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+This eBook, including all associated images, markup, improvements,
+metadata, and any other content or labor, has been confirmed to be
+in the PUBLIC DOMAIN IN THE UNITED STATES.
+
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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #69084 (https://www.gutenberg.org/ebooks/69084)
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-The Project Gutenberg eBook of Engineers and their triumphs: the
-story of the locomotive, the steamship, bridge building, tunnel making,
-by F. M. Holmes
-
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world 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. If you are not located in the United States, you
-will have to check the laws of the country where you are located before
-using this eBook.
-
-Title: Engineers and their triumphs: the story of the locomotive, the
-       steamship, bridge building, tunnel making
-
-Author: F. M. Holmes
-
-Release Date: October 1, 2022 [eBook #69084]
-
-Language: English
-
-Produced by: Fiona Holmes and the Online Distributed Proofreading Team
-             at http://www.pgdp.net (This file was produced from images
-             generously made available by The Internet Archive/American
-             Libraries.)
-
-*** START OF THE PROJECT GUTENBERG EBOOK ENGINEERS AND THEIR TRIUMPHS:
-THE STORY OF THE LOCOMOTIVE, THE STEAMSHIP, BRIDGE BUILDING, TUNNEL
-MAKING ***
-
-
-
-Transcriber’s Notes
-
-Hyphenation has been standardised.
-
-The Transcriber has constructed a ‘List of Illustrations’, as none was
-supplied.
-
-Page 132 — changed possibilites to =possibilities=
-
-
-
-
-[Illustration: THE TOWER BRIDGE, LONDON, SHOWING THE BASCULES
-RAISED.]
-
-
-
-
-ENGINEERS
-
-AND
-
-THEIR TRIUMPHS:
-
-_THE STORY OF THE LOCOMOTIVE—THE STEAMSHIP—BRIDGE BUILDING—TUNNEL
-MAKING._
-
-BY
-
-F. M. HOLMES,
-
-AUTHOR OF “FOUR HEROES OF INDIA,” ETC.
-
-[Illustration]
-
-FLEMING H. REVELL COMPANY
-
-NEW YORK CHICAGO TORONTO
-
-_Publishers of Evangelical Literature._
-
-
-
-
-[Illustration]
-
-
-PREFACE.
-
-
-Without attempting to be exhaustive, this little book aims at
-describing in a purely popular and non-technical manner some of
-the great achievements of engineers, more particularly during the
-nineteenth century.
-
-The four departments chosen have been selected not in pursuance of any
-comprehensive plan, but because they present some of the more striking
-features of constructional effort. The term Engineering, however,
-includes the design and supervision of numerous works, such as roads
-and canals, docks and break-waters, machinery and mining, as well as
-steam-engines and steamships, bridges and tunnels.
-
-Information, in certain cases, has been gained at first-hand, and I
-have to acknowledge the courtesy of the managers of the Cunard and
-White Star Steamship Companies, Messrs. Maudslay, Sons & Field, and
-others, in supplying various particulars.
-
-The narrative concerning Henry Bell and the steamship _Comet_, and of
-his connection with Fulton, is chiefly based on a letter from Bell
-himself in the _Caledonian Mercury_ in 1816.
-
-The statement that Mr. Macgregor Laird was so largely instrumental in
-founding the British and American Steam Navigation Company is made on
-the authority of his daughter, Miss Eleanor Bristow Laird. An article
-on “The Genesis of the Steamship,” which I wrote in the _Gentleman’s
-Magazine_, brought a letter from that lady in which she declares
-that her father was the prime mover in founding the Company. He had
-had experience, in the Niger Expedition of 1832-33, of the behaviour
-of steamships both at sea and in the river, and from the date of
-his return to England she asserts he advocated the establishment of
-steam communication between England and America, against the active
-opposition of Dr. Lardner and others. “Macgregor Laird’s claim to the
-foremost place amongst all those (not excepting Brunel) who worked for
-the same object,” writes Miss Laird, “was clearly shown in a letter
-from the late Mr. Archibald Hamilton of 17 St. Helen’s Place, E.C., to
-the editor of the _Shipping and Mercantile Gazette_, in which paper it
-was published on 15th May, 1873.”
-
-It is not a little curious to note how, in many of these great
-undertakings, several minds seem to have been working to the same end
-at about the same time. It was so with George Stephenson and others
-with regard to the locomotive, with Miller and Symington, Bell and
-Fulton, with regard to the steamship, with Laird and Brunel as regards
-transatlantic steam navigation, with Robert Stephenson and William
-Fairbairn as regards the tubular bridge.
-
-This volume does not seek to be the special advocate of any, or to
-enter into any minute details, but simply endeavours to gather up the
-more salient features and weave them into a connected and popular
-narrative.
-
-F. M. HOLMES.
-
-
-
-
-[Illustration]
-
-
-CONTENTS.
-
-
-THE STORY OF THE LOCOMOTIVE.
-
-CHAPTER PAGE
-
-I. FIRST STEPS, 9
-
-II. GLANCING BACKWARDS AND STRUGGLING FORWARDS, 19
-
-III. FIFTEEN MILES AN HOUR, 28
-
-IV. A MARVEL OF MECHANISM, 36
-
-V. A MILE A MINUTE, 46
-
-
-THE STORY OF THE STEAMSHIP.
-
-I. THE “COMET” APPEARS, 53
-
-II. TO THE NARROW SEAS, 60
-
-III. ON THE OPEN OCEAN, 68
-
-IV. THE OCEAN RACE, 74
-
-V. BEFORE THE FURNACE, 85
-
-
-FAMOUS BRIDGES AND THEIR BUILDERS.
-
-I. “THE BRIDGE BY THE EARTHEN HOUSE,” 101
-
-II. A NEW IDEA—THE BRITANNIA TUBULAR, 108
-
-III. LATTICE AND SUSPENSION BRIDGES, 119
-
-IV. THE GREATEST BRIDGE IN THE WORLD, 125
-
-V. THE TOWER BRIDGE, 133
-
-
-REMARKABLE TUNNELS AND THEIR CONSTRUCTION.
-
-I. HOW BRUNEL MADE A BORING-SHIELD, 137
-
-II. UNDER THE RIVER, 141
-
-III. THROUGH THE ALPS, 147
-
-IV. UNDER WATER AGAIN, 153
-
-[Illustration]
-
-
-List of Illustrations
-
-The Tower Bridge, London, showing the bascules raised. iii
-
-George Stephenson. 11
-
-“Puffing Billy,” the oldest locomotive engine in existence. 13
-
-James Watt. 21
-
-Edward Pease. 27
-
-The compound locomotive “Greater Britain.” 41
-
-Back and front view of the locomotive “Greater Britain.” 44
-
-The “Flying Dutchman.” 50
-
-Bell’s “Comet.” 55
-
-Robert Fulton. 59
-
-The ice-bound “Britannia” at Boston. 77
-
-Isambard Kingdom Brunel. 80
-
-The “Great Eastern.” 83
-
-High and low pressure cylinders of the “Campania’s” engines. 87
-
-The “Campania.” 89
-
-Stoke Hole. 93
-
-Promenade deck of the “Paris.” 99
-
-Pontypridd Bridge. 102
-
-The Post Bridge, Dartmoor. 105
-
-Robert Stephenson. 111
-
-The Britannia Tubular Bridge. 115
-
-Victoria Tubular Bridge, Montreal. 117
-
-The Clifton Bridge. 122
-
-The Brooklyn Bridge. 123
-
-The Forth Bridge. 129
-
-The Thames Tunnel. 143
-
-Boring machine used for the Mont Cenis Tunnel. 149
-
-The entrance to the air-lock. 155
-
-The boring machine used in the preliminary construction of the English
-Channel Tunnel. 159
-
-
-[Illustration]
-
-
-ENGINEERS AND THEIR TRIUMPHS.
-
-
-
-
-THE STORY OF THE LOCOMOTIVE.
-
-
-
-
-CHAPTER I.
-
-FIRST STEPS.
-
-
-“I think I could make a better engine than that.”
-
-“Do you? Well, some’ing’s wanted; hauling coal by horses is very
-expensive.”
-
-“Ay, it is, and I think an engine could do it better.”
-
-“Mr. Blackett’s second engine burst all to pieces; d’ye mind that?”
-
-“How came that about?”
-
-“Tommy Waters, who put it together, could not make it go, so he got
-a bit fractious and said she should move. He did some’ing to the
-safety-valve and she did begin to work, but then she burst all to
-pieces.”
-
-“Ay, ay, but this one is an improvement.”
-
-“It had need be. Even the third was a perfect plague.”
-
-“What! you mean Mr. Blackett’s third engine?”
-
-“Ay. It used to draw eight or nine truck loads at about a mile an hour,
-or a little less; but it often got cranky and stood still.”
-
-“Stood still!”
-
-“Ay; we thought she would never stick to the road, so we had a cogged
-wheel to work into a rack-work rail laid along the track, and somehow
-she was always getting off the rack-rail.”
-
-“And now you find that the engine is heavy enough herself to grip the
-rail.”
-
-“Ay, that was Will Hedley’s notion; he’s a viewer at the colliery. And
-it is a great improvement. Why, that third engine, I say, was a perfect
-nuisance. Chaps used to sing out to the driver: ‘How do you get on?’”
-
-“‘Get on,’ sez he, ‘I don’t get on; I on’y get off!’”
-
-“It was always goin’ wrong, and horses was always having to be got out
-to drag it along.”
-
-“How did Hedley find out that a rack-rail was not needful?”
-
-“Well, he had a framework put upon wheels and worked by windlasses
-which were geared to the wheels. Men were put to work these windlasses
-which set the wheels going; and, lo and behold, she moved! The wheels,
-though smooth, kept to the rails, though they were smooth also, and
-the framework went along without slipping. ‘Crikey!’ says Hedley, ‘no
-cogged wheels, no chains, no legs for me! We can do without ’em all.
-Smooth wheels will grip smooth rails.’ And he proved it too by several
-experiments.”
-
-“Then Mr. Blackett had this engine built?”
-
-“Ay, and it be, as you say, a great improvement. But that steam blowing
-off there, after it have done its work, frights the horses on the Wylam
-Road ter’ble, and makes it a perfect nuisance.”
-
-“Has nothing been done to alter it?”
-
-“Mr. Blackett has given orders to stop the engine when any horses comes
-along, and the men don’t like that because it loses time. He thinks he
-is going to let the steam escape gradual like, by blowing it off into
-a cask first.”
-
-“Umph! very wasteful.”
-
-“Oh, ay; it be wasteful; and many a one about here sez of Mr. Blackett
-that a fool and his money are soon parted.”
-
-“No,” said the first speaker, shaking his head thoughtfully, “Mr.
-Blackett is no fool. But I think I could build a better engine than
-that.”
-
-[Illustration: GEORGE STEPHENSON.]
-
-The tone in which these words were uttered was not boastful, but quiet
-and thoughtful.
-
-“You are Geordie Stephenson, the engine-wright of the Killingworth
-Collieries, ’beant you?”
-
-“Ay; and we have to haul coal some miles to the Tyne where it can be
-shipped. So you do away with all rack-work rails and all cogged wheels,
-do you?”
-
-“Ay, ay, Geordie, that’s so—smooth wheels on smooth rails.”
-
-This conversation, imaginary though to some extent it be, yet embodies
-some important facts. Jonathan Foster, Mr. Blackett’s engine-wright,
-informed Mr. Samuel Smiles, who mentions the circumstance in his “Lives
-of the Engineers,” that George Stephenson “declared his conviction
-that a much more effective engine might be made, that should work more
-steadily and draw the load more effectively.”
-
-Geordie had studied the steam-engine most diligently. Born at
-Wylam—some eight miles distant from Newcastle, about thirty years
-previously—he had become a fireman of a steam-engine and had been wont
-to take it to pieces in his leisure. He was now thinking over the
-subject of building a locomotive engine, and he decided to see what
-had already been accomplished. He would profit by the failures and
-successes of others. So he went over to Wylam to see Mr. Blackett’s
-engines, and to Coxlodge Colliery to see Mr. Blenkinsop’s from Leeds;
-and here again it is said, that after watching the machine haul
-sixteen locomotive waggons at a speed of about three miles an hour, he
-expressed the opinion that “he thought he could make a better engine
-than that, to go upon legs.”
-
-A man named Brunton did actually take out a patent in 1813 for doing
-this. The legs were to work alternately, like a living creature’s.
-The idea which seems to have troubled the early inventors of the
-locomotive, was that smooth wheels would not grip smooth rails to haul
-along a load. And it was Blenkinsop of Leeds who took out a patent in
-1811 for a rack-work rail into which a cog-wheel from his engine should
-work.
-
-Thus William Hedley’s idea of trusting to the weight of the engine to
-grip the rails, and abolishing all the toothed wheels and legs and
-rack-work for this purpose on a fairly level rail, was the first great
-step toward making the locomotive a practicable success.
-
-[Illustration: “PUFFING BILLY,” THE OLDEST LOCOMOTIVE ENGINE IN
-EXISTENCE.
-
-(_At present in South Kensington Museum._)]
-
-The idea that Stephenson invented the locomotive is a mistake. But
-just as James Watt improved the crude steam pumps and engines he found
-in existence, so George Stephenson of immortal memory developed and
-made practicable the locomotive. For, in spite of Hedley’s discovery or
-invention, all locomotives were partial failures until Stephenson took
-the matter in hand.
-
-Nevertheless, William Hedley’s “Puffing Billy” must be regarded as one
-of the first practicable railway engines ever built. It is still to be
-seen in the South Kensington Museum, London. Patented in 1813, it began
-regular work at Wylam in that year, and continued in use until 1872. It
-was probably this engine which Stephenson saw when he said to Jonathan
-Foster that he could make a better, and it was no doubt the first to
-work by smooth wheels on smooth rails. Altogether it has been looked
-upon as the “father” of the enormous number of locomotives which have
-followed.
-
-Mr. Blackett was a friend of Richard Trevithick; and among the various
-inventors and improvers of the locomotive engine Richard Trevithick, a
-tin-miner in Cornwall, must have a high place.
-
-Trevithick was a pupil of Murdock, who was assistant of James Watt.
-Murdock had made a model successfully of a locomotive engine at
-Redruth. Others also had attempted the same thing. Savery had suggested
-something of the kind; Cugnot, a French engineer, built one in Paris
-about 1763; Oliver Evans, an American, made a steam carriage in 1772;
-William Symington, who did so much for the steamboat, constructed
-a model of one in 1784. So that many minds had been at work on the
-problem.
-
-But Richard Trevithick was really the first Englishman who used a
-steam-engine on a railway. He had not much money and he persuaded his
-cousin, Andrew Vivian, to join him in the enterprise. In 1802 they took
-out a patent for a steam-engine to propel carriages.
-
-But before this he had made a locomotive to travel along roads, and on
-Christmas Eve, 1801, the wonderful sight could have been seen of this
-machine carrying passengers for the first time. It is indeed believed
-to have been the first occasion on which passengers were conveyed by
-the agency of steam—the pioneer indeed of a mighty traffic.
-
-The machine was taken to London and exhibited in certain streets, and
-at length, in 1808, it was shown on ground where now, curiously enough,
-the Euston Station of the London and North-Western Railway stands. Did
-any prevision of the extraordinary success of the locomotive flash
-across the engineer’s brain? Before the infant century had run its
-course what wonderful developments of the strange new machine were to
-be seen on that very spot!
-
-Much interest was aroused by the exhibition of this machine, and Sir
-Humphrey Davy, a fellow Cornishman, is reported to have written to a
-friend—“I shall soon hope to hear that the roads of England are the
-haunts of Captain Trevithick’s dragons—a characteristic name.”
-
-His letter tends to show that the idea then was that the engine should
-run on the public roads, and not on a specially prepared track like
-a railway. Had not this idea been modified, and the principle of a
-railroad adopted, it is hardly too much to say that the extraordinary
-development of the locomotive would not have followed.
-
-Trevithick’s first engine appears to have burst. At all events, in the
-year 1803 or 1804, he built, and began to run, a locomotive on a horse
-tramway in South Wales. It appears that he had been employed to build a
-forge-engine here, and thus the opportunity was presented for the trial
-of a machine to haul along minerals. This, it is believed, was the
-first railway locomotive, and its builder was Richard Trevithick.
-
-The trial, however, was not very successful. Trevithick’s engine was
-too heavy for the tramway on which it ran, and the proprietors were
-not prepared to put down a stronger road. Furthermore, it once alarmed
-the good folk, unused then to railway accidents, by actually running
-off its rail, though only travelling at about four or five miles an
-hour. It had to be ignominiously brought home by horses. That settled
-the matter. It became a pumping engine, and as such answered very well.
-
-In this locomotive, however, it should be noted Trevithick employed a
-device which, a quarter of a century later, Stephenson made so valuable
-that we might call it the very life-blood of the Locomotive. We mean
-the device of turning the waste steam into the funnel (after it has
-done its work by driving the piston), and thus forcing a furnace
-draught and increasing the fire. Stephenson, however, sent the steam
-through a small nozzled pipe which made of it a veritable steam-blast,
-while Trevithick, apparently, simply discharged the steam into the
-chimney.
-
-Disgusted it would seem by the failure, the inventor turned his
-attention to other things. Trevithick appears to have lingered on the
-very brink of success, and then turned aside. Another effort and he
-might have burst the barrier. But it was not to be; though if any one
-man deserve the title, Inventor of the Locomotive, that man is the
-Cornish genius Trevithick. Readers who may desire fuller information
-of Trevithick and his inventions will find it in his “Life” by Francis
-Trevithick, C.E., published in 1872.
-
-It must be borne in mind that Stephenson found the imaginary hindrance
-that smooth wheels would not grip smooth rails, cleared away for him
-by Hedley’s experiment, whereas Trevithick had to contend against this
-difficulty. He strove to conquer it by roughing the circumference of
-his wheels by projecting bolts, so that they might grip in that way.
-That is, his patent provided for it, if he did not actually carry out
-the plan.
-
-It is very significant that this imaginary fear should have hindered
-the development of the locomotive. The idea seems to have prevailed
-that, no matter how powerful the engine, it could not haul along very
-heavy loads unless special provision were made for its “bite” or grip
-of the rails. Another difficulty with which Trevithick had to contend
-was one of cost. It is said that one of his experiments failed in
-London for that reason. This was apparently the locomotive for roads,
-as distinct from the locomotive for rails. A machine may be an academic
-triumph, but the question of cost must be met if the machine is to
-become a commercial and industrial success.
