diff options
Diffstat (limited to '16792-h')
| -rw-r--r-- | 16792-h/16792-h.htm | 5407 | ||||
| -rw-r--r-- | 16792-h/images/1.png | bin | 0 -> 414884 bytes | |||
| -rw-r--r-- | 16792-h/images/10a.png | bin | 0 -> 33155 bytes | |||
| -rw-r--r-- | 16792-h/images/10a_th.png | bin | 0 -> 12622 bytes | |||
| -rw-r--r-- | 16792-h/images/10b.png | bin | 0 -> 10308 bytes | |||
| -rw-r--r-- | 16792-h/images/11.png | bin | 0 -> 84426 bytes | |||
| -rw-r--r-- | 16792-h/images/11_th.png | bin | 0 -> 34235 bytes | |||
| -rw-r--r-- | 16792-h/images/12a.png | bin | 0 -> 60547 bytes | |||
| -rw-r--r-- | 16792-h/images/12a_th.png | bin | 0 -> 32307 bytes | |||
| -rw-r--r-- | 16792-h/images/12b.png | bin | 0 -> 5269 bytes | |||
| -rw-r--r-- | 16792-h/images/12c.png | bin | 0 -> 2064 bytes | |||
| -rw-r--r-- | 16792-h/images/13a.png | bin | 0 -> 9296 bytes | |||
| -rw-r--r-- | 16792-h/images/13b.png | bin | 0 -> 40134 bytes | |||
| -rw-r--r-- | 16792-h/images/13b_th.png | bin | 0 -> 19252 bytes | |||
| -rw-r--r-- | 16792-h/images/13c.png | bin | 0 -> 5854 bytes | |||
| -rw-r--r-- | 16792-h/images/13d.png | bin | 0 -> 3774 bytes | |||
| -rw-r--r-- | 16792-h/images/13e.png | bin | 0 -> 14556 bytes | |||
| -rw-r--r-- | 16792-h/images/14a.png | bin | 0 -> 2665 bytes | |||
| -rw-r--r-- | 16792-h/images/14b.png | bin | 0 -> 3397 bytes | |||
| -rw-r--r-- | 16792-h/images/14c.png | bin | 0 -> 66955 bytes | |||
| -rw-r--r-- | 16792-h/images/14c_th.png | bin | 0 -> 15341 bytes | |||
| -rw-r--r-- | 16792-h/images/14d.png | bin | 0 -> 17087 bytes | |||
| -rw-r--r-- | 16792-h/images/14e.png | bin | 0 -> 18086 bytes | |||
| -rw-r--r-- | 16792-h/images/14f.png | bin | 0 -> 3676 bytes | |||
| -rw-r--r-- | 16792-h/images/14g.png | bin | 0 -> 3620 bytes | |||
| -rw-r--r-- | 16792-h/images/14h.png | bin | 0 -> 3672 bytes | |||
| -rw-r--r-- | 16792-h/images/15a.png | bin | 0 -> 8423 bytes | |||
| -rw-r--r-- | 16792-h/images/15b.png | bin | 0 -> 90139 bytes | |||
| -rw-r--r-- | 16792-h/images/15c.png | bin | 0 -> 2712 bytes | |||
| -rw-r--r-- | 16792-h/images/15d.png | bin | 0 -> 2717 bytes | |||
| -rw-r--r-- | 16792-h/images/15e.png | bin | 0 -> 7272 bytes | |||
| -rw-r--r-- | 16792-h/images/16.png | bin | 0 -> 3135 bytes | |||
| -rw-r--r-- | 16792-h/images/1_th.png | bin | 0 -> 31322 bytes | |||
| -rw-r--r-- | 16792-h/images/2.png | bin | 0 -> 86353 bytes | |||
| -rw-r--r-- | 16792-h/images/2_th.png | bin | 0 -> 27463 bytes | |||
| -rw-r--r-- | 16792-h/images/3.png | bin | 0 -> 175763 bytes | |||
| -rw-r--r-- | 16792-h/images/3_th.png | bin | 0 -> 47239 bytes | |||
| -rw-r--r-- | 16792-h/images/4.png | bin | 0 -> 114817 bytes | |||
| -rw-r--r-- | 16792-h/images/4_th.png | bin | 0 -> 12266 bytes | |||
| -rw-r--r-- | 16792-h/images/5.png | bin | 0 -> 69168 bytes | |||
| -rw-r--r-- | 16792-h/images/5_th.png | bin | 0 -> 11494 bytes | |||
| -rw-r--r-- | 16792-h/images/6.png | bin | 0 -> 89498 bytes | |||
| -rw-r--r-- | 16792-h/images/6_th.png | bin | 0 -> 70453 bytes | |||
| -rw-r--r-- | 16792-h/images/7.png | bin | 0 -> 41604 bytes | |||
| -rw-r--r-- | 16792-h/images/7_th.png | bin | 0 -> 24666 bytes | |||
| -rw-r--r-- | 16792-h/images/8.png | bin | 0 -> 33884 bytes | |||
| -rw-r--r-- | 16792-h/images/8_th.png | bin | 0 -> 10533 bytes | |||
| -rw-r--r-- | 16792-h/images/9a.png | bin | 0 -> 2106 bytes | |||
| -rw-r--r-- | 16792-h/images/9b.png | bin | 0 -> 4831 bytes | |||
| -rw-r--r-- | 16792-h/images/9c.png | bin | 0 -> 8028 bytes | |||
| -rw-r--r-- | 16792-h/images/9d.png | bin | 0 -> 3368 bytes | |||
| -rw-r--r-- | 16792-h/images/title.png | bin | 0 -> 49047 bytes | |||
| -rw-r--r-- | 16792-h/images/title_th.png | bin | 0 -> 36286 bytes |
53 files changed, 5407 insertions, 0 deletions
diff --git a/16792-h/16792-h.htm b/16792-h/16792-h.htm new file mode 100644 index 0000000..1bdb069 --- /dev/null +++ b/16792-h/16792-h.htm @@ -0,0 +1,5407 @@ +<!DOCTYPE html PUBLIC "-//W3C//DTD XHTML 1.0 Strict//EN" + "http://www.w3.org/TR/xhtml1/DTD/xhtml1-strict.dtd"> + +<html xmlns="http://www.w3.org/1999/xhtml"> +<head> +<meta http-equiv="Content-Type" content="text/html; charset=ISO-8859-1" /> + +<title> +The Project Gutenberg eBook of Scientific American Supplement, September 26, 1885 +</title> + +<style type="text/css"> +<!-- + body {margin-left: 15%; margin-right: 15%;} + img {border: 0;} + p { text-align: justify; margin-top: .75em; margin-bottom: 0em;} + h1, h2, h3 {text-align: center;} + + hr {text-align: center; width: 50%;} + hr.short {width: 25%;} + hr.long {width: 75%;} + hr.full {width: 100%;} + + .note {margin-left: 2em; margin-right: 2em; margin-bottom: 2em; margin-top: 0em;} + .ind {margin-left: 10%; margin-right: 10%;} + .longcaption {margin-left: 10%; + margin-right: 10%; + text-align: left; } + + .center {text-align: center; + margin-left: auto; + margin-right: auto; } + .center table { + margin-left: auto; + margin-right: auto; } + + .signature {font-variant: small-caps; + text-align: right;} + .smcap {font-variant: small-caps;} + + .trans {color: blue; text-decoration: none;} + + .figcenter {margin: auto; text-align: center;} + + .figleft {float: left; clear: left; margin-left: 0; margin-bottom: 1em; + margin-top: 1em; margin-right: 1em; padding: 0; text-align: center;} + + .figright {float: right; clear: right; margin-left: 1em; margin-bottom: 1em; + margin-top: 1em; margin-right: 0; padding: 0; text-align: center;} + + .over {text-decoration: overline;} +--> +</style> +</head> + +<body> + + +<pre> + +The Project Gutenberg EBook of Scientific American Supplement, No. 508, +September 26, 1885, 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. 508, September 26, 1885 + +Author: Various + +Release Date: October 3, 2005 [EBook #16792] + +Language: English + +Character set encoding: ISO-8859-1 + +*** START OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN *** + + + + +Produced by Juliet Sutherland, Josephine Paolucci and the +Online Distributed Proofreading Team at www.pgdp.net + + + + + + +</pre> + +<div class="figcenter"><a href="./images/title.png"><img src="./images/title_th.png" alt="Issue Title" /></a></div> +<h1>SCIENTIFIC AMERICAN SUPPLEMENT NO. 508</h1> +<h2>NEW YORK, SEPTEMBER 26, 1885</h2> +<h4>Scientific American Supplement. Vol. XX.*, No. 508.</h4> +<h4>Scientific American established 1845</h4> +<h4>Scientific American Supplement, $5 a year.</h4> +<h4>Scientific American and Supplement, $7 a year.</h4> +<hr /> + +<div class="center"><table summary="Contents" border="0" cellspacing="5" cellpadding="5"> +<tr> +<th colspan="2" align="center">TABLE OF CONTENTS.</th> +</tr> +<tr><td colspan="2"> </td><td>PAGE.</td> +</tr> +<tr> +<td valign="top">I.</td> +<td align="left"><a href="#art01">CHEMISTRY AND METALLURGY.—The Cowles Electric Smelting + Process. 5 figures.</a></td><td>8113</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art02"> On the Electrical Furnace and the Reduction of the Oxides of + Boron, Silicon, Aluminum, and other Metals by Carbon.—By <span class="smcap">Eugene + H. Cowles, Alfred H. Cowles</span>, and <span class="smcap">Charles F. Mabery</span>.</a></td><td>8112</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art03"> Chemical Action of Light.</a></td><td>8117</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art04"> Eutexia.—Cryohydrates.—Eutectic salt alloys and metal alloys.</a></td><td>8117</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art05"> Chinoline.</a></td><td>8118</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art06"> Method of Rapid Estimation of Urea. 1 figure.</a></td><td>8118</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art07"> Assay of Earthenware Glaze.</a></td><td>8112</td> +</tr> + +<tr> +<td valign="top">II.</td> +<td align="left"><a href="#art08">ENGINEERING AND MECHANICS.—Deep Shafts and Deep Mining.</a></td><td>8104</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art09"> Sinking of the Quievrechain Working Shaft.—Numerous figures.</a></td><td>8108</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art10"> On the Elementary Principles of the Gas Engine.—An interesting + paper read before the Gas Institute by Mr. <span class="smcap">Denny Lane</span>, of Cork, + and discussion following.</a></td><td>8109</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art11"> <span class="smcap">M. Meizel's</span> Reciprocating Exhauster.</a></td><td>8112</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art12"> Automatic Siphon for Irrigation. 1 figure.</a></td><td>8113</td> +</tr> + +<tr> +<td valign="top">III.</td> +<td align="left"><a href="#art13">ELECTRICITY, TELEGRAPHY, ETC.—Optical Telegraphy.— + Cryptography.—Preservation of Telegrams.—The projector in + optical telegraphy.—Use of balloons. 4 figures.</a></td><td>8114</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art14"> A New Style of Submarine Telegraph. 4 figures.</a></td><td>8115</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art15"> A New Circuit Cutter. 2 figures.</a></td><td>8115</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art16"> New Micro Telephonic Apparatus. 5 figures.</a></td><td>8116</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art17"> Messrs. Kapp and Crompton's Measuring Instruments. 5 figures.</a></td><td>8116</td> +</tr> + +<tr> +<td valign="top">IV.</td> +<td align="left"><a href="#art18">GEOLOGY, ETC.—Permeability of Sand Rock.—By <span class="smcap">F.H. Newell.</span></a></td><td>8103</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art19"> The Grotto of Gargas, in the Pyrenees.—Paleontological remains + found therein. 2 engravings.</a></td><td>8103</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art20"> Remarkable Wells and Caverns in Yucatan.—By <span class="smcap">Alice D. Le + Plongeon.</span></a></td><td>8105</td> +</tr> + +<tr> +<td valign="top">V.</td> +<td align="left"><a href="#art21">NATURAL HISTORY.—The Cabbage Butterfly and the Peacock + Butterfly.</a></td><td>8105</td> +</tr> + +<tr> +<td valign="top">VI.</td> +<td align="left"><a href="#art22">BOTANY AND HORTICULTURE.—The Bhotan Cypress (Cupressus + torulosa).—With engraving.</a></td><td>8106</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art23"> The Pitcher Plant.</a></td><td>8106</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art24"> What is a Plant?</a></td><td>8106</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art25"> Camellias.—Culture of the same.</a></td><td>8106</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art26"> Arisæma Fimbriatum.—Leaf, spathe, and floral details.—With + engraving.</a></td><td>8107</td> +</tr> + +<tr> +<td valign="top">VII.</td> +<td align="left"><a href="#art27">MISCELLANEOUS.—Striking a Light with Bamboo.</a></td><td>8107</td> +</tr> +<tr><td></td> +<td align="left"><a href="#art28"> Experiments in Memory.</a></td><td>8107</td> +</tr> +</table> +</div> + +<hr /> + + + + +<h2><a name="art18" id="art18"></a><a name="Page_8103" id="Page_8103"></a>PERMEABILITY OF SAND ROCK.</h2> + +<h3>By FREDERICK H. NEWELL, M.E.</h3> + +<p>Among oil producers, there has been much discussion +as to whether the sand rock in which petroleum +occurs is of necessity fissured or is still in its original +unbroken condition.</p> + +<p>The earliest and most natural theory, which for +years was indisputed, and is still given by some textbooks, +was, that oil wells reached a cavity filled with petroleum.</p> + +<p>Within the past few years, +however, the opinion has been +gaining ground that the oil +is stored in the sandrock itself +in the minute spaces between +the small grains of +sand, not entirely filled by +cementing material, and that +crevices holding and conducting +oil are rare, all fissures +as a rule being confined +to the upper fresh-water +bearing rocks of the well. +Mr. Carll, in III. Pennsylvania +Second Geological Survey, +has discussed this subject +very fully, and has made estimates +of the quantity of oil +that the sand rock can hold +and deliver into a well; also, +T. Sterry Hunt, in his +<i>Chemical and Geological Essays</i>, +has made deductions as to the +petroleum contained in the +Niagara limestone that outcrops +about Chicago.</p> + +<p>While the experiments and +conclusions of these geologists +go to prove that these +rocks are capable of holding +the oil, there are on record +no facts as to the phenomena +of its flow, other than by +capillarity, through the rock. +To obtain some data of the +flow of liquids under pressure +through certain oil-bearing +stones, series of tests on small +pieces were made. These +tests were carried on during +this spring, and many results +quite unlooked for were obtained. +When crude oil, kerosene, or water (river or +distilled) was forced through +the specimens, the pressure +being constant, the rate of +flow was variable. At first, +the amount flowing through +was large, then fell off rapidly, +and when the flow had diminished +to about one-quarter +of its original rate, the decrease +was very slight, but +still continued as long as +measurements were made, in +some cases for three weeks.</p> + +<p>When using crude oil, this +result was not surprising, for, +as the oil men say, crude oil +"paraffines up" a rock, that +is, clogs the minute pores by +depositing solid paraffine (?); +but this so-called paraffining +took place, not only with +crude oil, but with refined +oil, and even with distilled +water.</p> + +<p>The only explanation as +yet is, that liquids flowing +under pressure through rock +on which they exert little or +no dissolving effect, instead +of washing out fine particles, +tend to dislodge any minute +grains of the stone that may +not be firmly held by cement, +and these block up extremely +fine and crooked pores in +which the fluid is passing.</p> + +<p>Several tests indicated that +this blocking up was largely +near the surface into which +the fluid was passing. When +this surface was ground off, even 1/50 of an inch, the +flow increased immediately nearly to the original rate.</p> + +<p>Reversing the flow also had the effect of increasing +the rate, even above that of any time previous.</p> + +<p>With the moderate pressures used—from 2" to 80" of +mercury—the results show that the rate of flow, other +things being equal, is directly proportional to the pressure.</p> + +<p>The porosity of rock is not always a criterion of its +permeability; a very fine grained marble, containing +about 0.6 per cent. cell space, transmitted water and +oil more freely than a shale that would hold 4 per +cent. of its bulk of water.</p> + +<p>If the above conclusions hold on a large scale as on +the small, they may aid in explaining the diminished +flow of oil wells. Not only will the flow lessen from +reduced gas pressure, but the passages in the rock become +less able to allow the oil to flow through.</p> + +<p>The increase in flow following the explosion of large +shots in a sand rock may be due not only to fissuring +of the rock, but to temporary reversal of the pressure, +the force of the explosive tending to drive the oil back +for an instant.</p> + +<p>The large shots now used (up to 200 quarts, or say +660 pounds of nitroglycerine) must exert some influence +of this kind, especially when held down by 500± feet +of liquid tamping. In the course of these tests, it was +noticed that fresh water has a more energetic +disintegrating action on the shales and clay than on salt +water.</p> + +<p>This may furnish a reason for the fact, noticed by the +oil men, that fresh water has a much more injurious +effect than salt in clogging a well. No oil-bearing sand +rock is free from laminæ of shale, and when fresh water +gets down into the sand, the water must, as the experiments +show, rapidly break up the shale, setting +free fine particles, which soon are driven along into +the minute interstices of the sand rock, plastering it +up and injuring the well.—<i>Engineering and Mining +Journal.</i></p> + +<hr /> + +<h2><a name="art19" id="art19"></a>THE GROTTO OF GARGAS.</h2> + +<p>The grotto of Gargas is located in Mount Tibiran +about three hundred yards above the level of the valley, +and about two miles southeast of the village of Aventignan. +Access to it is easy, since a road made by Mr. +Borderes in 1884 allows carriages to reach its entrance.</p> + +<p>This grotto is one of the most beautiful in the +Pyrenees, and presents to the visitor a succession of +vast halls with roofs that are curved like a dome, or +are in the form of an ogive, or +are as flat as a ceiling. It is +easy to explore these halls, for +the floor is covered with a +thick stalagmitic stratum, +and is not irregular as in the +majority of large caves.</p> + +<div class="figcenter"> +<a href="./images/1.png"><img src="./images/1_th.png" alt="Fig. 1.—SECTION OF THE GROTTO OF GARGAS." /></a> +<br /><span class="smcap">Fig.</span> 1.—SECTION OF THE GROTTO OF GARGAS.</div> + +<p>Upon entering through the +iron gate at the mouth of +the grotto, one finds himself +in Bear Hall, wherein a +strange calcareous concretion +offers the form of the carnivorous +animal after which the +room is named. This chamber +is about 80 feet in width +by 98 in length. We first +descend a slope formed of +earth and debris mostly derived +from the outside. This +slope, in which are cut several +steps, rests upon a hard, compact, +and crystalline stalagmitic +floor. Upon turning to +the right, we come to the Hall +of Columns, the most beautiful +of all. Here the floor +bristles with stalagmites, +which in several places are +connected with the stalactites +that depend from the ceiling. +This room is about 50 feet +square. After this we reach +the Hall of Crevices, 80 feet +square, and this leads to the +great Hall of Gargas, which is +about 328 feet in length by 80, +98, and 105 in width. In certain +places enormous fissures +in the vault rise to a great +height. Some of these, shaped +like great inverted funnels, +are more than 60 yards in +length. The grotto terminates +in the Creeping Hall. As +its name indicates, this part +of the cave can only be +traversed by lying flat upon +the belly. It gives access to +the upper grotto through a +narrow and difficult passage +that it would be possible to +widen, and which would then +allow visitors to make their +exit by traversing the beautiful +upper grotto, whose +natural entrance is situated +150 yards above the present +one. This latter was blasted +out about thirty years ago.</p> + +<p>Upon following the direction +of the great crevices, we +reach a small chamber, wherein +are found the Oubliettes of +Gargas—a vertical well 65 feet +feet in depth. The aperture +that gives access to this +strange well (rendered important +through the paleontological +remains collected in +it) is no more than two feet +in diameter. Such is the +general configuration of the +grotto.</p> + +<p>In 1865 Dr. Garrigou and +Mr. De Chastaignier visited +the grotto, and were the +first to make excavations +therein. These latter allowed +these scientists to ascertain +that the great chamber contained +the remains of a +quaternary fauna, and, near +the declivity, a deposit of the +reindeer age.</p> + +<p>As soon as it was possible to +obtain a permit from the +Municipal Council of Aventignan to do so, I began the +work of excavation, and the persistence with which I +continued my explorations led me to discover one of +the most important deposits that we possess in the +chain of the Pyrenees. My first excavations in Bear +Hall were made in 1873, and were particularly fruitful +in an opening 29 feet long by 10 wide that terminates +the hall, to the left. I have remarked that these sorts +of retreats in grottoes are generally rich in bones. +Currents of water rushing through the entrance to the +grotto carry along the bones—entire, broken, or gnawed—that +lie upon the ground. These remains are transported +to the depths of the cave, and are often stopped +along the walls, and lie buried in the chambers in +argillaceous mud. Rounded flint stones are constantly +<a name="Page_8104" id="Page_8104"></a>associated with the bones, and the latter are always +in great disorder. The species that I met with were as +follows: the great cave bear, the little bear, the hyena, +the great cat, the rhinoceros, the ox, the horse, and the +stag.</p> + +<p>The stalagmitic floor is 1½, 2, and 2¼ inches thick. +The bones were either scattered or accumulated at +certain points. They were generally broken, and often +worn and rounded. They appeared to have been rolled +with violence by the waters. The clay that contained +them was from 3 to 6 feet in thickness, and rested upon +a stratum of water-worn pebbles whose dimensions +varied from the size of the fist to a grain of sand. A +thick layer of very hard, crystalline stalagmite covers +the Hall of Columns, and it was very difficult to excavate +without destroying this part of the grotto.</p> + +<p>I found that there anciently existed several apertures +that are now sealed up, either by calcareous concretions +or by earthy rubbish from the mountain. One of these +was situated in the vicinity of the present mouth, and +permitted of the access to Bear Hall of a host of carnivora +that found therein a vast and convenient place +of shelter.</p> + +<div class="figcenter"><a href="./images/2.png"> +<img src="./images/2_th.png" alt="Fig.2.—SKELETON OF THE CAVE HYENA." /></a> +<br /> <span class="smcap">Fig.</span> 2.—SKELETON OF THE CAVE HYENA.</div> + +<p>These excavations revealed to me at this entrance, at +the bottom of the declivity, a thick stratum of remains +brought thither by primitive man. This deposit, +which was formed of black earth mixed with charcoal +and numerous remains of bones, calcined and broken +longitudinally for the most part, contained rudely +worked flint stones. I collected a few implements, one +surface of which offered a clean fracture, while the +other represented the cutting edge. According to Mr. +De Mortillet, such instruments were not intended to +have a handle. They were capable of serving as paring +knives and saws, but they were especially designed +for scraping bones and skins. The deposit was from +26 to 32 feet square and from 2 inches to 5 feet deep, +and rested upon a bed of broken stones above the +stalagmite. The animals found in it were the modern +bear (rare), the aurochs, the ox, the horse, and the +stag—the last four in abundance.</p> + +<p>At the extremity of the grotto there is a well with +vertical sides which is no less than 65 feet in depth. It +is called the Gargas Oubilettes. Its mouth is from 15 +to 24 inches in diameter, and scarcely gives passage to +a man (Fig. 1). Mr. Borderes, in the hope of discovering +a new grotto, was the first to descend into this +well, which he did by means of a rope ladder, and collected +a few bones that were a revelation to me. +Despite the great difficulty and danger of excavating +at this point, I proceeded, and found at the first blow +of the pick that there was here a deposit of the highest +importance, since all the bones that I met with were +intact. The first thing collected was an entire skull of +the great cave bear, with its maxillaries in place. From +this moment I began a series of excavations that lasted +two years.</p> + +<p>The descent is effected through a narrow vertical +passage 6½ feet in length. The cavity afterward imperceptibly +widens, and, at a depth of 12 yards, reaches +6½ feet in diameter, and at 15 yards 10 feet. Finally, +in the widest part (at a depth of 62 feet) it measures +about 16 feet (Fig. 1).</p> + +<p>A glance at the section of the well, which I have +drawn as accurately as possible (not an easy thing to +do when one is standing upon a rope ladder), will give +an idea of the form of this strange pocket formed in +the limestone of the mountain through the most complex +dislocations and erosions. Two lateral pockets +attracted my attention because of the enormous +quantity of clay and bones that obstructed them. The +first, to the left, was about 15 feet from the orifice. +When we had entirely emptied it, we found that it communicated +with the bottom of the well by a narrow +passage. An entire skeleton of the great cave bear +had stopped up this narrow passage, and of this, by +the aid of a small ladder, we gathered the greater part +of the skeleton, the state of preservation of which was +remarkable.</p> + +<p>The second pocket, which was almost completely +filled with clay, and situated a little lower than the +other, likewise communicated with a third cavity that +reached the bottom of the well. The clay of these +different pockets contained so large a quantity of +bones that we could hardly use our picks, and the excavation +had to be performed with very short hooks, +and often by hand. In this way I was enabled to remove +the bones without accident. The lower pocket +was dug out first, and with extreme care, the bones being +hoisted out by means of a basket attached to a +rope. Three or four candles sufficed to give us light. +The air was heavy and very warm, and, after staying +in it for two hours, it was necessary to come to the surface +to breathe. After extracting the bones from the +lower pocket, and when no more clay remained, we +successively dug out the upper ones and threw the +earth to the bottom of the well.</p> + +<p>On the 20th of December, 1884, my excavating was +finished. To-day the Oubliettes of Gargas are obstructed +with the clay that it was impossible to carry +elsewhere. The animals that I thus collected in the +well were the following: The great bear (in abundance), +the little bear (a variety of the preceding), the +hyena, and the wolf. The pockets contained nearly entire +skeletons of these species. How had the animals +been able to penetrate this well? It is difficult to admit +that it was through the aperture that I have +mentioned. I endeavored to ascertain whether there +was not another communication with the Gargas +grotto, and had the satisfaction of finding a fissure that +ended in the cave, and that probably was wider at +the epoch at which the place served as a lair for the +bear and hyena.</p> + +<p>Very old individuals and other adults, and very +young animals, were living in the grotto, and, being +surprised, without power to save themselves, by a sudden +inundation, reached the bottom of the well that +we have described. The entire remains of these animals +were carried along by the water and deposited in +the pockets in the rock. Once buried in the argillaceous +mud, the bones no longer underwent the action of the +running water, and their preservation was thence +secured.—<i>F. Regnault, in La Nature.</i></p> + +<hr /> + +<h2><a name="art08" id="art08"></a>DEEP SHAFTS AND DEEP MINING.</h2> + +<p>A correspondent of the New York <i>Sun</i>, writing +from Virginia City, Nevada, describes the progress of +the work there on the Combination shaft of the Comstock +lode, the deepest vertical shaft in America, and +the second deepest in the world. It is being sunk by +the Chollar Potosi, Hale & Norcross, and Savage mining +companies; hence its name of the Combination +shaft. This shaft has now reached a perpendicular +depth of a little over 3,100 feet. There is only one +deeper vertical shaft in the world—the Adalbent shaft +of the silver-lead mines of Przibram, Bohemia, which at +last accounts had reached a depth of 3,280 feet. The +attainment of that depth was made the occasion of a +festival, which continued three days, and was still +further honored by the striking off of commemorative +medals of the value of a florin each. There is no record +of the beginning of work on this mine at Przibram, +although its written history goes back to 1527.</p> + +<p>Twenty years ago very few mining shafts in the +world had reached a depth of 2,000 feet. The very +deepest at that time was in a metalliferous mine in +Hanover, which had been carried down 2,900 feet; but +this was probably not a single perpendicular shaft. +Two vertical shafts near Gilly, in Belgium, are sunk to +the depth of 2,847 feet. At this point they are connected +by a drift, from which an exploring shaft or winze is +sunk to a further depth of 666 feet, and from that +again was put down a bore hole 49 feet in depth, making +the total depth reached 3,562 feet. As the bore +hole did not reach the seam of coal sought for, they returned +and resumed operations at the 2,847 level. In +Europe it is thought worthy of particular note that +there are vertical shafts of the following depths:</p> + + +<div class="center"> +<table border="0" cellpadding="4" cellspacing="0" summary=""> +<tr><td align="left"></td><td align="right">Feet.</td></tr> +<tr><td align="left">Eimkert's shaft of the Luganer Coal Mining Company, Saxony</td><td align="right">2,653</td></tr> +<tr><td align="left">Sampson shaft of the Oberhartz silver mine, near St. Andreasberg, Hanover.</td><td align="right">2,437</td></tr> +<tr><td align="left">The hoisting shaft of the Rosebridge Colliery, near Wigan, Lancashire, England.</td><td align="right">2,458</td></tr> +<tr><td align="left">Shaft of the coal mines of St. Luke, near St. Chaumont, France.</td><td align="right">2,253</td></tr> +<tr><td align="left">Amelia shaft, Shemnitz, Hungary.</td><td align="right">1,782</td></tr> +<tr><td align="left">The No. 1 Camphausen shaft, near Fishbach, in the department of the Saarbruck Collieries, Prussia.</td><td align="right">1,650</td></tr> +</table></div> + +<p>Now, taking the mines of the Comstock for a distance +of over a mile—from the Utah on the north to +the Alto on the south—there is hardly a mine that is +not down over 2,500 feet, and most of the shafts are +deeper than those mentioned above; while the Union +Consolidated shaft has a vertical depth of 2,900 feet, +and the Yellow Jacket a depth of 3,030 feet. In his +closing argument before the Congressional Committee +on Mines and Mining in 1872, Adolph Sutro of the +Sutro tunnel said: "The deepest hole dug by man since +the world has existed is only 2,700 feet deep, and it remains +for the youngest nation on earth to contribute +more to science and geology by giving opportunities of +studying the formation of mineral veins at a greater +depth than has ever been accomplished by any other +nation in the world." Mr. Sutro was of the opinion +that the completion of his tunnel would enable our +leading mining companies to reach a vertical depth of +5,000 feet.</p> + +<p>This great depth has never yet been attained except +in a bore hole or artesian well. The deepest points +to which the crust of the earth has ever been penetrated +have been by means of such borings in quest of +salt, coal, or water. A bore hole for salt at Probst +Jesar, near Lubtheen, for the Government of Mecklenberg-Schwerin, +is down 3,315 feet, the size of which +bore is twelve inches at the top and three inches at the +bottom. A bore hole was put down for the Prussian +Government to the depth of 4,183 feet. But in these +bore holes the United States leads the world, as there +is one near St. Louis, Mo., that is 5,500 feet in depth. +Here on the Comstock, in the Union Consolidated +mine, a depth of 3,300 feet has been attained, but not +by means of a single vertical shaft. The vertical depth +of the shaft is 2,900 feet; the remainder of the depth +has been attained by means of winzes sunk from drifts. +Several long drifts were run at this great depth without +difficulty as regards ventilation or heat.</p> + +<p>The combination shaft is situated much further east +(in which direction the lode dips) than any other on the +Comstock. It is 3,000 feet east of the point where the +great vein crops out on the side of Mount Davidson; +2,200 feet east of the old Chollar-Potosi shaft, 1,800 ft. +east of the old Hale & Norcross (or Fair) shaft, and +2,000 ft. east of the Savage shaft. Thus, it will be seen +it is far out to the front in the country toward which +the vein is going. The shaft is sunk in a very hard +rock (andesite), every foot of which requires to be +blasted. The opening is about thirty feet in length by +ten feet in width. In timbering up this is divided into +four different compartments, some for the hoisting and +some for the pumping machinery, thus presenting the +appearance at the top of four small shafts set in a row. +Over the shaft stand several large buildings, all filled +with ponderous machinery.</p> + +<p>The Sutro drain tunnel (nearly four miles in length) +connects with the shaft at a depth of 1,600 ft., up to +which point all the water encountered below is pumped. +The shaft was sunk to the depth of 2,200 ft. before +more water was encountered than could be hoisted +out in the "skips" with the dirt. At the 2,200 level +two Cornish pumps, each with columns fifteen inches +in diameter, were put in. At the 2,400 level the same +pumps were used. On this level a drift was run that connected +with the old Hale & Norcross and Savage shafts, +producing a good circulation of air both in the shaft +and in the mines mentioned. At this point, on account +of the inflow from the mines consequent upon connecting +with them by means of the drift, they had more +water than the Cornish pumps could handle, and introduced +the hydraulic pumps, which pumps are run +by the pressure of water from the surface through a +pipe running down from the top of the shaft, whereas +the Cornish pumps are run by huge steam engines.</p> + +<p>By means of the hydraulic pumps they were enabled +to sink the shaft to the 2,600 level, and extended the +Cornish pumps to that point, where another set of +hydraulic pumps was put in. They then sunk the +shaft to the 2,800 level, when they ran another drift +westward, and tapped the vein. The prospects at this +depth in the Hale & Norcross and Chollar mines were +so encouraging that the management decided to sink +the shaft to the depth of 3,000 ft. On reaching the +3,000 level, they ran a third drift through to the vein. +The distance from the shaft to the east wall of the vein +was found to be only 250 ft. At the depth of 3,000 ft. +they put in one of the pair of hydraulic pumps that is +to be set up there. The second pump is now arriving +from San Francisco, and as soon as the several parts +are on the ground, it will be at once put in place +alongside its fellow on the 3,000 level. This additional +pump will increase the capacity from 600,000 to 700,000 +gallons in twenty-four hours, or about forty-five miners' +inches.