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+The Project Gutenberg eBook of Scientific American Supplement, September 17, 1887
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+<pre>
+
+The Project Gutenberg EBook of Scientific American Supplement, No. 611,
+September 17, 1887, by Various
+
+This eBook is for the use of anyone anywhere at no cost and with
+almost no restrictions whatsoever.  You may copy it, give it away or
+re-use it under the terms of the Project Gutenberg License included
+with this eBook or online at www.gutenberg.org
+
+
+Title: Scientific American Supplement, No. 611, September 17, 1887
+
+Author: Various
+
+Release Date: October 26, 2005 [EBook #16948]
+
+Language: English
+
+Character set encoding: ISO-8859-1
+
+*** START OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN ***
+
+
+
+
+Produced by Juliet Sutherland and the Online Distributed
+Proofreading Team at www.pgdp.net
+
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+
+
+</pre>
+
+<p class="wider"><a href="./images/title.png"><img src="./images/title_th.png" alt="Issue Title" /></a></p>
+<h1>SCIENTIFIC AMERICAN SUPPLEMENT NO. 611</h1>
+<h2>NEW YORK, SEPTEMBER 17, 1887</h2>
+<h4>Scientific American Supplement. Vol. XXIV., No. 611.</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 />
+
+<div class="center">
+<table summary="Contents" border="0" cellspacing="5">
+<tr>
+<th colspan="2" align="center">TABLE OF CONTENTS.</th>
+</tr>
+<tr><td colspan="2">&nbsp;</td><td>PAGE.</td>
+</tr>
+<tr>
+<td class="tdtl1">I.</td>
+<td class="tdtl2"><a href="#art01">BIOGRAPHY.&mdash;The New Statue of Philip Lebon.&mdash;Biography of
+    the French pioneer inventor of gas lighting, with notes on
+    the recent inauguration of his statue.&mdash;1 illustration.</a></td><td>9757</td>
+</tr>
+
+<tr>
+<td class="tdtl1">II.</td>
+<td class="tdtl2"><a href="#art02">CHEMISTRY.&mdash;The Analysis of Urine.&mdash;An elaborate investigation
+    of the method of analyzing chemically and microscopically
+    this fluid, with illustrations of the apparatus employed.&mdash;4
+    illustrations</a></td><td>9758</td>
+</tr>
+
+<tr>
+<td class="tdtl1">III.</td>
+<td class="tdtl2"><a href="#art03">ELECTRICITY.&mdash;Electrical Alarm for Pharmacists.&mdash;An apparatus
+    for indicating to the pharmacist when he removes from the
+    shelf a bottle containing poison.&mdash;2 illustrations.</a></td><td>9753</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art04"> Electric Steel Railways.&mdash;By <span class="smcap">George W. Mansfield.</span>&mdash;A full
+    discussion of the problem of electric railways; comparison with
+    horse and cable traction.</a></td><td>9752</td>
+</tr>
+
+<tr>
+<td class="tdtl1">IV.</td>
+<td class="tdtl2"><a href="#art05">ENGINEERING.&mdash;Improved Oscillating Hydraulic Motor.&mdash;A
+    small motor for household use, as for driving sewing machines and
+    other domestic machinery.&mdash;8 illustrations.</a></td><td>9751</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art06"> The Ceara Harbor Works.&mdash;A remarkable engineering work now
+    in progress in Brazil; the formation of an artificial
+    harbor.&mdash;4 illustrations.</a></td><td>9752</td>
+</tr>
+
+<tr>
+<td class="tdtl1">V.</td>
+<td class="tdtl2"><a href="#art07">GEOLOGY.&mdash;Notes of a Recent Visit to Some of the Petroleum-Producing
+    Territories of the United States and Canada.&mdash;By
+    <span class="smcap">Boverton Redwood</span>, F.I.C., F.C.S.&mdash;The second portion of this
+    valuable paper, treating more particularly of Canadian
+    petroleum.</a></td><td>9765</td>
+</tr>
+
+<tr>
+<td class="tdtl1">VI.</td>
+<td class="tdtl2"><a href="#art08">METEOROLOGY.&mdash;The &quot;Meteorologiske Institut&quot; at Upsala,
+    and Cloud Measurements.&mdash;The methods used and results attained
+    in the famous Upsala observatory under Profs. Ekholm and
+    Hagström; the measurement of clouds.&mdash;1 illustration.</a></td><td>9764</td>
+</tr>
+
+<tr>
+<td class="tdtl1">VII.</td>
+<td class="tdtl2"><a href="#art09">MISCELLANEOUS.&mdash;Drawing Instrument for Accurate Work.&mdash;By
+    <span class="smcap">J. Lehrke.</span>&mdash;A magnifying instrument for fine work and
+    measurements.&mdash;2 illustrations.</a></td><td>9754</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art10"> Liquid and Gaseous Rings.&mdash;Notes on the production of vortex
+    rings.&mdash;The different aspects and breaking up of smoke rings.&mdash;6
+    illustrations.</a></td><td>9760</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art11"> Scenes among the Extinct Volcanoes of Rhineland.&mdash;The picturesque
+    features of the geological formations of this region described.&mdash;10
+    illustrations.</a></td><td>9762</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art12"> Shall We Have a National Horse?&mdash;An eloquent plea by <span class="smcap">Randolph
+    Huntington</span> for the production of a good type of animal.&mdash;Use
+    of the Arabian horse as an improver of the breed.</a></td><td>9760</td>
+</tr>
+
+<tr>
+<td class="tdtl1">VIII.</td>
+<td class="tdtl2"><a href="#art13">NAVAL ENGINEERING.&mdash;Trial Trip of the Ohio.&mdash;The remarkable
+    results attained by the introduction of new boilers and
+    machinery in an American steamship.</a></td><td>9751</td>
+</tr>
+
+<tr>
+<td class="tdtl1">IX.</td>
+<td class="tdtl2"><a href="#art14">PHYSIOLOGY.&mdash;Apparatus for Determining Mechanically the
+    Reaction Period of Hearing.&mdash;An interesting study of the time of
+    transmission of an impulse through the sensor and motor nerves.&mdash;1
+    illustration.</a></td><td>9753</td>
+</tr>
+
+<tr>
+<td class="tdtl1">X.</td>
+<td class="tdtl2"><a href="#art15">SANITATION.&mdash;A New Disinfector.&mdash;Description of a new apparatus
+    for disinfecting by superheated steam and air, with tabular
+    statement of elaborate tests made with it.&mdash;2
+    illustrations.</a></td><td>9754</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art16"> Trees from a Sanitary Aspect.&mdash;By <span class="smcap">Charles Roberts</span>, F.R.C.S.,
+    etc.&mdash;The sanitary value of trees considered by this eminent
+    sanitarian.&mdash;The uses and abuses of shade near houses.</a></td><td>9765</td>
+</tr>
+
+<tr>
+<td class="tdtl1">XI.</td>
+<td class="tdtl2"><a href="#art17">TECHNOLOGY.&mdash;A New Alkali Process.&mdash;The Parnell &amp; Simpson
+    process of making carbonate of soda, combining the features of
+    the Leblanc and ammonia methods.</a></td><td>9755</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art18"> A New Process for the Distillation and Concentration of Chemical
+    Liquids.&mdash;By <span class="smcap">George Anderson</span>, of London.&mdash;An apparatus
+    and process especially adapted to the manufacture of sulphate of
+    ammonia.&mdash;The invention of Alex. Angus Croll described.&mdash;1
+    illustration.</a></td><td>9757</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art19"> Barlow's Machine for Moulding Candles.&mdash;A new apparatus for
+    candle manufacture, fully described and illustrated.&mdash;5
+    illustrations.</a></td><td>9754</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art20"> Temperature of Gas Distillation.&mdash;The mooted question discussed
+    by Mr. <span class="smcap">Wm. Foulis</span>, the eminent gas engineer.</a></td><td>9756</td>
+</tr>
+<tr><td></td>
+<td class="tdtl2"><a href="#art21"> The Largest Black Ash Furnace in the World.&mdash;Note of a recent
+    furnace for use in the Leblanc process of soda manufacture.</a></td><td>9756</td>
+</tr>
+</table>
+</div>
+
+<hr />
+
+
+<h2><a name="art05" id="art05"></a><a name="Page_9751" id="Page_9751"></a>IMPROVED OSCILLATING HYDRAULIC MOTOR.</h2>
+
+<p>The motor of MM. Schaltenbrand &amp; Moller is adapted for use for
+household purposes, where small power is required, as in driving
+sewing machines.</p>
+
+<p>Fig. 1 shows the motor with all its parts in side elevation, the
+flywheel and head rest being in section. Fig. 2 is a side view, with
+the air reservoir and distribution valve in section through the line
+1-2. Figs. 3 and 4 represent the same apparatus, but without support,
+as where it is to be used on the table of a sewing machine, with the
+crank of the motor directly fastened to the flywheel of the sewing
+machine. Fig. 5 is a plan or horizontal section at the level of the
+line 3-4, and Fig. 6 is a section passing through the same line, but
+only including the cylinder and axis of the distributing valve. Fig. 7
+is a horizontal section of the button of the cock through the line 5-6
+of Fig. 3. Finally, Fig. 8 shows in detail, plan, and elevation the
+arrangement of the starting valve.</p>
+
+<div class="figcenter">
+<a href="./images/1.png"><img src="./images/1_th.png" width="362" height="450" alt="Figs. 1 through 8 IMPROVED OSCILLATING HYDRAULIC MOTOR." title="Figs 1 -8" /></a>
+<span class="caption"><br />Figs. 1 through 8<br />IMPROVED OSCILLATING HYDRAULIC MOTOR.</span>
+</div>
+
+<p>This little motor does not show any new principle. It uses the old
+oscillating cylinder, but it embraces in its construction ingenious
+details which render its application very simple and very easy,
+especially, as we have already said, to sewing machines.</p>
+
+<p>In the first place, the oscillating bronze cylinder, A, is cast in one
+piece with the distribution cock, <i>a</i>, Fig. 3, and its seat, <i>b</i>, also
+of bronze, is adjusted and fastened by means of the screw, <i>b</i>, to the
+air reservoir, C', cast with its cistern, C, acting as foundation or
+bed plate for the motor. This cistern is held either on the base of
+the cast iron bearing frame, D, of the main shaft, <i>d</i>, <i>d</i>, Figs. 1
+and 2, or directly on the sewing machine table, Figs. 3 and 4, by
+means of two pins, <i>e</i> and <i>e'</i>, so that it can oscillate about an
+axis which is perpendicular to the shaft, <i>d</i>, to which is attached
+the disk, F, carrying the crank.</p>
+
+<p>This arrangement of parts, in combination with the horizontal axis of
+the distribution valve and with the piston rod, <i>g</i>, considered as a
+vertical axis of rotation, forms a species of universal joint between
+the crank pin and the table, so that it can be put in place without
+adjustment by any workman, who only has to screw up the two screws,
+<i>h</i>, to fasten to the table the standard, E, and the piece, E', in
+which are screwed the pivots, <i>e</i> and <i>e'</i>, which support the tank,
+and this all the rest of the motor.</p>
+
+<p>As is seen more clearly in Fig. 2, the water under pressure enters by
+the pipe, <i>c</i>, to which is attached a small tube of India rubber, and
+leaves by the pipe, <i>c'</i>, and is carried away by another India rubber
+tube.</p>
+
+<p>The openings of the distribution cock are symmetrically pierced in the
+seat and plug, which latter is divided internally by a horizontal
+diaphragm so arranged that at each oscillation communication is
+established alternately above and below the piston. So that it can be
+started or stopped quickly, the opening and closing of the throttle
+valve, <i>i</i> (Fig. 2), is effected by a single pulling movement upon the
+handle, I, and this draws out the valve horizontally. For this end the
+lever is pivoted upon the extremity of the valve stem, and ends in a
+bar engaging with a fork which acts as its fulcrum. This fork is cast
+in one piece with the plug, J, which closes the opening through which
+the valve is put in place, as shown in detail in Fig. 8. To prevent
+the lever from spinning out of the fork when it is pulled or pushed,
+this lever is prevented from turning by the valve stem, provided for
+this purpose with a double rib, <i>i'</i> (Figs. 2 and 8), which engages in
+slots in one piece, <i>j</i>, secured in the interior of the plug, J.</p>
+
+<p>Lest the friction of the conical distribution valve oscillating with
+the cylinder should occasion a loss of power, care is taken to leave
+the key free in its seat, <i>b</i>, by not forcing the pivot, <i>k</i> (Figs. 1,
+3, and 5), whose position in its seat is regulated by the screw, <i>k'</i>.
+It follows that a very slight escape of water may be produced, but
+that does no harm, as it is caught in the reservoir, C, provided with
+a little pipe, K (Figs. 1 and 3), to carry it away.</p>
+
+<p>To maintain proper relations between the pressure of the water, or the
+work it is called upon to do, and the motor, the quantity of water
+introduced into the cylinder at each stroke of the piston is regulated
+by adjusting the length of stroke by the crank pin. For this end the
+course of the latter is made variable by means of the piece, <i>f</i>,
+adjusted by set-screw in the interior of the disk, F (Figs. 3 and 7),
+and tapped for the reception of a screw terminated by a milled button,
+<i>f</i>. If this button is turned, it moves the piece, <i>f</i>, and therefore
+regulates the distance of the crank pin, <i>g'</i>, to which the piston
+rod, <i>g</i>, is attached (Fig. 3) from the center of rotation.</p>
+
+<p>When the motor is arranged as shown in Figs. 1 and 2, or for the
+transmission of motion by means of a band wheel, <i>p</i>, cast in one with
+the flywheel, P, the disk which receives the crank pin of variable
+position is fixed directly upon the axle, <i>d</i>, of the same flywheel
+carried by the support, D; but when the motor can be applied directly,
+as is the case for example in the Singer sewing machine, upon the axle
+of the machine, no support is used, and the arrangement shown in Figs.
+3 and 4 is adopted. In this case the disk, F', is cast with three arms
+which serve, by means of a screw, to fasten it to the flywheel carried
+by the axle of the sewing machine.</p>
+
+<p>When the motor is used on the upper stories of buildings, the changes
+of speed incidental to drawing the water from the lower stories from
+the same pipe can be compensated by the use of an accumulator. This
+accessory apparatus is composed of a reservoir of a capacity of 10
+liters or more, intercalated in the pipe which supplies the motor, so
+that the water coming from the principal pipe enters the bottom of
+this reservoir, passing through an India rubber valve opening inward,
+the supply for the motor coming through a tube always open and placed
+above this valve. The air trapped in the accumulator is compressed by
+the water, and when the pressure in the pipe decreases, the valve
+closes and the compressed air drives the water through the motor with
+decreasing pressure until normal pressure is re-established in the
+pipes.&mdash;<i>Publication Industrielle.</i></p>
+
+<hr />
+
+<h2><a name="art13" id="art13"></a>TRIAL TRIP OF THE OHIO.</h2>
+
+<p>Some important trials of the new machinery of the screw steamer Ohio,
+belonging to the International Navigation Company, have recently taken
+place on the Clyde. The Ohio is an American built steamer measuring
+343 ft. by 43 ft. by 34 ft. 6 in., and of 3,325 tons gross. She has
+been entirely refitted with new engines and boilers by Messrs. James
+Howden &amp; Co., Glasgow, who also rearranged the bunker, machinery, and
+hold spaces, so as to give the important advantage of increased cargo
+accommodation obtainable from the use of their improved machinery,
+which occupies considerably less space than the engines and boilers of
+the same power which have been replaced. The new engines are of the
+triple expansion type, and the boilers, which are designed for
+supplying steam of 150 lb. pressure, are worked on Howden's system of
+forced draught, which combines increased power with high economy in
+fuel. The object of the owners in refitting the Ohio was to test the
+capability and economy of this system of forced draught on a
+sufficient scale to guide them in dealing with steamships of the
+largest class and great power.</p>
+
+<p>In the refit of the Ohio the boilers were designed to work with a very
+moderate air pressure, this being sufficient for the power required by
+the contract. The combined power and economy, however, guaranteed by
+Messrs. Howden &amp; Co. for the use of their system of forced draught was
+higher than has hitherto been attempted in any steamship, and
+sufficient, if attained, to prove the large reduction that could
+safely be made in the number and size of boilers for the use of the
+system, and the quantity of coal required to produce a given power.
+The contract for the refit of the steamer required that 2,100
+indicated horse power (which was the maximum power of the engines
+removed) should be maintained during the trial on a consumption of
+1.25 lb. of coal per indicated horse power per hour. Originally the
+boilers of the Ohio, from which this power was produced, were three in
+number, double ended, 12 ft. 6 in. in diameter by 17 ft. 6 in. in
+length, having each six furnaces 3 ft. in diameter, or eighteen
+furnaces in all, with an aggregate fire grate area of 300 square feet.
+The new boilers, fitted with the forced draught, are likewise three in
+number, but single ended, 13 ft. in diameter by 11 ft. 2 in. in
+length, having each three furnaces 3 ft. 3 in. in diameter, or nine
+furnaces in all, with an aggregate fire grate area of 112 square feet.
+Air for combustion is supplied to the boilers by one of Messrs. W.H.
+Allen &amp; Co.'s fans, 5 ft. 6 in. in diameter, driven direct by an
+engine having a cylinder 7 in. in diameter with stroke of 4 in. The
+boilers removed had two stoke holds across the ship, one fore and one
+aft of the boilers, while the new boilers have only one stoke hold on
+the after side. The engines removed have cylinders 57 in. and 90 in.
+in diameter by 48 in. stroke, while the new engines have three
+cylinders 31 in., 46 in., and 72 in. in diameter respectively, with
+piston stroke of 51 in.</p>
+
+<p>During the trials the coals were weighed out under the supervision of
+the officers of the company, who also took the record of speed and
+other data. After running down Channel for a considerable time, the
+trial on the coals weighed out began, and lasted 4 hours 10 minutes,
+during which time 10,885 lb. of Welsh coal were burned, the trial
+ending with the same revolutions of engines and the same pressure in
+boilers with <a name="Page_9752" id="Page_9752"></a>which it began. The mean indicated horse power,
+calculated from the mean of seven sets of indicator cards, taken
+during the trial, and the mean revolutions per minute, found by
+dividing the total revolutions recorded on the engine counter by the
+minutes in the period of the trial, amounted to 2,124, thus making the
+consumption 1.23 lb. per indicated horse power per hour, and the power
+per square foot of fire grate almost exactly 19 indicated horse power.
+While testing the indicated horse power and consumption of coal, the
+steamer ran to and fro between the Cloch and Cumbrae lights, and also
+made several runs on the measured mile at Skelmorlie, from which the
+mean speed of the vessel was found to be 14.12 knots per hour. The
+remarkably high results obtained were most satisfactory to the
+representatives of the owners, and a large party of experts on board
+congratulated Mr. Howden on the successful fulfillment of the onerous
+guarantees undertaken.&mdash;<i>Engineering.</i></p>
+
+<hr />
+
+<h2><a name="art06" id="art06"></a>THE CEARA HARBOR WORKS.</h2>
+
+<p>The works illustrated by the engravings are now being constructed
+under a concession from the imperial government of Brazil. The
+province of Ceara has an area of about 50,000 square miles, and is one
+of the richest in Brazil. Its produce comprises sugar, coffee, cocoa,
+cotton, tobacco, spices, fruit, cabinet and dye woods, India rubber,
+etc. Its population at the last census, taken in 1877, amounted to
+952,624 inhabitants, that of the capital, the city and port of Ceara,
+being about 40,000. Although Ceara is the principal seaport at which
+lines of English, French, American, Brazilian, and other steamers
+regularly call, prior to the commencement of the harbor improvements
+it was almost an open roadstead, passengers and goods having to be
+conveyed by lighters and boats between vessels and the shore. The
+official statistics of the trade and shipping of the port show that an
+income of £35,750 per annum will be collected by the Ceara harbor
+corporation from the dues which they are authorized by their
+concession to charge on all imports and exports and on the vessels
+using the port and from the rent of the bonded warehouses.</p>
+
+<div class="figcenter">
+<img src="./images/2_th.png" width="454" height="400" alt="NEW HARBOR WORKS, CEARA, BRAZIL." title="" />
+<span class="caption"><br />NEW HARBOR WORKS, CEARA, BRAZIL.</span>
+</div>
+
+<p>The drawings given here show the nature of the works, which are of a
+simple character. The depth of water along the principal quay, which
+is being constructed of solid concrete, and is connected with the
+shore by an iron and steel viaduct over 750 ft. in length&mdash;which is
+already completed&mdash;will be 19 ft. at low water and 25 ft. at high.
+This quay and breakwater is shown in perspective, in plan, and in
+section, and is of a very heavy section, as will be gathered by the
+scale given immediately below it. Meanwhile the landing of cargo is
+temporarily carried on at the end of the viaduct, which at high tide
+has a depth of about 20 ft. of water. The custom house and bonded
+warehouses are being built of the fine granite obtained at the Monguba
+quarries, which adjoin the Baturite railway, about sixteen miles from
+the port. A new incline has also been constructed from the rail way
+down to the port. The line has been laid along the viaduct, and will
+be extended over the quays as soon as they are completed. The
+concrete, of which a large quantity is being used, is mixed by Carey &amp;
+Latham's patent mixers, and the contractors have supplied the very
+large and complete plant for carrying out the operations.</p>
+
+<p>The engineer to the corporation is Mr. R.E. Wilson, M. Inst. C.E.,
+Westminster, and his resident at Ceara is Mr. R.T.H. Saunders, M.
+Inst. C.E. The contractors for the work are Messrs. Punchard,
+McTaggart &amp; Co., their representative at Ceara being Mr. George
+Wilson, M. Inst. C.E.<i>&mdash;The Engineer.</i></p>
+<hr />
+
+<h2><a name="art04" id="art04"></a>ELECTRIC STREET RAILROADS.</h2>
+
+<h3>By GEORGE W. MANSFIELD.</h3>
+
+<p>Why should we prefer electricity as the propelling agent of our street
+cars over all other known methods? I answer, without hesitation,
+because it is the best, and being the best is the cheapest. Briefly I
+will present the grounds upon which I take my stand.</p>
+
+<p>To-day the only methods for tramway service are three in number:
+Horses, with a history of fifty years and over; cables, with a history
+of fifteen years; and electricity, with a history of two years. I give
+the latter two years on the basis of the oldest electric street
+railroad in existence to-day, and that is the Baltimore railroad,
+equipped with the Daft system.</p>
+
+<p>The main points for consideration common to each are six in number:</p>
+
+
+<ul>
+<li>1st. Obtaining of franchise.</li>
+<li>2d. Construction of buildings, viz., engine house or stable.</li>
+<li>3d. Equipment&mdash;rolling stock, horses, engines and dynamos.</li>
+<li>4th. Construction of tramway.</li>
+<li>5th. Cost of operation.</li>
+<li>6th. Individual characteristics and advantages.</li>
+</ul>
+
+
+<p>Each of these requires a paper by itself, but in as concise a way as
+possible, presenting only the salient reasons and figures, I shall
+endeavor to embody it in one.</p>
+
+<p>1st. Obtaining of franchise.</p>
+
+<p>I assume the municipal officers and the promoters honest men.</p>
+
+<p>It is the universal settled conviction that a street car propelled
+with certainty and promptness by mechanical means is infinitely to be
+preferred to horses. Hence, if this guarantee can be given, there need
+be no fear from the other side of the house. Years of experience prove
+that this guarantee can be given.</p>
+
+<p>The mechanical methods are electricity and the cable. To suit local
+conditions the former has three general applications&mdash;overhead,
+underground, and accumulator systems; while the latter has but one,
+the underground. Hence, the former, electricity, has three chances to
+the latter's one to meet the whims, opinions, or decisions of
+municipal authorities. Other advantages accruing from mechanical
+methods are cleaner streets, absence of noise, quick time, no
+blockades, no stables accumulating filth and breeding pestilence, and
+lastly the great moral sympathetic feeling for man's most faithful and
+valuable servant, the horse. These all are directly in favor of
+obtaining the right franchise.</p>
+
+<p>The three general ways of obtaining the same are a definite payment of
+cash to the authorities, a guarantee of an annual payment of a certain
+per cent. of the earnings, and lastly a combination of the two. For
+the city or town the latter way is the safest, and the best, all
+things considered. As electricity is mechanical, and as it can be
+shown that it is the cheapest to construct and most economical, and
+has three chances to operate, it stands by far the most likely to
+obtain the franchise.</p>
+
+<p>2d. Construction of buildings.</p>
+
+<p>The governing factors under this head are the local land valuation and
+tax. The system necessitating a spread eagle policy on the land
+question will cost. What could be a more perfect illustration than the
+horse railroad system? The motive power of the New York Central
+Railroad between New York and Albany could be comfortably stowed in
+the barns of some of the New York City street railways. What a
+contrast! The real estate, buildings, and fixtures of the Third Ave.
+line are valued at $1,524,000, and what buildings! Cattle sheds in the
+metropolis of America. Surely they did not cost a tithe of this great
+sum. What did? The land, a whole block and more. Henry George
+advocates might find food for thought here. All this is true of the
+other lines in every city in the Union. Enormous expenditures for
+land. A good one half of their capital sunk in purchasing the
+necessary room. Go where you will, a good fifty per cent. of the
+capital is used for land for their stables. This obviously does not
+include equipment.</p>
+
+<p>How is it with mechanical systems? The land is one of the minor
+considerations, the last thing considered. Let us look at some
+figures. From careful examination of many engine plants, considering
+the ratio between a certain number of horses with their necessary
+adjuncts and a steam plant of numerically equal power, I find it
+stands as 1 to 30. That is, a steam plant complete of 30 horse power
+capacity would need only one thirtieth the floor space of thirty
+horses. With larger powers this ratio is still greater, and from one
+estimate I found that it stood as 1 to 108, i.e., for horses I should
+have to have 108 times more floor space than for an equal number of
+mechanical horse power. It must be remembered also that the mechanical
+horse power is 50 per cent. greater than the best animal horsepower.</p>
+
+<p>From one maker, taking the engine alone, I found that a rated 100
+horse power engine, guaranteed in every particular, would have ample
+room in the stall for one horse in the average stable. Another
+instance showed that I could get a steam plant complete, engine,
+boiler, etc., of 50 horse power, in a space 5 by 6 feet, which is
+smaller than the average stall. Here is shown the enormous saving in
+land purchase.</p>
+
+<p>For car room a building several stories high would answer perfectly,
+since quick-hoisting elevators could be put in and the tracks on each
+floor have wire connections with the dynamos, so that the cars could
+be run across the floor to where you please, facilitating storage and
+dispensing with handling. This would not be possible with the cable.</p>
+
+<p>Comparing electricity and cable on this point, all things favor the
+former clearly and beyond all question. Furthermore, if locality so
+favored, the subject of land purchase for electricity could be tabooed
+entirely, since distance can be so readily overcome. Way out in the
+suburbs or back in the country by the side of some waterfall, your
+station might be, while the current is sent to the great city over
+heavy conductors. Here land rent or tax would be at the minimum. With
+horses or cable plainly proximity must be had. It is estimated that
+the land occupied by the Madison Avenue line of New York City is worth
+the cost of 40 miles of ordinary double track.</p>
+
+<p>3d. Equipment at station and rolling stock.</p>
+
+<p>The rolling stock would be in each case approximately the same.
+Consisting of cars of equal seating capacity, the difference of cost
+would be the necessary attachments for the mechanical systems.</p>
+
+<ul>
+<li>A first class 16 foot horse car costs $1,200;</li>
+<li>A first class 16 foot cable car costs about $1,800; and</li>
+<li>A first class 16 foot electric car costs about $2,200.</li>
+<li>Rates: Electricity, 1; horse, 0.54; cable, 0.81.</li>
+</ul>
+
+
+<p>I believe, however, that the mechanical system is bound to work
+material changes in car construction, in fact it is almost imperative.
