> + +<p><i>Immovable fakirs</i>.--The number of these is large. They +remain immovable in the spot they have selected, and that too for +an exceedingly long period of time. An example of one of these is +cited who remained standing for twelve years, his arms crossed upon +his breast, without moving and without lying or sitting down. In +such cases charitable persons always take it upon themselves to +prevent the fakir from dying of starvation. Some remain sitting, +immovable, and apparently lifeless, while others, who lie stretched +out upon the ground, look like corpses. It may be easily imagined +what a state one of these beings is in after a few months or years +of immobility. He is extremely lean, his limbs are atrophied, his +body is black with filth and dust, his hair is long and +dishevelled, his beard is shaggy, his finger and toe nails have +become genuine claws, and his aspect is frightful. This, however, +is a character common to all fakirs.</p> + +<p>We may likewise class among the immovables those fakirs who +cause themselves to be interred up to the neck, and who remain thus +with their head sticking out of the ground either during the entire +time the fair or fete lasts or for months and years.</p> + +<p><i>Anchylotic Fakirs</i>.--The number of fakirs who continue to +hold one or both arms outstretched is very large in India. The +following description of one of them is given by a traveler: "He +was a goussain--a religious mendicant--who had dishevelled hair and +beard, and horrible tattooings upon his face, and, what was most +hideous, was his left arm, which, withered and anchylosed, stuck up +perpendicularly from the shoulder. His closed hand, surrounded by +straps, had been traversed by the nails, which, continuing to grow, +had bent like claws on the other side. Finally, the hollow of this +hand, which was filled with earth, served as a pot for a small +sacred myrtle."</p> + +<p>Other fakirs hold their two arms above their head, the hands +crossed, and remain perpetually in such a position. Others again +have one or both arms extended. Some hang by their feet from the +limb of a tree by means of a cord, and remain head downward for +days at a time, with their face uncongested and their voice clear, +counting their beads and mumbling prayers.</p> + +<p>One of the most remarkable peculiarities of fakirs is the +faculty that certain of them possess of remaining entirely buried +in vaults and boxes, and inclosed in bags, etc., for weeks and +months, and, although there is a certain deceit as regards the +length of their absolute abstinence, it nevertheless seems to be a +demonstrated fact that, after undergoing a peculiar treatment, they +became plunged into a sort of lethargy that allows them to remain +for several days or weeks without taking food. Certain fakirs that +have been interred under such conditions have, it appears, passed +ten months or a year in their grave.</p> + +<p><i>Tortured Fakirs</i>.--Fakirs that submit themselves to +tortures are very numerous. Some of them perform exercises +analogous to those of the Aissaoua. Mr. Rousselet, in his voyage to +the Indies, had an opportunity of seeing some of these at Bhopal, +and the following is the picturesque description that he gives of +them: "I remarked some groups of religious mendicants of a +frightfully sinister character. They were Jogins, who, stark naked +and with dishevelled hair, were walking about, shouting, and +dancing a sort of weird dance. In the midst of their contortions +they brandished long, sharp poniards, of a special form, provided +with steel chains. From time to time, one of these hallucinated +creatures would drive the poniard into his body (principally into +the sides of his chest), into his arms, and into his legs, and +would only desist when, in order to calm his apparent fury, the +idlers who were surrounding him threw a sufficient number of +pennies to him."</p> + +<p>At the time of the feast of the Juggernaut one sees, or rather +one <i>did</i> see before the English somewhat humanized this +ceremony, certain fakirs suspended by their flesh from iron hooks +placed along the sides of the god's car. Others had their priests +insert under their shoulder blades two hooks, that were afterward +fixed to a long pole capable of pivoting upon a post. The fakirs +were thus raised about thirty feet above ground, and while being +made to spin around very rapidly, smilingly threw flowers to the +faithful. Others, again, rolled over mattresses garnished with +nails, lance-points, poniards, and sabers, and naturally got up +bathed in blood. A large number cause 120 gashes (the sacred +number) to be made in their back and breast in honor of their god. +Some pierce their tongue with a long and narrow poniard, and remain +thus exposed to the admiration of the faithful. Finally, many of +them are content to pass points of iron or rods made of reed +through folds in their skin. It will be seen from this that fakirs +are ingenious in their modes of exciting the compassion and charity +of the faithful.</p> + +<p>Elsewhere, among a large number of savage tribes and +half-civilized peoples, we find aspirants to the priesthood of the +fetiches undergoing, under the direction of the members of the +religious caste that they desired to enter, ordeals that are +extremely painful. Now, it has been remarked for a long time that, +among the neophytes, although all are prepared by the same hands, +some undergo these ordeals without manifesting any suffering, while +others cannot stand the pain, and so run away with fright. It has +been concluded from this that the object of such ordeals is to +permit the caste to make a selection from among their recruits, and +that, too, by means of anesthetics administered to the chosen +neophytes.</p> + +<p>In France, during the last two centuries, when torturing the +accused was in vogue, some individuals were found to be insensible +to the most fearful tortures, and some even, who were plunged into +a species of somnolence or stupefaction, slept in the hands of the +executioner.</p> + +<p>What are the processes that permit of such results being +reached? Evidently, we cannot know them all. A certain number are +caste, sect, or family secrets. Many are known, however, at least +in a general way. The processes naturally vary, according to the +object to be attained. Some seem to consist only in an effort of +the will. Thus, those fakirs who remain immovable have no need of +any special preparation to reach such a result, and the same is the +case with those who are interred up to the neck, the will alone +sufficing. Fakirs probably pass through the same phases that +invalids do who are forced to keep perfectly quiet through a +fracture or dislocation. During the first days the organism revolts +against such inaction, the constraint is great, the muscles +contract by starts, and then the patient gets used to it; the +constraint becomes less and less, the revolt of the muscles becomes +less frequent, and the patient becomes reconciled to his +immobility. It is probable that after passing several months or +years in a state of immobility fakirs no longer experience any +desire to change their position, and even did they so desire, it +would be impossible owing to the atrophy of their muscles and the +anchylosis of their joints.</p> + +<p>Those fakirs who remain with one or several limbs immovable and +in an abnormal position have to undergo a sort of preparation, a +special treatment; they have to enter and remain two or three +mouths in a sort of cage or frame of bamboo, the object of which is +to keep the limb that is to be immobilized in the position that it +is to preserve. This treatment, which is identical with the one +employed by surgeons for curing affections of the joints, has the +effect of soldering or anchylosing the articulation. When such a +result is reached, the fakir remains, in spite of himself and +without fatigue, with outstretched arms, and, in order to cause +them to drop, he would have to undergo a surgical operation.</p> + +<p>As for those voluntary tortures that cause an effusion of blood, +the insensibility of those who are the victims of it is explainable +when we reflect that <i>India</i> is <i>the</i> country <i>par +excellence</i> of anæsthetic plants. It produces, notably, +Indian hemp and poppy, the first of which yields hashish and the +other opium. Now it is owing to these two narcotics, taken in a +proper dose, either alone or combined according to a formula known +to Hindoo fakirs and jugglers, but ignored by the lower class, that +the former are able to become absolutely insensible themselves or +make their adepts so.</p> + +<p class="ctr"><a href="./illustrations/12a.png"><img src= +"./illustrations/12a_th.jpg" alt= +"INDIAN FAKIRS IN VARIOUS POSITIONS."></a></p> + +<p class="ctr">INDIAN FAKIRS IN VARIOUS POSITIONS.</p> + +<p>There is, especially, a liquor known in the Indian pharmacopoeia +under the name of <i>bang</i>, that produces an exciting +intoxication accompanied with complete insensibility. Now the +active part of bang consists of a mixture of opium and hashish. It +was an analogous liquor that the Brahmins made Indian widows take +before leading them to the funeral pile. This liquor removed from +the victims not only all consciousness of the act that they were +accomplishing, but also rendered them insensible to the flames. +Moreover, the dose of the anæsthetic was such that if, by +accident, the widow had escaped from the pile (something that more +than once happened, thanks to English protection), she would have +died through poisoning. Some travelers in Africa speak of an herb +called <i>rasch</i>, which is the base of anæsthetic +preparations employed by certain Arabian jugglers and +sorcerers.