</p> + +<p>Owing to the excellent showing of ore obtained on +the 3,000 level by the Hale & Norcross Company, and to +the continuation of the ore below that level (as shown +by a winze sunk in the vein), the management determined +to sink the shaft to the vertical depth of 3,200 ft. +It is now 3,120 ft. deep, and it is safe to say that it will +reach the depth of 3,200 ft. early in September, when +it will lack but eighty feet of being as deep as the shaft +at Przibram was at the time of the great festival. +Although the shaft is of great size—about thirty feet +by ten feet before the timbers are put in—the workmen +lower it at the rate of about three feet a day, in +rock as hard as flint.</p> + +<p>The hydraulic pump now working at the 3,000 foot +level of the shaft is the deepest in the world. In +Europe the deepest is in a mine in the Hartz Mountains, +Germany, which is working at the depth of 2,700 +feet. It is, however, a small pump not half the size +of the one in the Combination shaft. Although +these pumps were first used in Europe, those in operation +here are far superior in size, and in every other +respect, to those of the Old World, several valuable +improvements having been made in them by the +machinists of the Pacific coast.</p> + +<p>The capacity of the two Cornish pumps, which lift +the water from the 2,900 foot level to the Sutro drain +tunnel (at the 1,600 level), is about 1,000,000 gallons in +twenty-four hours, and the capacity of the present +hydraulic pumps is 3,500,000 gallons in the same time. +They are now daily pumping, with both hydraulic and +Cornish pumps, about 4,000,000 gallons, but could pump +at least 500,000 gallons more in twenty-four hours than +they are now doing. The daily capacity with the +hydraulic pump now coming, and which will be set up +as mate to that now in operation at the 3,000 foot level, +will be 5,200,000 gallons.</p> + +<p>The water which feeds the pressure pipe of the three +sets of hydraulic pumps is brought from near Lake +Tahoe, in the Sierra Nevada Mountains. The distance +is about thirty miles, and the greater part of the way +the water flows through iron pipes, which at one point +cross a depression 1,720 feet in depth. The pressure +pipe takes this water from a tank situated on the eastern +slope of Mount Davidson, 3,500 feet west of the +shaft. At the tank this pipe is twelve inches in diameter, +but is only eight inches where it enters the top of +the shaft. The tank whence the water is taken is 426 +feet higher than the top of the shaft, therefore the +vertical pressure upon the hydraulic pump at the +3,000 foot level is 3,426 feet. The pressure pipe is of +ordinary galvanized iron where it receives the water at +<a name="Page_8105" id="Page_8105"></a>the tank, but gradually grows thicker and stronger, +and at the 3,000 level it is constructed of cast iron, and +is 2½ inches in thickness. The pressure at this point +is 1,500 pounds to the square inch.</p> + +<p>In the early days of hydraulic mining in California +the miners thought that with a vertical pressure of 300 +feet they could almost tear the world to pieces, and +not a man among them could have been made to +believe that any pipe could be constructed that would +withstand a vertical pressure of 1,000 feet; but we now +see that a thickness of two and a half inches of cast +iron will sustain a vertical pressure of over 3,400 feet.</p> + +<p>There is only one pressure pipe for all the hydraulic +pumps. This extends from the tank on the side of the +mountain to the 3,000 foot level. It is tapped at the +points where are situated the several sets of hydraulic +pumps. The water from the pressure pipe enters one +part of the pump, where it moves a piston-back and +forth, just as the piston of a steam engine is moved by +steam. This water engine moves a pump which not +only raises to the surface the water which has been +used as driving power, but also a vast quantity of +water from the shaft, all of which is forced up to the +Sutro drain tunnel through what is called a return +pipe. Each set of hydraulic pumps has its return pipe; +therefore there are three return pipes—one from the +2,400, one from the 2,600, and another from the 3,000 +level.</p> + +<p>Some idea may be formed of the great size of these +hydraulic engines when it is known that the stations +excavated for them at the several levels where they are +placed are 85 feet long, 28 feet wide, and 12 feet high. +All this space is so filled with machinery that only sufficient +room is left to allow of the workmen moving +about it. One of these stations would, on the surface, +form a hall large enough for a ball room, and to those +who are unacquainted with the skill of our miners it +must seem wonderful that such great openings can be +made and securely supported far down in the bowels +of the earth; yet it is very effectually done. These +great subterranean halls are supported by timbers +14×16 inches square set along the walls three feet apart, +from center to center, and the caps or joists passing +overhead are timbers of the same size. The timber +used is mountain spruce. Not one of these huge stations +has thus far cost one dollar for repairs. The station +at the 2,400 level has been in use five years, that at +the 2,600 three years, and the one at the 3,000 level +eight months. Room for ventilation is left behind the +timbers, and all are still sound. Timbers of the same +kind are used in the shaft, and all are sound. The +shaft has cost nothing for repairs. Being in hard +andesite rock from top to bottom, the ground does not +swell and crowd upon the timbers.</p> + +<p>If it shall be thought advisable to go to a greater +depth than 3,200 feet, a station of large size will be +made on the east side of the present shaft, and in this +station will be sunk a shaft of smaller size. The reason +why the work will be continued in this way is that +in a single hoist of 3,200 feet the weight of a steel wire +cable of that length is very great—so great that the +loaded cage it brings up is a mere trifle in comparison. +In this secondary shaft the hoisting apparatus and +pumps will be run by means of compressed air. As it +is very expensive to make compressed air by steam +power, the pressure pipe will be tapped at the level of +the Sutro tunnel, and a stream of water taken out that +will be used in running a turbine wheel of sufficient +capacity to drive three air compressors. As there will +be a vertical pressure upon the turbine at this depth +of over 2,000 feet, a large stream of water will not be +required. The water used in driving the wheel will +flow out through the Sutro tunnel, and give no trouble +in the shaft.</p> + +<p>By means of this great shaft and its powerful +hydraulic and Cornish pumps the crust of the earth +will probably yet be penetrated to far greater depth +than in any other place in the world. It has been only +a little over ten years since the work of sinking it was +begun, whereas in the mines of the Old World they +have been delving since "time whereof the memory of +man runneth not to the contrary." The work on the +Combination shaft has been by no means continuous. +There have been long stoppages aside from those +required at such times as they were engaged in running +long drifts to the westward to tap the vein, and +at times for many months, when the several companies +interested in the shaft were engaged in prospecting +the various levels it had opened up.</p> + +<hr /> + +<h2><a name="art20" id="art20"></a>REMARKABLE WELLS AND CAVERNS.</h2> + +<p>Yucatan is one of the most interesting States of +Mexico, owing to the splendid ancient palaces and +temples of once grand cities, now hidden in the forests. +That country also presents great attractions for geologists +and botanists, as well as naturalists, who there +find rare and beautiful birds, insects, and reptiles.</p> + +<p>There are no rivers on the surface of the land, but in +many parts it is entirely undermined by extensive caverns, +in which are basins of water fed by subterranean +currents. The caverns are delightfully cool even at +midday, and the fantastic forms of some of the stalactites +and stalagmites are a never-ending source of interest. +There are long winding passages and roomy +chambers following one after another for great distances, +with here and there some chink in the stony +vault above, through which a sunbeam penetrates, +enabling us to see to the right and left openings leading +to untrodden places in the bowels of the earth. +As few of these caves have been explored, the wildest +accounts are given by the natives concerning the dark +recesses where only wild beasts seek shelter. Before +venturing far in, it is advisable to secure one end of a +ball of twine at the entrance, and keep the ball in +hand; nor is it safe to go without lanterns or torches, +lest we step into some yawning chasm or deep water. +The leader of one party suddenly saw a very dark spot +just before him; he jumped over, instead of stepping +on it, and told the others to halt. Examination proved +the dark patch to be a pit that seemed bottomless.</p> + +<p>Awe-inspiring as are the interiors of some of these +caves, they are frequently most beautiful. The natural +pillars are often grand in dimensions and sparkling +with various hues, while stalactites and stalagmites +sometimes resemble familiar objects with astonishing +perfection. It is, however, not advisable to place +implicit confidence in accounts of the natives, for the +reality, no matter how beautiful, can hardly be equal +to what the vivid imagination of the Indian has pictured. +Anything bearing the least resemblance to a +woman is called "a most beautiful Virgin Mary." +Fantastic flutings become "an organ," and a level rock +"an altar." Only once we were not disappointed, +when, having been told to look for a pulpit, we found +one that appeared as if man must have fashioned it, +supported on a slender pyramidal base, the upper part +very symmetrical, and ornamented with a perfect imitation +of bunches of grapes and other fruit.</p> + +<p>As I have already said, in these caves are sheets of +water, some very large, others only a few feet in circumference, +fed by subterranean currents. When the +water is clear and sweet, it is peopled by a kind of +bagre, a blind fish called by the natives <i>tzau</i>, also a +species of <i>Silurus</i>. But there are likewise medicinal +and thermal waters, by bathing in which many people +claim to have been cured of most painful and obstinate +diseases.</p> + +<p>Strange stories are told of some of these waters. Of +one it is said that those who approach it without holding +their breath fall dead. People who live near the +place swear it is so, and say the water appears to boil +on such occasions. From the thermal waters, in some +cases 100 feet below the soil, and without means of +access except by buckets let down through an opening +in the rock, warm vapors issue at early morn, but +when the sun is high the water is cool and pleasant to +drink.</p> + +<p>The name <i>senote</i> is given to all these deposits of +water, also to some immense natural circular wells +from 50 to 300 feet in diameter. The walls are more or +less perpendicular, generally covered with tropical +vegetation. The current in some is swift, but no inlets +or outlets are visible. The water is deliciously pure +and sweet, much better than that of wells opened by +man in the same country. These enormous deposits +generally have a rugged path, sometimes very steep, +leading to the water's edge, but daring natives throw +themselves from the brink, afterward ascending by +stout roots that hang like ropes down the walls, the +trees above sucking through these roots the life-sustaining +fluid more than a hundred feet below.</p> + +<p>In the west part of Yucatan is a village called <i>Bolonchen</i> +(nine wells), because in the public square there are +nine circular openings cut through a stratum of rock. +They are mouths of one immense cistern, if natural or +made by hand the natives do not know, but in times +of drought it is empty, which shows that it is not supplied +by any subterranean spring. Then the people +depend entirely on water found in a cave a mile and +a half from the village; it is perhaps the most remarkable +cavern in the whole country. The entrance is +magnificently wild and picturesque. It is necessary to +carry torches, for the way is dark and dangerous. +After advancing sixty or seventy feet we descend a +strong but rough ladder twenty feet long, placed +against a very precipitous rock. Not the faintest +glimmer of daylight reaches that spot; but after +a while we stand on the brink of a perpendicular precipice, +the bottom of which is strongly illuminated +through a hole in the surface rock more than 200 feet +above. Standing on the verge of this awful pit in the +dim light, the rocks and crags seem to take on most +weird shapes. We go down into the great hole by a +ladder eighty feet high and twelve wide, and, reaching +the bottom, are as yet but at the mouth of the cave, +which, by the bye, is called <i>Xtacunbi Xunan</i> (the +hidden lady), because, say the Indians, a lady was stolen +from her mother and hidden there by her lover. Now, +to our right, we find a narrow passage, and soon +another ladder; the darkness is intense and the +descent continuous, though irregular, like a series of +hills and dales, ladders being placed against the steepest +places.</p> + +<p>After an exhausting journey we reach a vast chamber, +from which crooked passages lead in various directions +to wells, seven in all, each named according to +the peculiar kind of water. One, always warm, is +called <i>Chocohá</i> (hot water); another, <i>O[c]ihá</i> (milky +water), and <i>Akabhá</i> (dark water). About 400 paces +away from the chamber, passing through a very narrow, +close passage, there is a basin of red water that +ebbs and flows like the sea, receding with the south +wind, increasing with the northwest.</p> + +<p>To reach the most distant well, we go down yet one +more ladder, the seventh. On one side of it there is a +perpendicular wall, on the other a yawning gulf, so +when one of the steps, merely round sticks tied with +withes, gave way beneath our feet, we tightly grasped +the stick above. Having reached the bottom of the +ladder, we crawl on our hands and feet through a +broken, winding passage about 800 feet long, then see +before us a basin of crystalline water, and how thirsty +we are! This basin is 1,400 feet from the mouth of the +cave, and about 450 feet below the earth's surface. +Several hundred people during five months in every +year depend entirely on that source for all the water +they use. With their frail pitchers and flaring torches +they wend their way, gasping for breath, through the +intricate passages, and reaching the water, are so profusely +perspiring that they must wait before quenching +their thirst. The way back is even harder, and +they are tired and loaded; yet these people are such +lovers of cleanliness that on their arrival at their poor +huts, before tasting food, they will use some of the +water that has cost them so much, to bathe their +smoke-begrimed skin. As several women once fainted +in the cave, men generally fetch the water now.</p> + +<p>Yucatan is, and has been for ages past, quite free +from earthquakes, while all surrounding countries are +from time to time convulsed. This immunity may be +due to the vast caverns and numerous great wells existing +throughout the land. Pliny the Elder was of +opinion that if numerous deep wells were made in the +earth to serve as outlets for the gases that disturb its +upper strata, the strength of the earthquakes would +be diminished, and if we may judge by Yucatan, Pliny +was right in his conjectures. After him, other scientists +who have carefully studied the subject have +expressed the same opinion with regard to the efficacy +of large wells.</p> + +<p class="signature">ALICE D. LE PLONGEON.</p> + +<p>Brooklyn, July 15, 1885.</p> + +<hr /> + +<p>Cholera failed to strike a single one of the 4,000 +women employed in the national tobacco factory at +Valencia, Spain, though the disease raged violently in +that city, and the <i>Medical World</i> recalls that tobacco +workers were also noticed to enjoy exemption from attack +during an epidemic at Amsterdam.</p> + +<hr /> + +<h2><a name="art21" id="art21"></a>THE CABBAGE BUTTERFLY.</h2> + +<p>A patch of eggs and the minute caterpillars or larvæ +nearly emerged from them are seen on the leaf. These +tiny eggs are at first quite white or pale yellow, +and form an object for the microscope of remarkable +beauty, which is worthy of the examination of all who +take an interest in the garden and its insect life. An +egg magnified is drawn at the bottom left-hand corner +of the woodcut. When the eggs are near the hatching +point they darken in color, and a magnifying glass reveals +through the delicate transparent shell a sight +which fills the observer with amazement; the embryo +caterpillar is seen in gradual course of formation, and +if patience and warmth have permitted it, the observer +will witness slight movements within the life-case, and +presently the shell will break and a black head with +moving jaws will be thrust out; the little caterpillar +unfolds and slowly crawls away from the egg-shell, and +inserts its jaws into the green leaf. It is curious to +witness how judiciously the little creatures avoid crowding +together, but strike out in different directions, and +thus they make sure of a plentiful supply of food, and +distribute the effects of their depredations. These +caterpillars eat continually, and hence rapidly increase +in size, until they present the appearance shown in our +drawing at the bottom of the illustration, which is a +full grown caterpillar.</p> + +<div class="figright"><a href="./images/3.png"> +<img src="./images/3_th.png" alt="THE CABBAGE AND PEACOCK BUTTERFLIES." /></a> +<br />THE CABBAGE AND PEACOCK BUTTERFLIES.</div> + +<p>It will be observed that this insect is composed of +thirteen segments from head to tail, which is a distinctive +characteristic of all insects both in the larval and +perfect states; but in the case of this and most other +caterpillars these segments are sharply defined and +readily recognized. It will also be noticed that the +three segments or "joints" nearest the head bear a +pair of legs each; these are the real feet, or claspers, as +they are sometimes termed, which develop into the +feet of the future butterfly. There are four pairs of +false feet or suckers, which adhere to the ground by +suction, and which disappear in the butterfly. On +the last or tail end is a fifth pair of suckers also, which +can attach themselves to a surface with considerable +force, as any one can attest who has noticed the wrigglings +of one of these caterpillars when feeling for new +feeding ground.</p> + +<p>The caterpillar now ceases to eat, and quietly betakes +itself to a secluded corner, where in peace it spins a +web around its body, and wrapt therein remains quiescent, +awaiting its change into the butterfly. Although +so dormant outwardly, activity reigns inside; processes +are going on within that chrysalis-case which are the +amazement and the puzzle of all naturalists. In +course of time the worm is changed into the beautiful +winged butterfly, which breaks its case and emerges +soft and wet; but it quickly dries and spreads its wings +to commence its life in the air and sunshine. The chrysalis +is represented in the figure on the left. The butterfly, +it will be recognized, is one of the common insects +so familiar to all, with strongly veined white wings, +bearing three black spots, two on the upper and one +on the lower wing, and dark coloring on the corner of +the upper wings. The antennæ, as with all butterflies, +are clubbed at the extremity—unlike moths', which are +tapering—and the large black staring eyes are the +optical apparatus, containing, we are told, thousands +of lenses, each a perfect, simple eye.</p> + +<p>The wings derive their chief coloring from the covering +of scales, which lie on like slates on a roof, and are +attached in a similar manner. A small portion of the +wing magnified is represented at the bottom right +hand corner, and detached scales more highly magnified +<a name="Page_8106" id="Page_8106"></a>next to it, exhibiting somewhat the form of battledoors.</p> + + +<h3>THE PEACOCK BUTTERFLY.</h3> + +<p>Another well known insect is illustrated in the figure +in the upper portion—the peacock butterfly (Vanessa +Io). The curious spiked and spotted caterpillar feeds +upon the common nettle. This beautiful butterfly—common +in most districts—is brilliantly colored and +figured on the upper side of the wings, but only of a +mottled brown on the under surface, somewhat resembling +a dried and brown leaf, so that it is no easy matter +to detect the conspicuous, brightly-decked insect when +it alights from flight upon foliage, and brings its wings +together over its back after the manner of butterflies. +At the left-hand corner is seen the head of the insect, +magnified, showing the long spiral tongue.</p> + +<p>This is a curious structure, and one that will repay +the trouble of microscopic examination. In the figure +the profile is seen, the large compound eye at the side +and the long curved tongue, so elephantine-looking in +form, though of minute size, is seen unrolled as it is +when about to be inserted into flowers to pump up +the honey-juice. This little piece of insect apparatus +is a mass of muscles and sensitive nerves comprising +a machine of greater complexity and of no less precision +in its action than the modern printing machine. +When not in use, the tongue rolls into a spiral and disappears +under the head. A butterfly's tongue may +readily be unrolled by carefully inserting a pin within +the first spiral and gently drawing it out.—<i>The Gardeners' +Chronicle.</i></p> + +<hr /> + +<h2><a name="art22" id="art22"></a>THE BHOTAN CYPRESS.</h2> + +<h3>(CUPRESSUS TORULOSA.)</h3> + +<p>This cypress, apart from its elegant growth, is interesting +as being the only species of Cupressus indigenous +to India. It is a native of the Himalayas in +the Bhotan district, and it also occurs on the borders +of Chinese Tartary. It forms, therefore, a connecting +link, as it were, between the true cypresses of the extreme +east and those that are natives of Europe. It is +singular to note that this genus of conifers extends +throughout the entire breadth of the northern hemisphere, +Cupressus funebris representing the extreme +east in China, and C. macrocarpa the extreme west on +the Californian seacoast. The northerly and southerly +limits, it is interesting to mark, are, on the contrary, +singularly restricted, the most southerly being found +in Mexico; the most northerly (C. nutkaensis) in Nootka +Sound, and the subject of these remarks (C. torulosa) +in Bhotan. The whole of the regions intervening between +these extreme lateral points have their cypresses. +The European species are C. lusitanica (the cedar of +Goa), which inhabits Spain and Portugal; C. sempervirens +(the Roman cypress), which is centered chiefly in +the southeasterly parts of Europe, extending into Asia +Minor. Farther eastward C. torulosa is met with, and +the chain is extended eastward by C. funebris, also +known as C. pendula. The headquarters of the cypresses +are undoubtedly in the extreme west, for here +may be found some four or five distinct species, including +the well-known C. Lawsoniana, probably the most +popular of all coniferæ in gardens, C. Goveniana, +C. Macnabiana, C. macrocarpa, and C. nutkaensis (spelt +C. nutkanus by the Californian botanists). The eastern +representative of the cypresses in the United States of +North America is C. thyoides, popularly known as the +white cedar. In Mexico three or four species occur, so +that the genus in round numbers only contains about +a dozen species. The Californian botanist Mr. Sereno +Watson takes away Lawson's cypress from Cupressus +and puts it in the genus Chamæcyparis, the chief +points of distinction being the flattened two-ranked +branchlets and the small globose cones maturing the +first year.</p> + +<div class="figcenter"><a href="./images/4.png"> +<img src="./images/4_th.png" alt="CONES OF CUPRESSUS TORULOSA (NATURAL SIZE)." /></a> +<br /> CONES OF CUPRESSUS TORULOSA (NATURAL SIZE).</div> + +<p>All the cypresses are undoubtedly valuable from a +garden point of view, but the various species vary in +degree as regards their utility as ornamental subjects. +I should rank them in the following order in point of +merit: C. Lawsoniana, C. nutkaensis, C. macrocarpa, +C. sempervirens, C. thyoides, C. Macnabiana, and C. +Goveniana; then would follow C. torulosa, C. funebris, +C. Knightiana, and other Mexican species. These are +placed last, not because they are less elegant than the +others, but on account of their tenderness, all being +liable to succumb to our damp and cold winters. The +species which concerns us at present, C. torulosa, is an +old introduction, seeds of it having been sent to this +country by Wallich so long back as 1824, and previous +to this date it was found by Royle on the Himalayas, +growing at elevations of some 11,500 feet above sea +level. Coming from such a height, one would suppose +it to be hardier than it really is, but its tenderness may +probably be accounted for by the wood not getting +thoroughly ripened during our summers. It is a very +handsome tree, said to reach from 20 feet to 125 feet in +height in its native habitat. It has a perfectly straight +stem; the growth is pyramidal or rather conical, and +the old wood is of a warm purplish-brown. The foliage +is a glaucous gray-green, and the branches have a +twisted and tufted appearance.</p> + +<p>There are several varieties of it which are, or have +been, in cultivation. Of these one of the best is corneyana, +which Gordon ranked as a distinct species. It +was supposed to be Chinese, and was introduced to +cultivation by Messrs. Knight & Perry, the predecessors +of Messrs. Veitch at the Chelsea Nurseries. It +differs from C. torulosa proper, its habit being of low +stature, and has slender pendulous branches; hence, it +has been known in gardens by the names of C. gracilis, +C. cernua, and C. pendula. Other varieties of C. torulosa +are those named in gardens and nurseries—viridis, +a kind devoid of the glaucous foliage of the original; +majestica, a robust variety; and nana, a very dwarf +and compact-growing sort. There is also a so-called +variegated form, but it is not worthy of mention. The +synonyms of C. torulosa itself are C. cashmeriana, +C. nepalensis, and C. pendula. Having regard to the +tenderness of this Bhotan cypress, it should only be +planted in the warmest localities, and in dry sheltered +positions; upland districts, too, provided they are +sheltered, are undoubtedly suitable for it, inasmuch as +growth is retarded in spring, and, therefore, the young +shoots escape injury from late spring frosts.—<i>W.G., in +The Garden.</i></p> + +<hr /> + + + + +<h2><a name="art23" id="art23"></a>THE PITCHER PLANT.</h2> + + +<p>The variety of the pitcher plant (<i>Sarracenia variolaris</i>) +found in North America is carnivorous, being a +feeder on various animal substances.</p> + +<p>Mrs. Mary Treat, an American naturalist, made, +a few years ago, several experiments upon the plants +of this species to be found in Florida; and to the +labors of this lady the writer has been indebted, in +some measure, in the preparation of this paper.</p> + +<p>The <i>Sarracenia</i> derives its name of "pitcher plant" +from the fact of its possessing the following curious +characteristics: The median nerve is prolonged beyond +the leaves in the manner of a tendril, and terminates +in a species of cup or urn. This cup is ordinarily +three or four inches in depth, and one to one and a half +inches in width. The orifice of the cup is covered with +a lid, which opens and shuts at certain periods. At +sunrise the cup is found filled with sweet, limpid water, +at which time the lid is down. In the course of the day +the lid opens, when nearly half the water is evaporated; +but during the night this loss is made up, and +the next morning the cup is again quite full, and the +lid is shut.</p> + +<p>About the middle of March the plants put forth their +leaves, which are from six to twelve inches long, hollow, +and shaped something like a trumpet, while the aperture +of the apex is formed almost precisely in the same +manner as those of the plants previously described. A +broad wing extends along one side of the leaf, from the +base to the opening at the top; this wing is bound or +edged with a purple cord, which extends likewise +around the cup. This cord secretes a sweet fluid, and +not only flying insects, but those also that crawl upon +the ground, are attracted by it to the plants. Ants, +especially, are very fond of this fluid, so that a line of +aphides, extending from the base to the summit of a +leaf, may frequently be observed slowly advancing +toward the orifice of the cup, down which they disappear, +never to return. Flying insects of every kind +are equally drawn to the plant; and directly they taste +the fluid, they act very curiously. After feeding upon +the secretions for two or three minutes they become +quite stupid, unsteady on their feet, and while trying +to pass their legs over their wings to clear them, they +fall down.</p> + +<p>It is of no use to liberate any of the smaller insects; +every fly, removed from the leaf upon which it had +been feeding, returned immediately it was at liberty to +do so, and walked down the fatal cup as though drawn +to it by a species of irresistible fascination.</p> + +<p>It is not alone that flies and other small insects are +overpowered by the fluid which exudes from the cord +in question. Even large insects succumb to it, although +of course not so quickly. Mrs. Treat says: "A large +cockroach was feeding on the secretion of a fresh leaf, +which had caught but little or no prey. After feeding +a short time the insect went down the tube so tight +that I could not dislodge it, even when turning the leaf +upside down and knocking it quite hard. It was late +in the evening when I observed it enter; the next +morning I cut the tube open; the cockroach was still +alive, but it was covered with a secretion produced +from the inner surface of the tube, and its legs fell off +as I extricated it. From all appearance the terrible +<i>Sarracenia</i> was eating its victim alive. And yet, perhaps, +I should not say 'terrible,' for the plant seems to +supply its victims with a Lethe-like draught before +devouring them."</p> + +<p>If only a few insects alight upon a leaf, no unpleasant +smell is perceptible during or after the process of +digestion; but if a large number of them be caught, +which is commonly the case, a most offensive odor +emanates from the cup, although the putrid matter +does not appear to injure in any manner the inner surface +of the tube, food, even in this condition, being +readily absorbed, and going to nourish the plant. In +fact, it would seem that the <i>Sarracenia</i>, like some animals, +can feed upon carrion and thrive upon it.</p> + +<p>In instances in which experiments have been made +with fresh, raw beef or mutton, the meat has been covered +in a few hours with the secretions of the leaves, +and the blood extracted from it. There is, however, +one difference between the digesting powers of the +leaves when exercised upon insects or upon meat. +Even if the bodies of insects have become putrid, the +plant, as has already been stated, has no difficulty in +assimilating them; but as regards meat, it is only when +it is perfectly sweet that the secretions of the leaves +will act upon it.</p> + +<p>The pitcher plant undoubtedly derives its principal +nourishment from the insects it eats. It, too—unlike +most other carnivorous plants, which, when the quantity +of food with which they have to deal is in excess +of their powers of digestion, succumb to the effort and +die—appears to find it easy to devour any number of +insects, small or large, the operation being with it +simply a question of time. Flies, beetles, or even cockroaches, +at the expiration of three or four days at most, +disappear, nothing being left of them save their wings +and other hard, parts of their bodies.</p> + +<p>The <i>Sarracenia</i> is, indeed, not only the most voracious +of all known species of carnivorous plants, but +the least fastidious as to the nature of the food upon +which it feeds.—<i>W.C.M., Nature.</i></p> + +<hr /> + +<h2><a name="art24" id="art24"></a>WHAT IS A PLANT?</h2> + +<p>Mr. Worsley-Benison has been discussing this +question in a very interesting way, and he says in conclusion +that "<i>physiologically</i> the most distinctive +feature of plant-life is the power to manufacture protein +from less complex bodies; that of animal-life, the +absence of such power." He finds that in form, in the +presence of starch, of chlorophyl, in power of locomotion, +in the presence of circulatory organs, of the body +called nitrogen, in the functions of respiration and +sensation, there are no diagnostic characters. He +finds, however, "fairly constant and well-marked +distinctions" in the presence of a cellulose coat in the +plant-cell, in digestion followed by absorption, and in +the power to manufacture protein.