+In all probability a car with 15 to 20 per cent. greater seating
+capacity than the horse car can be constructed on a different plan for
+the price given for the electric car. This price, it must be noted, is
+the one for attachment of motor to the present horse car. The horse
+cars produced to-day are most carefully planned, thoroughly built, and
+admirably adapted to their service, but the inexorable law of progress
+decrees their extinction, for something better.</p>
+
+<p>Motive power. To represent clearly the costs, etc., of the three
+systems under this head, let us assume a road. Take, if you please, a
+double line 6 miles long, and operating 24 cars with speed of 6 miles
+an hour, and running 20 hours out of 24. This would call for 48 horses
+on the track and 192 horses in the stables, or a total of 240 horses;
+at $160, counting harness, etc., this would cost $38,400.</p>
+
+<p>With electricity we will proceed as follows: The weight of car with 30
+passengers and motor attachments would be about 9,000 lb. It is easily
+calculated that to propel the same at the specified rate on a level
+would take about 1.75 horse power, a total of 42 horse power. To make
+allowances for grades we can calculate that, if the entire road was
+one gradient of three per cent., each car would take about 6.4 horse
+power, or since only 12 are going up, a total of 76.8 horse power. It
+will be fair now to take the average of these two, or 59.4 horse power
+for an average road. Allowing 35 per cent. loss from engine to work
+done in actually propelling car, we would have to have 91.3 horse
+power. Allowing a good safety factor, it would be well to put in a 150
+horse power plant. This would cost complete $7,000; necessary dynamos,
+$3,500. Among these figures should be counted cost of conductor of
+sufficient size to allow of but three per cent. in energy to overcome
+its resistance. This I have calculated using a potential of 600 volts;
+and find that the total cost of six miles copper conductor is $16,000
+with above conditions. The total cost is now seen to be $26,500.</p>
+
+<p>As to cables, since the recovery of energy available for tractive
+purposes is but 35 percent., then the engine of 169 horse power
+represents what must be had. Allowing a generous factor of safety, let
+us say that a 250 is all sufficient. This would cost complete and
+erected about $12,000. The cable would cost $15.000, and gears, etc.,
+$8,000, making a total of $35,000.</p>
+
+<p>The ratio of the three systems stands: Electricity, 1; cable, 1.09;
+horse, 1.45.</p>
+
+<p>4th. Construction of tramway.</p>
+
+<p>Figures upon this point must necessarily be either averages or
+approximations. The nature of the locality socially, naturally, and we
+grieve to say it, politically, has a strong influence upon its
+construction. Estimating on single track only, a horse road would cost
+as an average $9,000 per mile. With electricity we have several
+methods we can avail ourselves of: Surface, costing about $10,000;
+overhead double conductor, $15.696; underground, $23,500.</p>
+
+<p>With cable but one method, the underground, is possible. This cost is
+variously estimated at from $30,000 to $110,000 per mile; however, the
+latter figure is excessive. A fair average would be $35,000.</p>
+
+<p>The ratio of constructions could be fairly placed as follows, putting
+electricity as 1, by taking the average <a name="Page_9753" id="Page_9753"></a>of the three methods at
+$16,732: Horse road, 0.53; cable, 2.09.</p>
+
+<p>Unquestionably a great majority of roads of the past have not been
+constructions of engineering, and of all places requiring care, skill,
+and engineering, the street roads are the places.</p>
+
+<p>5th. Cost of operation.</p>
+
+<p>A fair figure for cost of one horse for one year is $220.</p>
+
+<p>For electricity, allowing 35 per cent. loss in transmission, etc.,
+1.54 horsepower would be the work done by engine to get 1 horse power
+on the track. There are to-day plenty of steam plants producing 1
+horse power for work at from $30 to $50 per annum. Take the average,
+$40. With electricity then $65 would well represent the price of
+producing 1.54 horsepower.</p>
+
+<p>With cable these figures would hold true, but more work is required. A
+greater loss is entailed. Since but 32 per cent. is recovered, the
+figure for 1 horse power on the track would be 2.86 horse power. At
+the above rates this would be $110 per horse power per year.</p>
+
+<p>Our ratio here is: Electricity, 1; cables, 1.71; horses, 3.38.</p>
+
+<p>This is by no means the whole of the story, for just here must we
+compute the depreciation and hence repairs due to time. Let us take
+the road figured on heretofore, and make three tables.</p>
+
+<p>In the following I have under each system taken the estimated costs,
+allowed a fair per cent. for depreciation, summed up and obtained the
+ratios.</p>
+
+<p>Any figure then like interest, etc., which would not affect ratios, I
+have omitted.</p>
+
+<div class="center">
+<table border="0" cellpadding="2" cellspacing="0" summary="">
+<tr><td align="center">ELECTRICITY.</td></tr>
+<tr><td align="left">Conductors, 1 per cent.</td><td align="right">$160.00</td></tr>
+<tr><td align="left">Engine and dynamos, 5 per cent.</td><td align="right">525.00</td></tr>
+<tr><td align="left">Cars, 10 per cent.</td><td align="right">5,280.00</td></tr>
+<tr><td align="left">Roadway, 10 per cent.</td><td align="right">2,007.00</td></tr>
+<tr><td align="left">Total.</td><td align="right"><span class="over">$7,972.00</span></td></tr>
+<tr><td align="center">HORSES.</td></tr>
+<tr><td align="left">Horses and appurtenances, 20 per cent.</td><td align="right">$7,780.00</td></tr>
+<tr><td align="left">Cars, 10 per cent.</td><td align="right">2,880.00</td></tr>
+<tr><td align="left">Roadway, etc., 10 per cent.</td><td align="right">3,500.00</td></tr>
+<tr><td align="left">Total.</td><td align="right"><span class="over">$11,740.00</span></td></tr>
+<tr><td align="center">CABLES.</td></tr>
+<tr><td align="left">Cable, 50 per cent.</td><td align="right">$7,500.00</td></tr>
+<tr><td align="left">Engine and boiler, etc., 5 per cent.</td><td align="right">1,000.00</td></tr>
+<tr><td align="left">Cars, 10 per cent.</td><td align="right">4,320.00</td></tr>
+<tr><td align="left">Roadway, 10 per cent.</td><td align="right">3,500.00</td></tr>
+<tr><td align="left">Total.</td><td align="right"><span class="over">$16,320.00</span></td></tr>
+</table></div>
+
+<p>These totals put in ratio are as follows: Electricity, 1; cable, 2.04;
+and horses, 1.47.</p>
+
+<p>Placing all the ratios obtained in a table, we have the following:</p>
+
+
+
+<div class='center'>
+<table border="0" cellpadding="2" cellspacing="0" summary="">
+<tr><td align="left"></td><td align="center">Electricity.</td><td align="center">Horses.</td><td align="center">Cables.</td></tr>
+<tr><td align="left">Depreciation.</td><td align="center">1</td><td align="right">1.47</td><td align="right">2.04</td></tr>
+<tr><td align="left">Operating expenses.</td><td align="center">1</td><td align="right">3.38</td><td align="right">1.71</td></tr>
+<tr><td align="left">Construction of tramway.</td><td align="center">1</td><td align="right">0.53</td><td align="right">2.09</td></tr>
+<tr><td align="left">Motors, cars, etc.</td><td align="center">1</td><td align="right">1.63</td><td align="right">1.21</td></tr>
+<tr><td align="left">Cars.</td><td align="center">1</td><td align="right">0.54</td><td align="right">0.81</td></tr>
+<tr><td align="left">Totals.</td><td align="center"><span class="over">5</span></td><td align="right"><span class="over">7.55</span></td><td align="right"><span class="over">7.86</span></td></tr>
+<tr><td align="left">Average.</td><td align="center">1</td><td align="right">1.51</td><td align="right">1.57</td></tr>
+</table></div>
+
+<p>Now this table must stand by itself for what it represents, and no
+more. It will be noted that I have not introduced the subject of men.
+This would unquestionably show favorably for both electricity and
+cable. Again, note, please, that this table does not represent your
+profits exactly as per ratios. I have to get them operated the same
+number of cars and under the same headway. Now with either electricity
+or cable a higher rate of speed can be maintained with but a very
+small proportionate increase of cost. This means quicker time, more
+trips, and greater receipts.</p>
+
+<p>Evidently, as a financial investment, even if cost of maintenance and
+operating is greater, the cable is to be preferred to horses.</p>
+
+<p>How is it with electricity? The ratios of expenses, etc., stand for
+themselves, the law of speed is far simpler than with cable, bringing
+even greater receipts, and again in practice the saving of coal in
+proportion to work done on track day or night is immensely more
+economical than with the cable. This point will be touched upon later.</p>
+
+<p>6th. Individual characteristics and advantages.</p>
+
+<p>Under this head a few of the salient features of each system will be
+mentioned. As the possibilities and limitations of the horse railroad
+system are, however, so well known, it is needless to go over them. I
+therefore will confine myself to the electric and cable systems.</p>
+
+<p>With electricity single track lines, crooked streets, all descriptions
+of turnouts, crossings, branches, etc., are as easy to construct and
+operate as with horses. With the cable system they are either
+impossible or enormously expensive.</p>
+
+<p>With electricity the line is not a unit, so that the complete stoppage
+of the whole line is absolutely impossible. With cable it is a unit
+and it is possible.</p>
+
+<p>With electricity the life of the conductor is infinite; with cable,
+two years.</p>
+
+<p>With electricity, and the improvements now being made in traction
+wheels, etc., the heaviest grades are as easily surmounted as with the
+cable; although it is true that for grades exceptional in character,
+such as 20 per cent. grades or over, I should be willing to give the
+contract to cable.</p>
+
+<p>With electricity any speed can be attained by the individual cars.
+They are absolutely independent. Lost time can be made up, etc. With
+cable the cars are dependent upon speed of cable. Lost time cannot be
+made up except on down grades.</p>
+
+<p>With electricity work done by engine is synchronous with work done on
+the track at any time of the day or night, with the loss of 35 per
+cent. due to the conversions in each case. In other words, for every
+horse power of useful work done on track the engine does 1.54 horse
+power. This ratio is constant. It makes no difference whether 1 or 100
+horse power of work is necessary on the track, the engine has but to
+do 35 per cent. in excess.</p>
+
+<p>With cable, if 1 horse power of work is all that is required on the
+track, the engine may be doing 25 horse power to get that amount there
+through the gears and cable. With heavier loads this is somewhat
+diminished, but about the very best figure that can be put forth is
+but 35 per cent. recovery, with 65 per cent. loss&mdash;the exact converse
+of electricity under heavy loads.&mdash;<i>Street Railway Journal.</i></p>
+
+<hr />
+
+<h2><a name="art03" id="art03"></a>ELECTRICAL ALARM FOR PHARMACIES.</h2>
+
+<div class="figcenter">
+<img src="./images/3a.png" width="600" height="305" alt="Fig. 1." title="" />
+<span class="caption"><br />Fig. 1.</span>
+</div>
+
+<p>To avoid the errors which sometimes occur in a pharmacy or in a
+laboratory, where one bottle is taken for another, especially in the
+case of those containing highly poisonous or dangerous substances, a
+simple arrangement, shown in the cuts, has been proposed. The
+apparatus, in principle, is a species of electrical alarm, in circuit
+with an ordinary house telegraph line. It consists essentially, as
+shown in Fig. 1, of a battery, bell, and pedestal, provided with an
+electric contact on which the flask rests. Fig. 2 shows this contact
+or break piece. On a series of pedestals thus arranged and
+intercalated in the same circuit the flasks containing poisonous or
+dangerous substances, whose inadvertent handling might cause trouble,
+are placed. In removing one of these flasks the circuit is closed, and
+the electric bell notifies the pharmacist of the danger attendant on
+the use of the substances contained in the flask referred to, thus
+guarding against the errors due to carelessness, and quite too
+frequent, especially in pharmacies.&mdash;<i>Chronica Cientifica.</i></p>
+
+<div class="figcenter">
+<img src="./images/3b.png" width="600" height="334" alt="Fig. 2." title="" />
+<span class="caption"><br />Fig. 2.</span>
+</div>
+
+<hr />
+
+<h2><a name="art14" id="art14"></a>APPARATUS FOR DETERMINING MECHANICALLY THE REACTION PERIOD OF
+HEARING.</h2>
+
+<p>The following apparatus, constructed after the designs of Dr. Loeb,
+assistant in the Physiological Institute at Wurzburg, is for the
+purpose of measuring the reaction period of hearing, that is, the
+period which elapses between the time when a sound wave affects the
+auditory nerve and is thence transferred to the brain, then affecting
+the consciousness, and the moment when the motor nerves can be thrown
+into action by the will. It is, therefore, necessary to fix both
+instants&mdash;when the sound is produced and when the observer has, from
+its warning, received the impulse so as to press down a key. The great
+advantage of this instrument over others adapted for the same end
+consists in this, that the determination in its essentials is effected
+entirely by mechanism, and, therefore, the graphic results attained by
+it are free from all sources of error, which errors other methods
+always introduce to a greater or less extent. Thus its results are
+quite unexceptionable.</p>
+
+<div class="figcenter">
+<a href="./images/3c.png"><img src="./images/3c_th.png" width="600" height="431" alt="REACTION PERIOD OF HEARING." title="" />
+</a><span class="caption"><br />REACTION PERIOD OF HEARING.</span>
+</div>
+
+<p>The apparatus shown in the cut rests on three feet, two of them
+consisting of strong screws, so that by aid of the circular level,
+<i>l</i>, on the base plate, it can be adjusted perfectly level. On a
+little shelf attached to a square rod, seen on the left of the
+instrument, rising from the base plate, and near its top, is a
+horizontal tube, through which, by a bulb not shown in the cut, a
+blast of air can be blown. In front of the other opening of the tube
+is a horizontal fork of ebonite, whose arms carry on the side opposite
+the tube a metallic ball. Through the arms of the fork pass the wires
+of the circuit of an electric battery. These terminate in two rounded
+ends, which, when the arms approach each other, are touched by the
+metallic ball, so that the latter also closes the metallic circuit. By
+the blast of air a wooden wedge contained in the tube is driven
+between the arms of the fork, the ball falls from them, and the
+electric stream is cut off. The ball drops upon the inclined metallic
+plate, <i>p</i>, bounces off it, and is received in a little sack, S. When
+the observer hears the ball strike the plate, he presses on the key,
+<i>t</i>, and the interval between the two instants, namely, the falling of
+the ball upon the plate and the pressing of the key, <i>t</i>, is what is
+to be mechanically fixed and measured.</p>
+
+<p>The electric current, which is closed by the ball as long as it lies
+on the jaws of the fork, flows around the arms of the electro-magnet,
+<i>m</i>, which continually attracts an armature fastened to a lever arm,
+and coming over the poles of the magnet. If the circuit is broken by
+the fall of the ball, the armature at once rises upward. By this a
+spring contained in the tube, <i>g</i>, and hitherto kept compressed, is
+released, which gives a shock to the right angled &frac12;frame, <i>a a</i>,
+containing a blackened or smoked plate of glass, so that, following
+the wire, <i>b</i>, acting as a guide, the plate flies from left to right
+of the apparatus. To prevent the plate from recoiling, a catch, <i>d</i>,
+is fastened to the side bar, <i>c</i>. Furthermore, lest the friction of
+the wire, <i>b</i>, in the guiding apertures of the frame should impair its
+velocity as it moves from left to right, it is connected with a weight
+pan by a cord passing over the pulley, <i>g</i>, which is so loaded that by
+the added velocity with which it strives to fall, the retardation
+already alluded to is overcome, so that the frame moves from left to
+right with even speed.</p>
+
+<p>In front of the frame, <i>a a</i>, is the tuning fork, <i>f</i>, which as
+estimated makes 184 vibrations in a second. By the stylus, <i>y</i>, on the
+upper limb of the fork these oscillations are marked upon the sliding
+plate of glass as a wave line. Lest, after the first impulses of the
+fork have been registered, they should soon die away, in front of it
+is an electro-magnet, H, whose pole-faces near the arms of the tuning
+fork pass over them. The latter, to be more strongly affected by the
+magnet, are provided with faces of soft iron. To the lower face of the
+lower arm of the fork a small sharp stylus is fastened, which, with
+each beat of the fork, comes into contact with the mercury in the
+little cup, <i>n</i>, or a spring used instead of it. This closes an
+electric circuit, which passes around the magnet, thence going through
+the tuning fork by the binding screw, <i>k</i>, and thence by connections
+not shown in the cut back to the battery. In consequence of the
+magnetism thus excited, the arms of the tuning fork are attracted by
+the poles of the magnet, and forced to beat with increased amplitude.
+In a short time a constant amplitude of oscillation is reached, when
+the magnetic impulses are of equal influence with the atmospheric
+resistance and the internal force of the tuning fork restraining its
+movements.</p>
+
+<p>Finally, the stylus, <i>s</i>, which touches the glass plate directly above
+<i>y</i>, is for registering the moments when by the falling ball the sound
+is produced and when the observer presses the key. This is brought
+about by the rod, <i>i</i>, to which <i>s</i> is firmly screwed, being jerked
+upward a short distance at each of these instants, so that the
+horizontal lines which the stylus, <i>s</i>, marks upon the screen passing
+in front of it are broken at both places.</p>
+
+<p>The mechanism which jerks the rod, <i>i</i>, upward is thus arranged: The
+inclined plate, <i>p</i>, on which the ball drops, is carried by the upper
+horizontal arm of an angular lever turning on the axis, <i>x</i>, and
+counterpoised by the balancing weight, <i>x'</i>. By the falling ball this
+arm is pressed downward, and the lower horizontal arm, <i>w</i>, of the
+lever is also moved. On a second horizontal axis the lever, <i>v</i>,
+partly concealed, moves, restricted as to its length of swing by the
+screws, <i>n</i>. As long as the concealed arm is not moved, <i>v</i> is lightly
+pressed by the small spring, <i>e</i>, against <i>w</i>. The projection, <i>z</i>, at
+the upper end of <i>v</i> holds the rod, <i>i</i>, which the strong spring, <i>h</i>,
+is continually pressing upward. When the ball falls upon the plate,
+<i>p</i>, the arm, <i>w</i>, presses against the lower end of <i>v</i>, the
+projection, <i>z</i>, sets free the rod, and it springs upward. This
+movement is soon arrested, as the projection, <i>z'</i>, engages with a
+stud situated on the right side of the rod, <i>i</i>. This projection is
+situated on the vertical arm of an angular lever <a name="Page_9754" id="Page_9754"></a>whose other arm is
+the key, <i>t</i>. When the observer presses the key, the rod, <i>i</i>, again
+is jerked upward by the spring, <i>h</i>. The screw, <i>o</i>, tapped into the
+rod, <i>i</i>, prevents the rod going higher than necessary, by striking a
+plate, which also serves as guide for <i>i</i>.</p>
+
+<p>To determine the interval between the falling of the ball and pressing
+of the key, one has finally to count the waves inscribed by the tuning
+fork, which come under the portion of the line inscribed by <i>s</i>, which
+is bounded by the two breaks produced by the successive movements of
+the rod.</p>
+
+<p>To make the glass plate carried by the frame available for more
+observations, which plate can be used as a photographic negative, the
+frame, T, is adjustable up and down upon the pillars, N. This frame
+carries the tuning fork, mercury cup, <i>n</i>, and the electro-magnet, M.
+The spring, <i>s</i>, can also be moved up and down along the rod, i.&mdash;<i>H.
+Heele in Zeitschrift fur Instrumentenkunde.</i></p>
+
+<hr />
+
+<h2><a name="art15" id="art15"></a>A NEW DISINFECTOR.</h2>
+
+<p>The accompanying engravings represent a new disinfecting apparatus
+invented by Mr. W.E. Thursfield, M. Inst. C.E., of Victorgasse,
+Vienna. The principle on which its action is based is that the
+complete destruction of all germs in wearing apparel and bedding,
+without any material injury whatever to the latter, is only to be
+obtained by subjecting the articles infected, for a period
+proportionate to their structural resistance, to a moist heat of at
+least 212 deg. Fah. Recent experiences in Berlin have shown that, for
+security's sake, a temperature of 220 deg. is better. To insure the
+thorough penetration of this temperature in every fiber, a heat of
+from 260 deg. to 270 deg. must be maintained in the disinfecting
+chamber itself. To obtain this by means of ordinary or superheated
+steam involves the employment of boilers working under a pressure of
+2&frac12; to 3 atmospheres, of disinfecting chambers capable of resisting an
+equal tension, and of skilled labor in attending to the same; in other
+words, a large initial outlay and correspondingly heavy working
+expenses in fuel and wages.</p>
+
+<div class="figcenter">
+<a href="./images/4a.png"><img src="./images/4a_th.png" width="385" height="450" alt="Fig. I THE AERO-STEAM DISINFECTOR." title="" />
+</a><span class="caption"><br />Fig. I</span>
+</div>
+
+<div class="figcenter">
+<img src="./images/4b.png" width="600" height="405" alt="Fig. II  THE AERO-STEAM DISINFECTOR." title="" />
+<span class="caption"><br />Fig. II <br />THE AERO-STEAM DISINFECTOR.</span>
+</div>
+
+<p>The disinfecting apparatus, illustrated in a portable and stationary
+form, of the dimensions adopted by the sanitary authorities of Vienna,
+Budapest, Prague, Lemberg, Teplitz, etc., and by the Imperial and
+Royal Theresianum Institute, and sanctioned for use in barracks,
+military hospitals, etc., by the Austrian Ministry of War, and for
+ambulance hospitals by the Red Cross, acts by means of a mixture of
+steam and hot air in such proportion that the steam, after expending
+its mechanical energy in inducting the hot air into the disinfecting
+chamber, is, by contact with the clothes or bedding of a lower
+temperature, not only condensed, but by condensation completely
+neutralizes the risk of injury through any chance excess of hot air.
+The boiler being practically open is inexplosive, and requires neither
+safety valves nor skilled attendance.</p>
+
+<p>The heat generated in the furnace is utilized to the utmost, and the
+escaping vapors form a steam jacket in the double casing of the
+disinfecting chamber. The method of manipulation reduces the danger of
+contagion to a minimum, as the clothes or bedding are placed in
+specially constructed sacks in the sick chamber itself, and, after
+being tightly closed, the sacks are removed and hung in the
+disinfector. The stationary apparatus, which is constructed to
+disinfect four complete suits of clothes, including underlinen, or one
+complete set of bedding, including mattress, is specially adapted for
+hospitals, barracks, jails, etc. Its dimensions can easily be
+increased, but the size shown has proved itself, from an economical
+point of view, the best, as, where the quantity of articles to be
+disinfected varies, several apparatus can be erected at a less cost
+than one large one, and one or more be heated as the quantity of
+infected articles be small or large. In the accompanying drawing A is
+the boiler, which is filled by pouring water into the reservoir, B,
+until the same, entering the boiler at its lowest part through the
+tube, C, rises to the desired height in the water gauge, G. C acts
+also in the place of a safety valve. D is the fire space, E a movable
+grate, and F the coal hopper. The fuel consists of charcoal or coke.
+The boiler is emptied by the cock, H. I is a steam pipe connecting the
+steam space with the hot air tube, L¹. K is an auxiliary pipe to admit
+the steam into the chimney during stoppage for emptying and recharging
+the disinfecting chamber in continuous working. The admission of air
+is regulated by the handle, L, and the draught in the chimney, M, by
+the handle, N. O is the disinfecting chamber inclosed by the space, P,
+which acts at the same time as a steam jacket and as a channel for
+the downward passage of the vapors escaping from the chamber through
+the outlets, S. The lower portion of the disinfecting chamber, Q, is
+funnel-shaped for the better mixture and distribution of the steam and
+hot air, and to collect any condensation water. Q¹ is a sieve to catch
+any fallen article. The vertical tubes, S, which serve at the same
+time to strengthen the chamber, connect the lower portion of the steam
+jacket, P, with the circular channel, T, which is again connected with
+the chimney, M, by the tube, T'. The disinfection chamber is
+hermetically closed by the double cover, R, to the lower plate of
+which hooks for hanging the sacks are fastened. The cover fits in a
+sand bath, and is raised and lowered by means of the pulley chain, W,
+and the swinging crane, X. U is a thermometer indicating the
+temperature of the steam and hot air in the disinfecting chamber, V a
+cock for drawing off any condensation water, Y a battery connected
+with an electrical thermometer to be placed in the clothes or bedding,
+and Z the sacks in which the infected articles are hung.</p>
+
+<p>The portable apparatus, as shown, for heating with gas, or even
+spirits of wine, can also be heated with a similar steam and hot air
+apparatus as the stationary disinfector. In country towns or villages,
+or even in cities, whose architectural arrangements permit, the
+portable disinfector can easily be drawn by one man into the courtyard
+or garden of any house, and the process of disinfection conducted on
+the spot. Its usefulness in campaigns for ambulance hospitals is
+self-evident. The letters denoting the several parts are the same as
+in the stationary apparatus. The portable disinfector is constructed
+to disinfect two complete suits of clothes or one mattress. The
+extremely favorable results are shown in the accompanying table of
+trials.&mdash;<i>The Engineer.</i></p>
+
+
+<p class="center">TABLE OF RESULTS WITH WM. E. THURSFIELD'S STEAM AND HOT AIR DISINFECTORS.</p>
+
+<div class="center">
+<table summary="Steam and Hot Air" border="1">
+<tr><th rowspan="2" valign="middle" align="center">Series of Trials.</th>
+<th>I.</th><th>II.</th><th>III.</th><th> IV.</th><th> V.</th><th> VI.</th><th> VII.</th><th>VIII.</th>
+<th>IX.</th><th>  X.</th><th> XI.</th><th> XII.</th><th>XIII.</th><th> XIV.</th><th>XV.</th>
+</tr>
+<tr><th colspan="8" align="center">Portable Apparatus.</th>
+<th colspan="8" align="center">Stationary Apparatus.</th>
+</tr>
+<tr>
+<td class="lsmall">Contents of boiler, in <span class="emph">gallons</span></td>
+<td>3.85</td><td>4.18</td><td>&mdash;</td><td>4.18</td>
+<td>4.18</td><td>4.18</td><td>5.7</td><td>5.7</td>
+<td>10.0</td><td>10.0</td><td>10.0</td><td>10.0</td>
+<td>10.0</td><td>10.0</td><td>10.0
+</td>
+</tr>
+<tr>
+<td class="lsmall">Water added during the process</td>
+<td>&mdash;</td><td>1.54</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>1.4</td><td>0.6</td>
+<td>4.3</td><td>&mdash;</td><td>&mdash;</td><td>7.4</td>
+<td>1.4</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Temperature of water <span class="emph">degs. Fah</span>.</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>72</td>
+<td>57</td><td>54</td><td>43</td><td>132</td>
+<td>54</td><td>46</td><td>176</td><td>43</td>
+<td>43</td><td>43</td><td>104
+</td>
+</tr>
+<tr>
+<td class="lsmall">Firing commenced with spirits of wine at <span class="emph">hours min.</span></td>
+<td>&mdash;</td><td>2.12</td><td>9.10</td><td>4.30</td>
+<td>&mdash;</td><td>10.0</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Firing commenced with gas at <span class="emph">hours min.</span></td>
+<td>1.30</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>3.0</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Firing commenced with coke at <span class="emph">hours min.</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>1.10</td><td>&mdash;</td><td>8.15</td><td>1.13</td>
+<td>1.43</td><td>2.54</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Firing commenced with charcoal at <span class="emph">hours min.</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>10.12</td><td>&mdash;</td>
+<td>2.15</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>8.43</td><td>10.16
+</td>
+</tr>
+<tr>
+<td class="lsmall">Steam generated at <span class="emph">hours min.</span></td>
+<td>&mdash;  </td><td>2.34</td><td>9.28</td>
+<td>4.41</td><td>3.15</td><td>10.18</td><td>10.35</td>
+<td>1.34</td><td>2.38</td><td>8.53</td><td>1.20</td>
+<td>2.3</td><td>3.19</td><td>9.3</td><td>10.23
+</td>
+</tr>
+<tr>
+<td class="lsmall">212 deg. in chamber registered by external thermometer at <span class="emph">hours min</span>.</td>
+<td>2.30</td><td>2.40</td><td>9.34</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;  </td><td>10.50</td><td>1.52</td>
+<td>2.45</td><td>9.3</td><td>1.28</td><td>2.18</td>
+<td>3.37</td><td>9.12</td><td>10.31
+</td>
+</tr>
+<tr>
+<td class="lsmall">212 deg. in clothes registered by electrical thermometer at <span class="emph">hours min.</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>5.25</td><td>4.18</td><td>12.12</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>1.55</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">221 deg. in clothes registered by electrical thermometer at <span class="emph">hours min.</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>11.51</td>
+<td>2.34</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>3.50</td><td>4.26</td><td>10.4</td><td>12.03
+</td>
+</tr>
+<tr>
+<td class="lsmall">Highest temperature in chamber registered by external thermometer <span class="emph">deg.</span></td>
+<td>&mdash;</td><td>270 </td><td>250</td><td>&mdash;</td>
+<td>324</td><td>255</td><td>302</td><td>275</td>
+<td>293</td><td>320</td><td>284</td><td>284</td>
+<td>302</td><td>284</td><td>275
+</td>
+</tr>
+<tr>
+<td class="lsmall">Mean temperature in chamber registered by external thermometer <span class="emph">deg.</span></td>
+<td>241 </td><td>257</td><td>239</td>
+<td>266</td><td>&mdash;</td><td>253</td><td>266</td>
+<td>266</td><td>284</td><td>284</td><td>266</td>
+<td>266</td><td>284</td><td>266</td><td>266
+</td>
+</tr>
+<tr>
+<td class="lsmall">Trial closed at <span class="emph">hours, min.</span></td>
+<td>4.45</td><td>4.10</td><td>11.4</td>
+<td>5.45</td><td>4.30</td><td>12.30</td><td>11.51</td>
+<td>2.35</td><td>4.30</td><td>11.0</td><td>2.10</td>
+<td>3.50</td><td>4.35</td><td>10.10</td><td>12.03
+</td>
+</tr>
+<tr>
+<td class="lsmall">Max. therm. registered in mattress <span class="emph">deg.</span></td>
+<td>262</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Max. therm. registered in overcoat <span class="emph">deg.</span></td>
+<td>&mdash;</td><td>239</td><td>226</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>223</td><td>223</td>
+<td>253</td><td>244</td><td>226</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>223
+</td>
+</tr>
+<tr>
+<td class="lsmall">Max. therm. registered in winter coat <span class="emph">deg.</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>232</td>
+<td>223</td><td>214</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>230</td>
+<td>232</td><td>223</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Max. therm. regis'd in winter trousers <span class="emph">deg.</span></td>
+<td>&mdash;  </td><td>243</td><td>239</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>262</td><td>&mdash;</td><td>253</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Max. therm. regis'd in summer trousers <span class="emph">deg.</span></td>
+<td>&mdash;  </td><td>246</td><td>252</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>280</td><td>&mdash;</td><td>264</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Time required to generate steam <span class="emph">min.</span></td>
+<td>&mdash;</td><td>22</td><td>18</td>
+<td>11</td><td>15</td><td>18</td><td>23</td>
+<td>24</td><td>23</td><td>38</td><td>7</td>
+<td>20</td><td>25</td><td>20</td><td>7
+</td>
+</tr>
+<tr>
+<td class="lsmall">Time required to generate 212 deg. in chamber <span class="emph">min.</span></td>
+<td>60</td><td>28</td><td>24</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>38</td>
+<td>42</td><td>30</td><td>48</td><td>15</td>
+<td>35</td><td>43</td><td>29</td><td>15
+</td>
+</tr>
+<tr>
+<td class="lsmall">Time required to generate 212 deg. in clothes  <span class="emph">min.</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>55</td>
+<td>78</td><td>132</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>42</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Time required to generate 221 deg. in clothes  <span class="emph">min.</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>99</td><td>85</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>127</td>
+<td>92</td><td>81</td><td>107
+</td>
+</tr>
+<tr>
+<td class="lsmall">Total duration of process <span class="emph">min.</span></td>
+<td>135 </td><td>118</td><td>114</td>
+<td>75</td><td>90</td><td>150</td><td>99</td>
+<td>85</td><td>135</td><td>105</td><td>57</td>
+<td>127</td><td>101</td><td>87</td><td>107
+</td>
+</tr>
+<tr>
+<td class="lsmall">Water evaporated, in <span class="emph">gallons</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>1.65</td><td>1.90</td><td>2.75</td><td>4.3</td>
+<td>3.3</td><td>6.93</td><td>&mdash;</td><td>&mdash;</td>
+<td>9.24</td><td>&mdash;</td><td>3.63</td><td>4.84
+</td>
+</tr>
+<tr>
+<td class="lsmall">Consumption of spirits of wine <span class="emph">pints</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>3.0</td><td>&mdash;</td><td>9.6</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Consumption of gas, in <span class="emph">cubic feet</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>70</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Consumption of cokes, in <span class="emph">cbs</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>6</td><td>&mdash;</td><td>&mdash;</td><td>8.8</td>
+<td>16.5</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;
+</td>
+</tr>
+<tr>
+<td class="lsmall">Consumption of charcoal, in <span class="emph">cbs</span></td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>8.8</td>
+<td>&mdash;</td><td>&mdash;</td><td>&mdash;</td><td>&mdash;</td>
+<td>&mdash;</td><td>&mdash;</td><td>14.3</td><td>13.8
+</td>
+</tr>
+</table>
+</div>
+
+<div class="note">
+<p>N.B.&mdash;In every case, even in the trials V. and X., in which the
+temperature in the disinfecting chamber rose above 320 deg. Fah., the
+clothes, owing to the complete saturation of the hot air with live
+steam, remained absolutely unimpaired.</p>
+
+<p>The column &quot;water evaporated&quot; shows the quantity of live steam passing
+through the disinfecting chamber averages 13 cubic feet per minute
+with gas or spirits, and 22 cubic feet with charcoal or coke in the
+portable and 33 cubic feet in the stationary apparatus. Trials VI.,
+VII., and VIII. took place in open air.</p>
+
+<p>According to trial XII., from 28 to 30 complete suits of clothes can
+be disinfected at an expenditure of about 75 cbs. of coke per diem.</p>
+</div>
+
+<hr />
+
+<h2><a name="art09" id="art09"></a>DRAWING INSTRUMENT FOR ACCURATE WORK.</h2>
+
+<h3>By <span class="smcap">J. Lehrke.</span></h3>
+
+<p>This arrangement consists in a cylindrical metal or horn mounted lens
+two to four centimeters long, and magnifying two or three times, and
+two or three centimeters in diameter, whose side is provided with a
+contrivance for holding after it has been pushed into place a copying
+needle, a protractor, etc.</p>
+
+<p>While hitherto the architect in using millimeter paper must hold
+separately in his hands a magnifying glass and needle, while the
+engraver holds the engraving tool inclined in one hand and the
+magnifying glass in the other, or must work under a large lens
+standing on three feet, it is now possible by a firm connection
+between the lens and needle or other instrument to draw directly with
+one hand and under the lens. In the accompanying cut one of these
+lenses is shown in section, A, in which the glass is set obliquely, in
+whose focus the needle, <i>a</i>, is held and the field of view is
+enlarged. A longer description is unnecessary, as the illustration
+gives the best explanation. It need only be remarked that the stud,
+<i>s</i>, projecting a little near the glass, is for the purpose of
+preventing the instrument from leaving the position coinciding with
+the plane of the drawing. For architects and engineers is provided a
+small compass, <i>b</i>, of about 2 cm. diameter, for laying off parallel
+widths, for making smaller scales and the like. In these cases it is
+substituted for the needle. In like manner for calculating cross
+profiles by graphical methods, for reading parallel divisions, for
+estimating areas, or revising maps, a finely divided prismatic ivory
+rule, <i>c</i>, can be placed under the glass, B, and will do good service.
