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+<title>The Project Gutenberg eBook of Scientific American
+Supplement, October 22, 1881</title>
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+
+Project Gutenberg's Scientific American Supplement, No. 303, 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. 303
+       October 22, 1881
+
+Author: Various
+
+Posting Date: October 10, 2012 [EBook #8296]
+Release Date: June, 2005
+First Posted: July 4, 2003
+
+Language: English
+
+Character set encoding: ISO-8859-1
+
+*** START OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN SUPPL., NO. 303 ***
+
+
+
+
+Produced by Olaf Voss, Don Kretz, Juliet Sutherland, Charles
+Franks and the Online Distributed Proofreading Team.
+
+
+
+
+
+
+</pre>
+
+
+<p class="ctr"><a href="images/1a.png"><img src=
+"images/1a_th.png" alt=""></a></p>
+
+<h1>SCIENTIFIC AMERICAN SUPPLEMENT NO. 303</h1>
+
+<h2>NEW YORK, OCTOBER 22, 1881</h2>
+
+<h4>Scientific American Supplement. Vol. XII, No. 303.</h4>
+
+<h4>Scientific American established 1845</h4>
+
+<h4>Scientific American Supplement, $5 a year.</h4>
+
+<h4>Scientific American and Supplement, $7 a year.</h4>
+
+<hr>
+<table summary="Contents" border="0" cellspacing="5">
+<tr>
+<th colspan="2">TABLE OF CONTENTS</th>
+</tr>
+
+<tr>
+<td valign="top">I.</td>
+<td><a href="#1">ENGINEERING AND MECHANICS.--New Eighty-ton Steam
+Hammer at the Saint Chamond Works, France.--7 figures.--Elevation
+of hammer.--Profile-- Transverse section.--Profile view of
+foundation, etc.--Plan of plant.--General plan of the forging
+mill.--Details of truss and support for the cranes.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#2">Great Steamers.--Comparative details of the
+Servia, the City of Rome, the Alaska, and the Great
+Eastern.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#3">Improved Road Locomotive.--2 figures.--Side and
+end views</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#4">American Milling Methods. By ALBERT HOPPIN.--Ten
+years' progress.--Low milling.--Half high milling.--High
+milling.--Important paper read before the Pennsylvania State
+Millers' Association.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#5">Machine for Dotting Tulles and other Light
+Fabrics.--3 figures.</a></td>
+</tr>
+
+<tr>
+<td valign="top">II.</td>
+<td><a href="#6">TECHNOLOGY AND CHEMISTRY.--The Reproduction and
+Multiplication of Negatives. By ERNEST EDWARDS.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#7">A New Method of Making Gelatine Emulsion. By W. K.
+BURTON.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#8">The Pottery and Porcelain Industries of
+Japan.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#9">Crystallization Table.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#10">The Principles of Hop Analysis. By Dr. G. O.
+CECH.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#11">Water Gas.--A description of apparatus for
+producing cheap gas, and some notes on the economical effects of
+using such gas with gas motors, etc.--By J. EMERSON
+DOWSON.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#12">On the Fluid Density of Certain Metals. By
+Professors CHANDLER ROBERTS and T. WRIGLESON.</a></td>
+</tr>
+
+<tr>
+<td valign="top">III.</td>
+<td><a href="#13">PHYSICS, ELECTRICITY, ETC.--Electric Power.--The
+nature and uses of electricity.--Electricity vs. steam.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#14">On the Method of Obtaining and Measuring Very
+High Vacua with a Modified Form of Sprengel Pump. By Prof OGDEN N.
+ROOD.--4 figures.-- Apparatus for obtaining vacua of one four
+hundred-millionth of an
+atmosphere--Construction.--Manipulation.--Calculations.--Results</a></td>
+</tr>
+
+<tr>
+<td valign="top">IV.</td>
+<td><a href="#15">ART, ARCHITECTURE, ETC.--Old Wrought Iron Gates,
+Guildhall. Worcester, England. 1 figure.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#16">The French Crystal Palace, Park of St. Cloud,
+Paris. 1 full page illustration.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#17">Suggestions in Architecture. A Castellated
+Chateau. Perspective and plan. Chateau in the &AElig;gean
+Sea.</a></td>
+</tr>
+
+<tr>
+<td valign="top">V.</td>
+<td><a href="#18">HYGIENE AND MEDICINE.--Hydrophobia Prevented by
+Vaccination.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#19">On Diptera as Spreaders of Disease. By J. W.
+SLATER.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#20">On the Relations of Minute Organisms to Certain
+Specific Diseases.</a></td>
+</tr>
+
+<tr>
+<td valign="top">VI.</td>
+<td><a href="#21">ASTRONOMY--The Centenary of the Discovery of
+Uranus. By F. W. DENNING. 2 figures. Approximate place of Uranus
+among the stars at its discovery, March l3, 1871.--Orbits of the
+Uranian Satellites.</a></td>
+</tr>
+
+<tr>
+<td valign="top">VII.</td>
+<td><a href="#22">BIOLOGY, ETC.--The Varying Susceptibility of
+Plants and Animals to Poisons and Disease.</a></td>
+</tr>
+
+<tr>
+<td></td>
+<td><a href="#23">Kind Treatment of Horses.</a></td>
+</tr>
+</table>
+
+<hr>
+<p><a name="1"></a></p>
+
+<h2>NEW EIGHTY TON STEAM HAMMER AT THE SAINT CHAMOND WORKS</h2>
+
+<p>Ever since the improvements that have been introduced into the
+manufacture of steel, and especially into the erection of works for
+its production, have made it possible to obtain this metal in very
+large masses, it has necessarily been preferred to iron for all
+pieces of large dimensions, inasmuch as it possesses in the highest
+degree that homogeneousness and resistance which are so difficult
+to obtain in the latter metal. It has consequently been found
+necessary to construct engines sufficiently powerful to effect the
+forging of enormous ingots, as well as special furnaces for heating
+them and apparatus for manipulating and transporting them.</p>
+
+<p>The greatest efforts in this direction have been made with a
+view to supplying the wants of heavy artillery and of naval
+constructions; and to these efforts is metallurgy indebted for the
+creation of establishments on a scale that no one would have dared
+a few years ago to think of. The forging mill which we are about to
+describe is one of those creations which is destined to remain for
+a long time yet very rare; and one which is fully able to respond,
+not only to all present exigencies, but also, as far as can be
+foreseen, to all those that may arise for a long period to come.
+The mill is constructed as a portion of the vast works that the
+Compagnie des Forges et Aci&eacute;ries de la Marine own at Saint
+Chamond, and which embrace likewise a powerful steel works that
+furnishes, especially, large ingots exceeding 100 tons in
+weight.</p>
+
+<p>The mill consists, altogether, of three hammers, located in the
+same room, and being of unequal powers in order to respond to
+different requirements. The largest of these hammers is of 80 tons
+weight, and the other two weigh respectively 35 and 28 tons. Each
+of them has a corresponding furnace for heating by gas, as well as
+cranes for maneuvering the ingots and the different engines. The
+general plan view in Fig. 4 shows the arrangement of the hammers,
+cranes, and furnaces in the millhouse.</p>
+
+<p class="ctr"><a href="images/1b.png"><img src=
+"images/1b_th.png" alt=
+"FIG. A.--ELEVATION OF A HAMMER. FIG. B.--PROFILE VIEW"></a></p>
+
+<p class="ctr">FIG. A.--ELEVATION OF A HAMMER. FIG. B.--PROFILE
+VIEW</p>
+
+<p>The gas generators which supply the gas-furnaces are located out
+of doors, as are the steam-generators. The ingots are brought from
+the steel factory, and the forged pieces are taken away, by special
+trucks running on a system of rails. We shall now give the most
+important details in regard to the different parts of the
+works.</p>
+
+<p><i>The Mill-House</i>--This consists of a central room, 262 feet
+long, 98 feet wide, and 68 feet in height, with two lean-to annexes
+of 16 feet each, making the total width 100 feet. The structure is
+wholly of metal, and is so arranged as to permit of advantage being
+taken of every foot of space under cover. For this purpose the
+system of construction without tie-beams, known as the "De Dion
+type," has been adopted. Fig. 1 gives a general view of one of the
+trusses, and Fig. 5 shows some further details. The binding-rafters
+consist of four angle-irons connected by cross-bars of flat iron.
+The covering of corrugated galvanized iron rests directly upon the
+binding-rafters, the upper parts of which are covered with wood for
+the attachment of the corrugated metal. The spacing of these
+rafters is calculated according to the length of the sheets of
+corrugated iron, thus dispensing with the use of ordinary rafters,
+and making a roof which is at once very light and very durable, and
+consequently very economical. Rain falling on the roof flows into
+leaden gutters, from whence it is carried by leaders into a
+subterranean drain. The vertical walls of the structure are
+likewise of corrugated iron, and the general aspect of the building
+is very original and very satisfactory.</p>
+
+<p><i>The 80 Ton Hammer</i>--The three hammers, notwithstanding
+their difference in power, present similar arrangements, and
+scarcely vary except in dimensions. We shall confine ourselves here
+to a description of the 80 ton apparatus. This consists, in
+addition to the hammer, properly so called, of three cranes of 120
+tons each, serving to maneuver the pieces to be forged, and of a
+fourth of 75 tons for maneuvering the working implements. These
+four cranes are arranged symmetrically around the hammer, and are
+supported at their upper extremity by metallic stays. Besides the
+foregoing there are three gas furnaces for heating the ingots.
+Figs. 1, 2, and 3 show the general arrangement of the
+apparatus.</p>
+
+<p><i>Foundations of the Hammer and Composition of the
+Anvil-Bed</i>--To obtain a foundation for the hammer an excavation
+was made to a depth of 26 feet until a bed of solid rock was
+reached, and upon this there was then spread a thick layer of
+beton, and upon this again there was placed a bed of dressed stones
+in the part that was to receive the anvil-stock and hammer.</p>
+
+<p>On this base of dressed stones there was placed a bed formed of
+logs of heartwood of oak squaring 16 inches by 3 feet in height,
+standing upright, joined together very perfectly, and kept in close
+juxtaposition by a double band of iron straps joined by bolts. The
+object of this wooden bed was to deaden, in a great measure, the
+effect of the shock transmitted by the anvil-stock.</p>
+
+<p>NEW EIGHTY-TON STEAM HAMMER AT THE ST CHAMOND WORKS.</p>
+
+<p class="ctr"><a href="images/1c.png"><img src=
+"images/1c_th.png" alt="FIG. 1.--TRANSVERSE SECTION.">
+</a></p>
+
+<p class="ctr">FIG. 1.--TRANSVERSE SECTION.</p>
+
+<p class="ctr"><a href="images/2a.png"><img src=
+"images/2a_th.png" alt="FIG. 2.--PLAN."></a></p>
+
+<p class="ctr">FIG. 2.--PLAN.</p>
+
+<p class="ctr"><a href="images/1d.png"><img src=
+"images/1d_th.png" alt="FIG. 3.--PROFILE VIEW."></a></p>
+
+<p class="ctr">FIG. 3.--PROFILE VIEW.</p>
+
+<p class="ctr"><a href="images/2b.png"><img src=
+"images/2b_th.png" alt=
+"FIG. 4.--GENERAL PLAN OF THE FORGING MILL."></a></p>
+
+<p class="ctr">FIG. 4.--GENERAL PLAN OF THE FORGING MILL.</p>
+
+<p class="ctr"><a href="images/2c.png"><img src=
+"images/2c_th.png" alt=
+"FIG. 5.--DETAILS OF THE TRUSSAND SUPPORT FOR THE CRANE."></a></p>
+
+<p class="ctr">FIG. 5.--DETAILS OF THE TRUSSAND SUPPORT FOR THE
+CRANE.</p>
+
+<p><i>The Anvil-Stock</i>.--The anvil-stock, which is pyramidal in
+shape, and the total weight of which amounts to 500 tons, is
+composed of superposed courses, each formed of one or two blocks of
+cast iron. Each course and every contact was very carefully planed
+in order to make sure of a perfect fitting of the parts; and all
+the different blocks were connected by means of mortises, by hot
+bandaging, and by joints with key-pieces, in such a way as to
+effect a perfect solidity of the parts and to make the whole
+compact and impossible to get out of shape.</p>
+
+<p>The anvil-stock was afterwards surrounded by a filling-in of
+masonry composed of rag-stones and a mortar made of cement and
+hydraulic lime. This masonry also forms the foundation for the
+standards of the hammer, and is capped with dressed stone to
+receive the bed-plates.</p>
+
+<p><i>The Power-Hammer</i> (Figs. A and B).--The power-hammer,
+properly so-called, consists, in addition to the hammer-head, of
+two standards to whose inner sides are bolted guides upon which
+slides the moving mass. The bed-plates of cast iron are 28 inches
+thick, and are independent of the anvil-stock. They are set into
+the bed of dressed stone capping the foundation, and are connected
+together by bars of iron and affixed to the masonry by foundation
+bolts. To these bedplates are affixed the standards by means of
+bolts and keys. The two standards are connected together by iron
+plates four inches in thickness, which are set into the metal and
+bolted to it so as to secure the utmost strength and solidity. The
+platform which connects the upper extremities of the standards
+supports the steam cylinder and the apparatus for distributing the
+steam. The latter consists of a throttle valve, twelve inches in
+diameter, and an eduction valve eighteen inches in diameter, the
+maneuvering of which is done by means of rods extending down to a
+platform upon which the engineman stands. This platform is so
+situated that all orders can be distinctly heard by the engineman,
+and so that he shall be protected from the heat radiated by the
+steel that is being forged. All the maneuvers of the hammers are
+effected with most wonderful facility and with the greatest
+precision.</p>
+
+<p>The piston is of cast-steel, and the rod is of iron, 12 inches
+in diameter. The waste steam is carried out of the mill by a pipe,
+and, before being allowed to escape into the atmosphere, is
+directed into an expansion pipe which it penetrates from bottom to
+top. Here a portion of the water condenses and flows off, and the
+steam then escapes into the open air with a greatly diminished
+pressure. The object of this arrangement is to diminish to a
+considerable extent the shocks and disagreeable noise that would be
+produced by the direct escape of the steam at quite a high pressure
+and also to avoid the fall of condensed water.</p>
+
+<p>The following are a few details regarding the construction of
+the hammer:</p>
+
+<pre>
+  Total height of foundations........... 26    ft.
+  From the ground to the platform ...... 28     "
+<br>
+  Platform .............................. 3.25  "
+  Height of cylinder.................... 21     "
+                                         ________
+<br>
+      Total height...................... 78.25 ft.
+<br>
+  Weight of anvil-stock................ 500 tons.
+  Weight of bed-plates................. 122  "
+  Weight of standards.................. 270  "
+  Weight of platform and cylinder...... 148  "
+  Piston, valves, engineman's platform,
+    hammer, etc........................ 160  "
+                                        __________
+<br>
+      Total weight................... 1,200 tons.
+<br>
+  Weight of the hammer.................. 80 tons.
+  Maximum fall.......................... 25.75 ft.
+  Distance apart of the standards....... 21.6   "
+  Width of hammer.......................  6     "
+  Pressure of steam..................... 16 lb.
+  Effective pressure to lift 80 tons....  7  "
+</pre>
+
+<i>Description of Figures</i>.--A, the 80-ton hammer; B, B1, B2,
+cranes; C, C1, C2, supports of cranes; D, D1, D2, gas furnaces; A1,
+the 35-ton hammer; A2, the 28-ton hammer; EE, railways; F,
+engineman's platform; G, lever for maneuvering the throttle valve;
+H, an ingot being forged.
+
+<hr>
+<p><a name="2"></a></p>
+
+<h2>GREAT STEAMERS.</h2>
+
+<p>The <i>Brooklyn Eagle</i> gives a very interesting description
+of the three new steamships now almost completed and shortly to be
+placed in the New York and Liverpool trade by the Cunard, Inman,
+and Williams and Guion lines. The writer has prepared a table
+comparing the three vessels with each other and with the Great
+Eastern, the only ship of greater dimensions ever built. We give as
+much of the article as our space will allow, and regret that we
+have not the room to give it entire:</p>
+
+<pre>
+     Line.         Cunard.       Inman.        Guion.    Admiralty.
+    Vessel.        Servia     City of Rome.    Alaska.    Great[1]
+<br>
+  Length        530 feet.     546 feet.     520 feet.     679 feet.
+  Breadth        52 feet.      52 ft. 3 in.  50 ft. 6 in.  82 feet.
+  Depth          44 ft. 9 in.  37 feet.      38 feet.      60 feet.
+  Gross ton'ge     8,500         8,300         8,000      13,344[2]
+  Horse pow'r     10,500        10,000        11,000       2,600
+  Speed          17&frac12; knots.    18 knots.     18 knots.    14 knots.
+  Sal'n pas-                                 320 and 52
+    sengers.       450           300          2d class
+  Steerage         600         1,500         1,000
+  Where          Clydeb'nk     Barrow in      Clyde,
+    built.        Thomson       Furness       Elder
+  Date of
+    sailing.     October 22    October 13    November 5
+</pre>
+
+<p>[Footnote 1: To be sold at auction soon.]</p>
+
+<p>[Footnote 2: Net register.]</p>
+
+<p>In 1870 the total tonnage of British steam shipping was
+1,111,375; the returns for the year 1876 showed an increase to
+2,150,302 tons, and from that time to the present it has been
+increasing still more rapidly. But, as can be seen from the above
+table, not only has the total tonnage increased to this enormous
+extent, but an immense advance has been made in increasing the size
+of vessels. The reason for this is, that it has been found that
+where speed is required, along with large cargo and passenger
+accommodation, a vessel of large dimensions is necessary, and will
+give what is required with the least proportionate first cost as
+well as working cost. Up to the present time the Inman line
+possessed, in the City of Berlin, of 5,491 tons, the vessel of
+largest tonnage in existence. Now, however, the Berlin is surpassed
+by the City of Rome by nearly 3,000 tons, and the latter is less,
+by 200 tons, than the Servia, of the Cunard line. It will be
+observed, too, that while there is not much difference between the
+three vessels in point of length, the depth of the Alaska and the
+City of Rome, respectively, is only 38 feet and 37 feet, that of
+the Servia is nearly 45 feet as compared with that of the Great
+Eastern of 60 feet. This makes the Servia, proportionately, the
+deepest ship of all. All three vessels are built of steel. This
+metal was chosen not only because of its greater strength as
+against iron, but also because it is more ductile and the advantage
+of less weight is gained, as will be seen when it is mentioned that
+the Servia, if built of iron, would have weighed 620 tons more than
+she does of steel, and would have entailed the drawback of a
+corresponding increase in draught of water. As regards rig, the
+three vessels have each a different style. The Cunard Company have
+adhered to their special rig--three masts, bark rigged--believing
+it to be more ship shape than the practice of fitting up masts
+according to the length of the ship. On these masts there is a good
+spread of canvas to assist in propelling the ship. The City of Rome
+is rigged with four masts; and here the handsome full-ship rig of
+the Inman line has been adhered to, with the addition of the fore
+and aft rigged jigger mast, rendered necessary by the enormous
+length of the vessel. It will be seen that the distinctive type of
+the Inman line has not been departed from in respect to the old
+fashioned but still handsome profile, with clipper bow, figurehead,
+and bowsprit--which latter makes the Rome's length over all 600
+feet. For the figurehead has been chosen a full length figure of
+one of the Roman C&aelig;sars, in the imperial purple. Altogether,
+the City of Rome is the most imposing and beautiful sight that can
+be seen on the water. The Alaska has also four masts, but only two
+crossed.</p>
+
+<p>The length of the City of Rome, as compared with breadth,
+insures long and easy lines for the high speed required; and the
+depth of hold being only 37 feet, as compared with the beam of 52
+feet, insures great stability and the consequent comfort of the
+passengers. A point calling for special notice is the large number
+of separate compartments formed by water tight bulkheads, each
+extending to the main deck. The largest of these compartments is
+only about 60 feet long; and, supposing that from collision or some
+other cause, one of these was filled with water, the trim of the
+vessel would not be materially affected. With a view to giving
+still further safety in the event of collision or stranding, the
+boilers are arranged in two boiler rooms, entirely separated from
+each other by means of a water tight iron bulkhead. This reduces
+what, in nearly all full-powered steamships, is a vast single
+compartment, into two of moderate size, 60 feet in length; and in
+the event of either boiler room being flooded, it still leaves the
+vessel with half her boiler power available, giving a speed of from
+thirteen to fourteen knots per hour. The vessel's decks are of
+iron, covered with teak planking; while the whole of the deck
+houses, with turtle decks and other erections on the upper deck,
+are of iron, to stand the strains of an Atlantic winter. Steam is
+supplied by eight cylindrical tubular boilers, fired from both
+ends, each of the boilers being 19 feet long and having 14 feet
+mean diameter. There are in all forty eight furnaces. The internal
+arrangements are of the finest description. There are two smoking
+rooms, and in the after deckhouse is a deck saloon for ladies,
+which is fitted up in the most elegant manner, and will prevent the
+necessity of going below in showery weather. At the sides of the
+hurricane deck are carried twelve life boats, one of which is
+fitted as a steam launch. The upper saloon or drawing-room is 100
+feet long, the height between decks being 9 feet. The grand
+dining-saloon is 52 feet long, 52 feet wide, and 9 feet high, or 17
+feet in the way of the large opening to the drawing-room above.
+This opening is surmounted by a skylight, and forms a very
+effective and elegant relief to the otherwise flat and heavy
+ceiling. There are three large and fourteen small dining tables,
+the large tables being arranged longitudinally in the central part
+of the saloon, and the small tables at right angles on the sides.
+Each diner has his own revolving arm chair, and accommodation is
+provided for 250 persons at once. A large American organ is fixed
+at the fore end of the room, and opening off through double spring
+doors at the foot of the grand staircase is a handsome American
+luncheon bar, with the usual fittings. On each side of the vessel,
+from the saloon to the after end of the engine room, are placed
+staterooms providing for 300 passengers. The arrangements for
+steerage passengers are of a superior description. The berths are
+arranged in single tiers or half rooms, not double, as is usually
+the custom, each being separated by a passage, and having a large
+side light, thus adding greatly to the light, ventilation, and
+comfort of the steerage passengers, and necessitating the advantage
+of a smaller number of persons in each room. The City of Rome is
+the first of the two due here; she sails from Liverpool on October
+13.</p>
+
+<p>In the Servia the machinery consists of three cylinder compound
+surface condensing engines, one cylinder being 72 inches, and two
+100 inches in diameter, with a stroke of piston of 6 feet 6 inches.
+There are seven boilers and thirty-nine furnaces. Practically the
+Servia is a five decker, as she is built with four decks--of steel,
+covered with yellow pine--and a promenade reserved for passengers.
+There is a music room on the upper deck, which is 50 feet by 22
+feet, and which is handsomely fitted up with polished wood
+panelings. For the convenience of the passengers there are no less
+than four different entrances from the upper deck to the cabins.
+The saloon is 74 feet by 49 feet, with sitting accommodations for
+350 persons, while the clear height under the beams is 8 feet 6
+inches. The sides are all in fancy woods, with beautifully polished
+inlaid panels, and all the upholstery of the saloon is of morocco
+leather. For two-thirds of its entire length the lower deck is
+fitted up with first class staterooms. The ship is divided into
+nine water-tight bulkheads, and she is built according to the
+Admiralty requirements for war purposes. There are in all twelve
+boats equipped as life-boats. The Servia possesses a peculiarity
+which will add to her safety, namely, a double bottom, or inner
+skin. Thus, were she to ground on rocks, she would be perfectly
+safe, so long as the inner skin remained intact. Steam is used for
+heating the cabins and saloons, and by this means the temperature
+can be properly adjusted in all weathers. In every part of the
+vessel the most advanced scientific improvements have been adopted.
+The Servia leaves Liverpool on October 22.</p>
+
+<p>The Alaska, whose owners, it is understood, are determined to
+make her beat all afloat in speed, does not sail until November 5,
+and therefore it is premature to say anything about her interior
+equipments. She is the sister of the celebrated Arizona, and was
+built by the well-known firm of Elder &amp; Co., on the Clyde.</p>
+
+<hr>
+<p><a name="3"></a></p>
+
+<h2>IMPROVED ROAD LOCOMOTIVE.</h2>
+
+<p>Several attempts have been made to connect the leading wheels of
+a traction engine with the driving wheels, so as to make drivers of
+all of them, and thus increase the tractive power of the engine,
+and to afford greater facilities for getting along soft ground or
+out of holes. The wheels with continuous railway and India-rubber
+tires have been employed to gain the required adhesion, but these
+wheels have been too costly, and the attempts to couple driving and
+leading wheels have failed. The arrangement for making the leading
+wheels into drivers, illustrated on page 4825, has been recently
+brought out by the Durham and North Yorkshire Steam Cultivation
+Company, Ripon, the design being by Messrs. Johnson and Phillips.
+The invention consists in mounting the leading axle in a ball and
+long socket, the socket being rotated in fixed bearings. The ball
+having but limited range of motion in the socket, is driven round
+with it, but is free to move in azimuth for steering.</p>
+
+<p>This engine has now been in use more than twelve months in
+traction and thrashing work, and, we are informed, with complete
+success. The illustrations represent a 7-horse power, with a
+cylinder 8 in. diameter by 12 in. stroke, and steam jacketed. The
+shafts and axles are of Bowling iron. The boiler contains 140 ft.