</p> + +<p>It was hashish that the Old Man of the Mountain, the chief of +the sect of Assassins, had recourse to for intoxicating his adepts, +and it was, it is thought, by the use of a virulent solanaceous +plant--henbane, thornapple, or belladonna--that he succeeded in +rendering them insensible. We have unfortunately lost the recipe +for certain anæsthetics that were known in ancient times, +some of which, such as the <i>Memphis stone</i>, appear to have +been used in surgical operations. We are also ignorant of what the +wine of myrrh was that is spoken of in the Bible.</p> + +<p>We are likewise ignorant of the composition of the +anæsthetic soap, the use of which became so general in the +15th and 16th centuries that, according to Taboureau, it was +difficult to torture persons who were accused. The stupefying +recipe was known to all jailers, who, for a consideration, +communicated it to prisoners. It was this use of anæsthetics +that gave rise to the rule of jurisprudence according to which +partial or general insensibility was regarded as a certain sign of +sorcery. We may cite a certain number of preparations, which vary +according to the country, and to which is attributed the properly +of giving courage and rendering persons insensible to wounds +inflicted by the enemy. In most cases alcohol forms the base of +such beverages, although the <i>maslach</i> that Turkish soldiers +drink just before a battle contains none of it, on account of a +religious precept. It consists of different plant-juices, and +contains, especially, a little opium. Cossacks and Tartars, just +before battle, take a fermented beverage in which has been infused +a species of toadstool (<i>Agaricus muscarius</i>), and which +renders them courageous to a high degree.</p> + +<p>As well known, the old soldiers of the First Empire taught the +young conscripts that in order to have courage and not feel the +blows of the enemy, it was only necessary to drink a glass of +brandy into which gunpowder had been poured.--<i>La Nature</i>.</p> + +<hr> +<p>[SCHOOL OF MINES QUARTERLY.]</p> + +<p><a name="20"></a></p> + +<h2>THE DEPOSITION OF ORES.</h2> + +<h3>By J.S. NEWBERRY.</h3> + +<h3>MINERAL VEINS.</h3> + +<p>In the <i>Quarterly</i> for March, 1880, a paper was published +on "The Origin and Classification of Ore Deposits," which treated, +among other things, of mineral veins. These were grouped in three +categories, namely: 1. Gash Veins; 2. Segregated Veins; 3. Fissure +Veins; and were defined as follows:</p> + +<p><i>Gash Veins</i>.--Ore deposits confined to a single bed or +formation of <i>limestone</i>, of which the joints, and sometimes +planes of bedding, enlarged by the solvent power of atmospheric +water carrying carbonic acid, and forming crevices, galleries, or +caves, are lined or filled with ore leached from the surrounding +rock, e.g., the lead deposits of the Upper Mississippi and +Missouri.</p> + +<p><i>Segregated Veins</i>.--Sheets of quartzose matter, chiefly +lenticular and conforming to the bedding of the inclosing rocks, +but sometimes filling irregular fractures across such bedding, +found only in metamorphic rocks, limited in extent laterally and +vertically, and consisting of material indigenous to the strata in +which they occur, separated in the process of metamorphism, e.g., +quartz ledges carrying gold, copper, iron pyrites, etc., in the +Alleghany Mountains, New England, Canada, etc.</p> + +<p><i>Fissure Veins</i>.--Sheets of metalliferous matter filling +fissures caused by subterranean force, usually in the planes of +faults, and formed by the deposit of various minerals brought from +a lower level by water, which under pressure and at a high +temperature, having great solvent power, had become loaded with +matters leached from different rocks, and deposited them in the +channels of escape as the pressure and temperature were +reduced.</p> + +<p>Since that article was written, a considerable portion of +several years has been spent by the writer continuing the +observations upon which it was based. During this time most of the +mining centers of the Western States and Territories, as well as +some in Mexico and Canada, were visited and studied with more or +less care. Perhaps no other portion of the earth's surface is so +rich in mineral resources as that which has been covered by these +observations, and nowhere else is to be found as great a variety of +ore deposits, or those which illustrate as well their mode of +formation. This is so true that it maybe said without exaggeration +that no one can intelligently discuss the questions that have been +raised in regard to the origin and mode of formation of ore bodies +without transversing and studying the great mining belt of our +Western States and Territories.</p> + +<p>The observations made by the writer during the past four years +confirm in all essentials the views set forth in the former article +in the <i>Quarterly</i>, and while a volume might be written +describing the phenomena exhibited by different mines and mining +districts, the array of facts thus presented would be, for the most +part, simply a re-enforcement of those already given.</p> + +<p>The present article, which must necessarily be short, would +hardly have a <i>raison d'etre</i> except that it affords an +opportunity for an addition which should be made to the classes of +mineral veins heretofore recognized in this country, and it seems +called for by the recent publication of theories on the origin of +ore deposits which are incompatible with those hitherto presented +and now held by the writer, and which, if allowed to pass +unquestioned, might seem to be unquestionable.</p> + +<h3>BEDDED VEINS.</h3> + +<p>Certain ore deposits which have recently come under my +observation appear to correspond very closely with those that Von +Cotta has taken as types of his class of "bedded veins," and as no +similar ones have been noticed by American writers on ore deposits +they have seemed to me worthy of description.</p> + +<p>These are zones or layers of a sedimentary rock, to the bedding +of which they are conformable, impregnated with ore derived from a +foreign source, and formed long subsequent to the deposition of the +containing formation. Such deposits are exemplified by the Walker +and Webster, the Piñon, the Climax, etc., in Parley's Park, +and the Green-Eyed Monster, and the Deer Trail, at Marysvale, Utah. +These are all zones in quartzite which have been traversed by +mineral solutions that have by substitution converted such layers +into ore deposits of considerable magnitude and value.</p> + +<p>The ore contained in these bedded veins exhibits some variety of +composition, but where unaffected by atmospheric action consists of +argentiferous galena, iron pyrites carrying gold, or the sulphides +of zinc and copper containing silver or gold or both. The ore of +the Walker and Webster and the Piñon is chiefly +lead-carbonate and galena, often stained with copper-carbonate. +That of the Green Eyed Monster--now thoroughly oxidized as far as +penetrated--forms a sheet from twenty to forty feet in thickness, +consisting of ferruginous, sandy, or talcose soft material carrying +from twenty to thirty dollars to the ton in gold and silver. The +ore of the Deer Trail forms a thinner sheet containing considerable +copper, and sometimes two hundred to three hundred dollars to the +ton in silver.</p> + +<p>The rocks which hold these ore deposits are of Silurian age, but +they received their metalliferous impregnation much later, probably +in the Tertiary, and subsequent to the period of disturbance in +which they were elevated and metamorphosed. This is proved by the +fact that in places where the rock has been shattered, strings of +ore are found running off from the main body, crossing the bedding +and filling the interstices between the fragments, forming a coarse +stock-work.</p> + +<p>Bedded veins may be distinguished from fissure veins by the +absence of all traces of a fissure, the want of a banded structure, +slickensides, selvages, etc.; from gash veins and the floors of ore +which often accompany them, as well as from segregated veins, they +are distinguished by the nature of the inclosing rock and the +foreign origin of the ore. Sometimes the plane of junction between +two contiguous sheets of rock has been the channel through which +has flowed a metalliferous solution, and the zone where the ore has +replaced by substitution portions of one or both strata. These are +often called blanket veins in the West, but they belong rather to +the category of contact deposits as I have heretofore defined them. +Where such sheets of ore occupy by preference the planes of contact +between adjacent strata, but sometimes desert such planes, and show +slickensided walls, and banded structure, like the great veins of +Bingham, Utah, these should be classed as true fissure veins.</p> + +<h3>THEORIES OF ORE DEPOSIT.</h3> + +<p>The recently published theories of the formation of mineral +veins, to which I have alluded, are those of Prof. Von Groddek[1] +and Dr. Sandberger,[2] who attribute the filling of veins to +exudations of mineral solutions from the wall rocks (i.e., lateral +secretions), and those of Mr. S.F. Emmons,[3] and Mr. G.F. +Becker,[4] who have been studying, respectively, the ore deposits +of Leadville and of the Comstock, by whom the ores are credited to +the leaching of adjacent <i>igneous</i> rocks.</p> + +<p>[Footnote 1: Die Lehre von den Lagerstatten der Erze, von Dr. +Albrecht von Groddek, Leipzig. 1879.]</p> + +<p>[Footnote 2: Untersuchungen uber Erzgange, von Fridolin +Sandberger, Weisbaden, 1882.]</p> + +<p>[Footnote 3: Geology and Mining Industry of Leadville, Annual +Report, Director U.S. Geol. Surv., 1881.]</p> + +<p>[Footnote 4: Geology of the Comstock Lode and Washoe District, +G.F. Becker, Washington, 1883.</p> + +<p>It is but justice to Messrs. Becker and Emmons to say that +theirs are admirable studies, thorough and exhaustive, of great +interest and value to both mining engineers and geologists, and +most creditable to the authors and the country. No better work of +the kind has been done anywhere, and it will detract little from +its merit even if the views of the authors on the theoretical +question of the sources of the ores shall not be generally +adopted.]