</p> + +<p>The <i>morphological</i> feature of plants is this cellulose +coat; of animals, its absence; the <i>physiological</i> peculiarity +of plants, this <i>manufacturing power</i>; of animals, +the want of it. But after all the discussion he says: +"To the question, <i>Is this an animal or a plant?</i> we +must often reply, <i>We do not know</i>.—<i>The Microscope.</i></p> + +<hr /> + +<h2><a name="art25" id="art25"></a>CAMELLIAS.</h2> + +<p>Next to the rose, no <ins class="trans" title="Transcriber's Note: Original 'flour'.">flower</ins> is more beautiful or more +useful than the camellia. It may readily be so managed +that its natural season of blooming shall be from +October to March, thus coming in at a time when roses +can hardly be had without forcing. In every quality, +with the single exception of scent, the camellia may be +pronounced the equal of the rose. It can be used in +all combinations or for all purposes for which roses +can be employed. In form and color it is probably +more perfect, and fully as brilliant. It is equally or +more durable, either on the plant or as a cut flower. It +is a little dearer to buy, and perhaps slightly more +difficult to cultivate; but like most plants the camellia +has crucial periods in its life, when it needs special +treatment. That given, it may be grown with the utmost +ease; that withheld, its culture becomes precarious, +or a failure. The camellia is so hardy that it will +live in the open air in many parts of Great Britain, and +herein lies a danger to many cultivators. Because it is +quite or almost hardy, they keep it almost cool. This +is all very well if the cool treatment be not carried to +extremes, and persisted in all the year round. Camellias +in a dormant state will live and thrive in any temperature +above the freezing point, and will take little +or no hurt if subjected to from 3°-4° below it, or a +temperature of 27° Fahr.</p> + +<p>They will also bloom freely in a temperature of 40°, +though 45° suits them better. Hence, during the late +summer and early autumn it is hardly possible to keep +camellias too cool either out of doors or in. They are +also particularly sensitive to heat just before the flower-buds +begin to swell in late autumn or winter; a sudden +or sensible rise of temperature at that stage sends the +flower-buds off in showers. This is what too often happens, +in fact, to the camellias of amateurs. No sooner +do the buds begin to show then a natural impatience +seizes the possessor's of well-budded camellias to have +the flowers opened. More warmth, a closer atmosphere, +is brought to bear upon them, and down fall the buds +<a name="Page_8107" id="Page_8107"></a>in showers on stage or floor—the chief cause of this +slip between the buds and the open flowers being a rise +of temperature. A close or arid atmosphere often leads +to the same results. Camellias can hardly have too +free a circulation of air or too low a temperature. +Another frequent cause of buds dropping arises from +either too little or too much water at the roots. +Either a paucity or excess of water at the roots +should lead to identical results. Most amateurs overwater +their camellias during their flowering stages. +Seeing so many buds expanding, they naturally rush +to the conclusion that a good deal of water must be +used to fill them to bursting point. But the opening +of camellia buds is less a manufacture than a mere development, +and the strain on the plant and drain on +the roots is far less during this stage than many suppose. +Of course the opposite extreme of over-dry roots +must be provided against, else this would also cause +the plants to cast off their buds.</p> + +<p>But our object now is less to point out how buds are +to be developed into fully expanded flowers than to +show how they were to be formed in plenty, and +the plants preserved in robust health year after year. +One of the simplest and surest modes of reaching +this desirable end is to adopt a system of semi-tropical +treatment for two months or so after flowering. The +moment or even before the late blooms fade, the +plants should be pruned if necessary. Few plants bear +the knife better than camellias, though it is folly to +cut them unless they are too tall or too large for their +quarters or have grown out of form. As a rule healthy +camellias produce sufficient or even a redundancy of +shoots without cutting back; but should they need +pruning, after flowering is the best time to perform +the operation.</p> + +<p>During the breaking of the tender leaves and the +growth of the young shoots in their first stages, the +plant should be shaded from direct sunshine, unless, +indeed, they are a long way from the glass, when the +diffusion and dispersion of the rays of light tone down +or break their scorching force; few young leaves and +shoots are more tender and easily burned than camellia, +and scorching not only disfigures the plants, but +also hinders the formation of fine growths and the development +of flower-buds.</p> + +<p>The atmosphere during the early season of growth +may almost touch saturation. It must not fail to be +genial, and this geniality of the air must be kept up by +the surface-sprinkling of paths, floors, stages, walls, +and the plants themselves at least twice a day.</p> + +<p>With the pots or border well drained it is hardly +possible to overwater the roots of camellias during +their period of wood-making. The temperature may +range from 50° to 65° during most of the period. As +the flower-buds form, and become more conspicuous, +the tropical treatment may become less and less tropical, +until the camellias are subjected to the common +treatment of greenhouse or conservatory plants in +summer. Even at this early stage it is wise to attend +to the thinning of the buds. Many varieties of camellias—notably +that most useful of all varieties, the +double white—will often set and swell five or ten +times more buds than it ought to be allowed to carry. +Nothing is gained, but a good deal is lost, by allowing +so many embryo flower-buds to be formed or +partially developed. It is in fact far wiser to take +off the majority of the excess at the earliest possible +point, so as to concentrate the strength of the plant +into those that remain.</p> + +<p>As it is, however, often a point of great moment to +have a succession of camellia flowers for as long a +period as possible on the same plants, buds of all sizes +should be selected to remain. Fortunately, it is found +in practice that the plants, unless overweighted with +blooms, do not cast off the smaller or later buds in +their efforts to open their earlier and larger ones. With +the setting, thinning, and partial swelling of the flower-buds +the semi-tropical treatment of camellias must +close; continued longer, the result would be their +blooming out of season, or more probably their not +blooming at all.</p> + +<p>The best place for camellias from the time of setting +their flower-buds to their blooming season is a vexed +question, which can hardly be said to have been settled +as yet. They may either be left in a cool greenhouse, +or placed in a shaded, sheltered position in the open +air. Some of the finest camellias ever seen have been +placed in the open air from June to October. These +in some cases have been stood behind south, and in +others behind west walls. Those facing the east in +their summer quarters were, on the whole, the finest, +many of them being truly magnificent plants, not a +few of them having been imported direct from Florence +at a time when camellias were far less grown in +England than now.</p> + +<p>In all cases where camellias are placed in the open +air in summer, care will be taken to place the pots on +worm proof bases, and to shield the tops from direct +sunshine from 10 to 4 o'clock. If these two points are +attended to, and also shelter from high winds, it matters +little where they stand. In all cases it is well to place +camellias under glass shelter early in October, less for +fear of cold than of saturating rains causing a sodden +state of the soil in the pots.</p> + +<p>While adverting, however, to the safety and usefulness +of placing camellias in the open air in summer, +it must not be inferred that this is essential to +the successful culture; it is, in fact, far otherwise, as +the majority of the finest camellias in the country +are planted out in conservatories with immovable +roofs. Many such houses are, however, treated to +special semi-tropical treatment as has been described, +and are kept as cool and open as possible after the +flower-buds are fairly set, so that the cultural and climatic +conditions approximate as closely as possible to +those here indicated.</p> + +<p>Soil and seasons of potting may be described as +vexed questions in camellia culture. As to the first, +some affect pure loam, others peat only, yet more a +half and half of both, with a liberal proportion of +gritty sand, or a little smashed charcoal or bruised +bones as porous or feeding agents, or both. Most +growers prefer the mixture, and as good camellias are +grown in each of its constituents, it follows without +saying that they may also be well grown in various +proportions of both.</p> + +<p>Under rather than over potting suits the plants +best, and the best time is doubtless just before they +are about to start into fresh growth, though many +good cultivators elect to shift their plants in the late +summer or autumn, that is, soon after the growth is +finishing, and the flower-buds fairly and fully set for +the next season. From all which it is obvious that +the camellia is not only among the most useful and +showy, but likewise among the most accommodating +of plants.</p> + +<p>Under good cultivation it is also one of the cleanest, +though when scab gets on it, it is difficult to get rid +of it. Mealy-bugs also occasionally make a hurried +visit to camellias when making their growth, as well +as aphides. But the leaves once formed and advanced +to semi-maturity are too hard and leathery for such +insects, while they will bear scale being rubbed off +them with impunity. But really well-grown camellias, +as a rule, are wholly free from insect pests, and their +clean, dark, glossy leaves are only of secondary beauty +to their brilliant, exquisitely formed, and many sized +flowers.—<i>D.T., The Gardeners' Chronicle.</i></p> + +<hr /> + +<h2><a name="art26" id="art26"></a>ARISÆMA FIMBRIATUM.</h2> + +<h3><i>Mast.; sp. nov.</i></h3> + +<div class="figcenter"><a href="./images/5.png"> +<img src="./images/5_th.png" alt="ARISÆMA FIMBRIATUM: LEAF, SPATHE, AND" /></a> +<br /> ARISÆMA FIMBRIATUM: LEAF, SPATHE, AND FLORAL DETAILS.</div> + +<p>Some few years since we had occasion to figure some +very remarkable Himalayan species of this genus, in +which the end of the spadix was prolonged into a +very long, thread-like appendage thrown over the +leaves of the plant or of its neighbors, and ultimately +reaching the ground, and thus, it is presumed, affording +ants and other insects means of access to the flowers, +and consequent fertilization. These species were grown +by Mr. Elwes, and exhibited by him before the Scientific +Committee. The present species is of somewhat similar +character, but is, we believe, new alike to gardens and +to science. We met with it in the course of the +autumn in the nursery of Messrs. Sander, at St. Alban's; +but learn that it has since passed into the hands of Mr. +W. Bull, of Chelsea. It was imported accidentally with +orchids, probably from the Philippine Islands. It belongs +to Engler's section, trisecta, having two stalked +leaves, each deeply divided into three ovate acute +glabrous segments. The petioles are long, pale purplish, +rose-colored, sprinkled with small purplish spots. The +spathes are oblong acute or acuminate, convolute at the +base, brownish-purple, striped longitudinally with narrow +whitish bands. The spadix is cylindrical, slender, +terminating in along, whip-like extremity, much longer +than the spathe. The flowers have the arrangement and +structure common to the genus, the females being +crowded at the base of the spadix, the males immediately +above them, and these passing gradually into fleshy +incurved processes, which in their turn pass gradually +into long, slender, purplish threads, covering the whole +of the free end of the spadix.—<i>M.T.M., in The +Gardeness' Chronicle.</i></p> + +<hr /> + +<h2><a name="art27" id="art27"></a>STRIKING A LIGHT.</h2> + +<p>In the new edition of Mason's "Burma" we read that +among other uses to which the bamboo is applied, not +the least useful is that of producing fire by friction. +For this purpose a joint of thoroughly dry bamboo is +selected, about 1½ inches in diameter, and this +joint is then split in halves. A ball is now prepared +by scraping off shavings from a perfectly dry bamboo, +and this ball being placed on some firm support, as a +fallen log or piece of rock, one of the above halves is +held by its ends firmly down on it, so that the ball of +soft fiber is pressed with some force against its inner or +concave surface. Another man now takes a piece of +bamboo a foot long or less, and shaped with a blunt +edge, something like a paper knife, and commences a +sawing motion backward and forward across the horizontal +piece of bamboo, and just over the spot where +the ball of soft fiber is held. The motion is slow at +first, and by degrees a groove is formed, which soon +deepens as the motion increases in quickness. Soon +smoke arises, and the motion is now made as rapid as +possible, and by the time the bamboo is cut through +not only smoke but sparks are seen, which soon ignite +the materials of which the ball beneath is composed. +The first tender spark is now carefully blown, and +when well alight the ball is withdrawn, and leaves and +other inflammable materials heaped over it, and a fire +secured. This is the only method that I am aware of +for procuring fire by friction in Burma, but on the +hills and out of the way parts, that philosophical toy, +the "pyrophorus," is still in use. This consists<a name="FNanchor_1" id="FNanchor_1"></a><a href="#Footnote_1"><sup>1</sup></a> of a +short joint of a thick woody bamboo, neatly cut, which +forms a cylinder. At the bottom of this a bit of tinder +is placed, and a tightly-fitting piston inserted composed +of some hard wood. The tube being now held in one +hand, or firmly supported, the piston is driven violently +down on the tinder by a smart blow from the hand, +with the result of igniting the tinder beneath.</p> + +<p>Another method of obtaining fire by friction from +bamboos is thus described by Captain T.H. Lewin +("Hill Tracts of Chittagong, and the Dwellers <ins class="trans" title="Transcriber's Note: Closing quote missing in original.">Therein"</ins>, +Calcutta, 1869, p. 83), as practiced in the Chittagong +Hills. The Tipporahs make use of an ingenious device +to obtain fire; they take a piece of dry bamboo, about +a foot long, split it in half, and on its outer round surface +cut a nick, or notch, about an eighth of an inch +broad, circling round the semi-circumference of the +bamboo, shallow toward the edges, but deepening in +the center until a minute slit of about a line in breadth +pierces the inner surface of the bamboo fire-stick. Then +a flexible strip of bamboo is taken, about 1½ feet long +and an eighth of an inch in breadth, to fit the circling +notch, or groove, in the fire-stick. This slip or band +is rubbed with fine dry sand, and then passed round +the fire-stick, on which the operator stands, a foot on +either end. Then the slip, grasped firmly, an end in +each hand, is pulled steadily back and forth, increasing +gradually in pressure and velocity as the smoke comes. +By the time the fire-band snaps with the friction there +ought to appear through the slit in the fire-stick some +incandescent dust, and this placed, smouldering as it +is, in a nest of dry bamboo shavings, can be gently +blown into a flame.—<i>The Gardeners' Chronicle.</i></p> + +<p><a name="Footnote_1" id="Footnote_1"></a><a href="#FNanchor_1">[1]</a></p> +<div class="note"><p>It is also made of a solid cylinder of buffalo's horn, with a central hollow of +three-sixteenths of an inch in diameter and three inches deep burnt into it. The piston, which fits very tightly in it, is made of iron-wood or some wood equally hard.</p></div> + +<hr /> + +<h2><a name="art28" id="art28"></a>EXPERIMENTS IN MEMORY.</h2> + +<p>When we read how one mediæval saint stood erect +in his cell for a week without sleep or food, merely +chewing a plantain-leaf out of humility, so as not to be +too perfect; how another remained all night up to his +neck in a pond that was freezing over; and how others +still performed for the glory of God feats no less tasking +to their energies, we are inclined to think, that, +with the gods of yore, the men, too, have departed, +and that the earth is handed over to a race whose will +has become as feeble as its faith. But we ought not to +yield to these instigations, by which the evil one tempts +us to disparage our own generation. The gods have +somewhat changed their shape, 'tis true, and the men +their minds; but both are still alive and vigorous as +ever for an eye that can look under superficial disguises. +The human energy no longer freezes itself in +fish-ponds, and starves itself in cells; but near the +north pole, in central Africa, on Alpine "couloirs," and +especially in what are nowadays called "psycho-physical +laboratories," it maybe found as invincible as +ever, and ready for every fresh demand. To most +people a north pole expedition would be an easy task +compared with those ineffably tedious measurements +of simple mental processes of which Ernst Heinrich +Weber set the fashion some forty years ago, and the +necessity of extending which in every possible direction +becomes more and more apparent to students +of the mind. Think of making forty thousand estimates +of which is the heavier of two weights, or seventy +thousand answers as to whether your skin is touched +at two points or at one, and then tabulating and mathematically +discussing your results! Insight is to be +gained at no less price than this. The new sort of +study of the mind bears the same relation to the older +psychology that the microscopic anatomy of the body +does to the anatomy of its visible form, and the one +will undoubtedly be as fruitful and as indispensable as +the other.</p> + +<p>Dr. Ebbinghaus<a name="FNanchor_2" id="FNanchor_2"></a><a href="#Footnote_2"><sup>1</sup></a> makes an original addition to heroic +psychological literature in the little work whose title +we have given. For more than two years he has apparently +spent a considerable time each day in committing +to memory sets of meaningless syllables, and +trying to trace numerically the laws according to which +they were retained or forgotten. Most of his results, +we are sorry to say, add nothing to our gross experience +of the matter. Here, as in the case of the saints, +heroism seems to be its own reward. But the incidental +results are usually the most pregnant in this department; +and two of those which Dr. Ebbinghaus has +reached seems to us to amply justify his pains. The +first is, that, in <i>forgetting</i> such things as these lists of +syllables, the loss goes on very much more rapidly at +first than later on. He measured the loss by the number +of seconds required to <i>relearn</i> the list after it had +been once learned. Roughly speaking, if it took a +thousand seconds to learn the list, and five hundred to +relearn it, the loss between the two learnings would +have been one-half. Measured in this way, full half of +the forgetting seems to occur within the first half-hour, +while only four-fifths is forgotten at the end of a +month. The nature of this result might have been anticipated, +but hardly its numerical proportions.</p> + +<p>The other important result relates to the question +whether ideas are recalled only by those that previously +came immediately before them, or whether an idea +can possibly recall another idea, with which it was never +in <i>immediate</i> contact, without passing through the intermediate +mental links. The question is of theoretic +importance with regard to the way in which the process +of "association of ideas" must be conceived; +and Dr. Ebbinghaus' attempt is as successful as it is +original, in bringing two views, which seem at first +sight inaccessible to proof, to a direct practical test, +and giving the victory to one of them. His experiments +conclusively show that an idea is not only "associated" +directly with the one that follows it, and +with the rest <i>through that</i>, but that it is <i>directly</i> associated +with <i>all</i> that are near it, though in unequal degrees. +He first measured the time needed to impress +on the memory certain lists of syllables, and then the +time needed to impress lists of the same syllables +with gaps between them. Thus, representing the syllables +by numbers, if the first list was 1, 2, 3, 4 ... 13, +14, 15, 16, the second would be 1, 3, 5 ... 15, 2, 4, +6 ... 16, and so forth, with many variations.</p> + +<p>Now, if 1 and 3 in the first list were learned in that +<a name="Page_8108" id="Page_8108"></a>order merely by 1 calling up 2, and by 2 calling up 3, +leaving out the 2 ought to leave 1 and 3 with no tie in +the mind; and the second list ought to take as much +time in the learning as if the first list had never been +heard of. If, on the other hand, 1 has a <i>direct</i> influence +on 3 as well as on 2, that influence should be exerted +even when 2 is dropped out; and a person familiar +with the first list ought to learn the second one more +rapidly than otherwise he could. This latter case is +what actually occurs; and Dr. Ebbinghaus has found +that syllables originally separated by as many as seven +intermediaries still reveal, by the increased rapidity +with which they are learned in order, the strength of +the tie that the original learning established between +them, over the heads, so to speak, of all the rest. It +may be that this particular series of experiments is the +entering wedge of a new method of incalculable reach +in such questions. The future alone can show. Meanwhile, +when we add to Dr. Ebbinghaus' "heroism" in +the pursuit of true averages, his high critical acumen, +his modest tone, and his polished style, it will be seen +that we have a new-comer in psychology from whom +the best may be expected.—<i>W.J., Science.</i></p> + +<p><a name="Footnote_2" id="Footnote_2"></a><a href="#FNanchor_2">[1]</a></p><div class="note"><p>"Ueber das Gedächtniss. Untersuchungen zur experimentellen <ins class="trans" title="Transcriber's Note: Closing quote missing in original.">Psychologie."</ins> +Von Herm. Ebbinghaus. Leipzig: Duncker u. Humblot, 1885. 10+169 pp. 8vo.</p></div> + +<hr /> + +<h2><a name="art09" id="art09"></a>SINKING OF THE QUIEVRECHAIN WORKING SHAFT.</h2> + +<p>The sinking of mine shafts in certain Belgian and +French basins, where the coal deposit is covered with +thick strata of watery earth, has from all times been +considered as the most troublesome and delicate, and +often the most difficult operation, of the miner's +art. Of the few modern processes that have +been employed for this purpose, that of Messrs. Kind +and Chaudron has been found most satisfactory, although +it leaves much to be desired where it is a +question of traversing moving sand. An interesting +modification of this well-known process has recently +been described by Mr. E. Chavatte, in the Bulletin de +la Societe Industrielle du Nord de la France. Two +years ago the author had to sink a working shaft at +Quievrechain, 111 feet of which was to traverse a mass +of moving and flowing sand, inconsistent earth, gravel, +and marls, and proceeded as follows:</p> + +<p>He first put down two beams, A B (Pl. 1, Figs. 2, 3, +and 9), each 82 feet in length and of 20×20 inch section +in the center, and upon these placed two others, E F, +of 16×16 inch section. Beneath the two first were +inserted six joists, <i>c c c c c c</i>, about 82 feet in length +and of 14 or 16 inch section in the center. Finally +these were strengthened at their extremities with two +others, <i>d d</i>, about 82 feet in length. All these timbers, +having been connected by tie bands and bolts, constituted +a rigid structure that covered a surface of nearly +seven hundred square yards.</p> + +<p>From the beams, A B and E F, there was suspended +a red fir frame by means of thirty-four iron rods.</p> + +<p>Upon this frame, which was entirely immersed in the +moving sand, there was established brick masonry +(Figs. 1, 2, and 3). As the ends of the timbers entered +the latter, and were connected by 1½ inch bolts, they +concurred in making the entire affair perfectly solid. +The frame, K K, was provided with an oaken ring, +which was affixed to it with bolts.</p> + +<p>After this, a cast iron tubbing, having a cutting +edge, and being composed of rings 3.28 feet wide and +made of six segments, was lowered. This tubbing was +perfectly tight, all the surfaces of the joints having +been made even and provided with strips of lead one-tenth +of an inch thick. It weighed 4,000 pounds to the +running foot.</p> + +<div class="figcenter"><a href="./images/6.png"><img src="./images/6_th.png" alt="Plate I—SINKING A MINE SHAFT" /></a> +<div class="longcaption"><p> +<span class="smcap">Fig.</span> 1.—Section through A B. <span class="smcap">Fig.</span> 2.—Plan. +<span class="smcap">Fig.</span> 3.—Section through C D. <span class="smcap">Fig.</span> 5.—Section through E F of Fig. 4. +<span class="smcap">Figs. 6 and</span> 7.—Work Prepared and finished. <span class="smcap">Fig.</span> 10.—Section +through A B and C D of Fig. 12. <span class="smcap">Figs.</span> 11 6 <span class="smcap">and</span> 12.—Arrangement +of jack-screw. <span class="smcap">Fig.</span> 13.—Section through A B and C D of +Fig. 11.</p></div> +<p class="center"><span class="smcap">Plate</span> I.—SINKING A MINE SHAFT.</p></div> + +<p>It was first raised to a height of fifteen feet, so as to +cause it to enter the sand by virtue of its own gravity. +It thus penetrated to a depth of about twenty inches. +After this the workmen were ordered to man the windlasses +and hoist out some of the sand. This caused the +tubbing to descend about eight inches more, when it +came to a standstill. It was now loaded with 17,000 +pounds of pig iron, but in vain, for it refused to budge. +Mr. Chavatte therefore had recourse to a dredge with +vertical axis, constructed as follows:</p> + +<p>Upon a square axis, A B (Pl. 2, Figs. 1, 2, and 3), provided +with double cross braces, C D, and strengthened +by diagonals, were riveted, by their upper extremities, +two cheeks, G H, whose lower extremities held the +steel plates, I J I' J', which, in turn, were fastened to +the axis, A B, by their other extremities. These plates +were so inclined as to scrape the surface of the ground +over which they were moved. They each carried two +bags made of coarse canvas and strengthened by five +strong leather straps (Figs. 2 and 4). To the steel +plates were riveted two plates of iron containing numerous +apertures, through which passed leather straps +designed for fastening thereto the lower part of the +mouth of the bags. That portion of the mouth of the +latter that was to remain open was fastened in the +same way to two other plates, X Y, X¹ Y¹ (Fig. 1), held +between the lower cross-braces.</p> + +<p>When the apparatus was revolved, the plates scraped +the earth to be removed, and descended in measure as +the latter entered the bags. These bags, when full, +were hooked, by means of the five rings which they +carried, to the device shown in Fig. 8 (Pl. 2), and raised +to the surface and emptied into cars.</p> + +<p>The dredge was set in motion by four oak levers +(Figs. 5 and 6). Two of these were manned by workmen +stationed upon the surface flooring, and the other +two by workmen upon the flooring in the tubbing. +The axis was elongated, in measure as the apparatus +descended, by rods of the same dimensions fastened together +by cast iron sleeves and bolts (Fig. 7).</p> + +<p>The steel plates were not capable of acting alone, +even in cases where they operated in pure moving sand +containing no pebbles, for the sand was too compact +to be easily scraped up by the steel, and so it had to be +previously divided. For this purpose Mr. Chavatte +used rakes which were in form exactly like those of the +extirpators, U and V, of Figs. 1, 2, and 3, of Pl. 2, except +that the dividers carried teeth that were not so +strong as those of the extirpators, and that were set +closer together. These rakes were let down and drawn +up at will. They were maneuvered as follows:</p> + +<p>The dredge descended with the extirpators pointing +upward. When their heads reached the level of the +upper floor, the tools were removed. Then the dredge +was raised again. In this way the extirpators lay upon +the floor, and, if the lifting was continued, they placed +themselves in their working position, in which they +were fixed by the bolts A" B" C" (Fig. 1). After this, +the apparatus was let down and revolved. The rakes +divided the earth, the scrapers collected it, and the +bags pocketed it.</p> + +<p>The great difficulty was to cause the tubbing to descend +vertically, and also to overcome the enormous +lateral pressure exerted upon it by the earth that was +being traversed. Water put into the shaft helped +somewhat, but the great stress to be exerted had to be +effected by means of powerful jack screws. These were +placed directly upon the tubbing, and bore against +strong beams whose extremities were inserted into the +masonry.</p> + +<p>As a usual thing it is not easy to use more than four +or six such jacks, since the number of beams that can +be employed is limited, owing to the danger of obstructing +the mouth of the shaft. Yet twelve were used by +Mr. Chavatte, and this number might have been +doubled had it been necessary. As we have seen, the +frame, K K (Pl. 1, Fig. 3), was provided with an oak +circle traversed by 32 bolts. The length of these latter +was two inches and a quarter longer than they needed +to have been, or they were provided with wooden collars +of that thickness. Later on, these collars were replaced +with iron bars that held the wood against which +the jacks bore in order to press the tubbing downward +(Pl. 1, Figs. 10, 11, 12, and 13).</p> + +<p>Mr. Chavatte's great anxiety was to know whether +he should succeed in causing the first section of tubbing +to traverse the four feet of gravel; for in case it did +not pass, he would be obliged to employ a second section +of smaller diameter, thus increasing the expense. +He was persuaded that the coarse gravel remaining in +the side of the shaft would greatly retard the descent +of the tubbing. So he had decided to remove such obstructions +at the proper moment through divers or a +diving bell. Then an idea occurred to him that dispensed +with all that trouble, and allowed him to continue +with the first section. This was to place upon +the dredge two claw-bars, T (Pl. 2, Fig. 3), which +effected the operation of widening with wonderful ease. +To do this it was only necessary to turn up the bags, +and revolve the apparatus during its descent. The +claw at the extremity of the bar pulled out everything +within its reach, and thus made an absolutely free passage +for the tubbing.</p> + +<p>The sands and gravels were passed by means of a +single section of tubbing 31 feet in length, which was +not stopped until it had penetrated a stratum of white +chalk to a depth of two yards. This chalk had no consistency, +although it contained thin plates of quite +large dimensions. These were cut, as if with a punch, +by means of the teeth of the extirpator.</p> + +<p>It now remains to say a few words concerning the sinking +of the shaft, which, after the operation of the dredge, +was continued by the process called "natural level" +The work was not easy until a depth of 111 feet had +been reached. Up to this point it had been necessary +to proceed with great prudence, and retain the shifting +earth by means of four iron plate tubes weighing 54 +tons. Before finding a means of widening the work +already done by the dredge, Mr. Chavatte was certain +that he would have to use two sections of tubbing, and +so had given the first section a diameter of 16½ feet. +He could then greatly reduce the diameter, and bring it +to 15¾ feet as soon as the ground auger was used.</p> + +<p>After two yards of soil had been removed from beneath +the edge of the tubbing, the earth began to give +way. Seeing this, Mr. Chavatte let down a tube 13 feet +in length and 15.4 in diameter. The exterior of this +<a name="Page_8109" id="Page_8109"></a>was provided with 12 oak guides, which sliding over +the surface of the tubbing had the effect of causing +the tube to descend vertically. And this was necessary, +because this tube had to be driven down every time an +excavation of half a yard had been made.</p> + +<p>Afterward, a diameter of 15.35 feet was proceeded +with, and the small central shaft of 4¼ feet diameter +was begun. This latter had not as yet been sunk, for +fear of causing a fall of the earth.</p> + +<p>Next, the earth was excavated to a depth of 8.2 feet, +and a tube 16.4 feet in length was inserted; then a further +excavation of 8.2 feet was made, and the tube +driven home.</p> + +<p>After this an excavation of 26¼ feet was made, and a +tube of the same length and 14½ feet in diameter was +driven down. Finally, the shifting soil was finished +with a fourth tube 19½ feet in length and 14 feet in +diameter.</p> + +<p>A depth of 111 feet had now been reached, and the +material encountered was solid white chalk. From this +point the work proceeded with a diameter of 13.9 feet +to a depth of 450 feet. The small shaft had been sunk +directly to a depth of 475 feet. At 450 feet the diameter +was diminished by three inches. Then an advance of +a foot was made, and the diameter reduced by one and +a half inch.