-
-Mr. Blenkinsop of Leeds then took out his patent in 1811 for a
-rack-work rail and cogged wheel; but before this Mr. Blackett of Wylam
-had obtained a plan of Trevithick’s engine and had one constructed.
-He had met Trevithick at London, and it was as early as 1804 that
-he obtained the plan. The engines, therefore, of Mr. Blackett which
-Stephenson saw, came, so to speak, in direct line from Trevithick,
-except that Mr. Blackett’s second engine was a combination of
-Blenkinsop’s and Trevithick’s.
-
-Some progress was made, but when on that memorable day George
-Stephenson, the engine-wright of Killingworth, said, “I think I could
-build a better engine than that,” no very effective or economical
-working locomotive was in existence.
-
-Back therefore went George Stephenson to his home. He had seen what
-others had done, and with his knowledge of machinery and his love for
-engine work he would now try what he could do.
-
-Would he succeed?
-
-
-
-
-CHAPTER II.
-
-GLANCING BACKWARDS AND STRUGGLING FORWARDS.
-
-
-“My lord, will you spend the money to build a Travelling Engine?”
-
-“Why? what would it do?”
-
-“Haul coals to the Tyne, my lord. The present system of hauling by
-horses is very costly.”
-
-“It is. But how would you manage it by a Travelling Engine?” Thereupon
-George Stephenson the engine-wright proceeded to explain.
-
-In some such manner as this we can imagine that Stephenson opened up
-the subject to Lord Ravensworth, the chief partner in the Killingworth
-Colliery; and he won his lordship over.
-
-Stephenson had already improved the colliery engines, and Lord
-Ravensworth had formed a high opinion of his abilities. So after
-consideration he gave the required consent.
-
-Now, let us endeavour to imagine the position. The steam engine, of
-which the locomotive is one form, had been invented years before. The
-Marquis of Worcester made something of a steam engine which apparently
-was working at Vauxhall, South-west London, in 1656. It is said that he
-raised water forty feet, and by this we may infer that his apparatus
-was a steam-pump. He describes it in his work “Century of Inventions,”
-about 1655, and he is generally accredited with being the inventor of
-the steam engine. It was, however, a very primitive affair, the boiler
-being the same vessel as that in which the steam accomplished its work.
-
-Captain Savery took the next step. He was the first to obtain a patent
-for applying steam power to machinery. This was in 1698, and he used
-a boiler distinct from the vessel where the steam was to exert its
-power. Savery’s engines appear to have been used to drain mines.
-
-His engines acted in this way—the steam was condensed in a vessel and
-produced a vacuum which raised the water; then the steam pressing upon
-it raised it further in another receptacle.
-
-An obvious improvement was the introduction of the piston. This was
-Papin’s idea, and he used it first in 1690. Six years later an engine
-was constructed by Savery, Newcomen (a Devonshire man), and Cawley,
-in which the “beam” was introduced, and also the ideas of a distinct
-boiler separate from a cylinder in which worked a piston. This machine
-was in operation for about seventy years. The beam worked on an axle
-in its centre—something like a child’s “see-saw,” and one end being
-attached to the piston moving in the cylinder, it was worked up and
-down, the other end of the beam being fastened to the pump-rod, which
-was thus alternately raised and depressed.
-
-The upward movement of the piston having been effected by a rush of
-steam from the boiler upon its head, the steam was cut off and cold
-water run in upon it from a cistern. The steam was thus condensed by
-the water and a vacuum caused, and the piston was pressed down by the
-weight of the atmosphere—of course dragging down its end of the beam,
-and raising the pump-rod. The steam was then turned on again and pushed
-up the piston, and consequently the end of the beam also. Thus the
-engine continued to work, the turning of the cocks to admit steam and
-water being performed by an attendant. The engine was, however, made
-self-acting in this respect, and Smeaton improved this form of engine
-greatly. The beam is still used in engines for pumping.
-
-Nevertheless, improved though it became, it was still clumsy and almost
-impracticable. It was the genius of James Watt which changed it from a
-slow, awkward, cumbrous affair into a most powerful, practicable, and
-useful machine.
-
-His great improvements briefly were these: he condensed the steam in
-a separate vessel from the cylinder, and thus avoided cooling it and
-the consequent loss of steam power; secondly, he used the steam to
-push back the piston as well as to push it forward (this is called the
-“double-acting engine,” and is now always used); thirdly, he introduced
-the principle of using the steam expansively, causing economy in
-working; and fourthly, he enabled a change to be made of the up and
-down motion of the piston into a circular motion by the introduction of
-the crank.
-
-[Illustration: JAMES WATT.]
-
-The use of the steam expansively is to stop its rush to the cylinder
-when the piston has only partially accomplished its stroke, leaving the
-remainder of the stroke to be driven by the expansion of the steam.
-In early engines the steam was admitted by conical valves, worked by a
-rod from the beam. Murdock, we may add in parenthesis, is believed to
-have invented the slide-valve which came into use as locomotives were
-introduced, and of which there are now numerous forms. The valve is
-usually worked by an “eccentric” rod on the shaft of the engine.
-
-Watt was the author of many other inventions and improvements of the
-steam engine. Indeed, although Savery and Newcomen and others are
-entitled to great praise, it was Watt who gave it life, so to speak,
-and made it, in principle and essence, very much that which we now
-possess. There have, indeed, been improvements as to the boiler, as to
-expansive working, and in various details, since his day; but, apart
-from the distinctive forms of the locomotive and the marine engine, the
-machine as a whole is in principle much as Watt left it.
-
-The centre of all things in a steam engine is usually the cylinder.
-Here the piston is moved backward and forward, and thence gives motion
-as required to other parts of the machine.
-
-The cylinder is in fact an air-tight, round box, fitted with a
-close-fitting, round plate of metal, to which is fixed the piston-rod.
-Now, it must be obvious that if the steam be admitted at one end of the
-cylinder it will, as it rushes in, push the metal plate and the piston
-outward, and if this steam be cut off, and the steam admitted to the
-other end of the cylinder, it will push the metal plate and piston back
-again.
-
-But what is to be done with the steam after it has accomplished
-its work? It may be permitted to spurt out into the air, or into a
-separate vessel, where it may be condensed. In the locomotive, under
-Stephenson’s able handling, this escape of steam was created into a
-steam-blast in the chimney to stimulate the fire. In compound and
-triple-expansion engines the steam is used—or expanded, it is called—in
-two or three cylinders respectively. When steam is condensed, it may
-be returned to the boiler as water.
-
-It was the repairing of a Newcomen engine that seems to have started
-Watt on his inventions and improvements of the steam engine. He was
-then a mathematical instrument maker at Glasgow. As a boy he had
-suffered from poor health, but had been very observant and studious;
-and it is said that his aunt chided him on one occasion for wasting
-time in playing with her tea-kettle. He would watch the steam jetting
-from its spout, and would count the water-drops into which the steam
-would condense when he held a cup over the white cloud.
-
-Delicate though he was in health, he studied much, and came, indeed,
-to make many other articles besides mathematical instruments. When,
-therefore, the Newcomen engine needed repair, it was not unnatural
-that it should be brought to him. It appears to have been a working
-model used at Glasgow University. He soon repaired the machine; but,
-in examining it, he became possessed with the idea that it was very
-defective, and he pondered long over the problem—How it might be
-improved. What was wanting in it? How could the steam be condensed
-without cooling the cylinder?
-
-Suddenly, one day, so the story goes, the idea struck him, when
-loitering across the common with bent brows, that if steam were
-elastic, it would spurt into any vessel empty of air. Impatiently,
-he hastened home to try the experiment. He connected the cylinder of
-an engine with a separate vessel, in which the air was exhausted,
-and found that his idea was correct; the steam did rush into it.
-Consequently the steam could be condensed in a separate vessel, and
-the heat of the cylinder maintained and the loss of power prevented.
-This invention seems simple enough; yet it increased the power of an
-engine threefold, and is at the root of Watt’s fame. We must remember
-that the inventions which in process of time may appear the simplest
-and the most commonplace, may be the most difficult to originate. And
-it may fairly be urged—If it were so very simple, and so very obvious,
-why was it not invented before? The supposition is that in those days
-it was not so simple. It is possible that the great elasticity of steam
-was not sufficiently understood. In any case, the discovery and its
-application are regarded as his greatest invention.
-
-Yet ten years elapsed before he constructed a real working steam
-engine, and so great we may suppose were the difficulties he
-encountered, including poorness of health, that once he is reported
-to have exclaimed: “Of all things in the world, there is nothing so
-foolish as inventing.”
-
-But a brilliant triumph succeeded. Eventually Watt became partner
-with Mr. Matthew Boulton, and the firm of Boulton & Watt manufactured
-the engine at Soho Ironworks, Birmingham. Mining proprietors soon
-discovered the value of the new machine, and Newcomen’s engine was
-superseded for pumping.
-
-Watt continued to improve the machine, and together with Boulton also
-greatly improved the workmanship of constructing engines and machinery.
-In a patent taken out in 1784, he “described a steam locomotive”; but
-for some reason he did not prosecute the idea. It is possible that the
-notion of building a special road for it to run upon did not occur to
-him, or appear very practicable.
-
-His work was done, and it was a great work; but it was left for others
-to develop the steam engine into forms for hauling carriages on land or
-propelling ships upon the sea. Trevithick, Stephenson, and others did
-the one; Symington, Bell, and others did the second. Watt died in 1819,
-and though so delicate in youth, he lived to his eighty-fourth year.
-
-The steam engine, therefore, as Watt left it, was practically as
-Stephenson came to know it. He would be acquainted with it chiefly as
-a pumping machine. But he saw what others had done to adopt it as a
-locomotive, and he now set to work.
-
-Stephenson’s first engine did not differ very materially from some of
-those which had preceded it. He was, so to speak, feeling his way. The
-machine had a round, wrought-iron boiler, eight feet long, with two
-upright cylinders placed on the top of it. At the end of the pistons
-from the cylinders were cross-rods connected with cogged wheels below
-by other rods. These cogged wheels gave motion to the wheels running
-on the rails by cogs not very far from the axles. Stephenson abandoned
-the cogged rail, and adopted smooth wheels and smooth rails; but he did
-not connect the driving-wheel direct with the piston, the intervening
-cogged wheels being thought necessary to unite the power of the two
-cylinders.
-
-In adopting the principle of smooth wheels on smooth rails, it is said
-that Stephenson proved by experiment that the arrangement would work
-satisfactorily. Mr. Smiles writes that Robert Stephenson informed him,
-“That his father caused a number of workmen to mount upon the wheels
-of a waggon moderately loaded, and throw their entire weight upon the
-spokes on one side, when he found that the waggon could thus be easily
-propelled forward without the wheels slipping. This, together with
-other experiments, satisfied him of the expediency of adopting smooth
-wheels on his engine, and it was so finished accordingly.” Thus it may
-be said that this obstacle—imaginary though it largely proved to be—was
-cleared away from Stephenson’s first engine.
-
-Ten months were occupied in building the machine, and at last came the
-day of its trial. This was the 25th of July, 1814. Would it work?
-
-Jolting and jerking along, it did work, hauling eight carriages at a
-speed of about four or six miles an hour—as fast as a brisk man could
-walk. Then came the question—Would it prove more economical than
-horse-power?
-
-Calculations therefore were made, and after a time it was found that
-“Blucher” as the engine was called, though we believe its real name was
-“My Lord,” was about as expensive as horse-power.
-
-The locomotive needed something more, some magic touch to render it
-less clumsy and more effective. What was it?
-
-Then came the first great practicable improvement after the smooth
-wheels on smooth rails. It was the steam-blast in the funnel, by which
-the draught in the furnace was greatly increased. Indeed, the faster
-the engine ran the more furiously the fire would burn, the more rapid
-would be the production of steam, and the greater the power of the
-engine.
-
-At first Stephenson had allowed his waste steam from the cylinders
-to blow off into the air. So great was the nuisance caused by this
-arrangement that a law-suit was threatened if it were not abated.
-
-What was to be done with that troublesome waste steam? Now, whether
-Stephenson originated the idea or adapted what Trevithick had done,
-we cannot say, but at all events he achieved the object, wherever he
-gained the idea. He turned his exhaust steam through a pipe into the
-funnel, and at a stroke increased the power of his engine two-fold.
-
-But that expedient was not alone. Stephenson had watched the working of
-“Blucher” to some purpose, and he decided to build another engine with
-improvements.
-
-The cumbersome cog-wheels must go; they complicated the machine
-terribly, and prevented its practicability. Therefore in his second
-engine he introduced direct connection between the pistons and the
-wheels. There were a couple of upright cylinders as before, with
-cross-rods attached to the piston-ends, and connecting rods from the
-end of each cross-rod, reaching down to the wheels. But to overcome the
-difficulty of one wheel being at some time higher than the other on
-the poorly constructed railway of that period, a joint was introduced
-in the cross-rod, so that if, perchance, the two wheels should not be
-always on exactly the same level, no undue strain should be placed on
-the cross-rod. Furthermore, the two pairs of wheels were combined first
-by a chain, but afterwards by connecting rods. This may be called the
-locomotive of 1815, the year in which the patent was taken out.
-
-[Illustration: EDWARD PEASE.]
-
-The engine accomplished its work more satisfactorily than before,
-and was placed daily on the rails to haul coal from the mine to the
-shipping point. But still its economy over horse-power was not so great
-as to cause its wide adoption. And it was still little better, if
-anything, than a mere coal haul.
-
-Nevertheless Stephenson persevered. He was appointed engineer to the
-Stockton and Darlington Railway—an enterprise largely promoted by Mr.
-Edward Pease. It was opened on the 27th of September, 1825, and a local
-paper writes as follows:—
-
-“The signal being given, the engine started off with this immense
-train of carriages, and such was its velocity, that in some parts the
-speed was frequently 12 miles an hour; and at that time the number
-of passengers was counted to be 450, which, together with the coals,
-merchandise, and carriages, would amount to near 90 tons. The engine,
-with its load, arrived at Darlington, a distance of 8¾ miles, in 65
-minutes. The 6 waggons loaded with coals, intended for Darlington, were
-then left behind; and obtaining a fresh supply of water, and arranging
-the procession to accommodate a band of music and numerous passengers
-from Darlington, the engine set off again, and arrived at Stockton in 3
-hours and 7 minutes, including stoppages, the distance being nearly 12
-miles.”
-
-Stephenson became a partner in a business for constructing locomotives
-at Newcastle, and three engines were made for the Stockton and
-Darlington Railway. Nevertheless they appear to have been used chiefly
-if not almost entirely for hauling coal; for the passenger-coach called
-the _Experiment_ was hauled by a horse, and the journey occupied about
-two hours.
-
-The locomotive was not even yet a brilliant success over horse-power.
-What was to be the next step?
-
-
-
-
-CHAPTER III.
-
-FIFTEEN MILES AN HOUR.
-
-
-Five hundred pounds for the best locomotive engine!
-
-So ran the announcement one day in the year 1829. The Liverpool and
-Manchester Railway was nearly completed, but yet the directors had not
-fully decided what power they would employ to haul along their waggons.
-
-Horse-power had at length been finally abandoned, and numbers of
-schemes had been poured in upon the managers. But the contest seemed
-at last to resolve itself chiefly into a rivalry between fixed and
-locomotive engines. Principally, if not entirely, swayed however by the
-arguments of George Stephenson, the directors yielded to the hint of a
-Mr. Harrison, and offered a £500 prize.
-
-The engine was to satisfy certain conditions. Its weight was not to be
-above six tons; it was to burn its own smoke, haul twenty tons at a
-rate of ten miles an hour, be furnished with two safety valves, rest on
-springs and on six wheels, while its steam pressure must not be more
-than fifty lbs. to the square inch. The cost was not to exceed £550.
-
-Stephenson, who was the engineer of the Railway, decided to compete. He
-was now in a very different position from that which he occupied when
-he built his second locomotive in 1815. His appointment as engineer to
-the Stockton and Darlington Railway had greatly aided his advancement,
-and when it was decided to build a railway between the two busy cities
-of Manchester and Liverpool it was not unnatural that he should take
-part in the undertaking.
-
-The idea of constructing rail, or tram ways, was not new. Railways of
-some kind were used in England about two hundred years before, that
-is, about the beginning of the seventeenth century. Thus Roger North
-writes:—“The manner of the carriage is by laying rails of timber from
-the colliery to the river, exactly straight and parallel; and bulky
-carts are made with four rollers fitting those rails, whereby the
-carriage is so easy that one horse will draw down four or five chaldron
-of coals, and is an immense benefit to the coal merchants.”
-
-It is said that the word tramway is derived from tram, which was wont
-to mean a beam of timber and also a waggon. In any case, such rough
-ways were introduced in mining districts, for, as may be readily
-believed, one horse could draw twenty times the load upon them that it
-could on an ordinary road.
-
-The old ways were first made of wood, then of wood faced with iron,
-then altogether of iron.
-
-Now, in making his railway between Liverpool and Manchester, Stephenson
-had many difficulties to encounter. He decided that the line should
-be as direct as possible. But to accomplish this, he would have to
-pierce hills, build embankments, raise viaducts, and, hardest of all,
-construct a firm causeway across a treacherous bog called Chat Moss.
-
-“He will never do it,” said some of the most famous engineers of the
-day. “It is impossible!”
-
-Impossible it certainly seemed to be. Chat Moss was like a sponge, and
-how was an engineer to build a solid road for heavy trains over four
-miles of soppy sponge! A person could not trust himself upon it in
-safety, and when men did venture, they fastened flat boards to their
-feet, something after the fashion of snow-shoes, and floundered along
-upon them.
-
-Stephenson began by taking the levels of the Moss in a similar manner.
-Boards were placed upon the spongy moss, and a footpath of heather
-followed. Then came a temporary railroad. On this ran the trucks
-containing the material for a permanent path, which were pushed by boys
-who learned to trot along easily on the narrow rails.
-
-Drains were dug on either side of the proposed road, and tar-barrels
-covered with clay were fitted into a sewer underneath the line in the
-middle of the Moss. Heather, hurdles, tree branches, etc., were spread
-on the surface, and in some parts an embankment of dry moss itself
-was laid down. Ton after ton of it disappeared until the directors
-became alarmed, and the desperate expedient of abandoning the works was
-considered.
-
-But Stephenson was an Englishman out and out. He never knew when he was
-beaten. “Keep on filling,” he ordered; and in spite of all criticism
-and all alarm, he kept his hundreds of navvies hard at work, pouring in
-load after load of dry turf.