</p> + +<p>The lack of space must forbid the full discussion of these +theories at the present time, but I will briefly enumerate some of +the facts which render it difficult for me to accept them.</p> + +<p>First, <i>the great diversity of character exhibited by +different sets of fissure veins which cut the same country rock</i> +seems incompatible with any theory of lateral secretion. These +distinct systems are of different ages, of diversified composition, +and have evidently drawn their supply of material from different +sources. Hundreds of cases of this kind could be cited, but I will +mention only a few; among others the Humboldt, the Bassick, and the +Bull Domingo, near Rosita and Silver Cliff, Colorado. These are +veins contained in the same sheet of eruptive rock, but the ores +are as different as possible. The Humboldt is a narrow fissure +carrying a thin ore streak of high grade, consisting of sulphides +of silver, antimony, arsenic, and copper; the Bassick is a great +conglomerate vein containing tellurides of silver and gold, +argentiferous galena, blende, and yellow copper; the Bull Domingo +is also a great fissure filled with rubbish containing ore chimneys +of galena with tufts of wire silver. I may also cite the Jordan, +with its intersecting and yet distinct and totally different veins; +the Galena, the Neptune, and the American Flag, in Bingham Canon, +Utah; and the closely associated yet diverse system of veins the +Ferris, the Washington, the Chattanooga, the Fillmore, etc., in +Bullion Canon at Marysvale. In these and many other groups which +have been examined by the writer, the same rocks are cut by veins +of different ages, having different bearings, and containing +different ores and veinstones. It seems impossible that all these +diversified materials should have been derived from the same +source, and the only rational explanation of the phenomena is that +which I have heretofore advocated, the ascent of metalliferous +solutions from different and deep seated sources.</p> + +<p>Another apparently unanswerable argument against the theory of +lateral secretion is furnished by the cases <i>where the same vein +traverses a series of distinct formations, and holds its character +essentially unaffected by changes in the country rock</i>. One of +many such may be cited in the Star vein at Cherry Creek, Nevada, +which, nearly at right angles to their strike, cuts belts of +quartzite, limestone, and slate, maintaining its peculiar character +of ore and gangue throughout.</p> + +<p>This and all similar veins have certainly been filled with +material brought from a distance, and not derived from the +walls.</p> + +<h3>LEACHING OF IGNEOUS ROCKS.</h3> + +<p>The arguments against the theory that mineral veins have been +produced by the leaching of superficial <i>igneous</i> rocks are in +part the same as those already cited against the general theory of +lateral secretion. They may be briefly summarized as follows:</p> + +<p>1. Thousands of mineral veins in this and other countries occur +in regions remote from eruptive rocks. Into this category come most +of those of the eastern half of the Continent, viz., Canada, New +England, the Alleghany belt, and the Mississippi Valley. Among +those I will refer only to a few selected to represent the greatest +range of character, viz., the Victoria lead mine, near Sault Ste. +Marie, the Bruce copper mine on Lake Huron, the gold-bearing quartz +veins of Madoc, the Gatling gold vein of Marmora, the Acton and the +Harvey Hill copper mines of Canada, the copper veins of Ely, +Vermont, and of Blue Hills, Maine, the silver-bearing lead veins of +Newburyport, Mass.; most of the segregated gold veins of the +Alleghany belt, the lead veins of Rossie, Ellenville, and at other +localities farther South; the copper bearing veins of Virginia, +North Carolina, and Tennessee; the veins carrying argentiferous +galena in Central Kentucky and in Southern Illinois; the silver, +copper, and antimony veins of Arkansas; and the lead and zinc +deposits of Missouri and the Upper Mississippi.</p> + +<p>In these widely separated localities are to be found fissure, +segregated, and gash veins, and a great diversity of ores, which +have been derived, sometimes from the adjacent rocks--as in the +segregated veins of the Alleghany belt and the gash veins of the +Mississippi region--and in other cases--where they are contained in +true fissure veins--from a foreign source, but all deposited +without the aid of superficial igneous rocks, either as +contributors of matter or force.</p> + +<p>2. In the great mineral belt of the Far West, where volcanic +emanations are so abundant, and where they have certainly played an +important part in the formation of ore deposits, the great majority +of veins are not in immediate contact with trap rocks, and they +could not, therefore, have furnished the ores.</p> + +<p>A volume might be formed by a list of the cases of this kind, +but I can here allude to a few only, most of which I have myself +examined, viz.:</p> + +<p><i>(a.)</i> The great ore chambers of the San Carlos Mountains +in Chihuahua, the largest deposits of ore of which I have any +knowledge. These are contained in heavy beds of limestone, which +are cut in various places by trap dikes, which, as elsewhere, have +undoubtedly furnished the stimulus to chemical action that has +resulted in the formation of the ore bodies, but are too remote to +have supplied the material.</p> + +<p><i>(b.)</i> The silver mines of Santa Eulalia, in Chihuahua, +from which during the last century one hundred and twelve millions +of dollars were taken, opened on ore deposits situated in +Cretaceous limestones like those of San Carlos, and apparently +similar ore-filled chambers; an igneous rock caps the hills in the +vicinity, but is nowhere in contact or even proximity to the ore +bodies. (See Kimball, <i>Amer. Jour. Sci,</i>. March, 1870.)</p> + +<p><i>(c.)</i> The great chambers of Tombstone, and the copper +veins of the Globe District, the Copper Queen, etc., in +Arizona.</p> + +<p><i>(d.)</i> The large bodies of silver-ore at Lake Valley, New +Mexico; chambers in limestone, like <i>c</i>.</p> + +<p><i>(e.)</i> The Black Hawk group of gold mines, the Montezuma, +Georgetown, and other silver mines in the granite belt of +Colorado.</p> + +<p><i>(f.)</i> The great group of veins and chambers in the +Bradshaw, Lincoln, Star, and Granite districts of Southern Utah, +where we find a host of veins of different character in limestone +or granite, with no trap to which the ores can be credited.</p> + +<p><i>(g.)</i> The Crismon Mammoth vein of Tintic.</p> + +<p><i>(h.)</i> The group of mines opened on the American Fork, on +Big and Little Cottonwood, and in Parley's Park, including the +Silver Bell, the Emma, the Vallejo, the Prince of Wales, the +Kessler, the Bonanza, the Climax, the Piñon, and the +Ontario. (The latter, the greatest silver mine now known in the +country, lies in quartzite, and the trap is near, but not in +contact with the vein.)</p> + +<p><i>(i.)</i> In Nevada, the ore deposits of Pioche, Tempiute, +Tybo, Eureka, White Pine, and Cherry Creek, on the east side of the +State, with those of Austin, Belmont, and a series too great for +enumeration in the central and western portions.</p> + +<p><i>(j.)</i> In California, the Bodie, Mariposa, Grass Valley, +and other mines.[1]</p> + +<p><i>(k.)</i> In Idaho, those of the Poor Man in the Owyhee +district, the principal veins of the Wood River region, the +Ramshorn at Challis, the Custer and Charles Dickens, at Bonanza +City, etc.</p> + +<p>[Footnote 1: See Redmond's Report <i>(California Geol. Survey +Mining Statistics, No 1),</i> where seventy-seven mines are +enumerated, of which three are said to be in "porphyritic schist," +all the others in granite, mica schist, clay, slate, etc.]</p> + +<p>In nearly all these localities we may find evidence not only +that the ore deposits have not been derived from the leaching of +igneous rocks, but also that they have not come from those of any +kind which form the walls of the veins.</p> + +<p>The gold-bearing quartz veins of Deadwood are so closely +associated with dikes of porphyry, that they may have been +considered as illustrations of the potency of trap dikes in +producing concentration of metals. But we have conclusive evidence +that the gold was there in Archæan times, while the igneous +rocks are all of modern, probably of Tertiary, date. This proof is +furnished by the "Cement mines" of the Potsdam sandstone. This is +the beach of the Lower Silurian sea when it washed the shores of an +Archæan island, now the Black Hills. The waves that produced +this beach beat against cliffs of granite and slate containing +quartz veins carrying gold. Fragments of this auriferous quartz, +and the gold beaten out of them and concentrated by the waves, were +in places buried in the sand beach in such quantity as to form +deposits from which a large amount of gold is now being taken. +Without this demonstration of the origin and antiquity of the gold, +it might very well have been supposed to be derived from the +eruptive rock.</p> + +<p>Strong arguments against the theory that the leaching of +superficial igneous rocks has supplied the materials filling +mineral veins, are furnished by the facts observed in the districts +where igneous rocks are most prevalent, viz.: (1.) <i>Such +districts are proverbially barren of useful minerals</i>. (2.) +<i>Where these occur, the same sheet of rock may contain several +systems of veins with different ores and gangues.