</p> + +<p>The reason for this reduction in the diameter and +change in the mode of deepening was as follows:</p> + +<p>The Chaudron moss-box, when it chances to reach +its seat intact, and can consequently operate well, +undoubtedly makes a good wedging. But how many +times does it not happen that it gets injured before +reaching its destination? Besides, as it often rests +upon earth that has caved in upon its seat during the +descent of the tubbing, it gets askew, and later on has +to be raised on one side by means of jacks or other +apparatus. Under such circumstances, Mr. Chavatte +considered this moss-box as more detrimental than +useful, and not at all indispensable, and so substituted +beton for it, as had previously been done by Mr. +Bourg, director of the Bois-du-Luc coal mines.</p> + +<div class="figcenter"><a href="./images/7.png"><img src="./images/7_th.png" alt="PLATE II" /></a> +<div class="longcaption"><p><span class="smcap">Figs.</span> 1, 2, 3, 6 <span class="smcap">and</span> 4.—Details of dredge. +<span class="smcap">Figs.</span> 5 6 <span class="smcap">and</span> 6.—Details of maneuvering lever. +<span class="smcap">Fig.</span> 7.—Mode of lengthening the axis of the dredge. +<span class="smcap">Fig.</span> 8.—Hooks for lifting the dredge bags. +<span class="smcap">Fig.</span> 9.—Arrangement of valves in the beton box. +<span class="smcap">Fig.</span> 10.—Device for centering the tubbing.</p></div> +<p class="center"><span class="smcap">Plate</span> II.</p></div> + +<p>This engineer likewise suppressed the balancing +column, which is often a source of trouble in the descent +of the tubbing, and forced his tubbing to center +itself with the shaft through a guide with four branches +riveted under the false bottom that entered the small +shaft (Pl. 2, Fig. 10). Mr. Bourg so managed that there +remained an empty space of ten inches to fill in with +beton. Mr. Chavatte had at first intended to proceed +in the same way, but the two last tubbings, upon +which he had not counted, forced him to reduce the +space to 5¾ inches. Under such circumstances it was +not prudent to employ the same means for guiding the +base of the tubbing, because, if the central shaft had +not exactly the same center as the large one, there +would have been danger of throwing the tubbing sideways +and causing it to leak. Seeing which, Mr. Chavatte +strengthened the lower part of the base ring and +placed it upon another ring tapering downward, and +27½ inches in height (Pl. 1, Fig. 5). The object of this +lower ring was to force the tubbing to remain concentric +with the shaft, to form a tight joint with its upper +conical portion, and to form a joint upon the seat with +its lower flange, so as to prevent the beton from flowing +into the small shaft.</p> + +<p>After the shaft was pumped out, digging by hand +was begun with a diameter of 12 feet. After descending +20 inches an 8×10 inch curb was laid, in order to +consolidate the earth and prevent any movement of +the tubbing. Then the excavating was continued to a +depth of 31½ inches, and with a diameter of 9¾ feet. +At this point another curb was put in for consolidating +the earth. Finally, the bottom was widened out as +shown in Fig. 7, so that three basal wedged curbs could +be put in. This done, the false tubbing was put in +place; and finally, when proceeding upward, the last +ring composed of twelve pieces was reached, the earth +was excavated and at once replaced with a collar composed +of twelve pieces of oak tightened up by oak +wedges. Each of these pieces was cemented separately +and in measure as they were assembled.</p> + +<p>Through motive of economy no masonry was placed +under the base of the three wedged curbs. In fact, by +replacing this with a wedged curb of wood traversed +by six bolts designed to fix the cast iron curb immediately +above, Mr. Chavatte obtained a third curb that +he would have had to have made of cast iron.</p> + +<hr /> + +<h2><a name="art10" id="art10"></a>ON THE ELEMENTARY PRINCIPLES OF THE GAS-ENGINE.<a name="FNanchor_3" id="FNanchor_3"></a><a href="#Footnote_3"><sup>1</sup></a></h2> + +<h3>By <span class="smcap">Denny Lane</span>, of Cork.</h3> + +<p>Among the most useful inventions of the latter half of +the nineteenth century the gas-engine holds a prominent +place. While its development has not been so brilliant +or so startling as that which we can note in the employment +of electricity, it holds, among the applications +of heat, the most important place of any invention +made within that period. Even amid the contrivances +by which, in recent times, the other forces of nature +have been subdued to the uses of man, there are only +a few which rival the gas-engine in practical importance. +With regard to the steam-engine itself, it is remarkable +how little that is new has really been invented +since the time of Watt and Woulfe. In the specifications +of the former can be shown completely delineated, +or fully foreshadowed, nearly every essential condition +of the economy and efficiency attained in our own +days; and it is only by a gradual "survival of the +fittest" of the many contrivances which were made to +carry out his broad ideas that the steam-engine of the +present has attained its great economy.</p> + +<p>It is but within the last fifty years that the laws of +the relation between the different physical forces were +first enunciated by Justice Grove, and confirmed by +the classical researches of Dr. Joule—the one a lawyer, +working hard at his profession, the other a man of +business engaged in manufacture. Both are still living +among us; the latter having withdrawn from business, +while the former is a Judge of the High Court of +Justice. I always regret that the claims of his profession +have weaned Justice Grove from science; for, +while it may be possible to find in the ranks of the Bar +many who might worthily occupy his place on the +Bench, it would be hard to find among men of science +any with as wide-reaching and practical philosophy as +that which he owns. The chemist demonstrated long +since that it was impossible for man to create or destroy +a single particle of ponderable matter; but it remained +for our own time to prove that it was equally impossible +to create or destroy any of the energy which existed +in nature as heat, mechanical power, electricity, or +chemical affinity. All that it is in the power of man to +do is to convert one of these forms into another. This, +perhaps the greatest of all scientific discoveries since +the time of Newton, was first, I believe, enunciated in +1842 by Grove, in a lecture given at the London +Institution; and it was experimentally proved by the +researches of Joule, described in a paper which he read +at the meeting of the British Association which was +held at Cork—my native city—in 1843. My friend Dr. +Sullivan, now President of Queen's College, Cork, and +I myself had the privilege of being two of a select +audience of half a dozen people, who alone took sufficient +interest in the subject to hear for the first time +developed the experimental proof of the theory which +welds into one coherent system the whole physical +forces of the universe, and enables one of these to be +measured by another. One branch of the "correlation +of physical forces," as it was termed by Grove, was the +relation between mechanical power and heat, and the +convertibility of each into the other, which, under the +name of "Thermodynamics," has become one of the +most important branches of practical science.</p> + +<p>Joule's first experiments clearly proved that each of +these forms of energy was convertible into the other; but +some discrepancies arose in determining the exact +equivalent of each. His subsequent researches, however, +clearly demonstrated the true relation between +both. Taking as the unit of heat the amount which would +be necessary to raise 1 lb. of water 1° of Fahrenheit's +scale (now called "the English thermal unit"), he +proved that this unit was equivalent to the mechanical +power which would be required to raise 772 lb. 1 foot, +or to raise 1 lb. 772 ft. perpendicularly against the force +of gravity. The heat-unit—the pound-degree—which I +will distinguish by the Greek letter θ, is a compound unit +of mass and temperature; the second—the foot-pound = f.p.—a +compound unit of mass and space. This +equation, called "Joule's equivalent," or 1 thermal +unit = 772 foot-pounds, is the foundation and the +corner-stone of thermodynamics.</p> + +<p>It is essential to understand the meaning of this +equation. It expresses the maximum effect of the +given cause, viz., that if <i>all</i> the heat were converted +into power, or <i>all</i> the power were converted into heat, +1 thermal unit would produce 772 foot-pounds, or 772 +foot-pounds would raise 1 lb. of water 1° Fahr. But +there is never a complete conversion of any form of +energy. Common solid coal may be partly converted +into gases in a retort; but some of the carbon remains +unchanged, and more is dissipated but not lost. In +the same way, if I take five sovereigns to Paris and +convert them into francs, and return to London and +convert the francs into shillings, I shall not have 100 +shillings, but only perhaps 95 shillings. But the five +shillings have not been lost; three of them remain in +the French <i>change de monnaies</i>, and two of them in +the English exchange office. I may have forfeited +something, but the world has forfeited nothing. There +remains in it exactly the same number of sovereigns, +francs, and shillings as there was before I set out on +my travels. Nothing has been lost, but some of my +money has been "dissipated;" and the analogous case, +<a name="Page_8110" id="Page_8110"></a>"the dissipation of energy," has formed the subject of +more than one learned essay.</p> + +<p>Before the invention of the steam-engine, the only +powers employed in mechanics were those of wind and +water mills, and animal power. In the first two, no +conversion of one force into another took place; they +were mere kinematic devices for employing the +mechanical force already existing in the gale of wind +and the head of water. With regard to the power developed +by man and other animals, we had in them +examples of most efficient heat-engines, converting into +power a large percentage of the fuel burnt in the lungs. +But animal power is small in amount, and it is expensive +for two reasons—first, because the agents require +long intervals of rest, during which they still +burn fuel; and next, because the fuel they require is +very expensive. A pound of bread or beef, or oats or +beans, costs a great deal more than a pound of coal; +while it does not, by its combustion, generate nearly so +much heat. The steam-engine, therefore, took the +place of animal power, and for a long time stood alone; +and nearly all the motive power derived from heat is +still produced by the mechanism which Watt brought +to such great efficiency in so short a time.</p> + +<p>Now the practical question for all designers and employers +of heat-engines is to determine how the greatest +quantity of motive force can be developed from the +heat evolved from a given kind of fuel; and coal being +the cheapest of all, we will see what are the results +obtainable from it by the steam-engine. In this we +have three efficiencies to consider—those of the furnace, +the boiler, and the cylinder.</p> + +<p>First, with respect to the furnace. The object is to +combine the carbon and the hydrogen of the coal with a +sufficient quantity of the oxygen of the air to effect complete +combustion into carbonic acid and water. In order +to do this, we have to use a quantity of air much larger +than is theoretically necessary, and also to heat an +amount of inert nitrogen five times greater than the +necessary oxygen; and we are therefore obliged to +create a draught which carries away to the chimney a +considerable portion of the heat developed. The combustion, +moreover, is never perfect; and some heat is +lost by conduction and radiation. The principal loss is +by hot gases escaping from the flues to the chimney. +Even with well-set boilers, the temperature in the +chimney varies from 400° to 600° Fahr. Taking the +mean of 500°, this would represent a large proportion +of the total heat, even if the combustion were perfect; +for, as a general rule, the supply of air to a furnace is +double that which is theoretically necessary. For our +present purpose, it will be sufficient to see how much +the whole loss is, without dividing it under the several +heads of "imperfect combustion," "radiation," and +"convection," by the heated gases passing to the +chimney.</p> + +<p>With a very good boiler and furnace each pound of +coal evaporates 10 pounds of water from 62° Fahr., +changing it into steam of 65 lb. pressure at a temperature +of 312°, or 250° above that of the water from which +it is generated. Besides these 250°, each pound of steam +contains 894 units of latent heat, or 1,144 units in all. A +very good condensing engine will work with 2.2 lb. of +coal and 22 lb. of steam per horse power per hour. Now. +1 lb. of good coal will, by its combustion, produce +14,000 heat-units; and the 2.2 lb. of coal multiplied by +14,000 represent 30,800 θ. Of these we find in the boiler +22 × 1,144, or 25,168 units, or about 81½ per cent., of the +whole heat of combustion; so that the difference (5,632 +units, or 18½ per cent.) has been lost by imperfect combustion, +radiation, or convection. The water required +for condensing this quantity of steam is 550 lb.; and, +taking the temperature in the hot well as 102°, 550 lb. +have been raised 40° from 62°. Thus we account for +550 × 40 = 22,000, or (say) 71½ per cent. still remaining +as heat. If we add this 71½ per cent. to 18½ per cent. we have 90 +per cent., and there remain only 10 per cent. of the +heat that can possibly have been converted into power. +But some of this has been lost by radiation from steam-pipes, +cylinder, etc. Allowing but 1 per cent. for this, +we have only 9 per cent. as the efficiency of a really +good condensing engine. This estimate agrees very +closely with the actual result; for the 2.2 lb. of coal +would develop 30,800 θ; and this, multiplied by Joule's +equivalent, amounts to nearly 24 millions of foot-pounds. +As 1 horse power is a little less than 2 million +foot-pounds per hour, only one-twelfth, or a little more +than 8 per cent. of the total heat is converted; so that +whether we look at the total quantity of heat which +we show unconverted, or the total heat converted, we +find that each supplements and corroborates the other. +If we take the efficiency of the engine alone, without +considering the loss caused by the boiler, we find that +the 25,168 θ which entered the boiler should have given +19,429,696 foot-pounds; so that the 2 millions given by +the engine represent about 10 per cent. of the heat +which has left the boiler. The foregoing figures refer +to large stationary or marine engines, with first-rate +boilers. When, however, we come to high-pressure +engines of the best type, the consumption of coal is +twice as much; and for those of any ordinary type it is +usual to calculate 1 cubic foot, or 62½ lb., of water +evaporated per horse power. This would reduce the +efficiency to about 6 per cent. for the best, and 3 +per cent. for the ordinary non-condensing engines; and +if to this we add the inefficiency of some boilers, it is +certain that many small engines do not convert into +power more than 2 per cent. of the potential energy +contained in the coal.</p> + +<p>At one time the steam-engine was threatened with +serious rivalry by the hot-air engine. About the year 1816 +the Rev. Mr. Stirling, a Scotch clergyman, invented +one which a member of this Institute (Mr. George +Anderson) remembers to have seen still at work at +Dundee. The principle of it was that a quantity of air +under pressure was moved by a mass, called a "displacer," +from the cold to the hot end of a large vessel +which was heated by a fire beneath and cooled by a +current of water above. The same air was alternately +heated and cooled, expanded and contracted; and by +the difference of pressure moved the piston in a working +cylinder. In this arrangement the furnace was inefficient. +As only a small portion of heat reached the +compressed air, the loss by radiation was very great, +and the wear and tear exceedingly heavy. This system, +with some modifications, was revived by Rankine, +Ericsson, Laubereau, Ryder, Buckett, and Bailey. +Siemens employed a similar system, only substituting +steam for air. Another system, originally proposed by +Sir George Cayley, consisted in compressing by a pump +cold air which was subsequently passed partly through +a furnace, and, expanding, moved a larger piston at +the same pressure; and the difference of the areas of the +pistons multiplied by the pressure common to both represented +the indicated power. This principle was +subsequently developed by a very able mechanic, Mr. +Wenham; but his engine never came much into favor. +The only hot-air engines at present in use are Ryder's, +Buckett's, and Bailey's, employed to a limited extent +for small powers. I have not said anything of the +thermal principles involved in the construction of these +engines, as they are precisely the same as those affecting +the subject of the present paper.</p> + +<p>Before explaining the principle upon which the gas-engine +and every other hot-air engine depends, I shall +remind you of a few data with which most of you are +already familiar. The volume of every gas increases +with the temperature; and this increase was the basis +of the air thermometer—the first ever used. It is to be +regretted that it was not the foundation of all others; for +it is based on a physical principle universally applicable. +Although the volume increases with the temperature, +it does not increase in proportion to the +degrees of any ordinary scale, but much more slowly. +Now, if to each of the terms of an arithmetical series +we add the same number, the new series so formed increases +or decreases more slowly than the original; and +it was discovered that, by adding 461 to the degrees of +Fahrenheit's scale, the new scale so formed represented +exactly the increment of volume caused by increase of +temperature. This scale, proposed by Sir W. Thomson +in 1848, is called the "scale of absolute temperature." +Its zero, called the "absolute zero," is 461° below the +zero of Fahrenheit, or 493° below the freezing point of +water; and the degree of heat measured by it is termed +the "absolute temperature." It is often convenient to +refer to 39° Fahr. (which happens to be the point at +which water attains its maximum density), as this is +the same as 500° absolute; for, counting from this +datum level, a volume of air expands exactly 1 per +cent. for 5°, and would be doubled at 1,000° absolute, +or 539° Fahr.</p> + +<p>Whenever any body is compressed, its specific heat is +diminished; and the surplus portion is, as it were, +pushed out of the body—appearing as sensible heat. +And whenever any body is expanded, its specific heat +is increased; and the additional quantity of heat requisite +is, as it were, sucked in from surrounding bodies—so +producing cold. This action may be compared to +that of a wet sponge from which, when compressed, a +portion of the water is forced out, and when the sponge +is allowed to expand, the water is drawn back. This +effect is manifested by the increase of temperature in +air-compressing machines, and the cold produced by +allowing or forcing air to expand in air-cooling machines. +At 39° Fahr., 1 lb. of air measures 12½ cubic +feet. Let us suppose that 1 lb. of air at 39° Fahr. = +500° absolute, is contained in a non-conducting cylinder +of 1 foot area and 12½ feet deep under a counterpoised +piston. The pressure of the atmosphere on the piston += 144 square inches × 14.7 lb., or 2,116 lb. If the air +be now heated up to 539° Fahr. = 1,000° absolute, and +at the same time the piston is not allowed to move, the +pressure is doubled; and when the piston is released, it +would rise 12½ feet, provided that the temperature remained +constant, and the indicator would describe a +hyperbolic curve (called an "isothermal") because the +temperature would have remained equal throughout. +But, in fact, the temperature is lowered, because expansion +has taken place, and the indicator curve which +would then be described is called an "adiabatic curve," +which is more inclined to the horizontal line when the +volumes are represented by horizontal and the pressures +by vertical co-ordinates. In this case it is supposed +that there is no conduction or transmission (diabasis) +of heat through the sides of the containing vessel. If, +however, an <i>additional</i> quantity of heat be communicated +to the air, so as to maintain the temperature at +1,000° absolute, the piston will rise until it is 12½ feet +above its original position, and the indicator will describe +an isothermal curve. Now mark the difference. +When the piston was fixed, only a heating effect resulted; +but when the piston moved up 12½ feet, not +only a heating but a mechanical, in fact, a thermodynamic, +effect was produced, for the weight of the +atmosphere (2,116 lb.) was lifted 12½ feet = 26,450 foot-pounds.</p> + +<p>The specific heat of air at constant pressure has been +proved by the experiments of Regnault to be 0.2378, or +something less than one-fourth of that of water—a result +arrived at by Rankine from totally different data. +In the case we have taken, there have been expended +500 × 0.2378, or (say) 118.9 θ to produce 26,450 f.p. Each +unit has therefore produced 26,450 / 118.9 = 222.5 f.p., +instead of 772 f.p., which would have been rendered if +every unit had been converted into power. We therefore +conclude that 222.5 / 772 = 29 +per cent. of the total +heat has been converted. The residue, or 71 per cent., +remains unchanged as heat, and may be partly saved +by a regenerator, or applied to other purposes for +which a moderate heat is required.</p> + +<p>The quantity of heat necessary to raise the heat of +air at a constant volume is only 71 per cent. of that required +to raise to the same temperature the same +weight of air under constant pressure. This is exactly +the result which Laplace arrived at from observations +on the velocity of sound, and may be stated thus—</p> + + +<div class="center"> +<table border="0" cellpadding="0" cellspacing="6" summary=""> +<tr><td align='left'></td><td align="center">Specific<br />heat.</td><td align="center">Foot-<br />pounds.</td><td align="center">Per<br />cent.</td></tr> +<tr><td align='left'>K<sub>p</sub>= 1 lb. of air at constant pressure</td><td align="center">0.2378 × 772 =</td><td align="right">183.5 =</td><td align="right">100</td></tr> +<tr><td align='left'>K<sub>v</sub>= 1 lb. of air at constant volume</td><td align="center">0.1688 × 772 =</td><td align="right">130.3 =</td><td align="right">71</td></tr> +<tr><td align='left'>Difference, being heat converted into power</td><td align="center"><span class="over">0.0690 × 772</span> =</td><td align="right"><span class="over">53.2</span> =</td><td align="right"><span class="over">29</span></td></tr> +</table></div> + +<p>Or, in a hot-air engine without regeneration, the +maximum effect of 1 lb. of air heated 1° Fahr. would be +53.2 f.p. The quantity of heat K<sub>y</sub> necessary to heat air +under constant volume is to K<sub>v</sub>, or that necessary to +heat it under constant pressure, as 71:100, or as 1:1.408, +or very nearly as 1:√2—a result which was arrived +at by Masson from theoretical considerations. +The 71 per cent. escaping as heat may be utilized in +place of other fuel; and with the first hot-air engine I +ever saw, it was employed for drying blocks of wood. +In the same way, the unconverted heat of the exhaust +steam from a high-pressure engine, or the heated gases +and water passing away from a gas-engine, may be employed.</p> + +<div class="figright"><a href="./images/8.png"><img src="./images/8_th.png" alt="" /></a></div> + +<p>We are now in a position to judge what is the practical +efficiency of the gas-engine. Some years since, in +a letter which I addressed to <i>Engineering</i>, and which +also appeared in the <i>Journal of Gas Lighting</i>,<a name="FNanchor_4" id="FNanchor_4"></a><a href="#Footnote_4"><sup>2</sup></a> I +showed (I believe for the first time) that, in the Otto-Crossley +engine, 18 per cent. of the total heat was converted +into power, as against the 8 per cent. given by +a very good steam-engine. About the end of 1883 a +very elaborate essay, by M. Witz, appeared in the +<i>Annales de Chimie et de Physique</i>, reporting experiments +on a similar engine, which gave an efficiency +somewhat lower. Early in 1884 there appeared in <i>Van +Nostrand's Engineering Magazine</i> a most valuable +paper, by Messrs. Brooks and Steward, with a preface +by Professor Thurston,<a name="FNanchor_5" id="FNanchor_5"></a><a href="#Footnote_5"><sup>3</sup></a> in which the efficiency was +estimated at 17 to 18 per cent. of the total heat of combustion. +Both these papers show what I had no +opportunity of ascertaining, that is, what becomes of +the 82 per cent. of heat which is not utilized—information +of the greatest importance, as it indicates in what +direction improvement may be sought for, and how +loss may be avoided. But, short as is the time that +has elapsed since the appearance of these papers, you +will find that progress has been made, and that a still +higher efficiency is now claimed.</p> + +<p>When I first wrote on this subject, I relied upon +some data which led me to suppose that the heating +power of ordinary coal gas was higher than it really +is. At our last meeting, Mr. Hartley proved, by experiments +with his calorimeter, that gas of 16 or 17 candles +gave only about 630 units of heat per cubic foot. +Now, if all this heat could be converted into power, it +would yield 630 × 772, or 486,360 f.p.; and it would +require only 1,980,000 / 486,360 = 4.07 cubic feet to produce 1 +indicated horse power. Some recent tests have shown +that, with gas of similar heating power, 18 cubic feet +have given 1 indicated horse power, and therefore 4.07 / 18 = 22.6 +of the whole heat has been converted—a truly +wonderful proportion when compared with steam-engines +of a similar power, showing only an efficiency +of 2 to 4 per cent.</p> + +<p>The first gas-engine which came into practical use +was Lenoir's, invented about 1866, in which the mixture +of gas and air drawn in for part of the stroke at +atmospheric pressure was inflamed by the spark from +an induction coil. This required a couple of cells of a +strong Bunsen battery, was apt to miss fire, and used +about 90 cubic feet of gas per horse power. This was +succeeded by Hugon's engine, in which the ignition +was caused by a small gas flame, and the consumption +was reduced to 80 cubic feet. In 1864 Otto's atmospheric +engine was invented, in which a heavily-loaded +piston was forced upward by an explosion of gas and +air drawn in at atmospheric pressure. In its upward +stroke the piston was free to move; but in its downward +stroke it was connected with a ratchet, and the +partial vacuum formed after the explosion beneath the +piston, together with its own weight in falling, operated +through a rack, and caused rotation of the flywheel. +This engine (which, in an improved form, uses +only about 20 cubic feet of gas) is still largely employed, +some 1,600 having been constructed. The great objection +to it was the noise it produced, and the wear and +tear of the ratchet and rack arrangements. In 1876 the +Otto-Crossley silent engine was introduced. As you +are aware, it is a single-acting engine, in which the gas +and air are drawn in by the first outward, and compressed +by the first inward stroke. The compressed +mixture is then ignited; and, being expanded by heat, +drives the piston outward by the second outward +stroke. Near the end of this stroke the exhaust-valve +is opened, the products of combustion partly escape, +and are partly driven out by the second inward stroke. +I say partly, for a considerable clearance space, equal +to 38 per cent. of the whole cylinder volume, remains +unexhausted at the inner end of the cylinder. When +working to full power, only one stroke out of every +four is effective; but this engine works with only 18 +<a name="Page_8111" id="Page_8111"></a>to 22 cubic feet of gas per horse power. Up to the present +time I am informed that about 18,000 of these +engines have been manufactured. Several other compression +engines have been introduced, of which the +best known is Mr. Dugald Clerk's, using about 20 feet +of Glasgow cannel gas. It gives one effective stroke +for every revolution; the mixture being compressed +in a separate air-pump. But this arrangement leads +to additional friction; and the power measured by the +brake is a smaller percentage of the indicated horse +power than in the Otto-Crossley engine. A number of +gas engines—such as Bisschop's (much used for very +small powers), Robson's (at present undergoing transformation +in the able hands of Messrs. Tangye), Korting's, +and others—are in use; but, so far as I can +learn, all require a larger quantity of gas than those +previously referred to.</p> + +<div class="figcenter"><img src="./images/9a.png" alt="OTTO ATMOSPHERIC GAS ENGINE." /> +<br /> OTTO ATMOSPHERIC GAS ENGINE.</div> + +<div class="figcenter"><img src="./images/9b.png" alt="CLERCK'S GAS ENGINE, 6 HORSE POWER." /> +<br /> CLERCK'S GAS ENGINE, 6 HORSE POWER.</div> + +<div class="figcenter"><img src="./images/9c.png" alt="OTTO-CROSSLEY GAS ENGINE, 16 H.P." /> +<span class="longcaption">OTTO-CROSSLEY GAS ENGINE, 16 H.P. +<br />Consumption 17.6 cubic feet of 16-candle gas per theoretical horse +power per hour.<br /> +Average pressure, 90.4 × constant, .568 theoretical horse power per +pound = 50.8 theoretical horse power.</span></div> + +<div class="figcenter"><img src="./images/9d.png" alt="ATKINSON'S DIFFERENTIAL GAS ENGINE, 8 H.P." /> +<br /> ATKINSON'S DIFFERENTIAL GAS ENGINE, 8 H.P.</div> + +<p>I have all along spoken of efficiency as a percentage +of the total quantity of heat evolved by the fuel; and +this is, in the eyes of a manufacturer, the essential +question. Other things being equal, that engine is the +most economical which requires the smallest quantity +of coal or of gas. But men of science often employ the +term efficiency in another sense, which I will explain. +If I wind a clock, I have spent a certain amount of +energy lifting the weight. This is called "energy of +position;" and it is returned by the fall of the weight +to its original level. In the same way if I heat air or +water, I communicate to it energy of heat, which +remains potential as long as the temperature does not +fall, but which can be spent again by a decrease of +temperature. In every heat-engine, therefore, there +must be a fall from a higher to a lower temperature; +otherwise no work would be done. If the water in the +condenser of a steam-engine were as hot as that in the +boiler, there would be equal pressure on both sides of +the piston, and consequently the engine would remain +at rest. Now, the greater the fall, the greater the +power developed; for a smaller proportion of the heat +remains as heat. If we call the higher temperature T +and the lower T' on the absolute scale, T - T' is the +difference; and the ratio of this to the higher temperature +is called the "efficiency." This is the foundation +of the formula we meet so often: E = (T - T')/T. A perfect +heat-engine would, therefore, be one in which the +temperature of the absolute zero would be attained, +for (T - O)/T = 1. This low temperature, however, has +never been reached, and in all practical cases we are +confined within much narrower limits. Taking the +case of the condensing engine, the limits were 312° to +102°, or 773° and 563° absolute, respectively. The equation +then becomes (773 - 563)/773 = 210 / 773 or (say) 27 per cent. +With non-condensing engines, the temperatures may +be taken as 312° and 212°, or 773° and 673° absolute +respectively. The equation then becomes (773 - 673)/773 = +100 / 773, or nearly 13 per cent. The practical efficiencies +are not nearly this, but they are in about the same +ratio—27/13. If, then, we multiply the theoretical efficiencies +by 0.37, we get the practical efficiencies, say 10 +per cent. and 5 per cent.; and it is in the former sense +that M. Witz calculated the efficiency of the steam-engine +at 35 per cent.—a statement which, I own, puzzled +me a little when I first met it. These efficiencies +do not take any account of loss of heat before the +boiler. In the case of the gas-engine, the question is +much more complicated on account of the large clearance +space and the early opening of the exhaust. The +highest temperature has been calculated by the American +observers at 3,443° absolute, and the observed temperature +of the exhaust gases was 1,229°. The fraction +then becomes (3443 - 1229)/3443 = 64 per cent. If we multiply +this by 0.37, as we did in the case of the steam-engine, +we get 23.7 per cent., or approximately the +same as that arrived at by direct experience. Indeed, +if the consumption is, as sometimes stated, less than 18 +feet, the two percentages would be exactly the same. +I do not put this forward as scientifically true; but the +coincidence is at least striking.