+of heating surface, and is made entirely of Bowling iron, with the
+longitudinal seams welded. The gearing is fitted with two speeds
+arranged to travel at 1&frac12; and 3 miles per hour, and the front
+or hind road wheels can be put out of gear when not required. The
+hind driving wheels are 5 ft. 6 in. diameter, and the front wheels
+5 ft.; weight of engine 8 tons.--<i>The Engineer.</i></p>
+
+<p class="ctr"><img src="images/3a.png" alt=
+"IMPROVED ROAD LOCOMOTIVE"></p>
+
+<p class="ctr">IMPROVED ROAD LOCOMOTIVE</p>
+
+<p class="ctr"><a href="images/3b.png"><img src=
+"images/3b_th.png" alt="IMPROVED ROAD LOCOMOTIVE"></a></p>
+
+<p class="ctr">IMPROVED ROAD LOCOMOTIVE</p>
+
+<hr>
+<p><a name="4"></a></p>
+
+<h2>AMERICAN MILLING METHODS.</h2>
+
+<p>[Footnote 1: A paper read before the meeting of the Pennsylvania
+State Millers Association at Pittsburgh, Pa., by Albert Hoppin,
+Editor of the <i>Northwestern Miller</i>.]</p>
+
+<h3>By ALBERT HOPPIN.</h3>
+
+<p>To speak of the wonderful strides which the art of milling has
+taken during the past decade has become exceedingly trite. This
+progress, patent to the most casual observer, is a marked example
+of the power inherent in man to overcome natural obstacles. Had the
+climatic conditions of the Northwest allowed the raising of as good
+winter wheat as that raised in winter wheat sections generally, I
+doubt if we should hear so much to-day of new processes and gradual
+reduction systems. So long as the great bulk of our supply of
+breadstuffs came from the winter wheat fields, progress was very
+slow; the mills of 1860, and I may even say of 1870, being but
+little in advance, so far as processes were concerned, of those
+built half a century earlier. The reason for this lack of progress
+may be found in the ease with which winter wheat could be made into
+good, white, merchantable flour. That this flour was inferior to
+the flour turned out by winter wheat mills now is proven by the old
+recipe for telling good flour from that which was bad, viz.: To
+throw a handful against the side of the barrel, if it stuck there
+it was good, the color being of a yellowish cast. What good winter
+wheat patent to-day will do this? Still the old time winter wheat
+flour was the best there was, and it had no competitor. The
+settling up of the Northwest which could not produce winter wheat
+at all, but which did produce a most superior article of hard
+spring wheat, was a new factor in the milling problem. The first
+mills built in the spring wheat States tried to make flour on the
+old system and made a most lamentable failure of it. I can remember
+when the farmer in Wisconsin, who liked a good loaf of bread,
+thought it necessary to raise a little patch of winter wheat for
+his own use. He oftener failed than succeeded, and most frequently
+gave it up as a bad job. Spring wheat was hard, with a very tender,
+brittle bran. If ground fine enough to make a good yield a good
+share of the bran went into the flour, making it dark and specky.
+If not so finely ground the flour was whiter, but the large
+percentage of middlings made the yield per bushel ruinously small.
+These middlings contained the choicest part of the flour producing
+part of the berry, but owing to the dirt, germ, and other
+impurities mixed with them, it was impossible to regrind them
+except for a low grade flour. Merchant milling of spring wheat was
+impossible wherever the flour came in competition with winter wheat
+flours. At Minneapolis, where the millers had an almost unlimited
+water power, and wheat at the lowest price, merchant milling was
+almost given up as impracticable. It was certainly unprofitable. To
+the apparently insurmountable obstacles in the way of milling
+spring wheat successfully, we may ascribe the progress of modern
+milling. Had it been as easy to raise good winter wheat in
+Wisconsin and Minnesota as in Pennsylvania and Ohio, or as easy to
+make white flour from spring as from winter wheat, we should not
+have heard of purifiers and roller mills for years to come.</p>
+
+<p>The first step in advance was the introduction of a machine to
+purify middlings. It was found that the flour made from these
+purified middlings was whiter than the flour from the first
+grinding and brought a better price than even winter wheat flours.
+Then the aim was to make as many middlings as possible. To do this
+and still clean the bran so as to make a reasonable yield the dress
+of the burrs was more carefully attended to, the old fashioned
+cracks were left out, the faces and furrows made smooth, true, and
+uniform, self-adjusting drivers introduced, and the driving gear
+better fitted. Spring wheat patents rapidly rose to the first place
+in the market, and winter wheat millers waked up to find their
+vantage ground occupied by their hitherto contemned rivals. To
+their credit it may be said that they have not been slow in taking
+up the gauntlet, and through the competition of the millers of the
+two climatically divided sections of this country with each other
+and among themselves the onward march of milling progress has been
+constantly accelerated. Where it will end no man can tell, and the
+chief anxiety of every progressive miller, whether he lives in
+Pennsylvania or Minnesota, is not to be left behind in the
+race.</p>
+
+<p>The millers of the more Eastern winter wheat States have a
+two-fold question to solve. First, how to make a flour as good as
+can be found in the market, and second, how to meet Western
+competition, which, through cheap raw material and discriminating
+freight rates, is making serious inroads upon the local markets.
+Whether the latter trouble can be remedied by legislature, either
+State or national, or not, remains to be proven by actual trial.
+That you can solve the first part of the problem satisfactorily to
+yourselves depends upon your readiness to adopt new ideas and the
+means you have at hand to carry them out. It is manifestly
+impossible to make as good a flour out of soft starchy wheat as out
+of that which is harder and more glutinous. It is equally
+impossible for the small mill poorly provided with machinery to
+cope successfully with the large merchant mill fully equipped with
+every appliance that American ingenuity can suggest and money can
+buy. I believe, however, that a mill of moderate size can make
+flour equally as good as the large mill, though, perhaps, not as
+economically in regard to yield and cost of manufacture.</p>
+
+<p>The different methods of milling at present in use may be
+generally divided into three distinct processes, which, for want of
+any better names, I will distinguish as old style, new process, and
+gradual reduction. Perhaps the German division of low milling, half
+high milling, and high milling is better. Old style milling was
+that in general use in this country up to 1870, and which is still
+followed in the great majority of small custom or grist mills. It
+is very simple, consisting of grinding the wheat as fine as
+possible at the first grinding, and separating the meal into flour,
+superfine or extra, middlings, shorts, and bran. Given a pair of
+millstones and reel long enough, and the wheat could be made into
+flour by passing through the two. Because spring wheat was so
+poorly adapted to this crude process, it had to be improved and
+elaborated, resulting in the new process.</p>
+
+<p>At first this merely consisted of purifying and regrinding the
+middlings made in the old way. In its perfected state it may be
+said to be halfway between the old style and gradual reduction, and
+is in use now in many mills. In it mill stones are used to make the
+reductions which are only two in number, in the first of which the
+aim of the miller is to make as many middlings as he can while
+cleaning the bran reasonably well, and in the second to make the
+purified middlings into flour. In the most advanced mills which use
+the new process, the bran is reground and the tailings from the
+coarse middlings, containing germ and large middlings with pieces
+of bran attached, are crushed between two rolls. These can hardly
+be counted as reductions, as they are simply the finishing touches,
+put on to aid in working the stuff up clean and to permit of a
+little higher grinding at first. Regarding both old style and new
+process milling, you are already posted. Gradual reduction is
+newer, much more extensive, and merits a much more thorough
+explanation. Before entering upon this I will call your attention
+to one or two points which every miller should understand.</p>
+
+<p>The two essential qualities of a good marketable flour are color
+and strength. It should be sharply granular and not feel flat and
+soft to the touch. A wheat which has an abundance of starch, but is
+poor in gluten, cannot make a strong flour. This is the trouble
+with all soft wheats, both winter and spring. A wheat which is rich
+in gluten is hard, and in the case of our hard Minnesota wheat has
+a very tender bran. It is comparatively easy to make a strong
+flour, but it requires very careful milling to make a flour of good
+color from it. Probably the wheat which combines the most desirable
+qualities for flour-making purposes is the red Mediterranean, which
+has plenty of gluten and a tough bran, though claimed by some to
+have a little too much coloring matter, while the body of the berry
+is white. By poor milling a good wheat can be made into flour
+deficient both in strength and color, and by careful milling a
+wheat naturally deficient in strength may be made into flour having
+all the strength there was in the wheat originally and of good
+color. Good milling is indispensable, no matter what the quality of
+the wheat may be.</p>
+
+<p>The idea of gradual reduction milling was borrowed by our
+millers from the Hungarian mills. There is, however, this
+difference between the Hungarian system and gradual reduction, as
+applied in this country, that in the former, when fully carried
+out, the products of the different breaks are kept separate to the
+end, and a large number of different grades of flour made, while in
+the system, as applied in this country, the separations are
+combined at different stages and usually only three different
+grades of flour made, viz.: patent, baker's, or as it is termed in
+Minnesota, clear flour, and low grade or red dog. In the largest
+mills the patent is often subdivided into first and second, and
+they may make different grades of baker's flour, these mills
+approaching much nearer to the Hungarian system, though modifying
+it to American methods and machinery. In mills of from three to
+five hundred barrels daily capacity, it is hardly possible or
+profitable to go to this subdivision of grades, owing to the
+excessive amount of machinery necessary to handling the stuff in
+its different stages of completion. The Hungarian system has,
+therefore, been greatly modified by American millers and milling
+engineers to adapt it to the requirements of mills of average
+capacity. This modified Hungarian system we call gradual reduction.
+It can be profitably employed in any mill large enough to run at
+all on merchant work. So far it has not been found practicable to
+use it in mills of less than one hundred and twenty-five to one
+hundred and fifty barrels capacity in twenty-four hours, and it is
+better to have the mill of at least double this capacity.</p>
+
+<p>Gradual reduction, as its name implies, consists in reducing the
+wheat to flour, shorts, and bran, by several successive operations
+or reductions technically called breaks, the process going on
+gradually, each break leaving the material a little finer than the
+preceding one. Usually five reductions or breaks are made, though
+six or seven may be used. The larger the number of breaks the more
+complicated the system becomes, and it is preferable to keep it as
+simple as possible, for even at its simplest it requires a good,
+wide-awake thinking miller to handle it successfully. When it is
+thoroughly and systematically carried out in the mill it is without
+question as much in advance of the new process as that is ahead of
+the old style of milling.</p>
+
+<p>In order that I may convey to you as clear an idea of gradual
+milling reduction as possible, I will give as fully as possible the
+programme of a mill of one hundred and fifty barrels maximum daily
+capacity designed to work on mixed hard and soft spring wheat, and
+which probably will come much nearer to meeting the conditions
+under which you have to mill than any other I have found readily
+obtainable. I have chosen a mill of this size, first, because
+following out the programme of a larger one would require too much
+time and too great a repetition of details and not give you any
+clearer idea of the main principles involved, and secondly, because
+I thought it would come nearer meeting the average requirements of
+the members of your association. Your worthy secretary cautioned me
+that I must remember that I was going to talk to winter wheat
+millers. The main principles and methods of gradual reduction are
+the same, whether applied to spring or winter wheat; the details
+may have to be varied to suit the varying conditions under which
+different mills are operated. For this programme I am indebted to
+Mr. James Pye, of Minneapolis, who is rapidly gaining an enviable
+and well deserved reputation as a milling engineer, and one who has
+given much study to the practical planning and working of gradual
+reduction mills.</p>
+
+<p>And right here let me say that no miller should undertake to
+build a gradual reduction mill, or to change over his mill to the
+gradual reduction system, until he has consulted with some good
+milling engineer (the term millwright means very little nowadays),
+and obtained from him a programme which shall fit the size of the
+mill, the stock upon which it has to work, and the grade of flour
+which it is to make. This programme is to the miller what a chart
+is to the sailor. It shows him the course he must pursue, how the
+stuff must be handled, and where it must go. Without it he will be
+"going it blind," or at best only feeling his way in the dark. A
+gradual reduction mill, to be successful, must have a well-defined
+system, and to have this system, the miller must have a definite
+plan to work by. But to go on with my programme.</p>
+
+<p>The wheat is first cleaned as thoroughly as possible to remove
+all extraneous impurities. In the cleaning operations care should
+be taken to scratch or abrade the bran as little as possible, for
+this reason: The outer coating of the bran is hard and more or less
+friable. Wherever it is scratched a portion is liable to become
+finely comminuted in the subsequent reductions, so finely that it
+is impossible to separate it from the flour by bolting, and
+consequently the grade of the latter is lowered. The ultimate
+purpose of the miller being to separate the flour portion of the
+berry from dirt, germ, and bran it is important that he does not at
+any stage of the process get any dirt or fine bran speck or dust
+mixed in with his flour, for if he does he cannot get rid of it
+again. So it must be borne in mind that at all stages of flouring,
+any abrasion or comminution of the bran is to be avoided as far as
+possible.</p>
+
+<p>After the wheat is cleaned, it is by the first break or
+reduction split or cut open, in order to liberate the germ and
+crease impurities. As whatever of dirt is liberated by this break
+becomes mixed in with the flour, it is desirable to keep the amount
+of the latter as small as possible. Indeed, in all the reductions
+the object is to make as little flour and as many middlings as
+possible, for the reason that the latter can be purified, while the
+former cannot, at least by any means at present in use. After the
+first break the cracked wheat goes to a scalping reel covered with
+No. 22 wire cloth. The flour, middlings, etc., go through the
+cloth, and the cracked wheat goes over the tail of the reel to the
+second machine, which breaks it still finer. After this break the
+flour and middlings are scalped out on a reel covered with No. 22
+wire cloth. The tailings go to the third machine, and are still
+further reduced, then through a reel covered with No. 24 wire
+cloth. The tailings go to the fourth machine, which makes them
+still finer, then through a fourth scalping reel the same as the
+third. The tailings from this reel are mostly bran with some
+middlings adhering, and go to the fifth machine, which cleans the
+bran. From this break the material passes to a reel covered with
+bolting cloth varying in fineness from No. 10 at the head to No. 00
+at the tail. What goes over the tail of this reel is sent to the
+bran bin, and that which goes through next to the tail of the reel,
+goes to the shorts bin. The middlings from this reel go to a
+middlings purifier, which I will call No. 1, or bran middlings
+purifier. The flour which comes from this reel is sent to the chop
+reel covered at the head with say No. 9, with about No. 5 in the
+middle and No 0 at the tail. You will remember that after each
+reduction the flour and middlings were taken out by the scalping
+reels. This chop, as it is now called, also goes to the same reel I
+have just mentioned. The coarse middlings which go over the tail of
+this reel go to a middlings purifier, which I will designate as No.
+2. These go through the No. 0 cloth at the tail of the reel
+purifier No. 3; those which go through No. 5 cloth got to purifier
+No. 4; while all that goes through the No. 9 cloth at the head of
+the reel is dropped to a second reel clothed with Nos. 13 to 15
+cloth with two feet of No. 10 at the tail. The flour from this reel
+goes to the baker's flour packer; that which drops through the No.
+10 is sent to the middlings stone, while that which goes over the
+tail of the reel goes to purifier No. 4. We have now disposed of
+all the immediate products of the first five breaks, tracing them
+successively to the bran and shorts bins, to the baker's flour
+packer and to the middlings purifiers, a very small portion going
+to the middlings stone without going through the purifiers.</p>
+
+<p>The middlings are handled as follows in the purifiers. From the
+No. 1 machine, which takes the middlings from the fifth break, the
+tailings go to the shorts bin, the middlings which are sufficiently
+well purified go to the middlings stone, while those from near the
+tail of the machine which contain a little germ and bran specks go
+to the second germ rolls, these being a pair of smooth rolls which
+flatten out the germ and crush the middlings, loosening adhering
+particles from the bran specks. From the second germ rolls the
+material goes to a reel, where it is separated into flour which
+goes into the baker's grade, fine middlings which are returned to
+the second germ rolls at once, some still coarser which go to a
+pair of finely corrugated iron rolls for red dog, and what goes
+over the tail of the reel goes to the shorts bin. The No. 2
+purifier takes the coarse middlings from the tail of the first or
+chop reel as already stated. The tailings from this machine go to
+the shorts bin, some few middlings from next the tail of the
+machine are returned to the head of the same machine, while the
+remainder are sent to the first germ rolls. The reason for
+returning is more to enable the miller to keep a regular feed on
+the purifiers than otherwise. The No. 3 purifier takes the
+middlings from the 0 cloth on the chop reel. From purifier No. 3
+they drop to purifier No. 5. A small portion that are not
+sufficiently well purified are returned to the head of No. 3, while
+those from the head of the machine, which are well purified, are
+sent to the middlings stones. The remainder, which contain a great
+deal of the germ, are taken to the first germ rolls, in passing
+which they are crushed lightly to flatten the germ without making
+any more flour than necessary. The No. 4 purifier takes the
+middlings from No. 2 and also from No. 5 cloth on the chop reel and
+from the No. 10 on the tail of the baker's reel. The middlings from
+the head of this machine go to the middlings stones, and the
+remainder to purifier No. 6. The tailings from Nos. 3, 4, 5, and 6
+go to the red dog rolls. A small portion not sufficiently well
+purified are returned from No. 6 to the head of No. 4, while the
+cleaned middlings go to the middlings stones.</p>
+
+<p>The portions of the material which have not been traced either
+to the baker's flour or the bran and shorts bins are the middlings
+which have gone to the middlings stones, the germy middlings which
+have gone to the first germ rolls, and the tailings from purifiers
+Nos. 3, 4, 5, and 6, and some little stuff not quite poor enough
+for shorts from the reel following the second germ rolls. Taking
+these <i>seriatim</i>: the middlings after passing through the
+middlings stones, go to the first patent reel covered with eleven
+feet of No. 13 and four feet of No. 8. The flour from the head of
+the reel goes to the patent packer, that from the remainder of the
+reel is dropped to another reel, while the tailings go to the No. 4
+purifier. The lower patent reel is clothed with No. 14 and two feet
+of No. 10 cloth; from the head of the reel the flour goes to the
+patent packer, the remainder that passes through the No. 10 cloth
+which will not do to go into the patent, being returned to the
+middlings stones, while the tailings are sent to the No. 4
+purifier.</p>
+
+<p>The germ middlings, after being slightly crushed as before
+stated, are sent to a reel covered with five feet of No. 13 cloth,
+five feet of No. 14, and the balance with cloth varying in
+coarseness from No. 7 to No. 00. The flour from this reel goes into
+the patent, the tailings to the red dog rolls, the middlings from
+next the tail of the reel which still contain some germ to the
+second germ rolls, while the middlings which are free from germ go
+to the middlings stones.</p>
+
+<p>The tailings from purifiers 3, 4, 5, and 6, the material from
+the reel following the second germ rolls, which is too good for
+shorts, but not good enough to be returned into middlings again,
+and the tailings from the reel following the first germ rolls are
+sent to the red dog rolls, which, as I have stated, are finely
+corrugated. Following these rolls is the red dog reel. The flour
+goes to the red dog bin, the tailings to the shorts bin, while some
+stuff intermediate between the two, not fine enough for the flour
+but too good for shorts, is returned to the red dog rolls.</p>
+
+<p>This finishes the programme. I have not given it as one which is
+exactly suited to winter wheat milling. However, as I said before,
+the general principles are the same in either winter or wheat
+gradual reduction mills, and the various systems of gradual
+reduction, although they differ in many points, and although there
+are probably no two engineers who would agree as to all the details
+of a programme, the main ideas are essentially the same. The system
+has been well described as one of gradual and continued
+purification. In the programme above given the idea was to fit up a
+mill which should do a maximum amount of work of good quality with
+a minimum amount of expenditure and machinery. In a larger mill or
+even in a mill of the same capacity where money was not an object,
+the various separations would probably be handled a little
+differently, the flour and middlings from the first and fifth
+breaks being handled together, and those from the second, third,
+and fourth breaks being also handled together. The reason for this
+separation being that the flour from the first and fifth breaks
+contain, the first a great deal of crease dirt, and the fifth more
+bran dust than that from the other breaks, the result being a lower
+grade of flour. The object all along being to keep the amount of
+flour with which dirt can get mixed as small as possible, and not
+to lower the grade of any part of the product by mixing it with
+that which is inferior, always bearing in mind that the aim is to
+make as many middlings as possible, for they can be purified while
+the flour can not, and that whenever any dirt is once eliminated it
+should be kept out afterwards. This leads me to say that if a
+miller thinks the adoption of rolls or reduction machines is all
+there is of the system, he is very much mistaken. If anything, more
+of the success of the mill depends upon the careful handling of the
+stuff after the breaks are made, and here the miller who is in
+earnest to master the gradual reduction system will find his
+greatest opportunities for study and improvement. A few years back
+it was an axiom of the trade that the condition of the millstone
+was the key to successful milling. This was true because the
+subsequent process of bolting was comparatively simple. Now the
+mere making of the breaks is a small matter compared with the
+complex separations which come after. In the foregoing programme we
+had five breaks or successive reductions. Although this is better
+than a smaller number, I will here say that it is not absolutely
+essential, for very good work is done with four breaks. The mill
+for which this programme was made, including the building, cost
+about $15,000, and is designed to make about sixty per cent. of
+patent, thirty-five per cent. of baker's, and five per cent. of low
+grade, results which are in advance of many larger and more
+pretentious mills.</p>
+
+<p>One difficulty in the way of adapting the gradual reduction
+system to mills of very small capacity is that the various machines
+require to be loaded to a certain degree in order to work at their
+best. It is only a matter of short time when our milling inventors
+will design machinery especially for small mills; in fact they are
+now doing it, and every day brings it more within the power of the
+small miller to improve his manner of milling. To show what can be
+done in this direction I will briefly describe a mill of about
+ninety barrels maximum capacity per twenty-four hours, which is as
+small as can be profitably worked. I will premise this description
+by saying it is designed with a view to the greatest economy of
+cost, the best trade of work, and to reduce the amount of machinery
+and the handling of the stuff as much as possible. This latter
+point is of much importance in any mill, either large or small, no
+matter upon what system it is operated, for it takes power to run
+elevators and conveyors, and especially in elevating and conveying
+middlings, especially those made from winter wheat, their quality
+is inured and a loss incurred, by the unavoidable amount of flour
+made by the friction of the particles against each other. So much
+is this the case that in one of our largest mills it is deemed
+preferable to move the middlings from one end of the mill to the
+other by means of a hopper bin on a car which runs on a track
+spiked to the floor, rather than to employ a conveyor. A mill built
+as I am going to describe would require from fifty to sixty
+horse-power to run it, and including steam power and building would
+cost from $10,000 to $12,000, according to location. I give it as
+of interest to those among your number who own small mills and may
+contemplate improving them.</p>
+
+<p>The building is four stories high, including basement, and
+thirty-two feet square. It would be some better to have it larger,
+but it is made this small to show how small a space a mill of this
+size can be made to occupy. No story is less than twelve feet high.
+The machinery Is very conveniently arranged, and there is plenty of
+room all around. The system is a modification of the gradual
+reduction system, the middlings being worked upon millstones. The
+first break is on one pair of 9 x 18 inch corrugated iron rolls,
+eight corrugations to the inch, the corrugations running parallel
+with the axis of the rolls. The second break on rolls having twelve
+corrugations to the inch, the third sixteen, and the fourth twenty
+to the inch, while the fifth break, where the bran is finally
+cleaned, has twenty-four corrugations to the inch. The basement
+contains the line shaft and pulleys for driving rolls, stones,
+cockle machine, and separator. The only other machinery in the
+basement is the cockle machine. The line shaft runs directly
+through the center of the basement, the power being from engine or
+water wheel outside the building. The first floor has the roller
+mills in a line nearly over the line shaft below, the middlings
+stones, two in number, at one side opposite the entrance to the
+mill, the receiving bin at one side of the entrance in the corner
+of the mill, and the two flour packers for the baker's and patent
+flour in the other corner. This arrangement leaves over half of the
+floor area for receiving and packing purposes. The bolting chests,
+one with six reel and the other with three reel begin on the second
+floor and reach up into the attic. An upright shaft from the line
+shaft in the basement geared to a horizontal shaft running through
+the attic parallel with the line shaft below, comprise about all
+the shafting there is in the mill. There is a short shaft on the
+second floor from which the two purifiers on this floor and the two
+in the attic are driven, and another short shaft on the first floor
+to drive the packers. There are four purifiers, two on the second
+floor, and two more directly over them in the attic. The elevator
+heads are all directly upon the attic line shaft, and the bolting
+chests are driven by uprights dropped from this shaft. The combined
+smutter and brush machine is on the third floor at one end of the
+bolting chests and directly over the stock hoppers. This comprises
+all the machinery in the mill. The programme is about as
+follows:</p>
+
+<p>The break reels are clothed as follows: First break No. 20, wire
+cloth, second break No. 22, third break No. 24, and fourth break
+No. 24. The material passing through these scalping reels, now
+called chop, goes to a series of reels, the first clothed with Nos.
+6, 4, and 0. The material passing over the tail is sent to the germ
+purifier, that passing through Nos. 4 and 0, to the coarse
+middlings purifier, and that through the No. 6 goes to the reel
+below clothed with Nos. 12 and 13. Some nice granular flour is
+taken off from this reel; the remainder, which passes over the tail
+and through the cutoffs, goes to the next reel below clothed with
+Nos. 14, 15, and 9. Some good flour comes from the 14 and 15; that
+which passes through the 9 goes at once to the stones without
+purifying, while that which passes over the tail is sent to the
+fine middlings purifiers.</p>
+
+<p>After the purification, the middlings are ground on stones and
+bolted on Nos. 13 and 14 cloth, after having been scalped on No 8.
+The germ middlings are crushed on smooth rolls and bolted on Nos.
+12 and 13. What is not crushed fine enough goes with poor tailings
+to the second germ rolls, and from these to a reel by themselves or
+to the fifth reduction or bran reel. A mill of this kind could be
+made much more perfect by an expenditure of two or three thousands
+dollars more. I have instanced it to show what can be done with
+gradual reduction in a very small way.</p>
+
+<p>In mills of from three hundred to five hundred barrels capacity
+and still larger, the programme differs considerably from that I
+have sketched, the middlings being graded and handled with little,
+if any, returning, and are sized down on the smooth rolls, a much
+larger percentage of the work of flouring being done on millstones.
+For a three hundred barrel roller mill, the following plant is
+requisite: five double corrugated roller mills, five double smooth
+roller mills, three pairs of four foot burrs sixteen purifiers,
+four wire scalping reels, six feet long, one reel for the fifth
+break, one reel for low grade flour, eight chop reels, seven reels
+for flour from smooth rolls, three reels for the stone flour, two
+grading reels, three flour packers, and necessary cleaning
+machinery. The reels are eighteen feet thirty-two inches. The
+programme is necessarily more complicated.</p>
+
+<p>When it comes to the machinery to be employed in making the
+reductions or breaks, the miller has several styles from which to
+choose. Which is best comes under the head of what I don't know,
+and moreover, of that which I have found no one else who does know.