</i></p> + +<p>The great lava plain of Snake River, the Pedrigal country of +eastern Oregon, Northern California and Mexico are without valuable +ore deposits. The same may be said of the Pancake Range and other +mountain chains of igneous rock in Nevada, while the adjacent +ranges composed of sedimentary rocks are rich in ore deposits of +various kinds. A still stronger case is furnished by the Cascade +Mountains, which, north of the California line, are composed almost +exclusively of erupted material, and yet in all this belt, so far +as now known, not a single valuable mine has been opened. In +contrast with this is the condition of things in California, where +the Sierra Nevada is composed of metamorphic rocks which have been +shown to be the repositories of vast quantities of gold, silver, +and copper. Cases belonging to this category may be found at Rosita +and Silver Cliff, where the diversity in the ores of the mines +already enumerated can hardly be reconciled with the theory of a +common origin. At Lake City the prevailing porphyry holds the veins +of the Ute and Ulay and the Ocean Wave mines, which are similar, +and the Hotchkiss, the Belle, etc., entirely different.</p> + +<p>We have no evidence that any volcanic eruption has drawn its +material from zones or magmas especially rich in metals or their +ores, and on the contrary, volcanic districts, like those +mentioned, and regions, such as the Sandwich Islands, where the +greatest, eruptions have taken place, are poorest in metalliferous +deposits.</p> + +<p>All the knowledge we have of the subject justifies the inference +that most of the igneous rocks which have been poured out in our +Western Territories are but fused conditions of sediments which +form the substructure of that country. Over the great mineral belt +which lies between the Sierra Nevada and the front range of the +Rocky Mountains, and extends not only across the whole breadth of +our territory, but far into Mexico, the surface was once underlain +by a series of Palaeozoic sedimentary strata not less than twenty +to thirty thousand feet in thickness; and beneath these, at the +sides, and doubtless below, were Archæun rocks, also +metamorphosed sediments. Through these the ores of the metals were +generally though sparsely distributed. In the convulsions which +have in recent times broken up this so long quiet and stable +portion of the earth's crust (and which have resulted in depositing +in thousands of cracks and cavities the ores we now mine), portions +of the old table-land were in places set up at high angles forming +mountain chains, and doubtless extending to the zone of fusion +below. Between these blocks of sedimentary rocks oozed up through +the lines of fracture quantities of fused material, which also +sometimes formed mountain chains; and it is possible and even +probable that the rocks composing the volcanic ridges are but +phases of the same materials that form the sedimentary chains There +is, therefore, no <i>a priori</i> reason why the leaching of one +group should furnish more ore than the other; but, as a matter of +fact, the unfused sediments are much the richer in ore deposits. +This can only be accounted for, in my judgment, by supposing that +they have been the receptacles of ore brought from a foreign +source; and we can at least conjecture where and how gathered. We +can imagine, and we are forced to conclude, that there has been a +zone of solution below, where steam and hot water, under great +pressure, have effected the leaching of ore-bearing strata, and a +zone of deposition above, where cavities in pre-existent solidified +and shattered rocks became the repositories of the deposits made +from ascending solutions, when the temperature and pressure were +diminished. Where great masses of fused material were poured out, +these must have been for along time too highly heated to become +places of deposition; so long indeed that the period of active vein +formation may have passed before they reached a degree of +solidification and coolness that would permit their becoming +receptacles of the products of deposition. On the contrary, the +masses of unfused and always relatively cool sedimentary rocks +which form the most highly metalliferous mountain ranges (White +Pine, Toyabe, etc.) were, throughout the whole period of +disturbance, in a condition to become such repositories. Certainly +highly heated solutions forced by an irresistible <i>vis a +tergo</i> through rocks of any kind down in the heated zone, would +be far more effective leaching agents than cold surface water with +feeble solvent power, moved only by gravity, percolating slowly +through superficial strata.</p> + +<p>Richthofen, who first made a study of the Comstock lode, +suggests that the mineral impregnation of the vein was the result +of a process like that described, viz., the leaching of deep-seated +rocks, perhaps the same that inclose the vein above, by highly +heated solutions which deposited their load near the surface. On +the other hand, Becker supposes the concentration to have been +effected by surface waters flowing laterally through the igneous +rocks, gathering the precious metals and depositing them in the +fissure, as lateral secretion produces the accumulation of ore in +the limestone of the lead region. But there are apparently good +reasons for preferring the theory of Richthofen: viz., first, the +veinstone of the Comstock is chiefly quartz, the natural and common +precipitate of <i>hot</i> waters, since they are far more powerful +solvents of silica than cold. On the contrary, the ores deposited +from lateral secretion, as in the Mississippi lead region, at low +temperature contain comparatively little silica; second, the great +mineral belt to which reference has been made above is now the +region where nearly all the hot springs of the continent are +situated. It is, in fact, a region conspicuous for the number of +its hot springs, and it is evident that these are the last of the +series of thermal phenomena connected with the great volcanic +upheavals and eruptions, of which this region has been the theater +since the beginning of the Tertiary age. The geysers of Yellowstone +Park, the hot springs of the Wamchuck district in Oregon, the +Steamboat Springs of Nevada, the geysers of California, the hot +springs of Salt Lake City, Monroe, etc., in Utah, and the Pagosa in +Colorado, are only the most conspicuous among thousands of hot +springs which continue in action at the present time. The evidence +is also conclusive that the number of hot springs, great as it now +is in this region, was once much greater. That these hot springs +were capable of producing mineral veins by material brought up in +and deposited from their waters, is demonstrated by the phenomena +observable at the Steamboat Springs, and which were cited in my +former article as affording the best illustration of vein +formation.</p> + +<p>The temperature of the lower workings of the Comstock vein is +now over 150°F., and an enormous quantity of hot water is +discharged through the Sutro Tunnel. This water has been heated by +coming in contact with hot rocks at a lower level than the present +workings of the Comstock lode, and has been driven upward in the +same way that the flow of all hot springs is produced. As that flow +is continuous, it is evident that the workings of the Comstock have +simply opened the conduits of hot springs, which are doing to-day +what they have been doing in ages past, but much less actively, +i.e., bringing toward the surface the materials they have taken +into solution in a more highly heated zone below. Hence it seems +much more natural to suppose that the great sheets of ore-bearing +quartz now contained in the Comstock fissure were deposited by +ascending currents of hot alkaline waters, than by descending +currents of those which were cold and neutral The hot springs are +there, though less copious and less hot than formerly, and the +natural deposits from hot waters are there. Is it not more rational +to suppose with Richthofen that these are related as cause and +effect, rather than that cold water has leached the ore and the +silica from the walls near the surface? Mr. Becker's preference for +the latter hypothesis seems to be due to the discovery of gold and +silver in the igneous rocks adjacent to the vein, and yet, except +in immediate contact with it, these rocks contain no more of the +precious metals than the mere trace which by refined tests may be +discovered everywhere. If, as we have supposed, the fissure was for +a long time filled with a hot solution charged with an unusual +quantity of the precious metals, nothing would be more natural than +that the wall rocks should be to some extent impregnated with +them.</p> + +<p>It will perhaps illuminate the question to inquire which of the +springs and water currents of this region are now making deposits +that can be compared with those which filled the Comstock and other +veins. No one who has visited that country will hesitate to say the +hot and not the cold waters. The immense silicious deposits, +carrying the ores of several metals, formed by the geysers of the +Yellowstone, the Steamboat Springs, etc., show what the hot waters +are capable of doing; but we shall search in vain for any evidence +that the cold surface waters have done or can do this kind of +work.</p> + +<p>At Leadville the case is not so plain, and yet no facts can be +cited which really <i>prove</i> that the ore deposits have been +formed by the leaching of the overlying porphyry rather than by an +outflow of heated mineral solutions along the plane of junction +between the porphyry and the limestone. Near this plane the +porphyry is often thoroughly decomposed, is somewhat impregnated +with ore, and even contains sheets of ore within itself; but remote +from the plane of contact with the limestone, it contains little +diffused and no concentrated ore. It is scarcely more previous than +the underlying limestones, and why a solution that could penetrate +and leach ores from it should be stopped at the upper surface of +the blue limestone is not obvious; nor why the plane of junction +between the porphyry and the <i>blue limestone</i> should be the +special place of deposit of the ore.