-
-It must be borne in mind, however, that Stephenson did not continue
-blindly at his task. He had good reason for what he did. His
-persistence was a patient, intelligent perseverance, and not a stupid
-obstinacy. His main arguments seem to have been two. He judged that if
-he constructed a sufficiently wide road, it would float on the moss,
-even as ice or a raft of wood floats on water and bears heavy weights;
-and secondly, he seems to have been animated by the idea, that, if
-necessary, he could pour in enough solid or fairly solid stuff to reach
-the bottom and rise up to the surface in a hard mass.
-
-Both ideas seem to have been realised in different parts of the bog.
-Joy took the place of despair, and triumph exulted over discouragement,
-as at length the solid mass appeared through the surface. Furthermore,
-the expense was found to be none so costly after all. No doubt any
-quantity of turf could be obtained from the surrounding parts of the
-Moss and dried.
-
-At another part of the railway called Parr Moss an embankment about
-a mile and a-half was formed by pouring into it stone and clay from
-a “cutting” in the neighbourhood. In some places twenty-five feet of
-earth was thus concealed beneath the Moss. The eye of the engineer had
-as it were pierced through the bog and seen that his solid bank was
-steadily being built up there.
-
-Before, however, the road across Chat Moss was fairly opened, the trial
-of locomotives for the prize of £500 had taken place. The fateful
-day was the 1st day of October, 1829, and the competition was held
-at Rainhill. A grand stand was erected, and the side of the railway
-was crowded. Thousands of spectators were present. The future of the
-locomotive was to be decided on this momentous occasion.
-
-Now, hitherto the difficulty in the locomotive had been to supply a
-steady and sufficient supply of steam to work the engine quickly and
-attain high speed and power. Partly, this had been accomplished by
-Stephenson’s device of the steam-blast in the funnel. But something
-more was needed.
-
-That requirement was found in the tubular boiler. If the long
-locomotive boiler were pierced with tubes from end to end, it is clear
-that the amount of heating surface offered to the action of the fire
-would be greatly increased. It was this idea which was utilised in the
-“Rocket,” the engine with which Stephenson competed at Rainhill, and
-utilised more perfectly than ever before.
-
-Trevithick himself seems to have invented something of the kind, and
-M. Seguin, the engineer of the St. Etienne and Lyons Railway utilised
-a similar method. But Henry Booth, the secretary of the railway which
-Stephenson was then building, invented a tubular boiler without, it is
-said, knowing anything of Seguin’s plan, and Stephenson who had already
-experimented in the same direction, adopted Booth’s method.
-
-At first it was a failure. The boiler, fitted with tubes through
-which the hot air could pass, leaked disastrously, and Stephenson’s
-son, Robert, wrote to his father in despair. But again George said
-“persevere,” and he suggested a plan for conquering the difficulty.
-Again, it was a simple, but as the event proved, an effective plan.
-
-The copper tubes were merely to be fitted tightly to holes bored in the
-boiler and soldered in. The heat caused the copper to expand and the
-result was a very strong and water-tight boiler. There were twenty-five
-of these tubes, each three inches in diameter, and placed in the lower
-portion of the boiler, leading from the furnace to the funnel. Water
-also surrounded the furnace. Further, the nozzles of the steam-blast
-pipes were contracted so as to increase the power of the blast, and
-consequently raise the strength of the draught to the fire.
-
-[Illustration: “THE ROCKET.”]
-
-The cylinders were not placed at the top of the boiler, but at the
-sides in a slanting direction, one end being about level with the
-boiler roof. They occupied a position mid-way between the old situation
-upright on the roof and their present position below, or at the lower
-portion. The pistons acted directly on the driving wheels by means of a
-connecting rod, and the entire weight of the engine with water supply
-was but 4½ tons.
-
-On the day of trial only four engines competed. Many had been
-constructed, but either were not completed in time, or for various
-reasons could not be exhibited. The famous four were:—The “Novelty” by
-Messrs. Braithwaite and Ericsson; The “Rocket” by Messrs. R. Stephenson
-& Co.; The “Perseverance” by Mr. Burstall; and The “Sanspareil” by Mr.
-Timothy Hackworth. Each engine seems to have run separately, and the
-length of the course was two miles. The test was that the engine should
-run thirty miles, backwards and forwards, on the two mile level course,
-at not less than ten miles an hour, dragging three times its own weight.
-
-The “Novelty” at first appears to have beaten the “Rocket,” for she
-ran at times at the rate of twenty-four miles an hour; while the first
-trip of the “Rocket” covered a dozen miles in fifty-three minutes.
-The engineers of the “Novelty” used bellows to force the fire, but
-on the second day these bellows gave way, and the engine could not
-do its work. The boiler of the “Sanspareil” also showed defects, but
-Stephenson’s “Rocket” calmly stood the strain. Practicable as usual,
-Stephenson’s work was as good in its results, nay, even better than
-before, for he hooked the “Rocket” to a carriage load of thirty
-people, and rushed them along at the then surprising speed of between
-twenty-four to thirty miles an hour. Mr. Burstall’s “Perseverance”
-could not cover more than six miles an hour.
-
-The competitions continued, but the “Novelty,” although running at the
-rate of twenty-four and even twenty-eight miles an hour, broke down
-again and yet again; its boiler plates appear to have gone wrong on one
-occasion; while the “Sanspareil” also failed, and furthermore blew a
-good deal of its fuel into the air because of the arrangement of its
-steam-blast.
-
-But the more the “Rocket” was tried, the more practicable and reliable
-the engine appeared to be. On the 8th of October it gained a speed of
-29 miles an hour, its steam pressure being about 50 lbs. to the square
-inch, and its average speed was fifteen miles an hour—that is, five
-miles an hour over the conditions required. These results appear to
-have been accomplished with a weight of waggons of thirteen tons behind
-it. When detached it ran at the rate of thirty-five miles an hour.
-
-In short, the “Rocket” was the only locomotive which fulfilled all
-the conditions specified for the competition, and the prize was duly
-awarded to Stephenson and Booth.
-
-The battle of the locomotive was won. Men could see that the machine
-was feasible and practicable; that it was a new force with immense
-possibilities before it.
-
-How have those possibilities been realised?
-
-
-
-
-CHAPTER IV.
-
-A MARVEL OF MECHANISM.
-
-
-“The time is coming when it will be cheaper for a working man to travel
-on a railway than to walk on foot.”
-
-So prophesied George Stephenson some few years before his successful
-competition at Rainhill; and by his success on that fateful day, he had
-brought the time appreciably nearer. The directors of the Liverpool
-and Manchester Railway no longer debated as to what form of traction
-they should adopt.
-
-But Stephenson did not rest on his laurels. Every new engine showed
-some improvement. The “Arrow” sped over Chat Moss at about 27 miles an
-hour, on the occasion of the first complete journey along the line, on
-the 14th of June, 1830; and when, on the public opening of the railway
-on the 15th of September, 1830, Mr. William Huskisson, M.P., was
-unhappily knocked down by the “Rocket,” George Stephenson himself took
-the maimed body in the “Northumbrian,” fifteen miles in twenty-five
-minutes—that is, he drove the engine at the speed of thirty-six miles
-an hour.
-
-The sad death of Mr. Huskisson has often been referred to, but we
-may tell the story again, following the account given by Mr. Smiles,
-who had the advantage of the assistance of Robert Stephenson in the
-preparation of his biography.
-
-The engines it appears halted at Parkside, some seventeen miles from
-Liverpool, to obtain water. The “Northumbrian,” with a carriage
-containing the Duke of Wellington and some friends, stood on one
-line, so that all the trains might pass him in review on the other.
-Mr. Huskisson had descended from the carriage and was standing on the
-rail on which the “Rocket” was rapidly approaching. There had been
-some coolness between the Duke and Mr. Huskisson, but at this time the
-Duke extended his hand and Mr. Huskisson hurried to grasp it, when the
-bystanders cried “Get in! get in.”
-
-Mr. Huskisson became flurried and endeavoured to go round the carriage
-door which was open and hung over the rail; but while doing this, the
-“Rocket” struck him and he fell, his leg being doubled over the rail
-and immediately crushed. Unfortunately he died that evening at Eccles
-Parsonage.
-
-This sad event cast a gloom over the otherwise rejoicing day; but
-the wonderful speed at which the wounded man was conveyed, proved a
-marvellous object lesson as to what the locomotive could accomplish.
-
-In the “Planet,” put upon the line shortly after the opening, the
-cylinders were placed horizontally and within the fire box. The engine
-drew eighty tons from Liverpool to Manchester against a strong wind
-in two and a-half hours, while on another occasion with a company of
-voters, it sped from Manchester to Liverpool, thirty-one miles, in an
-hour. But next year the “Samson,” which was still further improved,
-and the wheels of which were coupled so as to secure greater grip on
-the rails, hauled 150 tons at twenty miles an hour with a smaller
-consumption of fuel.
-
-The locomotive had now become one of the wonders of the world. Since
-then its speed has been doubled. But all the improvements (with
-possibly one exception—that of the compound cylinder which is at
-present only partially in use) have been more in details than in
-principles. Thus the 70 or 80 ton express engine, which covers mile
-after mile at the rate of a mile a minute without a wheeze or a groan,
-is not very different essentially from George Stephenson’s locomotives,
-though its steam pressure is very much higher.
-
-There are, for instance, the multitubular boiler, the furnace
-surrounded by water and communicating with the boiler, the horizontal
-cylinders acting directly on the driving wheels, and the steam-blast by
-which the waste steam is spouted up the chimney, creating a draught in
-the furnace.
-
-These may be regarded as the more important of the essential
-principles, although there is diversity of details, more especially
-for the different work required. But the steam pressure is now much
-greater. Let us glance at a typical English locomotive. You might not
-think it, but the machine has about five thousand different parts, all
-put together as Robert Stephenson said “as carefully as a watch.”
-
-At first sight you will probably not see the cylinders. The tendency
-in many engines now seems to be to place them inside the wheels, for
-it is urged that the placing of the heavier parts of the mechanism
-near to the centre lessens oscillation, and protects the machinery
-more effectually. Against this, it is said that the placing of the
-cylinders in that position increases the cost and the complication of
-the driving axle, and renders the pistons and valves more inaccessible
-for the purposes of repair. Both forms have their advocates, and the
-outside-cylinder form may be seen on the London and South-Western and
-some other railways, while the inside may be seen on the North-Western
-and others.
-
-The boiler is of course the long, round body of the locomotive, and
-in English machines it is placed on a strong plate frame. Then as to
-the driving-wheels. Express engines, such as the splendid “eight-feet
-singles” of the Great Northern, have often, as the name implies, but
-one large driving-wheel on either side, and for great speeds this form
-is held to possess certain advantages. Certainly the performances of
-Mr. Patrick Stirling’s expresses would indicate that this is the case.
-
-With steam raising the safety valve at a pressure of 140 lbs. to
-the square inch, the engines will whisk a score of carriages out
-of King’s Cross up the northern height of London at forty miles an
-hour, and then without a stop rush on to Grantham at near sixty.
-Standing on the platform at King’s Cross, with a large part of the
-immense driving-wheel hidden below you as it rests on the rail, you
-do not realise its tremendous size. Yet, let the engine-driver open
-the throttle, as it is called—that is, turn on the steam to the
-cylinders—and that huge wheel will revolve, and with its neighbour on
-the other side, haul after them that heavy train of carriages, and,
-gathering speed as they go, they will soon be rushing up the incline at
-forty miles an hour, and then on at sixty. It is a marvel of mechanism!
-
-But then the compound engines that Mr. F. W. Webb, the engineer of the
-North-Western, builds for that Company can also perform remarkable
-things. The compound is the great modern improvement (some engineers
-might doubt whether improvement be the correct word) in the locomotive,
-effecting, it is said, an economy of from ten to fifteen per cent.
-in fuel. Now the compounding principle has been developed to such an
-extent in marine steam engines that it revolutionised steam navigation.
-But the application of the principle has not been so great in the case
-of the locomotive.
-
-Briefly, the principle is this—the steam is sent out from the boiler at
-a high pressure, say 160 to 180 lbs. to the square inch, and is used
-in one or in a pair of high-pressure cylinders, and then used again,
-by means of its expanding power, in a larger, low-pressure cylinder.
-Mr. John Nicholson, of the Great Eastern Railway, suggested a compound
-locomotive before even the compound marine engine had been made, and
-his design was successful; but in 1881 Mr. Webb, of the North-Western,
-patented a compound locomotive, with two small high-pressure, and one
-large low-pressure cylinders, the latter twenty-six inches in diameter.
-Placed between the front wheels, the bright boss of this cylinder may
-be seen in shining steel as it flies over the rails.
-
-The argument is that the compound burns less fuel and is more powerful
-than a non-compound of the same weight; but against this is launched
-the objection that the compound is more expensive to build, to repair,
-and to maintain. Still further it is argued, that a fast-speeding
-locomotive has not the time in its hurrying life to expand its steam in
-the tick of time between each stroke of the piston.
-
-[Illustration:
-
-THE COMPOUND LOCOMOTIVE “GREATER BRITAIN.” _By kind permission of Mr.
-F. W. Webb, L. & N. W. Railway._ ]
-
-Mr. Worsdell’s compounds on the North-Eastern Railway have but two
-cylinders, one high and the other low-pressure. The one is eighteen and
-the other twenty-six inches across. Instead of the steam alternating
-between the two cylinders, it all passes first to the high-pressure
-and then, through a pipe in the smoke-box, to the larger low-pressure
-cylinder. These locomotives, it is said, are not under the objection
-alleged against the other compounds—viz., that they have more parts,
-and are more costly to build and maintain. Yet it is claimed for them
-that they are more economical and more powerful than non-compounds.
-
-When doctors disagree who shall decide? The cost or speed might decide;
-but at present it seems doubtful on which side the balance does
-really fall. Engines of the three types have done splendid work. A
-Worsdell compound, built by Mr. Worsdell, of the North-Eastern Railway,
-is reported to have rushed down the incline to Berwick one day at
-seventy-six miles an hour for some miles at a time. Then the “Greater
-Britain,” a massive North-Western compound engine, turned out at the
-Crewe works in 1891, and weighing seventy-five tons, can whirl along
-with ease a heavy twenty-five coach express at an average of over fifty
-miles an hour, with a comparatively small consumption of fuel.
-
-This locomotive was described in the _Engineer_ newspaper as the most
-remarkable that had been built in England for several years. Its axle
-bearings are of great length, and its parts are very substantial,
-so that it ought to keep out of the repairing shops for long spells
-of time. It was specially planned for both fast and heavy passenger
-traffic to Scotland, and its work on its trial trip was so good that it
-was confidently expected it would answer expectations. In working, the
-engine has been found to develop great speed and power, easily running
-at over fifty miles an hour with what is called a double train—viz.,
-twenty-five coaches, behind it. Indeed, it has run at fifty-five
-miles with this heavy train. Its stated speed ranges from thirty to
-fifty-five miles an hour, with a low consumption of fuel.
-
-This last is a matter of very great importance to engineers and railway
-directors; and when we state that, according to Mr. Bowen Cooke, the
-North-Western engines altogether burn 3095 tons of coal per day, any
-small saving per hour would be eagerly welcomed.
-
-Now, it is claimed that the compounds have consumed about six pounds
-of coal per mile less than others on the same work, and that they also
-haul along loads which would require two of the other type. If so, the
-saving in the North-Western coal-bill must be enormous.
-
-[Illustration: BACK AND FRONT VIEW OF THE LOCOMOTIVE “GREATER BRITAIN.”]
-
-A great feature in this engine is a combustion chamber placed within
-the barrel of the boiler. This chamber catches all the gases from the
-furnace, and causes the heat generated by them to be used to the utmost
-for the production of steam. Though heavier than any engine previously
-built, yet it is so made that no greater weight than usual rests upon
-any of the wheels, thus throwing no extra strain on the railway or
-the bridges. The two couples of driving-wheels are placed before the
-furnace, and an additional couple of small wheels behind the furnace,
-and beneath the foot-plate where the driver and fireman stand. The
-weight therefore is evenly distributed, with another pair of wheels to
-bear the burden. The front wheels are fitted with the radial axle-box
-patented by Mr. Webb, so that, although the engine is of great length,
-yet it can speed round curves with perfect safety.
-
-Yet this engine, though one of the most remarkable developments of the
-locomotive, is in essence and in principle but very like the “Rocket.”
-The difference lies in its innumerable details, exhibiting so much
-engineering skill and ingenuity, in the compound cylinders, in higher
-pressure steam, and in its marvellous power and speed combined.
-
-On the other hand, the Great Northern runs daily from Grantham to
-London at fifty-three and fifty-four miles an hour average; while it
-was reported in the _Engineer_ of the 10th of March, 1888, that a Great
-Northern train from Manchester to London, when running from Grantham to
-London, covered one mile in forty-six seconds, that is, at the rate of
-seventy-eight and a-quarter miles an hour, and two miles following each
-other were run in forty-seven seconds each, that is, seventy-six miles
-an hour. We doubt, indeed, if any railway in the world can show regular
-faster daily running than some of the Great Northern expresses between
-London and Grantham. The average speed of their Manchester train over
-this ground is slightly over fifty-four miles an hour. Then there are
-the Great Western expresses, the “Dutchman” and the “Zulu,” at only
-slightly less speeds, to say nothing of the fine performances of the
-Midland. We may take it, therefore, that the compound locomotives,
-excellent as their work has been, have not really beaten their rivals
-in point of speed.
-
-Compounds are used largely on the North-Western, the Great Eastern,
-and the North-Eastern, and should they prove to be really more
-economical in working, while maintaining at least equal power and speed
-with their rivals, we have no doubt but that they will prevail.
-
-
-
-
-CHAPTER V.
-
-A MILE A MINUTE.
-
-
-“The express is to be quickened, my lord. Mr. Thompson, the general
-manager, has given instructions to that effect.”
-
-So spoke the station master at Carlisle, on the 17th of March, 1894, to
-Lord Rosebery.
-
-His lordship had very recently been appointed Prime Minister, and was
-on his way to Edinburgh to deliver a great public speech. The train,
-presumably, was late, or he, through stress of business probably, had
-left too little margin of time. However, by the instructions of Mr.
-Thompson, the general manager of the Caledonian Railway, the express
-was accelerated, and it rushed over 101 miles in 105 minutes, one of
-the quickest locomotive runs, we imagine, that have ever been recorded.
-The train arrived fifteen minutes before it was due, and Lord Rosebery
-was enabled to keep his engagement.
-
-This run was approximately at the rate of a mile a minute, and
-maintained for an hour and three-quarters. Only some two years or so
-previously a somewhat similar run was made. An officer of the Guards
-found that he had lost the south-going mail train at Stirling. He had
-been on leave in Scotland, and was bound to report himself in London
-next morning.