</p> + +<p>I have spoken of the illuminating power of the gas +as of importance; for the richer gases have also more +calorific power, and an engine would, of course, require +a smaller quantity of them. The heat-giving power +does not, however, vary as the illuminating power, but +at a much slower rate; and, adopting the same contrivance +as that on which the absolute scale of temperature +is formed, I would suggest a formula of the +following type: H = C (I + K), in which H represents +the number of heat-units given out by the combustion +of 1 cubic foot of gas, I is the illuminating power in +candles, and C and K two constants to be determined +by experiment. If we take the value for motive power +of the different qualities of gas as given in Mr. Charles +Hunt's interesting paper in our Transactions for 1882, +C might without any great error be taken as 22 and K +as 7.5. With Pintsch's oil gas, however, as compared +with coal gas, this formula does not hold; and C +should be taken much lower, and K much higher than +the figures given above. That is to say, the heating +power increases in a slower progression. The data +available, however, are few; but I trust that Mr. Hartley +will on this, as he has done on so many other scientific +subjects, come to our aid.</p> + +<p>I will now refer to the valuable experiments of +Messrs. Brooks and Steward, which were most carefully +made. Everything was measured—the gas by a +60 light, and the air by a 300 light meter; the indicated +horse power, by a steam-engine indicator; the +useful work, by a Prony brake; the temperature of +the water, by a standard thermometer; and that of +the escaping gases, by a pyrometer. The gas itself was +analyzed; and its heating power calculated, from its +composition, as 617.5θ. Its specific gravity was .464; +and the volume of air was about seven times that of +the gas used (or one-eighth of the mixture), and was +only 11½ per cent. by weight more than was needed +for perfect combustion. The results arrived at were as +follows:</p> + + + +<div class="center"> +<table border="0" cellpadding="4" cellspacing="0" summary=""> +<tr><td align='left'></td><td align="right">Per cent.</td></tr> +<tr><td align='left'>Converted into indicated horse power, including friction, etc.</td><td align="right">17.0</td></tr> +<tr><td align='left'>Escaped with the exhaust gas.</td><td align="right">15.5</td></tr> +<tr><td align='left'>Escaped in radiation.</td><td align="right">15.5</td></tr> +<tr><td align='left'>Communicated to water in the jacket.</td><td align="right">52.0</td></tr> +</table></div> + +<p>It will thus be seen that more than half of the heat +is communicated to the water in the jacket. Now, this +is the opposite of the steam-engine, where the jacket +is used to transmit heat <i>to</i> the cylinder, and not <i>from</i> +it. This cooling is rendered necessary, because without +it the oil would be carbonized, and lubrication of +the cylinder rendered impossible. Indeed, a similar +difficulty has occurred with all hot-air engines, and is, +I think, the reason they have not been more generally +adopted. I felt this so strongly that, for some time +after the introduction of the gas-engine, I was very +cautious in recommending those who consulted me to +adopt it. I was afraid that the wear and tear would +be excessive. I have, however, for some time past been +thoroughly satisfied that this fear was needless; as I +am satisfied that a well-made gas-engine is as durable +as a steam-engine, and the parts subject to wear can +be replaced at moderate cost. We have no boiler, no +feed pump, no stuffing-boxes to attend to—no water-gauges, +pressure-gauges, safety-valve, or throttle-valve +to be looked after; the governor is of a very simple +construction; and the slide-valves may be removed +and replaced in a few minutes. An occasional cleaning +out of the cylinder at considerable intervals is all +the supervision that the engine requires.</p> + +<p>The very large percentage of heat absorbed by the +water-jacket should point out to the ingenuity of inventors +the first problem to be attacked, viz., how to +save this heat without wasting the lubricant or making +it inoperative; and in the solution of this problem, +I look for the most important improvement to be expected +in the engine. The most obvious contrivance +would be some sort of intercepting shield, which would +save the walls of the cylinder and the rings of the piston +from the heat of the ignited gases. I have just +learned that something of the kind is under trial. +Another solution may possibly be found in the employment +of a fluid piston; but here we are placed in a +dilemma between the liquids that are decomposed and +the metals that are oxidized at high temperatures. +Next, the loss by radiation—15 per cent.—seems large; +but this is to be attributed to the fact that the inside +surface of the cylinder is at each inward stroke exposed +to the atmosphere—an influence which contributes to +the cooling necessary for lubrication. The remaining +15 per cent., which is carried away by the exhaust, is +small compared with the proportion passing away with +the exhaust steam of a high-pressure or the water of a +condensing engine. As the water in the jacket can be +safely raised to 212° Fahr., the whole of the jacket heat +can be utilized where hot water is required for other +purposes; and this, with the exhaust gases, has been +used for drying and heating purposes.</p> + +<p>With such advantages, it may be asked: Why does +not the gas-engine everywhere supersede the steam-engine? +My answer is a simple one: The gas we +manufacture is a dear fuel compared with coal. Ordinary +coal gas measures 30 cubic feet to the pound; and +1,000 cubic feet, therefore, weigh 33 lb. Taking the +price at 2s. 9d. per 1,000 cubic feet, it costs 1d. per lb. +The 30 cubic feet at 630θ give 19,000θ all available heat. +Although good coal may yield 14,000 units by its combustion, +only about 11,000 of these reach the boiler; so +that the ratio of the useful heat is 11/19. The thermal efficiency +of the best non-condensing engine to that of +the gas-engine is in the ratio 4/22. Multiplying together +these two ratios, we get (11 / 19)×(4 / 22<sub>½</sub>) = 44 / 4.28. That is, speaking +roughly, 1 lb. of gas gives about ten times as much +power as 1 lb. of coal does in a good non-condensing +engine. But at 18s. 8d. a ton we get 10 lb. of coal for +1d.; so that with these figures the cheapness of the +coal would just compensate for the efficiency of the +gas. As to the waste heat passing away from the +engine being utilized, here the gas-engine has no advantage; +and, so far as this is concerned, the gas is about +eight times dearer than coal. The prices of gas and +coal vary so much in different places that it is hard to +determine in what cases gas or coal will be the dearer +fuel, considering this point alone.</p> + +<p>But there are other kinds of non-illuminating gases—such +as Wilson's, Strong's, and Dowson's—which are now +coming into use; and at Messrs. Crossley's works you +will have an opportunity of seeing a large engineering +factory employing several hundred mechanics, and +without a chimney, in which every shaft and tool is +driven by gas-engines supplied by Dowson's gas, and +in which the consumption of coal is only 1.2 lb. per +indicated horse power. The greatest economy ever +claimed for the steam-engine was a consumption of 1.6 +lb.; and this with steam of very high pressure, expanded +in three cylinders successively. Thus in a quarter +of a century the gas-engine has beaten in the race the +steam-engine; although from Watt's first idea of +improvement, nearly a century and a quarter have +elapsed.</p> + +<p>As regards the steam-engine, it is the opinion of competent +authorities that the limits of temperature between +which it works are so restricted, and so much +of the heat is expended in producing a change of state +from liquid to vapor, that little further improvement +can be made. With respect to gas-engines, the limits +of temperature are much further apart. A change of +state is not required, and so very great improvement +may still be looked for. It is not impossible even that +some of the younger members of our body may live to +see that period foretold by one of the greatest of our +civil engineers—that happy time when boiler explosions +will only be matters of history; that period, not a +millennium removed by a thousand years, but an era +deferred perhaps by only half a dozen decades, when +the use of the gas-engine will be universal, and "a +steam-engine can be found only in a cabinet of antiquities."</p> + +<div class="center"><i>Discussion.</i></div> + +<p>The President said this was a very delightful paper; +and nothing could be finer than Mr. Lane's description +of the conversion of heat into power, and the gradual +growth of theory into practical work.</p> + +<p>Mr. W. Foulis (Glasgow) agreed that it was admirable; +but it required to be read to be thoroughly appreciated. +When members were able to read it, they +would find Mr. Lane had given a very clear description +of the elementary principles of thermo-dynamics in their +relation to the gas-engine and the steam-engine. There +was very little in the paper to raise discussion; but +Mr. Lane had made exceedingly clear how the present +loss in a gas-engine was occasioned, and had also shown +how, in the future development of the engine, the loss +might be saved, and the engine rendered more efficient.</p> + +<p>Mr. H.P. Holt (of Messrs. Crossley Bros., Limited) +said he could indorse everything Mr. Lane had said. +He had found the paper most interesting and instructive +even to himself, though he had some little practical +experience of gas-engines, and was supposed to +know a little about them. He did not pretend to be +able to teach other people; but if he could say anything +as to indicator cards, or answer any questions, +he should be happy to do so. (He then described the +indicator diagram of the atmospheric gas-engine.) In +this engine the proportion of the charging stroke to +the whole sweep of the piston was about 10 per cent.; +and as the charge drawn in consisted of about 10 per +cent. of gas, about 1-100 of the total sweep of the piston +was composed of the gas.</p> + +<p>Mr. Foulis asked what proportion the power indicated +on the diagram bore to the power indicated on the +brake in the atmospheric engine.</p> + +<p>Mr. Holt said unfortunately he had not any figures +with him which would give this information; and it +was so long since he had anything practically to do +with this form of engine, that he should not like to +speak from memory. He might add that the largest +size of gas-engine made (of about 100 horse power indicated) +was at work at Messrs. Edwin Butterworth +and Co.'s, of Manchester. It was now driven by ordinary +coal gas; but Dowson plant was to be put up +very shortly in order to reduce the cost of working, +which, though not excessive, would be still more +economical with the Dowson gas—probably only about +30s. per week. The present cost was about £4 per week, +though it was not working always at full power.</p> + +<p>Mr. T. Holgate (Batley) said he thought it was generally +understood, by those who had studied the subject, +that the adoption of compression of the gaseous mixture +before ignition had, so far, more than anything else, +contributed to the improved working of gas-engines. +This fact had not been sufficiently brought out in the +paper, although Mr. Lane had clearly indicated some +<a name="Page_8112" id="Page_8112"></a>of the directions in which further improvements were +likely to obtain. Gas engineers were largely indebted +to Mr. Dugald Clerk for the statement he had made of +the theory of the gas-engine.<a name="FNanchor_6" id="FNanchor_6"></a><a href="#Footnote_6"><sup>4</sup></a> Mr. Lane had given +some figures, arrived at by Messrs. Brooks and Steward, +from experiments made in America; but, prior to these +Mr. Clerk had given others which were in the main in +accordance with them. Professor Kennedy had also +made experiments, the results of which agreed with +them.<a name="FNanchor_7" id="FNanchor_7"></a><a href="#Footnote_7"><sup>5</sup></a> The extent of the loss by the cooling water +was thus well ascertained; and it was no doubt by a +reduction of this loss that further improvement in +the working of gas-engines would eventually be +obtained.</p> + +<p>Mr. J. Paterson (Warrington) expressed his appreciation +of the paper, as one of exceptional interest and +value. He said he did not rise with a view to make +any observations thereon. The analysis of first principles +required more matured consideration and thought +than could be given to it here. The opinion, however, he +had formed of the paper placed it beyond the reach of +criticism. It was now many years since his attention +had been drawn to the name of Denny Lane; and +everything that had come from his facile pen conveyed +sound scientific conclusions. The paper to which they +had just listened was no exception. It was invested with +great interest, and would be regarded as a valuable +contribution to the Transactions of the Institute.</p> + +<p>Mr. Lane, in reply, thanked the members for the +kind expressions used with respect to his paper. His +object in writing it was that any one who had not +paid any attention to the subject before should be able +to understand thoroughly the principles on which gas +and hot-air engines operated; and he believed any one +who read it with moderate care would perfectly understand +all the essential conditions of the gas-engine. +He might mention that not long after the thermo-dynamic +theory was so far developed as to determine +the amount of heat converted into power, a very +eminent French Engineer—M. Hirn—conducted some +experiments on steam-engines at a large factory, and +thought he could account for the whole heat of combustion +in the condensed water and the heat which +passed away; so much so that he actually doubted +altogether the theory of thermo-dynamics. However, +being open to conviction, he made further experiments, +and discovered that he had been in error, and ultimately +became one of the most energetic supporters of the +theory. This showed how necessary it was to be careful +before arriving at a conclusion on such a subject. +He had endeavored, as far as the nature of the case +allowed, to avoid any scientific abstractions, because +he knew that when practical men came to theory—<i>x's</i> +and <i>y's</i>, differentials, integrals, and other mathematical +formulæ—they were apt to be terrified.</p> + +<p>The President said it was like coming down to +every day life to say that it was important that gas +managers should be familiar with the appliances used +in the consumption of gas, and should be able, when +called upon, to give an intelligent description of their +method of working. A study of Mr. Lane's paper would +reveal many matters of interest with regard to this +wonderful motor, which was coming daily more and +more into use, not only to the advantage of gas manufacturers, +but of those who employed them.</p> + + +<p><a name="Footnote_3" id="Footnote_3"></a><a href="#FNanchor_3">[1]</a></p><div class="note"><p>A paper read before the Gas Institute, Manchester, June, 1885.</p></div> + +<p><a name="Footnote_4" id="Footnote_4"></a><a href="#FNanchor_4">[2]</a></p><div class="note"><p>See <i>Journal</i>, vol. xxxv, pp. 91, 133.</p></div> + +<p><a name="Footnote_5" id="Footnote_5"></a><a href="#FNanchor_5">[3]</a></p><div class="note"><p>Ibid., vol. xliii., pp. 703, 744.</p></div> + +<p><a name="Footnote_6" id="Footnote_6"></a><a href="#FNanchor_6">[4]</a></p><div class="note"><p>See Journal, vol. xxxix., p. 648.</p></div> + +<p><a name="Footnote_7" id="Footnote_7"></a><a href="#FNanchor_7">[5]</a></p><div class="note"><p>Ibid., vol. xl., p. 955.</p></div> + +<hr /> + +<h2><a name="art11" id="art11"></a>M. MEIZEL'S RECIPROCATING EXHAUSTER.</h2> + +<p>At the recent Congress of the Societe Technique de +l'Industrie du Gaz en France, M. Meizel, Chief Engineer +of the St. Etienne Gas Works, described a new exhauster +devised by him on the reciprocating principle, +and for which he claims certain advantages over the +appliances now in general use. Exhausters constructed +on the above-named principle have hitherto, +M. Meizel says, been costly to fit up, owing to the +necessity for providing machinery and special mechanism +for the transmission of motion. This has prevented +the employment of cylinders of large dimensions; +and, consequently, when the quantity of gas to +be dealt with has been considerable, the number of +exhausters has had to be increased. The result of this +has been inconvenience, which has led to a preference +being shown for other kinds of exhausters, notwithstanding +the manifest advantages which, in M. Meizel's +opinion, those of the reciprocating type possess. The +improvement which he has effected in these appliances +consists in the application to them of cylinders working +automatically; and the general features of the +arrangement are shown in the accompanying illustrations.</p> + +<div class="figcenter"><a href="./images/10a.png"> +<img src="./images/10a_th.png" alt="IMPROVED RECIPROCATING GAS EXHAUSTER." /></a> +<br /> IMPROVED RECIPROCATING GAS EXHAUSTER.</div> + +<p>The principal advantages to be gained by the use of +this exhauster are stated by M. Meizel to be the following: +Considerably less motive force is necessary +than is the case with other exhausters, which require +steam engines and all the auxiliary mechanism for the +transmission of power. By its quiet and regular action, +it prevents oscillation and unsteadiness in the flow of +gas in the hydraulic main, as well as in the pipes leading +therefrom—a defect which has been found to exist +with other exhausters. The bells, being of large area, +serve the purpose of a condenser; and as, owing to its +density, the tar falls to the bottom of the lower vessels, +which are filled with water, contact between the gas +and tar is avoided. Although the appliance is of substantial +construction, its action is so sensitive that it +readily adapts itself to the requirements of production. +It may be placed in the open air; and therefore its +establishment is attended with less outlay than is the +case with other exhausters, which have to be placed +under cover, and provided with driving machinery +and, of course, a supply of steam.</p> + +<p>The total superficial area of the exhauster above +described, including the governor, is 150 square feet; +and its capacity per 24 hours is 230,000 cubic feet. It +works silently, with an almost entire absence of friction; +and consequently there are few parts which +require lubrication. Exhausters of this type (which, +M. Meizel says, could be made available for ventilation +purposes, in case of necessity) may be constructed of +all sizes, from 500 cubic feet per hour upward.</p> + +<hr /> + +<h2><a name="art12" id="art12"></a>AUTOMATIC SIPHON FOR IRRIGATION.</h2> + +<p>When, at an elevated point in a meadow, there +exists a spring or vein of water that cannot be utilized +at a distance, either because the supply is not sufficient, +or because of the permeability of the soil, it becomes +very advantageous to accumulate the water in a reservoir, +which may be emptied from time to time +through an aperture large enough to allow the water +to flow in abundance over all parts of the field.</p> + +<div class="figcenter"><img src="./images/10b.png" alt="GIRAL'S AUTOMATIC SIPHON." /> +<br /> GIRAL'S AUTOMATIC SIPHON.</div> + +<p>The storing up of the water permits of irrigating a +much greater area of land, and has the advantage of +allowing the watering to be effected intermittingly, +this being better than if it were done continuously. +But this mode of irrigating requires assiduous attention. +It is necessary, in fact, when the reservoir is full, to go +and raise the plug, wait till the water has flowed out, +and then put in the plug again as accurately as possible—a +thing that it is not always easy to do. The work +is a continuous piece of drudgery, and takes just as +much the longer to do in proportion as the reservoir is +more distant from one's dwelling. In order to do away +with this inconvenience, Mr. Giral, of Langogne +(Lozere), has invented a sort of movable siphon that +primes itself automatically, however small be the spring +that feeds the reservoir in which it is placed. The apparatus +(see figure) consists of an elbowed pipe, C A B D E, +of galvanized iron, whose extremity, C, communicates +with the outlet, R, where it is fixed by means of a +piece of rubber of peculiar form that allows the other +extremity, B D E, to revolve around the axis, K, while +at the same time keeping the outlet pipe hermetically +closed. This rubber, whose lower extremity is bent +back like the bell of a trumpet, forms a washer against +which there is applied a galvanized iron ring that is +fixed to the mouth of the outlet pipe by means of six +small screws. This ring is provided with two studs +which engage with two flexible thimbles, K and L, +that are affixed to the siphon by four rivets. These +studs and thimbles, as well as the screws, are likewise +galvanized. Between the branches, A B D E, of the +pipe there is soldered a sheet of galvanized iron, which +forms isolatedly a receptacle or air-chamber, F, that +contains at its upper part a small aperture, <i>b</i>, that remains +always open, and, at its lower part, a copper +screw-plug, <i>d</i>, and a galvanized hook, H.</p> + +<p>In the interior of this chamber there is arranged a +small leaden siphon, <i>a b c</i>, whose longer leg, <i>a</i>, passes +through the bottom, where it is soldered, and whose +shorter one, <i>c</i>, ends in close proximity to the bottom. +Finally, a galvanized iron chain, G H, fixed at G to the +bottom of the reservoir, and provided with a weight, +P, of galvanized iron, is hooked at H to the siphon and +allows it to rise more or less, according as it is given a +greater or less length.</p> + +<p>From what precedes, it will be seen that the outlet is +entirely closed, so that, in order that the water may +escape, it must pass into the pipe in the direction, E D B A C.</p> + +<p>This granted, let us see how the apparatus works: +In measure as the water rises in the reservoir, the +siphon gradually loses weight, and its extremity, B D H, +is finally lifted by the thrust, so that the entire +affair revolves upon the studs, K, until the chain +becomes taut. The apparatus then ceases to rise; but +the water, ever continuing to rise, finally reaches the +apex, <i>b</i>, of the smaller siphon, and, through it, enters +the air chamber and fills it. The equilibrium being +thus broken, the siphon descends to the bottom, becomes +primed, and empties the reservoir. When the +level of the water, in descending, is at the height of the +small siphon, <i>a b c</i>, this latter, which is also primed, +empties the chamber, F, in turn, so that, at the moment +the large siphon loses its priming, the entire apparatus +is in the same state that it was at first.</p> + +<p>In short, when the water enters the reservoir, the +siphon, movable upon its base, rises to the height at +which it is desired that the flow shall take place. Being +arrested at this point by the chain, it becomes +primed, and sinks, and the water escapes. When +the water is exhausted, the siphon rises anew in order +to again sink; and this goes on as long as the period of +irrigation lasts.</p> + +<p>This apparatus, which is simple in its operation, and +not very costly, is being employed with success for irrigating +several meadows in the upper basin of the +Allier.—<i>Le Genie Civil.</i></p> + +<hr /> + +<h2><a name="art07" id="art07"></a>ASSAY OF EARTHENWARE GLAZE.</h2> + +<p>Lead oxide melted or incompletely vitrified is still in +common use in the manufacture of inferior earthenware, +and sometimes leads to serious results. To detect +lead in a glaze, M. Herbelin moistens a slip of white +linen or cotton, free from starch, with nitric acid at 10 +per cent. and rubs it for ten to fifteen seconds on the +side of the utensil under examination, and then deposits +a drop of a solution of potassium iodide, at 5 per +cent. on the part which has been in contact. A lead +glaze simply fused gives a very highly colored yellow +spot of potassium iodide; a lead glaze incompletely +vitrified gives spots the more decided, the less perfect +the vitrification; and a glaze of good quality gives no +sensible color at all.—<i>M. Herbelin.</i></p> + +<hr /> + +<h2><a name="art02" id="art02"></a>ON THE ELECTRICAL FURNACE AND THE REDUCTION OF +THE OXIDES OF BORON, SILICON, ALUMINUM, AND OTHER METALS +BY CARBON.<a name="FNanchor_8" id="FNanchor_8"></a><a href="#Footnote_8"><sup>1</sup></a></h2> + +<h3>By <span class="smcap">Eugene H. Cowles, Alfred H. Cowles, and +Charles F. Mabery.</span></h3> + +<p>The application of electricity to metallurgical processes +has hitherto been confined to the reduction of +metals from solutions, and few attempts have been +made to effect dry reductions by means of an electric +current. Sir W. Siemens attempted to utilize the intense +heat of an electric arc for this purpose, but accomplished +little beyond fusing several pounds of +steel. A short time since, Eugene H. Cowles and Alfred +H. Cowles of Cleveland conceived the idea of obtaining +a continuous high temperature on an extended scale by +introducing into the path of an electric current some +material that would afford the requisite resistance, +thereby producing a corresponding increase in the temperature. +After numerous experiments that need not +be described in detail, coarsely pulverized carbon was +selected as the best means for maintaining a variable +resistance and at the same time as the most available +substance for the reduction of oxides. When this material, +mixed with the oxide to be reduced, was made a +part of the electric circuit in a fire clay retort, and submitted +to the action of a current from a powerful dynamo +machine, not only was the oxide reduced, but +the temperature increased to such an extent that the +whole interior of the retort fused completely. In other +experiments lumps of lime, sand, and corundum were +fused, with indications of a reduction of the corresponding +metal; on cooling, the lime formed large, well-defined +crystals, the corundum beautiful red, green, +and blue hexagonal crystals.</p> + +<p><a name="Page_8113" id="Page_8113"></a>Following up these results with the assistance of +Charles F. Mabery, professor of chemistry in the Case +School of Applied Science, who became interested at +this stage of the experiments, it was soon found that +the intense heat thus produced could be utilized for +the reduction of oxides in large quantities, and experiments +were next tried on a large scale with a current +from two dynamos driven by an equivalent of fifty +horse power. For the protection of the walls of the +furnace, which were made of fire brick, a mixture of the +ore and coarsely pulverized gas carbon was made a +central core, and it was surrounded on the sides and +bottom by fine charcoal, the current following the lesser +resistance of the central core from carbon electrodes +which were inserted at the ends of the furnace in contact +with the core. In order to protect the machines +from the variable resistance within the furnace, a resistance +box consisting of a coil of German silver wire +placed in a large tank of water was introduced into the +main circuit, and a Brush ammeter was also attached +by means of a shunt circuit, to indicate the quantity of +current that was being absorbed in the furnace. The +latter was charged by first filling it with charcoal, +making a trough in the center, and filling this central +space with the ore mixture, which was covered with a +layer of coarse charcoal. The furnace was closed at the +top with fire brick slabs containing two or three holes +for the escape of the gaseous products of the reduction, +and the entire furnace made air-tight by luting with +fire clay. Within a few minutes after starting the dynamo, +a stream of carbonic oxide issued through the +openings, burning usually with a flame eighteen inches +in height. The time required for complete reduction +was ordinarily about an hour.</p> + +<p>The furnace at present in use is charged in substantially +the same manner, and the current is supplied by +a Brush machine of variable electromotive force driven +by an equivalent of forty horse power. A Brush machine +capable of utilizing 125 horse power, or two and +one-half times as large as any hitherto constructed by +the Brush Electric Company, is being made for the +Cowles Electric Smelting and Aluminum Company, +and this machine will soon be in operation. Experiments +already made so that aluminum, silicon, +boron, manganese, magnesium, sodium and potassium +can be reduced from their oxides with ease. In fact, +there is no oxide that can withstand temperatures attainable +in this electrical furnace. Charcoal is changed +to graphite. Does this indicate fusion or solution of +carbon? As to what can be accomplished by converting +enormous electrical energy into heat within a limited +space, it can only be said that it opens the way into an +extensive field for both pure and applied chemistry. +It is not difficult to conceive of temperatures limited +only by the capability of carbon to resist fusion. The +results to be obtained with the large Brush machine +above mentioned will be of some importance in this +direction.</p> + +<p>Since the cost of the motive power is the chief expense +in accomplishing reductions by this method, its +commercial success is closely connected with the +cheapest form of power to be obtained. Realizing the +importance of this point, the Cowles Electric Smelting +and Aluminum Company has purchased an extensive +and reliable water power, and works are soon to be +erected for the utilization of 1,200 horse power. An +important feature in the use of these furnaces, from a +commercial standpoint, is the slight technical skill required +in their manipulation. The four furnaces in +operation in the experimental laboratory at Cleveland +are in charge of two young men twenty years of age, +who, six months ago, knew absolutely nothing of electricity. +The products at present manufactured are the +various grades of aluminum bronze made from a rich +furnace product that is obtained by adding copper to +the charge of ore, silicon bronze prepared in the same +manner, and aluminum silver, an alloy of aluminum +with several other metals. A boron bronze may be +prepared by the reduction of boracic acid in contact +with copper.</p> + +<p>As commercial results may be mentioned the production +in the experimental laboratory, which averages +fifty pounds of 10 per cent. aluminum bronze daily, and +it can be supplied to the trade in large quantities at +prices based on $5 per pound for the aluminum contained, +the lowest market quotation of this metal being +at present $15 per pound. Silicon bronze can be furnished +at prices far below those of the French manufacturers.</p> + +<p>The alloys which the metals obtained by the +methods above described form with copper have been +made the subject of careful study. An alloy containing +10 per cent. of aluminum and 90 per cent. of copper +forms the so-called aluminum bronze with a fine golden +color, which it retains for a long time. The tensile +strength of this alloy is usually given as 100,000 pounds +to the square inch; but castings of our ten per cent. +bronze have stood a strain of 109,000 pounds. It is a +very hard, tough alloy, with a capacity to withstand +wear far in excess of any other alloy in use. All grades +of aluminum bronze make fine castings, taking very +exact impressions, and there is no loss in remelting, as +in the case of alloys containing zinc. The 5 per cent. +aluminum alloy is a close approximation in color to +18 carat gold, and does not tarnish readily. Its tensile +strength in the form of castings is equivalent to a +strain of 68,000 pounds to the square inch. An alloy +containing 2 or 3 per cent. aluminum is stronger than +brass, possesses greater permanency of color, and would +make an excellent substitute for that metal. When +the percentage of aluminum reaches 13, an exceedingly +hard, brittle alloy of a reddish color is obtained, and +higher percentages increase the brittleness, and the +color becomes grayish-black. Above 25 per cent. the +strength again increases.</p> + +<p>The effect of silicon in small proportions upon copper +is to greatly increase its tensile strength. When +more than 5 per cent. is present, the product is exceedingly +brittle and grayish-black in color. It is probable +that silicon acts to a certain extent as a fluxing material +upon the oxides present in the copper, thereby +making the metal more homogeneous. On account of +its superior strength and high conductivity for electrical +currents, silicon bronze is the best material known +for telegraph and telephone wire.</p> + +<p>The element boron seems to have almost as marked +an effect upon copper as carbon does upon iron. A +small percentage in copper increases its strength to +50,000 or 60,000 pounds per square inch without diminishing +to any large extent its conductivity.</p> + +<p>Aluminum increases very considerably the strength +of all metals with which it is alloyed. An alloy of +copper and nickel containing a small percentage of +aluminum, called Hercules metal, withstood a strain of +105,000 pounds, and broke without elongation. Another +grade of this metal broke under a strain of +111,000 pounds, with an elongation equivalent to 33 per +cent. It must be remembered that these tests were all +made upon castings of the alloys. The strength of +common brass is doubled by the addition of 2 or 3 per +cent. of aluminum. Alloys of aluminum and iron are +obtained without difficulty; one product was analyzed, +containing 40 per cent. of aluminum. In the furnace +iron does not seem to be absorbed readily by the reduced +aluminum when copper is present; but in one +experiment a mixture composed of old files, 60 per +cent.; nickel, 5 per cent.; and of 10 per cent. aluminum +bronze 35 per cent., was melted together, and it +gave a malleable product that stood a strain of 69,000 +pounds.