</p> + +<p>If the assays of the porphyry reported by Mr. Emmons were +accurately made, and they shall be confirmed by the more numerous +ones necessary to settle the question, and the estimates he makes +of the richness of that rock be corroborated, an unexpected result +will be reached, and, as I think, a remarkable and exceptional case +of the diffusion of silver and lead through an igneous rock be +established.</p> + +<p>It is of course possible that the Leadville porphyries are only +phases of rocks rich in silver, lead, and iron, which underlie this +region, and which have been fused and forced to the surface by an +ascending mass of deeper seated igneous rock; but even if the +argentiferous character of the porphyry shall be proved, it will +not be proved that such portions of it as here lie upon the +limestone have furnished the ore by the descending percolation of +cold surface waters. Deeper lying masses of this same silver, lead, +and iron bearing rock, digested in and leached by <i>hot</i> waters +and steam under great pressure, would seem to be a more likely +source of the ore. If the surface porphyry is as rich in silver as +Mr. Emmous reports it to be, it is too rich, for the rock that has +furnished so large a quantity of ores as that which formed the ore +bodies which I saw in the Little Chief and Highland Chief mines, +respectively 90 feet and 162 feet thick, should be poor in silver +and iron and lead, and should be rotten from the leaching it had +suffered, but except near the ore-bearing contact it is compact and +normal.</p> + +<p>Such a digested, kaolinized, desilicated rock as we would +naturally look for we find in the porphyry <i>near the contact</i>; +and its condition there, so different from what it is remote from +the contact, seems to indicate an exposure to local and decomposing +influences, such indeed as a hot chemical solution forced up from +below along the plane of contact would furnish.</p> + +<p>It is difficult to understand why the upper portions of the +porphyry sheet should be so different in character, so solid and +homogeneous, with no local concentrations or pockets of ore, if +they have been exposed to the same agencies as those which have so +changed the under surface.</p> + +<p>Accepting all the facts reported by Mr. Emmons, and without +questioning the accuracy of any of his observations, or +depreciating in any degree the great value of the admirable study +he has made of this difficult and interesting field, his conclusion +in regard to the source of the ore cannot yet be insisted on as a +logical necessity. In the judgment of the writer, the phenomena +presented by the Leadville ore deposits can be as well or better +accounted for by supposing that the plane of contact between the +limestone and porphyry has been the conduit through which heated +mineral solutions coming from deep seated and remote sources have +flowed, removing something from both the overlying and underlying +strata, and by substitution depositing sulphides of lead, iron, +silver, etc., with silica.</p> + +<p>The ore deposits of Tybo and Eureka in Nevada, of the Emma, the +Cave, and the Horn Silver [1] mines in Utah, have much in common +with those of Leadville, and it is not difficult to establish for +all of the former cases a foreign and deep seated source of the +ore. The fact that the Leadville ore bodies are sometimes +themselves excavated into chambers, which has been advanced as +proof of the falsity of the theory here advocated, has no bearing +on the question, as in the process of oxidation of ores which were +certainly once sulphides, there has been much change of place as +well as character; currents of water have flowed through them which +have collected and redeposited the cerusite in sheets of "hard +carbonate" or "sand carbonate," and have elsewhere produced +accumulations of kerargyrite, perhaps thousands of years after the +deposition of the sulphide ores had ceased and the oxidation had +begun. In the leaching and rearrangement of the ore bodies, nothing +would be more natural than that accumulations in one place should +be attended by the formation of cavities elsewhere.</p> + +<p>[Footnote 1: The Horn Silver ore body lies in a fault fissure +between a footwall of limestone and a hanging wall of trachyte, and +those who consider the Leadville ores as teachings of the overlying +porphyry would probably also regard the ore of the Horn Silver mine +as derived from the trachyte hanging wall; but three facts oppose +the acceptance of this view, viz., let, the trachyte, except in +immediate contact with the ore body, seems to be entirely barren; +2d, the Horn Silver ore "chimney," perhaps fifty feet thick, five +hundred feet wide, and of unknown depth, is the only mass of ore +yet found in a mile of well marked fissure; and 3d, the Carbonate +mine opened near by in a strong fissure with a bearing at right +angles to that of the Horn Silver, and lying entirely within the +trachyte, yields ore of a totally different kind. Both are opened +to the depth of seven hundred feet with no signs of change or +exhaustion. If the ore were derived from the trachyte, it should be +at least somewhat alike in the two mines, should be more generally +distributed in the Horn Silver fissure, and might be expected to +give out at, no great depth.</p> + +<p>If deposited by solutions coming from deep and different +sources, the observed differences in character would be natural; it +would accumulate as we find it in the channels of outflow, and +would be as time will probably prove it, perhaps variable in +quantity, but indefinitely continuous in depth.]</p> + +<p>Another question which suggests itself in reference to the +Leadville deposits is this: If the Leadville ore was once a mass of +sulphides derived from the overlying porphyry by the percolation of +surface waters, why has the deposit ceased? The deposition of +galena, blende, and pyrite in the Galena lead mines still +continues. If the leaching of the Leadville porphyry has not +resulted in the formation of alkaline sulphide solutions, and the +ore has come from the porphyry in the condition of carbonate of +lead, chloride of silver, etc., then the nature of the deposition +was quite different from that of the similar ones of Tybo, Eureka, +Bingham, etc., which are plainly gossans, and indeed is without +precedent. But if the process was similar to that in the Galena +lead region, and the ores were originally sulphides, their +formation should have continued and been detected in the Leadville +mines.</p> + +<p>For all these reasons the theory of Mr. Emmons will be felt to +need further confirmation before it is universally adopted.</p> + +<p>From what has gone before it must not be inferred that lateral +secretion is excluded by the writer from the list of agencies which +have filled mineral veins, for it is certain that the nature of the +deposit made in the fissure has frequently been influenced by the +nature of the adjacent wall rock. Numerous cases may be cited where +the ores have increased or decreased in quantity and richness, or +have otherwise changed character in passing from one formation to +another; but even here the proof is generally wanting that the vein +materials have been furnished by the wall rocks opposite the places +where they are found.</p> + +<p>The varying conductivity of the different strata in relation to +heat and electricity may have been an important factor. Trap dikes +frequently enrich veins where they approach or intersect them, and +they have often been the <i>primum mobile</i> of vein formation, +but chiefly, if not only, by supplying heat, the mainspring of +chemical action. The proximity of heated masses of rock has +promoted chemical action in the same way as do the Bunsen burners +or the sand baths in the laboratory; but no case has yet come under +my observation where it was demonstrable that the filling of a +fissure vein had been due to secretion from igneous or sedimentary +wall rocks.</p> + +<p>In the Star District of Southern Utah the country rock is +Palæozoic limestone, and it is cut by so great a number and +variety of mineral veins that from the Harrisburg, a central +location, a rifle shot would reach ten openings, all on as many +distinct and different veins (viz., the Argus, Little Bilk, Clean +Sweep, Mountaineer, St. Louis, Xenia, Brant, Kannarrah, Central, +and Wateree). The nearest trap rock is half a mile or more distant, +a columnar dike perhaps fifteen feet in thickness, cutting the +limestone vertically. On either side of this dike is a vein from +one to three feet in thickness, of white quartz with specks of ore. +Where did that quartz come from? From the limestone? But the +limestone contains very little silica, and is apparently of normal +composition quite up to the vein. From the trap? This is compact, +sonorous basalt, apparently unchanged; and that could not have +supplied the silica without complete decomposition.</p> + +<p>I should rather say from silica bearing hot waters that flowed +up along the sides of the trap, depositing there, as in the +numerous and varied veins of the vicinity, mineral matters brought +from a zone of solution far below.</p> + +<p>To summarize the conclusions reached in this discussion. I may +repeat that the results of all recent as well as earlier +observations has been to convince me that Richthofen's theory of +the filling of the Comstock lode is the true one, and that the +example and demonstration of the formation of mineral veins +furnished by the Steamboat Springs is not only satisfactory, but +typical.</p> + +<hr> +<p>[NATURE.]</p> + +<p><a name="21"></a></p> + +<h2>HABITS OF BURROWING CRAYFISHES IN THE UNITED STATES.