+In this case the plane of the lens must be perpendicular to the axis
+of the tube.</p>
+
+<div class="figcenter">
+<img src="./images/4c.png" width="600" height="359" alt="IMPROVED DRAWING INSTRUMENT." title="" />
+<span class="caption"><br />IMPROVED DRAWING INSTRUMENT.</span>
+</div>
+
+<p>For draughtsmen a parallel drawing pen, something like <i>b</i>, is used,
+which gives several lines at once, perfectly parallel and close
+together; or a drawing pen with which the smallest signatures, such as
+boundary stones and figures, can be made neatly and exactly, which is
+secured like the needle, <i>a</i>, and for which the cylinder serves also
+as pen holder, offers a great advance.</p>
+
+<p>Thus a whole series of instruments can be used with the lens. For
+instance, a naturalist can use with it a knife or other instrument. To
+avoid injury from the instruments, one should, in laying down the
+cylinder, place it on its side. It is also recommended that on the
+outer tube of the frame, which is appropriately lacquered of black
+color, white arrows should be placed in the direction of the points of
+the instrument, so that the eyes shall be protected from injury in
+handling the instrument, as by the points being stuck into the pupil,
+owing to lifting the instrument in an inverted position.&mdash;<i>Zeitschrift
+fur Instrumentenkunde.</i></p>
+
+<hr />
+
+<h2><a name="art19" id="art19"></a>BARLOW'S MACHINE FOR MOULDING CANDLES.</h2>
+
+<p>That style of machine for moulding candles in which the candles are
+forced out at the top by means of a piston is the one most employed,
+and it is an apparatus of this kind that we illustrate herewith. In
+its construction, this apparatus presents some important improvements
+in detail which it is of interest to set forth. The improvements made
+by the Messrs. Barlow have been studied with a view of manufacturing
+candles with conical ends, adapted to all chandeliers, without
+interfering with rapidity of production or increasing the net cost.</p>
+
+<p>These gentlemen have likewise so simplified the continuous system of
+drawing the wick along as to prevent any loss of cotton. In the next
+place, the structure of the moulds, properly so called, is new.
+Instead of being cast, as is usually the case, they are rolled and
+drawn out, thus giving them smooth surfaces and permitting of their
+being soldered, are assembled by means of threaded bronze sockets. The
+engravings between Figs. 3 and 4 show these two modes of fixation. At
+<i>a</i> may be seen the old method of junction by soldering, and at <i>b</i>
+the screwing of the moulds into the socket. This machine consists of a
+box which is alternately heated and cooled, and which is fixed upon a
+<a name="Page_9755" id="Page_9755"></a>frame, A, at the lower part of which are located the wick bobbins, E.
+Toward the top of the machine there is a mechanism for actuating the
+two pairs of jaws, B, which grasp the candles forced upward by the
+play of the pistons, D. This mechanism, which is controlled by a
+lever, acts by means of an eccentric.</p>
+
+<div class="wider" style="width: 800px">
+<div class="figleft" style="width: 368px;">
+<a href="./images/5b.png"><img src="./images/5b_th.png" width="368" height="400" alt="Fig. 1" title="" />
+</a><span class="caption">Fig. 1</span>
+</div>
+
+<div class="figright" style="width: 363px;">
+<a href="./images/5c.png"><img src="./images/5c_th.png" width="363" height="400" alt="Fig. 2. BARLOW&#39;S CANDLE MOULDING MACHINE." title="" />
+</a><span class="caption">Fig. 2.</span>
+</div>
+<p class="center">BARLOW&#39;S CANDLE MOULDING MACHINE.</p>
+</div>
+
+<p>The pistons, D, are hollow, and are provided above with pieces which
+form the small end of the candles. Instead of using tin, as is usually
+done, the Messrs. Barlow employ galvanized iron in the construction of
+these pistons, and mount them through screw rings&mdash;no soldering being
+used. For this reason, any workman whatever can quickly replace one of
+the tubes. All the pistons are placed upon a horizontal table, which
+is made to rise and descend at will, in order to regulate the length
+of the candles and remove them from the mould. A winch transmits the
+motion which is communicated to it to two pairs of pinions that gear
+with racks fixed to the frame to lift the table that supports the
+pistons. How these latter are mounted may be seen from an inspection
+of Figs. 3 to 5. This new arrangement of spiral springs for the
+purpose is designed to hold the pistons on the table firmly, and at
+the same time to prevent the shock that their upper ends might undergo
+in case of an abrupt turn of the winch. Moreover, the forged iron
+plate, H, is not exposed to breakage as it is in other machines, where
+it is of cast iron. The bobbins already mentioned revolve upon strong
+iron rods, and the moving forward of the wick in the moulds is
+effected automatically by the very fact of the manufactured candles'
+being forced out. These latter are held in position through the double
+play of the jaws, B, while the stearic acid is flowing into the upper
+part of the moulds. The cotton wick is thus drawn along and kept in
+the axis of the candles.</p>
+
+<div class="figcenter">
+<a href="./images/5a.png"><img src="./images/5a_th.png" width="574" height="450" alt="Figs. 1 and 2. BARLOW&#39;S CANDLE MOULDING MACHINE." title="" />
+</a><span class="caption"><br />Figs. 3, 4, and 5.<br /> BARLOW&#39;S CANDLE MOULDING MACHINE.</span>
+</div>
+
+<p>One peculiarity of the machine consists in the waste system applied to
+the mould box. Steam or hot or cold water is sent into the latter
+through the conduit, L, starting from a junction between pipes
+provided with cocks. When the water contained in the box is in excess,
+it flows out through the waste pipes, G, which terminate in a single
+conduit. Owing to the branchings at T, and to the cocks of the
+conduits that converge at L, it is very easy to vary the temperature
+of the box at will. The warm or cold water or steam may be admitted or
+shut off simultaneously.</p>
+
+<p>When first beginning operations, the wick is introduced into each
+mould by hand. The piston table is raised by means of the winch, and
+is held in this position through the engaging of a click with a
+ratchet on the windlass. A fine iron rod long enough to reach beneath
+the pistons and catch the end of the wick is next introduced. After
+this is removed, the wick is fixed once for all, and in any way
+whatever, to the top of the mould. This operation having been
+accomplished, the piston table is lowered, and the machine is ready to
+receive the stearic acid. The moulds are of tin and are open at both
+ends. In order to facilitate the removal of the candles, they are made
+slightly conical. When the candles have hardened, the ends are
+equalized with a wooden or tin spatula, and then the piston table is
+raised. At this instant, the jaws, B, are closed so as to hold the
+candles in place. The latter, in rising, pull into the mould a new
+length of wick, well centered. A slight downward tension is exerted
+upon the wick by hand, then a new operation is begun. During this
+time, the candles held between the jaws having become hard, their
+wicks are now cut by means of the levers, C, and they are removed from
+the machine and submitted to a finishing process.&mdash;<i>Revue
+Industrielle.</i></p>
+
+<hr />
+
+<h2><a name="art17" id="art17"></a>A NEW ALKALI PROCESS.</h2>
+
+<p>In several former notes and articles in these pages, we have spoken of
+the severe crisis through which the old established, or &quot;Leblanc,&quot;
+process has now for some years been passing. It is, in fact, pushed
+well nigh out of the running by the newer process, known as the
+&quot;ammonia-soda&quot; process, and would have had to give up the battle
+before now were it not for the fact that one of its by-products,
+bleaching powder, cannot, so far, be produced at all by the
+ammonia-soda works. The bleaching powder trade has thus remained in
+the hands of the workers of the Leblanc process, and its sale has
+enabled them to cover much of the loss which they are suffering on the
+manufacture of soda ash and caustic soda.</p>
+
+<p>In brief outline, the old Leblanc process consists in the following
+operations: Salt is decomposed and boiled down with sulphuric acid.
+Sulphate of sodium is formed, and a large amount of hydrochloric acid
+is given off. This is condensed, and is utilized in the manufacture of
+the bleaching powder mentioned above. The sulphate of sodium, known as
+&quot;salt cake,&quot; is mixed with certain proportions of small coal and
+limestone, and subjected to a further treatment in a furnace, by which
+a set of reactions take place, causing the conversion of the sulphate
+of sodium of the &quot;salt cake&quot; into carbonate of sodium, a quantity of
+sulphide of calcium being produced at the same time. The mass
+resulting from this process is known as &quot;black ash.&quot; It is extracted
+with water, which dissolves out the carbonate of sodium, which is sold
+as such or worked into &quot;caustic&quot; soda, as may be required. The
+insoluble residue is the &quot;alkali waste,&quot; which forms the vast piles,
+so hideous to look at and so dreadful to smell, which surround our
+large alkali works.</p>
+
+<p>The sulphuric acid required for the conversion of the salt into &quot;salt
+cake&quot; is made by the alkali manufacturer himself, this manufacture
+necessitating a large plant of &quot;lead chambers&quot; and accessories, and
+keeping up an immense trade in pyrites from Spain and Portugal. The
+development of the alkali trade in this country has been something
+colossal, and the interests involved in it and connected with it are
+so great that anything affecting it may safely be said to be of truly
+national importance, quite apart from what technical interest it may
+possess.</p>
+
+<p>The &quot;ammonia-soda&quot; process, which has played such havoc with the old
+style of manufacture, proceeds on totally different lines. Briefly
+stated, it depends on the fact that if a solution of salt in water is
+mixed with bicarbonate of ammonium, under proper conditions, a
+reaction takes place by which the salt, or chloride of sodium, is
+converted at once into bicarbonate of sodium, the bicarbonate of
+ammonium being at the same time converted into chloride of ammonium.</p>
+
+<p>The bicarbonate of sodium settles out at once as insoluble crystals,
+easily removed, marketable at once as such, or easily converted into
+simple carbonate of sodium, and further into caustic soda, as in the
+ordinary &quot;old&quot; process. The residual chloride of ammonium is
+decomposed by distillation with lime, giving ammonia for reconversion
+into bicarbonate of ammonium, and chloride of calcium, which is a
+waste product.</p>
+
+<p>The maker of &quot;ammonia&quot; soda works direct on the brine, as pumped from
+the salt fields. His plant is simpler and less costly, and he arrives
+at his first marketable product much more rapidly and with very much
+lower working costs than the maker of Leblanc soda, in spite of all
+the great mechanical improvements which have of late years been
+introduced into the old process, and which have cheapened its work.</p>
+
+<p>The original patents on the use of ammonium bicarbonate have, we
+understand, long since expired. But the working details of the process
+and much of the most successful apparatus have undergone great
+development and improvement during late years, all the important
+points being covered by patents still in force, and mainly, if not
+wholly, in the hands of the one large firm which is now carrying on
+the manufacture in this country, and is controlling the market.</p>
+
+<p>The one weak spot of the ammonia-soda process, as we mentioned before,
+is its inability to supply hydrochloric acid or chlorine, and so allow
+of making bleaching powder. Time after time it has been announced
+positively that the problem was solved, that the ammonia-soda <a name="Page_9756" id="Page_9756"></a>makers
+had devised a method of producing hydrochloric acid or chlorine, or
+both, without the use of sulphuric acid. But the announcements have so
+far proved baseless, and at present the Leblanc makers are getting
+incredulous, and do not much excite themselves over new statements of
+the kind, though they know that if once their rivals had this weapon
+in their hands the battle would be over and the Leblanc process doomed
+to rapid extinction.</p>
+
+<p>Such is at present the state of the struggle in this great industry,
+and the above outline sketch of the two processes is designed to give
+some idea of the conditions to such of our readers as may not have any
+special knowledge of these manufactures.</p>
+
+<p>At the present moment great interest is being taken in a new process,
+about to be put to work on a large scale, which is designed to take up
+the cudgels against the ammonia process and enable the Leblanc makers
+to continue the fight on something more like equal terms.</p>
+
+<p>We allude to the process proposed and patented by Messrs. Parnell &amp;
+Simpson, and about to be worked by the &quot;Lancashire Alkali and Sulphur
+Company,&quot; at Widnes. We recently had the opportunity of inspecting
+fully the plant erected, and of having the method of procedure
+explained to us. We look upon the new process as such a spirited
+attempt to turn the tide of a long and losing battle, and as so very
+interesting on its own merits, that an account of it in these pages
+will be thoroughly in place.</p>
+
+<p>The main idea of the process is to combine the &quot;Leblanc&quot; and the
+&quot;ammonia-soda&quot; manufacture. But in place of using caustic lime to
+decompose the ammonium chloride and get back the ammonia, the &quot;alkali
+waste&quot; spoken of above is employed, it being found that not only is
+the ammonia driven off, but that also the sulphur in the &quot;waste&quot; is
+obtained in a form allowing of its easy utilization, it and the
+ammonia combining to form ammonium sulphide, which passes over in
+gaseous form from the decomposing apparatus. This ammonium sulphide
+is, as we shall see, quite as available for the working of the
+ammonia-soda manufacture as pure and simple ammonia, and all the
+sulphur can be obtained from it.</p>
+
+<p>In outline the process is as follows: We will suppose that a quantity
+of bicarbonate of sodium has been just precipitated from a brine
+solution, and we have the residual ammonium chloride to deal with.
+This is decomposed by &quot;alkali waste,&quot; giving a final liquor of calcium
+chloride, which is run to waste, and a quantity of ammonium sulphide
+gas. This latter is led at once into a solution of salt in water, till
+saturation takes place. Into this liquor of brine and ammonium
+sulphide <i>pure</i> carbonic acid gas is now passed. The ammonium sulphide
+is decomposed, pure sulphureted hydrogen gas is given off, which is
+conducted to a gas holder and stored, while ammonium bicarbonate is
+formed in the liquor, which brings about the conversion of the salt
+into bicarbonate of sodium, ready for removal and preparation for the
+market.</p>
+
+<p>It will be observed that we printed the word <i>pure</i> in italics in
+speaking of the carbonic acid used. This is one of the great points in
+the process, as in order that the sulphureted hydrogen gas obtained
+shall be concentrated and pure, only pure carbonic acid can be used in
+liberating it. The apparatus employed in its preparation is perhaps
+the most ingenious part of the works, and well worthy of attention by
+others besides alkali makers. The method is based on the fact that if
+dilute impure carbonic acid is passed into a solution of carbonate of
+sodium, the carbonic acid is absorbed, bicarbonate of sodium being
+formed, and the diluting gases passing away.</p>
+
+<p>The bicarbonate of sodium on heating gives up the extra carbonic acid,
+which can be collected and stored pure, while the liquor passes back
+to simple carbonate of sodium, to be used over again as an absorbent.
+This is not at all new in theory, of course, nor is this the first
+proposal to use it commercially; but it is claimed that this is the
+first successful working of it on a large scale.</p>
+
+<p>The gases from a large limekiln supply the dilute carbonic acid gas,
+which contains 25 per cent. to 30 per cent. of pure gas, the principal
+diluting gas being, of course, nitrogen. This kiln gas is drawn from
+the kiln by a blowing engine, and is first cooled in two large
+receivers. It is then forced into the solution of sodium carbonate in
+the absorption tower, 65 ft. high by 6 ft. diameter, filled with the
+liquor. The tower has many diaphragms and perforated &quot;mushrooms,&quot; to
+cause a proper dispersion of the gases as they ascend through the
+liquor. The strength of liquor found best adapted for the work is
+equal to a density of about 30° Twaddell. After saturation the mud of
+bicarbonate of sodium is drawn off and passed into the &quot;decomposer,&quot; a
+tower 35 ft. high by 6 ft. 6 in. in diameter, with perforated shelves,
+into which steam is blown from below, the liquor passing downward. The
+bicarbonate is decomposed, pure carbonic acid being given off. This is
+passed through a scrubber and into a gas holder ready for use. The
+liquor, which has now returned to the state of simple carbonate of
+sodium, only requires cooling to be ready to absorb a fresh lot of
+carbonic acid gas. The cooling is effected in a tower packed loosely
+with bricks, the hot liquor trickling down against a powerful current
+of air blown in from below. Liquor has been cooled in this way, in
+once passing through the tower, from 220° Fahr. to 58° Fahr., but of
+course the exact cooling obtained depends more or less on the
+temperature of the atmosphere.</p>
+
+<p>The next stage of the process, if we follow on after the preparation
+of the pure carbonic acid, is the employment of the gas for the
+decomposition of the ammonium sulphide absorbed in a brine liquor as
+above explained. The brine and ammonium sulphide are contained in what
+is known as a &quot;Solvay tower,&quot; provided with proper means for
+dispersion and absorption of the carbonic acid gas. The precipitated
+bicarbonate of sodium is removed and washed, and prepared for the
+market in whatever form is required, the sulphureted hydrogen gas
+being led to a holder and stored, as before stated.</p>
+
+<p>The decomposition of the ammonium chloride by means of &quot;alkali waste&quot;
+is carried out in a specially designed still. This is a tower 45 ft.
+high by 8 ft. diameter, divided by horizontal plates into compartments
+of about 3 ft. 8 in. in height. These compartments communicate with
+one another by means of pockets, or recesses, in the shell of the
+tower. A vertical shaft, with arms, revolves in the tower. The &quot;waste&quot;
+is fed in at the top by means of hopper and screw feed. The liquor is
+heated by steam blown in to over 212° Fahr. The ammonium sulphide is
+led direct into an absorbing vessel full of brine.</p>
+
+<p>It now only remains to see how it is proposed to deal with the
+sulphureted hydrogen gas which represents the sulphur recovered from
+the waste. It can be burnt direct to sulphurous acid and utilized for
+the production of vitriol perfectly pure and free from arsenic,
+commanding a special price. But Messrs. Parnell &amp; Simpson state that
+by a method of restricted combustion they are able to obtain nearly
+all the sulphur as such, and put it on the market on equal terms with
+the best Sicilian sulphur. We did not gather that this has yet been
+done on the working scale, however.</p>
+
+<p>It will be seen that it is proposed that a Leblanc alkali maker shall
+continue to produce a portion of his make by the old process, but
+shall erect plant to enable him to make another portion by the Parnell
+&amp; Simpson method, using his Leblanc &quot;waste&quot; in place of the caustic
+lime now employed by the ammonia soda people. He is thus to have the
+benefit of the cheaper process for, say, half his make, while he
+further cheapens the ammonia method by saving the cost of lime and by
+recovering the sulphur otherwise lost in his waste.</p>
+
+<p>The saving in lime is stated to be one ton for each ton of sodium
+carbonate produced, or in cash value about 10s. per ton at Widnes,
+while the sulphur saved is estimated to be 6 cwt. per ton of sodium
+carbonate. We reproduce these figures with all reserve, not being
+ourselves sufficiently specialists to judge of them. But we were
+assured that they represent the minimum expected, and reasons were
+given to us to show that they would probably be exceeded.</p>
+
+<p>Another gain for the Leblanc maker would be that he will escape the
+cost of removal and disposal of a portion of his refuse or waste.</p>
+
+<p>The plant now erected was calculated for a yield of one hundred tons
+carbonate of sodium and about thirty-five tons of sulphur per week,
+but it now appears likely that this will be exceeded; while the
+carbonic acid plant was supposed to be equal to a yield of 6 tons of
+pure gas per day, and is now found capable of doing twice as much.</p>
+
+<p>A few weeks will now bring this new combination process into the
+active and crucial test of the markets. Chemists and chemical
+engineers have all along taken a keen interest in the ingenious ideas
+of Parnell &amp; Simpson. Commercial men are no less interested in the
+financial result of the experiment about to be tried at the expense of
+a few gentlemen of Liverpool and district. So far as we can learn,
+opinions are to some extent divided, though many good judges are very
+hopefully inclined. For our own part, speaking with diffidence, as
+being a little off our regular track of work, we will only say that we
+were favorably impressed with what we saw and heard; and we certainly
+wish the venture that full success which its cleverness and its pluck,
+as well as its great importance at this crisis, deserve for
+it.&mdash;<i>Engineering</i>.</p>
+
+<hr />
+
+<h2><a name="art20" id="art20"></a>TEMPERATURE OF GAS DISTILLATION.</h2>
+
+<p>An important subject for investigation, which has not yet been
+satisfactorily determined, is the temperature at which it is most
+beneficial to distill coals of various qualities. The practice of
+allowing the charge to remain in the retort for some time after most
+of the gas has been driven off, to enable (it is said) the retort to
+recover heat for the next charge, often leads to misconception as to
+the true temperature of carbonization. The effect of this is to
+equalize the temperatures inside and outside the retort. This inside
+temperature is not maintained, the temperature outside not being high
+enough to transmit the heat with sufficient rapidity; and so, in an
+apparently hot retort, the coal may be carbonized at a comparatively
+low temperature. A truer test of temperature is that of the outside of
+the retort, which should be not less than 400° to 500° Fahr. above the
+temperature necessary for proper carbonization. In all experiments
+relating to temperature pretending to any degree of accuracy, a
+pyrometer of some kind should be used. Judging of the temperature by
+the color is often misleading. Not only may the eye be deceived, but
+different clays do not present the same appearance at the same
+temperature. A good, reliable pyrometer to estimate temperatures to
+(say) 2500° Fahr. is much wanted.</p>
+
+<p>Experience during the last few years with the high temperatures
+obtained by the use of regenerative furnaces has led me to the
+conclusion that higher heats than are usual may be employed with
+advantage, as regards both the quantity and the quality of gas,
+provided the retorts are heated uniformly throughout their length, and
+the weight and duration of the charge are so adjusted that the coal
+does not remain longer in the retort than is just sufficient to drive
+off the gas; and that the more rapidly the coal is carbonized, the
+better are the results. In two retorts of the same size, one making
+5,000 and the other 10,000 cubic feet per day, the gas will be twice
+as long in contact with the surface of the retort in the former as in
+the latter&mdash;to the probable detriment of its quality, and increased
+tendency to stoppage in the ascension pipes.</p>
+
+<p>A subject closely allied to that just alluded to is the temperature of
+the gas as it leaves the retort. Until within the last few years, it
+was generally assumed that this was not higher than from 200° to 300°
+Fahr.; and a very plausible theory was given to account for such a
+comparatively low temperature. A discussion which took place a few
+years ago in the <i>Journal of Gas Lighting</i> showed that at that time
+opinions on this subject were not unanimous. But the conclusion
+arrived at seemed to be that the gas was not higher in temperature
+than that before stated; and if higher temperatures were observed,
+they were due to the tarry matter in the gas, and were not those of
+the gas itself. A little reflection is sufficient to show that the
+existence of gas intimately mixed with tarry matter at a high
+temperature, without being itself raised to that temperature, is a
+physical impossibility.</p>
+
+<p>In a paper read to a Continental gas association about a year ago, the
+writer stated, as the result of many experiments, that unless the
+temperature in the ascension pipe rises above 480° Fahr., thickening
+of the tar in the hydraulic main and choking of the ascension pipe
+will certainly occur. This led me to make a series of experiments,
+extending over many months, on the temperature of the gas in the
+ascension pipes at different points and at various times during the
+charge. The results of these experiments may be of some interest, and
+may lead to further investigation. The temperatures were taken by
+mercurial thermometers registering 600° Fahr., except those near the
+mouthpiece, which were taken by a Siemens water pyrometer. Every care
+was exercised to insure accuracy; and the instruments were carefully
+adjusted. At a distance of 18 inches from the mouthpiece, the
+temperatures varied from an average of 890°, shortly after the retort
+was charged, to 518° at the end of the charge; at 12 feet distant from
+the mouthpiece, the corresponding temperature was 444°, falling to
+167° at the end of the charge; and at 22 feet, the average temperature
+varied from 246° at the commencement to 144° at the end of the charge.