</p> + +<p>When the reduction of aluminic oxide by carbon is +conducted without the addition of copper, a brittle +product is obtained that behaves in many respects +like pig iron as it comes from the blast furnace. The +same product is formed in considerable quantities, even +when copper is present, and frequently the copper +alloy is found embedded in it. Graphite is always found +associated with it, even when charcoal is the reducing +material, and analysis invariably shows a very high percentage +of metallic aluminum. This extremely interesting +substance is at present under examination.</p> + +<p><a name="Footnote_8" id="Footnote_8"></a><a href="#FNanchor_8">[1]</a></p><div class="note"><p>Read at the recent meeting of the American Association, Ann Arbor, Mich.</p></div> + +<hr /> + +<h2><a name="art01" id="art01"></a>THE COWLES ELECTRIC SMELTING PROCESS.</h2> + +<p>The use of electricity in the reduction of metals from +their ores is extending so rapidly, and the methods of +its generation and application have been so greatly +improved within a few years, that the possibility of +its becoming the chief agent in the metallurgy of the +future may now be admitted, even in cases where the +present cost of treatment is too high to be commercially +advantageous.</p> + +<p>The refining of copper and the separation of copper, +gold, and silver by electrolysis have thus far attracted +the greatest amount of attention, but a commercial +success has also been achieved in the dry reduction by +electricity of some of the more valuable metals by the +Cowles Electric Smelting and Aluminum Company, +of Cleveland, Ohio. Both this method of manufacture +and the qualities of the products are so interesting and +important that it is with pleasure we call attention to +them as steps toward that large and cheap production +of aluminum that the abundance of its ores and the +importance of its physical properties have for several +years made the unattained goal of many skillful metallurgists.</p> + +<p>The Messrs. Cowles have succeeded in greatly reducing +the market value of aluminum and its alloys, and +thereby vastly extending its uses, and they are now +by far the largest producers in the world of these important +products. As described in their patents, the +Cowles process consists essentially in the use for metallurgical +purposes of a body of granular material of +high resistance or low conductivity interposed within +the circuit in such a manner as to form a continuous +and unbroken part of the same, which granular body, +by reason of its resistance, is made incandescent, and +generates all the heat required. The ore or light material +to be reduced—as, for example, the hydrated oxide +of aluminum, alum, chloride of sodium, oxide of calcium, +or sulphate of strontium—is usually mixed with +the body of granular resistance material, and is thus +brought directly in contact with the heat at the points +of generation, at the same time the heat is distributed +through the mass of granular material, being generated +by the resistance of all the granules, and is not localized +at one point or along a single line. The material +best adapted for this purpose is electric light carbon, +as it possesses the necessary amount of electrical resistance, +and is capable of enduring any known degree of +heat when protected from oxygen without disintegrating +or fusing; but crystalline silicon or other equivalent +of carbon can be employed for the same purpose. +This is pulverized or granulated, the degree of granulation +depending upon the size of the furnace. Coarse +granulated carbon works better than finely pulverized +carbon, and gives more even results. The electrical +energy is more evenly distributed, and the current can +not so readily form a path of highest temperature, and +consequently of least resistance through the mass along +which the entire current or the bulk of the current can +pass. The operation must necessarily be conducted +within an air-tight chamber or in a non-oxidizing +atmosphere, as otherwise the carbon will be consumed +and act as fuel. The carbon acts as a deoxidizing agent +for the ore or metalliferous material treated, and to +this extent it is consumed, but otherwise than from +this cause, it remains unimpaired.</p> + +<p>Fig. I. of the accompanying drawings is a vertical +longitudinal section through a retort designed for the +reduction of zinc ore, according to this process, and +Fig. II. is a front elevation of the same. Fig. III. is a +perspective view of a furnace adapted to withstand a +very high temperature, and Figs. IV. and V. are respectively +longitudinal and transverse sections of the +same.</p> + +<div class="figcenter"><a href="./images/11.png"> +<img src="./images/11_th.png" alt="THE COWLES ELECTRIC SMELTING PROCESS." /></a> +<br /> THE COWLES ELECTRIC SMELTING PROCESS.</div> + +<p>This retort consists of a cylinder, A, made of silica +or other non-conducting material, suitably embedded +in a body, B, of powdered charcoal, mineral wool, or +of some other material which is not a good conductor +of heat. The rear end of the retort-cylinder is closed +by means of a carbon plate, C, which plate forms the +positive electrode, and with this plate the positive +wire of the electric circuit is connected. The outer end +of the retort is closed by means of an inverted graphite +crucible, D, to which the negative wire of the electric +circuit is attached. The graphite crucible serves as a +plug for closing the end of the retort. It also forms +a condensing chamber for the zinc fumes, and it also +constitutes the negative electrode. The term "electrode" +is used in this case as designating the terminals +of the circuit proper, or that portion of it which +acts simply as an electrical conductor, and not with +the intention of indicating the ends of a line between +which there is no circuit connection. The circuit between +the "electrodes," so called, is continuous, being +established by means of and through the body of +broken carbon contained in the retort, A. There is +no deposit made on either plate of the decomposed +constituents of the material reduced. The mouth of +the crucible is closed with a luting of clay, or otherwise, +and the opening, <i>d</i>, made in the upper side of the +crucible, near its extremity, comes entirely within the +retort, and forms a passage for the zinc fumes from the +retort chamber into the condensing chamber. The +pipe, E, serves as a vent for the condensing chamber. +The zinc ore is mixed with pulverized or granular carbon, +and the retort charged nearly full through the +front end with the mixture, the plug, D, being removed +for this purpose.</p> + +<p>A small space is left at the top, as shown. After the +plug has been inserted and the joint properly luted, the +electric circuit is closed and the current allowed to pass +through the retort, traversing its entire length through +the body of mixed ore and carbon. The carbon +constituents of the mass become incandescent, generating +a very high degree of heat, and being in direct contact +with the ore, the latter is rapidly and effectually reduced +and distilled. The heat evolved reduces the ore +and distills the zinc, and the zinc fumes are condensed +in the condensing chamber, precisely as in the present +method of zinc making, with this important exception +that, aside from the reaction produced by heating carbon +in the presence of zinc oxide, the electric current, +in passing through the zinc oxide, has a decomposing +and disintegrating action upon it, not unlike the effect +produced by an electric current in a solution. This +action accelerates the reduction, and promotes economy +in the process.</p> + +<p>Another form of furnace is illustrated by Fig. III., +which is a perspective view of a furnace adapted for +the reduction of ores and salts of non-volatile metals and +similar chemical compounds. Figs. IV. and V. are +longitudinal and transverse sections, respectively, +<a name="Page_8114" id="Page_8114"></a>through the same, illustrating the manner of packing +and charging the furnace.</p> + +<p>The walls and floorsL L', of the furnace are made of +fire bricks, and do not necessarily have to be very thick +or strong, the heat to which they are subjected not being +excessive. The carbon plates are smaller than the +cross section of the box, as shown, and the spaces between +them and the end walls are packed with fine +charcoal.</p> + +<p>The furnace is covered with a removable slab of fireclay, +N, which is provided with one or more vents, <i>n</i>, +for the escaping gases.</p> + +<p>The space between the carbon plates constitutes the +working part of the furnace. This is lined on the bottom +and sides with a packing of fine charcoal, O, or +such other material as is both a poor conductor of heat +and electricity—as, for example, in some cases, silica +or pulverized corundum or well-burned lime—and the +charge, P, of ore and broken, granular, or pulverized +carbon occupies the center of the box, extending between +the carbon plates. A layer of granular charcoal, +O', also covers the charge on top. The protection +afforded by the charcoal jacket, as regards the heat, +is so complete, that with the covering-slab removed, the +hand can be held within a few inches of the exposed +charcoal jacket; but with the top covering of charcoal +also removed and the core exposed, the hand cannot be +held within several feet. The charcoal packing behind +the carbon plates is required to confine the heat and to +protect them from combustion.</p> + +<p>With this furnace, aluminum can be reduced directly +from its ores; and chemical compounds from corundum, +cryolite, clay, etc., and silicon, boron, calcium, +manganese, magnesium, and other metals are in like +manner obtained from their ores and compounds. The +reduction of ores according to this process can be +practiced, if circumstances require it, without any +built furnace.</p> + +<p>At present, the Cowles company is engaged mostly +in the producing of aluminum bronze and aluminum +silver and silicon bronze. The plant, were it run to its +full capacity, is capable of turning out eighty pounds +of aluminum bronze, containing 10 per cent. of aluminum +daily; or, were it to run upon silicon bronze, +could turn out one hundred and twenty pounds of that +per day, or, we believe, more aluminum bronze daily +than can be produced by all other plants in the world +combined. This production, however, is but that of +the experimental laboratory, and arrangements are +making to turn out a ton of bronze daily, and the +works have an ultimate capacity of from eight to ten +thousand horse power. The energy consumed by the +reduction of the ore is almost entirely electrical, only +enough carbon being used to unite with the oxygen of +the ore to carry it out of the furnace in the form of the +carbon monoxide, the aluminum remaining behind. +Consequently, the plant necessary to produce aluminum +on a large scale involves a large number of the +most powerful dynamos. These are to be driven by +water-power or natural gas and marine engines of great +capacity.</p> + +<p>The retail price of standard 10 per cent. aluminum +bronze is $1 per pound avoirdupois, which means less +than $9 per pound for aluminum, the lowest price at +which it has ever been sold, yet the Cowles company +has laid a proposition before the Government to furnish +this same bronze in large quantities at very much +lower prices than this. The Hercules alloy, castings +of which will stand over 100,000 pounds to +the square inch tensile strain, sells at 75 c. a pound, +and is also offered the Government or other large +consumers at a heavy discount. The alloys are +guaranteed to contain exactly what is advertised; +they are standardized into 10 per cent., 7.5 per cent., +5 per cent. and 2.5 per cent. aluminum bronze before +shipment.</p> + +<p>The current available at the Cowles company's works +was, until recently, 330 amperes, driven by an electromotive +force of 110 volts and supplied by two Edison +dynamos; but the company has now added a large +Brush machine that has a current of 560 amperes and +52 volts electromotive force. We shall, on another occasion, +give some particulars of experiments in the reduction +of refractory ores by the process.—<i>Eng. and +Mining Jour.</i></p> + +<hr /> + +<h2><a name="art13" id="art13"></a>OPTICAL TELEGRAPHY.<a name="FNanchor_9" id="FNanchor_9"></a><a href="#Footnote_9"><sup>1</sup></a></h2> + +<h3>CRYPTOGRAPHY.—PRESERVATION OF TELEGRAMS.</h3> + +<p>Optical telegraphy, by reason of its very principle, +presents both the advantage and inconvenience of +leaving no automatic trace of the correspondence that +it transmits. The advantage is very evident in cases +in which an optical station falls into the hands of the +enemy; on the other hand, the inconvenience is shown +in cases where a badly transmitted or badly collated +telegram allows an ambiguity to stand subject to dispute. +Moreover, in case of warfare between civilized +nations that have all the resources of science at their +disposal, there may be reason to fear lest one of the +enemy's optical stations substitute itself for the corresponding +station, and take advantage of the situation +to throw confusion into the orders transmitted. The +remedy for this appears to reside in the use of cryptography +and in the exchange, at various intervals, of +certain words that have been agreed upon beforehand, +and that the enemy is ignorant of.</p> + +<p>As for the automatic preservation of telegrams, the +problem has not been satisfactorily solved. It has been +proposed to connect the key of the manipulator of the +optical apparatus with the manipulator of an ordinary +Morse apparatus, thus permitting the telegram to be +preserved upon a band of paper. It is unnecessary to +say that the space occupied by a dispatch thus transmitted +would be considerable; but this is not what has +stopped innovators. The principal objection resides +in the increase in muscular work imposed by this arrangement +upon the telegrapher. Obliged to keep his +eye fixed intently at the receiving telescope, while at the +same time maneuvering the manipulator and spelling +aloud the words that he is receiving, the operator +should have a very sensitive manipulator at his disposal, +and not be submitted to mental or physical +overtaxation. So the apparatus that have been devised +have not met with much success.</p> + +<p>Two French officers, working independently, have +hit upon the same idea of receiving the indications +transmitted by the vibration of the luminous fascicle +directly upon their travel. The method consists in the +use of that peculiar property of selenium of becoming +a good conductor under the action of a luminous ray, +while in darkness it totally prevents the passage of the +electric current. Such modification of the physical +properties of selenium, moreover, occurs without the +perceptible development of any mechanical work. If, +then, in the line of travel of the luminous fascicle +emitted by the optical apparatus, or in a portion of +such fascicle, we interpose a fragment of selenium connected +with the two poles of a local pile, it is easy to +see that the current from the latter will be opened or +closed according as the luminous ray from the apparatus +will or will not strike the selenium, and that the +length of time during which the current passes will depend +upon the length of the luminous attacks. A Morse +apparatus interposed in this annexed circuit will +therefore give an automatic inscription of the correspondence +exchanged. Such is the principle. But, +practically, very great difficulties present themselves, +these being connected with the rapid weakening of the +electric properties of the selenium, and with the necessity +of having recourse to infinitely small mechanical +actions only. The problem is nevertheless before +us, and it is to be hoped that the perseverance of the +scientists who are at work upon it will some day succeed +in solving it.</p> + +<p>Finally, we may call attention to the attempts made +to receive the luminous impression upon a band prepared +with gelatino-bromide of silver. In practice this +band would unwind uniformly at the focus of the receiving +telescope, which would be placed in a box, +forming a camera obscura. The velocity of this band +prepared for photographing the signals would be regulated +by clockwork. The experiments that have been +made have not given results that are absolutely satisfactory, +by reason of the length of the signals received +and the mechanical complication of the device.</p> + + +<h3>OPTICAL TELEGRAPHY BY MEANS OF PROJECTORS.</h3> + +<div class="figcenter"><img src="./images/12b.png" alt="Fig. 23." /><br /> <span class="smcap">Fig.</span> 23.</div> + +<p>The projectors employed for lighting to a distance +the surroundings of a stronghold or of a ship have likewise +been applied in optical telegraphy. For this purpose +Messrs. Sautter, Lemonnier & Co. have added +to their usual projecting apparatus some peculiar arrangements +that permit of occultations of the luminous +focus at proper intervals. Figs. 21 and 22 show +the arrangement of the apparatus, the principle of +which is as follows: When the axis of the projector +points toward the clouds, and in the direction occupied +by a corresponding station, the occultations of the luminous +source placed in the focus of the apparatus +produce upon the clouds, which act as a screen, an alternate +series of flashes and extinctions. It is therefore +possible with this arrangement, and by the use of the +Morse alphabet, to establish an optical communication +at a distance. The use of this projector (the principal +inconvenience of which is that it requires a clouded +sky) even permits two observers who are hidden from +each other by the nature of the ground to easily communicate +at a distance of 36 or 48 miles.</p> + +<h3>USE OF THE PROJECTOR IN OPTICAL TELEGRAPHY.</h3> +<div class="figcenter"><a href="./images/12a.png"><img src="./images/12a_th.png" alt="Figs. 21 and 22.—FRONT VIEW AND LONGITUDINAL SECTION" /></a> +<div class="longcaption"><p><span class="smcap">Figs. 21 and 22.</span>—FRONT VIEW AND LONGITUDINAL SECTION +OF THE MANGIN PROJECTOR. +(Scale 1/15). A. Elliptical mirror. B. Arm of the same. C. Nut for +fixing the mirror. D. Support of the mirror. E. Occultator. +F. Support for same. G. Lever for maneuvering the occultator. I. Support +of the occultator rod. J. Screw for fixing the mirror support. +K. Screw for fixing the support of the occultator rod. +L. Screw for fixing the occultator support.</p></div> +</div> + + +<p>The apparatus shown in Figs. 21 and 22 permits of +signaling in three ways:</p> + +<p>1. <i>Upon the Clouds.</i>—In this case the mirror, A, is +removed, and the projector inclined above the horizon +in such a way as to illuminate the clouds to as great a +distance as possible. A maneuver of the occultator, E, +between the lamp and the mirror arrests the luminous +rays of the source, or allows them to pass, and thus +produces upon the clouds the dots and dashes of the +conventional alphabet.</p> + +<p>2. <i>Isolated Communication by Luminous Fascicles.</i>—When +it is desired to correspond to a short distance +of 2 or 3 miles, and establish a communication between +two isolated posts, the mirror, A, is put in place upon +its support, B. The luminous fascicle emanating from +the source reflected by the mirror is thrown vertically. +By revolving the mirror 90° around its horizontal axis +the fascicle becomes horizontal, and may thus be +thrown in a given direction at unequal intervals and +during irregular times, and furnish conventional signs.</p> + +<p>3. <i>Night Communication upon the Entire Horizon.</i>—When +we wish to correspond at a short distance, say +two miles, and make signals visible from the entire horizon, +the mirror, A, is put in place, so that it shall reflect +the luminous fascicle vertically. The fascicle, at a +distance of about fifty feet, meets a white balloon +which it renders visible from every point in the horizon. +The maneuver of the occultator brings the balloon +out of darkness or plunges it thereinto again, and +thus produces the signs necessary for aerial communication.</p> + +<div class="figcenter"><img src="./images/12c.png" alt="Fig. 24." /><br /> <span class="smcap">Fig.</span> 24.</div> + +<p>These ingenious arrangements, which depend upon +the state of the atmosphere, do not appear to have +been imitated outside of the navy.</p> + +<h3>CAPT. GAUMET'S OPTICAL TELEGRAPH.</h3> + +<p>The system of optical communication proposed by +Capt. Gaumet, and which he names the <i>Telelogue</i>, is +based upon the visibility of colored or luminous objects, +and upon the possibility of piercing the opaque +curtain formed by the atmosphere between the observer's +eye and a signal, by utilizing the difference in +brightness that exists between such objects and the +atmosphere. It is a question, then, of giving such difference +in intensity its maximum of brightness. To +do this, Capt. Gaumet proposes to employ silvered signals +<a name="Page_8115" id="Page_8115"></a>upon a black background. He uses the simple +letters of the alphabet, but changes their value. His +apparatus has the form of a large album glued at the +back to a sloping desk. Each silvered letter, glued to +a piece of black cloth, is seen in relief upon the open +register. A sort of index along the side, as in +commercial blank-books, permits of quickly finding any +letter at will. Such is the manipulator of the apparatus.</p> + +<p>The receiver consists of a spy-glass affixed to the +board that carries the register. For a range of two and +a half miles, the complete apparatus, with a 12×16 inch +manipulator and telescope, weighs but four and a half +pounds. For double this range, with a 20×28 inch +manipulator and telescope, the total weight is thirteen +pounds. The larger apparatus, according to the inventor, +have a range of seven miles.</p> + +<p>For night work the manipulator is lighted either by +one lamp, or by two lamps with reflector, placed laterally +against it.</p> + +<p>This apparatus, although well known, and having +been publicly experimented with, has not, to our +knowledge, been applied practically. From a military +standpoint, its short range will evidently not permit it +to compete with optical telegraphic apparatus, properly +so called. Perhaps it might rather be of service for +private communications between localities not very far +apart, since it costs but little and is easily operated.</p> + +<h3>OPTICAL SIGNALING BETWEEN BODIES OF TROOPS.</h3> + +<p>Optical communications by signals, during day and +night, with experienced men, may, in the absence of +telephones, telegraphs, and messengers, render +important service when the distance involved is +greater than two thousand feet.</p> + +<p>This mode of correspondence is based upon the use +of the Morse alphabet. The signals are divided into +night and day ones. The day signals are made with +small flags. When these are wanting, sheets of white +cardboard may be used. The night signals are made +with a lantern provided with a support, which may be +fixed to a wall or upon a bayonet.</p> + +<p>In day signaling, the dashes of the Morse alphabet +are formed by means of two flags (Fig. 23) held +simultaneously at arm's length by the signaler. The dots +are formed with a single flag held in the right hand +(Fig. 24). In this way it is possible, by extremely +simple combinations, to establish a correspondence, and +produce any conventional signal. By means of relay +stations, the signals may be transmitted from one to +another to a great distance.</p> + +<p>In signaling with the lantern, long and short +interruptions of the luminous source are produced +by means of a screen.</p> + +<h3>OPTICAL TELEGRAPHY BY LUMINOUS BALLOONS.</h3> + +<p>Various interesting experiments have been made +with a view to utilizing luminous captive balloons for +optical communications. As we have already seen, this +maybe effected by using opaque balloons, and throwing +upon them at unequal intervals a luminous fascicle by +means of a projector. As for using a luminous source +placed in the car of a balloon, that cannot be thought +of in the present state of aeronautic science; the +continual rotation of the balloon around its axis would +render the projection and reception of the signals in a +given direction impossible.</p> + + +<h3>OPTICAL TELEGRAPHY IN THE MARINE.</h3> + +<p>For communicating optically from ship to ship during +the day, the marine uses flags of different forms +and colors, and flames. Between ships and the land +there are used what are called semaphore signals, +which are made by means of a mast provided with +three arms and a disk placed at the upper part. The +combinations of signs thus obtained, which are analogous +in principle to those of the Chappe telegraph, +permit of satisfactorily communicating to a distance.</p> + +<p>On board ship, hand signals are used like those +employed by the army for communicating between bodies +of troops. For night communications the marine employs +lights corresponding to the day flags, as well as +rockets, and luminous rays projected by means of reflectors +and intercepted by screens.</p> + +<p>In conclusion, it may be said that optical telegraphy, +which has only within a few years emerged from the +domain of theory to enter that of practice, has taken a +remarkable stride in the military art and in science. +It is due to its processes that Col. Perrier has in recent +years been enabled to carry out certain geodesic work +that would have formerly been regarded as impracticable, +notably the prolongation of the arc of the meridian +between France and Spain. Very recently, an +optical communication established between Mauritius +and Reunion islands, to a distance of 129 miles, with +24 inch apparatus, proved that, in certain cases, the +costly laying of a submarine cable may be replaced by +the direct emission of a luminous ray.</p> + +<p><a name="Footnote_9" id="Footnote_9"></a><a href="#FNanchor_9">[1]</a></p><div class="note"><p>Continued from page 8094.</p></div> + +<hr /> + +<h2><a name="art14" id="art14"></a>A NEW STYLE OF SUBMARINE TELEGRAPH.</h2> + +<p>Mr. F. Von Faund-Szyll has devised an original +system of submarine telegraph, which is based upon +the well known property that selenium exhibits of +modifying its resistance under the influence of luminous +rays, and which he styles the +<i>Selen-Differenzialrecorder</i>.</p> + +<p>Contrary to what is found in the other systems +hitherto employed, the Faund-Szyll system utilizes the +cable current merely for starting the receiving apparatus, +which are operated by means of strong local batteries. +The result is that the mechanical work that +devolves upon the line current, which is, as well +known, very weak, is exceedingly reduced.</p> + +<p>The system consists of two essential parts: +(1) The receiver, properly so called. +(2) The relay as well as the registering apparatus +or <i>differenzialrecorder</i>. +The receiver consists of a closed box, K, in the interior of +which there is a very intense source of light whose rays +escape by passing through apertures, <i>a a'</i>, in the front +part (Fig. 1).</p> + +<p>As a source of light, there may be conveniently +employed an incandescent lamp, <i>g</i>, capable of giving an +intense light, and arranged (as shown in Fig. 2) behind +the side that contains the slits, <i>a a'</i>.</p> + +<p>The starting apparatus consists of a small galvanometric +helix, <i>r</i>, analogous to Thomson's siphon recorder, +which is suspended from a cocoon fiber and capable +of moving in an extremely powerful magnetic field, +N_S. This helix carries, as may be seen in Figs. 1, 3 +and 4, a prolongation, <i>v</i>, at its lower end whose form +is that of a prism, and which is arranged in front of the +partition of the box, K, in such a way that it exactly +covers the two slits, <i>a</i> and <i>a</i> when the bobbin is at +rest, and in this case prevents the luminous rays of the +lamp, <i>g</i>, from escaping from the box. But, as soon as +the current sent through the cable reaches the spirals +of the bobbin, through the conductors, <i>y y'</i>, the sum +of the elementary electrodynamic actions that arise +causes the helix to revolve to the right or left, according +to the polarity of the current, while at the same +time the helix slightly approaches one or the other of +the poles of the magnet. The prolongation, <i>v</i>, of the +helix, being firmly united with the latter, follows it in +its motion, and has the effect of permitting the luminous +rays to escape through one or the other of the slits, +<i>a_a'</i>, so that the freeing of the luminous fascicle, if such +an expression is allowable, is effected.</p> + +<div class="figcenter"><img src="./images/13a.png" alt="Fig. 1." /><br /> <span class="smcap">Fig.</span> 1.</div> + +<p>In order to prevent oscillations, which could not fail +to occur after each emission of a current (so that the +helix, instead of returning to a position of equilibrium +and stopping there, would go beyond it and alternately +uncover the slits, <i>a a'</i>), the apparatus is provided with +a liquid deadener. To this end, the prolongation, <i>v</i>, +carries a piece, <i>o</i>, which dips into a cup containing a +mixture of glycerine and water.</p> + +<p>We shall now describe the <i>differenzialrecorder</i>. Opposite +the two slits, <i>a</i> and <i>a'</i>, there are two powerful +converging lenses, <i>l</i> and <i>l'</i>, whose foci coincide with +two sorts of selenium plate rheostat, <i>z</i> and <i>z'</i>. The result +of this arrangement is that as soon as one of the +slits, as a consequence of the displacement of the helix, +<i>r</i>, allows a luminous fascicle to escape, this latter falls +upon the corresponding lens, which concentrates it and +sends it to the selenium plates just mentioned. Under +the influence of the luminous rays, the resistance that +the selenium offers to the passage of an electric current +instantly changes. At M and M' are placed two horseshoe +magnets whose poles are provided with pieces of +soft iron that serve as cores to exceedingly fine wire +bobbins, <i>d</i>. These polarized pieces are arranged in +the shape of a St. Andrew's cross, and in such a way +that the poles of the same name occupy the two extremities +of the same arm of the cross, an arrangement +very clearly shown in Fig. 2.</p> + +<div class="figcenter"><a href="./images/13b.png"><img src="./images/13b_th.png" alt="Fig. 2." /></a><br /> <span class="smcap">Fig.</span> 2.</div> + +<p>Between the poles of the magnets, M and M', there is +a permanent magnet, A, movable around a vertical +axis, <i>i</i>. Four spiral springs, <i>f</i>, whose tension may be +regulated, permit of centering this latter piece in such +a way that when the current is traversing the spirals +of the polar bobbins it is equally distant from the four +poles, <i>n</i>, <i>s</i>, <i>s'</i>, and <i>n'</i>. Under such circumstances it is +evident that a difference in the power of attraction of +these four poles, however feeble it be, will result in +moving the magnet, A, in one direction or the other +around its axis. The energy and extent of such motion +may, moreover, be magnified by properly acting upon +the four regulating springs.</p> + +<p>The bobbins of the magnet, M, are mounted in series +with the selenium plates, <i>z</i>, the local battery, B, and a +resistance box, W. Those of the magnet, M', are in +series with <i>z'</i>, B', and W'. The local batteries, B and +B', are composed of quite a large number of elements. +The current from the battery, B, traverses the selenium +plates and the bobbins of the magnet, M, and returns +to B through the rheostat, W; and the same occurs +with the current from B'. The two currents, then, are +absolutely independent of one another.</p> + +<p>From this description it is very easy to see how the +system works. Let us suppose, in fact, that the current +which is traversing the spirals of the helix, <i>r</i>, has +a direction such that the helix in its movement approaches +the pole, S; then the prolongation, <i>v</i>, will uncover +the slit, <i>a</i>, which, along with <i>a'</i>, had up to this +moment been closed, and a luminous fascicle escaping +through <i>a</i> will strike the lens, <i>l'</i>, and from thence +converge upon the selenium plates, <i>z'</i>. This is all the +duty that the line current has to perform.</p> + +<p>The luminous rays, in falling upon the selenium +plates, <i>z'</i>, modify the resistance that these offered to +the passage of the current produced by the battery, +B'. As this resistance diminishes, the intensity of the +current in the circuit supplied by the battery, B', increases, +the attractive action of the polar pieces of the +magnet, M', diminishes, the equilibrium is destroyed, +and the piece, A, revolves around the axis, <i>i</i>. If the +polarity of the line current were different, the same +succession of phenomena would occur, save that the +direction of A's rotation would be contrary. As for the +rheostats, W W', their object is to correct variations in +the selenium's resistance and to balance the resistances +of the two corresponding circuits. The magnet, A, +will be combined with a registering apparatus so as to +directly or indirectly actuate the printing lever. The +entire first part of this apparatus, which is very sensitive, +may be easily protected from all external influence +by placing it in a box, and, if need be, in a room +distant from the one in which the employes work.</p> + +<div class="figcenter"><img src="./images/13c.png" alt="Figs. 3 and 4." /> +<br /><span class="smcap">Figs.</span> 3 <span class="smcap">and</span> 4.</div> + +<p>The <i>differenzialrecorder</i> alone has to be in the work +room.