</h2> + +<p>On May 13, 1883, I chanced to enter a meadow a few miles above +Washington, on the Virginia side of the Potomac, at the head of a +small stream emptying into the river. It was between two hills, at +an elevation of 100 feet above the Potomac, and about a mile from +the river. Here I saw many clayey mounds covering burrows scattered +over the ground irregularly both upon the banks of the stream and +in the adjacent meadow, even as far as ten yards from the bed of +the brook. My curiosity was aroused, and I explored several of the +holes, finding in each a good-sized crayfish, which Prof. Walter +Faxon identified as <i>Cambarus diogenes</i>, Girard <i>(C. +obesus</i>, Hagen), otherwise known as the burrowing crayfish. I +afterward visited the locality several times, collecting specimens +of the mounds and crayfishes, which are now in the United States +National Museum, and making observations.</p> + +<p>At that time of the year the stream was receding, and the meadow +was beginning to dry. At a period not over a month previous, the +meadows, at least as far from the stream as the burrows were found, +had been covered with water. Those burrows near the stream were +less than six inches deep, and there was a gradual increase in +depth as the distance from the stream became greater. Moreover, the +holes farthest from the stream were in nearly every case covered by +a mound, while those nearer had either a very small chimney or none +at all, and subsequent visits proved that at that time of year the +mounds were just being constructed, for each time I revisited the +place the mounds were more numerous.</p> + +<p class="ctr"><img src="./illustrations/15a.png" alt= +"Fig. 1 Section of Crayfish burrow"></p> + +<p class="ctr">Fig. 1 Section of Crayfish burrow</p> + +<p>The length, width, general direction of the burrows, and number +of the openings were extremely variable, and the same is true of +the mounds. Fig. 1 illustrates a typical burrow shown in section. +Here the main burrow is very nearly perpendicular, there being but +one oblique opening having a very small mound, and the main mound +is somewhat wider than long. Occasionally the burrows are very +tortuous, and there are often two or three extra openings, each +sometimes covered by a mound. There is every conceivable shape and +size in the chimneys, ranging from a mere ridge of mud, evidently +the first foundation, to those with a breadth one-half the height. +The typical mound is one which covers the perpendicular burrow in +Fig. 1, its dimensions being six inches broad and four high. Two +other forms are shown in Fig. 2. The burrows near the stream were +seldom more than six inches deep, being nearly perpendicular, with +an enlargement at the base, and always with at least one oblique +opening. The mounds were usually of yellow clay, although in one +place the ground was of fine gravel, and there the chimneys were of +the same character. They were always circularly pyramidal in shape, +the hole inside being very smooth, but the outside was formed of +irregular nodules of clay hardened in the sun and lying just as +they fell when dropped from the top of the mound. A small quantity +of grass and leaves was mixed through the mound, but this was +apparently accidental.</p> + +<p>The size of the burrows varied from half an inch to two inches +in diameter, being smooth for the entire distance, and nearly +uniform in width. Where the burrow was far distant from the stream, +the upper part was hard and dry. In the deeper holes I invariably +found several enlargements at various points in the burrow. Some +burrows were three feet deep, indeed they all go down to water, +and, as the water in the ground lowers, the burrow is undoubtedly +projected deeper. The diagonal openings never at that season of the +year have perfect chimneys, and seldom more than a mere rim. In no +case did I find any connection between two different burrows. In +digging after the inhabitants I was seldom able to secure a +specimen from the deeper burrows, for I found that the animal +always retreated to the extreme end, and when it could go no +farther would use its claws in defense. Both males and females have +burrows, but they were never found together, each burrow having but +a single individual. There is seldom more than a pint of water in +each hole, and this is muddy and hardly suitable to sustain +life.</p> + +<p class="ctr"><img src="./illustrations/15b.png" alt= +"Fig. 2 Crayfish Mound"></p> + +<p class="ctr">Fig. 2 Crayfish Mound</p> + +<p>The neighboring brooks and springs were inhabited by another +species of crayfish, <i>Cambaras bartonii</i>, but although +especial search was made for the burrowing species, in no case was +a single specimen found outside of the burrows. <i>C. bartonii</i> +was taken both in the swiftly running portions of the stream and in +the shallow side pools, as well as in the springs at the head of +small rivers. It would swim about in all directions, and was often +found under stones and in little holes and crevices, none of which +appeared to have been made for the purpose of retreat, but were +accidental. The crayfishes would leave these little retreats +whenever disturbed, and swim away down stream out of sight. They +were often found some distance from the main stream under rocks +that had been covered by the brook at a higher watermark; but +although there was very little water under the rocks, and the +stream had not covered them for at least two weeks, they showed no +tendency to burrow. Nor have I ever found any burrows formed by the +river species <i>Cumbarus affinis.</i> although I have searched +over miles of marsh land on the Potomac for this purpose.</p> + +<p class="ctr"><img src="./illustrations/15c.png" alt= +"Fig. 2 Crayfish Mound (shorter)"></p> + +<p class="ctr">Fig. 2 Crayfish Mound (shorter)</p> + +<p>The brook near where my observations were made was fast +decreasing in volume, and would probably continue to do so until in +July its bed would be nearly dry. During the wet seasons the meadow +is itself covered. Even in the banks of the stream, then under +water, there were holes, but they all extended obliquely without +exception, there being no perpendicular burrows and no mounds. The +holes extended in about six inches, and there was never a +perpendicular branch, nor even an enlargement at the end. I always +found the inhabitant near the mouth, and by quickly cutting off the +rear part of the hole could force him out, but unless forcibly +driven out it would never leave the hole, not even when a stick was +thrust in behind it. It was undoubtedly this species that Dr. +Godman mentioned in his "Rambles of a Naturalist," and which Dr. +Abbott <i>(Am. Nal.,</i> 1873, p. 81) refers to <i>C. bartonii</i>. +Although I have no proof that this is so, I am inclined to believe +that the burrowing crayfishes retire to the stream in winter and +remain there until early spring, when they construct their burrows +for the purpose of rearing their young and escaping the summer +droughts. My reason for saying this is that I found one burrow +which on my first visit was but six inches deep, and later had been +projected to a depth at least twice as great, and the inhabitant +was an old female.</p> + +<p>I think that after the winter has passed, and while the marsh is +still covered with water, impregnation takes place and burrows are +immediately begun. I do not believe that the same burrow is +occupied for more than one year, as it would probably fill up +during the winter. At first it burrows diagonally, and as long as +the mouth is covered with water is satisfied with this oblique +hole. When the water recedes, leaving the opening uncovered, the +burrow must be dug deeper, and the economy of a perpendicular +burrow must immediately suggest itself. From that time the +perpendicular direction is preserved with more or less regularity. +Immediately after the perpendicular hole is begun, a shorter +opening to the surface is needed for conveying the mud from the +nest, and then the perpendicular opening is made. Mud from this, +and also from the first part of the perpendicular burrow, is +carried out of the diagonal opening and deposited on the edge. If a +freshet occurs before this rim of mud has had a chance to harden, +it is washed away, and no mound is formed over the oblique +burrow.</p> + +<p>After the vertical opening is made, as the hole is bored deeper, +mud is deposited on the edge, and the deeper it is dug the higher +the mound. I do not think that the chimney is a necessary part of +the nest, but simply the result of digging. I carried away several +mounds, and in a week revisited the place, and no attempt had been +made to replace them; but in one case, where I had in addition +partly destroyed the burrow by dropping mud into it, there was a +simple half rim of mud around the edge, showing that the crayfish +had been at work; and as the mud was dry the clearing must have +been done soon after my departure. That the crayfish retreats as +the water in the ground falls lower and lower is proved by the fact +that at various intervals there are bottled-shaped cavities marking +the end of the burrow at an earlier period. A few of those mounds +farthest from the stream had their mouths closed by a pellet of +mud. It is said that all are closed during the summer months.