+These are the averages of a number of experiments. In some instances
+they were considerably above these averages&mdash;temperatures over 900°
+being frequently obtained. This is about the temperature of a low red
+heat, and is much higher than any I have seen recorded. When the gas
+was allowed to issue from a hole in the ascension pipe, 1&frac14; inches in
+diameter, 18 inches above the mouthpiece, a strip of lead held about
+an inch from the orifice was freely melted.</p>
+
+<p>In the settings on which these experiments were made, the middle
+ascension pipe takes the gas from the two central retorts; and it is
+of interest to note that in this pipe the temperature of the gas 18
+inches from the upper retort was found to be 1014° Fahr., and at the
+point where it entered the hydraulic main it was 440° Fahr. Zinc was
+freely melted by the gas issuing from a hole 18 inches from the
+mouthpiece. The temperatures always fall toward the end of the charge;
+the fall of temperature in the ascension pipe being a good indication
+that the charge is worked off. They increase with the heat of the
+retort and with the weight of the charge.</p>
+
+<p>Experiments were also made to ascertain the temperature of the gas in
+the retort; and for this purpose one of Murrie's pyrometers was used,
+the action of which depends on the pressure produced by the
+vaporization of mercury in a malleable iron tube. The end of this tube
+was first rested on the top of the coal, but not in contact with the
+retort. It reached about 18 inches into the retort, and therefore was
+not in the hottest part. In this position the temperature indicated
+shortly after charging the retort was 1110° Fahr., gradually rising to
+1640° Fahr. The end of the tube was then embedded in the coal, when
+the pyrometer indicated a temperature of 1260° Fahr. within 30 minutes
+after the retort was charged; gradually rising toward the end of the
+charge as before. At the time these temperatures were taken, the
+retorts were each producing 10,000 cubic feet of gas per day. I had no
+opportunity of testing the accuracy of the statement that, with lower
+temperatures, there is a tendency to stoppage of the ascension pipes;
+but with these high temperatures (contrary to what might be expected)
+there is no trouble from stoppages.</p>
+
+<p>These experiments, so far as they have gone, lead to the conclusion
+that the temperature of the gas as it is evolved from the coal is not
+less than 1200° Fahr., and that cooling commences immediately on the
+gas leaving the retort. The temperatures being far above that of
+liquefaction, the gases are cooled very rapidly. The temperature of
+the gas in the ascension pipe depends on the rapidity with which the
+gas is evolved&mdash;that is to say, the greater the quantity produced in a
+given time, the less effective is the cooling action of the mouthpiece
+and the ascension pipe; and although I had no opportunity of testing
+it, I should expect to find that with retorts making from 5,000 to
+6,000 cubic feet of gas per day, the maximum temperature in the
+ascension pipe 18 inches from the mouthpiece will not exceed 400° to
+500° Fahr., while with lower heats and lighter charges the
+temperatures will be still lower. That these temperatures have some
+effect in causing or preventing stoppage in the ascension pipes there
+can be no doubt; and it is important that this subject should be
+thoroughly investigated.</p>
+
+<p>It is of interest to consider what must be the physical condition of
+the gas at these high temperatures. All the hydrocarbons which are
+afterward condensed must then be in the condition of gases having
+various degrees of condensability, mixed with and rendered visible by
+a cloud of carbon particles or soot. If this soot could be removed
+from the gas at this stage without reducing the temperature, we should
+probably have no thick tar or pitch, but only comparatively
+light-colored oils; and it might possibly lead to an entirely
+different mode of conducting the process of condensation.</p>
+
+<p>These are a few of the subjects on which it is extremely desirable
+that we should possess that complete information which can only be
+obtained by well-directed investigations with different materials and
+under varying conditions. There are many others in connection with
+carbonization and purification which might be mentioned; but I think I
+have said sufficient to show the necessity that exists for more minute
+investigation and research. Investigations such as are here indicated
+do not involve any large expenditure of money; but they do require
+care and intelligence to prevent errors being made. Experiments should
+not be condemned as defective because the results differ from
+old-established theories; yet when this does happen, it is in all
+cases better to suspect the new experiment rather than the old theory,
+until the results have been fully established.&mdash;<i>Wm. Foulis, Journal
+of Gas Lighting.</i></p>
+
+<hr />
+
+<h2><a name="art21" id="art21"></a>THE LARGEST BLACK ASH FURNACE IN THE WORLD.</h2>
+
+<p>The Widnes Alkali Company have recently erected an enormous revolving
+black ash furnace, which is 30 ft. in length and has a diameter of 12
+ft. 6 in. The inside length is 28 ft. 6 in., with a diameter of 11 ft.
+4 in. The furnace is lined with 16,000 fire bricks and 120 fire-clay
+breakers, each weighing 1&frac14; cwt. The weight of salt cake per charge,
+<i>i.e.</i>, contained in each charge of salt cake, limestone, mud, and
+slack, is 8 tons 12 cwt. For 110 tons of salt cake charged there are
+also used about 100 tons of lime mud and limestone and 55 tons of
+mixing slack. The total amount of salt cake decomposed weekly is about
+400 tons, which may be calculated to yield 240 tons of 60 per cent.
+caustic soda. There is claimed for this massive furnace an economy in
+iron plate, in expense on the engine power and on fuel consumed, as
+well as on wear and tear.&mdash;<i>Watson Smith, in Industries.</i></p>
+
+<hr />
+
+
+<h2><a name="Page_9757" id="Page_9757"></a><a name="art01" id="art01"></a>THE STATUE OF PHILIP LEBON.</h2>
+
+<p>The inauguration of the statue of Philip Lebon, the inventor of
+lighting by gas, occurred on the 26th of June, at Chaumont, under the
+auspices of the Technical Gas Society of France. The statue, which we
+illustrate herewith, is due to the practiced chisel of the young
+sculptor Antide Pechine, who has perfectly understood his work, and
+has represented the inventor at the moment at which he observes a
+flame start from a glass balloon in which he had heated some sawdust.
+The attitude is graceful and the expression of the face is meditative
+and intelligent. The statue, which is ten feet in height, was
+exhibited at the last <i>Salon</i>. It was cast at the Barbedienne works.</p>
+
+<p>It would be impossible to applaud too much the homage that has just
+been rendered to the inventor of gas lighting, for Philip Lebon, like
+so many other benefactors of humanity, has not by far the celebrity
+that ought to belong to him. When we study the documents that relate
+to his existence, when we follow the flashes of genius that darted
+through his brain, when we see the obstacles that he had to conquer,
+and when we thoroughly examine his great character and the lofty
+sentiments that animated him, we are seized with admiration for the
+humble worker who endowed his country with so great a benefit.</p>
+
+<p>Lebon was born at Brachay on the 29th of May, 1767. At the age of
+twenty, he was admitted to the School of Bridges and Roads, where he
+soon distinguished himself by his ingenious and investigating turn of
+mind. His first labors were in connection with the steam engine, then
+in its infancy, and on April 18, 1792, the young engineer obtained a
+national award of $400 to continue the experiments that he had begun
+on the improvement of this apparatus.</p>
+
+<p>It was at about the same epoch that Lebon was put upon the track of
+lighting by gas, during a sojourn at Brachay. He one day threw a
+handful of sawdust into a glass vial that he heated over a fire. He
+observed issuing from the bottle a dense smoke which suddenly caught
+fire and produced a beautiful luminous flame. The inventor understood
+the importance of the experiment that he had just performed, and
+resolved to work it further. He had just found that wood and other
+combustibles were, under the action of heat, capable of disengaging a
+gas fit for lighting and heating. He had seen that the gas which is
+disengaged from wood is accompanied with blackish vapors of an acrid
+and empyreumatic odor. In order that it might serve for the production
+of light, it was necessary to free it from these foreign products.</p>
+
+<p>Lebon passed the vapor through a tube into a flask of water, which
+condensed the tarry and acid substances, and the gas escaped in a
+state of purity. This modest apparatus was the first image of the gas
+works; and it comprised the three essential parts thereof&mdash;the
+generating apparatus, the purifying apparatus, and the receiver for
+collecting the gas.</p>
+
+<p>One year afterward, the inventor had seen Fourcroy, Prony, and the
+great scientists of his epoch. On the 28th of September, 1799, he took
+out a patent in which he gives a complete description of his thermo
+lamp, by means of which he produced a luminous gas, while at the same
+time manufacturing wood tar and pyroligneous or acetic acid. In this
+patent he mentions coal as proper to replace wood, and he explains his
+system with a visible emotion and singular ardor. In reading what he
+has written we are struck with that form of persuasion that does not
+permit of doubting that he foresaw the future in reserve for his
+system.</p>
+
+<p>Unfortunately, Lebon could not devote all his time to his discovery.
+Being a government engineer, without money and fortune, he had to
+attend to his duties. He went as an ordinary engineer to Angouleme,
+but he did not forget his illuminating gas, and he strongly regretted
+Paris, which he termed &quot;an incomparable focus of study.&quot; He devoted
+himself to mathematics and science, he made himself beloved by all,
+and his mind wandered far from his daily occupation. The engineer in
+chief soon complained of him, but a committee appointed to investigate
+the charges that had been made against him affirmed that he was free
+from any reproach. He was sent back to his post, but war was
+decimating the resources of France, and the republic, while Bonaparte
+was in Italy, no longer had any time to pay its engineers. Lebon wrote
+some pressing letters to the minister, asking for the sums due on his
+work, but all of them remained without reply. His wife went to Paris,
+but her applications were fruitless. She wrote herself to the minister
+the following letter, which exists in the archives of the School of
+Bridges and Roads:</p>
+
+<div class="note">
+<p>&quot;Liberty, equality, fraternity&mdash;Paris. 22 Messidor, year VII. of
+    the French Republic, one and indivisible&mdash;the wife of Citizen
+    Lebon to Citizen Minister of the Interior:</p>
+
+<p>&quot;It is neither alms nor a favor that I ask of you, it is
+    justice. I have for two months been languishing at 120 leagues
+    from my household. Do not, by further delay, force the father of
+    a family, for want of means, to leave a state for which he has
+    sacrificed everything. ... Have regard for our position,
+    citizen. It is oppressive, and my demand is just. There is more
+    than one motive to persuade me that my application will not be
+    fruitless with a minister who makes it a law and duty for
+    himself to be just.</p>
+
+<p>&quot;Greeting and esteem. Your devoted fellow-citizen,</p>
+
+<p class="right">&quot;Madame Lebon, <i>nee</i> De Brambille.&quot;</p>
+</div>
+
+<p>In 1801, Lebon was called to Paris, as <i>attache</i> in the service of
+Blin, engineer in chief of pavements. He took a second patent&mdash;a true
+scientific memoir full of facts and ideas. It speaks of the numerous
+applications of illuminating gas and its mode of production, lays down
+the basis of the entire manufacture&mdash;furnaces, condensers, purifiers,
+gas burners. Nothing is forgotten, not even the steam engine and
+balloon. Lebon proposed to the government to construct an apparatus
+for heating and lighting the public buildings, but the offer was
+rejected. It was then that the unfortunate inventor, wearied by all
+his tentatives, fatigued by his thousands of vexations, made up his
+mind to have recourse to the public in order to convince it of the
+utility of his invention. He rented the hotel Seignelay, St.
+Dominique-St. Germain St., and invited the public thither. Here he
+arranged a gas apparatus, which distributed light and heat to all the
+rooms. He lighted the gardens with thousands of gas jets in the form
+of rosettes and flowers. A fountain was illuminated with the new gas,
+and the water that flowed from it seemed to be luminous. The crowd
+hastened from all parts and came to salute the new invention. Lebon,
+excited by this success, published a prospectus, a sort of profession
+of faith, a model of grandeur and sincerity, a true monument of
+astonishing foresight. He followed his gas into the future and saw it
+circulating through pipes, whence it threw light into all the streets
+of future capitals. We reproduce a few passages from this remarkable
+production:</p>
+
+<p>&quot;It is painful,&quot; says he, &quot;and I experience the fact at this moment,
+to have extraordinary effects to announce. Those who have not seen cry
+out against the possibility, and those who have seen often judge of
+the facility of a discovery by what they have to conceive of its
+demonstration. If the difficulty is conquered, the merit of the
+inventor vanishes with it. I would rather destroy every idea of merit
+than allow the slightest appearance of mystery or charlatanism to
+exist.</p>
+
+<p>&quot;This aeriform principle is freed from those humid vapors that are so
+injurious and disagreeable to the organs of sight and smell, and of
+the soot which soils apartments. Purified to perfect transparency, it
+travels in the state of cold air, and is led by the smallest as well
+as frailest pipes, by conduits an inch square, formed in the plaster
+of ceilings or walls, and even tubes of gummed taffety would perfectly
+answer the purpose. Only the extremity of the tube, which puts the
+inflammable gas in contact with the air, and upon which the flame
+rests, should be of metal.&quot;</p>
+
+<div class="figright" style="width: 240px;">
+<a href="./images/7.png"><img src="./images/7_th.png" width="240" height="450" alt="STATUE OF PHILIP LEBON." title="" />
+</a><span class="caption">STATUE OF PHILIP LEBON.</span>
+</div>
+
+<p>Every one finally paid homage to the illustrious inventor, and a
+committee appointed in the name of the minister affirmed that &quot;the
+advantageous results given by the experiments of Citizen Lebon have
+met and even exceeded the hopes of the friends of the sciences and
+arts.&quot; Napoleon I. soon granted Lebon a concession in the forest of
+Rouvray for the organization of an industry of wood distillation and
+gas making. Unfortunately, Lebon was obliged to undertake too many
+things at once. He prepared the gas, and produced acetic acid and tar
+that he had to send to Harve for the use of the navy. Despite all his
+trouble and fatigue, he had something like a ray of hope. He believed
+that he saw the day of fortune dawning. His works were visited by
+numerous scientists, and among others the Russian princes Galitzin and
+Dolgorouki, who, in the name of their government, proposed to the
+inventor to transfer his plant to Russia, he to be free to set forth
+the conditions. Lebon refused this splendid offer, and, in an outburst
+of patriotism, answered that his discovery belonged to his country,
+and that no other nation should before his own have the benefit of his
+labors.</p>
+
+<p>The hopes of Lebon were of short duration. Enemies and competitors
+caused him a thousand troubles, and the elements themselves seemed to
+turn against him. During a hurricane, the humble house in which he
+dwelt was destroyed, and a fire shortly afterward consumed a portion
+of his works. Fatality, like the genius of old, seemed to be following
+up the unfortunate inventor; but sorrows and reverses could not have
+any hold on this invincible spirit, who was so well seconded by a wife
+of lofty character. Lebon, always at work, was seemingly about to
+triumph over all obstacles, and the hour of the realization of his
+project of lighting on a large scale was near, when a death as tragic
+as it was mysterious snatched him from his labors. On the very day of
+the crowning of the emperor, December 2, 1804, the body of Philip
+Lebon was found lying inert and lifeless in the Champs Elysees,
+exhibiting thirteen deep wounds made by a dagger.&mdash;<i>La Nature.</i></p>
+
+
+<hr />
+
+<h2><a name="art18" id="art18"></a>A NEW PROCESS FOR THE DISTILLATION AND CONCENTRATION OF CHEMICAL
+LIQUIDS.</h2>
+
+<h3>ESPECIALLY ADAPTED TO THE MANUFACTURE OF SULPHATE OF AMMONIA.
+INVENTOR, ALEX. ANGUS CROLL.<a name="FNanchor_1" id="FNanchor_1"></a><a href="#Footnote_1"><sup>1</sup></a>.</h3>
+
+<h3>By <span class="smcap">George Anderson</span>, of London.</h3>
+
+<p>The paper I have to lay before you describes the last product of the
+brain of one of your past presidents&mdash;Alexander Angus Croll&mdash;in
+connection with our industry. It may not be so well known to some of
+the younger as it is to many of the older members of the Institute
+that the fertile brain of Mr. Croll has done much for the improvement
+and the extension of the gas industry. I consider that he has been the
+most successful pioneer both in the cheapening and the purification of
+gas&mdash;two elements without which our industry would progress but slowly
+if at all; and the success which has crowned his efforts, to our
+advantage, has reflected itself favorably on himself, showing by his
+financial success that he has also been a good man of business. All
+these are conditions which enhance the value of this paper. In the
+present instance, I claim no other credit than that of being the
+mouthpiece of Mr. Croll, whose assistant I was for ten of the busiest
+and most important years of his eventful life; and having (with my son
+Bruce) taken part in the experiments, I have been asked to describe
+the process to the Institute.</p>
+
+<p>The manufacture of sulphate of ammonia, as hitherto conducted, has
+consisted either in bringing together sulphuric acid and ammoniacal
+liquor or in distilling the liquor by external heat, or by the
+introduction of steam, and bringing it into contact with the acid in
+the form of gases and vapor of water. In either case a large volume of
+noxious gases is given off, the chief of which, being sulphureted
+hydrogen, has to be fixed by another method, in order to comply with
+acts of Parliament for the prevention of nuisances.</p>
+
+<p>By the processes hitherto used, we sometimes get only 1&frac14; tons of salts
+to every ton of acid used; while in the more perfect forms of
+apparatus, we may get 1-1/3 tons of salts. By Mr. Croll's process,
+however, we get an increased yield of salts on the acid used, as
+follows: The experiments were made with sulphuric acid of the specific
+gravity of 1838, or nearly concentrated oil of vitriol; and the
+quantity used was 8 ounces in each experiment. The ammoniacal liquor
+was of uniform strength throughout all the experiments, being kept in
+a corked jar; and the solution of sulphate of ammonia was passed
+through filter paper before being crystallized. Thus we obtained a
+white salt. In each experiment the solution of sulphate was divided
+into four equal parts by weight, and one part filtered and
+crystallized to dryness over a spirit lamp; the weight in each
+experiment being as nearly as possible the same, or 3&frac14; oz. of salt to
+2 oz. of acid&mdash;being in the proportion of 26 oz. of sulphate to 1 lb.
+of acid, or 32&frac12; cwt. of salts to 20 cwt. of acid.</p>
+
+<p>The results surprised me; and being uniform over a number of
+experiments, pleased me. Still, I preserved the character of a critic
+and said: &quot;I should like to treat 8 oz. of acid in the ordinary
+way&mdash;saturating it with ammoniacal liquor, and then crystallizing it.&quot;
+&quot;Oh!&quot; Mr. Croll said, &quot;we know what that will produce.&quot; I replied:
+&quot;Yes; but I would like to do it with the precise acid and liquor we
+have been using, so that we may have the experiment on all fours with
+yours, barring your process.&quot; These experiments were made at his
+country residence. I was staying there for the night. So next morning
+I got down before him, went at my experiment, saturated 8 oz. of acid
+(and a nice smell I made) out in the grounds, treated it afterward by
+division into four parts, filtered and crystallized it, all as before,
+with the result that I obtained 2&frac34; oz., as against his 3&frac12; oz.&mdash;or in
+the proportion of 27&frac12; cwt. of salt to the ton of acid, as against his
+32&frac12; cwt.</p>
+
+<p>I now thought of business. &quot;What is the royalty to be?&quot; I said, as we
+sat at breakfast. This we settled as we Scotch say &quot;in a crack,&quot; or as
+an Englishman would say &quot;in a jiffy.&quot; Mr. Croll decided to have the
+apparatus put up on a manufacturing scale here in Glasgow; and I
+determined to erect similar apparatus at one of my gas works.</p>
+
+<p>I dare say that it will be uppermost in your minds, Whence comes the
+increased yield of salts? Well, I will state one fact, and leave you
+to ruminate on it, namely, by Mr. Croll's process we did not seem to
+produce any sulphureted hydrogen. The experiments were conducted in a
+room with ordinary doors and windows, but without a chimney; and we
+were not troubled with any offensive smell&mdash;a state of things that
+could not possibly have existed had we been experimenting with any
+other apparatus hitherto employed in the manufacture of sulphate of
+ammonia. The apparatus, which will presently be described, only
+substitutes, for the present mode of distillation, a new one, which
+forms the subject of Mr. Croll's patent. All other parts of present
+apparatus can remain as they now exist.</p>
+
+<p>Mr Croll has also introduced another mode of producing sulphate of
+ammonia, which dispenses with all the apparatus hitherto in use after
+the distillatory portion, and produces the salt in a state fit for the
+farmer, ready to be put on the land. This process consists in sending
+the products of distillation through a vessel filled with wood sawdust
+saturated with sulphuric acid. The ammonia becomes fixed and
+crystallized in the sawdust, and is ready for use. There are many
+works, both at home and abroad, to which the conveyance of sulphuric
+acid is both difficult and expensive, on account of the cost of
+carriage and the breakage which occurs; and thus in many such works
+the ammonia is not utilized. This saturated sawdust process will, I
+think, remove the difficulty; for I find that dry sawdust absorbs
+double its own weight of sulphuric acid, and this could be conveyed in
+the most ordinary casks in a damp state, and save all waste and
+annoyance from breakage of bottles. In this state it could be used by
+the farmer, or the sulphate of ammonia could be washed out,
+crystallized, and exported in the state of salt.</p>
+
+<p>In the remainder of this paper I have been assisted by my son Bruce,
+who also assisted in the experiments that I have described. He has
+since been engaged on the trials on a manufacturing scale; and I ask
+you to permit him to read the concluding portion of the paper, <a name="Page_9758" id="Page_9758"></a>in
+which he will describe the process, and what he has done.</p>
+
+<p>The process referred to in the foregoing portion of the paper is a
+method employed for heating the liquor, whereby a chemical action is
+brought into play, with the results already mentioned. This method
+consists in passing the products of combustion of a furnace from a
+clear fire in a hot state through a still containing the ammoniacal
+liquor. The hot gases from the furnace impart their heat to the
+liquor, causing the volatilization of the condensed gases, and at the
+same time act chemically upon the liquor and evolved gases, so that
+ammonia and sulphuric acid are resulting products, in the compound
+state of sulphate of ammonia. The formation of the ammonia produced in
+the process is probably due to the decomposition of nitrogenous bodies
+contained in solution in the liquor&mdash;the sulphocyanide, for instance;
+the nitrogen being given off in the form of ammonia. Of the sulphuric
+acid produced, we look upon the sulphureted hydrogen as the source,
+also any sulphites existing in the liquor, which in their volatile
+state take up the atom of oxygen necessary for their conversion into
+sulphate.</p>
+
+<div class="figleft" style="width: 257px;">
+<img src="./images/8a.png" width="257" height="450" alt="" title="" />
+</div>
+
+<p>The apparatus used in working the process consists of a tower still,
+containing a number of superposed trays about 3 or 4 inches apart,
+with a lipped hole through the bottom of each at the side. The trays
+are so placed in the tower that the holes are at alternate sides. The
+liquor passes into the top of the still, and zigzags down through the
+series of trays, as in an ordinary Coffey still. The bottom tray
+differs from the rest; being much deeper, and having holes through it
+connecting it with the furnace, which is set immediately below it. The
+products of combustion of the fuel are caused to pass from the furnace
+up through the holes in the trays in the still, and, together with the
+gases evolved from the liquor, are directed into the saturator, where
+the sulphate of ammonia is obtained either in solution or in the
+crystalline state.</p>
+
+<p>Where the process is at present being worked, an exhauster is used to
+draw the furnace gases through the still; but it might be advantageous
+to use a blower.</p>
+
+<p>A small plant has been put in action at the gas works in Kilkenny and
+another on a larger scale, and differing somewhat in detail, here in
+Glasgow at the Alum and Ammonia Company's works, where the liquor from
+the Tradeston Gas Works is converted. The trials on a working scale
+have only been made at both places within the past ten days; and, so
+far, nothing has appeared against the principle, though in certain of
+the details of construction some alterations are being made to improve
+it. The extra yield of salt from a given quantity of acid obtained in
+the experiments has been proved in practice, as also the absorption of
+the sulphureted hydrogen.</p>
+
+<p>The other day, while ammoniacal liquor of about 9 oz. strength was
+being run at the rate of 70 gallons per hour through the still, 5 feet
+in diameter and 10 feet high, containing seventeen trays, no smell of
+sulphureted hydrogen was perceptible from the waste gases from the
+saturator, although on applying lead paper a slight trace of this
+impurity was noticeable, and it may be stated that the gases were
+being delivered at the ground level, where there was no difficulty in
+testing them.</p>
+
+<p>In the Glasgow apparatus we have found it advisable to enlarge the
+pipe leading the gases into the saturator, as the volume of these is
+much greater than would be the case in the ordinary method of working.
+Further experience will probably indicate the desirability of
+increasing the height of the still, which, being only 10 feet, is not
+more than half the height that Coffey stills are ordinarily made.</p>
+
+<p><a name="Footnote_1" id="Footnote_1"></a><a href="#FNanchor_1">[1]</a></p>
+<div class="note"><p>Read at the recent meeting of the Gas Institute, Glasgow.</p></div>
+
+<hr />
+
+<h2><a name="art02" id="art02"></a>THE ANALYSIS OF URINE.</h2>
+
+<h3>INTRODUCTION.</h3>
+
+<p>Whatever may be the position of British pharmacists in comparison with
+those of other countries, it cannot be said that they have paid the
+attention to the analysis of urine which the subject has received from
+pharmacists on the Continent. Considering the importance of the
+subject, this curious neglect can only be attributed to the fact that
+the pharmacist in Great Britain is but slowly attaining the position
+of chemical expert to the physician, which his foreign <i>confrere</i> has
+so long held with credit and even distinction. In France, for example,
+M. Méhu, whose name is familiar to readers of this journal, is looked
+upon as one of the leading authorities on morbid urine and its
+analysis, and yet a list of goodly pharmaceutical papers shows that,
+as the medical analyst, he has not forgotten his connection with pure
+pharmacy.</p>
+
+<p>There are several points about urinary analysis which entitle it to a
+very high position in the estimation of pharmacists. In the first
+place, the physician is no more likely to be fonder of the test tube
+than of the pestle, of analyzing urine than of compounding his own
+medicines. Leading men in the profession are more and more setting
+their faces against the dispensing doctor, and there are numbers among
+them who admit that they succeed no better as analysts than they do as
+dispensers.</p>
+
+<p>Some old fashioned practitioners trouble themselves very little about
+their patients' urine, except, perhaps, in respect of sugar and
+albumen. On the other hand, numbers of leading physicians, including
+especially those highly educated gentlemen who cultivate a consulting
+practice, are in the habit of pushing urinary analysis almost to an
+excess. One well-known specialist of the writer's acquaintance, with
+an extensive West End practice, makes quantitative determinations of
+urea, uric acid, and total acidity, in addition to conducting other
+diagnostic experiments, on every occasion that he interviews his
+patients. By this means he has accumulated in his case books a mass of
+data which he considers most valuable as an aid to diagnosis, and
+through that to successful treatment.</p>
+
+<p>Pharmacists are proverbially neat-handed, as Mr. Martindale would say,
+and their habit of conducting dispensing operations which involve the
+dexterous manipulation of very small quantities of material fit them
+admirably to undertake volumetric and other rapid analytical
+determinations. Compared with the doctor there is no doubt that in
+this matter the chemist is <i>facile princeps</i>, and from the nature of
+their respective occupations such could only have been expected. A few
+chemists throughout the country lay themselves out to save their local
+doctors from unwelcome test tube practice, and these almost to a man
+find it pay. Some charge a handsome fee to patients, and a small one
+when the analysis comes through the physician. Others find it to their
+interest to furnish medical men with qualitative reports on sugar or
+albumen gratuitously. Although this practice has certain obvious
+drawbacks, if a doctor sends his prescriptions to a chemist, the
+latter is often willing to gratuitously perform his chemical work. In
+the present article we propose to describe briefly but fully the
+methods which have been found of most value in practice.</p>
+
+
+<h3>PRELIMINARY OPERATIONS.</h3>
+
+<p>It is the practice of some physicians to direct the patient to
+preserve all the urine passed in twenty-four hours, and to forward
+this in one bottle for analysis. Others, again, merely send a small
+sample of &quot;morning&quot; and &quot;evening&quot; urine in separate phials, desiring
+only a comparative report. In the former case the <i>volume</i> should be
+accurately measured, and the quantity noted either in fluid ounces or
+cubic centimeters before commencing the analysis. This need not be
+done if small samples only are received. The <i>color</i> should be noted.