+Each machine has its good points, and the mill owner must make his
+own decision as to which is best suited to his purpose. The main
+principles involved are to abrade the bran as little as possible
+while cleaning it thoroughly, and to make as little break flour,
+and as many middlings as possible, the latter to be made in such
+shape as to be the most easily purified. Regarding the difference
+between spring and winter wheat for gradual reduction milling, it
+may be stated something after this manner: Spring wheat has a
+thinner and more tender bran, makes more middlings because it is
+harder, and for the same reason the flour is more inclined to be
+coarse and granular. In milling with winter wheat, especially the
+better varieties, there will be more break flour made, the
+middlings will be finer with fewer bran specks, and the bran more
+easily cleaned, because it will stand harsher treatment. Winter
+wheat, moreover, requires more careful handling in making the
+breaks, not because of the bran, but to avoid breaking down the
+middlings, and making too much and too fine and soft break flour.
+In order to keep the flour sharp and granular, coarser cloths are
+used in bolting, and because the middlings are finer the bolting is
+not so free and a larger bolting surface is required. In milling
+either spring or winter wheat there should be ample purifying
+capacity, it being very unwise to limit the number of machines, so
+that any of them will be overtaxed. The day has gone by when one
+purifier will take care of all the middlings in the mill.</p>
+
+<p>There is one point which is of much interest to mill owners who
+wish to change their mills over to the gradual reduction process,
+that is, how far they can utilize their present plan of milling
+machinery in making the change. Of course the cleaning machinery is
+the same In both cases, so are the elevators, conveyors, bolting
+chests, etc. But to use the millstone is a debatable question.
+After carefully considering the matter I have come to the
+conclusion that it has its place, and an important one at that,
+under the new regime, viz., that of reducing the finer purified
+middlings to flour. The reason for this lies in the peculiar
+construction of the wheat berry. If the interior of the berry were
+one solid mass of flour, needing only to be broken up to the
+requisite fineness, it could be done as well on the rolls. But
+instead of this, as is well known, the flour part of the berry is
+made up of a large number of granules or cells, the walls of which
+are cellular tissue, different from the bran in that it is soft and
+white instead of hard and dark colored. It is also fibrous to a
+certain extent, and when the fine middlings are passed between the
+rolls instead of breaking down and becoming finer, it has a
+tendency to cake up and flatten out, rendering the flour soft and
+flaky. It does not hurt the color, but it does hurt the strength.
+When the millstone is used in place of the roll the flour is of
+equally good color, and more round and granular. I know that in
+this the advocates of smooth rolls will differ from my conclusions,
+but I believe that the final outcome will be the use of millstones
+on the finer middlings, and in fact on all the middlings that are
+thoroughly freed from the germ.</p>
+
+<p>It has been said that that which a man gives the most freely and
+receives with the worst grace is advice. I will, however, close
+with a little of the article which may not be wholly put of place.
+If you have a mill do not imagine that the addition of a few pairs
+of rolls, a purifier or two, and a little overhauling of
+bolting-chests, is going to make it a full-fledged Hungarian roller
+mill. If you are going to change an old mill or build a new one, do
+not take the counsel or follow the plans of every itinerant miller
+or millwright who claims to know all about gradual reduction. No
+matter what kind of a mill you want to build, go to some milling
+engineer who has a reputation for good work, tell him how large a
+mill you want, show him samples of the wheat it must use and the
+grades of flour it must make, and have him make a programme for the
+mill and plan the machinery to fit it. Then have the mill built to
+fit the machinery. When it starts follow the programme, whether it
+agrees with your preconceived notions or not, and the mill will, in
+ninety-nine cases out of one hundred, do good work.</p>
+
+<hr>
+<p><a name="5"></a></p>
+
+<h3>MACHINE FOR DOTTING TULLES AND OTHER LIGHT FABRICS.</h3>
+
+<p>Dotted or chenilled tulles are fabrics extensively used in the
+toilet of ladies, and the ornamentation of which has hitherto been
+done by the application to the tissue, by hand, either of chenille
+or of small circles previously cut out of velvet. This work, which
+naturally takes considerable time, greatly increases the cost price
+of the article.</p>
+
+<p>A few trials at doing the work mechanically have been made, but
+without any practical outcome. The workwomen who do the dotting are
+paid at Lyons at the rate of 80 centimes per 100 dots; so that if
+we take tulle with dots counter-simpled 0.04 of an inch, which is
+the smallest quincunx used, and suppose that the tissue is 31
+inches wide and that the daily maximum production is one yard, we
+find that 400 dots at 80 centimes per 100 = 3 francs and 20
+centimes (about 63 cents), the cost of dotting per yard. It is true
+that the workwoman furnishes the velvet herself.</p>
+
+<p>Mr. C. Ricanet, of Lyons, has recently invented a machine with
+which he effects mechanically the different operations of dotting,
+not only on tulles but also upon gauzes or any other light tissues
+whatever, such as those of cotton, silk, wool, etc. Aided by a
+talented mechanic, Mr. Ricanet has succeeded in constructing one of
+those masterpieces of wonderfully accurate mechanism of which the
+textile industry appears to have the monopoly--at least it is
+permissible to judge so from the remarkable inventions of
+Vaucanson, Jacquard, Philippe de Girard, Heilmann, and others.</p>
+
+<p>The object of this new machine, then, which has been doing its
+wonderful work for a few days only, is to reproduce artificially
+chenille embroidered on light tissues, by mechanically cutting out
+and gluing small circles of velvet upon these fabrics.</p>
+
+<p>For this purpose all kinds of velvet may be employed, and, in
+order to facilitate the cutting, they are previously coated on the
+reverse side with any glue or gum whatever, which gives the velvet
+a stiffness favorable to the action of the punch. To effect the
+object desired the apparatus has three successive operations to
+perform: first, cutting the circles; second, moistening; and third,
+fastening down the dots upon the tissue according to a definite
+order and spacing. The machine may be constructed upon any scale
+whatever, although at present it is only made for operating on
+pieces 31 inches wide, that being the normal width of dotted
+tulles. The quincuncial arrangement of the dots is effected by the
+punching, moistening, and fastening down of odd and even dots,
+combined with the forward movement of the tissue to be
+chenilled.</p>
+
+<p>The principal part of the machine is the cam-shaft, A (Figs. 1,
+2, and 3), which revolves in the direction of the arrows and passes
+in the center of 80 cam-wheels, 40 of which are odd and 40 even,
+alternately opposed to each other. This shaft actuates, through its
+two extremities, the different combined motions in view of the
+final object to be attained, and also carries the motive pulleys,
+PP'. Figs. 1 and 2 show the profile of two of these opposed
+cam-wheels--the arrangement by means of which two rows of dots (odd
+and even) are laid down upon the tissue during one revolution of
+the shaft or drum, A. Each of the wheels carries three cams (Figs.
+1 and 3), the first, (<i>a</i>), corresponding to the punching; the
+second, (<i>a'</i>), to the moistening, and the third,
+(<i>a''</i>), to the gluing down of the dots.</p>
+
+<p>The annexed figure, one-quarter actual size, shows in section
+the details of the cutting mechanism. To each cam-wheel there
+corresponds one punch, and the eighty punches are arranged side by
+side and parallel upon a shaft, B, a spring, <i>b</i>, holding them
+constantly against the circumference of the cam-wheels. In Fig. 2
+only one of these details is shown. The punching arrangement
+consists of an ordinary punch, <i>c</i>, of variable diameter,
+screwed to the extremity of a tube, <i>d</i>, which is itself
+suspended from the end of the lever, <i>p</i>, but which can
+receive from it at the desired moment the pressure necessary to
+effect the cutting. The vertical position of these multiple tubes
+is insured by a guide, <i>e</i>, which is thoroughly indispensable.
+Through each of the tubes, <i>d</i>, there passes a plunger
+designed for expelling from the punch the piece that has been cut
+out of the velvet, and for gluing it down to the fabric. The two
+small springs, <i>b'</i> and <i>b''</i>, tend continually to lift
+the tubes as well as the plunger. The whole mechanism is affixed to
+solid cast-iron frames, and the machine itself may be mounted on
+wooden supports or a metal frame.</p>
+
+<p>The punching is effected on a bronze straight-edge, C, which
+slides in a cast-iron channel, D. This presents alternately, in its
+movement, entire and punctured spaces, the former for receiving the
+blow of the punch and the latter for allowing passage at the
+desired moment to the plunger as it goes to fasten the dots upon
+the tulle which is passing along underneath the channel, D. The
+punching is done primarily and principally by pressure, but, in
+order to facilitate the complete detachment of filaments which
+might retain the punched-out piece, the punch is likewise given at
+the same time a slight rotary motion, thus imitating mechanically
+what is performed by hand in the maneuver of all punches. This
+rotary motion is communicated to the punches by means of levers
+actuated by an eccentric, E, and which move the frame, <i>h</i>,
+whose bars engage with the horizontal lever, <i>g</i>, soldered to
+the tube, <i>d</i>, thus causing the latter at the very moment the
+punch descends to revolve from right to left. The forty punches in
+operation cause the frame to return to its initial position through
+the action of the springs, <i>b'</i>. We say forty, since the
+inventor, in principle, has admitted 80 punches, operating 40 as
+odd and 40 as even; obtaining in this way a dotting in a regular
+quincunx of one yard, that is to say, 80 dots arranged in two rows
+on a fabric 31 inches wide. But it is evident that a much larger
+quincunx may be had by putting in play only a half, a third, or a
+fourth of the punches, and causing the tulle and velvet to advance
+proportionally. For this purpose it is only necessary to unscrew
+the punches which are not to act, and to substitute for the ratchet
+wheel which controls the unrolling of the I tulle, another having a
+number of teeth proportioned to the desired spacing of the
+dots.</p>
+
+<p>The punching having been executed, and the drum, A, continuing
+to revolve, the punches rise a little owing to the conformation of
+the cam-wheel, and through the action of the springs, <i>b</i>, and
+allow the moistener to move forward to dampen the little circles
+which remain at the orifice of the punches. The moistener or
+dampener is a sort of pad equal in length to the field of action of
+the punches, and is affixed to a cross-bar, F, which is connected
+at its two extremities with the levers, G, that are actuated by the
+cam-wheels, H. These cam-wheels, or eccentrics, H, which are
+mounted on the shaft of the drum, A, cause the moistener to move
+forward as soon as the punches rise after operating, and, when it
+arrives beneath the punches, the larger cams, <i>a</i>, of the
+cam-wheels, A, press the latter upon the pad and thus effect the
+dampening of the circles of velvet.</p>
+
+<p>Immediately afterwards, the same eccentrics, H, acting on a
+lever, I, uncover the holes in the straight-edge, C, and the
+channel, D. The large cams, <i>a"</i>, of the wheel, A, then acting
+very powerfully upon the respective punches, cause these latter to
+pass through the orifices so that the extremity of each punch comes
+within about one twenty-fifth of an inch of the fabric to be
+dotted. In this passage of the tube, <i>d</i>, a small rod,
+<i>i</i>, connected by a lever with the plunger, <i>f</i>, is made
+to abut against the guide, <i>e</i>, thus causing the descent of
+the plunger to a sufficient degree to push the velvet "dot" out of
+the tube and to glue it upon the fabric. The manner in which these
+operations are performed being now well enough understood, let us
+for a moment examine the motions of the fabrics to be cut and
+dotted--the first being velvet or any other material, even metal
+(goldleaf, for example), and the second, the tulle.</p>
+
+<p>The latter has but one motion, and that is in the direction of
+its length, while the velvet has, in addition to this same motion,
+another slight one from right to left in the direction of its width
+in order to diminish waste as much as possible.</p>
+
+<p>The tulle to be dotted is first wound around a roller, R, from
+whence it passes over the glass guide-roller, R', and between the
+channel, D, and the table, T, to the roller, R", which is heated by
+steam.</p>
+
+<p>The hot air which is radiated dries the dots, and from thence
+the fabric is taken up by other rollers or by any other method. The
+steam roller, R", carries at one of its extremities a ratchet wheel
+whose teeth vary in number according to the greater or less
+rapidity with which the tulle is unrolled. It is actuated by a
+lever which receives its motion from the eccentric, K.</p>
+
+<p class="ctr"><a href="images/6a.png"><img src=
+"images/6a_th.png" alt=
+"IMPROVED MACHINE FOR DOTTING TULLAND OTHER LIGHT FABRICS.">
+</a></p>
+
+<p class="ctr">IMPROVED MACHINE FOR DOTTING TULLAND OTHER LIGHT
+FABRICS.</p>
+
+<p>In the table, T, there is a rectangular receptacle, <i>t</i>,
+containing rasped or powdered velvet for the purpose of forming a
+reverse of the dot. This powder attaches itself to the gum and
+imitates on the wrong side of the fabric a dot similar to that on
+the upper or right side. The velvet is wound upon the roller,
+<i>r</i>, and from thence passes under the guiding roller,
+<i>r'</i>, the punches, and the second roller, <i>r"</i>. These two
+latter rollers are solidly connected by a straight-edge fixed at
+the extremity of the lever, L, whose other end is in continuous
+correlation with the eccentric, M, which controls the lateral
+displacements; while the eccentric, O, actuates, by means of the
+screw, Q, and the ratchet-wheel, S, the longitudinal advance of the
+velvet. The eccentric, M, is fixed upon an axle, A', which carries
+a wheel, U, having teeth inclined with respect to its axis, and
+which derives its motion from the Archimedean screw, N, fixed at
+one of the extremities of the cam-shaft, A.</p>
+
+<p>We have stated above that the maximum daily hand production of
+tulle dotted in quincunxes of 0.04 of an inch is about one yard. At
+the rate of 30 revolutions per minute, and for the same article as
+that just mentioned, this dotting machine is capable of producing,
+theoretically, 360 yards per 10 hours; but practically this
+production is reduced to about 250 yards, which, however, is
+sufficiently satisfactory.</p>
+
+<hr>
+<p><a name="6"></a></p>
+
+<h2>THE REPRODUCTION AND MULTIPLICATION OF NEGATIVES.</h2>
+
+<h3>By ERNEST EDWARDS, B.A.</h3>
+
+<p>A question, relative to the subject of reproducing negatives,
+which was put at a meeting of one of your New York societies,
+prompts me to make a few remarks on the subject.</p>
+
+<p>Among the numerous and widely diversified ramifications of our
+business (the Heliotype Printing Company) we have very often to
+reproduce and multiply negatives in both a direct and reversed
+form. Various methods for doing this have been tried, and I may
+here say that I am quite well aware of all the methods that have
+hitherto been suggested for the purpose, but that which I am to
+describe is the one to which preference has been given, and which
+is that known as the carbon process.</p>
+
+<p>A sheet of carbonized paper or "tissue," having been sensitized
+by immersion in a bath of bichromate of potash, is dried in the
+dark and placed away for future use, although it is undesirable
+that it be kept for more than four or five days. This is placed in
+a printing frame in contact with the negative and exposed for a few
+minutes, after which it is immersed in water, squeegeed down upon a
+glass plate, and developed with warm water in the way so well known
+to carbon printers. The result is a transparency which, owing to
+having received a sufficient exposure, should show every detail of
+the negative. The nature of the tissue employed for such a purpose
+must be such as to give no strong contrasts, but everything
+reproduced with soft and fine gradation of tone.</p>
+
+<p>The transparency thus obtained forms the <i>clich&eacute;</i> by
+which the negatives are subsequently made; and a negative of any
+size may be obtained by the camera on wet or dry plates. The
+transparency must, of course, be pointed to the sky and the light
+transmitted through it, no other light being allowed to reach the
+lens except that which passes through the carbon transparency. Care
+must also be taken that the transparency is <i>uniformly</i>
+lighted. If it is not possible to obtain a northern light, which is
+best, a reflector of white paper or card may be used which must be
+sufficiently large and placed at an angle of about forty-five
+degrees to the transparency.</p>
+
+<p>If the repeated negative is to be of the same size as the
+original it may be readily produced by repeating the operation of
+printing on carbon tissue, using the transparency in place of the
+negative, or using a dry plate in place of the tissue. But on the
+whole I have satisfied myself that the best results are to be
+obtained by the first method. There is a greater softness in the
+latter method, but a greater character and similarity to the
+original in the former method. There is no doubt that the use of
+the carbon transparency removes the hardness and riffidness of the
+outlines peculiar to the older method of a collodion transparency,
+while with carbon as the medium it is difficult for any but the
+most experienced eye to distinguish the copy from the
+original.--<i>Photo Times.</i></p>
+
+<hr>
+<p><a name="7"></a></p>
+
+<h2>A NEW METHOD OF MAKING GELATINE EMULSION.</h2>
+
+<p>Since gelatine emulsion first came into use one of the greatest
+troubles in connection with the manufacture of it has been that of
+washing. According to the first methods the time taken for this
+part of the process was, I believe, about twenty-four hours. It was
+very much reduced and the ease of manufacture greatly facilitated
+by the methods now most generally used, and which were, I believe,
+first communicated by Messrs. Wratten and Wainright. I refer to
+those of precipitating with alcohol and of straining the emulsion,
+when set, through canvas, so as to divide it very finely. When the
+latter method is resorted to a comparatively short time is
+sufficient to wash it. This method, although a great improvement
+upon the older ones, yet leaves much to be desired, especially for
+those who are not in the habit of making emulsion regularly, but
+only an occasional batch. When the weather is at all warm it takes
+a long time for the emulsion to set, unless ice be used, and when
+once it is set the washing process is an exceedingly "messy" one
+unless the water be cooled with ice; and the amount of water taken
+up during washing is often so great that there is considerable
+difficulty in getting the emulsion to set on the plates. In fact,
+even in cold weather, it is not an easy process to conduct in the
+necessary near approach to total darkness.</p>
+
+<p>Considerable suspicion has of late been thrown upon the
+thoroughness of the alcohol method, unless the emulsion has,
+previous to precipitation, been freed of the greater part of the
+soluble salts by washing; that is to say, it is doubtful whether
+the whole of the soluble salts can be eliminated by the process,
+and, therefore, unless in exceptionally hot weather, it would seem
+best not to trust to it, except as a further security against
+soluble bromide and nitrate after washing. Besides this, the
+consumption of alcohol is very large. Almost three times the amount
+of the emulsion precipitated is required, and this, even when
+methylated spirit is used, adds considerably to the expense. With a
+view of doing away with the washing altogether, or, rather, of
+washing of the silver bromide when not incorporated with the
+gelatine, several processes have been invented. By these silver
+bromide is obtained in a very fine state of division, ready to mix
+with gelatine and water in any proportion.</p>
+
+<p>The best known of them is Captain Abney's very ingenious
+glycerine method, which seems to have been thoroughly successful in
+his hands, although it has not been in every one's. The silver
+bromide obtained by his process is not highly sensitive, and
+requires boiling with gelatine before it is in a fit state to make
+a rapid plate.</p>
+
+<p>We have lately had described in these columns a method of
+obtaining bromide in a highly-sensitive state by means of the use
+of an acid, whereby, after emulsifying and boiling, the viscosity
+of the gelatine was destroyed, and the bromide in time deposited
+itself. During the late hot weather, when washing became almost
+impossible, I was led to cast about for some method of eliminating
+the soluble salts less tedious and "sloppy" than that of washing,
+more certain and less expensive than that of precipitating the
+whole of gelatine with alcohol, and which would take less time than
+the method of obtaining the bromide in a pure form.</p>
+
+<p>My first idea was to make up the solutions used in emulsifying
+in a very concentrated form, and, after emulsifying, boiling, and
+allowing to cool, to add to the thin emulsion thus obtained
+gelatine to the amount of twenty grains to the ounce, and to
+precipitate this with alcohol, the rest of the gelatine required to
+make up the bulk being afterwards added, and the whole thoroughly
+incorporated by warming and shaking. I was thus successful in
+reducing the amount of alcohol required to one-third of what would
+be necessary if the whole of the emulsion were precipitated; but
+still I found that, if a reliable emulsion were required, the
+pellicle as formed had to be washed to free it from the last trace
+of soluble salts.</p>
+
+<p>It now struck me that it might be possible to precipitate the
+bromide of silver direct from a very weak solution of gelatine, and
+obtain it in such a form that it might be filtered, washed, and in
+every way treated as an ordinary precipitate. I tried the following
+experiment. I took--</p>
+
+<pre>
+    1. Silver nitrate....................... 200  grains
+        Water...............................   1&frac12; ounce.
+    2. Ammonia bromide...................... 120  grains.
+       Water................................   1&frac12; ounce.
+       Gelatine.............................  12  grains.
+</pre>
+
+<p>I emulsified the two together in the usual way, allowed the
+whole to cool, and then poured the thin emulsion into about ten
+ounces of alcohol, stirring the while. As I had anticipated, a
+flocculent precipitate was formed, which settled to the bottom of
+the vessel in a few minutes. This was, in fact, sensitive bromide
+of silver mixed with a very small quantity of gelatine (about five
+per cent.), and could, I found, be treated in the same manner as a
+bromide precipitate from an aqueous solution; it might be washed,
+either by decantation or by filtration, easily dried, and doubtless
+could, when dry, be kept for an indefinite time, and be at any time
+used by mixing with gelatine and water in any proportion thought
+fit.</p>
+
+<p>I found that a less amount of gelatine than four grains to the
+ounce was sufficient to carry the bromide down, while five grains
+to the ounce carried it down in something which I considered too
+near an approach to a plastic mass.</p>
+
+<p>It will be noticed that in the experiments which I have
+described the emulsion had not been boiled, so that the
+sensitiveness of the bromide was probably not great. As the
+experiment was done in daylight it was of no practical use for
+making emulsion; but I have since made several batches in this
+manner and have found them most satisfactory.</p>
+
+<p>When sensitiveness is sought by boiling I rind it necessary to
+add a small quantity of gelatine after boiling and before
+precipitating, as that which has been kept for some time at a high
+temperature seems to have lost the viscosity necessary to carry
+down the silver bromide in such a form that it can he easily
+separated from the alcohol and water.</p>
+
+<p>The practical manner of making an emulsion by this method may be
+as follows. Make up the following mixtures:</p>
+
+<pre>
+  I.
+  Silver nitrate...........................................400 grains.
+  Water..................................................... 3 ounces.
+<br>
+  II.
+<br>
+  Ammonia bromide..........................................240 grains.
+  Gelatine..................................................24 grains
+  Water..................................................... 3 ounces.
+  Hydrochloric acid enough to slightly acidify the solution.
+<br>
+  III.
+  Gelatine................................................. 20 grains.
+  Water....................................................  &frac12; ounce.
+  IV.
+<br>
+  Hard gelatine (say Nelson's X opaque,
+  or Mr. A. L. Henderson's)................................240 grains.
+  Soft gelatine (Nelson's No.1)........................... 240 grains.
+  Water.....................................................24 ounces.
+</pre>
+
+<p>Nos. II., III., and IV. are allowed to stand until the gelatine
+is softened. No. I is then warmed in a hock bottle until the
+gelatine is just melted, when No. II. is poured into it, a little
+at a time, with vigorous shaking, until the whole is emulsified. It
+is then transferred to an ordinary jelly can, which is placed in a
+saucepan half full of water over a ring Bunsen burner in the dark
+room, and boiled for half an hour. It is then allowed to cool to
+about 100&deg; Fahr., when No. III. is added. The whole is then
+allowed to get quite cool, when it is poured, with stirring, into
+about one pint of methylated spirit. If it be wished the
+precipitate may now be filtered out and washed at once like an
+ordinary filtrate, but I prefer to allow it to settle, which it
+will do in about five minutes. The supernatant fluid is then gently
+poured off.</p>
+
+<p>This fluid will have the appearance of still containing a
+considerable amount of the silver bromide; but if it be kept and
+filtered it will be seen that the quantity is really so small that
+it may be disregarded. We all know what an alarming quantity of
+silver seems to be going down the sink when we wash vessels to
+which a very small quantity of emulsion is adhering. If filtering
+be resorted to the liquid which comes through will be quite clear.
+This was somewhat unexpected by me, as, if an emulsion containing
+the whole of the gelatine be precipitated into alcohol in the usual
+way, the alcohol becomes milky with a substance which could not, I
+imagine, be filtered from it.</p>
+
+<p>Two or three ounces of methylated spirit are now added to the
+vessel containing the silver bromide, and the latter well mixed
+with it. This makes the precipitate "firmer"--if such an expression
+be allowable--and this time it will sink to the bottom almost
+immediately after the stirring has ceased, and the alcohol may be
+poured off.</p>
+
+<p>I consider that the bromide in this state is practically free
+from soluble salts, but it may be washed with one or two changes of
+water if desired.</p>
+
+<p>No. IV. is now gently heated till the gelatine is melted and the
+precipitate mixed with it. It must be kept warm for some time, and
+shaken vigorously until all granularity has disappeared, This is,
+of course, ascertained by placing a drop of the emulsion on a piece
+of glass, and examining it. If it be wished to keep the bromide of
+silver for future use it may be placed on a piece of muslin
+stretched in the drying-box, when it will dry in a very short time;
+and, although I cannot speak from experience on this point, it
+will, I have no doubt, keep for an indefinite time so long as light
+is kept from it.</p>
+
+<p>If it be desired the ammonio-nitrate method may be used instead
+of the boiling one, although in my hands it does not give such
+sensitiveness. If it be desired to use this method, solution Nos.
+I, II., and IV. are made up exactly as for the boiling method,
+except that No. II. is not acidified. Liquid ammonia is then poured
+with stirring into the silver solution, until it blackens and again
+clears. Emulsification is performed exactly as described above, but
+instead of boiling, the emulsion is kept at a temperature of about
+100&deg; Fahr. for half an hour, when it is poured into the
+alcohol, no addition of gelatine being previously made.</p>
+
+<p>I think I may claim for the method which I have just described
+that it is less troublesome and more certain than either the
+ordinary washing method or the usual one of precipitating with
+alcohol, while it affords an easy method of making sensitive silver
+bromide in such a form that it can be more easily stored and
+afterwards manipulated than if it were in the form of pellicle. The
+whole of the soluble salts are eliminated, and also any gelatine
+which may have been destroyed in the cooking. The amount of alcohol
+used is comparatively small; in fact, to prepare silver bromide for
+a pint of emulsion very little more than a pint of methylated
+spirit is required. Besides this I do not think that I would be
+wrong in saying that the chance of green fog is reduced to a
+minimum.</p>
+
+<p>Let me take this opportunity of thanking Captain Abney for his
+prompt reply to my question about the connection between the
+proportion of bromide to gelatine in emulsions, and the density of
+resulting images.--<i>W. K. Burton, in British Journal of
+Photography</i>.</p>
+
+<hr>
+<p><a name="15"></a></p>
+
+<p class="ctr"><img src="images/7a.png" alt=
+"Old Wrought Iron Gates, Guildhall."></p>
+
+<p class="ctr">Old Wrought Iron Gates, Guildhall.</p>
+
+<hr>
+<p><a name="8"></a></p>
+
+<h2>THE POTTERY AND PORCELAIN INDUSTRIES OF JAPAN.</h2>
+
+<p>Japanese chronicles claim that the first pottery was made in the
+year 660 B.C.; it was not, however, until the Christian era that
+the art made any considerable advances. In the year 1223 A.D.,
+great improvements were made in manufacture and decoration of the
+ware. From that date to the sixteenth century the great potteries
+of Owari, Hizen, Mino, Kioto, Kaga, and Satsuma were established.