</p> + +<p>How these animals can live for months in the muddy, impure water +is to me a puzzle. They are very sluggish, possessing none of the +quick motions of their allied <i>C. bartonii,</i> for when taken +out and placed either in water or on the ground, they move very +slowly. The power of throwing off their claws when these are +grasped is often exercised. About the middle of May the eggs hatch, +and for a time the young cling to the mother, but I am unable to +state how long they remain thus. After hatching they must grow +rapidly, and soon the burrow will be too small for them to live in, +and they must migrate. It would be interesting to know more about +the habits of this peculiar species, about which so little has been +written. An interesting point to settle would be how and where it +gets its food. The burrow contains none, either animal or +vegetable. Food must be procured at night, or when the sun is not +shining brightly. In the spring and fall the green stalks of meadow +grasses would furnish food, but when these become parched and dry +they must either dig after and eat the roots, or search in the +stream. I feel satisfied that they do not tunnel among the roots, +for if they did so these burrows would be frequently met with. +Little has as yet been published upon this subject, and that little +covers only two spring months--April and May--and it would be +interesting if those who have an opportunity to watch the species +during other seasons, or who have observed them at any season of +the year, would make known their results.</p> + +<p>RALPH S. TARR</p> + +<hr> +<p><a name="22"></a></p> + +<h2>OUR SERVANTS, THE MICROBES.</h2> + +<p>Who of us has not, in a partially darkened room, seen the rays +of the sun, as they entered through apertures or chinks in the +shutters, exhibit their track by lighting up the infinitely small +corpuscles contained in the air? Such corpuscles always exist, +except in the atmosphere of lofty mountains, and they constitute +the dust of the air. A microscopic examination of them is a matter +of curiosity. Each flock is a true museum (Fig. 1), wherein we find +grains of mineral substances associated with organic debris, and +germs of living organisms, among which must be mentioned the +<i>microbes</i>.</p> + +<p>Since the splendid researches of Mr. Pasteur and his pupils on +fermentation and contagious diseases, the question of microbes has +become the order of the day.</p> + +<p>In order to show our readers the importance of the study of the +microbes, and the results that may be reached by following the +scientific method created by Mr. Pasteur, it appears to us +indispensable to give a summary of the history of these organisms. +In the first place, what is a microbe? Although much employed, the +word has not been well defined, and it would be easy to find +several definitions of it. In its most general sense, the term +microbe designates certain colorless algæ belonging to the +family Bacteriaceæ, the principal forms of which are known +under the name of <i>Micrococcus. Bacterium, Bacillus. Vibrio, +/Spirillum, etc</i>.</p> + +<p>In order to observe these different forms of Bacteriaceæ +it is only necessary to examine microscopically a drop of water in +which organic matter has been macerated, when there will be seen +<i>Micrococci</i> (Fig. 2, I.)looking like spherical granules, +<i>Bacteria</i> in the form of very short rods, <i>Bacilli</i> +(Fig. 2, V.), <i>Vibriones</i> (Fig. 2, IV.,) moving their straight +or curved filaments, and <i>Spirilli</i> (Fig. 2, VI.), rolled up +spirally. These varied forms are not absolutely constant, for it +often happens in the course of its existence that a species assumes +different shapes, so that it is difficult to take the form of these +algæ as a basis for classifying them, when all the phases of +their development have not been studied.</p> + +<p>The Bacteriaceæ are reproduced with amazing rapidity. If +the temperature is proper, a limpid liquid such as chicken or veal +broth will, in a few hours, become turbid and contain millions of +these organisms. Multiplication is effected through fission, that +is to say, each globule or filament, after elongating, divides into +two segments, each of which increases in its turn, to again divide +into two parts, and so on (Fig. 2, I. b). But multiplication in +this way only takes place when the bacteria are placed in a proper +nutritive liquid; and it ceases when the liquid becomes +impoverished and the conditions of life become difficult. It is at +this moment that the formation of <i>spores</i> +occurs--reproductive bodies that are destined to permit the +algæ to traverse, without perishing, those phases where life +is impossible. The spores are small, brilliant bodies that form in +the center or at the extremity of each articulation or globule of +the bacterium (Fig. 2, II. l), and are set free through the +breaking up of the joints. There are, therefore, two phases to be +distinguished in the life of microbes--that of active life, during +which they multiply with great rapidity, are most active, and cause +sicknesses or fermentations, and that of retarded life, that is to +say, the state, of resting spores in which the organisms are +inactive and consequently harmless. It is curious to find that the +resistance to the two causes of destruction is very different in +the two cases.</p> + +<p>In the state of active life the bacterides are killed by a +temperature of from 70 to 80 degrees, while the spores require the +application of a temperature of from 100 to 120 degrees to kill +them. Oxygen of a high pressure, which is, as well known from +Bert's researches, a poison for living beings, kills many bacteria +in the state of active life, but has no influence upon their +spores.</p> + +<p>In a state of active life the bacteriae are interesting to +study. The absence of green matter prevents them from feeding upon +mineral matter, and they are therefore obliged to subsist upon +organic matter, just as do plants that are destitute of chlorophyl +(such as fungi, broomrapes, etc.). This is why they are only met +with in living beings or upon organic substances. The majority of +these algae develop very well in the air, and then consume oxygen +and exhale carbonic acid, like all living beings. If the supply of +air be cut off, they resist asphyxia and take the oxygen that they +require from the compounds that surround them. The result is a +complete and rapid decomposition of the organic materials, or a +fermentation. Finally, there are even certain species that die in +the presence of free oxygen, and that can only live by protecting +themselves from contact with this gas through a sort of jelly. +These are ferments, such as <i>Bacillus amylobacter,</i> or butyric +ferment, and <i>B. septicus</i>, or ferment of the putrefaction of +nitrogenized substances.</p> + +<p class="ctr"><a href="./illustrations/15d.png"><img src= +"./illustrations/15d_th.jpg" alt="FIG. 1.--ATMOSPHERIC DUST."> +</a></p> + +<p class="ctr">FIG. 1.--ATMOSPHERIC DUST.</p> + +<p>These properties explain the regular distribution of bacteria in +liquids exposed to the air. Thus, in water in which plants have +been macerated the surface of the liquid is occupied by <i>Bacillus +subtilis</i>. which has need of free oxygen in order to live, while +in the bulk of the liquid, in the vegetable tissues, we find other +bacteria, notably <i>B. amylobacter</i>, which lives very well by +consuming oxygen in a state of combination. Bacteria, then, can +only live in organic matters, now in the presence and now in the +absence of air.</p> + +<p>What we have just said allows us to understand the process of +cultivating these organisms. When it is desired to obtain these +algae, we must take organic matters or infusions of such. These +liquids or substances are heated to at least 120° in order to +kill the germs that they may contain, and this is called +"sterilizing." In this sterilized liquid are then sown the bacteria +that it is desired to study, and by this means they can be obtained +in a state of very great purity.</p> + +<p>The Bacteriaceae are very numerous. Among them we must +distinguish those that live in inert organic matters, alimentary +substances, or debris of living beings, and which cause chemical +decompositions called fermentations. Such are <i>Mycoderma +aceti</i>, which converts the alcohol of fermented beverages into +vinegar; <i>Micrococcus ureae</i>, which converts the urea of urine +into carbonate of ammonia, and <i>Micrococcus nitrificans,</i> +which converts nitrogenized matters into intrates, etc. Some, that +live upon food products, produce therein special coloring matters; +such are the bacterium of blue milk, and <i>Micrococcus +prodigiosus</i> (Fig. 2, I.), a red alga that lives upon bread and +forms those bloody spots that were formerly considered by the +superstitious as the precursors of great calamities.</p> + +<p class="ctr"><a href="./illustrations/15e.png"><img src= +"./illustrations/15e_th.jpg" alt= +"Fig. 2.--VARIOUS MICROBES. (Highly magnified.)"></a></p> + +<p class="ctr">Fig. 2.--VARIOUS MICROBES. (Highly magnified.)</p> + +<p>Another group of bacteria has assumed considerable importance in +pathology, and that is the one whose species inhabit the tissues of +living animals, and cause more or less serious alterations therein, +and often death. Most contagious diseases and epidemics are due to +algæ of this latter group. To cite only those whose origin is +well known, we may mention the bacterium that causes charbon, the +micrococcus of chicken cholera, and that of hog measles.</p> + +<p>It will be seen from this sketch how important the study of +these organisms is to man, since be must defend his body against +their invasions or utilize them for bringing about useful chemical +modifications in organic matters.</p> + +<p><i>Our Servants.</i>--We scarcely know what services microbes +may render us, yet the study of them, which has but recently been +begun, has already shown, through the remarkable labors of Messrs. +Pasteur, Schloesing and Muntz, Van Tieghem, Cohn, Koch, etc., the +importance of these organisms in nature. All of us have seen wine +when exposed to air gradually sour, and become converted into +vinegar, and we know that in this case the surface of the liquid is +covered with white pellicles called "mother of vinegar." These +pellicles are made up of myriads of globules of <i>Mycoderma +aceti</i>. This mycoderm is the principal agent in the +acidification of wine, and it is it that takes oxygen from the air +and fixes it in the alcohol to convert it into vinegar. If the +pellicle that forms becomes immersed in the liquid, the wine will +cease to sour.