-
-What was he to do? Did he sit down and moan, or fly to the telegraph
-office and endeavour to excuse himself? Not he. He promptly engaged a
-special train, which flying over the metals, actually caught the mail
-at Carlisle, having covered 118 miles in 126 minutes; that is, again,
-approximately a mile a minute, and maintained for slightly over two
-hours.
-
-Now, in order to attain high average speed, some parts of the journey,
-say very easy inclines or levels, must be covered at a much higher
-rate. Thus, to obtain an average of fifty-two miles an hour—which is
-probably the regular average of our best English expresses—the pace
-will most likely be sometimes at the rate of seventy, or it may be
-seventy-six, miles per hour.
-
-The United States have claimed to run the fastest regular train. This
-is the “Empire State Express” of the New York Central, which bursts
-away from New York to Buffalo, a trip of 140 miles, at the average rate
-of 52-12/100 miles per hour, but running eighty miles at the rate of
-56¾ miles an hour. It is also said that, in August, 1891, a train on
-the New York portion of the Reading road ran a mile in less than forty
-seconds, and covered a dozen miles at an average of barely 43½ seconds
-per mile.
-
-English expresses could certainly accomplish these average speeds,
-but the fact is very high speeds do not pay. They wear everything
-to pieces. Then there is the coal consumption. American railway
-engineers—according to the _Engineer_ newspaper—“seem to be unable to
-get on with less than 100 lbs. per square foot (of fire grate area) as
-a minimum;” while, from the same paper, we learn that the average rate
-of burning of Mr. Webb’s remarkable North-Western engine, the “Greater
-Britain,” was but “a little over seventy-three lbs. per square foot per
-hour,” or, altogether, 1500 lbs. per hour.
-
-The rails also are greatly worn by continuous high speeds. Engineers
-have been equal to this difficulty, and rails are now made of steel,
-and even steel sleepers are constructed on which the rails repose. But
-still the wear and tear, especially to engines, of continuous high
-speeds, is very great. The reason why the famous “Race to Edinburgh”
-was stopped was doubtless because of the needless wear and tear. Surely
-an average of fifty to fifty-two miles an hour is fast enough for all
-ordinary purposes. If greater speed can be obtained without too great a
-cost, well and good; but if not, the public must be content.
-
-Nevertheless, during that famous “Race” in the summer of 1888, some
-magnificent engine work was accomplished. Thus, for instance, the
-North-Western and their partners actually ran from Euston to Edinburgh,
-400 miles, in 427 minutes. Then the Great Northern and their partners,
-the East Coast route, next day covered 393 miles in 423 minutes, this
-journey including 124½ miles from Newcastle to Edinburgh covered in 123
-minutes. This speed is, of course, more than a mile a minute, and kept
-up for slightly over two hours.
-
-The third-class passenger was at the root of the matter. Companies are
-finding out they must consult his convenience; and the beginning of the
-“Race” was probably the announcement that the “Flying Scotchman”—the
-10 o’clock morning train from King’s Cross—would carry third-class
-passengers. Hitherto it had beaten its rival, the West Coast route (run
-by the North-Western and its partner, the Caledonian), as to speed, but
-had conveyed only first and second-class passengers.
-
-Thereupon the West Coast announced that they would reach Edinburgh
-in nine hours. As this route is harder for engines—for it climbs the
-Cumbrian Hills, and is, moreover, seven miles longer—this would mean
-faster running and harder work than its rivals. The Great Northern,
-which according to its well-deserved reputation probably tops the world
-for speed, could not brook this, so the East Coast route reduced its
-time from nine hours to eight hours and a-half.
-
-So the contest stood for about a month, when the West Coast calmly
-announced the same time for its journey. Thenceforward the blows fell
-thick and fast. It was a battle of giants, but fought with good temper
-and gentlemanly honour on both sides.
-
-The West Coast were arriving at Edinburgh at half-past six. “The Flying
-Scotchman,” by the East Coast route, thereupon drew up in the Scotch
-capital at six o’clock. Then the West Coast ran to Edinburgh in eight
-hours, stretching away from Euston to Crewe, 158½ miles in 178 minutes,
-without a stop—probably the longest run without a break ever made. The
-Caledonian Company, the North-Western’s partner, then ran from Carlisle
-to Edinburgh, 100¾ miles, in 104 minutes. The North-Western thereupon
-actually ran from Preston to Carlisle, over the Cumberland Hills,
-ninety miles in ninety minutes—a magnificent performance hard indeed
-to beat, if, in fact, it ever has been really beaten; while, later
-on, the same Company ran from Euston to Crewe in 167 minutes instead
-of their remarkable 178 minutes a few days previously. This, with the
-other accelerations, gave the West Coast their record run of 400 miles
-in 427 minutes of running time, which took place on the 13th of August.
-But the East Coast had also accelerated, the North-Eastern covering 205
-miles in 235 minutes, and the Great Northern rendering an equally good,
-if not better, performance, the whole 393 miles being covered in 423
-minutes. Some of the miles on the East Coast route sped by at the rate
-of seventy-six an hour.
-
-To accomplish these runs the weight of trains was cut down, and the
-times of stoppages reduced or abolished altogether. But the expense
-was too great. It did not really “pay” in convenience or in money,
-and to these judgments companies must bow. But considering that the
-Great Northern reaches Grantham, 105¼ miles, in 115 minutes as a
-daily occurrence, an approximate running of near a mile a minute, and
-that the North-Western can run at an average of fifty-five miles an
-hour, the locomotive has amply justified George Stephenson’s prophecy
-when he made “Blucher,” that there was no limit to the speed of the
-locomotive, provided the work could be made to stand.
-
-Mr. C. R. Deacon also prophesied a few years since in an American
-magazine that a hundred miles an hour would be the express speed of
-the future, provided that passengers would give up luxurious cars and
-dining and sleeping carriages. At present it seems questionable if they
-will do so.
-
-[Illustration: THE “FLYING DUTCHMAN.”]
-
-But speed is by no means the monopoly of the North. Other companies
-beside the owners of the East and West Coast routes to Scotland can run
-expresses equally or almost as fast. There is the “Flying Dutchman,”
-for instance, of the Great Western. It daily covers the 77¼ miles
-from London to Swindon in 87 minutes. And the tale is told by Mr. W.
-M. Acworth, on the authority of an inspector who was in charge of the
-train, that a famous Great Western engine, the “Lord of the Isles,”
-which was in the Exhibition of 1851, actually whirled a train from
-Swindon to London, 77¼ miles in 72 minutes.
-
-Some of those older engines could run bravely. Mr. Acworth reports that
-“a Bristol and Exeter tank-engine with 9 feet driving wheels, a long
-extinct species,” pelted down a steep incline at the speed of 80 miles
-an hour, many years since, and it has never been surpassed. The fastest
-speed during the Race to Edinburgh days seems to have been 76 miles,
-but perhaps the weight of the trains may have accounted for this. Mr.
-Acworth himself is believed to have accomplished the fastest bit of
-advertised journeying in the world. He went down on the “Dutchman,”
-and leaving Paddington at 11.46, he caught the return train at Swindon
-and was back at 2.45, having covered 154½ miles, with five minutes for
-refreshments, in 177 minutes. The line is easier on the up journey to
-London, and mile after mile sped by at a rate of over 60 miles an hour.
-From 56½ to 58 seconds was the chronograph’s record again and again,
-while on the down journey to Swindon he records a burst of 34½ miles in
-34 minutes.
-
-The gradients of the railway form of course a most important factor
-in the question of speed. The Midland has one of the hardest roads in
-England for steep slopes, yet its magnificent engines bring its heavy
-trains from Leicester, 99¾ miles in 122 minutes. Considering the high
-levels the locomotives have to climb, only to sink again to low flats,
-as about the Ouse at Bedford, this performance is really as fine as
-some of the superb running of the Great Northern.
-
-The Southern lines out of London have no long distances to cover as
-the Northern, unless it may be the South-Western to Plymouth. The
-South-Western to Bournemouth and Exeter, and the mail trains on the
-South-Eastern, Chatham and Dover, and the Brighton trains can also show
-some excellent work as regards speed.
-
-The government of a large railway now has grown to something like the
-rule of a small state. Sir George Findlay, the general manager of the
-North-Western Company, in his evidence before the Labour Commission
-in 1892, deposed that the capital raised for British railways amounted
-to the vast sum of 897 millions of pounds; that the receipts were 80
-millions yearly, that much more than half of this immense amount,
-namely 43 millions, yearly was paid in wages, and that half-a-million
-of men directly or indirectly were given employment.
-
-To such enormous dimensions has the railway developed. And the
-locomotive engine is the centre and soul of it all. Stephenson got
-it, so to speak, on its right lines of working, and it has run along
-them ever since, until in its great capacity for speed, its power for
-drawing heavy loads, and its strength and beauty of construction it may
-fairly be called one of the wonders of the world.
-
-[Illustration]
-
-
-
-
-[Illustration]
-
-
-THE STORY OF THE STEAMSHIP.
-
-
-
-
-CHAPTER I.
-
-THE “COMET” APPEARS.
-
-
-“If only people could reach the place easier, I could do more business.”
-
-So mused Henry Bell of Glasgow about the year 1810. He was an ingenious
-and enterprising man, and he had established a hotel or bathing-house
-at Helensburgh on the Clyde. But he wanted more visitors, and he
-puzzled his brain to discover how he could offer facilities for them to
-reach the place.
-
-He tried boats, worked by paddles, propelled by hand; but these proved
-a failure. They had been in use years before, though perhaps he knew it
-not. Tradition says that boats fitted with paddle wheels and worked by
-oxen in the boat, were known to the Egyptians, but perhaps tradition
-is wrong. The Romans and the Chinese also are said to have known wheel
-boats, the wheels worked by men or by animals—in the case of the
-Chinese apparently by men alone. A similar kind of boat appears to have
-been tried on the Thames in the seventeenth century; but whether Bell
-knew of these things or not, his experiments of the same kind did not
-answer. What was to be done?
-
-He determined to build a steamboat. At first sight there does not seem
-to be much connection between baths and steamboats, but apparently it
-was the ownership of the one which led Henry Bell to build the other,
-and to become the first man in Great Britain who used a steamboat for
-what may be called public and commercial purposes.
-
-She was a queer craft. Her funnel was bent and was used also as a mast,
-and she poured forth quantities of thick smoke. But she was successful,
-and laboured along at the rate of five miles an hour. Up and down the
-river she plied, and whatever else she did, or did not, she made the
-good folk of those days understand that steam could be applied to
-navigation.
-
-She was called the _Comet_, not because, even in the opinion of her
-owner, she resembled a blazing meteor, but because, to use Bell’s own
-words, “she was built and finished the same year that a comet appeared
-in the north-west part of Scotland.”
-
-“Whatever made you think of starting a steamship?” we can imagine a
-friend asking him as they stood on the bank and watched the _Comet_
-with her paddles shaped like malt shovels, splashing up the water.
-
-“Partly it was Miller’s experiments, and partly it was a letter from
-Fulton. You know, Fulton has put the _Clermont_ successfully on
-American waters. He had been over here talking with Symington, who had
-a steamer on the Forth and Clyde Canal you remember, and he wrote to me
-also asking about machinery and requesting me to inquire about Miller’s
-boats, and send him drawings.”
-
-“And did you?”
-
-“Oh ay, I did; but when he replied afterwards that he had made a
-steamboat from the drawings though requiring some improvements, I
-thought how absurd it was to send my opinions to other countries and
-not put them into practice in our own.”
-
-“So you made the _Comet_?”
-
-“Well, I made a number of models before I was satisfied; but when I
-was convinced the idea would work, I made a contract with John Wood &
-Co., of Port-Glasgow, and they built me this boat, which I fitted up
-with engine and paddles, as you see. John Robertson actually set up the
-engine. We will go aboard presently, and you shall see her.”
-
-[Illustration: BELL’S “COMET.”]
-
-They did so, and this is something of what they saw. They found a
-small vessel, forty feet long and ten and a-half wide, and only about
-twenty-five tons burthen. The furnace was bricked round, and the
-boiler, instead of being in the centre, was seated on one side of the
-ship, with the engine beside it. But the funnel was bent and rose aloft
-in the middle, and it answered the purpose of a mast—to carry sail.
-
-“But look at the machinery,” we can imagine Bell saying to his friend.
-“We have one single cylinder, you see. The piston is attached to a
-crank on an axle. This axle carries a big cog wheel, which, working two
-more placed on the paddle axles, causes them to revolve.”
-
-“And the paddles?”
-
-“Well, you see, we have now two sets on each side, and each paddle is
-shaped something like a malt shovel; but I think I shall alter them,
-and have paddle wheels soon.”
-
-Bell carried out his improvement, and in a short time he did adopt the
-better form of paddle wheel. The improved _Comet_, with a new engine,
-attained six or seven miles an hour. But before this, Mr. Hutchison, a
-brewer, built another boat, bigger than the _Comet_, and her engine was
-of ten horse-power, while the _Comet’s_ was but three. She travelled
-at an average of nine miles an hour, and her fares were but a-third of
-those charged by coach.
-
-The news of the steamers on the Clyde became noised abroad, and
-steamboats began to appear on other British rivers. The success of the
-new venture became assured.
-
-But how had it been brought about? Bell had referred to the labours
-of others, and, indeed, his was not the first steamboat, though,
-doubtless, it was the first in Britain to ply for passengers.
-
-The truth is, that as with the locomotive, several minds were working
-towards the same object. And among those early steamboat seekers
-Patrick Miller, of Dalswinton, and William Symington, of Wanlockhead
-Mines, are entitled to high place.
-
-Indeed, Symington is said to have built the “first practically
-successful steamboat” in the world. She was called the _Charlotte
-Dundas_, and, in 1802, she tugged two barges, together of about 140
-tons, nineteen and a-half miles, in six hours, with a strong wind
-against her.
-
-She was built under the patronage of Lord Dundas, and was intended to
-be used for towing on the Forth and Clyde Canal, but the proprietors of
-the canal would not adopt this new method of propulsion; they feared
-that the wash from the wheels would damage the canal banks. So the
-_Charlotte Dundas_, successful though she was to a certain extent, had
-to be beached and broken up. But Fulton and Bell both inspected her,
-and we may infer that what they saw, influenced their subsequent action.
-
-The engine of the _Charlotte Dundas_ was of the “double action”
-character, introduced by Watt, and it turned a crank in the paddle
-wheel shaft. The wheel was placed at the stern; and boats with their
-wheels thus placed are still made for use in particular places. Thus
-Messrs. Yarrow built one in 1892, to voyage in the shallow rivers
-and lagoons on the west coast of Africa; the idea being that a
-screw-propeller would have been likely to become fouled with weeds.
-
-The _Charlotte Dundas_, we say, has been regarded as the “first
-practically successful steamboat ever built.” No doubt it was so, and
-the credit must be largely given to William Symington. But his success,
-and that which crowned the labours of others, were rendered possible by
-the inventions and improvements of James Watt.
-
-Others had experimented before Symington. Thus, if royal records
-in Spain may be trusted, a certain Blasco de Garay exhibited a
-steam vessel, in 1543, at Barcelona. He placed a large cauldron of
-boiling water in the ship, and a wheel on each side. Certain opinions
-concerning it were favourable, and Blasco was rewarded; but the
-invention was kept secret, and appears to have died.
-
-Then, in 1655, the Marquis of Worcester is said to have invented
-something like navigation by steam. Later on, Jonathan Hulls took out a
-patent for a paddle steam vessel in 1736; and among others, in England,
-France, and America, the Marquis de Jouffroy made a steamer which was
-tried at Lyons, in 1783. Then, in 1787, Patrick Miller is said to have
-patented paddle wheels in Britain.
-
-Miller was a retired gentleman at Dalswinton, in Dumfriesshire, who
-took much interest in mechanical affairs. He experimented with paddle
-wheels, and he also endeavoured to improve naval building. At first the
-wheels appear to have been turned by men, and there came a day when a
-double boat of Miller’s, worked by a couple of wheels with two men to
-turn each wheel, sailed with a Custom House boat, and the need of more
-efficient motive power to revolve the wheels became very marked. Then
-the idea of steam navigation was born, or re-born.
-
-There was a gentleman named Taylor, living with Miller, as tutor to his
-sons, and he often took part in the experiments with the boats. It is
-said that Taylor suggested the use of steam to propel the vessel, and
-that Miller doubted its practicability. However, he decided, at length,
-to try it, and in those summer days of 1787 the subject was much talked
-of at Dalswinton. Taylor mentioned the matter to Symington, who, it
-seems, was a friend of his, but it is not quite clear whether he had
-himself thought of this use of steam. However, in October, 1788, the
-experiment was tried on Dalswinton lake.
-
-A boy was there who afterwards became Lord Brougham, and Robert Burns
-was also there; and, no doubt, the experiment was watched with much
-interest.
-
-It appears to have been successful, and next year a bigger boat was
-tried on the Forth and Clyde Canal, again with some success. But
-whether Mr. Miller thought he had now spent enough money on these
-experiments—and Carlyle says Miller “spent his life and his estate
-on that adventure, and died _quasi_-bankrupt and broken-hearted”—or
-whether he was satisfied with the results attained, he abandoned all
-further effort. Possibly he did not see any opportunity of utilising
-the invention further. At all events, the development of the steamboat
-made practically no progress until Symington commenced his experiments
-under Lord Dundas.
-
-Russell is of opinion that the invention of steam navigation was the
-joint production of these three men. “The creation of the steamship,”
-says he, “appears to have been an achievement too gigantic for any
-single man. It was produced by one of those happy combinations in which
-individuals are but tools, working out each his part in a great system,
-of the whole of which no single one may have comprehended all the
-workings.”
-
-[Illustration: ROBERT FULTON.]
-
-To these three, however, must be added Henry Bell, in Britain, and
-Robert Fulton, in America. They carried the great enterprise further
-on, to something like assured success.
-
-Miller’s boats had two hulls, and the paddle wheels revolved between.
-Symington placed his wheel astern. Bell placed his paddles on either
-side.
-
-“Ah, she will work!” we can imagine the spectators saying, as they
-watched that strange craft, the _Charlotte Dundas_, with her double
-rudder, tugging along her barges.
-
-“Ay, she will work, but the canal folk won’t let her; they think the
-wash from the wheels will wear away the bank!”
-
-“Then I will take the idea where it won’t be so hindered,” said
-another. “We are not afraid of our river banks in America.”
-
-That man, whom we imagine said this, and who appears, without doubt, to
-have inspected the _Charlotte Dundas_, was Robert Fulton, who, with his
-companion, Livingstone, claim to have invented steamboats in the United
-States.