+It varies greatly, through every shade of yellow and amber to dark
+brown, with a tinge of green or red, if the coloring matter of bile or
+blood is present. Also note relative <i>transparency</i> or <i>cloudiness</i>,
+<i>specific gravity</i>, and <i>reaction</i>, as all these observations are
+useful in diagnosis. <i>Odor</i> is not quite so important. The <i>specific
+gravity</i> should be taken at about 60° F. in an ordinary specific
+gravity bottle, or more conveniently by means of a good <i>urinometer</i>.
+In the latter case it is very important to have an instrument of known
+accuracy, many of those in the market being valueless. Urinometers of
+glass, though fragile, are decidedly more cleanly and less liable to
+get out of order than the gilded brass instruments carried in the
+pocket by many physicians. Mr. J.J. Hicks, of 8 Hatton Garden, E.C.,
+manufactures a very creditable &quot;patent urinometer&quot; at an extremely low
+cost. Healthy urine has a density of from 1.015 to 1.025; but
+variations from this range are common.</p>
+
+<div class="figright" style="width: 138px;">
+<img src="./images/8b.png" width="138" height="450" alt="" title="" />
+</div>
+
+<p>A fair quantity of the urine, after shaking, should be placed in a
+tall conical glass vessel, to allow easy collection of the precipitate
+for subsequent, microscopical examination. If an abundant amorphous
+deposit of a fawn or pink&mdash;from <i>uroerythrin</i>&mdash;color slowly settles
+and is readily diffused, <i>urates</i> in excess can be anticipated. Their
+presence is proved by the readiness with which they dissolve on
+warming with the supernatant urine to about the temperature of the
+blood. No difficulty is experienced if small quantities of albumen are
+present, as that body is not coagulated until the temperature rises
+much higher. A sandy precipitate of free <i>uric acid</i> will not dissolve
+on warming the urine, and its identity can further be determined by
+means of the microscope, or by applying a well-known color-reaction. A
+grain or so is oxidized into reddish alloxan and alloxantin by
+carefuly evaporating with a few drops of strong nitric acid on a piece
+of porcelain. A little ammonia is then added, when the fine <i>purple</i>
+murexide stain will be produced.</p>
+
+<p>It is always advisable to mention the reaction to test papers of all
+samples received. Urine is normally <i>acid</i>, but there are certain
+diseases which render fluid neutral or alkaline. The urea of acid
+urine on standing is changed by a putrefactive ferment into ammonic
+carbonate, but this decomposition in a state of health should not
+take place for at least twenty-four hours. Alkalies, or organic salts
+of alkaline metals, when taken as medicine render the urine alkaline,
+and the indication is then not of much moment; but if none of these
+causes exist, the condition is of serious diagnostic import. Where it
+is desired to determine the degree of acidity of the urine voided,
+say, by a gouty patient, a dilute volumetric solution of caustic soda
+should be employed, using a few drops of an alcoholic solution of
+phenolphthalein as an indicator, and reporting in terms of oxalic
+acid. The soda solution may conveniently contain the equivalent of one
+milligramme of recrystallized oxalic acid (H<sub>2</sub>C<sub>2</sub>O<sub>4</sub>.2H<sub>2</sub>O) in
+each cubic centimeter.</p>
+
+<h3>UREA.</h3>
+
+<p>Carbamide, as it is called by systematic chemists, or <i>urea</i>, is next
+to water the largest constituent of urine, and forms about one-third
+of its total solids. Derived from ammonic carbonate by abstracting two
+molecules of the elements of water, it is readily converted by
+putrefaction into that salt, and the urine under these circumstances
+becomes strongly alkaline in reaction. Earthy phosphates then fall
+naturally out of solution, so that the putrid fluid is always well
+furnished with sediment. Nitrogen that has served its purpose as
+muscle or other proteid leaves the animal economy chiefly in the form
+of urea, and its proportion in the urine, therefore, is a fair index
+of the activity of wasting influences.</p>
+
+<p>For its determination Knop's sodic hypobromite method, on account of
+its convenience, is now generally preferred. The volumetric process of
+Liebig, which depends on the formation of an insoluble compound of
+urea with mercuric nitrate, possesses no advantages and is troublesome
+to work. The principle of the hypobromite process is simple. In a
+strongly alkaline solution urea is broken up by sodic hypobromite, its
+nitrogen being evolved in the gaseous state, and its carbon and
+hydrogen oxidized to carbonic anhydride and water respectively. The
+volume of free nitrogen obtained bears a direct ratio to the amount of
+urea decomposed.</p>
+
+<div class="figright" style="width: 282px;">
+<img src="./images/8c.png" width="282" height="400" alt="" title="" />
+</div>
+
+<p>Among the number of instruments which have been introduced for the
+purpose of conveniently measuring the evolved gas, that of Gerrard, an
+illustration of which we give, is one of the simplest, cheapest, and
+best. The ureometer tube, <i>b</i>, is connected at the base with a movable
+reservoir, <i>c</i>, and by means of a rubber tube passing through a cork
+at the top to the generating bottle, <i>a</i>. To use the apparatus, fill
+<i>b</i> to zero with water and have the reservoir placed so high that it
+contains only an inch or so of the liquid. Replace the cork with
+attached tube tightly in <i>b</i>. Now pour into the generating bottle 25
+c.c. of a solution prepared by dissolving 1 part of caustic soda in 2&frac12;
+parts of distilled water, and dexterously break in the liquid a tube
+containing 2.2 c.c. of bromine. The tubes will be found very
+convenient, obviating entirely the suffocating fumes diffused in the
+act of measuring bromine. Allow to stand in the solution of sodic
+hypobromite thus prepared a test tube containing exactly 5 c.c. of the
+urine under examination. Cork the bottle as shown in the illustration,
+see that the water is at zero, and that the liquid in the reservoir is
+at the same level, and then allow the urine to gradually mix with the
+hypobromite solution. Cool the evolved gas by placing the bottle in
+cold water, adjust the levels of the water in the tube and reservoir
+(to obviate a correction for pressure), and read off the percentage of
+urea in terms of which the tube is graduated. Stale urine, the urea of
+which has largely been converted into ammonic carbonate, still yields
+a very fair result, that salt being also completely split up by the
+powerful oxidant employed. Should the urine contain albumen, it is
+advisable to remove it by boiling and filtering, as, although only
+slowly decomposed by the hypobromite solution, it communicates to the
+liquid such a tendency to froth that the disengagement of the nitrogen
+is seriously impeded. Most of those alkaloids which might possibly be
+present do not yield the gas when treated in this manner, and
+therefore may be disregarded.</p>
+
+<h3>SUGAR.</h3>
+
+<p>Glucose, so characteristic of <i>diabetes mellitus</i>, is not difficult of
+detection or estimation. The facility with which it reduces alkaline
+cupric, argentic, bismuthous, ferric, mercuric salts, indigo and
+potassic picrate and chromate solutions has been utilized for the
+preparation of several ready methods for its determination. Trommer's
+test consists in adding enough cupric sulphate to color green, then
+excess of alkali, and boiling. Yellow to brick-red cuprous oxide forms
+as a heavy precipitate if glucose is present. The organic matter of
+the urine prevents the precipitation of cupric hydrate on the addition
+of the alkali. This test is delicate and deservedly popular. Fehling's
+well-known solution contains sodio-potassic tartrate, which serves the
+purpose chiefly of retaining the copper in solution. Unfortunately,
+Fehling's original solution has a tendency to become hyper-sensitive
+if kept long, a proneness to change that is much increased on
+dilution. <a name="Page_9759" id="Page_9759"></a>When so altered, the solution will yield a more or less
+copious precipitate of cuprous oxide on merely boiling, and quite
+independent of the presence of glucose. This decomposition is obviated
+by preserving the copper salt in a separate solution from the tartrate
+and alkali, and mixing before use. Schmiedeberg substitutes mannite
+and Cresswell glycerin for the Rochelle salt, in order to render the
+solution stable. Some prepared by the writer over twelve months ago,
+according to the suggestion of the latter physician, has since shown
+no signs of decomposition, and is now as good as it was then. For
+qualitative purposes the solution may be prepared thus: Dissolve 35
+gm. of recrystallized cupric sulphate and 200 c.c. of pure glycerin in
+100 c.c. of distilled water. Dissolve separately 80 gm. of caustic
+soda in 400 c.c. of water. Mix the solutions and boil for a quarter of
+an hour. A small amount of reduction from impurity in the glycerin
+takes place. Allow to stand till clear, decant, and dilute to 1,250
+c.c. Ten cubic centimeters will then equal roughly 5 centigrammes of
+glucose. For exact quantitative determination it is necessary to
+standardize the solution with pure anhydrous dextrose.</p>
+
+<p>To a practiced operator the indications yielded by the use of this
+test are of great value; but beginners are exceedingly liable to
+mistake its various reactions, and to report the urine as saccharine
+when normal traces only of sugar are present. The bismuth test of
+Bottger, as greatly improved by Nylander, is fairly delicate, and not
+so easily misread as Fehling's. A large volume of reagent being used
+with a comparatively small quantity of urine, the precipitate of
+earthy phosphates does not interfere in the least with the reaction.
+On boiling about 3 drachms of Nylander's solution and 20 minims of
+urine for a minute or two, the liquid darkens with a trace of sugar,
+and becomes opaque and black if the latter is present in quantity. The
+reagent is prepared by dissolving 494 grains of caustic soda, 247
+grains of Rochelle salt, and 154 grains of subnitrate of bismuth (free
+from silver) in 13 fluid oz. of distilled water. It should be decanted
+for use from any sediment.</p>
+
+<div class="figleft" style="width: 175px;">
+<a href="./images/9a.png"><img src="./images/9a_th.png" width="175" height="400" alt="DR. PAVY&#39;S APPARATUS." title="" />
+</a><span class="caption">DR. PAVY&#39;S APPARATUS.</span>
+</div>
+
+<p>In those cases where the amount of glucose present is required to be
+determined, Dr. Pavy's ammonia cupric process distances all compeers
+for ease of application and delicacy of end-reaction, combined with
+considerable accuracy. His solution differs from that of Fehling in
+containing ammonia, which dissolves the cuprous oxide as soon as it is
+formed, yielding a colorless solution. It is only necessary,
+therefore, to note the moment that the blue color of the liquid is
+exactly discharged, in order to tell when all the copper present has
+been reduced. Pavy's solution is prepared as follows: Dissolve 356
+grains of Rochelle salt and the same weight of caustic potash in
+distilled water; dissolve separately 73 grains of recrystallized
+cupric sulphate in more water with heat. Add the copper solution to
+that first prepared, and when cold add 12 fluid oz. of strong ammonia
+(sp. gr. 0.880), and distilled water to 40 fluid oz. The estimation is
+thus conducted: Dilute 10 c.c. of the ammoniated cupric
+solution&mdash;equivalent to 5 milligrammes of glucose&mdash;with 20 c.c. of
+distilled water, and place in a 6 or 8 oz. flask. Attach this by means
+of a cork to the nozzle of an ordinary Mohr's burette, <i>b</i>, preferably
+fitted with a glass stopcock, and filled previously with the diluted
+urine. The small tube, <i>c</i>, which traverses the cork is intended to
+permit the escape of steam. Now raise the blue liquid in the flask to
+active ebullition&mdash;not too violent&mdash;by the aid of a spirit lamp or
+small Bunsen flame. Turn the stopcock in order to allow the urine to
+flow into the boiling solution at the rate of about 100 drops per
+minute (not more or much less) until the azure tint is exactly
+discharged. Then stop the flow, and note the number of cubic
+centimeters used. That amount of dilute urine will contain 5
+milligrammes of glucose. To render the determination as accurate as
+possible, the urine should be diluted to such an extent that not less
+than 4 or more than 7 c.c. are required to decolorize the solution,
+and the proportions necessary will be found to vary from 1 part of
+urine in 2&frac12; to 1 in 30 or 40. The subsequent calculation is very
+simple. If you wish to give the percentage of sugar, multiply 0.005 by
+100, and divide the product by the number of cubic centimeters of
+dilute urine employed. The figure thus obtained, multiplied by the
+extent of dilution&mdash;<i>i.e.</i>, if there is 1 of urine in 10, multiply by
+10&mdash;gives the required percentage. The number of grains per fluid
+ounce can of course be obtained by multiplying the percentage by
+4.375. To observe easily the exact end-reaction a piece of white paper
+should be placed behind the flask. If the analyst objects to the
+escape of the waste ammoniacal fumes, they may be conducted by a
+suitable arrangement into water or dilute acid. In addition to glucose
+there are small quantities of other copper-reducing bodies present in
+all urine, which always render the reading higher than strict accuracy
+would demand. Their aggregate proportion, however, is, comparatively
+speaking, so minute that for most medical purposes their presence may
+be disregarded. Greater care must be exercised, though, in those
+instances where such a deoxidizer as chloral hydrate is accidentally
+present. In case of doubt, a little washed and pressed yeast should be
+allowed to stand with the urine for a day or two in a warm place.
+Alcoholic fermentation with evolution of carbonic acid gas soon sets
+in, and the specific gravity of the liquid is lowered considerably.
+This reaction points conclusively to the presence of sugar.</p>
+
+<p>Based upon Braun's potassic picrate test, Dr. G. Johnson has devised a
+colorimetric process for the estimation of sugar. On boiling an
+alkaline solution of that salt with glucose, the former is reduced to
+deep red-brown picramate, the color of the liquid, of course, varying
+in intensity according to the proportion of sugar present. This
+solution is diluted till it corresponds in tint with a ferric acetate
+standard, and the percentage of sugar is then readily calculated. For
+those who prefer this process the convenient apparatus manufactured by
+Mr. Cetti, of 36 Brooke street, Holborn, is recommended, who will also
+furnish full particulars of the test.</p>
+
+<h3>ALBUMEN.</h3>
+
+<p>Normal urine is free from coagulable proteids, though it is admitted
+that albumen may sometimes occur in the absence of disease. It is
+always highly important, therefore, to determine accurately the
+presence or absence of this body. In the relentless malady named after
+Richard Bright, the urine always contains albumen, and if accompanied
+by the &quot;casts&quot; of the uriniferous tubules your report may amount to a
+sentence of certain death. The tests which we now describe are
+accurate and easily applied; but reliance should never be placed on
+any single reaction&mdash;at any rate until the operator has acquired
+considerable experience.</p>
+
+<p>Galippe's <i>picric acid test</i> has within the last few years attracted
+much attention, chiefly through the commendation it has received from
+Dr. George Johnson. A saturated solution is prepared by dissolving 140
+grains of recrystallized picric acid (carbazotic acid, or, more
+correctly, trinitrophenol) in 1 pint of water with heat, and decanting
+the clear solution. Some of the urine is rendered perfectly bright by
+filtration&mdash;repeated, if necessary&mdash;through good filtering paper, and
+to this an equal volume of the picric acid solution is added. In the
+presence of albumen a more or less distinct haze is produced, which on
+heating to the boiling point is rather intensified than otherwise.
+Peptones, if present, yield a similar haze, and quinine or other
+alkaloid a more or less crystalline precipitate; but in both these
+cases the opalescence is completely dissipated by heat. Mucin, an
+important constituent of some urines, is not affected by picric acid,
+and the test is decidedly one of great value.</p>
+
+<p>The <i>nitric acid test</i>. Heller's contact method, which can also be
+used with the last-described reagent, is the best mode of applying the
+old-fashioned and favorite test with nitric acid. To 5 volumes of a
+filtered saturated solution of magnesic sulphate, prepared by
+dissolving 10 parts of the salt in 13 parts of distilled water, add 1
+volume of strong nitric acid, and label &quot;Sir W. Roberts' nitric acid
+reagent.&quot; A couple of drachms of bright filtered urine is allowed to
+float on an equal quantity of this solution in a test tube; care being
+taken that the contact line is sharply defined. In a period of time
+varying from a few seconds to a quarter of an hour, according to the
+amount of albumen present, a delicate opalescent zone forms at the
+point of junction, and if mucin also is present, a more diffused haze
+higher up in the urine. Special attention should be given to the
+position of the opacity. In some concentrated urines a belt of urates
+will appear at the line of demarkation; but these dissolve on warming.
+Moreover, owing to the dilution necessary in the mode of applying
+Galippe's picric acid test, they are not so readily shown by the
+latter. A &frac12; oz. glass syringe can very conveniently be substituted for
+a test tube in making analyses according to Heller's method. Some of
+the urine should be drawn up, and then an equal volume of the reagent.
+On setting aside, the albumen ring will rapidly develop.</p>
+
+<p>The <i>boiling test</i>. This method also is very delicate and valuable. It
+depends on the well-known property possessed by many proteids of
+coagulating under the influence of heat. The urine should have an acid
+reaction to test paper; if alkaline, it must be cautiously neutralized
+with dilute acetic acid. In either case a single drop of strong acetic
+acid should be added to about three drachms of the bright liquid. If
+this precaution is omitted, there is danger of precipitating earthy
+phosphates on heating; and should a great excess of acid be employed,
+a non-coagulable form of albumen known as syntonin is formed, besides
+increasing the likelihood of precipitating mucin. Place the prepared
+urine in a narrow test-tube and hold it in a small flame so that the
+upper part only of the liquid approaches the boiling point. By this
+means very small traces of albumen are easily observed, the
+opalescence produced contrasting strongly with the cold and clear
+fluid beneath.</p>
+
+<p>The <i>ferrocyanide test</i>. Hydroferrocyanic acid yields a precipitate
+immediately in the presence of much albumen, and if traces only are
+present, in the course of a few minutes. To apply the test, strongly
+acidulate with acetic acid, and then add a few drops of recently
+prepared potassic ferrocyanide solution. This is one of the most
+delicate tests known.</p>
+
+<p>It is often desirable that the percentage of albumen present should be
+determined at frequent intervals, in order to note the success or
+otherwise of the physician's treatment. These quantitative
+determinations, being intended only for comparative purposes, do not
+demand any very excessive degree of accuracy, such as would be
+difficult to obtain in ordinary practice. The recent method of a
+Continental worker. Dr. Esbach, affords indications sufficiently
+precise for therapeutical requirements, and is at the same time
+extremely easy of application. The filtered acid urine is poured into
+the glass tube up to the mark U, and then the special reagent is added
+till the level of the liquid stands at R.</p>
+
+<div class="figright" style="width: 66px;">
+<a href="./images/9b.png"><img src="./images/9b_th.png" width="66" height="400" alt="" title="" />
+</a></div>
+
+<p>Mix the liquids thoroughly, without shaking, by reversing the tube a
+dozen times, close with a cork, and allow it to stand upright for
+twenty-four hours. The height at which the coagulum then stands, read
+off on the scale, will indicate the number of parts per thousand, or
+grammes of albumen in one liter. This divided by ten gives the
+percentage. Dr. Esbach's test solution is prepared by dissolving 10
+grammes of picric acid and 20 grammes of citric acid in 900 c.c. of
+boiling distilled water, and then adding, when cold, sufficient water
+to yield 1 liter. The citric acid is only employed for the purpose of
+maintaining the acidity of the liquid, and is really not essential.</p>
+
+<h3>URIC OR LITHIC ACID.</h3>
+
+<p>The determination of the proportion of uric acid in urine was formerly
+rather neglected by physicians. There is now, however, a growing
+tendency in a certain class of diseases to attach considerable
+importance to its accurate estimation, and, as some little trouble is
+involved, pharmacists should be prepared to undertake the work. A
+rough way is to concentrate somewhat, acidulate with hydrochloric
+acid, and collect and weigh the precipitate thrown down on standing.
+There are several objections, however, to this method, and many
+attempts have been made to elaborate a more reliable process. One of
+the most recent, and which has been pronounced the most practical and
+successful, has been devised by Professor Haycraft. Although
+apparently rather detailed and elaborate, the determination is easy
+and extremely simple.</p>
+
+<p>The following solutions must be prepared: 1. Dissolve 5 grammes of
+nitrate of silver in 100 c.c. of distilled water, and add ammonia
+until the precipitate first formed redissolves. 2. Dilute strong
+nitric acid with about two volumes of distilled water; boil, to
+destroy the lower oxides of nitrogen, and preserve in the dark. 3.
+Dissolve about 8 grammes of ammonic thiocyanate (sulphocyanide)
+crystals in a liter of water, and adjust to decinormal argentic
+nitrate solution, by diluting till one volume is exactly equal to a
+volume of the latter. Dilute the solution thus prepared with nine
+volumes of distilled water, and label &quot;Centinormal ammonic-thiocyanate
+solution.&quot; 4. A saturated solution of ferric alum. 5. Strong solution
+of ammonia (sp. gr. 0.880). The uric acid estimation is conducted as
+follows: Place 25 per cent. of urine in a beaker with 1 gramme of
+sodic bicarbonate. Add 2 or 3 c.c. of strong ammonia, and then 1 or 2
+c.c. of the ammoniated silver solution. If, on allowing the
+precipitate caused by the latter reagent to subside, a further
+precipitate is produced by the addition of more solution, the urine
+contains an iodide, and silver solution must be added till there is an
+excess. The gelatinous urate must now be collected, the following
+special procedure being necessary: Prepare an asbestos filter by
+filling a 4 oz. glass funnel to about one-third with broken glass, and
+covering this with a bed of asbestos to about a quarter of an inch
+deep. This is best managed by shaking the latter in a flask with water
+until the fibers are thoroughly separated, and then pouring the
+emulsion so made in separate portions on to the<a name="Page_9760" id="Page_9760"></a> broken glass. On
+account of the nature of the precipitate and of the filter, it is
+necessary to use a Sprengel pump, in order to suck the liquid through.
+The small apparatus sold to students by chemical instrument makers
+will answer the purpose admirably. Having collected the precipitate of
+silver urate on the prepared filter, wash it repeatedly with distilled
+water, until the washings cease to become opalescent with a soluble
+chloride. Now dissolve the pure urate by washing it through the filter
+with a few cubic centimeters of the special nitric acid. The process
+is carried out thus: Add to the liquid in the beaker a few drops of
+the ferric-alum solution to act as an indicator, and from a burette
+carefully drop in centinormal ammonic thiocyanate until a permanent
+red coloration of ferric thiocyanate barely appears. The number of
+cubic centimeters used of the thiocyanate solution multiplied by
+0.00168 gives the amount of uric acid in the 25 c.c. One milligramme
+may be added to compensate for loss, and the whole multiplied by four
+gives the percentage of uric acid in the urine. The whole process
+depends on the fact that argentic urate fails to dissolve in ammonia,
+but is soluble in nitric acid, and is thus easily obtained in the pure
+state. By determining the amount of combined silver, the percentage of
+uric acid can readily be calculated. The addition of sodic bicarbonate
+prevents the otherwise inevitable reduction of the silver salt.</p>
+
+<h3>BILE.</h3>
+
+<p>In diseases affecting the liver, the urine frequently becomes
+contaminated with biliary constituents. If the coloring matter of bile
+is present (<i>bilirubin</i>, etc.), the liquid is darkened considerably in
+tint, and may assume various shades of brown or green. Should the
+color be decided, the fluid will be found to foam strongly on shaking,
+and white blotting-paper will be stained by it yellow or greenish.
+These characters point to the presence of bile in fair quantity, and
+it is only necessary to apply a single confirmatory test. Allow some
+of the urine to flow carefully, according to Heller's method, over a
+couple of drachms of yellow nitric acid (i.e., acid containing traces
+of the lower oxides of nitrogen). A number of rapidly changing colors
+soon appear, passing through green, blue, violet, and red to yellow.
+The first of these tints, green, is the only one that undoubtedly
+points to the presence of biliary coloring matter, all the others
+being yielded by another constituent of urine, indican, when similarly
+treated. Should the color of the urine suggest the presence of only
+traces of bile, the best plan is not to treat the urine directly, but
+extract a quantity of it by shaking with chloroform. On separating the
+latter, and covering with yellowish nitric acid, the color changes
+will be observed penetrating into the chloroform. A little, also,
+evaporated on a slide yields reddish crystals, which exhibit a pretty
+play of colors under the microscope when touched with nitric acid.</p>
+
+<p>It is not unfrequently considered important to test urine for the
+sodium salts of the conjugate biliary acids, taurocholic and
+glycocholic. Dr. Oliver, of Harrogate, has proposed the use of an
+acidulated peptone solution for this purpose, and the reaction is
+undoubtedly a good one. The reagent is prepared by dissolving 30
+grains of flesh peptone, 4 grains of salicylic acid, and 30 minims of
+strong acetic acid, in sufficient water to produce 8 fluid oz. of
+solution. Thus prepared, the peptone shows no signs of decomposition
+on keeping. To use the test, mix 1 fluid drachm of the reagent with 20
+minims of urine, previously diluted to a standard specific gravity of
+1.003. A haze is produced, which will be found to be more or less
+distinct, according to the proportion of bile salts present.</p>
+
+<h3>CHLORIDES.</h3>
+
+<p>A normal and variable constituent of urine, chlorine, is not usually
+required to be determined. Should the estimation be considered
+necessary, however, Volhard's silver process, which has been noticed
+in treating of uric acid, possesses several advantages over other
+methods: 10 c.c. of urine are diluted with 60 c.c. of distilled water.
+To this is added 2 c.c. of pure 70 percent. nitric acid and 15 c.c. of
+a standard solution of silver nitrate (1 c.c. = 0.01 gramme NaCl).
+Shake well and make up to 100 c.c. with water. All the chlorine
+present will now be precipitated in the liquid as a silver salt.