</p> + +<p>The vinegar manufacturers of Orleans did not suspect the role of +the mother of vinegar in the production of this article when they +were employing empirical processes that had been established by +practice. The vats were often infested by small worms ("vinegar +eals") which disputed with the mycoderma for the oxygen, killed it +through submersion, and caused the loss of batches that had been +under troublesome preparation for months. Since Mr. Pasteur's +researches, the <i>Mycoderma aceti</i> has been sown directly in +the slightly acidified wine, and an excellent quality of vinegar +has thus been obtained, with no fear of an occurrence of the +disasters that accompanied the old process.</p> + +<p>Another example will show us the microbes in activity in the +earth. Let us take a pinch of vegetable mould, water it with +ammonia compounds, and analyze it, and we shall find nitrates +therein. Whence came these nitrates? They came from the oxidation +of the ammonia compounds brought about by moistening, since the +nitrogen of the air does not seem to combine under normal +conditions with the surrounding oxygen. This oxidation of ammonia +compounds is brought about, as has been shown by Messrs. Schloesing +and Muntz, by a special ferment, the <i>Micrococcus +nitrificans</i>, that belongs to the group of Bacteriacæ. In +fact, the vapors of chloroform, which anesthetize plants, also +prevent nitrification, since they anaesthetize the nitric ferment. +So, too, when we heat vegetable humus to 100°, nitrification is +arrested, because the ferment is killed. Finally, we may sow the +nitric ferment in calcined earth and cause nitrification to occur +therein as surely as we can bring about a fermentation in wine by +sowing <i>Mycoderma aceti</i> in it.</p> + +<p>The nitric ferment exists in all soils and in all latitudes, and +converts the ammoniacal matters carried along by the rain into +nitrates of a form most assimilable by plants. It therefore +constitutes one of the important elements for fertilizing the +earth.</p> + +<p>Finally, we must refer to the numerous bacteria that occasion +putrefaction in vegetable or animal organisms. These microbes, +which float in the air, fall upon dead animals or plants, develop +thereon, and convert into mineral matters the immediate principles +of which the tissues are composed, and thus continually restore to +the air and soil the elements necessary for the formation of new +organic substances. Thus, <i>Bacillus amylobacter</i> (Fig. 2, +II.), as Mr. Van Tieghem has shown, subsists upon the hydrocarbons +contained in plants, and disorganizes vegetable tissues in +disengaging hydrogen, carbonic acid, and vegetable acids. +<i>Bacterium roseopersicina</i> forms, in pools, rosy or red +pellicles that cover vegetable debris and disengage gases of an +offensive odor. This bacterium develops in so great quantity upon +low shores covered with fragments of algæ as to sometimes +spread over an extent of several kilometers. These microbes, like +many others, continuously mineralize organic substances, and thus +exhibit themselves as the indispensable agents of the movement of +the matter that incessantly circulates from the mineral to the +organic world, and <i>vice versa</i>.--<i>Science et +Nature.</i></p> + +<hr> +<p><a name="24"></a>Palms sprouted from seeds kept warm by contact +of the vessel with the water boiler of a kitchen range are grown by +a man in New York.</p> + +<hr> +<p><a name="28"></a></p> + +<h2>EPITAPHIUM CHYMICUM.</h2> + +<p>The following epitaph was written by a Dr. Godfrey, who died in +Dublin in 1755:</p> + +<pre> + Here lieth, to <i>digest macerate</i>, and <i>amalgamate</i> into clay, + <i>In Batneo Arenæ</i>, + <i>Stratum super Stratum</i> + The <i>Residuum, Terra damnata</i> and <i>Caput Mortuum</i>, + Of BOYLE GODFREY, Chymist and M.D. + A man who in this Earthly Laboratory pursued various + <i>Processes</i> to obtain <i>Arcanum Vitæ</i>, + Or the Secret to Live; + Also <i>Aurum Vitæ</i>, + or the art of getting rather than making gold. + <i>Alchymist</i>-like, all his Labour and <i>Projection</i>, + as <i>Mercury</i> in the Fire, <i>Evaporated</i> in <i>Fume</i> when he + <i>Dissolved</i> to his first principles. + He <i>departed</i> as poor + as the last drops of an <i>Alembic</i>; for Riches are not + poured on the <i>Adepts</i> of this world. + Though fond of News, he carefully avoided the + <i>Fermentation, Effervescence</i>, and <i>Decrepitation</i> of this + life. Full seventy years his <i>Exalted Essence</i> + was <i>hermetically</i> sealed in its <i>Terrene Matrass</i>; but the + Radical Moisture being <i>exhausted</i>, the <i>Elixir Vitæ</i> spent, + And <i>exsiccate</i> to a <i>Cuticle</i>, he could not <i>suspend</i> + longer in his <i>Vehicle</i>, but <i>precipitated Gradatim, per</i> + <i>Campanam</i>, to his original dust. + May that light, brighter than <i>Bolognian Phosphorus</i>, + Preserve him from the <i>Athanor, Empyreuma</i>, and <i>Reverberatory + Furnace</i> of the other world, + Depurate him from the <i>Fæces</i> and <i>Scoria</i> of this, + Highly <i>Rectify</i> and <i>Volatilize</i>, his <i>æthereal</i> spirit, + Bring it over the <i>Helm</i> of the <i>Retort</i> of this Globe, place + in a proper <i>Recipient</i> or <i>Crystalline</i> orb, + Among the elect of the <i>Flowers of Benjamin</i>; never to + be <i>saturated</i> till the General <i>Resuscitation, Deflagration, + Calcination,</i> and <i>Sublimation</i> of all things. +</pre> + +<hr> +<p><a name="23"></a></p> + +<h2>A NEW STOVE CLIMBER.</h2> + +<h3>(<i>Ipomæa thomsoniana</i>.)</h3> + +<p>The first time we saw flowers of this beautiful new climbing +plant (about a year ago) we thought that it was a white-flowered +variety of the favorite old Ipomæa Horsfalliæ, as it so +nearly resembles it. It has, however, been proved to be a distinct +new species, and Dr. Masters has named it in compliment to Mr. +Thomson of Edinburgh. It differs from I. Horsfalliæ in having +the leaflets in sets of threes instead of fives, and, moreover, +they are quite entire. The flowers, too, are quite double the size +of those of Horsfalliæ, but are produced in clusters in much +the same way; they are snow-white. This Ipomæa is indeed a +welcome addition to the list of stove-climbing plants, and will +undoubtedly become as popular as I. Horsfalliæ, which may be +found in almost every stove. It is of easy culture and of rapid +growth, and it is to be hoped that it is as continuous in flowering +as Horsfalliæ. It is among the new plants of the year now +being distributed by Mr. B.S. Williams, of the Victoria Nurseries, +Upper Holloway.--<i>The Garden</i>.</p> + +<p class="ctr"><a href="./illustrations/16a.png"><img src= +"./illustrations/16a_th.jpg" alt= +"A NEW STOVE CLIMBER. IPOMÆA THOMSONIANA."></a></p> + +<p class="ctr">A NEW STOVE CLIMBER. IPOMÆA THOMSONIANA.</p> + +<hr> +<p></a><a name="25"></a></p> + +<h2>HISTORY OF WHEAT.</h2> + +<p>Isis was supposed to have introduced wheat into Egypt, Demeter +into Greece, and the Emperor Chin-Wong into China, about 3000 B.C. +In Europe it was cultivated before the period of history, as +samples have been recovered from the lacustrine dwellings of +Switzerland.</p> + +<p>The first wheat raised in the "New World" was sown by the +Spaniards on the island of Isabella, in January, 1494, and on March +the 30th the ears were gathered. The foundation of the wheat +harvest of Mexico is said to have been three or four grains +carefully cultivated in 1530, and preserved by a slave of Cortez. +The first crop of Quito was raised by a Franciscan monk in front of +the convent. Garcilasso de la Vega affirms that in Peru, up to +1658, wheaten bread had not been sold in Cusco. Wheat was first +sown by Goshnold Cuttyhunk, on one of the Elizabeth Islands in +Buzzard's Bay, off Massachusetts, in 1602, when he first explored +the coast. In 1604, on the island of St. Croix, near Calais, Me., +the Sieur de Monts had some wheat sown which flourished finely. In +1611 the first wheat appears to have been sown in Virginia. In +1626, samples of wheat grown in the Dutch Colony at New Netherlands +were shown in Holland. It is probable that wheat was sown in the +Plymouth Colony prior to 1629, though we find no record of it, and +in 1629 wheat was ordered from England to be used as seed. In 1718 +wheat was introduced into the valley of the Mississippi by the +"Western Company." In 1799 it was among the cultivated crops of the +Pimos Indians of the Gila River, New Mexico.</p> + +<hr> +<h2>DETERMINATION OF STARCH.</h2> + +<p>According to Bunzener and Fries <i>(Zeitschrift fur das gesammte +Brauwesen</i>), a thick, sirupy starch paste prepared with a +boiling one per cent solution of salicylic acid is only very slowly +saccharified, and on cooling deposits crystalline plates of starch. +For the determination of starch in barley the finely-ground sample +is boiled for three-quarters of an hour with about thirty times its +weight of a one per cent solution of salicylic acid, the resulting +colorless opalescent liquid filtered with the aid of suction, and +the starch therein inverted by means of hydrochloric acid. The +dextrose formed is estimated by Fehling's solution. The results are +one to two per cent higher than when the starch is brought into +solution by water at 135° C.</p> + +<hr> +<p>A catalogue, containing brief notices of many important +scientific papers heretofore published in the SUPPLEMENT, may be +had gratis at this office.</p> + +<hr> +<h2>THE SCIENTIFIC AMERICAN SUPPLEMENT.</h2> + +<h3>PUBLISHED WEEKLY.</h3> + +<p><b>Terms of Subscription, $5 a Year.</b></p> + +<p>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.</p> + +<p>All the back numbers of THE SUPPLEMENT, from the commencement, +January 1, 1876, can be had. Price, 10 cents each.</p> + +<p>All the back volumes of THE SUPPLEMENT can likewise be supplied. +Two volumes are issued yearly. 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