-
-This, then, in brief, seems to be the story. While bearing in mind the
-efforts of others, yet it would seem that Miller, Taylor, and Symington
-invented steam navigation, utilising improvements of Watt on the steam
-engine; but Fulton, in America, and Bell, in Britain, seeing something
-of these experiments, developed them to assured success.
-
-What were Fulton’s adventures?
-
-
-
-
-CHAPTER II.
-
-TO THE NARROW SEAS.
-
-
-“I should not like to risk my money in the thing.”
-
-“Nor I, she will never pay.”
-
-“I reckon she will burst up before the day is over.”
-
-“Well, she is about to start now.” A few minutes more, and the smiles
-on the faces of the speakers changed to expressions of astonishment.
-The boat was actually “walking the waters like a thing of life,” and
-gathering speed as she drew away from the pier.
-
-“Why, stranger, this thing’s going to succeed.”
-
-“It does look so.”
-
-Still the speakers gazed, and still the vessel continued to glide
-along. And shouts and applause burst from the thronging crowd around.
-The “thing” was succeeding indeed.
-
-They were watching the trial trip of the first practically successful
-steamboat in America, the _Clermont_. Fulton had been successful, and
-together with his companion, Livingstone—after whose residence the
-vessel was named—had launched a satisfactory steamer in America, five
-years before the _Comet_ appeared in Britain. Yet the _Clermont’s_
-engines were made in Britain by Boulton & Watt, and men from their
-works helped in mounting the machinery.
-
-Colden, Fulton’s biographer, describing this trial trip, says:—
-
-“The minds of the most incredulous were changed in a few minutes—before
-the boat had made the progress of a quarter of a mile the greatest
-unbeliever must have been converted. The man who, while he looked on
-the expensive machine, thanked his stars that he had more wisdom than
-to waste his money on such idle schemes, changed the expression of his
-features as the boat moved from the wharf and gained her speed; his
-complacent smile gradually stiffened into an expression of wonder;
-the jeers of the ignorant, who had neither sense nor feeling enough
-to repress their contemptuous ridicule and rude jokes, were silenced
-for the moment by a vulgar astonishment, which deprived them of the
-power of utterance, till the triumph of genius extorted from the
-incredulous multitude which crowded the shores shouts and acclamations
-of congratulations and applause.”
-
-The scene of the vessel’s exploit was the famous river Hudson, and she
-came to make several trips between New York and Albany as a passenger
-boat. She performed the journey from Albany to New York in thirty-two
-hours, and back in thirty hours; her average speed being five miles an
-hour. Steamers now perform the passage in about eight hours.
-
-The boat caused great astonishment at the time. Colden says she was
-described by some who saw her but indistinctly at night as “a monster
-moving on the water, defying the winds and tide, and breathing flames
-and smoke.” He states:—“She had the most terrific appearance from
-other vessels which were navigating the river when she was making her
-passage. The first steamboats, as others yet do, used dry pine-wood for
-fuel, which sends forth a column of ignited vapour, many feet above
-the flue, and whenever the fire is stirred a galaxy of sparks fly off,
-which, in the night, have an airy, brilliant, and beautiful appearance.
-This uncommon light first attracted the attention of the crews of
-other vessels. Notwithstanding the wind and tide were adverse to its
-approach, they saw, with astonishment, that it was rapidly coming
-towards them; and when it came so near that the noise of the machinery
-and the paddles was heard, the crews in some instances shrunk beneath
-their decks from the terrific sight; and others left their vessels to
-go on shore; while others, again, prostrated themselves and besought
-Providence to protect them from the approach of the horrible monster
-which was marching on the tides, and lighting its path by the fires
-which it vomited.”
-
-Compare this with the stately passenger boats of the end of the
-century, gliding along four or five times as fast, but with little
-noise and less smoke, and beaming forth brilliant electric light from
-every saloon window.
-
-The _Clermont_ was 133 feet long, 18 feet wide, and 7 feet deep. The
-cylinder of her engine was 24 inches in diameter, and her piston had a
-stroke of four feet; her paddle wheels were at first too large, or at
-all events dipped too deeply in the water. When improved they appear
-to have been fifteen feet in diameter. Her engines were 18 horse-power,
-and the tonnage was but 160.
-
-Fulton was busily engaged in constructing steam vessels until he died
-in 1815. One of his efforts was the building of a steam war vessel; and
-so greatly were his efforts esteemed that both Houses of the United
-States Legislature testified their respect for him by wearing mourning
-apparel on the occasion of his death.
-
-His work was developed by Mr. R. L. Stevens, whose father, indeed, had
-a steamer ready, only a few weeks after the success of the _Clermont_.
-Mr. R. L. Stevens came to grasp the idea that the form of the hull of
-steamships could be much improved by giving them fine lines instead of
-full round bows. Stevens, it is said, was able to obtain a speed of
-thirteen miles an hour; and he also, it is stated, used a different
-form of engine from that adopted by Fulton.
-
-The engines of those early steamboats were, as a rule, a sort of beam
-engine. The famous _Comet_ was engined in that manner. John Robertson,
-who actually set up the _Comet’s_ engines, lived to place them
-subsequently in South Kensington Museum. A beam, or lever, which worked
-on a pivot at its centre, was placed between the piston on one side,
-and the connecting rod—which was fastened to the crank—on the other.
-Thus, one end of the beam, or lever, was attached to the piston rod,
-and the other to the end of the connecting rod which drove the crank
-and the wheel.
-
-A development apparently of this beam-engine arrangement was the
-side-lever engine—a form of which marine engineers were also fond. The
-side lever seems, in fact, to have been a sort of double beam engine.
-The cylinder was placed upright, and a cross-piece was fixed to the
-end of the piston rod. From either end of this cross-piece a rod was
-connected with a beam or lever on either side of the machinery below.
-These levers worked on pivots at their centres, and their other ends
-were joined by a cross-piece united by a rod to the crank-shaft above.
-The idea in the side-lever engines appears to have been to obtain equal
-strength on both sides for each paddle wheel. Marine engineers did
-not apparently at first grasp the idea of a direct-acting engine—that
-is, simply one connecting rod between the piston and the crank which
-pulled round the wheel; perhaps the sizes and arrangements of those
-early steamboats did not permit of this. But in the development of the
-locomotive, the direct-acting engine did not appear at once. In any
-case, even the first vessels of the celebrated Cunard Line were of the
-cumbrous side-lever type.
-
-Now, when Fulton had made his _Clermont_ in 1807, and Bell had put his
-_Comet_ on the Clyde, some of the English speaking people on both sides
-of the Atlantic began, we say, to see that there was a future before
-the new invention. In 1809, the _Accommodation_ ploughed the waters
-of the great St. Lawrence, and two years later a steamer startled the
-dwellers on the mighty Mississippi. The _Elizabeth_ also followed the
-_Comet_ on the Clyde in 1813.
-
-She was bigger than her predecessor, but only of thirty-three tons;
-she was fifty-eight feet long, and her engine of ten horse-power.
-She was built by the constructors of the _Comet_, Wood & Company,
-of Port-Glasgow, under the direction of Mr. Thompson, who had been
-connected with some of Bell’s experiments.
-
-The next step was the introduction of steamers on the Thames. All
-things gravitate to London, steamboats among the rest. Passing by some
-experiments, in which the names of a Mr. Dawson and a Mr. Lawrence
-appear, we find that George Dodd brought a steamboat from the Clyde to
-the Thames by sea, using both sails and steam, about the year 1813 or
-1814. It is said that Dawson had a steamer plying between London and
-Gravesend in 1813, and that Lawrence, of Bristol, after using a steamer
-on the Severn brought her through the canals to the Thames, but was
-obliged to take her back because of the antagonism of the watermen. It
-is said also that the _Marjorie_, built by William Denny, of Dumbarton,
-was brought to the Thames about 1815 in six days from Grangemouth,
-having been purchased by some London merchants.
-
-However this may be, the name of George Dodd should take a high place,
-perhaps next to that of Bell, for the enterprise and effort he showed
-in seeking to establish steam vessels. His sphere was chiefly the
-Thames, though he appears to have been also animated with the idea of
-using them upon the sea. The vessel he brought round from the Clyde
-was named first the _Glasgow_ and afterwards the _Thames_, and was
-of about seventy-five tons, with nine feet paddle-wheels, and some
-fourteen or sixteen horse-power. He had some rough weather in the Irish
-Sea, and an account of the voyage is given in his book on steamboats.
-This, presumably in 1813, was the first steamship voyage at sea, as
-distinguished from steamers’ voyages on rivers.
-
-Such great progress had the introduction of steamboats made in 1818,
-that according to Dodd there were in that year eighteen on the Clyde,
-two on the Tay, two at Dundee, two at Cork, two on the Tyne, two on the
-Trent, two on the Mersey, four on the Humber, three on the Yare, one on
-the Avon, the Severn, the Orwell, six on the Forth, and actually two
-intended to run from Dublin to Holyhead. There may have been more than
-these, but they seem at all events to be the chief. Apparently there
-were, or had been, several on the Thames. Two, the _London_ and the
-_Richmond_, according to Dodd’s book, were plying between London and
-Twickenham, and had carried 10,000 persons in four months. No wonder
-the watermen were alarmed.
-
-Other vessels also had appeared on the royal river. The _Majestic_
-even had got as far as Margate, and had ventured across to Calais. The
-_Regent_ had been burned off Whitstable, and the _Caledonia_, which
-had actually two engines, had steamed across to Flushing. Dodd further
-designed a vessel which seems to have gone to Margate in about seven
-and a-half hours, speeding along at about ten or eleven miles an hour.
-No wonder that Bell could say—“I will venture to affirm that history
-does not afford an instance of such rapid improvement in commerce and
-civilisation as that which will be effected by steam vessels.” The
-_Richmond_ was a little boat of 50 tons, and 17 indicated horse-power.
-She was engined by Messrs. Maudslay & Field, of London, and presumably
-was the first steamer engined on the Thames. She ran from London to
-Richmond. In the next year Messrs. Maudslay engined the _Regent_ of 112
-tons and 42 indicated horse-power, and intended to ply between London
-and Margate; while, in 1817, this famous firm engined three vessels,
-including the _Quebec_ of 500 tons and 100 indicated horse-power,
-intended for Quebec and Montreal. Since then they have engined hundreds
-of vessels, including screw-propeller ironclads of 20,000 horse-power.
-
-Dodd, alas, though he worked so hard for the establishment of the
-steamship, does not seem to have profited by his labour. Like some
-other ingenious men he unhappily fell into poverty.
-
-The next in order of succession, who apparently became the most
-prominent and among the most useful in the story of the steamship, was
-David Napier. Russell avers that from 1818 to about 1830 he “effected
-more for the improvement of steam navigation than any other man.” David
-Napier ran the _Rob Roy_, a steamer of 90 tons and 30 horse-power,
-fitted with his own engines, between Greenock and Belfast. It appears
-that at one of the worst seasons he sailed in a vessel plying between
-the two ports,—sometimes taking a week to cover the journey, afterwards
-made in nine hours by steam,—and eagerly watched the effect of the
-heaving waves on the ship as she was tossed by the storm. Then, assured
-that there was no overwhelming difficulty for steamers, he started the
-_Rob Roy_. He also experimented upon the best shape of hull, and,
-without apparently any communication with Stevens across the Atlantic,
-came to adopt a wedge-shaped bow, instead of a rounded fore front as
-common in sailing ships.
-
-In 1819 he put the _Talbot_ on the Channel between Dublin and Holyhead.
-She was built by Wood & Company, and was one of the most perfect
-vessels of the kind then constructed. She had two engines of 60
-horse-power combined, and was 150 tons burthen. She was followed by the
-_Ivanhoe_, and in 1821 steam vessels were regularly used to carry the
-mails.
-
-Gradually the length of vessels increased without the beam being
-proportionately widened. The builders of those early boats did not at
-first realise the practicability and usefulness of altering the form
-of vessels for steamers. David Napier altered the bow, and gradually
-the vessels were lengthened. The idea came gradually to be grasped
-that as a steamer was forced forward along the line of its keel, and
-not by a power exerted upon it from without and in various quarters,
-its form might advantageously be changed. Moreover, it would seem that
-the best form for steamers is also the best for fast sailers. Russell
-is of opinion “that the fastest schooners, cutters, smugglers, yachts,
-and slavers” approach more nearly to the form of the best steamers than
-any other class of sailing vessels. However this may be, the shape of
-a steamer as well as its machinery has much to do with its speed, and
-David Napier appears to have contributed largely to these results in
-Britain.
-
-Steamers had now sped out from the rivers into the narrow seas around
-Great Britain. The next step would be into the wide and open ocean. Who
-would venture to take it?
-
-
-
-
-CHAPTER III.
-
-ON THE OPEN OCEAN.
-
-
-Why should not the Great Western end at New York?
-
-That was Brunel’s idea, and it had an immense effect on the
-establishment of transatlantic steamships.
-
-Brunel was the engineer of the Great Western Railway, and he
-audaciously desired his line to end, not at Bristol or Penzance, but,
-conquering the sea, he wished to plant his foot in the Empire city
-itself.
-
-Still he was not the first, nor the only one, in the field. To the
-_Savannah_ belongs the honour of being the first steamship to cross the
-Atlantic. Yet she was not altogether a steamship.
-
-Mr. Scarborough, of Savannah—a port of the state of Georgia—purchased a
-sailing ship of about 300 tons and 100 feet long, launched her at New
-York in 1818, intending her to ply between the two places, and had her
-fitted with machinery.
-
-Why he changed his mind and sent her to Europe, we cannot say.
-Apparently he could not trust to steam alone, for the paddle wheels
-were so constructed that they could be folded up on deck when not in
-use, and the shaft also was jointed for that purpose. Then in the
-following May she started forth for Liverpool—the precursor of a mighty
-fleet of magnificent ships which have followed since.
-
-She reached the Mersey in twenty-five days—vessels now perform the
-journey in about six. But she used steam on only eighteen days out of
-the twenty-five. Several times during the journey the paddle wheels
-were taken on deck, this operation occupying about half-an-hour.
-Possibly this was done when the wind was very favourable for sails, and
-so saved the fuel, which was pitch-pine.
-
-Apparently Mr. Scarborough was not satisfied with the venture, for,
-after failing to sell the ship in Russia, whither she voyaged, she
-touched at different ports and returned home. The machinery was taken
-out, and she winged her way henceforth by sails alone.
-
-England next did something of the same kind. The _Falcon_ steam yacht,
-a little vessel of 175 tons, voyaged to India in 1824, mostly, however,
-by the power of sails. In the next year the _Enterprize_, engined by
-Messrs. Maudslay & Field, made the passage by steam to Calcutta from
-London in the net time of 103 days—ten being used in stoppages, and
-the entire voyage thus occupying 113 days. She was a vessel of 500
-tons, 122 feet keel, and 27 feet broad, while her engines were of 240
-indicated power. Then the _Royal William_, hailing from Quebec, made
-the transatlantic passage in 1831, principally by steam, in twenty-six
-days. In 1835 Messrs. Willcox & Anderson began to run steamships to
-Peninsular ports—an undertaking which blossomed out afterwards into the
-celebrated Peninsular and Oriental Steamship Company.
-
-Then in 1838 two steamships, the _Sirius_ and the _Great Western_,
-crossed the Atlantic, the latter in fourteen and a-half days. Brunel
-had had his wish, and in 1836 he had formed the Great Western Steamship
-Company, and the vessel of the same name had been commenced. Others
-also were in the field, notably Messrs. Laird of Birkenhead, and
-the British and American Steam Navigation Company was founded. The
-_Sirius_, which had been built on the Thames, was purchased by them and
-prepared for her voyage.
-
-The prime mover in this matter is said to have been Mr. Macgregor
-Laird. He had witnessed the work of steamships in the Niger Expedition
-of 1832-33 both on sea and river, and from the time of his return he
-advocated the establishment of steamships between Great Britain and
-America.
-
-The _Sirius_ left Cork on the 5th of April, and arrived at New York
-eighteen days afterwards. She carried seven passengers, and close at
-her heels followed Brunel’s _Great Western_, which had left Bristol
-three days later. The two ships were received with loud acclaim, a vast
-crowd of spectators beholding their arrival. The vessels proved beyond
-possibility of doubt that the transatlantic voyage by steamships was
-possible, and, at a stroke, the duration of the passage was reduced by
-almost one-half. It has since been reduced to less than a quarter.
-
-The _Sirius_ made on an average about 161 miles a-day, or slightly less
-than seven miles an hour. She apparently, however, had been originally
-built for plying between London and Cork; while the _Great Western_,
-which had presumably been especially built for the transatlantic
-traffic, was both larger and more powerful. Her average speed was about
-208 miles a-day, that is between eight and nine miles an hour; while
-returning, the speed was a little better, averaging about 213 miles per
-day. The return voyage of the _Sirius_ was also better than her outward
-passage.
-
-The engines of the _Great Western_ were side-lever, and were built by
-Messrs. Maudslay & Field, of London. The cylinders were 73½ inches
-diameter, and the pistons had a big stroke of seven feet. The wheels’
-diameter was no less than 28¾ feet, while the steam was generated in
-four boilers. Her tonnage was 1340—the largest Maudslay’s had yet
-engined, with 750 indicated horse-power. She voyaged many times across
-the Atlantic, her fastest eastward passage being 12 days, 7½ hours.
-The variation in her coal consumption was very remarkable. Thus, on
-her first voyage 655 tons were burnt, but on her return journey she
-consumed 263 tons less. No doubt this was owing to the greater use she
-was able to make of the wind.
-
-The proprietors of the two vessels soon began to build others. The
-owners of the _Great Western_ laid down the _Great Britain_, and the
-proprietors of the _Sirius_ began the _British Queen_. She had paddle
-wheels of 31 feet diameter, and her piston stroke was the same as the
-_Great Western_, 7 feet. Her engines were 500 horse-power, and her
-cylinders 77½ inches in diameter. She was 275 feet long, 40 feet wide,
-and 27 feet deep. From Portsmouth to New York she crossed in 14 days, 8
-hours.
-
-Satisfactory as these results were, the pecuniary returns unfortunately
-were not so favourable. The _Great Western_, it is said, continued
-running at a loss, but others were withdrawn. Something seemed wanting
-to make the venture a commercial success. What was it?