+The Rahn-Yaki, or crackled ware, was first made at Kioto, at the
+commencement of the sixteenth century. The best old Hizen ware,
+that which is still the most admired, was made at Arita Hizen, in
+1580 to 1585; the old Satsuma dates from 1592. Consul-General Van
+Buren states that porcelain clays are found in nearly all parts of
+the country, and the different kinds are usually found in close
+proximity, and close to canals and rivers, which is of considerable
+advantage, as affording a means of transport. In all cases every
+variety of clay used in the manufacture of pottery is found in a
+natural state; there is no necessity to manufacture the quartzose
+or fusible clays as is done in other parts of the world, and which
+adds considerably to the cost of the ware. One of the peculiarities
+in the clay found in Japan is that it contains both the fusible and
+infusible materials in such proportions as to make a light,
+beautiful, translucent, and durable porcelain. At Arita, in Hizen,
+there is a clay found which contains 783/4 per cent, of silica, and
+l73/4 per cent, of alumina; from this clay is made the delicate,
+translucent eggshell ware, without the addition of any other
+matter. From an adjoining bluff a clay is taken which has 50 per
+cent, of silica, and 38 per cent, of alumina; from this the common
+porcelain is made.</p>
+
+<p>Potter's clay is found in very large quantities in the provinces
+of Yamashiro, Hoki, Turoo Iyo, Hizen, Higo, Owari, Mikaera, Idyn,
+Musashi, and Mino. In the whole of Japan there are 283 localities
+where the clay is deposited; many of these only furnish inferior
+clays, but they are all fitted for use in some of the various kinds
+of pottery. These clays are thoroughly powdered by means of what is
+called "balance pounders," worked in some localities by
+water-power, but the work is often done by hand. The powder is then
+dried, and stored on boards or in flat boxes. This dough does not
+go through the process of fermentation. The shaping is almost
+exclusively done on the potter's wheel, which is set on a pivot
+working in a porcelain eye. As a rule, the wheel is turned by the
+potter himself, but in Hizen it is kept in motion by means of a
+band connected with its pivot and another wheel turned by a boy. In
+making dishes of other shape than round, a crude mould is sometimes
+used. After the clay has been shaped on the wheel, it is set away
+for drying, and usually in two or three days it is considered
+sufficiently dry for smoothing, which is done on the wheel with a
+sharp curved knife. The material is now made into "bisque," or
+biscuit, by a preliminary baking in small ovens, when it is ready
+for painting, if it is to be painted on the biscuit; if not, it is
+ready for the glazing. In either event it will then go to the large
+furnace for the final baking. The kilns for this purpose are always
+built on hill sides, and are joined together, increasing in size
+from the lower to the higher ones, and in number from four to
+twenty five; these kilns are so constructed that the draught is
+from the lowest one, in addition to which each kiln has its own
+firing place. The result of this construction is that the upper
+ones are by far the most heated, and the ware is arranged
+accordingly; that which requires the least baking, in the lower
+kiln, and that which requires the greatest heat, in the upper.
+These connecting kilns have the merit of being heat saving, but
+they are usually small and badly constructed, and the heat in none
+of them is uniform.</p>
+
+<p>The glaze is made from the silicious clay and potash extracted
+from wood ashes. This potash is not a pure white, and this accounts
+for the dirty color usually to be observed in unpainted Japanese
+ware. In different districts the painting varies. For instance, in
+Owari, the greater part of the ware is painted a cobalt blue--the
+cobalt ore being found in the bluffs near the clay deposits, and is
+used for painting the cheaper wares, and for this purpose German
+cobalt is also employed. The painting with cobalt is generally done
+on the biscuit before glazing. In several districts a very handsome
+ware is made, and painted on the glaze. For this kind of painting
+the colors are mixed with a silicate of lead and potash, and baked
+the third time in a small furnace at a low temperature. The
+coloring oxides in use are those of copper, cobalt, iron, antimony,
+manganese, and gold. Japanese porcelain painting may be divided
+into two categories, decorative and graphic; the first is used to
+improve the vessel upon which it is placed, and this class includes
+all the ware except that of the province of Kaga, which would come
+under the head of graphic, as it delineates all the trades,
+occupations, sports, customs, and costumes of the people, as well
+as the scenery, flora, and fauna of the country. "Owari ware" is
+made in the province of that name; it is not as translucent, but
+stronger and more tenacious than some of the Hizen manufacture.</p>
+
+<p>The principal potteries are at a village called S&egrave;to,
+twelve miles from the sea; in this village there are more than 200
+kilns. The ware is mostly painted a cobalt blue, and is merely of a
+decorative kind, consisting of branches of trees, grass, flowers,
+birds, and insects, all these being copied by the artist from
+nature. All the Owari ware is true hard porcelain, and is strong
+and durable. In Hizen, a number of wares are manufactured, the best
+known kind being the "Eurari," which is made at Arita, but painted
+at Eurari. The colors in use are red, blue, green, and gold; these
+are combined in various proportions, but, as a rule, the red
+predominates. Generally the surface of the vessel is divided into
+medallions of figures, which alternately have red, blue, or white
+back-ground, with figures in green or blue and gold.</p>
+
+<p>The egg-shell porcelain sold at Nagasaki is made in this
+province from Arita clay, and this is made from clay with no
+admixture of fusible matter except that contained by the clay
+naturally. The province of Satsuma is noted for crackled ware. It
+is only within a very few years that large vases have been
+manufactured, and in earlier days the old ware was confined to
+small vessels. The glaze is a silicate of alumina and potash, and
+the best ware has a complete network of the finest crackles; the
+painting is of birds and flowers, and noted for its delicate lines
+of green, red, and gold.</p>
+
+<p>In Kioto, the ware manufactured is very similar to that produced
+in Satsuma, but it is lighter and more porous; the decorations are
+also nearly the same, being of birds and flowers. There is a
+description of ware made in Kioto, called "Eraku," the whole body
+of which is covered with a red oxide of iron, and over this
+mythical figures of gold are traced. That produced in Kagja is
+<i>fa&iuml;ence</i>, and in the style of painting is unlike any
+other in Japan, the predominating color being a light red, used
+with green and gold. The designs with which it is profusely
+decorated are trees, grasses, flowers, birds, and figures of all
+classes of people, with their costumes, occupations, and pastimes.
+The "Banko" ware is made at the head of the Owari Bay; it is an
+unglazed stone-ware, very light and durable, made on moulds in
+irregular shapes, and decorated with figures in relief. On the
+island of Awadji, a delicate, creamy, crackled, soft paste
+porcelain is made. The figures used in decoration are birds and
+flowers, but outlined by heavy, dark lines.</p>
+
+<p>Consul Van Buren is of opinion that, at no distant day, Japan
+will be one of the foremost competitors in the pottery markets of
+the world, on account of the great variety and excellence of the
+clays, their proximity to the sea, the cheapness of labor, and the
+beauty and originality of the decorations. Already this important
+industry has been greatly stimulated by the foreign demand, and by
+the success of Japanese exhibitors at the Exhibitions of Vienna,
+Philadelphia, and Paris.--<i>Journal of the Society of
+Arts</i>.</p>
+
+<hr>
+<p>Professor Julius E. Hilgard, for twenty years assistant in
+charge of the office, has been placed in temporary charge of the
+Coast and Geodetic Survey. It is understood that he will be
+appointed superintendent to succeed the late Captain Carlile P.
+Patterson.</p>
+
+<hr>
+<p><a name="16"></a></p>
+
+<h2>THE FRENCH CRYSTAL PALACE.</h2>
+
+<p>The first idea of the French Crystal Palace was suggested by the
+English structure of the same name at Sydenham, about eight miles
+from London. Such a structure, as may be readily conceived,
+requires a site of vast extent, and one that shall be easy of
+access and possess the most agreeable surroundings. To the promoter
+of the project, those portions of the park of St. Cloud in the
+vicinage of the old chateau appeared to combine within themselves
+all the conditions that were desirable, and he, therefore, on the
+15th of December, 1879, addressed the Ministers of Public Works and
+of Finances asking for the necessary concessions. The extensive
+specifications have been finally completed and will probably be
+shortly submitted for the approval of the parliament. The moment
+has arrived then for the public press to take cognizance of a
+project which concerns so great interests.</p>
+
+<p class="ctr"><a href="images/8a.png"><img src=
+"images/8a_th.png" alt=
+"THE FRENCH CRYSTAL PALACE--PARK OF ST CLOUD, PARIS."></a></p>
+
+<p class="ctr">THE FRENCH CRYSTAL PALACE--PARK OF ST CLOUD,
+PARIS.</p>
+
+<p>At present we shall say a few words <i>&agrave; propos</i> of
+the engraving we present herewith. The French Crystal Palace will
+consist of one great nave, two lateral naves, two surrounding
+galleries, and a vast rotunda behind. The principal entrance,
+located at the head of the avenue leading from the present ruins
+(which will, ere long, be transformed into a most interesting
+museum), will exhibit a very striking aspect with its monumental
+fountain and the dome which it is proposed to erect over the very
+entrance itself. The whole structure will cover about nineteen
+acres of ground, thus being two and a half times the extent of the
+Palace of Industry in the Champs Elysees. The great nave of honor
+will be nearly 1,650 ft. in length, 78 ft. in width, and 98 ft. in
+height. The dome will measure exactly 328 ft. in height, or 105 ft.
+more than the towers of Notre Dame. The structure, with the
+exception of basement and foundation, will be of glass and
+iron.</p>
+
+<p>The project which we publish to-day has been studied and gotten
+up, according to the general plans and dimensions suggested by the
+promoter, by Mr. Dumoulin, the architect. We are informed that the
+builder is to be Mr. Alfred Hunnebelle, a contractor well known
+from the extensive works that he has executed, and who is president
+of the Syndical Chamber of Contractors of Paris.</p>
+
+<p>Among the annexes of this palace we may note a "Palace of the
+Republic," to be built on the ruins and designed for illustrious or
+distinguished visitors, such as the President of the Republic, the
+Ministers, the Municipal Council of Paris, foreign delegates, etc.;
+a farm house for special exhibitions and a field for experiments;
+galleries, cottages, etc.</p>
+
+<p>As for the programme, which embraces six divisions and numerous
+subdivisions, we are unable to give it at present for want of
+space; we need only say that it satisfies perfectly all the
+conditions of so vast an undertaking.</p>
+
+<p>In the hands of the projector, Mr. Nicole, who is well known
+from his long experience in such matters, the exhibition will
+undoubtedly prove a success and be instrumental in adding
+prosperity to all French industries.</p>
+
+<hr>
+<p>THE GREAT HEAT OF THE SUN.--Prof. S. P. Langley has made the
+following calculation: A sunbeam one centimeter in section is found
+in the clear sky of the Alleghany Mountains to bring to the earth
+in one minute enough heat to warm one gramme of water by 1&deg; C.
+It would, therefore, if concentrated upon a film of water 1/500th
+of a millimeter thick, 1 millimeter wide, and 10 millimeters long,
+raise it 83 1/3&deg; in one second, provided all the heat could be
+maintained. And since the specific heat of platinum is only 0.0032
+a strip of platinum of the same dimensions would, on a similar
+supposition, be warmed <i>in one second</i> to 2,603&deg; C.--a
+temperature sufficient to melt it!</p>
+
+<hr>
+<p><a name="17"></a></p>
+
+<h2>CHATEAU IN THE AEGEAN SEA.</h2>
+
+<p>From the site of this building, magnificent views are obtained
+over the island-dotted sea and the mainland of Asia Minor: but,
+"though every prospect pleases," it is a land of earthquakes, and
+unfortunately, the works at the chateau have been suspended, owing
+to the dreadful calamity which has recently fallen upon the
+district. The building is intended for the residence of an English
+lady of exalted rank. It is to be built of local white stone, the
+hall, staircase, etc., being lined and paved with marbles. The hall
+is a large apartment about 25 ft. high, with paneled ceiling,
+having galleries on two sides, giving access to the rooms
+surrounding it on first floor, and to the turret staircase leading
+to roofs, etc. With the exception of sanitary apparatus, painted
+windows, etc. (which will be supplied by English firms), the whole
+of the work will be executed by native labor. The architect is Mr.
+Edwin T. Hall, London.--<i>Building News</i>.</p>
+
+<p class="ctr"><a href="images/9a.png"><img src=
+"images/9a_th.png" alt=
+"SUGGESTIONS IN ARCHITECTURE--A CASTELLATED CHATEAU."></a></p>
+
+<p class="ctr">SUGGESTIONS IN ARCHITECTURE--A CASTELLATED
+CHATEAU.</p>
+
+<hr>
+<p><a name="13"></a></p>
+
+<h2>ELECTRIC POWER.</h2>
+
+<p>Just now nothing save electricity is talked about in scientific
+circles. During the meeting of the British Association the greatest
+possible prominence was given to electrical questions and
+propositions The success of the electric light, the introduction of
+the Faure battery with a great flourish of trumpets, and the
+magnificent display of electrical instruments and machinery at
+Paris, have all operated to the same end. The daily press has taken
+the subject up, and journals which were nothing hitherto if not
+political, now indulge in magnificent rhapsodies concerning the
+future of electricity. Even eminent engineers, carried away by the
+intoxication of the moment, have not hesitated to say that the
+steam engine is doomed, and that its place will be taken by the
+electricity engine. In the midst of all this noise and clamor and
+blowing of personal trumpets, it is not easy to keep one's head
+clear, and mistakes may be made which will cause disappointment to
+many and retard the progress of electrical science. We confidently
+expect that electricity will prove a potent agent by and by in the
+hands of the speculator for extracting gold from the pockets of the
+public, and we write now to warn our readers in time, and to
+endeavor to clear the air of some of the mists with which it is
+obscured. There is, no doubt, a great future before electricity;
+but it is equally certain that electricity can never do many things
+which the half informed may be readily made to believe it will do.
+We propose here to say enough on this point to enlighten our
+readers, without troubling them with perplexing problems and
+speculations.</p>
+
+<p>No one at this moment knows what electricity is; but for our
+present purpose we may regard it as a fluid, non-elastic, and
+without weight, and universally diffused through the universe. To
+judge by recently published statements, a large section of the
+reading public are taught that this fluid is a source of power, and
+that it may be made to do the work of coal. This is a delusion. So
+long as electricity remains in what we may call a normal state of
+repose, it is inert. Before <i>we can get any work out of
+electricity a somewhat greater amount of work must be done upon
+it</i>. If this fundamental and most important truth be kept in
+view it will not be easy to make a grave mistake in estimating the
+value of any of the numerous schemes for making electricity do work
+which will ere long be brought before the public. To render our
+meaning clearer, we may explain that in producing the electric
+light, for instance, a certain quantity of electricity passes in
+through one wire to the lamp, and precisely the same quantity
+passes out through the other wire, and on to the earth or return
+wire completing the circuit. Not only is the quantity the same, the
+velocity is also unchanged. But in going through the lamp the
+current has done something. It has overcome the resistance of the
+carbons, heated them to a dazzling white heat, and so performed
+work. In doing this the current of electricity has lost something.
+Led from the first lamp to a second, it is found powerless--if the
+first lamp be of sufficient size. What is it that the electricity
+has lost? It has parted with what electricians would term
+"potential," or the capacity for performing work. What this is
+precisely, or in what way the presence or absence of potential
+modifies the nature of the electric current, no one knows; but it
+is known that this potential can only be conferred on electricity
+by doing work on the electricity in the first instance. The analogy
+between electricity and a liquid like water will now be recognized.
+So long as the water is at rest, it is inert. If we pump it up to a
+height, we confer on it the equivalent of potential. We can let the
+water fall into the buckets of an overshot wheel. Its velocity
+leaving the tail race may be identical with that at which it left
+the supply trough to descend on the wheel. Its quantity will be the
+same. It will be in all respects unchanged, just as the current of
+electricity passing through a lamp is unchanged; but it has,
+nevertheless, lost something. It has parted with its
+potential--capacity for doing work--and it becomes once more inert.
+But the duty which it discharged in turning the mill wheel was
+somewhat less than the precise equivalent of the work done in
+pumping it up to a level with the top of the wheel. In the same way
+the electric current never can do work equal in amount to the work
+done on it in endowing it with potential.</p>
+
+<p>It will thus be seen that electricity can only be used as a
+means of transmitting power from one place to another, or for
+storing power up at one time to be used at a subsequent period; but
+it cannot be used to originate power in the way coal can be used.
+It possesses no inherent potential. It is incapable of performing
+work unless something is done to it first. We have spoken of it as
+a fluid, but only for the sake of illustration. As we have said, no
+one knows what it is, but the theory which bids fair for acceptance
+is that it is a mode of motion of the all-pervading ether. Very
+curious and instructive experiments are now being carried out in
+Paris by Dr. Bjerkness, of Christiania, in the Norwegian section of
+the electrical exhibition. This gentleman submerges thin elastic
+diaphragms in water, and causes them to vibrate, or rather pulsate,
+by compressed air. He finds that if they pulsate synchronously they
+attract each other. If the pulsations are not simultaneous, the
+disks repel each other. From this and other results he has
+obtained, it may be argued that the ether plays the part of the
+water in Dr. Bjerkness' tank, and that when special forms of
+vibration are set up in bodies they become competent to attract or
+repel other bodies. This being so, it will be seen that the power
+of attraction or repulsion of an electrical body depends in the
+first instance on the motion set up in the body attracted or
+repulsed, and this motion is, of course, some function of the work
+originally done on the body. We need not pursue this argument
+further. Among the most scientific investigators of the day it is
+admitted that the efficiency of electricity as a doer of work, or a
+producer of action at a distance, must depend for its value on the
+performance of work in some one way or another on the electricity
+itself in the first instance. It may be worth while here to dispel
+a popular delusion. It is held very generally that electricity can
+be made, as, for instance, by the galvanic battery. There is no
+reason to believe anything of the kind; but whether it is or is not
+true that electricity is actually made by the combustion of zinc in
+a galvanic trough, it is quite certain that this electricity,
+unless it possesses potential, can do no work, no matter how great
+its quantity. Of course, it is to be understood that all electric
+currents possess potential. If they did not, their presence would
+be unknown; but the potential of a current is in all cases the
+result of work done on electricity, either by the oxidation of
+zinc, or in some other way. This is a broad principle, but it is
+strictly consistent in every respect with the truth. Electricity,
+then, is, as we have said, totally different from coal; and it can
+never become a substitute for it alone. Water power, air power, or
+what we may, for want of a better phrase, call chemical power,
+combined with electricity, can be used as a substitute for coal;
+but electricity cannot of itself be employed to do work. It is
+true, however, that electricity, on which work has already been
+done, may be found in nature. Atmospheric electricity, for example,
+may perhaps yet be utilized. It is by no means inconceivable that
+the electricity contained in a thunder cloud might be employed to
+charge a Faure battery; but up to the present no one has
+contemplated the obtaining of power from the clouds, and whether it
+is or is not practicable to utilize a great natural force in this
+way does not affect our statement. The use of electricity must be
+confined to its power of transmitting or storing up energy, and
+this truth being recognized, it becomes easy to estimate the future
+prospects of electricity at something like their proper value.</p>
+
+<p>It has been proved to a certain extent that electricity can be
+used to transmit power to a distance, and that it can be used to
+store it up. Thus far the man of pure science. The engineer now
+comes on the stage and asks--Can practical difficulties be got
+over? Can it be made to pay? In trying to answer these questions we
+cannot do better than deal with one or two definite proposals which
+have been recently made. That with which we shall first concern
+ourselves is that trains should be worked by Faure batteries
+instead of by steam. It is suggested that each carriage of a train
+should be provided with a dynamo motor, and that batteries enough
+should be carried by each to drive the wheels, and so propel the
+train. Let us see how such a scheme would comply with working
+conditions. Let us take for example a train of fifteen coaches on
+the Great Northern Railway, running without a stop to Peterborough
+in one hour and forty minutes. The power required would be about
+500 horses indicated. To supply this for 100 minutes, even on the
+most absurdly favorable hypothesis, no less than 25 tons of Faure
+batteries would be required. Adding to these the weight of the
+dynamo motors, and that unavoidably added to the coaches, it will
+be seen that a weight equal to that of an engine would soon be
+reached. The only possible saving would be some 28 to 30 tons of
+tender. In return for this all the passengers would have to change
+coaches at Peterborough, as the train could not be delayed to
+replace the expended with fresh batteries. This is out of the
+question. The Faure batteries must all be carried on one vehicle or
+engine, which could be changed for another, like a locomotive. Even
+then no advantage would be gained. As to cost, it is very unlikely
+that the stationary engines which must be provided to drive the
+dynamo machines for charging the batteries would be more economical
+than locomotive engines; and if we allow that the dynamo machine
+only wasted 10 per cent. of the power of the engine, the Faure
+batteries 10 per cent. of the power of the dynamo machines, and the
+dynamo motors 10 per cent. of the power of the batteries--all
+ridiculously favorable assumptions--yet the stationary engines
+would be handicapped with a difference in net efficiency between
+themselves and the locomotive--admitting the original efficiency
+per pound of coal in both to be the same--of some 27 per cent., we
+think we may relegate this scheme to the realms of oblivion.
+Another idea is that by putting up turbines and dynamo machines the
+steam engine might be superseded by water power. Now it so happens
+that if all the water power of England were quadrupled it would not
+nearly suffice for our wants. It may be found worth while perhaps
+to construct steam engines close to coalpits and send out power
+from these engines by wire; but the question will be asked, Which
+is the cheaper of the two, to send the coal or to send the power?
+On the answer to this will depend the decision of the mill owners.
+Another favorite scheme is that embodied in the Siemens electrical
+railway. We believe that there is a great future in store for
+electricity as a worker of tramway traffic; but the traffic on a
+great line like the Midland or Great Northern Railway could not be
+carried on by it. As Robert Stephenson said of the atmospheric
+system, it is not flexible enough. The working of points and
+crossings, and the shunting of trains and wagons, would present
+unsurmountable difficulties. We have cited proposals enough, we
+think, to illustrate our meaning. Sir William Armstrong, Sir
+Frederick Bramwell, Dr. Siemens, Sir W. Thomson, and many others
+may be excused if they are a little enthusiastic. They are just now
+overjoyed with success attained; but when the time comes for sober
+reflection they will, no doubt, see good reason to moderate their
+views. No one can say, of course, what further discoveries may
+bring to light; but recent speakers and writers have found in what
+is known already, materials for sketching out a romance of
+electricity. It is but romancing to assert that the end of the
+steam engine is at hand. Wonderful and mystical as electricity is,
+there are some very hard and dry facts about it, and these facts
+are all opposed to the theory that it can become man's servant of
+all work. Ariel-like, electricity may put a girdle round the earth
+in forty minutes; but it shows no great aptitude for superseding
+the useful old giant steam, who has toiled for the world so long
+and to such good purpose--<i>The Engineer</i>.</p>
+
+<hr>
+<p><a name="14"></a></p>
+
+<h2>ON A METHOD OF OBTAINING AND MEASURING VERY HIGH VACUA WITH A
+MODIFIED FORM OF SPRENGEL-PUMP.</h2>
+
+<h3>By Ogden N. Rood, Professor of Physics in Columbia
+College.</h3>
+
+<p>In the July number of this Journal for 1880, I gave a short
+account of certain changes in the Sprengel-pump by means of which
+far better vacua could be obtained than had been previously
+possible. For example, the highest vacuum at that time known had
+been reached by Mr. Crookes, and was about 1/17,000,000, while with
+my arrangement vacua of 1/100,000,000 were easily reached. In a
+notice that appeared in <i>Nature</i> for August, 1880, p. 375, it
+was stated that my improvements were not new, but had already been
+made in England four years previously. I have been unable to obtain
+a printed account of the English improvements, and am willing to
+assume that they are identical with my own; but on the other hand,
+as for four years no particular result seems to have followed their
+introduction in England, I am reluctantly forced to the conclusion
+that their inventor and his customers, for that period of time,
+have remained quite in ignorance of the proper mode of utilizing
+them. Since then I have pushed the matter still farther, and have
+succeeded in obtaining with my apparatus vacua as high as
+1/390,000,000 without finding that the limit of its action had been
+reached. The pump is simple in construction, inexpensive, and, as I
+have proved by a large number of experiments, certain in action and
+easy of use; stopcocks and grease are dispensed with, and when the
+presence of a stopcock is really desirable its place is supplied by
+a movable column of mercury.</p>
+
+<p><i>Reservoir</i>.--An ordinary inverted bell-glass with a
+diameter of 100 mm. and a total height of 205 mm. forms the
+reservoir; its mouth is closed by a well-fitting cork through which
+passes the glass tube that forms one termination of the pump. The
+cork around tube and up to the edge of the former is painted with a
+flexible cement. The tube projects 40 mm. into the mercury and
+passes through a little watch-glass-shaped piece of sheet-iron, W,
+figure 1, which prevents the small air bubbles that creep upward
+along the tube from reaching its open end; the little cup is firmly
+cemented in its place. The flow of the mercury is regulated by the
+steel rod and cylinder, CR, Figure 1. The bottom of the steel
+cylinder is filled out with a circular piece of pure India-rubber,
+properly cemented; this soon fits itself to the use required and
+answers admirably. The pressure of the cylinder on the end of the
+tube is regulated by the lever, S, Figure 1; this is attached to a
+circular board which again is firmly fastened over the open end of
+the bell-glass. It will be noticed that on turning the milled head,
+S, the motion of the steel cylinder is not directly vertical, but
+that it tends to describe a circle with c as a center; the
+necessary play of the cylinder is, however, so small, that
+practically the experimenter does not become aware of this
+theoretical defect, so that the arrangement really gives entire
+satisfaction, and after it has been in use for a few days
+accurately controls the flow of the mercury. The glass cylinder is
+held in position, but not supported, by two wooden
+<i>adjustable</i> clamps, <i>a a</i>, Figure 2. The weight of the
+cylinder and mercury is supported by a shelf, S, Figure 2, on which
+rests the cork of the cylinder; in this way all danger of a very
+disagreeable accident is avoided.</p>
+
+<p class="ctr"><img src="images/10a.png" alt=
+"MODIFIED FORM OF SPRENGEL PUMP."></p>
+
+<p class="ctr">MODIFIED FORM OF SPRENGEL PUMP.</p>
+
+<p><i>Vacuum-bulb</i>.--Leaving the reservoir, the mercury enters
+the vacuum-bulb, B, Figure 2, where it parts with most of its air
+and moisture; this bulb also serves to catch the air that creeps
+into the pump from the reservoir, even when there is no flow of
+mercury; its diameter is 27 mm. The shape and inclination of the
+tube attached to this bulb is by no means a matter of indifference;
+accordingly Figure 3 is a separate drawing of it; the tube should
+be so bent that a horizontal line drawn from the proper level of
+the mercury in the bulb passes through the point, <i>o</i>, where
+the drops of mercury break off. The length of the tube, EC, should
+be 150 mm., that of the tube, ED, 45 mm.; the bore of this tube is
+about the same as that of the fall-tube.</p>
+
+<p><i>Fall-tube and bends</i>.--The bore of the fall-tube in the
+pump now used by me is 1.78 mm.; its length above the bends (U,
+Figure 2) is 310 mm.; below the bends the length is 815 mm. The
+bends constitute a fluid valve that prevents the air from returning
+into the pump; beside this, the play of the mercury in them greatly
+facilitates the passage of the air downward. The top of the mercury
+column representing the existing barometric pressure should be
+about 25 mm. below the bends when the pump is in action. This is
+easily regulated by an adjustable shelf, which is also employed to
+fill the bends with mercury when a measurement is taken or when the
+pump is at rest. On the shelf is a tube, 160 mm. high and 20 mm. in
+diameter, into which the end of the fall-tube dips; its side has a
+circular perforation into which fits a small cork with a little
+tube bent at right angles. With the hard end of a file and a few
+drops of turpentine the perforation can be easily made and shaped
+in a few minutes. By revolving the little bent tube through
+180&deg; the flow of the mercury can be temporarily suspended when
+it is desirable to change the vessel that catches it.</p>
+
+<p><i>Gauge</i>.--For the purpose of measuring the vacua I have
+used an arrangement similar to McLeod's gauge, Figure 4; it has,
+however, some peculiarities. The tube destined to contain the
+compressed air has a diameter of 1.35 mm. as ascertained by a
+compound microscope; it is not fused at its upper extremity, but
+closed by a fine glass rod that fits into it as accurately as may
+be, the end of the rod being ground flat and true. This rod is
+introduced into the tube, and while the latter is gently heated a
+very small portion of the cement described below is allowed to
+enter by capillary attraction, but not to extend beyond the end of
+the rod, the operation being watched by a lens. The rod is used for
+the purpose of obtaining the compressed air in the form of a
+cylinder, and also to allow cleansing of the tube when necessary.