</p> + +<p>As may be seen, the system is not wanting in originality. +Experience alone will permit of pronouncing +upon the question as to whether it is as practical as +ingenious.—<i>La Lumiere Electrique.</i></p> + +<hr /> + +<h2><a name="art15" id="art15"></a>A NEW CIRCUIT CUTTER.</h2> + +<p>Messrs. Thomson & Bottomley have recently invented +a peculiar circuit cutter based upon the use of +a metal whose melting point is exceedingly low. Recourse +is had to this process for breaking the current +within as short a time as possible. In this new device +the ends of the conductors are soldered together with +the metal in question at one or several points of the +circuit. The metal employed is silver or copper of very +great conductivity, seeing that the increase of temperature +in a conductor, due to a sudden increase of +the current, is inversely proportional to the product of +the electric resistance by the specific heat of the conductor; +that these metals are best adapted for giving +constant and definite results; and that the contacts are +better than with lead or the other metals of low melting +point which are frequently employed in circuit +cutters.</p> + +<div class="figcenter"><img src="./images/13d.png" alt="Fig. 1." /><br /> <span class="smcap">Fig.</span> 1.</div> + +<p>Fig. 1 represents one form of the new device. Here, +a is the copper or silver wire, and <i>b</i> is a soldering made +with a very fusible metal and securing a continuity of +<a name="Page_8116" id="Page_8116"></a>the circuit. Each extremity of the wire, <i>a</i>, is connected +with a heavy ring, <i>c</i>, of copper or other good conducting +metal. The hook, <i>d</i>, with which the upper +ring, <i>c</i>, is in contact, communicates metallically with +one of the extremities of the conductor at the place +where the latter is interrupted for the insertion of the +circuit cutter. The hook, <i>e</i>, with which the lower +ring, <i>c</i>, is in contact, tends constantly to descend under +the action of a spiral spring, <i>f</i>, which is connected metallically +with the other extremity of the principal +conductor. The hooks, <i>d</i> and <i>e</i>, are arranged approximately +in the same vertical plane, and have a slightly +rounded upper and lower surface, designed to prevent +the rings, <i>c</i>, of the fusible wire, <i>a</i>, from escaping from +the hooks. In Fig. 1 the position of the arm, <i>e</i>, when +there is no fusible wire in circuit, is shown by dotted +lines. When this arm occupies the position shown by +entire lines, it exerts a certain traction upon the soldering, +<i>b</i>, and separates the two halves of the wire, <i>a</i>, as +soon as the intensity of circulation exceeds its normal +value. The mode of putting the wire with fusible +soldering into circuit is clearly shown in the engraving.</p> + +<div class="figcenter"><img src="./images/13e.png" alt="Fig. 2." /><br /> <span class="smcap">Fig.</span> 2.</div> + +<p>Fig. 2 shows a different mode of mounting the wire. +The wire, <i>q</i>, is soldered in the center, and is bent into +the shape of a U, and kept in place by the pieces, +<i>r</i> and <i>s</i>. In this way the two ends of it tend constantly +to separate from each other. Messrs. Thomson & Bottomley +likewise employ weights, simply, for submitting +the wire to a constant stress. The apparatus is +inclosed in a box provided with a glass cover.—<i>La Lumiere +Electrique.</i></p> + +<hr /> + +<h2><a name="art16" id="art16"></a>NEW MICRO-TELEPHONIC APPARATUS.</h2> + +<p>Despite the simplicity of their parts, and the slight +value of the materials employed, the existing micro-telephonic +apparatus keep at relatively high prices, +and the use of them is often rejected, to the benefit of +speaking tubes, when the distance between stations is +not too great. We propose to describe a new style of +apparatus that are in no wise inferior to those in general +use, and the price of which is relatively low.</p> + +<p>The microphone transmitter may have several forms. +The most elementary of these consists of two pieces of +carbon, from one to one and a quarter inches in length +by one-half inch in width, between which are fixed two +<i>nails</i>, about two inches in length, whose extremities, +filed to a point, enter small conical apertures in the +carbons. Fig. 1 gives an idea of the arrangement.</p> + +<div class="figcenter"><img src="./images/14a.png" alt="Fig. 1." /><br /> <span class="smcap">Fig.</span> 1.</div> + +<p>Fig. 2 represents a model which is a little more complicated, +but which gives remarkable results. The +largest nail is here two inches in length, and the +shortest three-quarter inch.</p> + +<div class="figcenter"><img src="./images/14b.png" alt="Fig. 2." /><br /> <span class="smcap">Fig.</span> 2.</div> + +<p>The receivers may be Bell telephones of the simplest +form found in the market (Fig. 3); but for these there +may be substituted a bar of soft iron, cast iron, or steel, +one of the extremities of which is provided with a bobbin +upon, which is wound insulated copper wire 0.02 +inch in diameter. The apparatus is mounted like an +ordinary Bell telephone. A horseshoe electro may +also be used, and the poles be made to act (Fig. 4). The +current sent by the transmitter suffices to produce a +magnetic field in which the variations in intensity produced +by the microphone succeed perfectly in reproducing +speech and music. With four Leclanche elements, +the sounds are perceived very clearly. The +elements used may be bichromate of potash ones, those +of Lelande and Chaperon, etc.</p> + +<div class="figcenter"><a href="./images/14c.png"><img src="./images/14c_th.png" alt="Fig. 3.—RECEIVER." /></a> +<br /> <span class="smcap">Fig.</span> 3.—RECEIVER.</div> + +<div class="figcenter"><img src="./images/14d.png" alt="Fig. 4." /><br /> <span class="smcap">Fig.</span> 4.</div> + +<p>To this apparatus there may be added a second bobbin +of coarser wire into which is passed a current from +a local pile. This produces a much intenser magnetic +field, and, consequently, louder sounds. This modification, +however, is really useful only for long distances.</p> + +<p>Any arrangement imaginable may be given the +transmitter and receiver; but, aside from the fact that +the ones just indicated are the simplest, they give results +that are at least equal, if not superior, to all +others.</p> + +<p>We shall insist here only upon the arrangement of +the microphone, which is new (at least in practice), and +upon the uselessness of having well magnetized steel +bars and wires of extreme fineness in the receiver.</p> + +<p>We have stated that the nail microphones are the +simplest. The nails may be replaced by copper or any +other metal, or they may be well nickelized; but common +nails answer very well, and do not oxidize +much. An apparatus of this kind (Fig. 5) that has +been for more than a year in a laboratory filled with +acid vapors is yet working very well. These apparatus +possess the further advantage of being very strong, and +of undergoing violent shocks without breaking or even +getting out of order. They may be used either with +or without induction coils. We have not yet measured +their range, but can cite the following fact:</p> + +<div class="figcenter"><img src="./images/14e.png" alt="Fig. 5." /><br /> <span class="smcap">Fig.</span> 5.</div> + +<p>One of these apparatus, quite crudely mounted, was +put into a circuit with a resistance of 300 ohms. With +a single already exhausted bichromate element, giving +scarcely 2 volts, musical sounds and speech reached the +receiver without being notably weakened. Such resistance +represents a length of eighteen miles of ordinary +telegraph wire. After this, 700 ohms were overcome +with 3.4 volts. This result was obtained by direct +transmission, and without an induction coil, and it is +probable that it might be much exceeded without sensibly +increasing the electromotive force of the current.—<i>Le +Genie Civil.</i></p> + +<hr /> + +<h2><a name="art17" id="art17"></a>MESSRS. KAPP AND CROMPTON'S MEASURING +INSTRUMENTS.</h2> + +<p>We give herewith, from the <i>Elektrotechnische Zeitschrift</i>, +a few interesting details in regard to the measuring +apparatus of Messrs. Kapp and Crompton.</p> + +<p>It is evident that when we use permanent magnets +or springs as directing forces in measuring instruments, +we cannot count upon an absolute constancy in the indications, +as the magnetism of the magnetized pieces, +or the tension of the springs, modifies in time. The +apparatus require to be regulated from time to time, +and hence the idea of substituting electro-magnets for +permanent ones.</p> + +<div class="figcenter"><img src="./images/14f.png" alt="Fig. 1." /><br /> <span class="smcap">Fig.</span> 1.</div> + +<p>If we suppose (Fig. 1) a magnetized needle, <i>n s</i>, placed +between the extremities of a soft iron core, N S, and if +we group the circuit in such a way that the current, +after traversing the coil, <i>e e</i>, of the electro, traverses a +circle, <i>d d</i>, situated in a plane at right angles with the +plane of the needle's oscillation, it is evident that we +shall have obtained an apparatus that satisfies the +aforesaid conditions. It seems at first sight that in +such an instrument the directing force should be constant +from the moment the electro was saturated, and +it would be possible, were sufficiently thin cores +<a name="Page_8117" id="Page_8117"></a>used, to obtain a constancy in the directing magnetic +field for relatively feeble intensities. In reality, the +actions are more complex. The needle, <i>n s</i>, is, in fact, +induced to return to its position of equilibrium by +two forces, the first of which (the attraction of the +poles, N S) rapidly increases with the intensity so as +to become quickly and perceptibly constant, while the +second (the sum of the elementary electrodynamic +actions that are exerted between the spirals, <i>e e</i>, and +the needle, <i>n s</i>) increases proportionally to the intensity +of the current. If we represent these two sections +graphically by referring the magnetic moments as ordinates +and the current intensities as abscissas to two +co-ordinate axes (Fig. 2), we shall obtain for the first +force the curve, O A B, which, starting from A, becomes +sensibly parallel with the axis of X, and for the second +the right line, O D. The resultant action is represented +by the curve, O E E' F. It will be seen that this action, +far from being constant, increases quite rapidly with +the intensity of the current, so that the deflections +would become feebler and feebler for strong intensities, +of current; and this, as well known, would render +the apparatus very defective from a practical point of +view.</p> + +<div class="figcenter"><img src="./images/14g.png" alt="Fig. 2." /><br /> <span class="smcap">Fig.</span> 2.</div> + +<p>But the action of the spirals can be annulled without +sensibly diminishing the magnetism of the core +by arranging a second system of spirals identical with +the first, but placed in a plane at right angles therewith, +or, more simply still, by having a single system +of spirals comprising the coil of the electro-magnet, +but distributed in a plane that is oblique with respect +to the needle's position of rest. It then becomes possible, +by properly modifying such angle of inclination, +to obtain a total directing action that shall continue to +increase with the intensity, and which, graphically +represented, shall give the curve, O G G' H, for example +(Fig. 2).</p> + +<div class="figcenter"><img src="./images/14h.png" alt="Fig. 3." /><br /> <span class="smcap">Fig.</span> 3.</div> + +<div class="figcenter"><img src="./images/15a.png" alt="Fig. 4." /><br /> <span class="smcap">Fig.</span> 4.</div> + +<p>This arrangement, which is adopted in Mr. Kapp's +instruments, gives very good results, as may be easily +seen by reference to Figs. 3 and 4, in which the current +intensities or differences of potential are referred as +ordinates and the degrees of deflection of the needle as +abscissas. The unbroken lines represent the curves obtained +with the apparatus just described, while the +dotted ones give the curve of deflection of an ordinary +tangent galvanometer. These curves show that +for strong intensities of current Mr. Kapp's instrument +is more advantageous than the tangent galvanometer. +Mr. Crompton has constructed an amperemeter upon +the same principle, which is shown in Fig. 5.—<i>La +Lumiere Electrique.</i></p> + +<div class="figcenter"><img src="./images/15b.png" alt="Fig. 5." /><br /> <span class="smcap">Fig.</span> 5.</div> + +<hr /> + +<h2><a name="art03" id="art03"></a>THE CHEMICAL ACTION OF LIGHT.</h2> + +<p>Professor A. Vogel, in a communication to the +"Sitzungsberichte der Munchener Akademie," brings +into prominence the fact that the hemlock plant, which +yields coniine in Bavaria, contains none in Scotland. +Hence he concludes that solar light plays a part in the +generation of the alkaloids in plants. This view is +corroborated by the circumstance that the tropical +cinchonas, if cultivated in our feebly lighted hothouses, +yield scarcely any alkaloids. Prof. Vogel has proved +this experimentally. He has examined the barks of +cinchona plants obtained from different conservatories, +but has not found in any of them the characteristic reaction +of quinine. Of course it is still possible that +quinine might be discovered in other conservatory-grown +cinchonas, especially as the specimens operated +upon were not fully developed. But as the reaction +employed indicates very small quantities of quinine, it +may be safely assumed that the barks examined contained +not a trace of this alkaloid, and it can scarcely +be doubted that the deficiency of sunlight in our +hothouses is one of the causes of the deficiency of +quinine.</p> + +<p>It will at once strike the reader as desirable that specimens +of cinchonas should be cultivated in hothouses +under the influence of the electric light, in addition to +that of the sun.</p> + +<p>If sunlight can be regarded as a factor in the formation +of alkaloids in the living plant, it has, on the other +hand, a decidedly injurious action upon the quinine in +the bark stripped from the tree. On drying such bark +in full sunlight the quinine is decomposed, and there +are formed dark-colored, amorphous, resin-like masses. +In the manufacture of quinine the bark is consequently +dried in darkness.</p> + +<p>This peculiar behavior of quinine on exposure to sunlight +finds its parallel in the behavior of chlorophyl +with the direct rays of the sun. It is well known that +the origin of chlorophyl in the plant is entirely connected +with light, so that etiolated leaves growing in +the dark form no chlorophyl. But as soon as chlorophyl +is removed from the sphere of vegetable life, a +brief exposure to the direct rays of the sun destroys its +green color completely.</p> + +<p>Prof. A. Vogel conjectures that the formation of tannin +in the living plant is to some extent influenced by light. +This supposition is supported by the fact that the proportion +of tannin in beech or larch bark increases from +below upward—that is, from the less illuminated to +the more illuminated parts, and this in the proportions +of 4:6 and 5:10.</p> + +<p>Sunny mountain slopes of a medium height yield, +according to wide experience, on an average the pine-barks +richest in tannin. In woods in level districts the +proportion of tannin is greatest in localities exposed to +the light, while darkness seems to have an unfavorable +effect. Here, also, we must refer to the observation that +leaves exceptionally exposed to the light are relatively +rich in tannin.</p> + +<p>We may here add that in the very frequent cases +where a leaf is shadowed by another in very close proximity, +or where a portion of a leaf has been folded over +by some insect, the portion thus shaded retains a pale +green color, while adjacent leaves, or other portions of +the same leaf, assume their yellow, red, or brown +autumnal tints. If, as seems highly probable, these +tints are due to transformation products of tannin, we +may not unnaturally conclude that they will be absent +where tannin has not been generated.—<i>Jour. of +Science.</i></p> + +<hr /> + +<h2><a name="art04" id="art04"></a>EUTEXIA.<a name="FNanchor_10" id="FNanchor_10"></a><a href="#Footnote_10"><sup>1</sup></a></h2> + +<h3>By <span class="smcap">Thomas Turner</span>, Assoc. R.S.M., F.C.S., +Demonstrator of Chemistry, Mason College.</h3> + +<p>There are a number of interesting facts, some of +which are known to most persons, and many of them +have been long recognized, of which, however, it must +be owned that the explanation is somewhat obscure, +and the connections existing between them have been +but recently pointed out. As an example of this, it is well +known that salt water freezes at a lower temperature +than fresh water, and hence sea-water may be quite +liquid while rivers and ponds are covered with ice. +Again, it is noticed that mixtures of salts often have a +fusing-point lower than that of either of the constituent +salts, and of this fact we often take advantage +in fluxing operations. Further, it is well known that +certain alloys can be prepared, the melting-points of +which are lower than the melting-point of either of +the constituent metals alone. Thus, while potassium +melts at 62.5° C., and sodium at about 98°, an alloy of +these metals is fluid at ordinary temperatures, and +fusible metal melts below the temperature of boiling +water, or more than 110° lower than the melting-point +of tin, the most fusible of the three metals which enter +into the composition of this alloy. But though these +and many similar facts have been long known, it is but +recently, owing largely to the labors of Dr. Guthrie, +that fresh truths have been brought to light, and a +connection shown to exist throughout the whole which +was previously unseen, though we have still to acknowledge +that at present there is much at the root of the +matter which is but imperfectly understood. Still Dr. +Guthrie proves a relationship to exist between the +several facts we have previously mentioned, and also +between a number of other phenomena which at first +sight appear to be equally isolated and unexpected, +and we are asked to regard them all as examples of +what he has called "eutexia."</p> + +<p>We may define a eutectic substance as a body composed +of two or more constituents, which constituents +are in such proportion to one another as to give to the +resultant compound body a minimum temperature of +liquefaction—that is, a lower temperature of liquefaction +than that given by any other proportion.<a name="FNanchor_11" id="FNanchor_11"></a><a href="#Footnote_11"><sup>2</sup></a> It will +be seen at once by this definition that the temperature +of liquefaction of a eutectic substance is lower than the +temperature of liquefaction of either or any of the constituents +of the mixture. And, further, it is plain that +those substances only can be eutectic which we can +obtain both as liquid and solid, and hence the property +of eutexia is closely connected with solution.</p> + +<p>Following in the natural divisions adopted by Dr. +Guthrie, we may consider eutexia in three aspects:</p> + +<h3>I. CRYOHYDRATES.</h3> + +<p>If a <i>dilute</i> aqueous saline solution be taken at ordinary +temperatures, and then slowly cooled to some +point below zero on the Centigrade scale, the following +series of changes will in general be observed: On reaching +a point below zero, the position of which is dependent +upon the nature of the salt and the amount of +dilution, it will be found that ice is formed; this will +float upon the surface of the solution, and may be +readily removed. If the ice so removed be afterward +pressed, or carefully drained, it will be found to consist +of nearly pure water, the liquid draining away being a +strong saline solution which had become mechanically +entangled among the crystals of ice during solidification. +If we further cool the brine which remains, we +notice a tolerably uniform fall of temperature with accompanying +formation of ice. But at length a point is +reached at which the temperature ceases to fall until +the whole of the remaining mother-liquor has solidified, +with the production of a compound called a cryohydrate,<a name="FNanchor_12" id="FNanchor_12"></a><a href="#Footnote_12"><sup>3</sup></a> +which possesses physical properties different +from those of either the ice or the salt from which it is +formed.</p> + +<p>If, on the other hand, we commence with a <i>saturated</i> +saline solution, in general it is noticed on cooling the +liquid a separation of salt ensues, which salt sinks to +the bottom of the mass, and may be removed. The +salt so separating may be either anhydrous or a +"hydrate" of greater concentration than the mother-liquor. +So long as this separation proceeds the temperature +falls, but at length a point is reached at which +the thermometer remains stationary until the whole is +solidified, with the production of a cryohydrate. This +temperature of solidification is the same whether we +start with a dilute or a saturated solution, and the +composition of the cryohydrate is found to be constant. +The temperature of production of the cryohydrate is +identical with the lowest temperature which can be +produced on employing a mixture of ice and the salt as +a freezing mixture or cryogen.</p> + +<p>It will be readily seen that in the formation of a +cryohydrate we have an example of eutexia, since the +constituents are present in such proportion as to give to +the resultant compound body a minimum temperature +of liquefaction.</p> + +<h3>II. EUTECTIC SALT ALLOYS.<a name="FNanchor_13" id="FNanchor_13"></a><a href="#Footnote_13"><sup>4</sup></a></h3> + +<p>Although it has been long known that on mixing +certain salts the resulting substance possessed a lower +melting-point than either of the constituent salts alone, +still but few determinations of the melting-points of +mixtures of salts have been made, and even these are +often of small value, on account of the very considerable +range of temperature observed during solidification. +This is due largely to the fact that eutectic mixtures +were not known, as equivalent proportions of +various salts have been employed, while eutectic mixtures +are seldom found to possess any simple arithmetical +molecular relationship between their constituents.</p> + +<p>Eutectic salt alloys closely resemble cryohydrates in +behavior. If for simplicity we confine our attention to +a fused mixture of two salts in any proportion other +than eutectic, it is found that, on cooling, the thermometer +falls steadily, until at length that salt which is in +excess of the proportion required for a eutectic mixture +begins to separate out. If this is removed, the thermometer +falls until a fixed point is reached at which the +temperature remains stationary until the whole of the +<a name="Page_8118" id="Page_8118"></a>mixture solidifies. On remelting, the temperature of +solidification is found to be quite fixed, and the mixture +is evidently eutectic.</p> + +<p>It is of interest to notice that from our knowledge of +the cryohydrates it becomes possible to predict the +existence, composition, and temperature of solidification +of a eutectic alloy, if we are previously furnished +with the melting-points of mixtures of the substances +in question. Or, in other cases, we may predict from +the curve of melting-points that no eutectic alloy is +possible.</p> + +<p>As an example, we may take the determinations of +the melting-points of mixtures of potassium and sodium +nitrate by M. Maumené.<a name="FNanchor_14" id="FNanchor_14"></a><a href="#Footnote_14"><sup>5</sup></a> These are graphically represented +in Fig. 1, the curve being derived from the mean +of the temperatures given in the memoir. From this +diagram we should be led to expect a eutectic mixture, +since the curve dips below a horizontal line passing +through the melting-point of the more fusible of its +constituents. From our curve we should expect a +eutectic mixture with about 35 per cent. KNO<sub>3</sub>, and +with a temperature of solidification below 233°. Dr. +Guthrie gives 32.9 per cent. at 215°. This agreement is +as good as might be expected when one remembers +that the melting-points, not being of eutectic mixtures, +are difficult to determine, and a considerable range is +given; that analyses of mixtures of potassium and +sodium salts are apt to vary; and that the two +observers differ by ±7° in the temperatures given for +the melting-points of the original salts.</p> + +<div class="figcenter"><img src="./images/15c.png" alt="Fig. 1." /><br /> <span class="smcap">Fig.</span> 1.</div> + +<p>Dr. Tilden has drawn my attention to an interesting +example of the lowering of melting-point by the mixture +of salts. The melting-point of monohydrochloride +of turpentine oil is 125°, while that of the dihydrochloride +is 50°; but on simply stirring together these +compounds in a mortar at common temperatures, they +immediately liquefy. Two molecules of the monohydrochloride +and one molecule of the dihydrochloride form +a mixture which melts at about 20°.</p> + +<h3>III. EUTECTIC METALLIC ALLOYS.</h3> + +<p>Although many fusible alloys have been long known, +I believe no true eutectic metallic alloy had been +studied until Dr. Guthrie<a name="FNanchor_15" id="FNanchor_15"></a><a href="#Footnote_15"><sup>6</sup></a> worked at the subject, employing +the same methods as with his cryohydrates. It +is found if two metals are fused together and the mixture +allowed to cool, that the temperature falls until a +point is reached at which that metal which is present +in a proportion greater than is required to form the +eutectic alloy begins to separate. If this solid be removed +as it forms, the temperature gradually falls +until a fixed point is reached, at which the eutectic +alloy solidifies. Here the thermometer remains stationary +until the whole has become solid, and, on remelting, +this temperature is found to be quite fixed. In +addition to the di-eutectic alloys, we have also tri- and +tetra-eutectic alloys, and as an example of the latter +we may take the bismuth-tin-lead-cadmium eutectic +alloy, melting at 71°.</p> + +<p>We have already seen with salt eutectics that, given +the curve of melting-points of a mixture in various proportions, +we may predict the existence, composition, +and melting-point of the eutectic alloy. As a matter +of course, the same thing holds good for metallic +eutectics. An interesting example of this is furnished +by the tin-lead alloys, the melting-points of which +have been determined by Pillichody.<a name="FNanchor_16" id="FNanchor_16"></a><a href="#Footnote_16"><sup>7</sup></a> From these +determinations we obtain the curve given in Fig. 2, +and from this curve, since it dips below a horizontal +line passing through the melting-point of the more +fusible constituent, we are at once able to predict a +eutectic alloy. We should further expect this to have +a constitution between PbSn<sub>3</sub> and PbSn<sub>4</sub> and a melting-point +somewhat below 181°. On melting together +tin and lead, and allowing the alloy to cool, we find our +expectation justified; for by pouring off the fluid portion +which remains after solidification has commenced, +and repeating this several times with the portion so removed, +we at length obtain an alloy which solidifies at +the constant temperature of 180°, when the melting-point +of tin is taken as 228°. On analysis 1.064 grm. +of this alloy gave 0.885 grm. SnO<sub>2</sub>, which corresponds +to Sn 65.43 per cent., or PbSn<sub>3.3</sub>. This, therefore, is +the composition of the eutectic alloy, and it finds its +place naturally on the curve given in Fig. 2.</p> + + +<div class="figcenter"><img src="./images/15d.png" alt="Fig. 2." /><br /> <span class="smcap">Fig.</span> 2.</div> + +<p>It will be seen that the subject of eutexia embraces +many points of practical importance and of theoretical +interest. Thus it has been shown by Dr. Guthrie that +the desilverizing of lead in Pattinson's process is but a +case of eutexia, the separation of lead on cooling a bath +of argentiferous lead poor in silver being analogous to +the separation of ice from a salt solution. Dr. Guthrie +has also shown that eutexia may reasonably be supposed +to have played an important part in the production +and separation of many rock-forming minerals.</p> + +<p>It is with considerable diffidence that I suggest the +following as an explanation of the multitude of facts to +which previous reference has been made.</p> + +<p>In a mixture of two substances, A and B, we have +the following forces active, tending to produce solidification:</p> + +<div class="note"> +<p>1. The cohesion between the particles of A.</p> + +<p>2. The cohesion between the particles of B.</p> + +<p>3. The cohesion between the particles of A and the +particles of B.</p> +</div> + +<p>With regard to this last factor, it will be seen that +there are three cases possible:</p> + +<div class="note"> +<p>1. The cohesion of the mixture A B may be greater +than the cohesion of A + the cohesion of B.</p> + +<p>2. The cohesion of A B may be equal to the cohesion +of A + the cohesion of B.</p> + +<p>3. The cohesion of A B may be less than the cohesion +of A + the cohesion of B.</p> +</div> + +<p>Now, since cohesion tends to produce solidification, +we should in the first case expect to find the melting-point +of the mixture <i>higher</i> than the mean of the +melting-points of its constituents, or the curve of melting-points +would be of the form given in <i>a</i>, Fig. 3. +Here no eutectic mixture is possible.</p> + +<div class="figcenter"><img src="./images/15e.png" alt="Fig. 3." /><br /> <span class="smcap">Fig.</span> 3.</div> + +<p>In the second case, where cohesionA B = cohesion +A + B, we should obtain melting-points for the mixture +which would agree with the mean of the melting-points +of the constituents, the curve of melting-points +would be a straight line, and again no eutectic mixture +would be possible.</p> + +<p>In the third case, however, where cohesionA B is +less than cohesion A + B, we should find the melting-points +of the mixture lower than the mean of the melting-points +of its constituents, and the curve of melting-points +would be of the form given in <i>e</i>, Fig. 3. Here, +in those cases where the difference of cohesion on mixture +is considerable, the curve of melting-points may +dip below the line <i>e f</i>. This is the <i>only case</i> in which a +eutectic mixture is possible, and it is, of course, found +at the lowest point of the curve.</p> + +<p>If it be true, as above suggested, that the force of +cohesion is at its minimum in the eutectic alloy, we +should expect to find, in preparing a eutectic substance, +either that actual expansion took place, or that the +molecular volume would gradually increase in passing +along our curve of melting-points, from either end, for +each molecule added, and that it would obtain its +greatest value at the point corresponding to the eutectic +alloy.</p> + +<p>Of this I have no direct evidence as yet, but it is a +point of considerable interest, and I may possibly return +to it at some future time.—<i>Chemical News.</i></p> + +<p><a name="Footnote_10" id="Footnote_10"></a><a href="#FNanchor_10">[1]</a></p><div class="note"><p>Read before the Birmingham Philosophical Society, January 22, 1885.</p></div> + +<p><a name="Footnote_11" id="Footnote_11"></a><a href="#FNanchor_11">[2]</a></p><div class="note"><p>Guthrie, <i>Phil. Mag.</i> [5], xvii., p. 462.</p></div> + +<p><a name="Footnote_12" id="Footnote_12"></a><a href="#FNanchor_12">[3]</a></p><div class="note"><p>Guthrie, <i>Phil. Mag.</i>, 4th Series, xlix., pp. 1, 206, 266; 5th Series, i., pp. 49, 354, 446, vi., p. 35.</p></div> + +<p><a name="Footnote_13" id="Footnote_13"></a><a href="#FNanchor_13">[4]</a></p><div class="note"><p>F. Guthrie, <i>Phil. Mag.</i> [5], xvii., +<ins class="trans" title="Transcriber's Note: First digit of page number obscured in two different copies. '4' is best guess.">p. 469</ins>; F.B. Guthrie, <i>Journ. Chem. Soc</i>,. 1885, p. 94.</p></div> + +<p><a name="Footnote_14" id="Footnote_14"></a><a href="#FNanchor_14">[5]</a></p><div class="note"><p><i>Comptes Rendus</i>, 1883, 2, p. 45.</p></div> + +<p><a name="Footnote_15" id="Footnote_15"></a><a href="#FNanchor_15">[6]</a></p><div class="note"><p><i>Phil. Mag.</i>, 5th Series, xvii., p. 462.</p></div> + +<p><a name="Footnote_16" id="Footnote_16"></a><a href="#FNanchor_16">[7]</a></p><div class="note"><p><i>Dingler's Polyt. Jour.</i>, 162, p. 217; <i>Jahresberichte</i>, 1861, p. 279.</p></div> + +<hr /> + +<h2><a name="art05" id="art05"></a>CHINOLINE.</h2> + +<p>Dr. Conrad Berens, of the University of Pennsylvania, +reaches the following:</p> + +<p>1. Chinoline tartrate is a powerful agent, producing +death by asphyxia.</p> + +<p>2. The drug increases the force and frequency of the +respirations by stimulating the vagus roots in the +lung.</p> + +<p>3. It paralyzes respiration finally by a secondary +depressant action upon the respiratory center.</p> + +<p>4. It does not cause convulsions.</p> + +<p>5. It lessens and finally abolishes reflex action by a +direct action upon the cord, and by a slight action +upon the muscles and nerves.</p> + +<p>6. It diminishes or abolishes muscular contractility +respectively when applied through the circulation or +directly.</p> + +<p>7. It coagulates myosin and albumen.</p> + +<p>8. It causes insalivation by paralysis of the secretory +fibers of the chorda tympani; increases the flow of +bile; has no action upon the spleen.</p> + +<p>9. It lowers blood-pressure by paralyzing the vaso-motor +centers and by a direct depressant action upon +the heart muscle.</p> + +<p>10. It diminishes the pulse rate by direct action upon +the heart.