-
-Meantime Willcox & Anderson’s steamers plied with remarkable regularity
-to the Peninsula, and this regularity aroused some attention. The
-Government of the day applied to the proprietors to submit a scheme for
-carrying the mails. It seems that previously Willcox & Anderson had
-proposed this, but it had come to nothing. The end of the matter was,
-however, that the first mail contract was signed with them, the 22nd
-of August, 1837. To carry out their bargain, Captain Richard Bourne
-and Messrs. Willcox & Anderson founded the Peninsula Company, and
-three years later it was expanded to the Peninsular and Oriental Steam
-Navigation Company—popularly known as the P. & O.—and incorporated by
-Royal Charter. The mail service was the keystone of the enterprise.
-
-The first steamer, built in 1829, was the _William Fawcett_, a small
-vessel of 206 gross tonnage, and but 60 horse-power. In 1842 the
-proprietors owned the _Hindostan_, of 2017 gross tonnage, and 520
-horse-power. She was a paddle-wheel vessel, and opened the Indian Mail
-Service. The commencement of this service marks another stage in the
-history of steam navigation. About fifty years later the Company owned
-about half-a-hundred ships, two being of 8000 horse-power and 7000
-tonnage.
-
-Some two years after the _Hindostan_ first steamed to India, Brunel’s
-_Great Britain_ was finished. She was a very remarkable vessel, and the
-wonder of her time. In the first place, she was built of iron, and,
-secondly, she was propelled by a screw, though at first it was intended
-that she should have paddle-wheels, and the engines for these wheels
-had been partly made.
-
-Barges and light vessels had been built of iron since about 1790, or
-earlier, and the Lairds of Birkenhead, among others, had built an iron
-vessel about 1829. It is said that the _Aglaia_ was the first iron
-steamer built on the Clyde in 1832. As for the screw-propeller, John
-Ericsson was successful with the _Francis B. Ogden_ in 1836, and three
-years later Sir Francis Pettit Smith clearly showed, in the vessel
-appropriately called the _Archimedes_, the value and the feasibility of
-the new system.
-
-Brunel, therefore, ever open to improvements, combined these two
-alterations in the _Great Britain_. It was in 1839, probably after
-Sir Pettit Smith’s success, that the change was made as regards the
-screw for this vessel, though the paddle-wheel engines had been begun.
-The superiority of the screw-propeller over the paddle-wheels are
-said to be these:—the engines occupy less room, and are lighter—two
-very important considerations. Then there is greater wear and tear on
-paddle-wheels, and consequently the screw vessels are less expensive.
-But most important of all, the screw being deep in the water, the
-vessel is much more suitable for ocean traffic. In the heaving billows
-of the sea one wheel may be buried deep on one side of the ship, and
-the other whirling round high in the air, and not propelling the
-vessel; whereas the screw, being always immersed, except possibly in
-severe pitching, is more constantly efficient for the whole of the
-vessel.
-
-Nevertheless, paddle-boats have their advantages. They need less water
-to work in, are started more easily, and stopped sooner. Further, it is
-said they are less liable to cause sea-sickness, as they do not roll so
-much. In a word, the difference seems to be this: paddle vessels are
-better suited as passenger boats on the shallower waters; screw vessels
-for deep sea and long distance voyages, though whether the adoption
-of twin-screws,—which it appears need not be immersed so deeply in the
-water as one screw,—will bring screw vessels into use on shallower
-waters remains to be seen.
-
-But when the _Great Britain_ was being built the greater efficiency of
-the screw-propeller for ocean voyages was not widely understood. She
-was a fine vessel, over 320 feet long, 51 feet wide, and 32½ feet deep.
-Her screw was successful; but on her fourth voyage to New York she
-became stranded in Dundrum Bay, and lay aground for nearly a year.
-
-Incidentally, however, this catastrophe seems to have given great
-impetus to iron shipbuilding; for after being floated, she was
-discovered to have suffered but comparatively slight damage. She
-was seen in dock by many persons interested in shipping, and they
-became impressed with the practicability and usefulness of iron for
-shipbuilding.
-
-Unfortunate _Great Britain_! She passed through many vicissitudes. Her
-owners got into difficulties, and after some alterations, she ran to
-Australia, and at length she wheezed her way to the Falkland Islands,
-where, it is said, she served as a hulk—a sorry end to a successful
-beginning.
-
-The engines of the early screw vessels appear to have very much
-resembled those for paddle-wheels ships. Thus the _Rattler_, engined
-by Messrs. Maudslay for the Admiralty about the year 1841, had upright
-cylinders, with a crank-shaft overhead and wheels to give speed to the
-screw.
-
-In the meantime, however, the commercial difficulty of transatlantic
-steam traffic was being solved. The something lacking had been
-supplied. What was it?
-
-
-
-
-CHAPTER IV.
-
-THE OCEAN RACE.
-
-
-“This is the very opportunity I have been wanting!”
-
-The speaker was looking at a paper setting forth that the British
-Government were open to consider contracts for the carrying of the
-letters by steamships between Great Britain and America. Encouraged, no
-doubt, by the success attending the conveyance of the mails by similar
-means to the Peninsula, the Government were now going farther afield.
-
-The practicability of ocean steam traffic had been amply demonstrated;
-but some of those early steamships did not “pay,” and to that test,
-after all, such undertakings must come. Now, the man into whose hands
-the circular had fallen was of great intelligence and remarkable
-energy. He was a merchant and owner of ships, and agent for the East
-India Company at Halifax, Nova Scotia. His name has since become known
-the wide world over. It was Samuel Cunard.
-
-Apparently he had cherished the idea of establishing transatlantic
-steam traffic for some years—since 1830 it is said—and now, here was
-the opportunity. The British Government would, of course, give a
-handsome sum for carrying the mails, and that sum would form a backbone
-to the enterprise.
-
-Over came Cunard to London in 1838. Mr. Melvill, the secretary of
-the East India Company, gave him a letter of introduction to Mr.
-Robert Napier, the eminent engineer at Glasgow. Thither then went the
-indomitable merchant, and was heartily welcomed. Napier knew Mr. George
-Burns, who was partner with Mr. David MacIver in a coasting trade,
-and the upshot of the matter was that capital of considerably over
-a quarter of a million (£270,000) was subscribed through Mr. Burns’s
-influence.
-
-The first great step thus taken, Mr. Cunard made a good offer to the
-Government, and although another offer was made by the owners of the
-_Great Western_, Cunard got the contract, the tender being regarded as
-much more favourable. The subsidy was eventually £81,000 per annum. The
-contract was for seven years, and was signed by the three gentlemen
-mentioned—Cunard, Burns, and MacIver.
-
-These three divided the labour. Cunard ruled at London, MacIver at
-Liverpool, and Burns at Glasgow. Napier was to engine the new vessels.
-It was decided that their names were all to end in “ia,” and nearly
-every one of the now historic fleet has rejoiced in a title of that
-ending. There is a sailor’s superstition that it is unlucky if the
-vessels of a fleet are not named with some uniformity; but we doubt if
-the superstition influenced the Cunard Company. In any case, they broke
-another superstition by starting their first ship on a Friday! She was
-a mail ship, and she had to go. The Cunard Company meant business.
-
-But about their fleet. Their first order was for four vessels, all
-of about the same size and power. The _Britannia_ was the first, and
-her sisters were the _Caledonia_, the _Columbia_, and the _Acadia_.
-They were paddle steamers, the value of the screw not having then
-been clearly and widely demonstrated, all of them about 207 feet
-long, 35⅓ feet broad, 22½ feet deep, and 1154 tons burthen. The
-engines—side-lever, of course, in those days—were of 740 horse-power.
-The boilers had return-flues, and were heated by a dozen furnaces.
-
-They would look now quite out of fashion, like a lady’s dress of a past
-age. They appeared something like sailing ships, with the straight
-funnels added.
-
-The _Britannia_ began the service by starting from Liverpool on the 4th
-of July, 1840, and, attaining a speed of about 8½ knots per hour, she
-made the passage to Halifax in 12 days, 10 hours, and returned in 10
-days. Her average consumption of fuel was about thirty-eight tons daily.
-
-The Bostonians gave the _Britannia_ quite an ovation. A grand banquet,
-followed by speeches, celebrated the great occasion. But they gave even
-more practical appreciation of their favour subsequently, for when, in
-the winter season, the vessel became ice-bound in the harbour, they cut
-a seven-mile passage for her through the ice, at their own cost.
-
-The Cunarders were successful, and the conveyance of the mails by
-steamship became quite established. The white-winged clipper ships
-fought hard against the Cunarders, but they had to yield. Three years
-later the Company put another vessel on the route—the _Hibernia_—and in
-1845 the _Cambria_. These were of greater size and developed a little
-better speed than their forerunners. It has always been the policy of
-the owners to improve their ships as they went on building, and even
-thus early that policy ruled.
-
-The establishment of the Cunard Company marks a most important step
-in ocean steam navigation. Further, in the same year, 1840, in which
-the Cunarders began to run, the Pacific Steam Navigation Company was
-established. Ten years later saw the foundation of the Collins and the
-Inman Lines. The Collins, an American Line, boasted that they would
-run “the Cunarders off the Atlantic.” They were very fine vessels, and
-they were the first fleet to fully adopt the upright stem and discard
-the bowsprit. But the Cunarders were ready for the fierce competition.
-They had actually put on six new vessels, and their new postal contract
-of 1847 had stipulated for a weekly, instead of a fortnightly service;
-while the subsidy was much increased. It was to be £173,340 annually
-instead of £81,000.
-
-[Illustration: THE ICE-BOUND “BRITANNIA” AT BOSTON. _By permission of
-The Cunard Steamship Co._ ]
-
-The echoes of that fierce struggle between the Cunarders’ and the
-Collins’ boats have now died away, or have been quite lost in the other
-clamorous cries of that wonder of the world, the development of
-the transatlantic steamship traffic; but apparently partisanship ran
-very high. The Collins’ seem to have been slightly the faster vessels,
-coming from America in 9 days 17 hours, but occupying nearly two more
-days to return. Alas, disaster overtook them. The _Arctic_ perished by
-collision; the _Pacific_ was lost at sea, and no one knows the story
-of her death, for she was never heard of more. Bad management, and
-extravagance surged over the remaining vessels, and the fine ships went
-as old iron!
-
-But the Inman line had also begun to run, about 1850. These ships, like
-the _Great Britain_, were built of iron and propelled by a screw. The
-first was the _City of Glasgow_, and several famous “Cities” followed;
-though years afterwards the Inman line became the “American,” and
-the appellation “City” was dropped, the ships being simply known as
-_Paris_, _New York_, _Berlin_, etc. The Inman line had the distinction
-of being the first, apart from the _Great Britain_, to use iron screw
-steamers regularly on the Atlantic. Other lines soon followed, the
-Anchor, the Allan, and the Guion, while the Cunarders, not to be
-beaten, came along in due course with iron and screw steamers.
-
-But great changes were at hand. To mark these changes let us look at
-what may be called the culminating ship of the old type of steamers—the
-_Great Eastern_.
-
-This historical vessel was the largest ever built. She was 680 feet
-long, by 83 feet broad, and her hull was 60 feet high, 70 feet
-including bulwarks. But the steam pressure of her engines was only
-from 15 to 25 lbs. She was fitted with both screw-propeller and paddle
-wheels. Her screw-propeller engines were of 4000 indicated horse-power,
-and paddle of 2600, but they could together work up to 11,000
-horse-power.
-
-Commenced at Millwall early in 1854, she was not launched until near
-upon four years later. The launching itself was a difficult and
-expensive business, costing £60,000, and only effected after various
-attempts extending over nearly three months. The total cost of the
-vessel has been estimated at £732,000.
-
-[Illustration:
-
-ISAMBARD KINGDOM BRUNEL. _By permission of Messrs. Graves & Co._ ]
-
-It will be seen at once that so large an outlay required an immense
-business to yield a satisfactory return, and indeed, financial
-difficulties hampered her success almost from the very commencement,
-even before she was launched.
-
-She was planned, in 1852, by the great engineer, I. K. Brunel, and by
-Scott Russell. In the life of Brunel by his son, it is stated:—“It was,
-no doubt, his connection with the Australian Mail Company that led Mr.
-Brunel to work out into practical shape the idea of a great ship for
-the Indian or Australian service.”
-
-The Eastern Steam Navigation Company desired a vessel to trade to
-Australia and back, large enough to carry a sufficiency of coal for the
-outward and homeward journey, and yet to have space for a goodly number
-of passengers and a bulky amount of cargo.
-
-That was the idea, and we perhaps can hardly realise what a difficulty
-this question of coal carrying capacity was in those days, before
-the problem had been solved by high-pressure steam boilers, triple
-expansion engines, improved condensation, and quick passages. Even so
-great a philosopher as Dr. Lardner could not believe in 1835 that a
-steamship could voyage from Liverpool to New York without stopping—we
-presume for fresh fuel.
-
-The _Great Eastern_, therefore, was planned to carry 15,000 tons of
-coal; whereas now the large Atlantic liner _Paris_ needs only 2700 tons
-for her Atlantic trip. The difference is most striking, for the _Paris_
-is one of the largest steamships afloat, but her working steam pressure
-is 150 lbs. instead of the 15 or 25 lbs. of the _Great Eastern_.
-
-This immense vessel was also planned to carry some 5000 persons, or
-about 500 less if any large number were to require state-rooms, and
-finally she was to convey 5000 tons of cargo. The idea of water-tight
-compartments was anticipated in her case, even to the extent of
-longitudinal ones, and she had half-a-dozen masts of which five were of
-iron.
-
-When at length she was launched, the directors’ minds misgave them
-as to an Australian trip, and they determined to cross the Atlantic
-instead, for a trial voyage. She started on the 8th of September,
-1859, but alas! when off Hastings some steam pipes burst. Several
-persons were killed and wounded, and the voyage ended at Portland.
-
-Next year she tried again and crossed in eleven days, after which she
-made several voyages with success—on one occasion conveying soldiers to
-Canada. Unfortunately for the owners, however, she did not pay.
-
-Then in 1865 she began to be engaged in submarine telegraph work, by
-which she will most likely be best remembered, and two years later she
-was chartered to convey passengers from America to Havre for the French
-Exhibition, but this scheme failed.
-
-Then for some years from 1869 she was successfully engaged in
-cable-laying, in the Red Sea, the Atlantic, and the Mediterranean,
-etc., after which she came down to be a coal hulk in 1884, stationed at
-Gibraltar.
-
-At length she was sold for £26,200 at London, by auction, and was on
-view in the Thames, and also in the Mersey. At this latter river her
-huge sides were used as an advertising “board” for a Liverpool business
-house. Again in November, 1888, she was sold by auction, this time for
-breaking up, and it is said that the total proceeds of the sale which
-lasted five days was £58,000, more than double what she had previously
-brought!
-
-“A ship before her time,” says some one, thinking of the huge vessels
-of the last decade of the nineteenth century. That is true, but the
-immense space required for coal, and her low-pressure engines, had
-also something to do with her comparative failure. The problem which
-the _Great Eastern_ failed to solve has been met in other ways—viz.,
-by the use of high-pressure steam and compound, triple-expansion and
-even quadruple-expansion engines. That is, the steam, working at 150 or
-160 lbs. pressure, instead of the 25 lbs. of the _Great Eastern_, is
-passed through two, three, and even four cylinders respectively, and
-the economy in coal consumption is astounding. Thus the use of triple
-expansion engines has brought the saving in coal down from 4 lbs. per
-indicated horse-power to less than 1½ lbs.
-
-There have been many other improvements also, such as the use of steel
-instead of iron, the parts being thus stronger and yet lighter; the
-circular tubular boiler enabling high-pressure steam to be economically
-produced and maintained; the use of surface condensers, by which the
-exhaust steam is quickly reduced to water and returned to a “hot well”
-ready for the boilers, to be speedily again raised to high pressure
-steam; and a forced draught by which the furnaces are made to roar
-furiously and heat the water in the boilers speedily.
-
-[Illustration: THE “GREAT EASTERN.”]
-
-But these things were not all attained in a day. The introduction of
-the compound marine engines in 1854-56 by John Elder, marks the first
-great step of the new departure. In 1856 he engined vessels for the
-Pacific Steam Navigation Company, on the compound principle, which
-proved very satisfactory.
-
-Again in 1870, the appearance of the White Star liner _Oceanic_, marked
-a new development. Her yacht-like shape, great length, and general
-symmetry of form commenced a marked change in Atlantic liners.
-
-It was in 1867 that Mr. T. H. Ismay bought the interest of the managing
-owner of the White Star line—a set of sailing clippers, dating from
-the rush to the Australian gold diggings—and began to introduce iron
-vessels instead of wooden clipper ships. In 1869 he established the
-Oceanic Steam Navigation Company—popularly known as the White Star—and
-was later on joined by Mr. William Imrie. The Company was started with
-so much wisdom and boldness that the £1000 shares were privately taken
-up at once. The order for the new steamers was given to Harland &
-Wolff, of Belfast, because, it is said, an influential share-holder had
-had satisfactory dealings with them before.
-
-The _Oceanic_ was of 3600 tons burthen, and with engines of 3000
-horse-power. The accommodation for first-class passengers was placed
-amidships, where the motion of the vessel is said to be felt the least,
-and altogether she embodied improvements which made her the type of
-many of the Atlantic passenger ships since. The earlier White Stars
-were fitted with compound engines, and reduced the passage to about 8½
-days.
-
-But when the White Stars _Germanic_ and _Britannic_ appeared in 1877,
-then a marked advance indeed was made in the Atlantic record. The
-_Britannic_ astonished the world by speeding from Queenstown to New
-York in 7 days, 10 hours, and 50 minutes, and since then she has beaten
-her own record. Her sister ship _Germanic_ also did as well, and the
-fierce race for the blue ribbon of the Atlantic may be said to have
-begun.
-
-It was even prophesied that the time across the water might be reduced
-to six days. How has that been fulfilled?
-
-
-
-
-CHAPTER V.
-
-BEFORE THE FURNACE.
-
-
-“The record’s broken again, Jemmy! The White Star has come home a
-couple of hours earlier!”
-
-“She has, has she? Well, it will be the Cunard’s turn next week. It’s
-wonderful what they get out of the Cunard’s engines.”
-
-“They do; but I’m thinking the American’s _New York_ will be doin’ the
-fastest bit.”
-
-“Well, well, it may be. They’re all main powerful vessels. Do you mind
-when the Guion’s _Alaska_ came home in 6 days, 18 hours, 37 minutes?”
-
-“I do, and about ten years later, I suppose, some ships were doing it
-in about a day less time!”
-
-“Ay, ay, and I see they’re goin’ ahead down south too.”
-
-“Yes, there’s fast steaming all over the world, Jemmy!”