+The capacity of the gauge-sphere was obtained by filling it with
+mercury; its external diameter was sixty millimeters; for measuring
+very high vacua this is somewhat small and makes the probable
+errors rather large; I would advise the use of a gauge-sphere of
+about twice as great capacity. The tube, CB, Figure 4, has the same
+bore as the measuring tube in order to avoid corrections for
+capillarity. The tube of the gauge, CD, is not connected with an
+India-rubber tube, as is usual, but dips into mercury contained in
+a cylinder 340 mm. high, 58 mm. in diameter, which can be raised
+and lowered at pleasure. This is best accomplished by the use of a
+set of boxes of various thicknesses, made for the purpose and
+supplemented by several sheets of cardboard and even of
+writing-paper. These have been found to answer well and enable the
+experimenter to graduate with a nicety the pressure to which the
+gas is exposed during measurement. By employing a cylinder filled
+with mercury instead of the usual caoutchouc tubing small bubbles
+of air are prevented from entering the gauge along with the
+mercury. An adjustable brace or support is used which prevents
+accident to the cylinder when the pump is inclined for the purpose
+of pumping out the vacuum-bulb. The maximum pressure that can be
+employed in the gauge used by me is 100 mm.</p>
+
+<p>All the tubing of the pump is supported at a distance of about
+55 mm. from the wood-work; this is effected by the use of simple
+adjustable supports and adjustable clamps; the latter have proved a
+great convenience. The object is to gain the ability to heat with a
+Bunsen burner all parts of the pump without burning the wood-work.
+Where glass and wood necessarily come in contact the wood is
+protected by metal or simply painted with a saturated solution of
+alum. The glass portions of the pump I have contrived to anneal
+completely by the simple means mentioned below. If the glass is not
+annealed it is certain to crack when subjected to heat, thus
+causing vexation and loss of time. The mercury was purified by the
+same method that was used by W. Siemens (Pogg. Annalen, vol. ex.,
+p. 20), that is, by a little strong sulphuric acid to which a few
+drops of nitric acid had been added; it was dried by pouring it
+repeatedly from one hot dry vessel to another, by filtering it
+while quite warm, the drying being completed finally by the action
+of the pump itself. All the measurements were made by a fine
+cathetometer which was constructed for me by William Grunow; see
+this Journal, Jan., 1874, p. 23. It was provided with a
+well-corrected object-glass having a focal length of 200 mm. and as
+used by me gave a magnifying power of 16 diameters.</p>
+
+<p><i>Manipulation</i>.--The necessary connections are effected
+with a cement made by melting Burgundy pitch with three or four per
+cent of gutta percha. It is indispensable that the cement when cold
+should be so hard as completely to resist taking any impression
+from the finger nail, otherwise it is certain to yield gradually
+and finally to give rise to leaks. The connecting tubes are
+selected so as to fit as closely as possible, and after being put
+into position are heated to the proper amount, when the edges are
+touched with a fragment of cold cement which enters by capillary
+attraction and forms a transparent joint that can from time to time
+be examined with a lens for the colors of thin plates, which always
+precede a leak. Joints of this kind have been in use by me for two
+months at a time without showing a trace of leakage, and the
+evidence gathered in another series of unfinished experiments goes
+to show that no appreciable amount of vapor is furnished by the
+resinous compound, which, I may add, is never used until it has
+been repeatedly melted. As drying material I prefer caustic potash
+that has been in fusion just before its introduction into the
+drying tube; during the process of exhaustion it can from time to
+time be heated nearly to the melting point: if actually fused in
+the drying tube the latter almost invariably cracks. The pump in
+the first instance is to be inclined at an angle of about 10
+degrees, the tube of the gauge being supported by a semicircular
+piece of thick pasteboard fitted with two corks into the top of the
+cylinder. This seemingly awkward proceeding has in no case been
+attended with the slightest accident, and owing to the presence of
+the four leveling-screws, the pump when righted returns, as shown
+by the telescope of the cathetometer, almost exactly to its
+original place. In the inclined position the exhaustion of the
+vacuum bulb is accomplished along with that of the rest of the
+pump. The exhaustion of the vacuum-bulb when once effected can be
+preserved to a great extent for use in future work, merely by
+allowing mercury from the reservoir to flow in a rapid stream at
+the time that air is allowed to re-enter the pump. During the first
+process of exhaustion the tube of the gauge is kept hot by moving
+to and fro a Bunsen burner, and is in this way freed from those
+portions of air and moisture that are not too firmly attached.
+After a time the vacuum-bulb ceases to deliver bubbles of air; it
+and the attached tube are now to be heated with a moving Bunsen
+burner, when it will be found to furnish for 15 or 20 minutes a
+large quantity of bubbles mainly of vapor of water. After then
+production ceases the pump is righted and the exhaustion carried
+farther. In spite of a couple of careful experiments with the
+cathetometer I have not succeeded in measuring the vacuum in the
+vacuum bulb, but judge from indications, that is about as high as
+that obtained in an ordinary Geissler pump. Meanwhile the various
+parts of the pump can be heated with a moving Bunsen burner to
+detach air and moisture, the cement being protected by wet
+lamp-wicking. In one experiment I measured the amount of air that
+was detached from the walls of the pump by heating them for ten
+minutes somewhat above l00&deg; C., and found that it was
+1/1,000,000 of the air originally present. I have also noticed that
+a still larger amount of air is detached by electric discharges.
+This coincides with an observation of E. Bessel-Hagen in his
+interesting article on a new form of T&ouml;pler's mercury-pump
+(Annalen der Physik und Chemie, 1881, vol. xii.). Even when potash
+is used a small amount of moisture always collects in the bends of
+the fall tube; this is readily removed by a Bunsen burner; the
+tension of the vapor being greatly increased, it passes far down
+the fall-tube in large bubbles and is condensed. Without this
+precaution I have found it impossible to obtain a vacuum higher
+than 1/25,000,000; in point of fact the bends should always be
+heated when a high exhaustion is undertaken even if the pump has
+been standing well exhausted for a week; the heat should of course
+never be applied at a late stage of the exhaustion. Conversely, I
+have often by the aid of heat completely and quickly removed quite
+large quantities of the vapor of water that had been purposely
+introduced. The exhaustion of the vacuum-bulb is of course somewhat
+injured by the act of using the pump and also by standing for
+several days, so that it has been usual with me before undertaking
+a high exhaustion to incline the pump and re-exhaust for 20
+minutes; I have, however, obtained very high vacua without using
+this precaution.</p>
+
+<p>During the process of exhaustion not more than one-half of the
+mercury in the reservoir is allowed to run out, other wise when it
+is returned bubbles of air are apt to find their way into the
+vacuum-bulb. In order to secure its quiet entrance it is poured
+into a silk bag provided with several holes. When the reservoir is
+first filled its walls for a day or two appear to furnish air that
+enters the vacuum-bulb; this action, however, soon sinks to a
+minimum and then the leakage remains quite constant for months
+together.</p>
+
+<p><i>Measurement of the vacuum</i>.--The cylinder into which the
+gauge-tube dips is first elevated by a box sufficiently thick
+merely to close the gauge, afterwards boxes are placed under it
+sufficient to elevate the mercury to the base of the measuring
+tube; when the mercury has reached this point, thin boards and
+card-boards are added till a suitable pressure is obtained. The
+length of the inclosed cylinder of air is then measured with the
+cathetometer, also the height of the mercurial "meniscus," and the
+difference of the heights of the mercurial columns in A and B,
+figure 4. To obtain a second measure an assistant removes some of
+the boxes and the cylinder is lowered by hand three or four
+centimeters and then replaced in its original position. In
+measuring really high vacua, it is well to begin with this process
+of lowering and raising the cylinder, and to repeat it five or six
+times before taking readings. It seems as though the mercury in the
+tube, B, supplies to the glass a coating of air that allows it to
+move more freely; at all events it is certain that ordinarily the
+readings of B become regular, only after the mercury has been
+allowed to play up and down the tube a number of times. This
+applies particularly to vacua as high 1/50,000,000 and to pressures
+of five millimeters and under. It is advantageous in making
+measurements to employ large pressures and small volumes; the
+correct working of the gauge can from time to time be tested by
+varying the relations of these to each other. This I did quite
+elaborately, and proved that such constant errors as exist are
+small compared with inevitable accidental errors, as, for example,
+that there was no measurable correction for capillarity, that the
+calculated volume of the "meniscus" was correct, etc. It is
+essential in making a measurement that the temperature of the room
+should change as little as possible, and that the temperature of
+the mercury in the cylinder should be at least nearly that of the
+air near the gauge-sphere. The computation is made as follows</p>
+
+<pre>
+  n = height of the cylinder inclosing the air;
+  c = a factor which, multiplied by n, converts it into cubic
+                millimeters;
+  S = cubic contents of the meniscus;
+  d = difference of level between A and B, fig. 4;
+    = the pressure the air is under;
+  N = the cubic contents of the gauge in millimeters;
+  x = a fraction expressing the degree of exhaustion obtained; then
+<br>
+          x=1/([N (760/d)]/[nc - S])
+</pre>
+
+<p>It will be noticed that the measurements are independent of the
+actual height of the barometer, and if several readings are taken
+continuously, the result will not be sensibly affected by a
+simultaneous change of the barometer. Almost all the readings were
+taken at a temperature of about 20&deg; C., and in the present
+state of the work corrections for temperature may be considered a
+superfluous refinement.</p>
+
+<p><i>Gauge correction</i>.--It is necessary to apply to the
+results thus obtained a correction which becomes very important
+when high vacua are measured. It was found in an early stage of the
+experiments that the mercury, in the act of entering the highly
+exhausted gauge, gave out invariably a certain amount of air which
+of course was measured along with the residuum that properly
+belonged there; hence to obtain the true vacuum it is necessary to
+subtract the volume of this air from nc. By a series of experiments
+I ascertained that the amount of air introduced by the mercury in
+the acts of entering and leaving the gauge was sensibly constant
+for six of these single operations (or for three of these double
+operations), when they followed each other immediately. The
+correction accordingly is made as follows: the vacuum is first
+measured as described above, then by withdrawing all the boxes
+except the lowest, the mercury is allowed to fall so as nearly to
+empty the gauge; it is then made again to fill the gauge, and these
+operations are repeated until they amount in all to six; finally
+the volume and pressure are a second time measured. Assuming the
+pressure to remain constant, or that the volumes are reduced to the
+same pressure,</p>
+
+<pre>
+  v = the original volume;  v' = the final volume;
+  V' = volume of air introduced by the first entry of the mercury;
+  V = corrected volume; then
+<br>
+  V' = (v'-v)/6
+  V = v - [(v'-v)/6]
+</pre>
+
+<p>It will be noticed that it is assumed in this formula that the
+same amount of air is introduced into the gauge in the acts of
+entry and exit; in the act of entering in point of fact more fresh
+mercury is exposed to the action of the vacuum than in the act
+exit, which might possibly make the true gauge-correction rather
+larger than that given by the formula. It has been found that when
+the pump is in constant use the gauge-correction gradually
+diminishes from day to day; in other words, the air is gradually
+pumped out of the gauge-mercury. Thus on December 21, the amount of
+air entering with the mercury corresponded to an exhaustion of</p>
+
+<pre>
+  1/27,308,805 .......Dec. 21.
+<br>
+  1/38,806,688 ...... Dec. 29.
+<br>
+  1/78,125,000 .......Jan. 15.
+<br>
+  1/83,333,333 .......Jan. 23
+<br>
+  1/128,834,063 ......Feb. 1.
+<br>
+  1/226,757,400 ..... Feb. 9.
+<br>
+  1/232,828,800 ..... Feb. 19.
+<br>
+  1/388,200,000 ......March 7.
+</pre>
+
+<p>That this diminution is not due to the air being gradually
+withdrawn from the walls of the gauge or from the gauge-tube, is
+shown by the fact that during its progress the pump was several
+times taken to pieces, and the portions in question exposed to the
+atmosphere without affecting the nature or extent of the change
+that was going on. I also made one experiment which proves that the
+gauge-correction does not increase sensibly, when the exhausted
+pump and gauge are allowed to stand unused for twenty days.</p>
+
+<p><i>Rate of the pump's work</i>.--It is quite important to know
+the rate of the pump at different degrees of exhaustion, for the
+purpose of enabling the experimenter to produce a definite
+exhaustion with facility; also if its maximum rate is known and the
+minimum rate of leakage, it becomes possible to calculate the
+highest vacuum attainable with the instrument. Examples are given
+in the tables below; the total capacity was about 100,000 cubic
+mm.</p>
+
+<pre>
+  Time.         Exhaustion.         Ratio.
+<br>
+                1/78,511
+  10 minutes              }........ 1:1/3.53
+                1/276,980
+  10 minutes              }........ 1:1/6.10
+               1/1,687,140
+  10 minutes              }........ 1:1/4.15
+               1/7,002,000
+</pre>
+
+<p>Upon another occasion the following rates and exhaustions were
+obtained:</p>
+
+<pre>
+  Time.         Exhaustion.         Rate.
+<br>
+               1/7,812,500
+  10 minutes              }........ 1:1/3.18
+              1/24,875,620
+  10 minutes              }........ 1:1/2.69
+              1/67,024,090
+  10 minutes              }........ 1:1/1.22
+              1/81,760,810
+  10 minutes              }........ 1:1.67
+             1/136,986,300
+  10 minutes              }........ 1:1.23
+             1/170,648,500
+</pre>
+
+<p>The <i>irregular</i> variations in the rates are due to the mode
+in which the flow of the mercury was in each case regulated.</p>
+
+<p><i>Leakage</i>.--We come now to one of the most important
+elements in the production of high vacua. After the air is detached
+from the walls of the pump the leakage becomes and remains nearly
+constant. I give below a table of leakages, the pump being in each
+case in a condition suitable for the production of a very high
+vacuum:</p>
+
+<pre>
+  Duration of the                           Leakage per hour in
+     experiment                               cubic mm., press.,
+                                                 760 mm.
+<br>
+      18&frac12; hours............................ 0.000853
+      27  hours............................ 0.001565
+      26&frac12; hours.............................0.000791
+      20  hours.............................0.000842
+      19  hours.............................0.000951
+      19  hours.............................0.001857
+       7  days..............................0.001700
+       7  days..............................0.001574
+<br>
+                Average.................... 0.001266
+</pre>
+
+<p>I endeavored to locate this leakage, and proved that one-quarter
+of it is due to air that enters the gauge from the top of its
+column of mercury, thus:</p>
+
+<pre>
+  Duration of the                         Gauge-leakage per hour
+    experiment.                            in cubic mm., press.
+                                                  760 mm.
+<br>
+    18 hours.................................0.0002299
+     7 days..................................0.0004093
+     7 days..................................0.0003464
+<br>
+               Average.......................0.0003285
+</pre>
+
+<p>This renders it very probable that the remaining three quarters
+are due to air given off from the mercury at B, Fig. 4, from that
+in the bends and at the entrance of the fall-tube, <i>o</i>, Fig.
+3.</p>
+
+<p>Further on some evidence will be given that renders it probable
+that the leakage of the pump when in action is about four times as
+great as the total leakage in a state of rest.</p>
+
+<p>The gauge, when arranged for measurement of gauge-leakage,
+really constitutes a barometer, and a calculation shows that the
+leakage would amount to 2.877 cubic millimeters per year, press.
+760 mm. If this air were contained in a cylinder 90 mm. long and 15
+mm. in diameter it would exert a pressure of 0.14 mm. To this I may
+add that in one experiment I allowed the gauge for seven days to
+remain completely filled with mercury and then measured the leakage
+into it. This was such as would in a year amount to 0.488 cubic
+millimeter, press. 760 mm., and in a cylinder of the above
+dimensions would exert a pressure of 0.0233 mm.</p>
+
+<p><i>Reliability of the results: highest vacuum.</i></p>
+
+<p>The following are samples of the results obtained. In one case
+sixteen readings were taken in groups of four with the following
+result:</p>
+
+<pre>
+        Exhaustion.
+       1 / 74,219,139
+       1 / 78,533,454
+       1 / 79,017,272
+       1 / 68,503,182
+  Mean 1 / 74,853,449
+</pre>
+
+<p>Calculating the probable error of the mean with reference to the
+above four results it is found to be 2.28 per cent of the quantity
+involved.</p>
+
+<p>A higher vacuum measured in the same way gave the following
+results:</p>
+
+<pre>
+  1 / 146,198,800
+  1 / 175,131,300
+  1 / 204,081,600
+  1 / 201,207,200
+</pre>
+
+<p>The mean is 1 / 178,411,934, with a probable error of 5.42 per
+cent of the quantity involved. I give now an extreme case; only
+five single readings were taken; these corresponded to the
+following exhaustions:</p>
+
+<pre>
+  1 / 379,219,500
+  1 / 371,057,265
+  1 / 250,941,040
+  1 / 424,088,232
+  1 / 691,082,540
+</pre>
+
+<p>The mean value is 1 / 381,100,000, with a probable error of
+10.36 per cent of the quantity involved. Upon other occasions I
+have obtained exhaustions of 1 / 373,134,000 and 1 / 388,200,000.
+Of course in these cases a gauge-correction was applied; the
+highest vacuum that I have ever obtained irrespective of a
+gauge-correction was 1 / 190,392,150. In these cases and in
+general, potash was employed as the drying material; I have found
+it practical, however, to attain vacua as high as 1 / 50,000,000 in
+the total absence of all such substances. The vapor of water which
+collects in bends must be removed from time to time with a Bunsen
+burner while the pump is in action.</p>
+
+<p>It is evident that the final condition of the pump is reached
+when as much air leaks in per unit of time as can be removed in the
+same interval. The total average leakage per ten minutes in the
+pump used by me, when at rest, was 0.000211 cubic millimeter at
+press. 760 mm. Let us assume that the leakage when the pump is in
+action is four times as great as when at rest; then in each ten
+minutes 0.000844 cubic millimeter press., 760 mm., would enter;
+this corresponds in the pump used by me to an exhaustion of 1 /
+124,000,000; if the rate of the pump is such as to remove one-half
+of the air present in ten minutes, then the highest attainable
+exhaustion would be 1 / 248,000,000. In the same way it may be
+shown that if six minutes are required for the removal of half the
+air the highest vacuum would be 1 / 413,000,000 nearly, and rates
+even higher than this have been observed in my experiments. An
+arrangement of the vacuum-bulb whereby the entering drops of
+mercury would be exposed to the vacuum in an isolated condition for
+a somewhat longer time would doubtless enable the experimenter to
+obtain considerably higher vacua than those above given.</p>
+
+<p><i>Exhaustion obtained with a plain Sprengel Pump.</i>--I made a
+series of experiments with a plain Sprengel pump without stopcocks,
+and arranged, as far as possible, like the instrument just
+described. The leakage per hour was as follows:</p>
+
+<pre>
+  Duration of the             Leakage per hour in
+    experiment.               cubic mm. at press.
+                                    760 mm.
+<br>
+  22 hours                          0.04563
+   2 days                           0.04520
+   2 days                           0.09210
+   4 days                           0.06428
+                                    -------
+            Mean                    0.06180
+</pre>
+
+<p>Using the same reasoning as above we obtain the following
+table</p>
+
+<pre>
+  Time necessary for removal     Greatest attainable
+     of half the air.                exhaustion.
+<br>
+    10 minutes                     1 / 5,000,000
+    7.5 minutes                    1 / 7,000,000
+    6.6 minutes                    1 / 12,000,000
+</pre>
+
+<p>In point of fact the highest exhaustion I ever obtained with
+this pump was 1 / 5,000,000; from which I infer that the leakage
+during action is considerably greater than four times that of the
+pump at rest. The general run of the experiments tends to show that
+the leakage of a plain Sprengel pump, without stopcocks or grease,
+is, when in action, about 80 times as great as in the form used by
+me.</p>
+
+<p><i>Note on annealing glass tubes.</i>--It is quite necessary to
+anneal all those parts of the pump that are to be exposed to heat,
+otherwise they soon crack. I found by inclosing the glass in heavy
+iron tubes and exposing it for five hours to a temperature somewhat
+above that of melting zinc, and then allowing an hour or two for
+the cooling process, that the strong polarization figure which it
+displays in a polariscope was completely removed, and hence the
+glass annealed. A common gas-combustion furnace was used, the
+bends, etc, being suitably inclosed in heavy metal and heated over
+a common ten-fold Bunsen burner. Thus far no accident has happened
+to the annealed glass, even when cold drops of mercury struck in
+rapid succession on portions heated considerably above 100&deg;
+C.</p>
+
+<p>I wish, in conclusion, to express my thanks to my assistant, Dr.