+Filter an aliquot part (about 70 or 80 c.c.), and determine in the
+clear solution the excess of silver with standard ammonic thiocyanate,
+using the ferric alum indicator. The difference between this and the
+amount of silver originally present in the aliquot part has been
+precipitated as silver chloride (AgCl). The whole estimation should be
+conducted as rapidly as possible. A simple calculation will then give
+the proportion of chlorine in the dilute urine, and this multiplied by
+ten shows the percentage. It is usual to report in terms of NaCl.</p>
+
+<h3>PHOSPHATES.</h3>
+
+<p>In those cases where the pharmacist is asked to determine phosphoric
+acid quantitatively, the uranic-acetate method described in Sutton's
+&quot;Volumetric Analysis&quot; yields the most satisfactory results. The
+process requires some little experience to use it with ease, and is
+too lengthy for quotation here.</p>
+
+<h3>MICROSCOPICAL EXAMINATION.</h3>
+
+<p>A good microscope is one of the first necessaries of the urinary
+analyst. By its aid it is possible to distinguish easily many solid
+constituents of urine&mdash;normal and pathological; indeed, the
+examination of urinary deposits is often quite as important as the
+more elaborate wet analysis. A well-made instrument is no luxury to
+the pharmacist; but even those whose chief aim is <i>bon marché</i> can
+procure capital students' microscopes at exceedingly low cost. One of
+the cheapest, and at the same time an instrument of good quality, is
+the &quot;Star,&quot; manufactured by Messrs. R. &amp; J. Beck, of 31 Cornhill, E.C.</p>
+
+<p>Equipped with a good microscope, the analyst should obtain a fair
+supply of typical slides for comparison. The following selection will
+be found sufficient for his purpose: A set of the chief varieties of
+uric acid, calcic oxalate, and triple phosphate; the urates and
+oxalurates; urea nitrate, calcic hippurate and carbonate, hippuric
+acid, cystin, well mounted &quot;casts&quot; of the <i>tubili uriniferi</i>,
+spermatozoa, etc. In doubtful cases microchemical reagents can be
+employed, using Professor Attfield's &quot;Chemistry&quot; as a guide. Where
+mounted objects are not at hand, reference may be made to the
+capitally executed plates in that work. After obtaining a little
+experience in the use of the microscope, no difficulty will be met
+with in these examinations.&mdash;<i>The Chemist and Druggist.</i></p>
+
+<hr />
+
+<h2><a name="art10" id="art10"></a>LIQUID AND GASEOUS RINGS.</h2>
+
+<p>All who have learned a little of chemistry doubtless remember the
+experiment with vortex rings produced by phosphorus trihydride mixed
+with a little phosphide of hydrogen. As this curious phenomenon
+evidently does not depend upon the peculiar properties of this gas, I
+have been trying for some time to reproduce it by means of tobacco
+smoke, and even with chemical precipitates, which are, in a way,
+liquid smoke. After a few tentatives made at different times, my
+experiment succeeded perfectly. The following is, in brief, the mode
+of operating:</p>
+
+<p>Take up a little hydrochloric acid in a pipette and put a few drops of
+it into a very dilute solution of nitrate of mercury, and you will
+obtain rings of mercurial chloride that will, in their descent, take
+on the same whirling motion that characterizes the aureolas of
+phosphureted hydrogen.</p>
+
+<p>The drops of acid should be allowed to fall slowly, and from a feeble
+height, to the surface of the liquid contained in the vessel. It is
+unnecessary to say that the result may be obtained through the use of
+other solutions, provided that a precipitate is produced that is not
+very thick, for in the latter case the rings do not form. If need be,
+we may have recourse to milk, and carefully pour a few drops of it
+into a glass of water.</p>
+
+<div class="figcenter">
+<img src="./images/10a.png" width="519" height="400" alt="Fig. 1.&mdash;PRODUCTION OF SMOKE RINGS." title="" />
+<span class="caption"><br />Fig. 1.&mdash;PRODUCTION OF SMOKE RINGS.</span>
+</div>
+
+<p>As regards smoke rings, it is easy to produce these by puffing cigar
+smoke through a tube (Fig. 1). But, in order to insure success, a few
+precautions are necessary. The least current of air must be avoided,
+and this requires the closing of the windows and doors. Moreover, in
+order to interrupt the ascending currents that are formed in proximity
+to the body, the operation should be performed over a table, as shown
+in the figure. The rings that pass beyond the table are not
+perceptibly influenced by currents of hot air. A tube &frac34; inch in
+diameter, made by rolling up a sheet of common letter paper, suffices
+for making very beautiful rings of one inch or more in diameter. In
+order to observe the rings well, it is well to project them toward the
+darkest part of the room, or toward the black table, if the operator
+is seated. The first puffs will not produce any rings if the tube has
+not previously been filled with smoke. The whirling motion is
+perfectly visible on the exit of the ring from the tube, and even far
+beyond.</p>
+
+<div class="figcenter">
+<img src="./images/10b.png" width="600" height="201" alt="Figs. 2, 3, and 4.&mdash;VARIOUS ASPECTS OF SMOKE RINGS." title="" />
+<span class="caption"><br />Figs. 2, 3, and 4.&mdash;VARIOUS ASPECTS OF SMOKE RINGS.</span>
+</div>
+
+<p>As for the aspect of the rings projected with more or less velocity
+to different distances from the tube, Figs. 2, 3, and 4 give quite a
+clear idea of that. Figs. 3 and 6 show the mode of destruction of the
+rings when the air is still. There are always filaments of smoke that
+fall after being preceded by a sort of cup. These capricious forms of
+smoke, in spreading through a calm atmosphere, are especially very
+apparent when the rays of the sun enter the room. Very similar ones
+may be obtained in a liquid whose transparency is interfered with by
+producing a precipitate or rings in it.&mdash;<i>La Nature.</i></p>
+
+<div class="figcenter">
+<img src="./images/10c.png" width="536" height="400" alt="Figs. 5 and 6..&mdash;SMOKE RINGS BREAKING UP." title="" />
+<span class="caption"><br />Figs. 5 and 6..&mdash;SMOKE RINGS BREAKING UP.</span>
+</div>
+
+<hr />
+
+<h2><a name="art12" id="art12"></a>SHALL WE HAVE A NATIONAL HORSE?</h2>
+
+<p><i>To the Editor of</i> <span class="smcap">Scientific American Supplement:</span></p>
+
+<p>In your issue for August 13 is &quot;A Proposition for a Government
+Breeding Farm for Cavalry Horses,&quot; by Lieutenant S.C. Robertson
+U.S.A., First Cavalry. The article is national in conception, deep in
+careful thought, which only gift, with practical experience with
+ability, could so ably put before the people. As a business
+proposition, it is creditable to an officer in the United States army.</p>
+
+<p>The husbandman and agriculturist, also the navy and scientific
+explorations, each in turn present their wants before the government
+for help in some way, and receive assistance. The seaman wants new and
+improved or better ships, and the navy gets them; but the poor
+cavalryman must put up with any kind of a craft he can get; the horse
+is the cavalryman's ship&mdash;war vessel on land.</p>
+
+<p>The appeal of Lieut. Robertson to our government for better horses is
+reasonable; and he tries to help the government with a carefully
+studied business proposition through which to enable our government to
+grant the supplication of the army. That Lieut. Robertson loves a
+horse, and knows what a good one is, no man can dispute who has read
+his article; but as to how it can best be produced, he does not know.
+While I for one applaud both his article and his earnestness, with
+your permission I will make some suggestions as to the breeding side
+of his proposition. The business portion will, of course, come under
+the ordnance department in any event.</p>
+
+<p>As for a government breeding establishment for any kind of livestock
+in this great agricultural country, I feel that such would be at
+variance with the interests of husbandry in America.</p>
+
+<p>The breeding of horses is particularly an important branch of
+agriculture, and the farmers should be assisted by the government in
+the improvement of their horses, until they are raised to a standard
+which in case of emergency could supply the army at a moment's notice
+with the best horses in the world at the least possible expense.</p>
+
+<p>Our government Agricultural Bureau is constantly spending thousands of
+dollars to help the agriculturist in matter of better and greater
+varieties of improved seeds and the better way for cultivation. Now,
+the seed of animal life is as important as in vegetable life to the
+interest and welfare of the husbandman, which also means the
+government. For the government to become a monopolist of any important
+branch in agriculture is not in harmony with the principles of our
+republican-democratic form of government. While advocating a
+protective tariff against outside depreciation of home industries, our
+government should not in any way approach monarchical intrusion upon
+the industries of its husbandmen. Our government cannot afford to make
+its agriculturists competitors in so important a matter to them (the
+farmers) as in the raising of horses; but the government can see to it
+that the husbandman has a standard for excellence in the breeding of
+horses which shall be recognized as a national standard the civilized
+world over. Then, by that standard, and through our superior
+advantages <a name="Page_9761" id="Page_9761"></a>over any other civilized nation in the vast extent of
+cheap and good grass lands, with abundance of pure water, and with all
+temperatures of climate, we can grow, as a people, the best horses in
+the world, to be known as the National Horse of America. Our
+government must have a blood standard for the breeding of horses, by
+which our horses can be bred and raised true to a type, able to
+reproduce itself in any country to which we may export them; and the
+types can be several, as our territory is so great and demands so
+varied, but blood and breeding must be the standard for each type. Our
+fancy breeders have a standard now, called a &quot;time standard,&quot; which is
+purely a gambling standard, demoralizing in all its tendencies to both
+man and beast. With this the government need have nothing to do, for
+it will die out of itself as the masses learn more of it, and
+especially would it cease to be, once the government established a
+<i>blood</i> standard for the breeding of all horses, and particularly a
+National Horse.</p>
+
+<p>When the cereal crops of our country are light, or the prices fall
+below profitable production, the farmer has always a colt or two to
+sell, thus helping him through the year. In place of constantly
+importing horses from France, England, and Scotland, where they are
+raised mostly in paddocks, and paying out annually millions of
+dollars, it is our duty to be exporting.</p>
+
+<p>As an American I am ashamed when I see paraded at our county or state
+fairs stallions and mares wearing the &quot;blue ribbon&quot; of
+superexcellence, with boastful exclamation by the owner of &quot;a
+thoroughbred imported Percheron, or a thoroughbred imported French
+coacher, or a thoroughbred imported Scotch Clyde, or a thoroughbred
+imported English coacher, or a thoroughbred imported English Shire, or
+a thoroughbred imported English Cleveland Bay!&quot;</p>
+
+<p>The American farmer and his boys look on aghast at the majesty and
+beauty of these prize winners over our big-headed, crowbar-necked,
+limp-tailed, peeked-quartered horses called &quot;standard bred!&quot; What
+standard? &quot;Time standard,&quot; as created by a man who is neither a
+horseman nor a breeder; but because of the lack of intelligent
+information and want of courage upon the part of a few, this man's
+<i>ipse dixit</i> has become law for the American breeders until such time
+as cultured intelligence shall cause them to rebel. It soon will.</p>
+
+<p>It is indeed time for the government to step in and regulate our horse
+breeding. Of all the national industries there is none of more
+importance than that of horses. More so in America than in any other
+country, because our facilities are greater, and results can be
+greater under proper regulation. Lieut. Robertson has proved to be the
+right man in the right place, to open the door for glorious results to
+our nation. No one man or a small body of men can regulate this
+horse-breeding industry, but as in France, Russia, and England, the
+government must place its hand and voice.</p>
+
+<p>We are indeed an infant country, but have grown to an age where
+parental restraint must be used now, if ever. We have millions of
+farmers in America, breeding annually millions of horses; and except
+we have another internal war, our horses will soon become a burden and
+a pest.</p>
+
+<p>There are numbers of rich men throughout the country breeding fancy
+horses, for sport and speculation, but they only add to the increasing
+burden of useless animals, except for gambling purposes; for they are
+neither work horses, coach horses, nor saddle horses. Our farmers of
+the land are the breeders, as our recent war of the rebellion
+testified. The war of 1812, the Mexican war of 1847, and the war of
+1861 each called for horses at a moment's notice, and our farmers
+supplied them, destroying foundation bloods for recuperation. From
+1861 to 1863 the noble patriotism of our farmers caused them to vie
+with each other as to who should give the best and least money to help
+the government; and cannot our government now do something for the
+strength and sinew of the land, the farmers?</p>
+
+<p>I was dealing in horses, more or less, from 1861 to 1863 (as I had
+been before and long after), and many was the magnificent horse I saw
+led out by the farmer for the government, at a minimum price, when,
+previous to 1861, $400, $500, and even $600 was refused for the same
+animals. Horses that would prove a headlight to any gentleman's coach
+in the city, and others that would trot off fourteen to sixteen miles
+an hour on the road as easy as they would eat their oats, went into
+the cavalry or artillery or to baggage trains. What were left for
+recuperation at the close of the war were mongrels from Canada or the
+Indian and wild lands of the West, and such other lazy brutes as our
+good farmers would not impose upon the government with or later were
+condemned by the army buyers. These were largely of the Abdallah type
+of horse, noted for coarseness, homeliness, also soft and lazy
+constitutions. No one disputes the brute homeliness of the Abdallah
+horse, and in this the old and trite saying of &quot;Like begets like&quot; is
+exemplified in descendants, with which our country is flooded. The
+speed element of which we boast was left in our mares of Arabian blood
+through Clay and Morgan, but was so limited in numbers as to be an
+apology for our present time standard in the breeding of fancy horses.
+Knowing that Abdallah blood produced no speed, and being largely
+ignorant as to the breeding of our mares, which were greatly scattered
+over the land after the war, some kind of a guess had to be made as to
+the possibility of the colts we were breeding, hence the time standard
+fallacy. But it has ruined enough men, and gone far enough.</p>
+
+<p>Upon Lieutenant Robertson's proposition, a turn can be made, and a
+solid base for blood with breeding of all American horses can be
+demanded by the government for the country's good.</p>
+
+<p>From the earliest history of man, as a people increased in wealth,
+they gave attention to mental culture with refinement; following which
+the horse was cultivated to a high <i>blood</i> standard with national
+pride. From the Egyptians, the Moors, the Romans, and Britons to
+France, Russia, and Prussia we look, finding the horse by each nation
+had been a national pride&mdash;each nation resorting to the same primitive
+blood from which to create its type, and that primitive was the
+Arabian. Scientists have theorized, men have written, and boys have
+imagined in print, as to some other than the Arabian from which to
+create a type of horse, and yet through all ages we find that Arabian
+has been the one stepping stone for each advanced nation upon which
+blood to build its national horse.</p>
+
+<p>Scientists have reasoned and explored, trying to prove to the
+contrary, but what have they proved? The Arabian horse still remains
+the fact.</p>
+
+<p>The lion, the tiger, the leopard, still remain the same, as does the
+ass and the zebra. As God created and man named them, with all animal
+life, subject to the will of man, so do they all continue to remain
+and reproduce, each true to its type, free from imperfections or
+disease; also the same in vegetable and mineral life. In animal life,
+the build, form, color, size, and instincts remain the same, true to
+its blood from the first, and yet all was created for man through
+which to amuse him and make him work.</p>
+
+<p>It is a fact that all of man's creations from any primitive life,
+either animal or vegetable, will degenerate and cease to be, while of
+God's perfect creations, all continue the same.</p>
+
+<p>We will condense on the horse. The Arabian is the most pliable in its
+blood of any other known to man. From it, any other type can be
+created. Once a type has been created, it must be sustained in itself
+by close breeding, which can be continued for quite a number of years
+without degeneracy. For invigoration or revitalizing, resort must be
+made to its primitive blood cause. To go out of the family to colder
+or even warmer creations of man means greater mongrelization of both
+blood and instinct, also to invite new diseases.</p>
+
+<p>Nothing is more infatuating than the breeding of horses. A gifted
+practical student in the laws of animal life may create a new and
+fixed type of horse, but it can be as quickly destroyed by the
+multitude, through ignorant mongrelization.</p>
+
+<p>In the breeding of horses, our people are wild; and in no industry can
+our government do more good than in making laws relating to their
+breeding. It can father the production of a national horse without
+owning a breeding farm. It can make <i>blood</i> and <i>breeding</i> a standard
+for different types, and see to it that its laws are obeyed, thus
+benefiting all the agriculturists, and have breeding farms in America;
+and also itself as a government, financially. We must not however
+begin upon the creation of other nations, but independently upon God's
+gift to man, as did England, France, and Russia. That a government
+should interfere in the breeding of horses is no new thing. The Arabs
+of the desert boast to this day of King Solomon's stud of horses; but
+in each and every instance where a nation has regulated and encouraged
+the breeding of the horse to a high standard of excellence, they have
+all begun at the primitive, or Arabian. Thus England in boasting of
+her thoroughbred race horse admits it to be of Arabian origin. Russia
+in boasting of her Orloff trotting and saddle horse tells you it is of
+Arabian origin. France boldly informs you that her Percheron is but an
+enlarged Arabian, and offers annual special premiums to such as
+revitalize it with fresh Arabian blood.</p>
+
+<p>After the war of 1812 our forefathers imported many Arabian stallions
+to recuperate the blood of their remnants in horses. From 1830 such
+prominent men as Andrew Jackson and Henry Clay said all they could by
+private letter and public speech to encourage the importation of and
+breeding freely to the Arabian horse, and specially did the State of
+Kentucky follow the advice of Henry Clay, so that from 1830 up to 1857
+Kentucky had more Arabian stallions in her little district than the
+combined States of the Union. Kentucky has had a prestige in her mares
+since the war, and it comes in the larger amount of Arabian blood
+influence she has had in them, than could be found elsewhere. Kentucky
+is shut in, as it were, and retaining her mares largely impregnated
+with Arabian blood, all that was necessary for them to do was to get
+trotting-bred stallions from New York State, then eclipse all other
+States in the produce. While I cheerfully award to Kentucky all credit
+due to it, I am not willing that Lieut. Robertson should make his base
+for government breeding establishment sectional, nor would I submit to
+England through Kentucky. I am too American for that.</p>
+
+<p>For cavalry purposes, the Prussian horse is the best in the world, and
+is also Arabian in its closest foundation.</p>
+
+<p>To get at this blood question more definitely, let us inquire into
+these different recognized self-producing national types of horses
+abroad.</p>
+
+<p>First is the English thoroughbred race horse, which is simply an
+improved Arab. The functions of this English national horse are but
+twofold&mdash;to run races and to beget himself, after which he ceases to
+be of value. He is not a producer of any other type of value; to breed
+him out of his family is mongrelism and degeneracy, so we don't want
+him, even though we could humiliate our American pride through our
+loved State of Kentucky.</p>
+
+<p>Count Orloff of Russia was a great horseman, exceedingly fond of
+horseback riding independent of the chase. He tried in 1800 to breed a
+satisfactory horse from the English thoroughbred race horse, but went
+from bad to worse until he resorted to the ever-pliant blood of the
+Arabian. He sent to Egypt and secured a thoroughbred Arabian stallion,
+paying $8,000 for him (in our money). This horse he bred to Danish
+mares, largely of Arabian blood, and created a very stout, short-backed
+horse, standing from 15&frac12; to 15&frac34; and 16 hands high, of great trotting
+speed, also able to run to weight, and with good disposition, which
+the English thoroughbred did not have. This type he continued to
+close-breed, going back to the Arabian for renewed stoutness. At his
+death, his estates passed to his daughter, who continued her father's
+breedings until the Russian government purchased the entire
+collection, about 1846, since when the Russian government Orloff
+trotting and saddle horse has become famous the world over as a
+first-class saddle, cavalry, stage coach, and trotting horse combined.
+They are broken at three years of age, and scarce any that cannot beat
+2:30 at trotting speed, and from that down to 2:15 in their crude way
+of hitching and driving. This is something for American breeders to
+think very interestedly upon.</p>
+
+<p>France wanted heavy draught horses, also proud coach horses; so rather
+than go to any competing nation for their created types, her
+enterprising subjects took the same Arabian blood, and from it created
+the beautiful Percheron, also French coach horses, so greatly valued
+and admired the world over, and which the gifted and immortal Rosa
+Bonheur has so happily reproduced upon canvas. Can America show any
+kind of a horse to tempt her brush?</p>
+
+<p>With regard to a foundation for a government or national horse, I am
+certain so gifted and able United States officer as Mr. S.C. Robertson
+did not know that it was unnecessary to go to England for the blood of
+their national horse, even though we smuggled it through Kentucky or
+any other of our States. Again, it would be impossible to produce any
+type of a horse from the English thoroughbred, except a dunghill, and
+Mr. Robertson would not have his government breed national dunghills!</p>
+
+<p>I love England as our mother country, but am an American, born and
+dyed in the wool to our independence, from the &quot;Declaration.&quot;</p>
+
+<p>Now let us see what England says of her thoroughbred: &quot;He is no longer
+to be relied upon for fulfilling his twofold functions as a racer and
+reproducer of himself. He is degenerating in stoutness and speed. As a
+sire he has acquired faults of constitution and temper which, while
+leaving him the best we have, is not the best we should aspire to
+have. His stoutness and speed are distinctly Arabian qualities, to
+which we must resort for fresh and pure blood.&quot; We have shown that the
+Englishman says &quot;his thoroughbred is full of radical and growing
+defects in wind, tendons, feet, and temper, and that his twofold
+functions are to run races and reproduce himself, which are the end of
+his purpose.&quot; Does our government want breeding farms upon which to
+nurse these admitted &quot;defects,&quot; including the &quot;confirmed roarer,&quot; for
+cavalry horses? I quote again: &quot;Those who have had most to do with him
+are ready to admit that he no longer possesses the soundness,
+stoutness, speed, courage, and beauty he inherited from his Arabian
+parentage. As a sire for half-bred stock, he may do for those who will
+use him, but we must resort to the Arabian if we would revitalize and
+sustain our thoroughbred race horse.&quot;</p>
+
+<p>In the face of these statements, in print abroad, would Lieut.
+Robertson make the base for our proposed national horse that of the
+English thoroughbred, scattering the weeds from such imperfect
+breedings among the farmers of our land?</p>
+
+<p>I am writing as an old horseman and breeder, and not as a newspaper
+man or young enthusiast, although the enthusiasm of youth is still in
+me, for which I am thankful.</p>
+
+<p>This question of horse breeding I have been deeply interested in for
+forty years past. Let me quote to the reader from one of many letters
+I have received from Sir Wilfrid Seawen Blunt during the past seven
+years. His practical knowledge of the English thoroughbred race horse
+and his blood cause, the Arabian, is the equal if not superior to any
+other one man of this present age.</p>
+
+<p>With his wife, Lady Anne, he dwelt with the different tribes of the
+desert, studying the Arabs as a people, in their customs and habits,
+also traditions with beliefs. In matter of their horses, Mr. Blunt
+made a special study, while Lady Anne put her diaries in book form
+after her return, and which book should be owned by every cultured and
+educated lady in America. After spending a year in Arabia, traveling
+both sides of the Euphrates and through Mesopotamia, as no other
+Anglo-Saxons have been known to do, living with the different Bedouin
+tribes of the desert as they lived, Mr. Blunt and his wife, Lady Anne,
+came out with sixteen of the choicest bred mares to be found, also two
+stallions, the mares mostly with foal. These were placed upon their
+estates, &quot;Crabbet Park,&quot; to continue inbreeding as upon the desert,
+pure to its blood. As this question in itself will make a long and
+interesting article, I will avoid it at present, quoting to the reader
+from one of my old letters:</p>
+
+<div class="note">
+<p>&quot;CRABBET PARK, SUSSEX, ENGLAND.</p>
+
+<p>&quot;Dear Sir: Political matters have prevented an earlier reply to
+    your last.</p>
+
+<p>&quot;I am well satisfied with my present results, and shall not
+    abandon what I have undertaken. The practical merits of Arabian
+    blood are well understood by us.</p>
+
+<p>&quot;Our sale of young stock maintains itself in good prices in
+    spite of bad times; indeed, my average within the past two years
+    has risen from £84 to £102 on the pure-breds sold as yearlings,
+    and we receive the most flattering and satisfactory accounts
+    from purchasers, although it is known that I retain the best of
+    each year's produce, and so have greatly improved my breeding
+    stock.</p>
+
+<p>&quot;You speak of the opinions of the press as against you. The
+    sporting press are not breeders, but are the mouthpiece of
+    prejudices. We have had them somewhat against us, but they now
+    view things in more friendly tone.</p>
+
+<p>&quot;For immediate use in running races (in which the sporting press
+    are chiefly interested), the Arabian in his undeveloped state
+    and under size will not compete with the English race horse.
+    This fact has caused racing men to doubt his other many and more
+    important merits; indeed, it is only those who have had personal
+    experience of him that as yet acknowledge them.</p>
+
+<p>&quot;The strong points in the Arabian are many:</p>
+
+<p>&quot;<i>First</i>, his undoubted soundness in constitution, in <i>wind</i>,
+    <i>limb</i>, and <i>feet</i>. It will be noticed that the Englishman must
+    have soundness in wind, limb, and feet, showing that their
+    thoroughbred is the thorn in that particular. The Arabian has
+    also wonderful intelligence, great beauty, and good disposition,
+    with an almost affectionate desire to adapt himself to your
+    wishes.</p>
+
+<p>&quot;In breeding, I have found the pure-breds delicate during the
+    first few weeks after birth, and have lost a good many,
+    especially those foaled early in the year; yet it is a
+    remarkable fact that during the eight years of my breeding them,
+    I have had no serious illness in the stables; once over the
+    dangerous age, they seem to have excellent constitutions, and
+    are always sound in <i>wind</i>, <i>limb</i>, and <i>feet</i>.</p>
+
+<p>&quot;<i>Second</i>, they are nearly all good natural and <i>fast walkers</i>,
+    also fast trotters; and from the soundness of their feet are
+    especially fitted for fast road work, being able to do almost
+    any number of miles without fatigue.</p>
+
+<p>&quot;<i>Third</i>, they are nearly all good natural jumpers, and I have
+    not had a single instance of a colt that would not go across
+    country well to hounds.</p>
+
+<p>&quot;They are very bold fencers, requiring neither whip nor spur.
+    They carry weight well, making bold and easy jumps where other
+    larger horses fail.</p>
+
+<p>&quot;<i>Fourth</i>, they have naturally good mouths, and good tempers,
+    with free and easy paces; so that one <a name="Page_9762" id="Page_9762"></a>who has accustomed
+    himself to riding a pure-bred Arabian will hardly go back, if he
+    can help it, to any other sort of horse.</p>
+
+<p>&quot;There is all the difference in riding the Arabian and the
+    ordinary English hunter or half-bred that there is in riding in
+    a well-hung gig or a cart without springs.</p>
+
+<p>&quot;<i>Fifth.</i> As sires for half-bred stock, the Arabian may not be
+    better than a <i>first-class</i> English thoroughbred, but is
+    certainly better than a <i>second</i>-class one, and <i>first</i>-class
+    sires are out of the reach of all ordinary breeders; for that
+    reason I recommend a fair trial of his quality, confident your
+    breeders will not be disappointed.</p>
+
+<p>&quot;With good young mares who require a horse to give their
+    offspring quality, that is to say, beauty, with courage and
+    stoutness, and with a turn of speed for fast road work, the
+    Arabian is better than any class of English thoroughbreds that
+    are used for cross breeding.</p>
+
+<p>&quot;I trust then for that reason you will not allow yourself to be
+    discouraged by the slowness of the people to appreciate all the
+    merits of the Arabian at once.</p>
+
+<p>&quot;Our breeders are full of prejudices, and only experience can
+    teach them the value of things outside their own circle of
+    knowledge.</p>
+
+<p>&quot;I have no doubt whatever that truth will in the end prevail;
+    but you must have patience. Remember that a public is always
+    impatient, and most often unreasonably so.</p>
+
+<p>&quot;My stud I keep at a permanent strength of twelve brood mares,
+    and as many fillies growing in reserve.</p>
+
+<p>&quot;You ask me regarding the <i>pacing</i> gait. I have seen it in the
+    pure-bred Arabs on the desert; and in many parts of the East it
+    is cultivated, notably in Asia Minor and Barbary. The walk,
+    pace, amble, trot, and run are found in the Arabian, and either
+    can be cultivated as a specialty.</p>
+
+<p>&quot;If you think any of my letters to you are of general value to
+    your people, I am quite willing you should so use them.</p>
+
+<p>&quot;I am, very truly yours,</p>
+
+<p class="signature">&quot;WILFRID SCAWEN BLUNT.</p>
+
+<p>&quot;To RANDOLPH HUNTINGTON, Rochester, N.Y.&quot;</p>
+</div>
+
+<p>My experience with Arabian blood the past seven years justifies all
+that Mr. Blunt has predicted to me from time to time. So also do old
+letters by Andrew Jackson and Henry Clay hold out the same inducements
+to the breeders of Kentucky and Tennessee in their day.</p>
+
+<p>From my long years of experience in all classes of horses, I am frank
+to say to-day that I would not be without a thoroughbred Arabian
+stallion on my place, and journalists who inform their readers that
+they &quot;are liable to splints, ringbones, and spavins,&quot; give themselves
+away to all intelligent readers and breeders as exceedingly
+superficial in matter of horses; for ringbones and spavins are
+positively unknown among the Arabs. The way to get rid of such
+imperfections in our mongrel breed of horses is to fill them up with
+pure Arab blood.</p>
+
+<p>Such paper men also talk about &quot;<i>fresh Diomed</i>&quot; and &quot;fresh Messenger
+blood,&quot; as though there had been a drop of it in never so diluted form
+for any influence these many years, of course forgetting that <i>Diomed</i>
+was a very strongly <i>inbred Arabian</i> horse. He came to this country
+when 21 years old.</p>
+
+<p>He was foaled 1777, and arrived in Virginia in 1798. From his old age
+and rough voyage in an old-fashioned ship, it required nearly a year
+to recuperate from the journey, and was 23 years old before he could
+do stud service to any extent. Then, at no time to his death was he a
+sure foal getter, even to a few mares. He died in 1808, thirty-one
+years old, long enfeebled and unfit for service.</p>
+
+<p>Between 1808 and 1887 is quite a period of time, during which we have
+had four different wars, beginning with 1812, and how much Diomed
+blood does the reader suppose there is in this country? Yet I take up
+daily and weekly papers devoted to horse articles, extolling the value
+of <i>Diomed</i> blood as cause for excellence in some young horse. Are we
+a nation of idiots to be influenced by such nonsense?</p>
+
+<p>I wish there was fresh Diomed blood; thus the public would know what
+Arab blood had done for England. So I can say of imported Messenger.