-
-“I told you what would happen when the compound engine came into use. I
-said, ‘Mark my words, now they’ve got the compound engine, they will go
-ahead’—and they have.”
-
-Jemmy’s prediction has been amply verified, for almost every year since
-the compound engine came largely into use, has witnessed a greater
-speed in ocean steamers.
-
-And the speed has not been obtained at sacrifice of comfort. On the
-contrary, an ocean passenger steamer belonging to any of the great
-passenger lines is something like a floating palace.
-
-After the _Britannic_ and _Germanic_ appeared, line after line put
-forth fine vessels; and in 1889 was launched the White Star steamer
-_Teutonic_, which for some time held the proud position of the
-fastest ship on the Atlantic. She had crossed in 5 days, 16 hours,
-31 minutes. The average of several trips, both for herself and her
-sister _Majestic_, was 5 days, 18 hours, 6 minutes. And they were run
-very close by the American liners, _Paris_ and _New York_. These four
-vessels were among the first propelled by twin-screws. Engineers began
-to see that it was better to use great power in two shafts and two
-propellers than in one.
-
-In July, 1892, the fine Inman (now called American) liner _Paris_
-crossed the Atlantic in 5 days, 15 hours, and 58 minutes, and in
-October of the same year the same vessel steamed from Liverpool,
-touching as usual at Queenstown, in 6 days, 2 hours, and 24
-minutes—including the time at the Irish port. This was then the
-quickest time on record for the entire journey. From Queenstown to
-Sandy Hook the time was 5 days, 14 hours, and 24 minutes, a gain of 1
-hour and 34 minutes on her voyage in the previous July. Her best day’s
-run was 530 knots.
-
-The contest, therefore, between the two White Stars and the two Inmans
-has been very close, the record time resting now with the one and then
-with the other.
-
-But the Cunard Company, not to be beaten, put on the _Campania_ in
-1893, and in April of that year she made the fastest maiden trip then
-on record, one day indeed compassing 545 knots in the 24 hours.
-
-The _Campania_ is 625 feet long by 65¼ feet broad, and 43 feet deep
-from the upper deck. Her gross tonnage is 12,950. She is fitted with a
-cellular double bottom extending fore and aft, and also with sixteen
-bulkheads, so arranged that the vessel would float even if two, or in
-some cases three, compartments were open to the ocean.
-
-She is a twin-screw vessel, fitted with two sets of very powerful
-triple-expansion engines. They are seated in two separate engine-rooms
-with a dividing bulkhead and water-tight doors.
-
-Each set of engines has five inverted cylinders—viz., two
-high-pressure, one intermediate, and two low-pressure—all arranged to
-work on three cranks set at an angle of 120 degrees to each other. Her
-indicated horse-power is 30,000. The boiler-rooms are doubly cased, the
-space between being fitted with nonconducting material for sound and
-heat.
-
-[Illustration: HIGH AND LOW PRESSURE CYLINDERS OF THE “CAMPANIA’S”
-ENGINES.]
-
-In this huge vessel four decks rise tier above tier, beside erections
-on the upper deck, known as promenade and shade decks. These four
-principal decks are the orlop, the lowest of all, used for cargo,
-stores, and machinery; the lower, the main, and the upper decks, the
-last three being devoted entirely to passengers.
-
-Imagine yourself on the upper deck. Before you stretches the long
-vista of its length, like some far-reaching walk ashore; a circuit of
-the vessel four times makes a mile. Above rises the shade deck with
-the navigating apparatus, and surrounded by the twenty lifeboats of
-the vessel; above again is the captain’s bridge, where are placed the
-telegraph and wheel house, while higher still is perched the crow’s
-nest or look-out box, on the foremast, and about 100 feet from the
-water-level. Give a glance, too, at the huge funnels, 120 feet high,
-and so large that when in the builder’s yard a coach full of passengers
-was driven with four horses through one of them.
-
-Descending then, the grand staircase, which is sufficiently wide for
-six persons to walk down abreast, and admiring the polished panelling,
-the rich Japanese paper, and the lounges on the landings, we enter the
-superb dining-saloon 100 feet long by 62 feet broad. Four huge tables
-run almost along its length, with smaller tables in the corners, while
-the wood-carving, carpeting, gold decorated roof, costly mirrors, and
-upholstering in rich red velvet are of the most sumptuous description.
-
-From this magnificent hall you can wander on through other apartments
-of great splendour, drawing-room, library, smoking, music room,
-bath-rooms, and numbers of state-rooms. There are single berth, double
-berth, and three and four berth cabins—the old wooden benches for beds,
-however, being replaced by iron bed-steads throughout the ship. The
-electric light glows everywhere, being distributed by some fifty miles
-of wire.
-
-[Illustration:
-
-THE “CAMPANIA.” _By permission of The Cunard Steamship Co._ ]
-
-The second-class accommodation differs but in degree from the
-magnificence of the saloon, while the steerage passengers are berthed
-on the lower deck, but have the privilege of walking on the upper deck.
-An additional idea of the size of the ship may be gained when we learn
-that the crew consists of over 420 persons—viz., 190 engineers, 179
-stewards, and 54 sailing hands, while the vessel’s full complement
-of passengers brings up the total number of persons aboard to 1600
-souls—quite a floating town indeed.
-
-About five years after the birth of the _Teutonic_ the newspapers
-recorded, in May, 1894, that the _Lucania_, sister ship to the
-_Campania_, and one of the newest Cunarders, had performed the journey
-across the Atlantic in 5 days, 13 hours, and 28 minutes. Her average
-speed was 22¼ knots, or 25·7 land miles per hour, marking one of the
-quickest runs then ever recorded; and about the same time came the news
-that the P. & O. steamer _Himalaya_ had completed a mail transit from
-Bombay of 12½ days, and as her voyage to Bombay had been just over 13
-days—the best outward passage—she had completed a round mail transit to
-Bombay and back, excluding stoppages, of 25½ days.
-
-A little later, in the same year, the torpedo-boat destroyer, _Hornet_,
-built by Messrs. Yarrow & Co., of Poplar, for the British Navy,
-achieved, it is said, about 27 knots; that is, roughly speaking, near
-to 29 or 30 miles an hour, which speed proclaimed her to be then
-one of the fastest steamships in the world. She was fitted with the
-Yarrow water-tube boilers, which are both light and strong, while the
-consumption of coal was said to be remarkably small. She has two sets
-of triple-expansion inverted engines.
-
-Again, a short time later, Messrs. Thorneycroft, of Chiswick, obtained
-similar results with the _Daring_, another boat of the same kind built
-for the British Government, and fitted with the Thorneycroft improved
-water-tube boilers. These, it is claimed, will raise steam from cold
-water in fifteen minutes. She passed the measured mile on the Maplin at
-the high speed of 29¼ miles an hour.
-
-In the same summer a Company put on a fine steamer for service on
-the Thames and the English Channel, called _La Marguerite_, which
-developed, it is said, a speed of 25 miles an hour, which would make
-her one of the fastest passenger vessels then afloat.
-
-Another Company has also a noteworthy vessel running on the Estuary
-of the Thames—viz., the _London Belle_, plying from London Bridge to
-Clacton-on-Sea. She is a triple-expansion paddle boat, and the first
-river steamer fitted with three crank triple-expansion paddle engines.
-She was built by Denny of Dumbarton, and can develop a speed of 19½
-knots—_i.e._, twenty-three statute miles per hour, and is worked with
-great economy of coal consumption.
-
-An example of a quadruple-expansion engine steamer may be found in the
-_Tantallon Castle_, one of the newest vessels for voyaging to South
-Africa. She is 456 feet long, over 50 broad, with a gross tonnage
-of 5636. She is fitted with quadruple-expansion engines of 7500
-horse-power, and the stoke holes are well ventilated by large fans
-speeding round with great swiftness.
-
-Improvements in steamship building had gone steadily on; and it is safe
-to say that a pound of coal, after the compounding principle came fully
-into use, did four or five times the work it accomplished before high
-pressure engines were fully utilised.
-
-Let us enter the engine-room of a big liner, and see for ourselves. It
-is a triumph of engineering. Still, at first, you cannot understand
-anything of the complicated mass of machinery. Then you notice three
-large cylinders—for these are triple-expansion engines—with pistons
-shooting in and out downwards, and attached by connecting rods to the
-cranks of the propeller shaft below. The cranks are bent at different
-angles so that they can never all be in the same position at once.
-There is a maze of machinery and shining rods, bewildering to the
-uninitiated eye. But you gradually notice how absolutely regular every
-part is in its action, and how beautifully one part fits with another.
-
-Then go before the furnace; you find yourself in front of a huge
-structure, at the bottom of which is the long fire box; above rises the
-heat box communicating with tubes over the furnaces, with the water
-circulating between. The water, indeed, is beneath the furnace, about
-parts of the heat box, between and above the tubes. The object is,
-of course, to obtain as great heating surface as possible. The tubes
-communicate with the funnel at their other end. Boilers are made of
-a “mild” steel which has, it is said, a most remarkable tenacity of
-28 tons to the square inch. Consequently they are able to bear great
-pressure of steam.
-
-[Illustration: STOKE HOLE.]
-
-Hot distilled water is admitted to the boiler from the surface
-condenser. This is a “box,” riddled with tubes, through which cold
-sea water is pumped. The waste steam, having done its work in the
-cylinders, is passed into this “box,” is condensed by touching the
-chilly tubes of sea water, and can be run off or pumped to a hot
-cistern, whence it is used to feed the boiler and be turned once more
-to steam. About 4000 tons of water an hour pass through the surface
-condensers of a large liner when she is at full work.
-
-The largest steamers require over 150 men to work the furnaces and
-machinery, and the attention given is hard and unremitting. In some of
-the fast Atlantic greyhounds the strain is terribly severe, especially
-when the sea is beginning to run high. The rollers may be but 20 feet,
-yet these are quite high enough even for a splendid ocean racer to
-contend with and yet maintain her speed.
-
-Now her bows are pointing sky high, and her stern is deeply submerged;
-now she takes a header plump into the trough of the sea, and the
-engines race round; the propeller is suddenly raised out of water.
-But blow high, or blow low, on she goes, and the engineers are always
-busy. The furnaces roar with ceaseless rage. For days and nights the
-fires are kept at glowing heat. A forced blast maintains the draught;
-the steam condensed back into warm water is supplied to the boilers;
-half-naked men work hour after hour to rake the fires, clean them, pile
-on the fuel, and keep the most powerful head of steam the boilers can
-stand.
-
-When the furnace doors are opened tongues of flame leap forth, and
-the heat is enough to make a man sick. But with head turned away, the
-stoker stirs up the fire with his huge “slice” or fire rake, and cleans
-out the clinker clogging the bars.
-
-Then on go the coals! One layer, shot in from the shovel with unerring
-precision and skilful experience, right at the back; then another just
-in front of the first, and so on till the long furnace is filled.
-Bang! the furnace door clangs, and the man reels away, sick and
-exhausted, with tingling eyes and heaving chest. Then coal has to be
-brought from the bunkers to the furnaces, tons of it per day, and if
-the ship rolls too much for the barrows to be used, the fuel must be
-carried in baskets.
-
-There is an engineer in charge of each stoke hole, and two on the
-platform in each engine room; as a rule, the staff are on duty in
-turns—four hours out of every twelve. But if the weather be bad they
-may have harder times.
-
-No matter how hot the machinery becomes, the engineers must not
-reduce speed, except it be to prevent disaster. Oil is swabbed on in
-bucketfuls, so to speak, but at every thrust the polished steel may
-gleam dry and smoking. Then on goes the water, as if there actually was
-a conflagration, and meantime a mixture of oil and sulphur is dabbed
-on. The water flies off in steam, so hot are the bearings, so terrific
-the friction of the incessant speed; and at last, down comes the
-reluctant order, wrung out of the chief like gold from a miser—“Slow
-her down.”
-
-It is done—dampers are clapped on furnaces, steam pressure dropped a
-little, and engines reduced to half speed; the three great cranks of
-the high, intermediate, and low pressure cylinders move round easily,
-and the tremendous noise gradually sinks to a murmur, compared with the
-previous rush and roar. The machinery cools. But when quite safe, on
-is piled the speed once more, and again the cranks fly round, and the
-mighty engines work their hardest to drive the mammoth ship through the
-surging green rollers.
-
-So superbly are these marine engines built, and so excellently are they
-maintained, being continually overhauled, so as to be kept in the pink
-of perfection, that, as years go on, they seem to “warm to their work”
-and do even better than at first.
-
-On the completion of the 200th round voyage of the celebrated “White
-Stars,” _Germanic_ and _Britannic_, about January, 1894, they seemed
-steaming as regularly and as fast, or faster than ever. Thus, on the
-198th outward trip of the _Germanic_, in September, 1893, she made the
-fastest westward passage, but one, she had ever accomplished. During
-their lives, it was said these vessels had maintained remarkable
-uniformity in speed, and each vessel had steamed 200 times 6200
-nautical miles, that is nearly a million and a-half statute miles, with
-the original engines and boilers—a performance, in all probability,
-without parallel in the world.
-
-Those people who care for figures may be interested in knowing that
-the _Britannic_ had been 91,741 hours under steam, and 85,812 hours
-actually under weigh. Her engines had made 280 million revolutions, and
-maintained an average speed of 15 knots, or 17¼ statute miles an hour,
-while she had burnt 406,000 tons of coal. During their nineteen years
-of life the two vessels had carried 100,000 saloon, and over 260,000
-steerage passengers, in safety and in comfort.
-
-This is a record of which all concerned, builders, owners, and working
-staff, may well be proud. It augurs first-class, honest work, and
-superb engineering skill. Since the construction of these ships,
-however, vessels surpassing them in speed have, of course, been built,
-among which may be mentioned the same line’s _Teutonic_ and _Majestic_.
-
-The well-known Cunarders, _Umbria_ and _Etruria_, have also done some
-very fine work, indicating great excellence of construction. Thus,
-on her eighty-second voyage, the _Umbria_ steamed from Queenstown to
-Sandy Hook in 5 days, 22 hours; or, allowing for detention through fog,
-5 days, 18½ hours, which is within three or four hours of the White
-Stars’ and American’s time.
-
-The story of the British warship _Calliope_, at Samoa, will also show
-how marvellously well ships’ engines can be built. Some difficulties
-had arisen between the United States and Germany as to Samoa, and
-several warships had gathered there. Some weeks of bad weather had
-occurred, and then, on the 15th of March, 1889, the wind began to blow
-with tremendous force. Down came the top masts from the warships—taken
-down as a precaution; steam was raised in the boilers in case anchors
-should not hold, and spars were made secure. But no man among the
-sailors expected such a hurricane as ensued.
-
-Rain fell at midnight, and the wind increased. Huge waves rolled in
-from the South Pacific, and the vessels tugged madly at their anchor
-chains and pitched fearfully up and down, like corks. Then the _Eber_,
-one of the German ships, began to drag her anchors; and the _Vandalia_,
-one of the Americans, followed suit. But by their steam power they kept
-off a dangerous reef, and also prevented themselves from colliding with
-their neighbours.
-
-Still higher and higher blew the hurricane, and the rain fell with
-tropic severity. Three hours after midnight the situation had become
-terrible. Almost every vessel was dragging her anchors, and the danger
-of collision was constant.
-
-The scene of the occurrence was a small bay before Apia, the capital
-of Samoa. But there is a coral reef extending in front of the bay
-for about two miles, and in the centre of the reef an opening about
-a quarter of a mile wide. The ships, therefore, were shut up in a
-comparatively small space, from which the way of escape was this
-gateway through the reef. The tide rushed in with great rapidity,
-swamping the land a hundred feet or so above high-water mark.
-
-As morning dawned and wore on to-day, the _Eber_ collided with the
-_Nipsic_ and then with the _Olga_, and, finally, was dashed by the huge
-waves, like a toy, upon the reef, and rolled over into deep water.
-Only five men struggled to shore and were saved. Other sad disasters
-occurred; and then, shortly before noon, the _Vandalia_ and the
-_Calliope_ were tossed perilously near together, and also toward the
-dangerous reef. In endeavouring to steam away, the _Vandalia_ collided
-with the _Calliope_, and was much damaged. Then, with splendid courage,
-Captain Kane determined to steam right away to sea—to remain would but
-risk another collision, or a wreck on the reef. Sea-room he must have
-at any cost!
-
-“Lift all anchors!” was the thrilling order, and then—“Full speed
-ahead!” Round swung the vessel’s head to the wind, and though the
-powerful engines were working “all they knew” to force the ship along,
-the steamer stood still, as if aghast at being asked to break through
-these tremendous waves.
-
-But she stood for a moment only. The superb engines began to tell;
-the quickly-whirling screw churned up the heavy water at the stern,
-and slowly the good ship made headway through the huge billows. They
-crashed over her stern and poured over her decks, as if in anger at her
-defiance. But on went the coal to her furnaces, and the thick smoke
-reeled off from the funnel in volumes. The strain quivered through
-every limb of the ship, but her captain kept her at it, and inch by
-inch she forced her way through the pounding seas.
-
-“This manœuvre of the gallant British ship,” says an eye-witness, Mr.
-John P. Dunning, of the Associated U.S. Press, “is regarded as one
-of the most daring in naval annals. It was the one desperate chance
-offered her commander to save his vessel and the three hundred lives
-aboard. An accident to the machinery at this critical moment would have
-meant certain death to all. Every pound of steam which the _Calliope_
-could possibly carry was crowded on, and down in the fire-rooms the
-men worked as they never had worked before. To clear the harbour, the
-_Calliope_ had to pass between the _Trenton_ (an American warship)
-and the reef, and it required the most skilful seamanship to avoid a
-collision with the _Trenton_, on the one hand, or total destruction
-upon the reef, on the other. The _Trenton’s_ fires had gone out by that
-time, and she lay helpless almost in the path of the _Calliope_.”
-
-[Illustration: PROMENADE DECK OF THE “PARIS.”]
-
-But the dreaded collision did not take place. And as the _Calliope_
-passed near to the _Trenton_, a great shout was given for the British
-vessel, and the Englishmen responded with a noble cheer. Captain Kane,
-who subsequently was appointed to the _Inflexible_, said afterwards:
-
-“Those ringing cheers of the American flag-ship pierced deep into my
-heart, and I shall ever remember that mighty outburst of fellow-feeling
-which, I felt, came from the bottom of the hearts of the gallant
-Admiral and his men. Every man on board the _Calliope_ felt as I did;
-it made us work to win. I can only say, ‘God bless America and her
-noble sailors!’”