+Ihlseng, for the labor he has expended in making the large number
+of computations necessarily involved in work of this
+kind.--<i>Amer. Jour. of Science.</i></p>
+
+<hr>
+<p><a name="9"></a></p>
+
+<h2>CRYSTALLIZATION TABLE.</h2>
+
+<p>The following table, prepared by E. Finot and Arm. Bertrand for
+the <i>Jour. de Ph. et de Chim.</i>, shows the point at which the
+evaporation of certain solutions is to be interrupted in order to
+procure a good crop of crystals on cooling. The density is
+according to Baum&eacute;'s scale, the solution warm:</p>
+
+<pre>
+  Aluminum sulphate       25 | Nickel acetate             30
+  Alum (amm. or pot.)     20 |   "    ammon. sulphate     18
+  Ammonium acetate        14 |   "    chloride            50
+    "      arsenate        5 |   "    sulphate            40
+    "      benzoate        5 | Oxalic acid                12
+    "      bichromate     28 | Potass. and sod. tartrate  36
+    "      bromide        30 | Potassium arsenate         36
+    "      chloride       12 |   "       benzoate          2
+    "      nitrate        29 |   "       bisulphate       35
+    "      oxalate         5 |   "       bromide          40
+    "      phosphate      35 |   "       chlorate         22
+    "      sulphate       28 |   "       chloride         25
+    "      sulphocyanide  18 |   "       chromate         38
+    "      tartrate       25 |   "       citrate          36
+  Barium ethylsulphate    43 |   "       ferrocyanide     38
+    "    formate          32 |   "       iodide           17
+    "    hyposulphite     24 |   "       nitrate          28
+    "    nitrate          18 |   "       oxalate          30
+    "    oxide            12 |   "       permanganate     25
+  Bismuth nitrate         70 |   "       sulphate         15
+  Boric acid               6 |   "       sulphite         25
+  Cadmium bromide         65 |   "       sulphocyanide    35
+  Calcium chloride        40 |   "       tartrate         48
+    "     ethylsulphate   36 | Soda                       28
+    "     lactate          8 | Sodium acetate             22
+    "     nitrate         55 |   "    ammon. phosp.       17
+  Cobalt chloride         41 |   "    arsenate            36
+    "    nitrate          50 |   "    borate              24
+    "    sulphate         40 |   "    bromide             55
+  Copper acetate           5 |   "    chlorate            43
+    "    ammon. sulph.    35 |   "    chromate            45
+    "    chloride         45 |   "    citrate             36
+    "    nitrate          55 |   "    ethylsulphate       37
+    "    sulphate         30 |   "    hyposulphite        24
+  Iron-ammon. oxalate     30 |   "    nitrate             40
+    " ammon. sulphate     31 |   "    phosphate           20
+    " sulphate            31 |   "    pyrophosphate       18
+    " tartrate            40 |   "    sulphate            30
+  Lead acetate            42 |   "    tungstate           45
+    " nitrate             50 | Stroutium bromide          50
+  Magnesium chloride      35 |   "       chlorate         65
+    "       lactate        6 |   "       chloride         34
+    "       nitrate       45 | Tin choride (stannous)     75
+    "       sulphate      40 |
+  Manganese chloride      47 | Zinc acetate               20
+    "       lactate        8 |   "  ammon. chloride       43
+    "       sulphate      44 |   "  nitrate               55
+  Mercury cyanide         20 |   "  sulphate              45
+</pre>
+
+<hr>
+<p><a name="10"></a></p>
+
+<h2>THE PRINCIPLES OF HOP-ANALYSIS.</h2>
+
+<h3>By Dr. G. O. CECH</h3>
+
+<p>[Footnote: 'Zeitschrift fur Analyt. Chemie,' 1881.]</p>
+
+<p>Hop flowers contain a great variety of different substances
+susceptible of extraction with ether, alcohol, and water, and
+distinguishable from one another by tests of a more or less complex
+character. The substances are: Ethereal oil, chlorophyl, hop
+tannin, phlobaphen, a wax-like substance, the sulphate, ammoniate,
+phosphate, citrate and malates of potash, arabine, a crystallized
+white and an amorphous brown resin, and a bitter principle. That
+the characteristic action of the hops is due to such of these
+constituents only as are of an organic nature is easy to
+understand; but up to the present we are in ignorance whether it is
+upon the oil, the wax, the resin, the tannin, the phlobaphen, or
+the bitter principle individually, or upon them all collectively,
+that the effect of the hops in brewing depends.</p>
+
+<p>It is the rule to judge the strength and goodness of hops by the
+amount of farina--the so-called lupuline; and as this contains the
+major portion of the active constituents of the hop, there is no
+doubt that approximately the amount of lupuline is a useful
+quantitative test. But here we are confronted by the question
+whether the lupuline is to be regarded as containing <i>all</i>
+that is of any value in the hops and the leaves, the organic
+principles in which pass undetected under such a test, as
+supererogatory for brewers' purposes? Practical experience
+negatives any such conclusion. Consequently, we are justified in
+assuming that the concurrent development and the presence of the
+several organic principles--the oil, the wax, the bitter, the
+tannin, the phlobaphen, in the choicer sorts--are subject, within
+certain limits, to variations depending on skilled culture and
+careful drying, and that the aggregate of these principles has a
+certain attainable maximum in the finer sorts, under the most
+favorable conditions of culture, and another, lower maximum in less
+perfectly cultivated and wild sorts. The difference in the
+proportion of active organic substance in each sort must be
+determined by analysis. There then remains to be discovered which
+of the aforesaid substances plays the leading role in brewing, and
+also whether the presence of chlorophyl and inorganic salts in the
+hop extract influences or alters the results.</p>
+
+<p>That in brewing hops cannot be replaced by lupuline alone, even
+when the latter is employed in relatively large quantities is well
+known, as also that a considerable portion of the bitter principle
+of the hop is found in the floral leaves. Neither can the lupuline
+be regarded as the only active beer agent, as both the hop-tannin
+and the hop-resin serve to precipitate the albuminous matter, and
+clarify and preserve the beer.</p>
+
+<p>Both chemists and brewers would gladly welcome some method of
+testing hops, which should be expeditious, and afford reliable
+results in practical hands. To accomplish this account must be
+taken of all the active organic constituents of the hops, which can
+be extracted either with ether, alcohol, or water containing soda
+(for the conversion of the hop tannin in phlobaphen).[1] It should
+further be ascertained whether the chlorophyl percentage in the hop
+bells, new and old, is or is not the same in cultivated and in wild
+hops, and whether the aggregate percentages of organic and
+constituent observe the same limits.</p>
+
+<p>[Footnote 1: See C. Etti, in "Dingler's Polytech. Journ.," 1878,
+p. 354.]</p>
+
+<p>As wild hops nowadays are frequently introduced in brewing, the
+proportion of chlorophyl and organic and inorganic constituents in
+them should be compared with those of cultivated sorts, taking the
+best Bavarian or Bohemian hops as the standard of measurement. The
+chlorophyl is of minor importance, as it has little effect on the
+general results.</p>
+
+<p>By a series of comparative analysis of cultivated and wild hops,
+in which I would lay especial stress on parity of conditions in
+regard of age and vegetation, the extreme limits of variation of
+which their active organic principles are susceptible could be
+determined.</p>
+
+<p>There is every reason to suppose that the chlorophyl and
+inorganic constituents do not differ materially in the most widely
+different sorts of hops. The more important differences lie in the
+proportions of hop resin and tannin. When this is decided, the
+proportion of tannin or phlobaphen in the hop extract or the beer
+can be determined by analysis in the ordinary way. But whenever
+some quick and sure hop test shall have been found, <i>appearance
+and aroma</i> will still be most important factors in any estimate
+of the value of hops. Here a question arises as to whether hops
+from a warm or even a steppe climate, like that of South Russia,
+contain the same proportion of ethereal oil--that is, of aroma--as
+those from a cooler climate, like Bavaria and Bohemia, or like
+certain other fruit species of southern growth, they are early in
+maturing, prolific, large in size, and abounding in farina, but
+<i>deficient in aroma</i>.</p>
+
+<p>The bearings of certain experimental data on this point I
+reserve for consideration upon a future occasion.--<i>The
+Analyst</i>.</p>
+
+<hr>
+<p><a name="11"></a></p>
+
+<h2>WATER GAS.</h2>
+
+<h3>A DESCRIPTION OF APPARATUS FOR PRODUCING CHEAP GAS, AND SOME
+NOTES ON THE ECONOMICAL EFFECT OF USING SUCH GAS WITH GAS MOTORS,
+ETC.</h3>
+
+<p>[Footnote: Abstract of paper read in Section G. British
+Association, York]</p>
+
+<h3>By MR. J. EMERSON DOWSON, C.E., of London.</h3>
+
+<p>In many countries and for many years past, inventors have sought
+some cheap and easy means of decomposing steam in the presence of
+incandescent carbon in order to produce a cheap heating gas; and
+working with the same object the writer has devised an apparatus
+which has been fitted up in the garden of the Industrial
+Exhibition, and is there making gas for a 3&frac12; horse power
+(nominal) Otto gas engine. The retort or generator consists of a
+vertical cylindrical iron casing which incloses a thick lining of
+ganister to prevent loss of heat and oxidation of the metal, and at
+the bottom of this cylinder is a grate on which a fire is built up.
+Under the grate is a closed chamber, and a jet of superheated steam
+plays into this and carries with it by induction a continuous
+current of air. The pressure of the steam forces the mixture of
+steam and air upward through the fire, so that the combustion of
+the fuel is maintained while a continuous current of steam is
+decomposed, and in this way the working of the generator is
+constant, and the gas is produced without fluctuations in quality.
+The well-known reactions occur, the steam is decomposed, and the
+oxygen from the steam and air combines with the carbon of the fuel
+to form carbon dioxide (CO<sub>2</sub>), which is reduced to the
+monoxide (CO) on ascending the fuel column. In this way the
+resulting gases form a mixture of hydrogen, carbon, monoxide, and
+nitrogen, with a small percentage of carbon dioxide which usually
+escapes without reduction. The steam should have a pressure of
+1&frac12; to 2 atmospheres, and is produced and superheated in a
+zigzag coil fed with water from a neighboring boiler. The quantity
+of water required is very small, being only about 7 pints for each
+1,000 cubic feet of gas, and, except on the first occasion when the
+apparatus is started, the coil is heated by some of the gas drawn
+from the holder, so that after the gas is lighted under the coil
+the superheater requires no attention.</p>
+
+<p>For boiler and furnace work the gas can be used direct from the
+generator; but where uniformity of pressure is essential, as for
+gas engines, gas burners, etc., the gas should pass into a holder.
+The latter somewhat retards the production, but the steam injector
+causes gas to be made so rapidly that a holder is easily filled
+against a back pressure of 1 in. to 1&frac12; in. of water, and at
+this pressure the generator can pass gas continuously into the
+holder, while at the same time it is being drawn off for
+consumption.</p>
+
+<p>The nature of the fuel required depends on the purpose for which
+the gas is used. If for heating boilers, furnaces, etc, coke or any
+kind of coal maybe used; but for gas engines or any application of
+the gas requiring great cleanliness and freedom from sulphur and
+ammonia it is best to use anthracite, as this does not yield
+condensable vapors, and is very free from impurities. Good
+qualities of this fuel contain over 90 per cent of carbon and so
+little sulphur that, for some purposes, purification is not
+necessary. For gas engines, etc., it is, however, better to pass
+the gas through some hydrated oxide of iron to remove the
+sulphureted hydrogen. The oxide can be used over and over again
+after exposure to the air, and the purifying is thus effected
+without smell or appreciable expense. Gas made by this process and
+with anthracite coal has no tar and no ammonia, and the small
+percentage of carbon dioxide present does not sensibly affect the
+heating power. A further advantage of this gas is that it cannot
+burn with a smoky flame, and there is no deposition of soot even
+when the object to be heated is placed over or in the flame, and
+this is of importance for the cylinder and valves of a gas
+engine.</p>
+
+<p>To produce 1,000 cubic feet only 12 lb. of anthracite are
+required, allowing 8 to 10 per cent, for impurities and waste; thus
+a generator A size, which produces 1,000 cubic feet per hour, needs
+only 12 lb. in that time, and this can be added once an hour or at
+longer intervals. No skilled labor is necessary, and in practice it
+is usual to employ a man who has other work to attend to near the
+generator, and to pay him a small addition to his usual wages.</p>
+
+<p>The comparative explosive force of coal gas and the Dowson gas
+calculated in the usual way is as 3.4:1, i. e., coal gas has 3.4
+times more energy than the writer's gas. Messrs. Crossley, of
+Manchester, the makers of the Otto gas engines, have made several
+careful trials of this gas with some of their 3&frac12; horse power
+(nominal) engines, and in one trial they took diagrams every
+half-hour for nine consecutive days. These practical trials have
+shown that without altering the cylinder of the engine it is
+possible to admit enough of the Dowson gas to give the same power
+as with ordinary coal gas. It has been seen that the comparative
+explosive force of the two gases is as 3.4:1, but as it is well
+known the combustion of carbon monoxide proceeds at a comparatively
+slow rate, and for this reason, and because of the diluents present
+in the cylinder which affect the weaker gas more than coal gas,
+experience has shown that it is best to allow five volumes of the
+Dowson gas for one volume of coal gas, and then the same uniform
+power is obtained as with the latter.</p>
+
+<p>This gives very important economical results; for if the cost of
+the Dowson gas given in the tables as 4&frac14;d., 3-1/3d., and
+2&frac34;d. per 1,000 cubic feet, be multiplied by 5 there will be
+1s. 9&frac14;d., 1s. 4&frac34;d., and 1s. 2&frac34;d., or a mean of
+1s. 5&frac12;d. for the equivalent of 1,000 cubic feet of coal gas,
+which usually costs from 3s. to 4s., and this represents an actual
+saving of about 50 to 60 per cent, in working cost. Another
+practical consideration is that coal gas requires 224 lb. to 250
+lb. of coal per 1,000 cubic feet of gas, but the writer requires
+only 12 lb. per 1,000 cubic feet, and multiplying this by 5 to give
+the equivalent of 1,000 cubic feet of coal gas, for engine work,
+there are 60 lb. instead of 224 lb. to 250 lb. This is only 24 to
+27 per cent, of the weight of the coal required for coal gas, and
+in many outlying districts this will effect an appreciable saving
+in the cost of transport.</p>
+
+<h3>APPENDIX.</h3>
+
+<pre>
+   TABLE I.
+<br>
+  _Generator A Size_ (producing 1,000 cubic feet per hour):
+    Anthracite to make gas at the rate of 1,000   s.  d.
+      cubic feet per hour=l2 lb x 9 working
+      hours=l08 lb., or say, 1 cwt. at 20s. a
+      ton....................................     1   0
+    Allowance for wages of attendant.........     1   0
+    Repairs and depreciation of generator,
+      gasholder, etc. (5 per cent. on &pound;l25)=
+      per working day........................     0   5
+    Interest on capital outlay, ditto........     0   5
+                                                 ______
+<br>
+             Total...........................     2  10
+                                                  cub. ft.
+<br>
+    Gas produced.............................     9.000
+    Less gas used for generating and
+       superheating steam.....................    1,000
+                                                  _____
+             Total effective gas for 2s. 10d.     8,000
+<br>
+  Net cost 4&frac14; d. per 1,000 cubic feet.
+<br>
+  TABLE II.
+<br>
+  _Generator B Size_ (producing 1,500 cubic feet per hour)
+    Anthracite to make gas at the rate of 1,500   s.  d.
+      cubic feet per hour=18 lb. x 9 working
+      hours=162 lb., or, say, 1&frac12; cwt. 20s.
+      a ton..................................     1    6
+    Allowance for wages of attendant.........     1    0
+    Repairs and depreciation of generator,
+      gasholder, etc. (5 per cent, on &pound;140)
+      =per working day.......................     0    5&frac12;
+    Interest on capital outlay, ditto........     0    5&frac12;
+                                                 ___  ___
+             Total...........................     3    5
+                                                 cub. ft.
+    Gas produced.............................    13,500
+    Less gas used for generating and
+      superheating steam.....................     1,200
+                                                 ______
+             Total effective gas for 3s. 5d..    12,300
+<br>
+  Net cost 3 1/3d. per 1,000 cubic feet.
+<br>
+  TABLE III.
+<br>
+  _Generator C Size_ (producing 2,500 cubic feet per hour):
+    Anthracite to make gas at the rate of 2,500      s. d.
+    cubic feet per hour=30 lb. x 9 working
+    hours=270 lb. at 20s. a ton............          2  4&frac12;
+    Allowance for wages of attendant.......          1  6
+    Repairs and depreciation of generator,
+      gasholder, etc. (5 per cent, on &pound;160)=
+      per working day......................          0  6&frac12;
+    Interest on capital outlay, ditto......          0  6&frac12;
+                                                    _______
+             Total.........................          4 11&frac12;
+<br>
+                                                     cub. ft.
+    Gas produced...........................        22,500
+    Less gas used for generating and
+      superheating steam...................         1,500
+                                                   ______
+             Total effective gas for 4s. 11&frac12;d      21,000
+<br>
+  Net cost, say, 2&frac34; d. per 1,000 cubic feet.
+</pre>
+
+<hr>
+<p><a name="12"></a></p>
+
+<h2>ON THE FLUID DENSITY OF CERTAIN METALS.</h2>
+
+<p>[Footnote: Abstract of paper read before Section C (Chemical
+Science), British Association meeting, York.]</p>
+
+<h3>By PROFESSOR W. CHANDLER ROBERTS, F.R.S., and T.
+WRIGHTSON.</h3>
+
+<p>The authors described their experiments on the fluid density of
+metals made in continuation of those submitted to Section B at the
+Swansea meeting of the Association. Some time since one of the
+authors gave an account of the results of experiments made to
+determine the density of metallic silver, and of certain alloys of
+silver and copper when in a molten state. The method adopted was
+that devised by Mr. R. Mallet, and the details were as follows: A
+conical vessel of best thin Lowmoor plate (1 millimeter thick),
+about 16 centimeters in height, and having an internal volume of
+about 540 cubic centimeters, was weighed, first empty, and
+subsequently when filled with distilled water at a known
+temperature. The necessary data were thus afforded for accurately
+determining its capacity at the temperature of the air. Molten
+silver was then poured into it, the temperature at the time of
+pouring being ascertained by the calorimetric method. The
+precautions, as regards filling, pointed out by Mr. Mallet, were
+adopted; and as soon as the metal was quite cold, the cone with its
+contents was again weighed. Experiments were also made on the
+density of fluid bismuth; and two distinctive determinations gave
+the following results:</p>
+
+<pre>
+  10.005 )
+         ) mean 10.039.
+  10.072 )
+</pre>
+
+<p>The invention of the oncosimeter, which was described by one of
+the authors in the "Journal of the Iron and Steel Institute" (No.
+II., 1879, p. 418), appeared to afford an opportunity for resuming
+the investigation on a new basis, more especially as the delicacy
+of the instrument had already been proved by experiments on a
+considerable scale for determining the density of fluid cast iron.
+The following is the principle on which this instrument acts:</p>
+
+<p>If a spherical ball of any metal be plunged below the surface of
+a molten bath of the same or another metal, the cold ball will
+displace its own volume of molten metal. If the densities of the
+cold and molten metal be the same, there will be equilibrium, and
+no floating or sinking effect will be exhibited. If the density of
+the cold be greater than that of the molten metal, there will be a
+sinking effect, and if less a floating effect when first immersed.
+As the temperature of the submerged ball rises, the volume of the
+displaced liquid will increase or decrease according as the ball
+expands or contracts. In order to register these changes the ball
+is hung on a spiral spring, and the slightest change in buoyancy
+causes an elongation or contraction of this spring which can be
+read off on a scale of ounces, and is recorded by a pencil on a
+revolving drum. A diagram is thus traced out, the ordinates of
+which represent increments of volume, or, in other words, of weight
+of fluid displaced--the zero line, or line corresponding to a ball
+in a liquid of equal density, being previously traced out by
+revolving the drum without attaching the ball of metal itself to
+the spring, but with all other auxiliary attachments. By means of a
+simple adjustment the ball is kept constantly depressed to the same
+extent below the surface of the liquid; and the ordinate of this
+pencil line, measuring from the line of equilibrium, thus gives an
+exact measure of the floating or sinking effect at every stage of
+temperature, from the cold solid to the state when the ball begins
+to melt.</p>
+
+<p>If the weight and specific gravity of the ball be taken when
+cold, there are obtained, with the ordinate on the diagram at the
+moment of immersion, sufficient data for determining the density of
+the fluid metal; for</p>
+
+<p>W / W<sub>1</sub> = D / D<sub>1</sub></p>
+
+<p>the volumes being equal. And remembering that</p>
+
+<p>W (weight of liquid) = W<sub>1</sub> (weight of ball) + x</p>
+
+<p>(where x is always measured as +<i>ve</i> or -<i>ve</i> floating
+effect), there is obtained the equation: <img src=
+"images/tex1.png" align="middle" alt=
+"D = \frac{D_1 \times (W_1 +x)}{W_1}"></p>
+
+<p>The results obtained with metallic silver are perhaps the most
+interesting, mainly from the fact that the metal melts at a higher
+temperature, which was determined with great care by the
+illustrious physicist and metallurgist, the late Henri St. Claire
+Deville, whose latest experiments led him to fix the melting point
+at 940&deg; Cent. The authors of the paper showed that the density
+of the fluid metal was 9.51 as compared with 10.57, the density of
+the solid metal. Taking their results generally, it is found that
+the change of volume of the following metals in passing from the
+solid to the liquid state may be thus stated:</p>
+
+<pre>
+               Specific       Specific
+   Metal.        Gravity,      Gravity,      Percentage of
+                 Solid.        Liquid.         Change.
+<br>
+  Bismuth         9.82         10.055     Decrease of volume  2.3
+  Copper          8.8           8.217     Increase       "    7.1
+  Lead           11.4          10.37          "          "    9.93
+  Tin.            7.5           7.025         "          "    6.76
+  Zinc            7.2           6.48          "          "   11.10
+  Silver         10.57          9.51          "          "   11.20
+  Iron            6.95          6.88          "          "    1.02
+</pre>
+
+<hr>
+<p><a name="18"></a></p>
+
+<h2>HYDROPHOBIA PREVENTED BY VACCINATION.</h2>
+
+<p>M. Pasteur and other French savants have lately been devoting
+special attention to hydrophobia. The great authority on germs has,
+in fact, definitely announced that he does not intend to rest until
+he has made known the exact nature and life-history of this
+terrible disease, and discovered a means of preventing or curing
+it. The most curious result yet attained in this direction,
+however, has been announced by Professor V. Galtier, of the Lyons
+Veterinary School. This inquirer has found, in the first place,
+that if the virus of rabies be injected into the veins of a sheep,
+the animal does not subsequently exhibit any symptoms of
+hydrophobia. This in itself would be a sufficiently curious result
+to justify attention, though its importance, except as confirmatory
+testimony, becomes less striking when it is remembered that M.
+Pasteur has lately shown that the special <i>nidus</i> of the
+disease appears to be the nervous tissue, and particularly the
+ganglionic centers. But there is this further curious consequence:
+sheep who have thus been treated through the blood, and who are
+afterwards inoculated in the ordinary way through the cellular
+tissue, as if by a bite, are proof against the disease. It is as
+though the injection into the veins acted as a vaccine. Twenty
+sheep were experimented upon; ten only were treated to the venous
+injection, and then all were inoculated through the cellular
+tissue. The ten which had been first "vaccinated" continue alive
+and well; they have not even shown any adverse symptoms. The other
+ten have all died of rabies. It remains to say why M. Galtier
+experimented upon sheep, and not upon dogs and cats, which usually
+communicate the disease. The incubation of the disease is much more
+rapid and less capricious in the sheep than in the dog or in man,
+and hence M. Galtier was able to get his results more certainly
+within a short period. Having succeeded so far, he is now justified
+in undertaking the more protracted series of observations which
+experiments upon the canine species will involve; and this he
+proposes to do. Experiments of this nature are not without a
+serious risk, and admiration is almost equally due to the courage
+and the intelligence of the experimentalist. But what will the
+anti-vaccinator say?--<i>Pall Mall Gazette</i>.</p>
+
+<hr>
+<p><a name="19"></a></p>
+
+<h2>ON DIPTERA AS SPREADERS OF DISEASE.</h2>
+
+<h3>By J.W. SLATER.</h3>
+
+<p>The two-winged flies, in their behavior to man, stand in a
+marked contrast to all the other orders of insects. The
+Lepidoptera, the Coleoptera, the Neuroptera, the Hymenoptera no
+doubt occasion, in some of their forms at least, much damage to our
+crops. But none of them are parasitic in or upon our bodies; none
+of them persistently intrude into our dwellings, hover around us in
+our walks, and harass us with noise and constant attempts to bite,
+or at least to crawl upon us. Even the ants, except in a few
+tropical districts, rarely act upon the offensive. The Hemiptera
+contain one semi-parasitic species which has attained a "world-wide
+circulation," and one degraded, purely parasitic group. But the
+Diptera, among which the fleas are now generally included as a
+degenerated type, comprise more forms personally annoying to man
+than all the remaining insect orders put together. These hostile
+species are, further, incalculably numerous, and occur in every
+part of the globe. Mosquitoes swarm not merely in the swampy
+forests of the Orinoco or the Irrawaddy, but in the Tundras of
+Siberia, en the storm-beaten rocks of the Loffodens, and are even
+encountered by voyagers in quest of the North Pole. The common
+house fly was probably at one time peculiar to the Eastern
+Continent, but it followed the footsteps of the Pilgrim Fathers,
+and is now as great a nuisance in the United Slates and the
+Dominion as in any part of Europe. It is curious, but distressing,
+to note the tendency of evils to become international. We have
+communicated to America the house-fly and the Hessian fly, the
+"cabbage-white," the small pox, and the cholera. She, in return,
+has given us the <i>Phylloxera</i>, a few visitations of yellow
+fever, the <i>Blatta gigantea</i>, and, climate allowing, may
+perhaps throw in the Colorado beetle as a make-weight. In this
+department, at least, free trade reigns undisputed. It is a
+singular thing that no beautiful, useful, or even harmless species
+of bird or insect seems capable of acclimatizing itself as do those
+characterized by ugliness and noisomeness.</p>
+
+<p>But, returning from this digression, we find in the Diptera the
+habit of obtrusion and intrusion, of coming in actual contact with
+our food and our persons, combined with another propensity--that of
+feeding upon carrion, excrement, blood, pus, and morbid matter of
+all kinds. This is a combination far more serious than is generally
+imagined. If the fly--which may at any moment settle upon our lips,
+our eyes, or upon an abraded part of our skin--were cleanly in its
+habits, we need feel little annoyance at its visits. Or if it were
+the most eager carrion devourer, but did not, after having dined,
+think it necessary to seek our company, we might hold it, as is
+done too hastily by some naturalists, a valuable scavenger. I fear,
+however, that I have already made too great a concession. So long
+as very many persons are suffering from disease--so long as many
+diseases are capable of being transmitted from the sick to the
+healthy--so long must any creature which is in the habit of flying
+about, and touching first one person and then another, be a
+possible medium of infection and death.</p>
+
+<p>Let us take the following case, by no means imaginary, but a
+generalization from occurrences far too frequent: A healthy man,
+sitting in his house or walking in the fields, especially in
+countries where the insectivorous birds have been shot down,
+suddenly feels a sharp prick on his neck or his cheek. Putting his
+hand to the place he perhaps crushes, perhaps merely brushes away,
+a fly which has bitten him so as to draw blood. The man thinks
+little of so trifling a hurt, but the next morning he finds the
+puncture exceedingly painful. An inflamed pimple forms, which
+quickly gets worse, while constitutional symptoms of a feverish
+kind come on. In alarm he seeks medical advice. The doctor tells
+him that it is a malignant pustule, and takes at once the most
+active measures. In spite of all possible skill and care the
+patient too often succumbs to the bite of a <i>mouche
+charbonneuse</i>, or carbuncle-fly. But has any kind of fly the
+property of producing malignant pustule by some specific inherent
+power of its own? Surely not. The antecedent circumstances are
+these: A sheep or heifer is attacked with the disease known in
+France as <i>charbon</i>, in Germany as <i>milz-brand</i>, and in
+England as <i>splenic fever</i>. Its blood on examination would be
+found plentifully peopled with bacteria. If a lancet were plunged
+into the body of the animal, and were then used to slightly scratch
+or cut the skin of a man, he would be inoculated with "charbon."