+What our breeders want is good, solid information in print, and not
+the; dreamings of some professional writer for money. For myself, I am
+on the downhill side of life, but so long as I can help the young by
+pen or example, I shall try.</p>
+
+<p class="signature">RANDOLPH HUNTINGTON.</p>
+
+<p>Rochester, N.Y.</p>
+
+<hr />
+
+<h2><a name="art11" id="art11"></a>SCENES AMONG THE EXTINCT VOLCANOES OF RHINELAND.</h2>
+
+<p>In the province of the Rhine there is a range of mountains, including
+several extinct volcanoes, which offer grand and beautiful scenery and
+every opportunity for geological study, leading the mind back to the
+early ages of the earth.</p>
+
+<p>Let us take an imaginary trip through this region, starting on our
+wanderings from the Rhine, where it breaks through the vine-clad slate
+mountains of the Westerwald and the Eifel. A short distance above the
+mouth of the Ahr we leave its banks, turning to the west, and entering
+the mountains at the village of Nieder Breisig. A pretty valley leads
+us up through orchards and meadows. The lower hills are covered with
+vineyards and the mountains with a dense growth of bushes, so that we
+do not obtain an extended view until we reach an elevated ridge.</p>
+
+<div class="figright" style="width: 478px;">
+<img src="./images/13c.png" width="478" height="450" alt="DISTANT VIEW OF THE VOLCANIC PORTION OF THE EIFEL, TAKEN FROM THE HEIGHTS OF THE SCHNEIFEL." title="" />
+<span class="caption">DISTANT VIEW OF THE VOLCANIC PORTION OF THE EIFEL, TAKEN FROM THE HEIGHTS OF THE SCHNEIFEL.</span>
+</div>
+
+<p>The valley of the Rhine lies far below us, but the glittering surface
+of the river, with the little towns, the castles and villas and the
+gardens and vineyards on its banks are still visible, while in the
+background the mountains of the Westerwald have risen above the hills
+on the river. This range stretches out into a long wooded ridge
+crowned by cone-shaped peaks of basalt. To the northwest of this lies
+Siebengebirge, with its numerous domes and pinnacles, making a grand
+picture veiled in the blue mist of distance. On the opposite side we
+have a very different view of curious dome and cone shaped summits
+surrounded by undulating plateaus or descending into deep ravines and
+gorges. It is the western part of the volcanic region of Rhineland
+which lies before us, and in the center of which is the Laachersee or
+lake of Laach. The origin of these volcanoes is not as remote as many
+suppose, but their activity must have continued for a comparatively
+long period, judging from the extent of their lava beds.</p>
+
+<div class="figcenter">
+<img src="./images/13b.png" width="568" height="450" alt="THE SHORES OF LAACHERSEE." title="" />
+<span class="caption"><br />THE SHORES OF LAACHERSEE.</span>
+</div>
+
+<p>There was a time when the sea covered the lowlands of North Germany,
+and the waves of a deep bay washed the slopes of the Siebengebirge.
+Then the bed of the Rhine lay in the highlands, which it gradually
+washed away until the surface of the river was far, far below the
+level of its old bed; and then the volcanoes poured forth their
+streams of lava over the surrounding plains.</p>
+
+<p>In the course of time the surface of the country has changed so that
+these lava beds now lie on the mountain sides overhanging the valleys
+of to-day. Some of the volcanoes sent forth melted stones and ashes
+from their summits, and streams of lava from their sides, while the
+craters of others cracked and then sank in, throwing their debris over
+the neighboring country. In the Eifel there are many such funnels
+which now contain water forming beautiful lakes (Maaren), which add
+much to the scenery of the Eifel. The Laachersee is the largest of
+these lakes. In the mean time the channel of the Rhine had been worn
+away almost to its present level, but the mountains still sent forth
+their streams of lava, which stopped brooks and filled the ravines,
+and even the Rhine itself was dammed up by the great stream from
+Fornicherkopf forming what was formerly the Neuwied. The old lava
+stream which obstructed the river is still to be seen in a towering
+wall of rock, extending close beside the road and track that follow
+the shore.</p>
+
+<div class="figcenter">
+<img src="./images/12a.png" width="600" height="396" alt="CRATER AND LAKE ON TOP OF THE MOSENBERGE." title="" />
+<span class="caption"><br />CRATER AND LAKE ON TOP OF THE MOSENBERGE.</span>
+</div>
+
+<p>After having made these observations, we descend from the height which
+afforded us the view of the Vinrt Valley. A clear brook flows through
+green meadows and variegated fields stretch along the mountain sides,
+while modest little villages are scattered among the fruit trees. On
+the other side of the valley rises the Herchenberg, an extinct
+volcano. As we climb its sides we see traces of the former
+devastation. Loose ashes cover the ground, bits of mica glittering in
+the sun, and on the summit we find enormous masses of stone which were
+melted and then baked together. In the center lies the old crater, a
+quiet, barren place bearing very little vegetation, but from its wall
+an <a name="Page_9763" id="Page_9763"></a>excellent view of the surrounding country can be obtained. Not far
+from this mountain lies the mighty Bausenberg, with its immense, well
+preserved crater, only one side of which has been broken away, and
+which is covered with a thick growth of bushes. The ledges of this
+mountain are full of interest for the mineralogist. Nearer to Lake
+Laach are the Wahnenkopfe, the proud Veitskopf, and other cone-shaped
+peaks. To these we direct our steps, and after a long tramp over the
+rolling, cultivated plateau, we climb the wood-covered sides of the
+great basin in whose depths the Laachersee lies. From the shore of
+this lake rise the high volcanic peaks which tower above all the other
+mountains.</p>
+
+<div class="figcenter">
+<img src="./images/12d.png" width="469" height="450" alt="LAKE GEMUNDEN." title="" />
+<span class="caption"><br />LAKE GEMUNDEN.</span>
+</div>
+
+<p>Tired from our climb through the ashes, which are heated by the sun,
+we rest in the shade of a beech-wood, looking through the leaves into
+the valley below us, with the old cloisters and the high Roman church
+which the monks once built on the banks of the lake.</p>
+
+<div class="figcenter">
+<img src="./images/13a.png" width="503" height="450" alt="THE CRATER OF THE HERCHENBERGES." title="" />
+<span class="caption"><br />THE CRATER OF THE HERCHENBERGES.</span>
+</div>
+
+<p>To the south of the lake rise other volcanoes, lying on the border of
+the fertile Maifeld, which gradually descends to the valley of
+Neuwied. Here, at the southern declivity of the group of volcanoes
+which surrounds the Laachersee, remarkably large streams of lava were
+ejected, covering the surface of the plateau with a thick layer. The
+largest of these streams is that from the Niedermendig, which consists
+of porous masses of nepheline lava. In the time of the Romans
+millstones were made from this mass of rock, and the industry is
+carried on now on a larger scale. It is a strange sight which meets
+one's eyes when, after descending through narrow passages, he finds
+himself in large, dark halls, from which the stone has been cut away,
+and in which there are well-like shafts. The stones are raised through
+these shafts by means of gigantic cranes and engines. Because of the
+rapid evaporation of the water in the porous stone, these vaults are
+always cool, winter and summer, and therefore they are used by several
+brewers as storehouses for their beer, which owes its fame to these
+underground halls.</p>
+
+<div class="figcenter">
+<img src="./images/13d.png" width="600" height="326" alt="THE MILLSTONE GALLERIES IN THE LAVA BEDS OF NIEDERMENDIG." title="" />
+<span class="caption"><br />THE MILLSTONE GALLERIES IN THE LAVA BEDS OF NIEDERMENDIG.</span>
+</div>
+
+<div class="figcenter">
+<img src="./images/13f.png" width="488" height="450" alt="ON THE LAVA BEDS OF NIEDERMENDIG." title="" />
+<span class="caption"><br />ON THE LAVA BEDS OF NIEDERMENDIG.</span>
+</div>
+
+<p>Although the traces of former volcanic action are evident to the
+student of nature, the Rhine with its mild climate and luxuriant
+vegetation has covered many marks of the former chaotic state of the
+land. Very little of this beauty is seen on the higher and,
+therefore, more severe and barren mountains of the Western Eifel,
+through which a volcanic fissure runs from the foot of the high
+unhospitable Schneifel to Bertrich Baths, near the Moselle. From the
+ridge of the Schneifel the traveler from the north has his first
+glimpse of the still distant system of volcanoes. The most beautiful
+part of this portion of the Eifel is in the neighborhood of Dann and
+Manderscheid. Near the former rises a barren mountain with a long
+ridge, on each side of which is a deep basin. These are sunken
+craters, which now contain lakes, and near these two there is a third,
+larger lake, the Maar von Schalkemehren, on the cultivated banks of
+which we find a little village. The middle one, the Weinfelder Maar,
+is the most interesting for geologists, for there seems to have been
+scarcely any change here since the time of the eruption. On the other
+side of the mountain lies the Gremundener Maar, the shores of which
+are not barren and waste land, like those of the middle lake, but it
+is surrounded by a dark wreath of woods whose tops are mirrored in the
+crystal water. Farther to the south, near the villages of Gillenfeld
+and Meerfeld, there are more lakes.</p>
+
+<div class="figcenter">
+<img src="./images/13e.png" width="600" height="371" alt="THE WEINFELDER LAKE ON THE MAUSEBERGE." title="" />
+<span class="caption"><br />THE WEINFELDER LAKE ON THE MAUSEBERGE.</span>
+</div>
+
+<div class="figcenter">
+<img src="./images/12b.png" width="600" height="358" alt="EASTERN DECLIVITY OF MOSENBERGE NEAR MANDERSCHEID." title="" />
+<span class="caption"><br />EASTERN DECLIVITY OF MOSENBERGE NEAR MANDERSCHEID.</span>
+</div>
+
+<p><a name="Page_9764" id="Page_9764"></a>The grandest picture of these ancient events is offered by the
+Mosenberg, near Manderscheid, a mighty volcano which commands an
+extensive view of the country. Two old craters lie on its double top,
+one of which has fallen in, forming a short rocky valley, but the
+other retains its original regular shape. In the circular funnel,
+whose walls consist of masses of lava stone, rests a quiet, black
+lake, that looks very mysterious to the wanderer. Only low juniper
+bushes grow near the crater, bearing witness to the barrenness of the
+land. From the foot of this mountain an immense stream of lava, as
+wide and deep as a glacier, broke forth and flowed into the valley,
+where the end of the stream is still to be seen in a high, steep wall
+of rock.</p>
+
+<div class="figright" style="width: 353px;">
+<img src="./images/12c.png" width="353" height="400" alt="THE &quot;CHEESE GROTTO&quot; AT BERTRICH BATHS." title="" />
+<span class="caption">THE &quot;CHEESE GROTTO&quot; AT BERTRICH BATHS.</span>
+</div>
+
+<p>Similar sights are met all through this western volcanic region, and
+we can consider the mineral and acid springs, which are very numerous,
+as the last traces of the former disturbances, the products of the
+decomposition of the volcanic stones buried in the earth. At Bertrich
+Baths there are hot springs which were known to the Romans, for
+numerous antiquities dating from their time have been excavated here.
+Near these springs, at Bertrich, there is a &quot;Cheese Grotto,&quot; which is
+a break through the foot of a stream of lava, the stones of which have
+not assumed the usual form of solidified columns, but have taken flat,
+round shapes which resemble the forms of cheeses.</p>
+
+<p>Now we have completed our wanderings, which required only a few days,
+although they extended over this whole volcanic region, and which end
+here on the Moselle.&mdash;<i>Ueber Land und Meer; Allgemeine Illustrirte
+Zeitung.</i></p>
+
+<div style="width: 100%">
+<hr />
+</div>
+
+<p class="center">[<span class="smcap">Nature.</span>]</p>
+
+<h2><a name="art08" id="art08"></a>THE &quot;METEOROLOGISKE INSTITUT&quot; AT UPSALA, AND CLOUD
+MEASUREMENTS.</h2>
+
+<p>The Meteorological Institute at Upsala has gained so much fame by the
+investigations on clouds which have been carried on there during the
+last few years, that a few notes on a recent visit to that
+establishment will interest many readers.</p>
+
+<p>The Institute is not a government establishment; it is entirely
+maintained by the University of Upsala. The <i>personnel</i> consists of
+Prof. Hildebrandsson, as director; M. Ekholm and one other male
+assistant, besides a lady who does the telegraphic and some of the
+computing work.</p>
+
+<p>The main building contains a commodious office, with a small library
+and living apartments for the assistant. The principal instrument room
+is a separate pavilion in the garden. Here is located Thiorell's
+meteograph, which records automatically every quarter of an hour on a
+slip of paper the height of the barometer, and the readings of the wet
+and dry thermometers. Another instrument records the direction and
+velocity of the wind.</p>
+
+<p>This meteograph of Thiorell's is a very remarkable instrument. Every
+fifteen minutes an apparatus is let loose which causes three wires to
+descend from rest till they are stopped by reaching the level of the
+mercury in the different tubes. When contact is made with the surface
+of the mercuries, an electric current passes and stops the descent of
+each wire at the proper time. The downward motion of the three wires
+has actuated three wheels, each of which carries a series of types on
+its edge, to denote successive readings of its own instrument. For
+instance, the barometer-wheel carries successive numbers for every
+five-hundredth of a millimeter&mdash;760.00, 760.05, 760.1, etc.; so that
+when the motion is stopped the uppermost type gives in figures the
+actual reading of the barometer. Then a subsidiary arrangement first
+inks the types, then prints them on a slip of paper, and finally winds
+the dipping wires up to zero again.</p>
+
+<p>An ingenious apparatus prevents the electricity from sparking when
+contact is made, so that there is no oxidation of the mercury. The
+mechanism is singularly beautiful, and it is quite fascinating to
+watch the self acting starting, stopping, inking, and printing
+arrangements.</p>
+
+<p>We could not but admire the exquisite order in which the whole
+apparatus was maintained. The sides of the various glass tubes were as
+clean as when they were new, and the surfaces of the mercuries were as
+bright as looking glasses.</p>
+
+<p>The university may well be proud that the instruments were entirely
+constructed in Stockholm by the skillful mechanic Sorrenson, though
+the cost is necessarily high. The meteograph, with the anemograph,
+cost £600, but the great advantage is that no assistant is required to
+sit up at night, and that all the figures wanted for climatic
+constants are ready tabulated without any further labor.</p>
+
+<p>But the Institute is most justly celebrated for the researches on the
+motion and heights of clouds that have been carried on of late years
+under the guidance of Prof. Hildebrandsson, with the assistance of
+Messrs. Ekholm and Hagström.</p>
+
+<p>The first studies were on the motion of clouds round cyclones and
+anticyclones; but the results are now so well known that we need not
+do more than mention them here.</p>
+
+<p>Latterly the far more difficult subjects of cloud heights and cloud
+velocities have been taken up, and as the methods employed and the
+results that have been obtained are both novel and important, we will
+describe what we saw there.</p>
+
+<p>We should remark, in the first instance, that the motion of the higher
+atmosphere is far better studied by clouds than by observations on
+mountain tops, for on the latter the results are always more or less
+influenced by the local effect of the mountain in deflecting the wind
+and forcing it upward.</p>
+
+<p>The instrument which they employ to measure the angles from which to
+deduce the height of the clouds is a peculiar form of altazimuth that
+was originally designed by Prof. Mohn, of Christiania, for measuring
+the parallax of the aurora borealis. It resembles an astronomical
+altazimuth, but instead of a telescope it carries an open tube without
+any lenses. The portion corresponding to the object glass is formed by
+thin cross wires: and that corresponding to the eye piece by a plate
+of brass, pierced in the center by a small circular hole an eighth of
+an inch in diameter. The tube of the telescope is replaced by a
+lattice of brass work, so as to diminish, as far as possible, the
+resistance of the wind. The vertical and horizontal circles are
+divided decimally, and this much facilitates the reduction of the
+readings.</p>
+
+<p>The general appearance of the instrument is well shown in the figure,
+which is engraved from a photograph I took of Mr. Ekholm while
+actually engaged in talking through a telephone to M. Hagström as to
+what portion of a cloud should be observed. The latticework tube, the
+cross wires in place of an object glass, and the vertical circle are
+very obvious, while the horizontal circle is so much end on that it
+can scarcely be recognized except by the tangent screw which is seen
+near the lower telephone.</p>
+
+<p>Two such instruments are placed at the opposite extremities of a
+suitable base. The new base at Upsala has a length of 4,272 feet; the
+old one was about half the length. The result of the change has been
+that the mean error of a single determination of the highest clouds
+has been reduced from 9 to a little more than 3 per cent. of the
+actual height. At the same time the difficulty of identifying a
+particular spot on a low cloud is considerably increased. A wire is
+laid between the two ends of the base, and each observer is provided
+with two telephones&mdash;one for speaking, the other for listening. When
+an observation is to be taken, the conversation goes on somewhat as
+follows: First observer, who takes the lead&mdash;&quot;Do you see a patch of
+cloud away down west?&quot; &quot;Yes.&quot; &quot;Can you make out a well-marked point on
+the leading edge?&quot; &quot;Yes.&quot; &quot;Well, then; now.&quot; At this signal both
+observers put down their telephones, which have hitherto engaged both
+their hands, begin to count fifteen seconds, and adjust their
+instruments to the point of cloud agreed on. At the fifteenth second
+they stop, read the various arcs, and the operation is complete.</p>
+
+<p>But when the angles have been measured the height has to be
+calculated, and also the horizontal and vertical velocities of the
+cloud by combining the position and height at two successive
+measurements at a short interval. There are already well-known
+trigonometrical formul&aelig; for calculating all these elements, if all the
+observations are good; but at Upsala they do far more. Not only are
+the observations first controlled by forming an equation to express
+the condition that the two lines of sight from either end of the base
+should meet in a point, if the angles have been correctly measured and
+all bad sets rejected; but the mean errors of the rectangular
+co-ordinates are calculated by the method of least squares.</p>
+
+<div class="figcenter">
+<img src="./images/14.png" width="600" height="406" alt="N. EKHOLM MEASURING CLOUDS." title="" />
+<span class="caption"><br />N. EKHOLM MEASURING CLOUDS.<br /><br /></span>
+<p class="longcaption">This figure shows the peculiar ocular part of the altazimuth,
+with the vertical and horizontal circles. It also shows the telephonic arrangement.</p>
+</div>
+
+<p>The whole of the calculations are combined into a series of formul&aelig;
+which are necessarily complicated, and even by using logarithms of
+addition and subtraction and one or two subsidiary tables&mdash;such as for
+log. sin²(&theta;/2) specially constructed for this work&mdash;the
+computation of each set of observations takes about twenty minutes.</p>
+
+<p>Before we describe the principal results that have been attained, it
+may be well to compare this with the other methods which have been
+used to determine the height of clouds. A great deal of time and skill
+and money have been spent at Kew in trying to perfect the photographic
+method of measuring the height of clouds. Very elaborate cloud
+cameras, or photo-nephoscopes, have been constructed, by means of
+which photographs of a cloud were taken simultaneously from both ends
+of a suitable base. The altitude and azimuth of the center of the
+plate were read off by the graduated circles which were attached to
+the cameras; and the angular measurements of any point of cloud on the
+picture were calculated by proper measurements from the known center
+of the photographic plate. When all this is done, the result ought to
+be the same as if the altitude and azimuth of the point of the cloud
+had been taken directly by an ordinary angle measuring instrument.</p>
+
+<p>It might have been thought that there would be less chance of
+mistaking the point of the cloud to be measured, if you had the
+pictures from the two ends of the base to look at leisurely than if
+you could only converse through a telephone with the observer at the
+other end of the base. But in practice it is not so. No one who has
+not seen such cloud photographs can realize the difficulty of
+identifying any point of a low cloud when seen from two stations half
+a mile or a whole mile apart, and for other reasons, which we will
+give presently, the form of a cloud is not so well defined in a
+photograph as it is to the naked eye.</p>
+
+<p>At Kew an extremely ingenious sort of projector has been devised,
+which gives graphically the required height of a cloud from two
+simultaneous photographs at opposite ends of the same base, but it is
+evident that this method is capable of none of the refinements which
+have been applied to the Upsala measures, and that the rate of
+vertical ascent or descent of a cloud could hardly be determined by
+this method. But there is a far greater defect in the photographic
+method, which at present no skill can surmount.</p>
+
+<p>We saw that the altazimuth employed at Upsala had no lenses. The
+meaning of this will be obvious to anyone who looks through an opera
+glass at a faint cloud. He will probably see nothing for want of
+contrast, and if anything of the nature of a telescope is employed,
+only well-defined cloud outlines can be seen at all. The same loss of
+light and contrast occurs with a photographic lens, and many clouds
+that can be seen in the sky are invisible on the ground glass of the
+camera. Cirrus and cirro-stratus&mdash;the very clouds we want most to
+observe&mdash;are always thin and indefined as regards their form and
+contrast against the rest of the sky, so that this defect of the
+method is the more unfortunate.</p>
+
+<p>But even when the image of a cloud is visible on the focusing glass,
+it does not follow that any image will be seen in the picture. In
+practice, thin, high white clouds against a blue sky can rarely be
+taken at all, or only under exceptional circumstances of illumination.
+The reason seems to be that there is very little light reflected at
+all from a thin wisp of cirrus, and what there is must pass through an
+atmosphere always more or less charged with floating particles of ice
+or water, besides earthy dust of all kinds. The light which is
+scattered and diffused by all these small particles is also
+concentrated on the sensitive plate by the lens, and the resulting
+negative shows a uniform dark surface for the sky without any trace of
+the cloud. What image there might have been is buried in photographic
+fog.</p>
+
+<p>In order to compare the two methods of measuring clouds, I went out
+one day last December at Upsala with Messrs. Ekholm and Hagström when
+they were measuring the height of some clouds. It was a dull
+afternoon, a low foggy stratus was driving rapidly across the sky at a
+low level, and through the general misty gloom of a northern winter
+day we could just make out some striated stripes of strato-cirrus&mdash;low
+cirro-stratus&mdash;between the openings in the lower cloud layer. The
+camera and lens that I use habitually for photographing cloud
+forms&mdash;not their angular height&mdash;was planted a few feet from the
+altazimuth with which M. Ekholm was observing, and while he was
+measuring the necessary angles I took a picture of the clouds. As
+might have been expected under the circumstances, the low dark cloud
+came out quite well, but there was not the faintest trace of the
+strato-cirrus on the negative. MM. Ekholm and Hagström, however,
+succeeded in measuring both layers of cloud, and found that the low
+stratus was floating at an altitude of about 2,000 feet high, while
+the upper strato-cirrus was driving from S. 57° W. at an altitude of
+19,653 feet, with a horizontal velocity of 81 and a downward velocity
+of 7.2 feet per second. This is a remarkable result, and shows
+conclusively the superiority of the altazimuth to the photographic
+method of measuring the heights of clouds.</p>
+
+<p>Whenever opportunity occurs, measures of clouds are taken three times
+a day at Upsala, and it may be well to glance at the principal results
+that have been obtained.</p>
+
+<p>The greatest height of any cloud which has yet been satisfactorily
+measured is only 43,800 feet, which is rather less than has usually
+been supposed; but the highest velocity, 112 miles an hour with a
+cloud at 28,000 feet, is greater than would have been expected. It may
+be interesting to note that the isobars when this high velocity was
+reported were nearly straight, and sloping toward the northwest.</p>
+
+<p>The most important result which has been obtained from all the
+numerous measures that have been made is the fact clouds are not
+distributed promiscuously at all heights in the air, but that they
+have, on the contrary, a most decided tendency to form at three
+definite levels. The mean summer level of these three stories of
+clouds at Upsala has been found to be as follows: low clouds&mdash;stratus,
+cumulus, cumulo-nimbus, 2,000-6,000 feet; middle clouds&mdash;strato-cirrus
+and cumulo-cirrus, 12,900-15,000 feet; high clouds&mdash;cirrus,
+cirro-stratus, cirro-cumulus, 20,000-27,000 feet.</p>
+
+<p>It would be premature at present to speculate on the physical
+significance of this fact, but we find the same definite layers of
+clouds in the tropics as in these high latitudes, and no future cloud
+nomenclature or cloud observations will be satisfactory which do not
+take the idea of these levels into account.</p>
+
+<p>But the refinements of the methods employed allow the diurnal
+variations both of velocity and altitude to be successfully measured.
+The velocity observations confirm the results that have been obtained
+from mountain stations&mdash;that, though the general travel of the middle
+and higher clouds is much greater than that of the surface winds, the
+diurnal variation of speed at those levels is the reverse of what
+occurs near the ground. The greatest velocity on the earth's surface
+is usually about 2 p.m.; whereas the lowest rate of the upper currents
+is about midday.</p>
+
+<p>The diurnal variation of height is remarkable, for they find at Upsala
+that the mean height of all varieties of clouds rises in the course of
+the day, and is higher between 6 and 8 in the evening than either in
+the early morning or at midday.</p>
+
+<p>Such are the principal results that have been obtained at Upsala, and
+no doubt they surpass any previous work that has been done on the
+subject. But whenever we see good results it is worth while to pause a
+moment to consider the conditions under which the work has been
+developed, and the nature and nurture of the men by whom the research
+has been conducted. Scientific research is a delicate plant, that is
+easily nipped in the bud, but which, under certain surroundings and in
+a suitable moral atmosphere, develops a vigorous growth.</p>
+
+<p>The Meteorological Institute of Upsala is an offshoot of the
+Astronomical Observatory of the university; and a university, if
+properly directed, can develop research which promises no immediate
+reward in a manner that no other body can approach.</p>
+
+<p>If you want any quantity of a particular kind of calculation, or to
+carry on the routine of any existing work in an observatory, it is
+easy to go into the labor market and engage a sufficient number of
+accurate computers, either by time or piece work, or to find an
+assistant who will make observations with the regularity of clockwork.</p>
+
+<p>But original research requires not only special natural aptitudes and
+enthusiasm to begin with, but even then will not flourish unless
+developed by encouragement and the identification of the worker with
+his work. It is rarely, except in universities, that men can be found
+for the highest original research. For there only are young students
+encouraged to come forward and interest themselves in any work for
+which they seem to have special aptitude.</p>
+
+<p>Now, this is the history of the Upsala work. Prof. <a name="Page_9765" id="Page_9765"></a>Hildebrandsson was
+attached as a young man to the meteorological department of the
+astronomical observatory, and when the study of stars and weather were
+separated, he obtained the second post in the new Meteorological
+Institute. From this his great abilities soon raised him to the
+directorship, which he now holds with so much credit to the
+university. M. Ekholm, a much younger man, has been brought up in the
+same manner. First as a student he showed such aptitude for the work
+as to be engaged as assistant; and now, as the actual observation and
+reduction of the cloud work is done by him and M. Hagström, the
+results are published under their names, so that they are thoroughly
+identified with the work.</p>
+
+<p>Upsala is the center of the intellectual life of Sweden, and there,
+rather than at Stockholm, could men be found to carry out original
+research. It redounds to the credit of the university that it has so
+steadily supported Prof. Hildebrandsson, and that he in his turn has
+utilized the social and educational system by which he is surrounded
+to bring up assistants who can co-operate with him in a great work
+that brings credit both to himself, to themselves, and to the
+institute which they all represent.</p>
+
+<p class="signature">Ralph Abercromby.</p>
+
+<hr />
+
+
+<p class="center">[Continued from <span class="smcap">Supplement</span>, No. 610, page 9744.]</p>
+
+<p class="center">[<span class="smcap">Journal Of The Society Of Chemical Industry.</span>]</p>
+
+<h2><a name="art07" id="art07"></a>NOTES OF A RECENT VISIT TO SOME OF THE PETROLEUM-PRODUCING
+TERRITORIES OF THE UNITED STATES AND CANADA.</h2>
+
+<h3>By <span class="smcap">Boverton Redwood</span>, F.I.C., F.C.S.</h3>
+
+<h3>CANADIAN PETROLEUM.</h3>
+
+<p>When I visited Canada in 1877-78, the refining of petroleum was
+principally conducted in the city of London, Ontario. At the present
+time Petrolia, Ontario, is the chief seat of the industry, and it was
+accordingly to this city that we made our way. Here we were treated
+with the greatest kindness and hospitality by Mr. John D. Noble,
+vice-president of the Petrolia Crude Oil and Tanking Co., and his
+brother, Mr. R. D'Oyley Noble, and were enabled in the short time at
+our disposal to visit typical portions of the producing territory and
+some of the principal refineries.</p>
+
+<p>The development of the Canadian petroleum industry may be said to date
+from 1857, when a well dug for water was found to yield a considerable
+quantity of petroleum; but long previously, indeed from the time of
+the earliest settlements in the county of Lamberton, in the western
+part of the province of Ontario, petroleum was known to exist in
+Canada. In 1862 productive flowing wells were drilled at Oil Springs,
+but these wells, which were comparatively shallow, quickly became
+exhausted, and the territory was deserted on the discovery in 1865 of
+oil at Petrolia, seven miles to the northward, and about 16 miles
+southwest of the outlet of Lake Huron. Recently the Oil Springs wells
+have been drilled deeper, and are now producing 10,000 to 12,000
+barrels (of 42 American gallons) per month. Petroleum has also been
+found at Bothwell, 35 miles from Oil Springs, but this district has
+ceased to yield. Quite recently a new territory has been discovered at
+Euphemia, 17 miles from Bothwell, where, at the time of our visit,
+there were four wells producing collectively 70 barrels per day. This
+territory is by some regarded as part of the Bothwell field.</p>
+
+<p>The present producing oil belt extends from Petrolia in a
+northwesterly direction, to the township of Sarnia, and in a
+southeasterly direction to Oil Springs, but in the latter direction
+there is a break of about four and a quarter miles, commencing at a
+point about two miles from Petrolia. At Oil Springs there appears to
+be a pool about two miles square. The extension of the belt then
+continues in the same direction, with another break of about nine
+miles, to the new oil field of Euphemia, the average width of the oil
+belt being about two miles. In all, about 15,000 wells are believed to
+have been drilled in the Canadian oil fields, and of these about 2,500
+are now producing, the average yield being about three quarters of a
+barrel per well per day. The aggregate production is probably about
+700,000 barrels per annum, the greater part of which is obtained in
+the Petrolia district, and the stocks were at the time of our visit
+stated to amount to from 400,000 to 450,000 barrels.</p>
+
+<p>In the Canadian oil fields the drilling contractor usually employs his
+own derrick, engine, boiler, and tools, furnishes wood and water,
+cases the well, and fixes the pump; the well owner providing the
+casing and pump, and subsequently erecting the permanent derrick.</p>
+
+<p>The wells in the Oil Springs field were formerly from 200 ft. to 300
+ft. in depth, but the oil stratum then worked became waterlogged, and
+the wells are now sunk to a depth of about 375 ft., and are cased to a
+depth of about 275 ft. to shut off the water. The contract price for
+drilling a 4&#8541; in. hole to a depth of about 375 ft. under the
+conditions mentioned is 150 dols. (£30), and the time occupied in
+drilling is usually about a week when the work is continued night and
+day. The wells in the Petrolia field have a depth of 480 ft., the
+contract price, including the cost of 100 ft. of wooden conductor,
+being 175 dols. (£35), and the time occupied in drilling being from
+six to twelve days. Pole tools are used in drilling, the poles being
+of white ash, 37 ft. in length. The derrick is about 48 ft. in height.