</p> + +<p>11. It lowers the temperature by increasing the loss +of heat.</p> + +<p>12. It is a powerful antiseptic; and, finally,</p> + +<p>13. Its paths of elimination are not known.</p> + + +<hr /> + +<h2><a name="art06" id="art06"></a>METHOD FOR RAPID ESTIMATION OF UREA.</h2> + +<p>Being called upon to make a good many brief and +rapid analyses of urine on "clinic days" of our medical +department, I devised the following modification of +Knop's method of estimating urea; and after using it +for a year with perfectly satisfactory results, venture +to describe and recommend it as especially adapted for +physicians' use, by reason of simplicity, cheapness, and +accuracy. In perfecting and testing it I was assisted +greatly by J. Torrey, Jr., then working with me.</p> + +<div class="figleft"><img src="./images/16.png" alt="" /></div> + +<p>The apparatus consists of the glass tube, A, which is +about 8 cm. long and 2½ cm. in diameter, joined to the +tube, B, which is about 25 or 30 cm. in length in its +longer arm and 8 or 10 in its shorter, and has a diameter +of about 5 mm. Near the bend is an outlet +tube, <i>c</i>, provided with "ball valve" or pinch cock. <i>d</i>, +e, <i>f</i>, <i>g</i>, are marks upon the tubes. C is a rubber cork +with two holes through which the bent tube, D, +passes. D is of such size and length as to hold about +1 c.c., and one of its ends may be a trifle longer than +the other.</p> + +<p>The apparatus is used as follows: Remove the cork +and pour in mercury until it stands at <i>e</i> and <i>g</i>, then fill +up to the mark, <i>f</i>, with sodium or potassium hypobromite +(made by shaking up bromine with a strong +solution of sodium or potassium hydroxide). Next +carefully fill the tube in the cork with the urine, being +careful especially not to run it over or leave air +bubbles in it. This can easily be done by using a +small pipette, but if accidentally a little runs over, it +should be wiped off the end of the cork with blotting +paper. The cork is then to be inserted closely into the +tube; the urine tube being so small, the urine will not +run out in so doing. The mercury is then drawn out +through <i>c</i> till it stands in B at <i>d</i>. Its level in A will of +course not be changed greatly. Now, incline the apparatus +till the surface of the hypobromite touches the +urine in the longer part of the urine tube, and then +bring it upright again. The urine will thus be discharged +into the hypobromite, which will of course +decompose the urea, liberating nitrogen, which will +cause the mercury to rise in B. Shake until no further +change of level is seen, and mark the level of mercury in +B with a rubber band, then remove the cork, draw out +the liquid with a pipette, dry out the tube above the +mercury with scrap of blotting paper, pour back the +mercury drawn out, and repeat the process to be sure +that no error was made.</p> + +<p>If now two or three marks have been made upon the +tube, B, indicating the height of the mercury when solutions +containing known per cents. of urea are used, +an accurate opinion can be at once formed as to the +condition of the urine as regards urea.</p> + +<p>As is well known, normal urine contains about 2.5-3 +per cent. of urea, so that graduations representing 2, 2.5, +3, and 4 per cent. are usually all that are needed, though +of course many more can be easily made.</p> + +<p>The results obtained with this apparatus have been +repeatedly compared with those of more elaborate +ones, and no practical difference observed. Evidently +the same apparatus, differently graduated, might be +employed to determine the carbonate present in such a +substance as crude soda ash or other similar mixture. +In such a case the weighed material would be put +upon the mercury with water and the small tube filled +with acid.</p> + +<p>Bowdoin College Chemical Laboratory.</p> +<p class="signature">—<i>F.C. +Robinson, in Amer. Chem. Jour.</i></p> + +<hr /> + +<p>A <span class="smcap">Catalogue</span> containing brief notices of many important +scientific papers heretofore published in the +<span class="smcap">Supplement</span>, may be had gratis at this office.</p> + +<hr /> + +<h3>THE</h3> +<h2>Scientific American Supplement.</h2> +<h3>PUBLISHED WEEKLY.</h3> + +<div class="center">Terms of Subscription, $5 a year.</div> + +<p>Sent by mail, postage prepaid, to subscribers in any +part of the United States or Canada. Six dollars a +year, sent, prepaid, to any foreign country.</p> + +<p>All the back numbers of <span class="smcap">The Supplement</span>, from the +commencement, January 1, 1876, can be had. Price, +10 cents each.</p> + +<p>All the back volumes of <span class="smcap">The Supplement</span> can likewise +be supplied. Two volumes are issued yearly. +Price of each volume, $2.50 stitched in paper, or $3.50 +bound in stiff covers.</p> + +<p><span class="smcap">Combined Rates.</span>—One copy of <span class="smcap">Scientific American</span> +and one copy of <span class="smcap">Scientific American Supplement</span>, +one year, postpaid, $7.00.</p> + +<p>A liberal discount to booksellers, news agents, and +canvassers.</p> + +<p class="center"><b>MUNN & CO., Publishers</b>,<br /> +<b>361 Broadway. New York, N.Y.</b></p> + +<hr /> + + +<h2>PATENTS.</h2> + +<p>In connection with the <b>Scientific American</b>, Messrs. MUNN & +CO. are solicitors of American and Foreign Patents, have had 40 years' +experience, and now have the largest establishment in the world. Patents +are obtained on the best terms.</p> + +<p>A special notice is made in the <b>Scientific American</b> of all inventions +patented through this Agency, with the name and residence of the +Patentee. By the immense circulation thus given, public attention is directed +to the merits of the new patent, and sales or introduction often +easily effected.</p> + +<p>Any person who has made a new discovery or invention can ascertain, +free of charge, whether a patent can probably be obtained, by writing to +MUNN & CO.</p> + +<p>We also send free our Hand Book about the Patent Laws, Patents, +Caveats, Trade Marks, their costs, and how procured. Address</p> + +<p class="center"><b>Munn & Co., 361 Broadway, New York.</b></p> + +<p>Branch Office, cor. F and 7th Sts., Washington, D.C.</p> + + + + + + + +<pre> + + + + + +End of the Project Gutenberg EBook of Scientific American Supplement, No. +508, September 26, 1885, by Various + +*** END OF THIS PROJECT GUTENBERG EBOOK SCIENTIFIC AMERICAN *** + +***** This file should be named 16792-h.htm or 16792-h.zip ***** +This and all associated files of various formats will be found in: + https://www.gutenberg.org/1/6/7/9/16792/ + +Produced by Juliet Sutherland, Josephine Paolucci and the +Online Distributed Proofreading Team at www.pgdp.net + + +Updated editions will replace the previous one--the old editions +will be renamed. + +Creating the works from public domain print editions means that no +one owns a United States copyright in these works, so the Foundation +(and you!) can copy and distribute it in the United States without +permission and without paying copyright royalties. Special rules, +set forth in the General Terms of Use part of this license, apply to +copying and distributing Project Gutenberg-tm electronic works to +protect the PROJECT GUTENBERG-tm concept and trademark. Project +Gutenberg is a registered trademark, and may not be used if you +charge for the eBooks, unless you receive specific permission. If you +do not charge anything for copies of this eBook, complying with the +rules is very easy. You may use this eBook for nearly any purpose +such as creation of derivative works, reports, performances and +research. They may be modified and printed and given away--you may do +practically ANYTHING with public domain eBooks. Redistribution is +subject to the trademark license, especially commercial +redistribution. + + + +*** START: FULL LICENSE *** + +THE FULL PROJECT GUTENBERG LICENSE +PLEASE READ THIS BEFORE YOU DISTRIBUTE OR USE THIS WORK + +To protect the Project Gutenberg-tm mission of promoting the free +distribution of electronic works, by using or distributing this work +(or any other work associated in any way with the phrase "Project +Gutenberg"), you agree to comply with all the terms of the Full Project +Gutenberg-tm License (available with this file or online at +https://gutenberg.org/license). + + +Section 1. General Terms of Use and Redistributing Project Gutenberg-tm +electronic works + +1.A. By reading or using any part of this Project Gutenberg-tm +electronic work, you indicate that you have read, understand, agree to +and accept all the terms of this license and intellectual property +(trademark/copyright) agreement. If you do not agree to abide by all +the terms of this agreement, you must cease using and return or destroy +all copies of Project Gutenberg-tm electronic works in your possession. +If you paid a fee for obtaining a copy of or access to a Project +Gutenberg-tm electronic work and you do not agree to be bound by the +terms of this agreement, you may obtain a refund from the person or +entity to whom you paid the fee as set forth in paragraph 1.E.8. + +1.B. "Project Gutenberg" is a registered trademark. It may only be +used on or associated in any way with an electronic work by people who +agree to be bound by the terms of this agreement. There are a few +things that you can do with most Project Gutenberg-tm electronic works +even without complying with the full terms of this agreement. See +paragraph 1.C below. There are a lot of things you can do with Project +Gutenberg-tm electronic works if you follow the terms of this agreement +and help preserve free future access to Project Gutenberg-tm electronic +works. See paragraph 1.E below. + +1.C. The Project Gutenberg Literary Archive Foundation ("the Foundation" +or PGLAF), owns a compilation copyright in the collection of Project +Gutenberg-tm electronic works. Nearly all the individual works in the +collection are in the public domain in the United States. If an +individual work is in the public domain in the United States and you are +located in the United States, we do not claim a right to prevent you from +copying, distributing, performing, displaying or creating derivative +works based on the work as long as all references to Project Gutenberg +are removed. Of course, we hope that you will support the Project +Gutenberg-tm mission of promoting free access to electronic works by +freely sharing Project Gutenberg-tm works in compliance with the terms of +this agreement for keeping the Project Gutenberg-tm name associated with +the work. You can easily comply with the terms of this agreement by +keeping this work in the same format with its attached full Project +Gutenberg-tm License when you share it without charge with others. + +1.D. The copyright laws of the place where you are located also govern +what you can do with this work. Copyright laws in most countries are in +a constant state of change. If you are outside the United States, check +the laws of your country in addition to the terms of this agreement +before downloading, copying, displaying, performing, distributing or +creating derivative works based on this work or any other Project +Gutenberg-tm work. The Foundation makes no representations concerning +the copyright status of any work in any country outside the United +States. + +1.E. Unless you have removed all references to Project Gutenberg: + +1.E.1. The following sentence, with active links to, or other immediate +access to, the full Project Gutenberg-tm License must appear prominently +whenever any copy of a Project Gutenberg-tm work (any work on which the +phrase "Project Gutenberg" appears, or with which the phrase "Project +Gutenberg" is associated) is accessed, displayed, performed, viewed, +copied or distributed: + +This eBook is for the use of anyone anywhere at no cost and with +almost no restrictions whatsoever. You may copy it, give it away or +re-use it under the terms of the Project Gutenberg License included +with this eBook or online at www.gutenberg.org + +1.E.2. If an individual Project Gutenberg-tm electronic work is derived +from the public domain (does not contain a notice indicating that it is +posted with permission of the copyright holder), the work can be copied +and distributed to anyone in the United States without paying any fees +or charges. If you are redistributing or providing access to a work +with the phrase "Project Gutenberg" associated with or appearing on the +work, you must comply either with the requirements of paragraphs 1.E.1 +through 1.E.7 or obtain permission for the use of the work and the +Project Gutenberg-tm trademark as set forth in paragraphs 1.E.8 or +1.E.9. + +1.E.3. If an individual Project Gutenberg-tm electronic work is posted +with the permission of the copyright holder, your use and distribution +must comply with both paragraphs 1.E.1 through 1.E.7 and any additional +terms imposed by the copyright holder. Additional terms will be linked +to the Project Gutenberg-tm License for all works posted with the +permission of the copyright holder found at the beginning of this work. + +1.E.4. Do not unlink or detach or remove the full Project Gutenberg-tm +License terms from this work, or any files containing a part of this +work or any other work associated with Project Gutenberg-tm. + +1.E.5. Do not copy, display, perform, distribute or redistribute this +electronic work, or any part of this electronic work, without +prominently displaying the sentence set forth in paragraph 1.E.1 with +active links or immediate access to the full terms of the Project +Gutenberg-tm License. + +1.E.6. You may convert to and distribute this work in any binary, +compressed, marked up, nonproprietary or proprietary form, including any +word processing or hypertext form. However, if you provide access to or +distribute copies of a Project Gutenberg-tm work in a format other than +"Plain Vanilla ASCII" or other format used in the official version +posted on the official Project Gutenberg-tm web site (www.gutenberg.org), +you must, at no additional cost, fee or expense to the user, provide a +copy, a means of exporting a copy, or a means of obtaining a copy upon +request, of the work in its original "Plain Vanilla ASCII" or other +form. Any alternate format must include the full Project Gutenberg-tm +License as specified in paragraph 1.E.1. + +1.E.7. Do not charge a fee for access to, viewing, displaying, +performing, copying or distributing any Project Gutenberg-tm works +unless you comply with paragraph 1.E.8 or 1.E.9. + +1.E.8. You may charge a reasonable fee for copies of or providing +access to or distributing Project Gutenberg-tm electronic works provided +that + +- You pay a royalty fee of 20% of the gross profits you derive from + the use of Project Gutenberg-tm works calculated using the method + you already use to calculate your applicable taxes. The fee is + owed to the owner of the Project Gutenberg-tm trademark, but he + has agreed to donate royalties under this paragraph to the + Project Gutenberg Literary Archive Foundation. Royalty payments + must be paid within 60 days following each date on which you + prepare (or are legally required to prepare) your periodic tax + returns. Royalty payments should be clearly marked as such and + sent to the Project Gutenberg Literary Archive Foundation at the + address specified in Section 4, "Information about donations to + the Project Gutenberg Literary Archive Foundation." + +- You provide a full refund of any money paid by a user who notifies + you in writing (or by e-mail) within 30 days of receipt that s/he + does not agree to the terms of the full Project Gutenberg-tm + License. You must require such a user to return or + destroy all copies of the works possessed in a physical medium + and discontinue all use of and all access to other copies of + Project Gutenberg-tm works. + +- You provide, in accordance with paragraph 1.F.3, a full refund of any + money paid for a work or a replacement copy, if a defect in the + electronic work is discovered and reported to you within 90 days + of receipt of the work. + +- You comply with all other terms of this agreement for free + distribution of Project Gutenberg-tm works. + +1.E.9. If you wish to charge a fee or distribute a Project Gutenberg-tm +electronic work or group of works on different terms than are set +forth in this agreement, you must obtain permission in writing from +both the Project Gutenberg Literary Archive Foundation and Michael +Hart, the owner of the Project Gutenberg-tm trademark. Contact the +Foundation as set forth in Section 3 below. + +1.F. + +1.F.1. Project Gutenberg volunteers and employees expend considerable +effort to identify, do copyright research on, transcribe and proofread +public domain works in creating the Project Gutenberg-tm +collection. Despite these efforts, Project Gutenberg-tm electronic +works, and the medium on which they may be stored, may contain +"Defects," such as, but not limited to, incomplete, inaccurate or +corrupt data, transcription errors, a copyright or other intellectual +property infringement, a defective or damaged disk or other medium, a +computer virus, or computer codes that damage or cannot be read by +your equipment. + +1.F.2. LIMITED WARRANTY, DISCLAIMER OF DAMAGES - Except for the "Right +of Replacement or Refund" described in paragraph 1.F.3, the Project +Gutenberg Literary Archive Foundation, the owner of the Project +Gutenberg-tm trademark, and any other party distributing a Project +Gutenberg-tm electronic work under this agreement, disclaim all +liability to you for damages, costs and expenses, including legal +fees. YOU AGREE THAT YOU HAVE NO REMEDIES FOR NEGLIGENCE, STRICT +LIABILITY, BREACH OF WARRANTY OR BREACH OF CONTRACT EXCEPT THOSE +PROVIDED IN PARAGRAPH F3. YOU AGREE THAT THE FOUNDATION, THE +TRADEMARK OWNER, AND ANY DISTRIBUTOR UNDER THIS AGREEMENT WILL NOT BE +LIABLE TO YOU FOR ACTUAL, DIRECT, INDIRECT, CONSEQUENTIAL, PUNITIVE OR +INCIDENTAL DAMAGES EVEN IF YOU GIVE NOTICE OF THE POSSIBILITY OF SUCH +DAMAGE. + +1.F.3. LIMITED RIGHT OF REPLACEMENT OR REFUND - If you discover a +defect in this electronic work within 90 days of receiving it, you can +receive a refund of the money (if any) you paid for it by sending a +written explanation to the person you received the work from. If you +received the work on a physical medium, you must return the medium with +your written explanation. The person or entity that provided you with +the defective work may elect to provide a replacement copy in lieu of a +refund. If you received the work electronically, the person or entity +providing it to you may choose to give you a second opportunity to +receive the work electronically in lieu of a refund. If the second copy +is also defective, you may demand a refund in writing without further +opportunities to fix the problem. + +1.F.4. Except for the limited right of replacement or refund set forth +in paragraph 1.F.3, this work is provided to you 'AS-IS' WITH NO OTHER +WARRANTIES OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO +WARRANTIES OF MERCHANTIBILITY OR FITNESS FOR ANY PURPOSE. + +1.F.5. Some states do not allow disclaimers of certain implied +warranties or the exclusion or limitation of certain types of damages. +If any disclaimer or limitation set forth in this agreement violates the +law of the state applicable to this agreement, the agreement shall be +interpreted to make the maximum disclaimer or limitation permitted by +the applicable state law. The invalidity or unenforceability of any +provision of this agreement shall not void the remaining provisions. + +1.F.6. INDEMNITY - You agree to indemnify and hold the Foundation, the +trademark owner, any agent or employee of the Foundation, anyone +providing copies of Project Gutenberg-tm electronic works in accordance +with this agreement, and any volunteers associated with the production, +promotion and distribution of Project Gutenberg-tm electronic works, +harmless from all liability, costs and expenses, including legal fees, +that arise directly or indirectly from any of the following which you do +or cause to occur: (a) distribution of this or any Project Gutenberg-tm +work, (b) alteration, modification, or additions or deletions to any +Project Gutenberg-tm work, and (c) any Defect you cause. + + +Section 2. Information about the Mission of Project Gutenberg-tm + +Project Gutenberg-tm is synonymous with the free distribution of +electronic works in formats readable by the widest variety of computers +including obsolete, old, middle-aged and new computers. It exists +because of the efforts of hundreds of volunteers and donations from +people in all walks of life. + +Volunteers and financial support to provide volunteers with the +assistance they need, is critical to reaching Project Gutenberg-tm's +goals and ensuring that the Project Gutenberg-tm collection will +remain freely available for generations to come. In 2001, the Project +Gutenberg Literary Archive Foundation was created to provide a secure +and permanent future for Project Gutenberg-tm and future generations. +To learn more about the Project Gutenberg Literary Archive Foundation +and how your efforts and donations can help, see Sections 3 and 4 +and the Foundation web page at https://www.pglaf.org. + + +Section 3. Information about the Project Gutenberg Literary Archive +Foundation + +The Project Gutenberg Literary Archive Foundation is a non profit +501(c)(3) educational corporation organized under the laws of the +state of Mississippi and granted tax exempt status by the Internal +Revenue Service. The Foundation's EIN or federal tax identification +number is 64-6221541. Its 501(c)(3) letter is posted at +https://pglaf.org/fundraising. Contributions to the Project Gutenberg +Literary Archive Foundation are tax deductible to the full extent +permitted by U.S. federal laws and your state's laws. + +The Foundation's principal office is located at 4557 Melan Dr. S. +Fairbanks, AK, 99712., but its volunteers and employees are scattered +throughout numerous locations. Its business office is located at +809 North 1500 West, Salt Lake City, UT 84116, (801) 596-1887, email +business@pglaf.org. Email contact links and up to date contact +information can be found at the Foundation's web site and official +page at https://pglaf.org + +For additional contact information: + Dr. Gregory B. Newby + Chief Executive and Director + gbnewby@pglaf.org + + +Section 4. Information about Donations to the Project Gutenberg +Literary Archive Foundation + +Project Gutenberg-tm depends upon and cannot survive without wide +spread public support and donations to carry out its mission of +increasing the number of public domain and licensed works that can be +freely distributed in machine readable form accessible by the widest +array of equipment including outdated equipment. Many small donations +($1 to $5,000) are particularly important to maintaining tax exempt +status with the IRS. + +The Foundation is committed to complying with the laws regulating +charities and charitable donations in all 50 states of the United +States. Compliance requirements are not uniform and it takes a +considerable effort, much paperwork and many fees to meet and keep up +with these requirements. We do not solicit donations in locations +where we have not received written confirmation of compliance. To +SEND DONATIONS or determine the status of compliance for any +particular state visit https://pglaf.org + +While we cannot and do not solicit contributions from states where we +have not met the solicitation requirements, we know of no prohibition +against accepting unsolicited donations from donors in such states who +approach us with offers to donate. + +International donations are gratefully accepted, but we cannot make +any statements concerning tax treatment of donations received from +outside the United States. U.S. laws alone swamp our small staff. + +Please check the Project Gutenberg Web pages for current donation +methods and addresses. Donations are accepted in a number of other +ways including including checks, online payments and credit card +donations. To donate, please visit: https://pglaf.org/donate + + +Section 5. General Information About Project Gutenberg-tm electronic +works. + +Professor Michael S. Hart was the originator of the Project Gutenberg-tm +concept of a library of electronic works that could be freely shared +with anyone. For thirty years, he produced and distributed Project +Gutenberg-tm eBooks with only a loose network of volunteer support. + + +Project Gutenberg-tm eBooks are often created from several printed +editions, all of which are confirmed as Public Domain in the U.S. +unless a copyright notice is included. Thus, we do not necessarily +keep eBooks in compliance with any particular paper edition. + + +Most people start at our Web site which has the main PG search facility: + + https://www.gutenberg.org + +This Web site includes information about Project Gutenberg-tm, +including how to make donations to the Project Gutenberg Literary +Archive Foundation, how to help produce our new eBooks, and how to +subscribe to our email newsletter to hear about new eBooks. + + +</pre> + +</body> +</html> diff --git a/16792-h/images/1.png b/16792-h/images/1.png Binary files differnew file mode 100644 index 0000000..78ac3b1 --- /dev/null +++ b/16792-h/images/1.png diff --git a/16792-h/images/10a.png b/16792-h/images/10a.png Binary files differnew file mode 100644 index 0000000..62a3f0b --- /dev/null +++ b/16792-h/images/10a.png diff --git a/16792-h/images/10a_th.png b/16792-h/images/10a_th.png Binary files differnew file mode 100644 index 0000000..ff45f9d --- /dev/null +++ b/16792-h/images/10a_th.png diff --git a/16792-h/images/10b.png b/16792-h/images/10b.png Binary files differnew file mode 100644 index 0000000..0a3aa14 --- /dev/null +++ b/16792-h/images/10b.png diff --git a/16792-h/images/11.png b/16792-h/images/11.png Binary files differnew file mode 100644 index 0000000..71a6812 --- /dev/null +++ b/16792-h/images/11.png diff --git a/16792-h/images/11_th.png b/16792-h/images/11_th.png Binary files differnew file mode 100644 index 0000000..991b190 --- /dev/null +++ b/16792-h/images/11_th.png diff --git a/16792-h/images/12a.png b/16792-h/images/12a.png Binary files differnew file mode 100644 index 0000000..208b74d --- /dev/null +++ b/16792-h/images/12a.png diff --git a/16792-h/images/12a_th.png b/16792-h/images/12a_th.png Binary files differnew file mode 100644 index 0000000..e406917 --- /dev/null +++ b/16792-h/images/12a_th.png diff --git a/16792-h/images/12b.png b/16792-h/images/12b.png Binary files differnew file mode 100644 index 0000000..3f33a33 --- /dev/null +++ b/16792-h/images/12b.png diff --git a/16792-h/images/12c.png b/16792-h/images/12c.png Binary files differnew file mode 100644 index 0000000..d5890ea --- /dev/null +++ b/16792-h/images/12c.png diff --git a/16792-h/images/13a.png b/16792-h/images/13a.png Binary files differnew file mode 100644 index 0000000..8b45b42 --- /dev/null +++ b/16792-h/images/13a.png diff --git a/16792-h/images/13b.png b/16792-h/images/13b.png Binary files differnew file mode 100644 index 0000000..75e6a16 --- /dev/null +++ b/16792-h/images/13b.png diff --git a/16792-h/images/13b_th.png b/16792-h/images/13b_th.png Binary files differnew file mode 100644 index 0000000..75de25c --- /dev/null +++ b/16792-h/images/13b_th.png diff --git a/16792-h/images/13c.png b/16792-h/images/13c.png Binary files differnew file mode 100644 index 0000000..575565f --- /dev/null +++ b/16792-h/images/13c.png diff --git a/16792-h/images/13d.png b/16792-h/images/13d.png Binary files differnew file mode 100644 index 0000000..16df490 --- /dev/null +++ b/16792-h/images/13d.png diff --git a/16792-h/images/13e.png b/16792-h/images/13e.png Binary files differnew file mode 100644 index 0000000..dabbafa --- /dev/null +++ b/16792-h/images/13e.png diff --git a/16792-h/images/14a.png b/16792-h/images/14a.png Binary files differnew file mode 100644 index 0000000..6448c69 --- /dev/null +++ b/16792-h/images/14a.png diff --git a/16792-h/images/14b.png b/16792-h/images/14b.png Binary files differnew file mode 100644 index 0000000..6960193 --- /dev/null +++ b/16792-h/images/14b.png diff --git a/16792-h/images/14c.png b/16792-h/images/14c.png Binary files differnew file mode 100644 index 0000000..cf1b7f9 --- /dev/null +++ b/16792-h/images/14c.png diff --git a/16792-h/images/14c_th.png b/16792-h/images/14c_th.png Binary files differnew file mode 100644 index 0000000..5bc7c3b --- /dev/null +++ b/16792-h/images/14c_th.png diff --git a/16792-h/images/14d.png b/16792-h/images/14d.png Binary files differnew file mode 100644 index 0000000..e840b40 --- /dev/null +++ b/16792-h/images/14d.png diff --git a/16792-h/images/14e.png b/16792-h/images/14e.png Binary files differnew file mode 100644 index 0000000..9bd0a1b --- /dev/null +++ b/16792-h/images/14e.png diff --git a/16792-h/images/14f.png b/16792-h/images/14f.png Binary files differnew file mode 100644 index 0000000..32bdc7e --- /dev/null +++ b/16792-h/images/14f.png diff --git a/16792-h/images/14g.png b/16792-h/images/14g.png Binary files differnew file mode 100644 index 0000000..a5ff20f --- /dev/null +++ b/16792-h/images/14g.png diff --git a/16792-h/images/14h.png b/16792-h/images/14h.png Binary files differnew file mode 100644 index 0000000..08b9828 --- /dev/null +++ b/16792-h/images/14h.png diff --git a/16792-h/images/15a.png b/16792-h/images/15a.png Binary files differnew file mode 100644 index 0000000..8136a2e --- /dev/null +++ b/16792-h/images/15a.png diff --git a/16792-h/images/15b.png b/16792-h/images/15b.png Binary files differnew file mode 100644 index 0000000..665c48c --- /dev/null +++ b/16792-h/images/15b.png diff --git a/16792-h/images/15c.png b/16792-h/images/15c.png Binary files differnew file mode 100644 index 0000000..a252caf --- /dev/null +++ b/16792-h/images/15c.png diff --git a/16792-h/images/15d.png b/16792-h/images/15d.png Binary files differnew file mode 100644 index 0000000..5dff9b7 --- /dev/null +++ b/16792-h/images/15d.png diff --git a/16792-h/images/15e.png b/16792-h/images/15e.png Binary files differnew file mode 100644 index 0000000..292e24c --- /dev/null +++ b/16792-h/images/15e.png diff --git a/16792-h/images/16.png b/16792-h/images/16.png Binary files differnew file mode 100644 index 0000000..2711644 --- /dev/null +++ b/16792-h/images/16.png diff --git a/16792-h/images/1_th.png b/16792-h/images/1_th.png Binary files differnew file mode 100644 index 0000000..05f6576 --- /dev/null +++ b/16792-h/images/1_th.png diff --git a/16792-h/images/2.png b/16792-h/images/2.png Binary files differnew file mode 100644 index 0000000..fa2b1e7 --- /dev/null +++ b/16792-h/images/2.png diff --git a/16792-h/images/2_th.png b/16792-h/images/2_th.png Binary files differnew file mode 100644 index 0000000..42b6e74 --- /dev/null +++ b/16792-h/images/2_th.png diff --git a/16792-h/images/3.png b/16792-h/images/3.png Binary files differnew file mode 100644 index 0000000..d9ccfcf --- /dev/null +++ b/16792-h/images/3.png diff --git a/16792-h/images/3_th.png b/16792-h/images/3_th.png Binary files differnew file mode 100644 index 0000000..6ed2121 --- /dev/null +++ b/16792-h/images/3_th.png diff --git a/16792-h/images/4.png b/16792-h/images/4.png Binary files differnew file mode 100644 index 0000000..b28690c --- /dev/null +++ b/16792-h/images/4.png diff --git a/16792-h/images/4_th.png b/16792-h/images/4_th.png Binary files differnew file mode 100644 index 0000000..f441670 --- /dev/null +++ b/16792-h/images/4_th.png diff --git a/16792-h/images/5.png b/16792-h/images/5.png Binary files differnew file mode 100644 index 0000000..ed03770 --- /dev/null +++ b/16792-h/images/5.png diff --git a/16792-h/images/5_th.png b/16792-h/images/5_th.png Binary files differnew file mode 100644 index 0000000..68b41dc --- /dev/null +++ b/16792-h/images/5_th.png diff --git a/16792-h/images/6.png b/16792-h/images/6.png Binary files differnew file mode 100644 index 0000000..e01bfd7 --- /dev/null +++ b/16792-h/images/6.png diff --git a/16792-h/images/6_th.png b/16792-h/images/6_th.png Binary files differnew file mode 100644 index 0000000..497b105 --- /dev/null +++ b/16792-h/images/6_th.png diff --git a/16792-h/images/7.png b/16792-h/images/7.png Binary files differnew file mode 100644 index 0000000..939341b --- /dev/null +++ b/16792-h/images/7.png diff --git a/16792-h/images/7_th.png b/16792-h/images/7_th.png Binary files differnew file mode 100644 index 0000000..cd96f85 --- /dev/null +++ b/16792-h/images/7_th.png diff --git a/16792-h/images/8.png b/16792-h/images/8.png Binary files differnew file mode 100644 index 0000000..deb48cf --- /dev/null +++ b/16792-h/images/8.png diff --git a/16792-h/images/8_th.png b/16792-h/images/8_th.png Binary files differnew file mode 100644 index 0000000..62b5abb --- /dev/null +++ b/16792-h/images/8_th.png diff --git a/16792-h/images/9a.png b/16792-h/images/9a.png Binary files differnew file mode 100644 index 0000000..4b5c152 --- /dev/null +++ b/16792-h/images/9a.png diff --git a/16792-h/images/9b.png b/16792-h/images/9b.png Binary files differnew file mode 100644 index 0000000..8ae38dd --- /dev/null +++ b/16792-h/images/9b.png diff --git a/16792-h/images/9c.png b/16792-h/images/9c.png Binary files differnew file mode 100644 index 0000000..be16bb7 --- /dev/null +++ b/16792-h/images/9c.png diff --git a/16792-h/images/9d.png b/16792-h/images/9d.png Binary files differnew file mode 100644 index 0000000..f40e749 --- /dev/null +++ b/16792-h/images/9d.png diff --git a/16792-h/images/title.png b/16792-h/images/title.png Binary files differnew file mode 100644 index 0000000..0990d7b --- /dev/null +++ b/16792-h/images/title.png diff --git a/16792-h/images/title_th.png b/16792-h/images/title_th.png Binary files differnew file mode 100644 index 0000000..1540012 --- /dev/null +++ b/16792-h/images/title_th.png |