+The bite of the fly is precisely similar in its action. Its rostrum
+has been smeared with the poisoned blood, an infinitesimal particle
+of which is sufficient to inclose several of the disease "germs,"
+and these are then transferred to the blood of the next man or
+animal which the fly happens to bite. The disease is reproduced as
+simply and certainly as the spores of some species of fern give
+rise to their like if scattered upon soil suitable for their
+growth. But flies which do not bite may transfer infection. Every
+one must know that if blood be spilt upon the ground a crowd of
+flies will settle upon and eagerly absorb it. Animals suffering
+from splenic fever in the later stages of the disease sometimes
+emit bloody urine. Often they are shot or slaughtered by way of
+stamping out the plague, and their carcasses are buried deep in the
+ground. But some loss of blood is sure to happen, and this will
+mostly be left to soak into the ground. Here again the flies will
+come, and their feet and mouth will become charged with the
+contagion. Such a fly, settling upon another animal or a man, and
+selecting--as it will do by preference, if such exist--a wound, or
+a place where the skin is broken, will convey the disease.</p>
+
+<p>Again, M. Pasteur has thoughtfully pointed out that if an animal
+has died of splenic fever, and has been carefully buried, the
+earth-worms may bring up portions of infectious matter to the
+surface, so that sheep grazing, or merely being folded over the
+spot in question, may take the plague and die. Hence be wisely
+counsels that the bodies of such animals should be buried in sandy
+or calcareous soils where earth-worms are not numerous. But it is
+perfectly legitimate to go a step farther. If such worm-borings
+retain the slightest savor of animal matter, flies will settle upon
+them and will convey the infectious dust to the most unexpected
+places, giving wings to the plague.</p>
+
+<p>Now it is very true that no one has seen a fly feasting upon the
+blood of a heifer or sheep dying or just dead of splenic fever, has
+then watched it settle upon and bite some person, and has traced
+the following stages of the disease. But it is positively known
+that a person has been bitten by a fly, and has then exhibited all
+the symptoms of charbon, the place of the bite being the primary
+seat of the infection. We know also, beyond all doubt, the
+eagerness with which flies will suck up blood, and we likewise know
+the strange persistence of the disease "germs."</p>
+
+<p>Again, the avidity of flies for purulent matter is not a thing
+of mere possibility. In Egypt, where ophthalmia is common, and
+where the "plague of flies" seems never to have been removed, it is
+reported as almost impossible to keep these insects away from the
+eyes of the sufferers. The infection which they thus take up they
+convey to the eyes of persons still healthy, and thus the scourge
+is continually multiplied.</p>
+
+<p>A third case which seems established beyond question is the
+agency of mosquitoes in spreading elephantiasis. These so-called
+sanitary agents suck from the blood of one person the Filariae, the
+direct cause of the disease, and transfer them to another. The
+manner in which this process is effected will appear simple enough
+if we reflect that the mosquito begins operations by injecting a
+few drops of fluid into its victim, so as to dilute the blood and
+make it easier to be sucked.</p>
+
+<p>So much being established it becomes in the highest degree
+probable that every infectious disease may be, and actually is, at
+times propagated by the agency of flies. Attention turned to this
+much neglected quarter will very probably go far to explain obscure
+phenomena connected with the distribution of epidemics and their
+sudden outbreaks in unexpected quarters. I have seen it stated that
+in former outbreaks of pestilence flies were remarkably numerous,
+and although mediaeval observations on Entomology are not to be
+taken without a grain of salt, the tradition is suggestive. Perhaps
+the Diptera have their seasons of unusual multiplication and
+emigration. A wave of the common flea appears to have passed over
+Maidstone in August, 1880.</p>
+
+<p>We now see the way to some practical conclusions not without
+importance. Recognizing a very considerable part of the order of
+Diptera, or two-winged flies, as agents in spreading disease, it
+surely follows that man should wage war against them in a much more
+systematic and consistent manner than at present. The destruction
+of the common house-fly by "<i>papier Moure</i>," by decoctions of
+quassia, by various traps, and by the so-called "catch 'em alive,"
+is tried here and there, now and then, by some grocer,
+confectioner, or housewife angry at the spoliation and defilement
+caused by these little marauders. But there is no concerted
+continuous action--which after all would be neither difficult nor
+expensive--and consequently no marked success. Experiments with a
+view of finding out new modes of fly-killing are few and far
+between.</p>
+
+<p>Every one must occasionally have seen, in autumn, flies as if
+cemented to the window-pane, and surrounded with a whitish halo.
+That in some seasons numbers of flies thus perish--that the
+phenomenon is due to a kind of fungus, the spores of which readily
+transfer the disease from one fly to another--we know. But here our
+knowledge is at fault. We have not learnt why this fly-epidemic is
+more rife in some seasons than others. We are ignorant concerning
+the methods of multiplying this fungus at will, and of launching it
+against our enemies. We cannot tell whether it is capable of
+destroying <i>Stomoxys calcitram</i>, the blowflies, gadflies,
+gnats, mosquitoes, etc. Experiment on these points is rendered
+difficult by the circumstance that the fungus is rarely procurable
+except in autumn, when some of the species we most need to destroy
+are not to be found. Another question is whether the fungus, if
+largely multiplied and widely spread, might not prove fatal to
+other than Dipterous insects, especially to the Hymenoptera, so
+many of which, in their character of plant-fertilizers, are highly
+useful, or rather essential to man.</p>
+
+<p>Another fungus, the so-called "green muscardine" (<i>Isaria
+destructor</i>), has been found so deadly to insects that Prof.
+Metschnikoff, who is experimenting upon it, hopes to extirpate the
+<i>Phylloxera</i>, the Colorado beetle, etc., by its agency.</p>
+
+<p>Coming to better known and still undervalued fly-destroyers, we
+have interfered most unwisely with the balance of nature. The
+substitution of wire and railings for live fences in so many fields
+has greatly lessened the cover both for insectivorous birds and for
+spiders. The war waged against the latter in our houses is plainly
+carried too far. Whatever may be the case at the Cape, in
+Australia, or even in Southern Europe, no British species is
+venomous enough to cause danger to human beings. Though cobwebs are
+not ornamental, save to the eye of the naturalist, there are parts
+of our houses where they might be judiciously tolerated: their
+scarcity in large towns, even where their prey abounds, is somewhat
+remarkable.</p>
+
+<p>But perhaps the most effectual phase of man's war against the
+flies will be negative rather than positive, turning not so much on
+putting to death the mature individuals as in destroying the matter
+in which the larvae are nourished. Or if, from other
+considerations, we cannot destroy all organic refuse, we may and
+should render it unfit for the multiplication of these vermin. We
+have, indeed, in most of our large towns and in their suburbs,
+abolished cesspools, which are admirable breeding-places for many
+kinds of Diptera, and which sometimes presented one wriggling mass
+of larvae. We have drained many marshes, ditches, and unclean
+pools, rich in decomposing vegetable matter, and have thus notably
+checked the propagation of gnats and midges. I know an instance of
+a country mansion, situate in one of the best wooded parts of the
+home counties, which twenty years ago was almost uninhabitable,
+owing to the swarms of gnats which penetrated into every room. But
+the present proprietor, being the reverse of pachydermatous, has
+substituted covered drains for stagnant ditches, filled up a number
+of slimy ponds as neither useful nor ornamental, and now in most
+seasons the gnats no longer occasion any annoyance.</p>
+
+<p>But if we have to some extent done away with cesspools and
+ditches, and have reaped very distinct benefit by so doing, there
+is still a grievous amount of organic matter allowed to putrefy in
+the very heart of our cities. The dust bins--a necessary
+accompaniment of the water-carriage system of disposing of
+sewage--are theoretically supposed to be receptacles mainly for
+organic refuse, such as coal-ashes, broken crockery, and at worst
+the sweepings from the floors. In sober fact they are largely mixed
+with the rinds, shells, etc., of fruits and vegetables, the bones
+and heads of fish, egg-shells, the sweepings out of dog-kennels and
+henhouses, forming thus, in short, a mixture of evil odor, and well
+adapted for the breeding-place of not a few Diptera.</p>
+
+<p>The uses to which this "dust" is put when ultimately fetched
+away are surprising: without being freed from its organic refuse it
+is used to fill up hollows in building-ground, and even for the
+repair of roads. A few weeks ago I passed along a road which was
+being treated according to the iniquity of Macadam. Over the broken
+stones had been shot, to consolidate them, a complex of ashes,
+cabbage-leaves, egg and periwinkle shells, straw, potato-parings, a
+dead kitten (over which a few carrion-flies were hovering), and
+other promiscuous nuisances. The road in question, be it remarked,
+is highly "respectable," if not actually fashionable. The houses
+facing upon it are severely rated, and are inhabited chiefly by
+"carriage people." What, then, may not be expected in lower
+districts?</p>
+
+<p>Much attention has lately been drawn to the fish trade of
+London. It has <i>not</i>, however, come out in evidence that the
+fish retailers, if they find a quantity of their perishable wares
+entering into decomposition, send out late in the evening a
+messenger, who, watching his opportunity, throws his burden down in
+some plot of building land, or over a fence. When I say that I have
+seen in one place, close alongside a public thoroughfare, a heap of
+about fifty herrings, in most active putrefaction and buzzing with
+flies, and some days afterward, in another place, some twenty
+soles, it will be understood that such nuisances can only be
+occasioned by dealers. To get rid of, or at least greatly diminish,
+carrion-flies, house-flies, and the whole class of winged travelers
+in disease, it will be, before all things, essential to abolish
+such loathsome malpractices. The dustbins must cease being made the
+receptacle for putrescent and putrescible matter, the destruction
+of which by fire should be insisted upon.</p>
+
+<p>The banishment of slaughter-houses to some truly rural
+situation, where the blood and offal could be at once utilized,
+would be another step toward depriving flies of their pabulum in
+the larva state. An equally important movement would be the
+substitution of steam or electricity for horsepower in propelling
+tram-cars and other passenger carriages, with a view to minimize
+the number of horses kept within greater London. Every large stable
+is a focus of flies--<i>Journal of Science</i>.</p>
+
+<hr>
+<p><a name="20"></a></p>
+
+<h2>ON THE RELATIONS OF MINUTE ORGANISMS TO CERTAIN SPECIFIC
+DISEASES.</h2>
+
+<p>At the recent Medical Congress in London, Professor Klebs
+undertook to answer the question: "Are there specific organized
+causes of disease?"</p>
+
+<p>A short historical review of the various opinions of mankind as
+to the origin of disease led, the speaker thought, to the
+presumption that these causes were specific and organized.</p>
+
+<p>If we now, he said, consider the present state of this question,
+the three following points of view present themselves as those from
+which the subject may be regarded:</p>
+
+<p>I.--We have to inquire whether the lower organisms, which are
+found in the diseased body, may arise there spontaneously; or
+whether even they may be regarded as regular constituents of the
+body.</p>
+
+<p>II.--The morphological relations of these organisms have to be
+investigated, and their specific nature in the different morbid
+processes has to be determined.</p>
+
+<p>III.--We have to inquire into their biological relations, their
+development inside and outside the body, and the conditions under
+which they are able to penetrate into the body, and there to set up
+disease.</p>
+
+<p><i>First</i>.--With regard to the first question, that of the
+possibility of spontaneous generation, the speaker gave a decided
+negative.</p>
+
+<p><i>Second and third</i>.--There is in microscopic organisms a
+difference of form corresponding, as a rule, to difference of
+function. The facts regarding these various lower forms are briefly
+reviewed.</p>
+
+<p>"Three groups of hyphomycetae, algae, and schizomycetae, have
+been demonstrated to occur in the animal and human organism in
+infective diseases. Their significance increases with the increase
+of their capacity for development in the animal body. This depends
+partly upon their natural or ordinary conditions of life, but
+partly also, and that in a very high degree, upon their power of
+adaptation, which, as Darwin has shown, is a property of all living
+things, and causes the production of new species with new active
+functions.</p>
+
+<p>"1. The hyphomycetae, on account of their needing an abundant
+supply of oxygen, give rise to but few morbid processes, and these
+run their course on the surface of the body, and are hence
+relatively of less importance. It will be sufficient here to refer
+to the forms, achorion, trichophyton, o&iuml;dium, aspergillus, and
+the diseases produced by them, favus, ringworm, and thrush, to show
+this peculiarity. Nevertheless, we see that these organisms also
+(as was proved by the older observations of Hannover and Zenker)
+may, under certain circumstances, penetrate into the interior of
+the organs. Grawitz, moreover, has recently shown that their
+faculty of penetrating into the interior of the organism, and there
+undergoing further development, depends on their becoming
+accustomed to nitrogenous food.</p>
+
+<p>"2. Only one of the algae, viz., leptothrix, has as yet acquired
+any importance as a producer of disease. It gives rise to the
+formation of concretions, and that not only in the mouth, but also,
+as I have shown, in the salivary ducts and urinary bladder.</p>
+
+<p>"Another alga, the sarcina of Goodsir, may indeed pass through
+the organism, without, however, producing in its passage either
+direct or indirect disturbances. It seems more worthy of note that
+many schizomycetae, and especially the group of bacilli, are
+evidently nearly allied to the algae in their morphological and
+vegetative relations--so as to be assigned to this class by several
+authors, and especially by Cienkowski.</p>
+
+<p>"The schizomycetae furnish, without doubt, by far the most
+numerous group of infective diseases. We distinguish within this
+group two widely different series of forms, which we will speak of
+as bacilli and cocco-bacteria respectively. The former, which was
+first exhaustively described by Ferdinand Cohn, and the
+pathological importance of which, especially in relation to the
+splenic disease of cattle, was first shown by Koch, consist of
+threads, in the interior of which permanent or resting-spores are
+developed. These spores becoming free, are able, under suitable
+conditions of life, again to develop into threads. The whole
+development of these organisms, and especially the formation of
+spores, is completed on the surface of the fluids, and under the
+influence of an abundant supply of oxygen.</p>
+
+<p>"The number of affections in which these organisms have been
+found, and which may be to a certain extent produced artificially
+by the introduction of these organisms into healthy animal bodies,
+has been largely increased since the discovery of Koch, that the
+bacteria of splenic fever (anthrax) belong to this group. Under
+this head must be placed the bacillus malarise (Klebs and
+Tommassi-Crudeli), the bacillus typhi abdominalis (Klebs, Ebert),
+the bacillus typhi exanthematici (Klebs, observations not yet
+published), the bacillus of hog-cholera (Klein), and, finally the
+bacillus leprosus (Neisser). It would exceed the time appointed
+were I to attempt to describe these forms more minutely. This may,
+perhaps, be better reserved for discussion and demonstration.</p>
+
+<p>"Alongside of these general infective diseases produced by
+bacilli, local affections also occur, which indicate the presence
+of these organisms at the point where disease begins. As an example
+of these processes, which probably occur in various organs, I would
+mention gastritis bacillaris, of which I shall show you
+preparations. In this, we can trace the entrance of the bacilli
+into the peptic glands, as well as their further distribution in
+the walls of the stomach, and in the vascular system.</p>
+
+<p>"The second group of the pathogenetic schizomycetae I propose to
+call, with Billroth, cocco-bacteria, because they consist of
+collections of micrococci, which are capable of transforming
+themselves into short rods. The former usually form groups united
+by zo&ouml;gloea; by prolongation of the cocci rods are formed,
+which sprout out, break up by division into chains, and further
+lead again to the formation of resting masses of cocci. I
+distinguish, further, in this group, two genera--the microsporina
+and the monadina; in the former of which the micrococci are
+collected into spherical lumps, in the latter into layers. The one
+class is developed in artificial cultivation fluid, the other on
+the surface. The former requires a medium poor in oxygen, the
+latter a medium rich in oxygen, for their development.</p>
+
+<p>"Among the affections produced by microsporina, I reckon
+especially the septic processes, and also true diphtheria. On the
+other hand, to the processes produced by monadina belong especially
+a large series of diseases, which according to their clinical and
+anatomical features, may be characterized as inflammatory
+processes, acute exanthemata, and infective tumors, or
+leucocytoses. Of inflammatory processes, those belong here which do
+not generally lead to suppuration, such as rheumatic affections,
+including the heart, kidney, and liver affections, which accompany
+this process, sequelae which, as is well known, lead more
+especially to formation of connective tissue, and not to
+suppuration. Here, also, belong croupous pneumonia, the allied
+disease erysipelas, certain puerperal processes, and finally,
+parotitis epidemica, or mumps.</p>
+
+<p>"Among the acute exanthemata, the following may, up to the
+present time, be placed in this group; variola-vaccina, scarlatina,
+and measles.</p>
+
+<p>"The group of infective tumors is represented by tuberculosis,
+syphilis, and glanders. Throughout the whole group of
+cocco-bacteria the demonstration of organisms in the diseased parts
+encounters difficulties which vary considerably in the different
+kinds."</p>
+
+<p>The speaker concluded by describing the methods (now well known)
+by which the powers of the different organisms are tested.</p>
+
+<p>He also referred to Pasteur's, Chauveau's, and Toussaint's
+recent experiments.</p>
+
+<p>His conclusion was that the specific communicable diseases are
+produced by specific organisms.</p>
+
+<hr>
+<p><a name="21"></a></p>
+
+<h2>THE CENTENARY OF THE DISCOVERY OF URANUS.</h2>
+
+<h3>By W. F. DENNING, F.R.A.S.</h3>
+
+<p>The year 1781 was signalized by an astronomical discovery of
+great importance, and one which marked the epoch as memorable in
+the annals of science. A musician at Bath, William Herschel by
+name, who had been constructing some excellent telescopes and
+making a systematic survey of the heavens, observed an object on
+the night of March 13 of that year, which ultimately proved to be a
+large planet revolving in an orbit exterior to that of Saturn. The
+discovery was as unique as it was significant. Only five planets,
+in addition to the Earth, had hitherto been known; they were
+observed by the ancients, and by each succeeding generation, but
+now a new light burst upon men. The genius of Herschel had singled
+out from the host of stars which his telescope revealed an object
+the true character of which had evaded human perception for
+thousands of years!</p>
+
+<p class="ctr"><a href="images/14a.png"><img src=
+"images/14a_th.png" alt=""></a></p>
+
+<p class="ctr">FIG. 1.--APPROXIMATE PLACE OF URANUS AMONGST THE
+STARS AT ITS DISCOVERY<br>
+ON MARCH 13, 1781</p>
+
+<p>The centenary of this remarkable advance in knowledge naturally
+recalls to mind the circumstances of the discovery, and makes us
+inquisitive to know what new facts have been gleaned of Herschel's
+planet, now that a hundred years have passed away, and we are
+enabled to look back and review the vast amount of labor which has
+been accomplished in this wide and attractive field of astronomical
+research. We may learn what new features have been discerned of the
+new body, and what additional discoveries in connection with other
+planets unknown in Herschel's day, have been effected by aid of the
+powerful telescopes which have been devoted to the work. We do not,
+however, intend dealing with the general question of planetary
+discovery, for at a glance we are impressed with its magnitude.
+While a century ago five planets only were known, we now have some
+two hundred and thirty of these bodies, and the stream of discovery
+flows on without abatement through each succeeding year. The
+detection of Uranus seems, indeed, to have been the prelude to many
+similar discoveries, and to have offered the incentive to greater
+diligence and energy on the part of observers in various parts of
+the world.</p>
+
+<p class="ctr"><a href="images/14b.png"><img src=
+"images/14b_th.png" alt=
+"Fig. 2.--ORBITS OF THE URANIAN SATELLITES."></a></p>
+
+<p class="ctr">Fig. 2.--ORBITS OF THE URANIAN SATELLITES.</p>
+
+<p>Many great discoveries have resulted from accident; and the
+leading facts attending that of Uranus prove that, in a large
+measure, the result was brought about in a similar way. Herschel,
+as he unwearyingly swept the heavens night after night, was in
+quest of sidereal wonders--such as double stars and nebulae--and he
+happened to alight upon the new planet in a purely chance way. He
+had no expectation of finding such a remarkable object, and indeed,
+when he had found it, wholly mistook its character. There could be
+no doubt that it was a body wholly dissimilar to the fixed stars,
+and it was equally certain that it could not be a nebula. It had a
+perceptible disk, for when it had first come under the critical eye
+of its discoverer he had noticed immediately that its appearance
+differed widely from the multitude of objects which crossed the
+field of his telescope. He had been accustomed to see hosts of
+stars pass in review, and their aspect was in one respect similar,
+namely, they were invariably presented as points of light incapable
+of being sensibly magnified, even with the highest powers. True,
+there was a great variety of apparent brightness in these objects
+and a singular diversity of configuration, but there was no
+exception to the invariable feature referred to. The point of light
+was constant, and no striking exception was anticipated until one
+night--March 13, 1781--Herschel being intently engaged in the
+examination of some small stars in the region of Gemini, brought an
+object under the range of, his telescope, which his eye at once
+selected as one of anomalous character.</p>
+
+<p>Applying a higher power, he noticed that it exhibited a
+planetary disk, but his instrument failed to define it with
+sufficient distinctness, and hence he became doubtful as to its
+real nature. The object was found to be in motion, and subsequent
+observations led him to the assumption that it must be a comet of
+rather exceptional type. This appeared to be the best explanation
+of the strange body, for history contained many records of curious
+comets, some of which were observed as nearly circular patches of
+nebulous light, and probably of similar aspect to the object then
+visible; and apart from this it must be remembered that the idea of
+a large planet exterior to Saturn was a fact of such momentous
+import that Herschel, with a due regard to that modesty which
+accompanies true genius, refrained from attaching such an
+interpretation to his observations. He was content to direct the
+notice of astronomers to it as a phenomenon requiring close
+attention, and suggested that it might be a comet in consequence of
+its motion and the faint and somewhat ill-defined character of its
+appearance.</p>
+
+<p>From the earliest ages five planets only were known, and the
+discovery of another large planet beyond the sphere of Saturn must
+at once revolutionize existing ideas as to the range of the solar
+system, and immediately take rank as a scientific event of equal
+interest to the discovery of the moons of Jupiter or the rings of
+Saturn, which each in their day impressed men with new ideas of the
+celestial mechanism. But the truth could not long be delayed. The
+new body being watched and its orbit rigorously computed from a
+series of observed positions revealed its true character, and
+Herschel was awarded the honor due to the author of a discovery of
+such importance. His diligence and pertinacity alone had enabled
+him to search out from among the multitude of stars thickly strewn
+over the firmament this unknown and well-nigh invisible planet
+which, during all the preceding years of the world's history, had
+eluded human perception. Men had been all unconscious of its
+existence as it had been slowly completing its circuits around the
+sun, obedient to the same laws as the other planets of the solar
+system, and awaiting the hour when the unfailing eve of Herschel
+should introduce it as the faint and far-off planet girding our
+system within its expansive folds.</p>
+
+<p>As soon as the existence of the new orb was confirmed and the
+fact rendered indisputable, the question naturally arose whether it
+had ever been seen in former years by the authors of star
+catalogues, who could hardly have overlooked an object like this
+though its planetary nature had manifestly escaped detection. It
+was just perceptible to the naked eye, shining like a star of the
+sixth magnitude, and ought to have been distinguished by those who
+had reviewed the heavens with the purpose of determining and
+mapping the positions of the stars. Reference was, therefore, made
+to the chief catalogues, when it was found at once that the planet
+had been unquestionably observed by Tobias Mayer, Le Monnier,
+Bradley, and Flamsteed. It was several times noted by these
+observers: by Le Monnier no less than twelve times, and by
+Flamsteed on six occasions; and it is remarkable that in every
+instance its true character escaped detection. Neither its special
+appearance nor its motion attracted attention, so that it was
+merely catalogued as an ordinary fixed star. Thus Herschel was not
+anticipated in his discovery. It remained for him, in 1781, to note
+its exceptional aspect, and to specify it as an object requiring
+critical investigation. But the early observations above alluded to
+served a useful purpose in testing the accuracy of the computed
+orbit, for without waiting many years to compare the theoretical
+and observed positions, astronomers had in these old records a
+reliable series of points through which the previous course of the
+planet could be traced.</p>
+
+<p>The calculations showed that its mean distance from the sun was
+some 1,750,000,000 miles, and that a revolution was completed in
+about eighty-four years. It was also found to be a very large
+planet, greatly exceeding either Mercury, Venus, the Earth, or
+Mars, though considerably inferior to either Jupiter or Saturn.</p>
+
+<p>Here, then, was a discovery of the utmost importance, and one of
+the most salient additions to our knowledge which the telescope had
+ever achieved. The new planet was now definitely assigned its
+proper place in the solar system, and was regarded as of equal
+significance with the old planets. True, the new planet of Herschel
+could not be compared as regards its visible aspect with the other
+previously known members of our system, but it was nevertheless an
+object of equal weight. Its vast distance alone rendered it faint.
+It formed one of the constituent parts of the solar system, which,
+though separated by immense intervals of space, are yet coherent by
+the far-reaching effects of gravitation. There is, indeed, a bond
+of harmony between the series of planetary orbits, which exhibit a
+marked degree of regularity in their successive distances from the
+sun; and though they are not connected by any visible links, they
+are firmly held together by unseen influences, and their motions
+are subject to certain laws which have been revealed by centuries
+of observation.</p>
+
+<p>The question of suitably naming the new planet soon came to the
+fore. Herschel himself proposed to designate it the "Georgium
+Sidus," in honor of his patron, George III., just as Galileo had
+called the satellites of Jupiter the "Medicean stars," after Cosmo
+de' Medici. But La Place proposed that the planet should be named
+after its discoverer; and thus it was frequently referred to as
+"Herschel," and sometimes as "The Herschelian planet." Astronomers
+on the continent objected to this system of personal nomenclature,
+and argued that the new body should receive an appellative in
+accordance with those adopted for the old planets, which had been
+selected from the heathen mythology. Several names were suggested
+as suitable (on the basis of this principle), and ultimately the
+one advanced by Bode received the most favor, and the planet
+thereafter was called "Uranus."</p>
+
+<p>The varying positions of the new body as observed on successive
+nights were determined by comparisons with a group of six small
+stars, termed by Herschel [Greek: alpha, beta, gamma, delta,
+epsilon] and afterwards formed into a constellation under the
+designation of "Britannia," though it does not appear that this
+little asterism is acknowledged as one of our constellations. Its
+position is about midway between Taurus and Gemini, and the
+following are the principal stars computed for 1881.0, as given by
+Mr. Marth:</p>
+
+<pre>
+  Star.   Magnitude.  Right Ascension.   Declination.
+                      h. m.   s.
+  alpha     9.0       5  42  6.06        23&deg; 35'  6.7" N.
+  eta       8.7       5  43 17.82        23  26'  7.2  N.