+An auger some 4 ft. in length, and about a foot in diameter, is used
+to bore through the earth to the bed rock, the auger being rotated by
+horse power.</p>
+
+<p>The drilling tools commonly consist of a bit, 2&frac12; ft. in length by
+4&#8541; in. in diameter, weighing about 60 lb.; a sinker bar, into which
+the bit is screwed, 30 ft. in length by 3 in. in diameter, weighing
+about 1,040 lb.; and the jars, inserted between the sinker bar and the
+poles about 6 ft. in length, and weighing 150 lb. The tools are
+suspended by a chain, which passes three times round the end of the
+walking beam and thence to the windlass, with ratchet wheel fixed on
+the walking beam, by means of which the tools are gradually lowered as
+the drilling proceeds. The cable is thus only employed in raising the
+tools from the well and lowering them into it.</p>
+
+<p>The sand pump or bailer is frequently as much as 37 ft. in length, and
+is about 4 in. in diameter. The casing (4&#8541; in diameter) costs about
+45 cents (1s. 10&frac12;d.) per foot, and the 1&frac14; in. pump, with piping, costs
+from 65 dols. (£13) to 85 dols. (£17), according to the length of
+pipe required. An ordinary square frame derrick costs, with mud sill,
+from 22 dols. (£4 8s.) to 27 dols. (£5 8s.), and the walking beam
+about 8 dols. (£1 12s.) In many cases, however, a three-pole derrick,
+which can be erected at an expense of about 10 dols. (£2), is
+employed. A 100 barrel wooden tank costs, erected, 50 dols. (£10).</p>
+
+<h3>THE CANADIAN TORPEDO.</h3>
+
+<p>The wells are torpedoed on completion with from 8 to 10 quarts of
+nitroglycerine, at a cost of 4 dols. (16s.) per quart. The torpedoes
+employed in the Canadian oil field are much smaller than those used
+for a similar purpose in the United States, the tin shell being only 6
+ft. in length by 3 in. in diameter. We were enabled to witness the
+operation of torpedoing a well, and the following particulars, based
+on notes taken at the time, may be of interest: The torpedo case,
+which was furnished with a tube or &quot;anchor&quot; at the lower end, 8 ft. in
+length, was placed in the mouth of the well and suspended so that its
+upper end was level with the surface of the ground. Eight quarts of
+nitroglycerine, which was in a tin can, was then poured into the
+torpedo case, and the torpedo was carefully lowered into the well,
+which contained at the time about 250 ft. of water, until the end of
+the anchor rested on the bottom of the well. A traveling primer or
+&quot;go-devil squib&quot; was then prepared as follows: A tin cone, 14 in. in
+length by 2 in. in diameter at the open end, was partially filled with
+sand to give it the necessary weight. A piece of double tape fuse, 2
+ft. long, was inserted into a Nobel's treble detonator, and over the
+detonator and a portion of the fuse a perforated tin tube or sheath
+was passed. This tube was then inserted through a hole in a strip of
+tin fixed across the mouth of the conical cup into the sand, so that
+the detonator was embedded. The sand was then saturated with
+nitroglycerine, the fuse lighted, and the primer dropped into the
+well. In about 45 seconds there was a perceptible tremor of the
+ground, immediately followed by a slight sound of the explosion. After
+an interval of a second or two there was a gurgling noise, and a
+magnificent black fountain shot up twice as high as the derrick, upon
+which all the spectators ran for shelter from the impending shower of
+oil and water. The well not being a flowing one, the outrush was only
+of momentary duration, and within a few minutes the drillers were at
+work removing from the well, by means of the sand pump, the fragments
+of rock which had been detached by the explosion. On the table are
+specimens of this rock, which I obtained at the time.</p>
+
+<p>The maximum yield per well is ten barrels per day, and the minimum
+yield for which it is considered profitable to pump is a quarter of a
+barrel per day. The yield being in some cases so small, it is usual to
+pump a number of wells through the agency of one engine, the various
+pumps being connected with the motor by means of wooden rods. In one
+instance I saw as many as eighty wells being thus pumped from one
+center. The motive power was a 70 h.p. engine, which communicated
+motion, similar to that of the balance wheel of a watch, to a large
+horizontal wheel. From this wheel six main rod lines radiated, the
+length of stroke of the main lines being 16 in., and the rate of
+movement 32 strokes per minute. Some of the wells being pumped from
+this center were from one-half to three-quarters of a mile distant,
+and altogether about eight miles of rods were employed in the pumping
+of the eighty wells.</p>
+
+<p>The pipe line system in Canada has not been fully developed, and
+accordingly the well owner has to convey his oil by road to the
+nearest receiving station. Thus from the Euphemia oil field the oil
+has to be &quot;teamed&quot; 17 miles, to Bothwell. For the conveyance of the
+oil by road a long and slightly conical wooden tank or barrel, resting
+horizontally on a wagon, is employed. These vessels hold from eight to
+ten barrels of oil. The Petrolia Crude Oil and Tanking Company is the
+principal transporting and storing company. The storage charge is one
+cent (&frac12;d.) per barrel per month, and the delivery charge two cents
+per barrel. The petroleum produced in the Oil Springs field is stored
+separately from that obtained in the Petrolia field.</p>
+
+<p>The storage takes place for the most part in large underground tanks
+excavated in the retentive clay. These remarkable tanks are often as
+much as 30 ft. in diameter by 60 ft. in depth, and hold from 5,000 to
+8,000 barrels. In the construction of the tanks the alluvial soil, of
+which there is about 18 ft. or 20 ft. above the clay, is curbed with
+wood and thoroughly puddled with clay. On the completion of the
+excavation, the entire vertical surface is then lined with rings of
+pine wood, so that the upper part down to the solid clay is doubly
+lined. The bottom is not lined. The roof of the tank is of wood,
+covered with clay. The cost of such a tank is about 22 cents (11d.)
+per barrel, or 1,760 dols. (£363) for an 8,000 barrel tank, and the
+time occupied in making such a tank is about six weeks.</p>
+
+<p>The crude petroleum from the Petrolia field usually has a specific
+gravity ranging from 0.859 to 0.877, while the specific gravity of the
+petroleum from the Oil Springs field ranges from 0.844 to 0.854.</p>
+
+<p>The oil occurs in the corniferous limestone, and buildings constructed
+of this stone frequently exude petroleum in hot weather.</p>
+
+<p>Canadian crude petroleum is of a black color, and possesses a very
+disagreeable odor, due to the presence of sulphur compounds. These
+characteristics are shown by the samples on the table, for some of
+which I am indebted to Mr. James Kerr, secretary of the Petrolia Oil
+Exchange.</p>
+
+<p>The stills used in the process of refining the crude oil are
+horizontal two-flued cylinders, 30 ft. in length by 10 ft. in
+diameter, provided with six 2 in. vapor pipes. The charge is 260
+barrels, and the following is an outline of the method of working.
+Assuming the still to be charged on Monday morning, heating is
+commenced about 7 A.M., and the naphtha begins to come over about 8
+A.M. Of this product about six barrels is obtained in the case of
+Petrolia crude, or 7&frac12; barrels in the case of Oil Springs crude. The
+distillation of the naphtha takes from 2 to 3 hours, say till 10:30
+A.M. The heat is then increased, and the distillation of the kerosene
+commences about noon, and continues till about 10 P.M. Of the kerosene
+distillate about 80 barrels are obtained. The first portion of the
+kerosene distillate is usually collected separately, is steamed to
+drive off the more volatile hydrocarbons, and is then mixed with the
+remainder of the kerosene distillate. The product which then commences
+to distill is known as tailings. This is collected separately and is
+redistilled. The distillation of the tailings continues till about 5
+A.M. on Wednesday, by which time about 80 barrels has been obtained.
+Steam is then passed into the still through a perforated pipe
+extending to the bottom, and about 21 barrels of &quot;gas oil&quot; is
+distilled over. The additional quantity of kerosene obtained on
+redistilling the tailings brings up the total yield of this product to
+about 42 per cent. of the crude oil. The gas oil is sold for the
+manufacture of illuminating gas. The residue is distilled for
+lubricating oils and paraffin.</p>
+
+<p>The agitator in which the kerosene distillate is treated commonly
+takes a charge of 465 barrels. To this quantity of distillate two
+carboys of oil of vitriol is added, and the oil and acid are agitated
+together for 20 minutes. The tarry acid having been allowed to settle
+is drawn off, and seven carboys more of acid is added. Agitation
+having been effected for 30 or 40 minutes, the tarry acid is removed
+as before. Another similar treatment with seven carboys of acid
+follows, and occasionally a fourth addition of acid is made. The oil
+is next allowed to remain at rest for an hour, any acid which settles
+out being drawn off, and cold (or, in winter, slightly warmed) water
+is allowed to pass down through the oil in fine streams, this
+treatment being continued, without agitation of the oil, for half an
+hour, or until the dark color which the oil assumed on treatment with
+acid is removed. The water is then drawn off, 10 barrels of solution
+of caustic soda (sp. gr. 15° B.) is added, and agitation conducted for
+15 minutes. The caustic soda solution having been drawn off, 30
+barrels of a solution of litharge in caustic soda is added. This
+solution is made by dissolving caustic soda in water to a density of
+18° B. and then adding the litharge. Agitation with this solution is
+continued for about six hours, or until the oil is thoroughly
+deodorized. About 100 lb. of sublimed sulphur is then added, and the
+agitation is continued for another two hours. The oil having been
+allowed to settle all night, the litharge solution is drawn off, and
+the oil run into a shallow tank or &quot;bleacher,&quot; where it is exposed to
+the light to improve its color, and is, if necessary, steamed to drive
+off the lighter hydrocarbons and raise the flashing point to the legal
+minimum of 95° F. To raise the flashing point from 73° F. to 95° F.
+(Abel test) is stated to involve in practice a loss of 10 per cent.,
+the burning quality of the oil being at the same time seriously
+impaired, and upon this ground the Ontario refiners in 1886 petitioned
+for a reduction of the test standard.</p>
+
+<p>The average percentage yield of the various products is given in the
+following table:</p>
+
+
+
+<div class='center'>
+<table border="0" cellpadding="2" cellspacing="0" summary="">
+<tr><td align="left">Naphtha.</td><td align="right">5</td></tr>
+<tr><td align="left">Kerosene.</td><td align="right">42</td></tr>
+<tr><td align="left">Gas oil.</td><td align="right">8</td></tr>
+<tr><td align="left">Tar.</td><td align="right">25</td></tr>
+<tr><td align="left">Coke.</td><td align="right">10</td></tr>
+<tr><td align="left">Loss (including water).</td><td align="right">10</td></tr>
+<tr><td align="left"></td><td align="right"><span class="over">100</span></td></tr>
+</table></div>
+
+<p>There are a dozen petroleum refineries in Canada, and the annual
+outturn of kerosene is about 200,000 barrels of 45 imperial gallons
+per annum. The total consumption of kerosene in Canada is about
+300,000 barrels, one-third of which is manufactured in the United
+States. The United States oil is subject to a duty of 40 cents on the
+package and 7-1/5 cents per imperial gallon on the contents, besides
+which there is an inspection fee of 30 cents per package. Of
+lubricating oils the outturn is from 75,000 to 100,000 barrels per
+annum.</p>
+
+<p>The quality of Canadian kerosene has been greatly improved of late
+years, but notwithstanding the elaborate process of refining, the oil,
+though thoroughly deodorized and of good color, contains sulphur, and
+of course evolves sulphur compounds in its combustion.</p>
+
+<p>The rules of the Petrolia Oil Exchange provide that refined kerosene
+shall be of the odor &quot;locally known as inoffensive,&quot; and shall
+&quot;absolutely stand the test of oxide of lead in a strong solution of
+caustic soda without change of color.&quot;</p>
+
+<p>The &quot;burning percentage&quot; in the case of &quot;Extra Refined Oil,&quot; &quot;Water
+White&quot; in color, and of specific gravity not exceeding 0.800, is
+required to be not less than 70; in the case of &quot;No. 1 Refined Oil,&quot;
+&quot;Prime White&quot; in color, not less than 60; and in the case of &quot;No. 2
+Refined Oil,&quot; &quot;Standard White&quot; in color, to be not less than 55.</p>
+
+<p>The &quot;burning percentage&quot; is determined by the use of a lamp thus
+described: &quot;The bowl of the lamp is cylindrical, 4 in. in diameter and
+2&frac34; in. deep, with a neck placed thereon of such a height that the top
+of the wick tube is 3 in. above the bowl. A sun-hinge burner is used,
+taking a wick 7/8 in. wide and 1/8 in. thick, and a chimney about 8
+in. long.&quot; The test is conducted as follows: &quot;The lamp bowl is filled
+with the oil and weighed, then lighted and turned up full flame just
+below the smoking point, and burned without interference till 12 oz.
+of the oil is consumed. The quantity consumed during the first hour
+and the last hour is noted.&quot; The ratio of the two quantities is the
+measure of the burning quality, and the percentage that the latter
+quantity is of the former is the &quot;burning percentage&quot; referred to.</p>
+
+<hr />
+
+<h2><a name="art16" id="art16"></a>TREES FROM A SANITARY ASPECT.</h2>
+
+<h3>By <span class="smcap">Charles Roberts</span>, F.R.C.S., etc.</h3>
+
+<p>As this is the usual time of the year for planting, pruning, and
+removing forest trees and shrubs, it is a fit time for considering the
+influence which trees exert on the sanitary surroundings of dwelling
+places. The recent parliamentary report on forestry shows that trees
+are now of little commercial value in this country. And we may
+conclude, therefore, that they are chiefly grown for picturesque
+effect, and for the shelter from the sun and winds which they afford.</p>
+
+<p>The relation of forests to rainfall has been studied by
+meteorologists, but little attention has been given by medical
+climatologists to the share which trees take in determining local
+variations of climate and the sanitary condition of dwellings,
+notwithstanding they play as important a part as differences of soil,
+of which so much is said and written nowadays. This remark does not
+apply to large towns, where trees grow with difficulty <a name="Page_9766" id="Page_9766"></a>and are
+comparatively few in number, and where they afford a grateful relief
+to the eye, shade from the sun, and to a very slight extent temper the
+too dry atmosphere, but to suburban and country districts, where it is
+the custom to bury houses in masses of foliage&mdash;a condition of things
+which is deemed the chief attraction, and often a necessary
+accompaniment, of country life.</p>
+
+<p>Trees of all kinds exercise a cooling and moistening influence on the
+atmosphere and soil in which they grow. The extent of these conditions
+depends on the number of trees and whether they stand alone, in belts,
+or in forests; on their size, whether tall trees with branchless stems
+or thickets of underwood: on their species, whether deciduous or
+evergreen; and on the season of the year. The cooling of the air and
+soil is due to the evaporation of water by the leaves, which is
+chiefly drawn from the subsoil&mdash;not the surface&mdash;by the roots, and to
+the exclusion of the sun's rays from the ground, trees themselves
+being little susceptible of receiving and radiating heat. The moisture
+of the atmosphere and ground about trees is due to the collection by
+the leaves and branches of a considerable portion of the rainfall, the
+condensation of aqueous vapor by the leaves, and the obstruction
+offered by the foliage to evaporation from the ground beneath the
+trees.</p>
+
+<p>The experiments of M. Fautrat show that the leafage of leaf bearing
+trees intercepts one-third, and that of pine trees the half, of the
+rainfall, which is afterward returned to the atmosphere by
+evaporation. On the other hand, these same leaves and branches
+restrain the evaporation of the water which reaches the ground, and
+that evaporation is nearly four times less under a mass of foliage in
+a forest, and two and one-third times under a mass of pines, than in
+the open. Moreover, trees prevent the circulation of the air by
+lateral wind currents and produce stagnation. Hence, as Mr. E.J.
+Symons has truly observed, &quot;a lovely spot embowered in trees and
+embraced by hills is usually characterized by a damp, misty, cold, and
+stagnant atmosphere,&quot; a condition of climate which is obviously
+unfavorable to good health and especially favorable to the development
+of consumption and rheumatism, our two most prevalent diseases.</p>
+
+<p>Now, if we examine the surroundings of many of our suburban villas and
+country houses of the better sort, we shall find them embowered in
+trees, and subject to all the insanitary climatic conditions just
+mentioned. The custom almost everywhere prevails of blocking out of
+view other houses, roads, etc., by belts of trees, often planted on
+raised mounds of earth, and surrounded by high close walls or palings,
+from a foolish ambition of seeming to live &quot;quite in the country.&quot;</p>
+
+<p>This is a most unwise proceeding from a sanitary point of view, and
+should be protested against as strongly by medical men as defective
+drainage and bad water supply. Many houses stand under the very drip
+and shadow of trees, and &quot;the grounds&quot; of others are inclosed by dense
+belts of trees and shrubs, which convert them into veritable
+reservoirs of damp, stagnant air, often loaded with the effluvia of
+decaying leaves and other garden refuse, a condition of atmosphere
+very injurious to health, and answerable for much of the neuralgia of
+a malarious kind, of which we have heard so much lately. A very slight
+belt of trees suffices to obstruct the lateral circulation of the air,
+and if the sun be also excluded the natural upward currents are also
+prevented.</p>
+
+<p>As far back as 1695 Lancisi recognized the influence of slight belts
+of trees in preventing the spread of malaria in Rome, and the cold,
+damp, stagnant air of spaces inclosed by trees is easily demonstrated
+by the wet and dry bulb thermometer, or even by the ordinary
+sensations of the body. A dry garden, on gravel, of three acres in
+extent in Surrey, surrounded by trees, is generally three or four
+degrees colder than the open common beyond the trees; and a large pond
+in a pine wood twenty miles from London afforded skating for ninety
+consecutive days in the winter of 1885-86, while during the greater
+part of the time the lakes in the London parks were free from ice.</p>
+
+<p>The speculative builder has more sins to answer for than the faulty
+construction of houses. He generally begins his operations by cutting
+down all the fine old trees which occupy the ground, and which from
+their size and isolation are more beautiful than young ones and are
+little likely to be injurious to health, and ends them by raising
+mounds and sticking into them dense belts of quick-growing trees like
+poplars to hide as speedily as possible the desolation of bricks and
+mortar he has created. It is this senseless outdoor work of the
+builder and his nurseryman which stands most in need of revision from
+time to time in suburban residences, but which rarely receives it from
+a silly notion, amounting to tree worship, which prohibits the cutting
+down of trees, no matter how injudicious may have been the planting of
+them in the first instance from a sanitary or picturesque point of
+view.</p>
+
+<p>The following hints for planting and removing trees may be useful to
+those persons who have given little attention to the subject. A tree
+should not stand so near a house that, if it were to fall, it would
+fall on the house; or, in other words, the root should be as far from
+the house as the height of the tree. Belts of trees may be planted on
+the north and east aspects of houses, but on the east side the trees
+should not be so near, nor so high, as to keep the morning sun from
+the bedroom windows in the shorter days of the year. On the south and
+west aspects of houses isolated trees only should be permitted, so
+that there may be free access of the sunshine and the west winds to
+the house and grounds.</p>
+
+<p>High walls and palings on these aspects are also objectionable, and
+should be replaced by fences, or better still open palings, especially
+about houses which are occupied during the fall of the leaf, and in
+the winter. Trees for planting near houses should be chosen in the
+following order: Conifers, birch, acacia, beech, oak, elm, lime, and
+poplar. Pine trees are the best of all trees for this purpose, as they
+collect the greatest amount of rainfall and permit the freest
+evaporation from the ground, while their branchless stems offer the
+least resistance to the lateral circulation of the air.</p>
+
+<p>Acacias, oaks, and birches are late to burst into leaf, and therefore
+allow the ground to be warmed by the sun's rays in the early spring.
+The elm, lime, and chestnut are the least desirable kinds of trees to
+plant near houses, although they are the most common. They come into
+leaf early and cast their leaves early, so that they exclude the
+spring sun and do not afford much shade in the hot autumn months,
+when it is most required. The lime and the elm are, however, beautiful
+trees, and will doubtless on this account often be tolerated nearer
+houses than is desirable from a purely sanitary point of view.</p>
+
+<p>Trees are often useful guides to the selection of residences. Numerous
+trees with rich foliage and a rank undergrowth of ferns or moss
+indicate a damp, stagnant atmosphere; while abundance of flowers and
+fruit imply a dry, sunny climate. Children will be healthiest where
+most flowers grow, and old people will live longest where our common
+fruits ripen best, as these conditions of vegetation indicate a
+climate which is least favorable to bronchitis and rheumatism. Pines
+and their companions, the birches, indicate a dry, rocky, sandy, or
+gravel soil; beeches, a dryish, chalky, or gravel soil; elms and
+limes, a rich and somewhat damp soil; oaks and ashes, a heavy clay
+soil; and poplars and willows, a low, damp, or marshy soil. Many of
+these are found growing together, and it is only when one species
+predominates in number and vigor that it is truly characteristic of
+the soil and that portion of the atmosphere in connection with it.</p>
+
+<p>Curzon Street, Mayfair, W.&mdash;<i>Lancet.</i></p>
+
+<hr />
+
+<h2><a name="art00" id="art00"></a>SOLIDIFICATION BY PRESSURE.</h2>
+
+<p>M. Amagat has succeeded in solidifying various liquids, by compressing
+them in cylinders of bronze and steel. He has also photographed the
+crystals after crystallization, by means of a ray of electric light
+traversing the interior of the vessel by glass cones serving as panes.
+The stages of crystallization can be observed in this way with
+chloride of carbon, and it is seen that the process varies with the
+rapidity with which the pressure is produced. If rapidly, a sudden
+circlet of crystals gathers round the edge of the luminous field, and
+grows to the center. The pressure being continued, the field becomes
+obscure, then transparent. As the pressure is diminished the reverse
+takes place, and the liquid state is reproduced. M. Amagat finds that
+chloride of carbon solidifies at 19.5° Cent., under a pressure of 210
+atmospheres. At 22° Cent., benzine crystallizes with a pressure of
+about 900 atmospheres.</p>
+
+<hr />
+
+<h3>The</h3>
+
+<h2>Scientific American Supplement.</h2>
+
+<h3>PUBLISHED WEEKLY.</h3>
+
+<div class="center">Terms of Subscription, $5 a year.</div>
+
+<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. Price of each volume, $2.50 stitched in
+paper, or $3.50 bound in stiff covers.</p>
+
+<p>COMBINED RATES.&mdash;One copy of SCIENTIFIC AMERICAN and one copy of
+SCIENTIFIC AMERICAN SUPPLEMENT, one year, postpaid, $7.00.</p>
+
+<p>A liberal discount to booksellers, news agents, and canvassers.</p>
+
+<p class="center"><b>MUNN &amp; CO., Publishers,</b><br />
+<b>361 Broadway, New York, N. Y</b>.</p>
+
+<hr />
+
+
+<h2>PATENTS.</h2>
+
+<p>In connection with the <b>Scientific American</b>, Messrs. MUNN &amp; Co. are
+solicitors of American and Foreign Patents, have had 42 years'
+experience, and now have the largest establishment in the world.
+Patents are obtained on the best terms.</p>
+
+<p>A special notice is made in the <b>Scientific American</b> of all
+inventions patented through this Agency, with the name and residence
+of the Patentee. By the immense circulation thus given, public
+attention is directed to the merits of the new patent, and sales or
+introduction often easily effected.</p>
+
+<p>Any person who has made a new discovery or invention can ascertain,
+free of charge, whether a patent can probably be obtained, by writing
+to MUNN &amp; Co.</p>
+
+<p>We also send free our Hand Book about the Patent Laws, Patents,
+Caveats, Trade Marks, their costs, and how procured. Address</p>
+
+<p class="center"><b>Munn &amp; Co.,</b><br />
+<b>361 Broadway, New York.</b></p>
+
+<p>Branch Office, 622 and 624 F St., Washington, D.C.</p>
+
+<hr />
+
+<h3>THE SCIENTIFIC AMERICAN</h3>
+
+<h2>Architects and Builders Edition.</h2>
+
+<div class="center"><b>$2.50 a Year. Single Copies, 25 cts.</b></div>
+
+<p>This is a Special Edition of the <span class="smcap">Scientific American</span>, issued
+monthly&mdash;on the first day of the month. Each number contains about
+forty large quarto pages, equal to about two hundred ordinary book
+pages, forming, practically, a large and splendid <b>Magazine of
+Architecture</b>, richly adorned with <i>elegant plates in colors</i> and with
+fine engravings, illustrating the most interesting examples of modern
+Architectural Construction and allied subjects.</p>
+
+<p>A special feature is the presentation in each number of a variety of
+the latest and best plans for private residences, city and country,
+including those of very moderate cost as well as the more expensive.
+Drawings in perspective and in color are given, together with full
+Plans, Specifications, Costs, Bills of Estimate, and Sheets of
+Details.</p>
+
+<p>No other building paper contains so many plans, details, and
+specifications regularly presented as the <span class="smcap">Scientific
+American</span>. Hundreds of dwellings have already been erected on the
+various plans we have issued during the past year, and many others are
+in process of construction.</p>
+
+<p>Architects, Builders, and Owners will find this work valuable in
+furnishing fresh and useful suggestions. All who contemplate building
+or improving homes, or erecting structures of any kind, have before
+them in this work an almost <i>endless series of the latest and best
+examples</i> from which to make selections, thus saving time and money.</p>
+
+<p>Many other subjects, including Sewerage, Piping, Lighting, Warming,
+Ventilating, Decorating, Laying out of Grounds, etc., are illustrated.
+An extensive Compendium of Manufacturers' Announcements is also given,
+in which the most reliable and approved Building Materials, Goods,
+Machines, Tools, and Appliances are described and illustrated, with
+addresses of the makers, etc.</p>
+
+<p>The fullness, richness, cheapness, and convenience of this work have
+won for it the <b>Largest Circulation</b> of any Architectural publication
+in the world.</p>
+
+<p class="center"><b>MUNN &amp; CO., Publishers</b>,<br />
+<b>361 Broadway, New York</b>.</p>
+
+<p>A Catalogue of valuable books on Architecture, Building, Carpentry,
+Masonry, Heating, Warming, Lighting, Ventilation, and all branches of
+industry pertaining to the art of Building, is supplied free of
+charge, sent to any address.</p>
+
+<hr />
+
+<h3>Building Plans and Specifications.</h3>
+
+<p>In connection with the publication of the <span class="smcap">Building Edition</span> of
+the <span class="smcap">Scientific American</span>, Messrs. Munn &amp; Co. furnish plans and
+specifications for buildings of every kind, including Churches,
+Schools, Stores, Dwellings, Carriage Houses, Barns, etc.</p>
+
+<p>In this work they are assisted by able and experienced architects.
+Full plans, details, and specifications for the various buildings
+illustrated in this paper can be supplied.</p>
+
+<p>Those who contemplate building, or who wish to alter, improve, extend,
+or add to existing buildings, whether wings, porches, bay windows, or
+attic rooms, are invited to communicate with the undersigned. Our work
+extends to all parts of the country. Estimates, plans, and drawings
+promptly prepared. Terms moderate. Address</p>
+
+<p class="center"><span class="smcap">Munn &amp; Co., 361 Broadway, New York.</span></p>
+
+
+
+
+
+
+
+<pre>
+
+
+
+
+
+End of the Project Gutenberg EBook of Scientific American Supplement, No.
+611, September 17, 1887, by Various
+
+*** END OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN ***
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