+  theta     8.8       5  44  0.99        23  53' 30.8  N.
+  epsilon   8.8       5  45 40.68        23  34' 46.8  N.
+</pre>
+
+<p>The stars are therefore merely telescopic, and are confined to a
+small area of space, so that the propriety of adopting the group as
+a distinct constellation is very questionable. Their positions
+close to Uranus at the time of its discovery, and the fact that the
+planet's motion was detected by means of comparisons with them, has
+given to these stars an historical interest which in future years
+must often attract the student to their reobservation. But it would
+be unwise, as forming a bad precedent, to accept a group of stars
+of this inferior type as meriting to rank among the old
+constellations, when we have numbers of richer groups, situated on
+their confines, which first deserve such a distinction. However
+special or unique the circumstances connected with certain
+telescopic stars may be, and however necessary it may appear to
+signalize them by a specific title, we are inclined to question the
+adoption of such means as likely to exercise a wrong influence,
+inasmuch as it may hereafter originate further innovations of a
+similar character, and ultimate complications will be certain to
+arise.</p>
+
+<p>Soon after the discovery of Uranus it was suspected that the
+planet was encircled, like Saturn, by a luminous ring, but on
+subsequent observation this was not confirmed, and no such
+appendage has ever been revealed in the more perfected instruments
+of our own times. Indeed, if Uranus displays a peculiarity of
+constitution in any way analogous to the ring system of Saturn, it
+must be of the most minute character so as to have thus evaded
+telescopic scrutiny during a hundred years.</p>
+
+<p>The discovery soon attracted the notice of royalty, and the
+reigning sovereign, George III., anxious to practically express his
+appreciation of the valuable labors of Herschel, awarded him a
+pension of &pound;200 a year and furnished him with a residence at
+Slough, near Windsor, and the means to erect a gigantic telescope
+with which he might be enabled to continue his important
+researches. This instrument consisted of a reflector on the
+"Front-view" construction, with a speculum 4 feet in diameter and
+of 40 feet focal length. Upon its completion, Herschel immediately
+began to observe the region of the new planet with the idea of
+discovering any satellites which might belong to it, for analogy
+suggested that it was surrounded by a numerous retinue of such
+bodies. He was soon successful, for, on the night of January 11,
+1787. he saw two minute objects near the planet, which renewed
+observations revealed to be satellites; and he detected two
+additional ones in 1790, and two others in 1794, making six in all.
+But the observations were of extreme difficulty. The path of the
+planet frequently passed near minute stars, and it became hard to
+distinguish between them and the suspected satellites. Herschel,
+however, considered he had obtained conclusive evidence of the
+existence of six satellites with sidereal periods ranging from 5d.
+21h. 25m. to 107d. 16h. 39m., and his means of observation being
+much superior to those possessed by any of his contemporaries it
+was impossible to have corroborative testimony.</p>
+
+<p>The matter was thus allowed to rest until the middle of the
+present century, when Lassell, in the pure sky at Malta, endeavored
+to reobserve the satellites with a two-foot reflector. This
+instrument was considered superior to Herschel's telescope; and the
+atmosphere at this station being decidedly more suitable for such
+delicate observations than in England, it was removed there for the
+express purpose of dealing successfully with objects of extreme
+difficulty. The results were very important. Mr. Lassell became
+convinced that Uranus had only four satellites, and that if any
+others existed they remained to be discovered. Two of these were
+found to be identical with those seen by Herschel in 1787, and now
+called Titania and Oberon. The other two, Ariel and Umbriel, could
+not be identified with any of those alleged to have been previously
+detected by Herschel, so that the inference was that they were new
+bodies, and that the priority of discovery was due to Mr. Lassell;
+whence it also followed that the older observations were erroneous,
+and that in fact Herschel had been entirely mistaken with regard to
+the four satellites he believed he had detected subsequently to
+1787.</p>
+
+<p>In November, 1873, a fine twenty-six-inch object glass, by Alvan
+Clark, was mounted at the U. S. Naval Observatory at Washington,
+and it was soon employed upon the difficult task of solving the
+problem as to the exact periods of the Uranian satellites. This was
+very satisfactorily effected, and with distinct and conclusive
+favor to Mr. Lassell, whose observations were fully corroborated.
+Only four satellites could be distinguished by the American
+observers, and their periods, as computed from a valuable series of
+measures, agreed with those previously derived at Malta. In
+Appendix I. to the "Washington Observations" for 1873, Prof.
+Newcomb gave a valuable summary of results--the first obtained, be
+it noted, with that splendid instrument which soon afterward, in
+1877, revealed the satellites of Mars--which included the elements
+of the satellites of Uranus as follows:</p>
+
+<pre>
+  Mean Longitude.
+<br>
+      Satellite.      Epoch 1871.     Radius of        Period of
+                    Dec. 31, W.M.T.     Orbit.      Revolution in days.
+    I. Ariel........       21.83&deg;       13.78"          2.52038
+   II. Umbriel.....        13.52        19.20           4.14418
+  III. Titania.....       229.93        31.48           7.70590
+   IV. Oberon......       154.83        42.10          13.43327
+</pre>
+
+<p>Speaking of the comparative brightness of the satellites, Prof.
+Newcomb says:</p>
+
+<p>"The greater proximity of the inner satellites to the planet
+makes it difficult to compare them photometrically with the outer
+ones, as actual feebleness of light cannot be distinguished from
+difficulty of seeing arising from the proximity of the planet.
+However, that Umbriel is intrinsically fainter than Titania is
+evinced by the fact that, although the least distance of the latter
+is somewhat less than the greatest distance of the former, there is
+never any difficulty in seeing it in that position. From their
+relative aspects in these respective positions I judge Umbriel to
+be about half as bright as Titania. Ariel must be brighter than
+Umbriel, because I have never seen the latter unless it was farther
+from the planet than the former at its maximum distance.... I think
+I may say with considerable certainty that there is no satellite
+within 2' of the planet, and outside of Oberon, having one-third
+the brilliancy of the latter, and therefore that none of Sir
+William Herschel's supposed outer satellites can have any real
+existence. The distances of the four known satellites increase in
+so regular a way that it can hardly be supposed that any others
+exist between them. Of what may be inside of Ariel it is impossible
+to speak with certainty, since in the state of atmosphere which
+prevails during our winter all the satellites named disappear at
+10" from the planet."</p>
+
+<p>Prof. Newcomb mentions that no systematic search for new
+satellites was undertaken because it must have interfered with the
+fullness and accuracy of the micrometer measures of the old
+satellites, which constituted the main purpose of the observations.
+Some faint objects were occasionally glimpsed near the planet, and
+their relative places determined, but they were never found to
+accompany Uranus. The fact, therefore, that no additional
+satellites were discovered is not to be regarded as a strong point
+in favor of the theory of their non-existence, because the great
+power and excellence of the telescope was expressly directed to the
+attainment of other ends; and moreover the season in which the
+planet came to opposition was distinctly unfavorable for the
+prosecution of a rigorous search for new satellites. There can,
+however, be no doubt that the analogies of the planetary systems
+interior to Uranus plainly suggest that this planet is attended by
+several satellites which the power of our greatest telescopes has
+hitherto failed to reveal; and that it is in this direction and
+that of Neptune we may anticipate further discoveries in future
+years when the conditions are more auspicious and the work is
+entered upon with special energy, aided by instruments of even
+greater capacity than those which have already so far conduced to
+our knowledge of the heavenly bodies.</p>
+
+<p>Notwithstanding the extreme difficulty with which the Uranian
+satellites are observed, the two brighter ones, Titania and Oberon,
+discovered by William Herschel in 1787, have been occasionally
+detected in telescopes of moderate power, and identified by means
+of an ephemeris which has shown that the computed positions
+approximately agree with those observed. During the last few years
+Mr. Marth has published ephemerides of the satellites of both
+Saturn and Uranus, and many amateurs have to acknowledge the
+valuable aid rendered by these tables, which supply a ready means
+of identifying the satellites, and thus act as an incentive to
+observers who are induced to pursue such work for the sake of the
+interesting comparisons to be made afterward. In one exceptional
+instance the two outer satellites of Uranus appear to have been
+glimpsed with an object glass of only 43 inches aperture, and the
+facts are given in detail in the "Monthly Notices of the R.A.S.,"
+April 1876, pp. 294-6. The observations were made in January,
+February, and March, 1876, by Mr. J.W. Ward, of Belfast; and the
+positions of the satellites, as he estimated them on several
+nights, are compared with those computed, the two sets presenting
+tolerably good agreement. Indeed the corroborations are such as to
+almost wholly negative any skepticism, though such extraordinary
+feats should always be received with caution.</p>
+
+<p>In this particular case the chances of being misled are
+manifold; even Herschel himself fell into error in taking minute
+stars to be satellites and actually calculating their periods; so
+that when we remember the difficulties of the question our doubts
+are not altogether dispelled. Extreme acuteness of vision will, in
+individual instances, lead to success of abnormal character, and
+certainly in Mr. Ward's case the remarkable accordances in the
+observed and calculated positions appear to be conclusive evidence
+that he was not mistaken.</p>
+
+<p>It will be readily inferred that the great distance and
+consequent feebleness of Uranus must render any markings upon the
+disk of the planet beyond the reach of our best telescopes; and
+indeed this appears to have been a matter of common experience.
+Though the surface has been often scanned for traces of spots, we
+seldom find mention that any have been distinguished. Consequently
+the period of rotation has yet to be determined. It is true that an
+approximate value was assigned by Mr. T.H. Buffham from
+observations with a nine-inch reflector in 1870 and 1872. but the
+materials on which the computation was based were slender and
+necessarily somewhat uncertain, so that his period of about twelve
+hours stands greatly in need of confirmation. The bright spots and
+zones seen on the disk in the years mentioned appear to have
+entirely eluded other observers, though they are probably phenomena
+of permanent character and within reach of instruments of moderate
+size. Mr. Buffham [1] thus describes them:</p>
+
+<p>[Footnote 1: "Monthly Notices K. A. S.," January, 1873.]</p>
+
+<p>"1870, Jan. 25, 11h. to 12h. in clear and tolerably steady air;
+power 132 showed that the disk was not uniform. With powers 202 and
+3.0, two round, bright spots were perceived, not quite crossing the
+center but a little nearer to the eastern side of the planet, the
+position angle of a line passing through their centers being about
+20&ordm; and 200--ellipticity of Uranus seemed obvious, the major
+axis lying parallel to the line of the spots.</p>
+
+<p>"Jan. 27, 10h. to 10&frac12;h.; some fog, and definition not
+good, but the appearance of the spots was almost exactly the same
+as on the 25th."</p>
+
+<p>On March 19 glimpses were obtained of a light streak and two
+spots. On April 1, 4, 6, and 8, a luminous zone was seen on the
+disk, and in February and March, 1872, when observations were
+resumed, certain regions were noted brighter than others, and
+underwent changes indicating the rotation of the planet in a
+similar direction to that derived from the results obtained in
+1870. Mr. Buffham points out that, if this is admitted, then the
+plane of the planet's equator is not coincident with the plane of
+the orbits of the satellites. Nor need we be surprised at this
+departure from the general rule, where such an anomalous
+inclination exists. In singular confirmation of this is Mr.
+Lassell's observation of 1862, Jan. 29, where he says: "I received
+an impression which I am unable to render certain of an equatorial
+dark belt, and of an ellipticity of form."</p>
+
+<p>Some observations made in 1872-3 with the great six-foot
+reflector of Lord Rosse may here be briefly referred to. A number
+of measures, both of position and distance, of Oberon and Titania,
+were made, [1] and a few of Umbriel and Ariel, but "the shortness
+of the time available (40 minutes) each night for the observation
+of the planet with the six-foot instrument, the atmospheric
+disturbance, so often a source of annoyance in using so large an
+aperture, and other unfavorable circumstances, tended to affect the
+value of the observations, and to make the two inner satellites
+rarely within detection."</p>
+
+<p>[Footnote 1: "Monthly Notices R. A. S.," March, 1875.]</p>
+
+<p>On Feb. 10, 1872, Lord Rosse notes that all four satellites were
+seen on the same side of the planet. On Jan. 16, 1873, when
+definition was good, no traces of any markings were seen. Diameter
+of Uranus = 5.29". Power 414 was usually employed, though at times
+the inner satellites could be more satisfactorily seen with
+625.</p>
+
+<p>It may be mentioned as an interesting point that, some fifty
+years after the first discovery of Uranus by Herschel, it was
+accidentally rediscovered by his son, Sir John Herschel, who
+recognized it by its disk, and had no idea as to the identity of
+the object until an ephemeris was referred to. Sir John mentions
+the fact as follows, in a letter to Admiral Smyth, written in 1830,
+August 8:</p>
+
+<p>"I have just completed two twenty-foot reflectors, and have got
+some interesting observations of the satellites of Uranus. The
+first sweep I made with my new mirror I <i>re-discovered</i> this
+planet by its <i>disk</i>, having blundered upon it by the merest
+accident for 19 Capricorni."</p>
+
+<p>In commenting upon the centenary of an important scientific
+discovery we are naturally attracted to inquire what progress has
+been made in the same field during the comparatively short interval
+of one hundred years which has elapsed since it occurred. We have
+called it a short interval, because it cannot be considered
+otherwise from an astronomical or geological point of view, though,
+as far as human life is concerned, it can only be regarded as a
+very lengthy period, including several generations within its
+limits.</p>
+
+<p>Since Herschel, in 1781, discovered Uranus, astronomy has
+progressed with great rapidity, so that it would be impossible to
+enumerate in a brief memoir the many additional discoveries which
+have resulted from assiduous observation. A century ago only five
+planets were known (excluding the Earth), now we are acquainted
+with about two hundred and thirty of these bodies; and one of
+these, found in 1846, is a large planet whose orbit lies exterior
+to that of Uranus. In fact, the state of astronomical knowledge a
+century ago has undergone wonderful changes. It has been rendered
+far more complete and comprehensive by the diligence of its
+adherents and by the unwearying energy with which both in theory
+and practice it has been pursued. A zone of small planets has been
+discovered between Mars and Jupiter just where the analogies of the
+planetary distances indicated the probable existence of a large
+planet. The far-off Neptune was revealed in 1846 by a process of
+analytical reasoning as unique as it was triumphant, and which
+proved how well the theory of planetary perturbations was
+understood. The planet was discovered by calculation, its position
+in the heavens assigned, and the telescope was then employed merely
+as the instrument of its detection. The number of satellites which
+a century ago numbered only ten has now reached twenty, and the
+discovery in 1877 of two moons accompanying Mars shows that the
+work is being continued with marked success.</p>
+
+<p>In other departments we also find similar evidence of increasing
+knowledge. The periodicity of the sun spots, the existence of
+systems of binary stars, meteor showers, and their affinity with
+cometary orbits may be mentioned as among the more important, while
+a host of new comets, chiefly telescopic, have been detected. Large
+numbers of nebul&aelig; and double stars have been catalogued, and
+we have evidence every year of the activity with which these
+several branches are being followed up.</p>
+
+<p>In fine, it matters little to what particular department of
+astronomical investigation we look for traces of advancement during
+the past hundred years, for it is evident throughout them all, and
+sufficiently proves that the interest formerly taken in the science
+has not only been well sustained but has become more general and
+popular, and is extending its attractive features to all classes of
+the community.</p>
+
+<p>In Herschel's day large telescopes were rare. A man devoting
+himself to the study of the heavenly bodies as a means of
+intellectual recreation was considered a phenomenon, and indeed
+that appellation might be fittingly applied to the few isolated
+individuals who really occupied themselves in such work. How
+different is the case now that the pleasant ways of science have
+called so many to her side and so far perfected her means of
+research as to make them accessible to all who care to see and
+investigate for themselves the unique and wonderful truths so
+easily within reach! Large telescopes have become common enough,
+and there is no lack of hands and eyes to utilize them, nor of
+understanding, ever ready to appreciate, in sincerity and
+humbleness, those objects which display in an eminent degree the
+all-wise conceptions of a great Creator! It is, therefore, a most
+gratifying sign to notice this rapid development of astronomy, and
+to see year by year the increasing number of its advocates and the
+record of many new facts gleaned by vigorous observation.</p>
+
+<p>The character of recent discoveries distinctly intimates that,
+in future years, some departments of the science will become very
+complicated, owing to the necessity of dealing with a large number
+of minute bodies, for the tendency of modern researches has been to
+reveal objects which by their faintness had hitherto eluded
+detection. And when we consider that these bodies are rapidly
+increasing year by year, the idea is obviously suggested that,
+inasmuch as their numbers are comparatively illimitable, and there
+is likely to be no immediate abatement in the enthusiasm of
+observers, difficulties will arise in identifying them apart and
+forming them into catalogues with their orbital elements attached,
+so that the individual members may be redetected at any time.</p>
+
+<p>In this connection we allude particularly to minor planets, to
+telescopic comets, and to meteoric streams, which severally form a
+very numerous group of bodies of which the known members are
+accumulating to a great extent. As complications arise, some
+remedies must be applied to their solution, and one probable effect
+will be that astronomers will be induced each one to have a
+specialty or branch to which his energies are mainly directed. The
+science will become so wide in its application and so intricate in
+its details that it will become more than ever necessary for
+observers to select or single out definite lines of investigation
+and pursue them closely, for success is far more likely to attend
+such exertions than those which are not devoted to any special end,
+but employed rather in a general survey of phenomena.</p>
+
+<p>We have already before us some excellent instances in which
+individual energies have been aptly utilized in the prosecution of
+original work in some specific branch of astronomy, and we are
+strongly disposed to recommend such exclusive labors to those who
+have the means and the desire to achieve something useful.
+Observers who find one subject monotonous and then take up another
+for the sake of variation are not likely to get far advanced in
+either. In the case of amateurs who use a telescope merely for
+amusement, and indiscriminately apply it to nearly every
+conspicuous object in the firmament without any particular purpose
+other than to satisfy their curiosity, the matter is somewhat
+different, and our remarks are not applicable to them. We refer
+more pointedly to those who have a regard for the interests of the
+science and whose enthusiasm enables them to work habitually and
+with some pertinacity.</p>
+
+<p>History tells us that the Great Alexander wept when he found he
+had no other worlds to conquer, and we fear that some astronomers
+will lament that they have little prospect of discovering anything
+fresh in a sphere to which our giant telescopes have been so often
+directed, but this is founded on a palpable misconception. Certain
+objects, such as comets for example, do not require great power,
+and the revelation of new meteor showers is entirely a question for
+the naked eye. In fact, it may be confidently asserted that
+observations undertaken with energy and persistency will, if
+rightly directed, more than compensate for defects of instrumental
+power.</p>
+
+<p>It is true, however, that in certain quarters we must look to
+large instruments alone for new discoveries. It would be useless
+searching for an ultra-Neptunian planet, or for additional
+satellites to Uranus or Neptune, or for the materials to determine
+the rotation periods of these planets with a small telescope. Every
+observer will find objects suited to the capacity of his
+instrument, and he may not only employ it usefully but possibly
+make a discovery of nearly equal import with that which rendered
+the name of Herschel famous a century ago.--<i>Popular Science
+Review</i>.</p>
+
+<hr>
+<p><a name="22"></a></p>
+
+<h2>THE VARYING SUSCEPTIBILITY OF PLANTS AND ANIMALS TO POISONS AND
+DISEASES.</h2>
+
+<p>Much attention is being devoted to the causes which determine
+the aptitude or immunity with animals for maladies. This is in a
+general sense called medical geography, as a physician who has
+prescribed for patients in various parts of the world, and
+belonging to different races--the white, yellow, and black--has
+been able to note the diversities in the same disease, and the
+contradictions in the remedies employed.</p>
+
+<p>The true social peril, hardly discovered before we became aware
+how to conjure it, lies in those legions of animalcules or microbes
+that surround us and in the middle of which we live. M. Pasteur has
+revealed them to us as the factors in infectious diseases. Claude
+Bernard has demonstrated the community which exists between animals
+and vegetables--phenomena of movement, of sensibility, of
+production of heat, of respiration, of digestion even, for there
+are the <i>Drosera</i> and kindred carnivorous plants. Iron cures
+chlorosis in vegetables as well as in animals, and chloroform and
+ether render both insensible. There resemblances are more striking
+still between animals. After Baudrimont, insects are, in presence
+of alcohols, chloroform, and irrespirable gases, similarly affected
+as man. Many maladies, too, are common to man and several species
+of animals; and this organic identity is best illustrated in the
+relationship between epidemics and epizootias, cancer, asthma,
+phthisis, smallpox, rabies, glanders, charbon, etc., afflict alike
+man and many species of animals.</p>
+
+<p>The differences between races are not less remarkable--odor and
+taste, for example. According to anthropophagy, negroes are best,
+and white people most detestable. Broca remarked, that, in the
+dissecting room, the muscles of the negro putrefied less rapidly
+than those of whites. It is perhaps to these anatomical differences
+that the diverse action of the same poison, in the case of races or
+species, may be attributed. On certain rodentia belladonna
+exercises no influence; morphine for a horse is a violent
+stimulant; a snail remains insensible to digitalis; goats eat
+tobacco with impunity; and in the Tarentin the inhabitants rear
+only black sheep, because a plant abounds which is noxious for
+white sheep.</p>
+
+<p>The nature of these conditions is a mystery for science. The
+<i>Solan&aelig;</i> tribe of plants furnish a principle which, as
+its name implies, produces consolation or forgetfulness, by acting
+on the tissues of the brain where resides the organ of thought;
+now, on the authority of Professor Bouchardat, these opiates have
+the less of effect in proportion as the animals possess the less of
+intelligence.</p>
+
+<p>To the same anatomical peculiarities must be ascribed the choice
+that disease makes in such or such a race. Glanders, for instance,
+so virulent with the horse, the ass, and man, produce in the case
+of the dog only a local accident; peripneumonia, so contagious
+among horned cattle, is more benign in its action on Dutch than
+other breeds of stock; the cattle plague that decimates so many
+farms is communicated by cattle to each other from the slightest
+contact, while the closest and most constant association is
+necessary to communicate the disease to sheep, and even when they
+are affected its action is not severe. Further, that plague only
+attacks ruminant animals--oxen, goats, sheep, zebras, gazelles,
+etc. Ten years ago this plague broke out in the Jardin
+d'Acclimatation; not a ruminant escaped, and also one animal not of
+that class, a little tenant nearly related to the pig--the
+<i>peccari</i>.</p>
+
+<p>Now, Dr. Condereau has demonstrated recently that the stomach of
+the pig has a rudimentary organization recalling that of the
+ruminants. Clearly, the stomach of the peccari, and perhaps that of
+the pig, present a favorable medium for the parasitical microbe
+peculiar to the rinderpest. In the potato disease, again, all the
+varieties are not affected with the same degree of violence; it is
+more marked in its action on the round yellows than the reds, and
+on the latter rather than the pink. But the symptoms even of the
+same malady differ, the parasite's attacks on the tissues being
+dissimilar. Oak galls are produced from the prickings of insects;
+now around the same larva often four varieties of galls are
+recognized. In the case of consumption in cattle, the disease
+marches slowly; in that of pigs it takes the galloping form, as
+with man.</p>
+
+<p>Each people or nation has its peculiar pathology and also its
+peculiar cures. A negro can take a dose of tartar ten times more
+excessive than a white; the same dose of brandy given to a black, a
+yellow, and a white, will not produce on the three men either
+drunkenness at the same moment, or intoxication at all. Mulattoes
+can sustain more drastic aperients than other races; the negro does
+not suffer from yellow fever, but he readily falls to phthisis; he
+will catch the cholera more quickly than a white. Human races,
+where they may catch the same intermittent fever at the identical
+moment and in the same swamp, will not the less display different
+types of fever. Dr. Crevaux has shown that a certain insect with
+the North American Indian is not the same as with the negro or the
+maroon, and both differ from that peculiar to Europeans.</p>
+
+<p>M. Pasteur's beautiful experiments have conclusively
+demonstrated that fowls do not catch the <i>charbon</i>; now the
+vital warmth of birds is from seven to nine degrees higher than in
+the case of mammiferous animals; he imagined that if the fowl was
+cooled down by baths to the lower temperature, it would be liable
+equally to become affected; he tried, and the result proved he was
+correct.</p>
+
+<p>The absence, then, of a certain temperature would be the reason
+why birds are exempt. The microbes are the agents of infectious
+disease; when these swarm in the blood of an individual they seem
+to leave there something pernicious for parasites resembling
+themselves, or to bring away with them something necessary to the
+life of their successors. A glass of sugar and water, where leaven
+has already fermented and yielded alcohol, is incapable of
+producing a second crop of leaven; similarly the blood of an
+individual, once contaminated, becomes uninhabitable afterward for
+like microbes. The individual has acquired immunity. Such is the
+principle of vaccination.--<i>Paris Correspondent of the Kansas
+City Review</i>.</p>
+
+<hr>
+<p><a name="23"></a></p>
+
+<h2>KIND TREATMENT OF HORSES.</h2>
+
+<p>It has been observed by experienced horse trainers that
+naturally vicious horses are rare, and that among those that are
+properly trained and kindly treated when colts they are the
+exception.</p>
+
+<p>It is superfluous to say that a gentle and docile horse is
+always the more valuable, other qualities being equal, and it is
+almost obvious that gentle treatment tends to develop this
+admirable quality in the horse as well as in the human species,
+while harsh treatment has the contrary tendency. Horses have been
+trained so as to be entirely governed by the words of his driver,
+and they will obey and perform their simple but important duties
+with as much alacrity as the child obeys the direction of the
+parent.</p>
+
+<p>It is true that all horses are not equally intelligent and
+tractable, but it is probable that there is less difference among
+them in this regard than there is among his human masters, since
+there are many incitements and ambitions among men that do not
+affect animals.</p>
+
+<p>The horse learns to know and to have confidence in a gentle
+driver, and soon discovers how to secure for himself that which he
+desires, and to understand his surroundings and his duties. The
+tone, volume, and inflection of his master's voice indicate much,
+perhaps more than the words that are spoken. Soothing tones rather
+than words calm him if excited by fear or anger, and angry and
+excited tones tend to excite or anger him. In short, bad masters
+make bad horses.</p>
+
+<hr>
+<p>A catalogue, containing brief notices of many important
+scientific papers heretofore published in the SUPPLEMENT, may be
+had gratis at this office.</p>
+
+<hr>
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+</body>
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+
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