-
-The _Calliope_ did win. Her superb machinery and the fine seamanship
-with which she was handled were successful, and she returned to the
-harbour when the storm had subsided. Happily the brave men of the
-_Trenton_ also survived, though fourteen vessels were wrecked and
-nearly 150 lives were lost.
-
-Strongly and staunchly as are built the Government ships, many of the
-great liners are their equals in these respects. Indeed, several of
-them are now retained by the Government to be used as armed cruisers
-should occasion require. The fittings and accommodation on many a
-large liner are also luxurious in the extreme. There are library
-and smoking-room, superb saloons and state-rooms, drawing-rooms,
-music-rooms, and tea-rooms, bath-rooms, etc. In short, they are
-floating hotels of a most sumptuous character.
-
-A modern steamship, with its multitude of comforts and conveniences
-for passengers and its complexities of machinery for fast and safe
-steaming, is a great triumph of engineering skill. Patience and
-forethought, the persevering development of sound principles, and
-the application of new ideas, have all contributed to this great
-achievement.
-
-From the _Comet_ to the _Campania_ is a marvellous development within
-a century. And it has not been accomplished along one line, but upon
-many. The use of steel, of many-tubed and strong boilers, of high
-pressure steam, which would have frightened Henry Bell out of his
-senses, the forced draught and the surface condensers, the screw
-propeller, the direct-acting and the triple and quadruple expansion
-engines, have all contributed to the noble results. Steamships, with
-their complex, beautiful, and powerful machinery, may rank among the
-most wonderful things that mankind has ever made.
-
-[Illustration]
-
-
-
-
-[Illustration]
-
-
-FAMOUS BRIDGES AND THEIR BUILDERS.
-
-
-
-
-CHAPTER I.
-
-“THE BRIDGE BY THE EARTHEN HOUSE.”
-
-
-“You will not try again, surely?”
-
-“Ay, I shall indeed!”
-
-“What! after two failures?”
-
-“Yes; I see the mistakes now. This bridge fell because it had too much
-weight on its haunches.”
-
-“Haunches! you mean the two side-curves of the arch were too heavy.”
-
-“Ay; you’ve heard the proverb no doubt that ‘An arch never sleeps.’
-That is, should too great a weight fall on the crown or top part, the
-arch will fall at the sides outwardly, and the crown will sink; while,
-curiously enough, if it be built with too little weight on the crown,
-as this was, the crown will be forced upwards, and the sides will fall
-inwards.”
-
-“Then you mean to build your third bridge with less weight
-proportionately on its haunches?”
-
-“Exactly so.”
-
-“Well, I wish you good luck, friend Edwards, for we need a bridge
-sorely over the brawling Taff.”
-
-“You shall have it, neighbour. I shall succeed this time. I have
-gripped the right principle at last.”
-
-He had indeed, for the bridge he then built lasts to this day. It was
-the famous Pontypridd bridge over the Taff on the Llantrissant and
-Merthyr road, and was called the Pont y du Prydd, or the bridge by the
-earthen house, for a mud hut stood near.
-
-[Illustration:
-
-PONTYPRIDD BRIDGE. _From Encyclopædia Britannica._ ]
-
-About the year 1745 it was determined to build a bridge over the
-rushing Taff, and William Edwards, a self-taught mason of the country,
-undertook the task. The first bridge he built was of three arches,
-which, in less than three years, was dashed away by a great flood. The
-water rose so high as to surge over the parapet.
-
-It must have been a sore disappointment to the hard worker to see his
-structure suddenly swept to ruins. But he was a shrewd, common-sense,
-observing man, and, nothing daunted, he tried again. This time he
-determined to build one bold arch of 140 feet. The object was to
-obviate the necessity of raising piers for more arches, and so
-obstructing the water; these former piers having caused, or assisted
-in causing, the destruction of his first bridge.
-
-But the second gave way from the proportionally heavy weights on the
-haunches, as Edwards, we imagine, told his friend, and once more he had
-to face ruins. Yet a third time he tried, and the third time he was
-successful. Generations have come and gone, the children who played
-about its abutments have grown grey and have passed away, but still the
-country mason’s bridge of 140 feet span stands its ground and serves
-the community.
-
-He reduced the heavy weight on the sides by making openings in the
-spandrels—that is, the part above the curve of the arch; while, instead
-of filling up the interior space with rubble, he used charcoal. But the
-arch is very steep, and a chain and drag is kept to assist any horse
-when descending.
-
-These bridges illustrate the principle of the arch. Passing by the
-fact that it is evidently safer to span a swelling river by a bridge
-of wide, rather than of several narrow arches, three powers or forces
-act on the row of stones or bricks forming the arch. There is first the
-force that would carry the stone downward—that is, the force of its own
-weight and of anything that might be placed upon it. But then there are
-stones or bricks pressing against it on either side, and in its turn it
-presses upon them. When, therefore, every part presses equally, one not
-heavier or weaker than the others, a support for all is gained by the
-contiguous pressure and by the balance of forces.
-
-Long bridges were sometimes built in this way, and the longest in
-England in the Middle Ages was at Burton, over the Trent. It was 1545
-feet long, and had 36 arches. It was not superseded till 1864, when a
-new bridge was built.
-
-In an arched bridge, the higher it rises in proportion to the width of
-the arch, the easier is its construction, and the less is the stress
-upon its parts; moreover, any inaccuracy in design or in building is
-likely to be less harmful. We are not surprised, therefore, that
-Edwards, in his third attempt, decided upon that form.
-
-One of the widest arches in the world is that of the famous Grosvenor
-Bridge at Chester. It has a span of 200 feet, with a rise of 42 feet.
-An arch, however, in the Washington Aqueduct extends to 220 feet span,
-while the central span in the Southwark Bridge, designed by Rennie, is
-240 feet. This last, however, is of cast-iron.
-
-The principle of the arch, however, does not appear first in the
-history of bridge building. Bridges are as old as mankind; that is, no
-one knows when first men began to cross streams and chasms by placing
-the trunk of a tree from one side to the other, and thus bridging the
-gulf.
-
-Then, possibly, the next step was to build up a pile of stones in the
-centre of the stream—taking the stones there by coracle or canoe—and
-placing a tree trunk from the side to the central heap.
-
-Yet another development would most likely be a simple cantilever
-bridge—though these early builders would not have known that
-Frenchified word. But they knew that after embedding a tree trunk
-firmly on each side of the bank so that a considerable portion should
-project over the stream, they could place a third log from one end to
-the other, and thus get a bridge much longer than when made of one tree
-trunk alone.
-
-This principle, known so long ago, was used and immensely developed in
-the construction of the famous Forth Bridge, one of the most remarkable
-structures of the nineteenth century. This cantilever principle is
-very important in bridge building, and it is said that there exists an
-ancient bridge on this principle across the Sutlej in India with a span
-of 200 feet.
-
-[Illustration: THE POST BRIDGE, DARTMOOR.
-
-(_An example of an early bridge, of “slab” construction._)]
-
-A further variety of early bridges was the “slab” bridge, consisting
-of slabs of granite placed from side to side, or from the sides of
-the bank to heaps of stones piled up in the stream. A good example
-of such a bridge may be seen at “Post Bridge” over the Dart on
-Dartmoor. Ages ago this bridge was built, and as we study it and
-compare it with the modern structure not far distant, we wonder how the
-ancient Britons—if those sturdy individuals are really responsible for
-it—could raise and place those huge slabs of stone without engineering
-apparatus. Probably it was done with levers and rollers, and there must
-have been many shoulders to the wheel in the process. Certainly they
-had plenty of granite at hand on wild Dartmoor.
-
-But passing by all these early forms of bridges—which it will be
-noticed are built of a few large pieces of material—it was left to
-the Romans, at all events in Europe, to largely adopt the arch as a
-principle of construction.
-
-Now, here we are dealing with an altogether different principle. The
-arch is made up of a number of comparatively small pieces of material
-bound together by mortar, or cement, or even clamps, and by the power
-of gravitation.
-
-We doubt if that idea is realised by half the people using the
-multitudinous arches abounding to-day; yet it is true. Or to put it in
-another way, the various parts are arranged so that they keep up each
-other by pressure.
-
-If you take two cards, or bricks, or slabs of stone and lean them
-together at the top, while the other ends may be far apart, you will
-find they will bear a certain amount of weight. Here you have the
-principle of the arch in its simplest form; and it may be that out of
-that primitive performance the arch has grown. This kind of triangular
-arch is to be met with in ancient structures in Great Britain. The
-flanks or haunches of an arch are its sides, from the first stone to
-the keystone; and the crown is its highest part; while the central
-wedge-shaped piece of stone or brick is called the keystone.
-
-The stones or bricks are cemented together when being built over a
-framework of timber, called the centering, and when the keystone is
-placed and the arch is complete it ought to remain firm.
-
-But should too great a weight fall on the crown the bridge will fall
-outwardly at the sides, and the crown will sink; while, curiously
-enough, if it be built with too little weight on the crown, it will be,
-as it were, forced upwards, and the sides will fall inwards, as in the
-case of the second of the famous Pontypridd bridges, which actually did
-this. The material in the middle of the arch was less in proportion
-than that over the sides or “haunches,” and these heavier weights on
-the sides caused the crown to be forced upwards.
-
-Two causes combined to make changes in bridge building. These were the
-needs of railways and the introduction of iron as a building material.
-The first iron bridge was constructed over the Severn, near an
-appropriately named place, Ironbridge, in 1779. It had an arch of near
-upon a hundred feet span.
-
-When, however, very wide span bridges were required, the question
-arose of the superiority of wrought-iron over cast-iron for such
-structures. The Menai Strait had to be crossed for the Chester and
-Holyhead Railway, and the greatest existing cast-iron span was Rennie’s
-Southwark Bridge, where 240 feet had been reached. But over the Conway
-and the Menai Strait, spans of 400 feet were involved. How were these
-yawning gulfs to be bridged?
-
-
-
-
-CHAPTER II.
-
-A NEW IDEA—THE BRITANNIA TUBULAR.
-
-
-“We must cross the Strait at the Britannia Rock—that is settled.”
-
-“And where is the Britannia Rock?”
-
-“Nearly in mid-channel. It seems placed there for the purpose.”
-
-And the great engineer smiled.
-
-“What are the distances?”
-
-“From coast to coast the span of the Strait is some 1100 feet, with
-that rock in the centre. Now the problem is, to build a bridge across
-that gulf of surging water strong enough to bear heavy trains at high
-speeds, and sufficiently above the water to prevent any interference
-with navigation.”
-
-“And how will you manage it?”
-
-“First I thought of large cast-iron arches, but they will not do. I
-doubt if they would stand the strain; and moreover we should impede
-navigation by raising scaffolding during the building. At length I came
-to the idea of a tube bridge.”
-
-“What! a tube bridge! I’ve never heard of it!”
-
-“No, it is a new idea. By reconsidering a design I had made for a small
-bridge over the Lea at Ware in 1841, and thinking over the matter, I
-came to the idea that a bridge consisting of a hollow beam or tube
-might solve the difficulty.”
-
-“A huge hollow girder, so to speak!” exclaimed his friend.
-
-“Exactly so. Accordingly,” the engineer continued, “I had drawings
-prepared and calculations made, by which to ascertain the strength
-of such a bridge, and they were so satisfactory that I decided on
-attempting one.”
-
-“It is like constructing one huge hollow beam of iron by rivetting
-plates together. Can it be done?” remarked his friend.
-
-“The making of the high-level bridge over the Tyne, in which I had
-a part—the bridge between Newcastle and Gateshead, you know—was a
-transition between an arched bridge and a girder bridge. A girder of
-course is a beam, it may be of iron or wood, and the little bridge at
-Ware has been built of girders made of plates of wrought-iron rivetted
-together. Therefore, you see, I am not unused to wrought-iron girders,
-and what they will bear.”
-
-“Why, it is like a huge extension of the primitive log-bridge of our
-ancestors.”
-
-“If you like,” replied the engineer, laughing.
-
-Robert Stephenson—for he it is whom we suppose to be speaking to his
-friend on this gigantic engineering enterprise—became satisfied by
-reflection that the principles involved in constructing an immense
-tubular beam were but a development of those commonly in use; and Sir
-William Fairbairn was entrusted with the duty of experimenting as to
-the strength of tubes, the directors of the Railway Company voting a
-sum of money for the purpose.
-
-Sir William, then Mr., Fairbairn concluded that rectangular tubes were
-the strongest, and a model was made of the suggested bridge. It proved
-successful, and indicated that the tube would be able to stand the
-strain of a heavy train passing rapidly over it.
-
-In September, 1846, Mr. Fairbairn read a paper on the subject at
-the meeting of the British Association at Southampton, as also did
-Professor Hodgkinson, a mathematician, who had verified Fairbairn’s
-experiments. Not long afterwards Stephenson became satisfied that
-chains were not needed to assist in supporting the bridge, and that his
-tubes would be strong enough to support themselves entirely between the
-piers.
-
-Work therefore went forward. Some 1500 men were engaged on the
-Britannia Bridge, and the quiet shores of the Menai Straits resounded
-with the busy hum of hammers and machinery. Cottages of wood were built
-for the men, and workshops for the punching and rivetting of the plates
-for the gigantic tubes.
-
-The design included two abutments of masonry on either side of the
-Strait, and three towers or huge piers, one of which, the centre pier,
-was to rise from the Britannia Rock, 230 feet high. There are four
-spans, two over the water of 460 feet each, and two of 230 feet each
-over the land. Two tubes, quite independent of each other, but lying
-side by side, form the bridge across. Each tube or beam is 1510 feet
-long, and weighs 4680 tons. Its weight at one of the long spans is
-1587 tons.
-
-Now how could these gigantic tubes be put together and raised to their
-positions? Here was a problem almost as great as the original one of
-the bridge itself, and it troubled the engineer sorely.
-
-[Illustration: ROBERT STEPHENSON.]
-
-“Often at night,” he declared, “I would lie tossing about, seeking
-sleep in vain. The tubes filled my head. I went to bed with them, and
-got up with them. In the gray of the morning, when I looked across
-Gloucester Square, it seemed an immense distance across to the houses
-on the opposite side. It was nearly the same length as the span of my
-tubular bridge.”
-
-The principle adopted was to construct the shorter tubes on scaffolds
-in the places which they were to occupy. This could be done, for such
-scaffolding would not impede navigation. But scaffolding could not be
-built for the large tubes across the great spans of water. What then
-was to be done?
-
-It was decided to build them on platforms on the shore quite close
-to the water, and float them when ready on pontoons to their places
-between the piers, raising them to their position by hydraulic power.
-Such a task would be hazardous enough. It was first tried at Conway,
-where a similar bridge was being built by Robert Stephenson, being
-indeed part of the same railway. The Britannia was, however, a much
-greater enterprise, though the span of the Conway is 400 feet. The
-Conway bridge, indeed, is but of one span, and contains two tubes.
-
-The experience at Conway was of great benefit to the gigantic
-undertaking at the Menai Strait. The floating of the first tube was to
-take place on the 19th of June, 1849, in the evening; but owing to some
-of the machinery having given way, the great event was put off to the
-next night. The shores were crowded with spectators. When the tube was
-finished it could be transferred to the pontoons; for the tubes had
-been built at high-water mark. When the pontoons were fairly afloat on
-this fateful evening, they were held and guided by leading strings of
-mighty strength. Stephenson himself directed in person, from a point
-of vantage at the roof of the tube. Thence he gave the signals which
-had been agreed upon, whilst a crew of sailors, directed by Captain
-Claxton, manned the strange barque.
-
-A pontoon is a light, buoyant boat, and the tube was supported on sets
-of these, their speed increasing terribly as they approached their
-place by the towers. The idea was, as related by Mr. Edwin Clark,
-Stephenson’s assistant, that they should strike a “butt” properly,
-underneath the Anglesey Tower, “on which, as upon a centre, the tube
-was to be veered round into its position across the opening. This
-position was determined by a twelve-inch line, which was to be paid
-out to a fixed mark from the Llanfair capstan. The coils of the rope
-unfortunately over-rode each other upon this capstan, so that it could
-not be paid out.”
-
-Destruction seemed imminent. The capstan was actually dragged from the
-platform, and the tube seemed likely to be swept away. Then Mr. Rolfe,
-the captain of the capstan, shouted to the spectators, and threw out a
-spare twelve-inch rope. Seizing this, the crowd, with right good-will,
-rushed it up the field, and clung tightly to it, checking the voyage of
-the mighty tube. It was brought to the “butt,” and duly turned round.
-
-A recess had been left in the masonry of the tower, and the end near
-the Britannia pier was drawn into it by means of a chain. The Anglesey
-end followed. Then the tide gradually sank, the pontoons sank with it,
-and the tube subsided also to a shelf which had been made at either
-end. The first stage was accomplished; the mighty tube was in position
-to be raised.
-
-Shouts of rejoicing burst from the sympathetic crowds, and the boom of
-cannon joined its congratulatory note at the grand success. But the
-further stages remained. At midnight the pontoons were all cleared
-away, and the huge, hollow beam hung silent over the surging water.
-It rested on the shelves or beds prepared for it at either end. The
-second great operation, of course, was to haul it up the towers to its
-permanent position. This was to be performed by hydraulic machinery of
-great power, and Mr. Stephenson’s instructions were to raise it a short
-distance at a time, and then build under it.
-
-He took every imaginable precaution against accident or failure; and
-well was it that he did so, for an accident happened which, but for the
-careful building under the tube in the towers as it was raised, would
-have been most calamitous. The accident occurred while Mr. Stephenson
-was absent in London. One day, suddenly, while the machinery was at
-work raising the tube, the bottom burst from one of the hydraulic
-presses, and down fell the tube on to the bed provided for it.
-
-Though the fall was but nine inches, tons weight of metal castings were
-crushed, and the mighty tube itself was strained and slightly bent. But
-it was serviceable still, and the fact that it stood the strain so well
-showed its great strength. It weighed some five thousand tons, and for
-such an immense weight to fall even three-quarters of a foot was a very
-severe test.
-
-But for Stephenson’s wise precaution in lifting it slowly, and building
-underneath it as it was raised, the tube would have crashed to the
-bottom of the water. As it was, the accident cost £5000; but the tube
-was soon being hauled upward again. In due course the others followed,
-and on the 5th of March, 1850, Robert Stephenson inserted the final
-rivet in the last tube, and the bridge was complete. He crossed over
-with about a thousand persons, three locomotives whirling them along.
-
-The tubes of the bridge are made of iron plates, and at the top and
-bottom are a number of small cells or tubes—instead of thick iron
-plating—which assist in giving strength to the whole gigantic tube.
-Thus it may be said the floor and roof are tubular, as well as the
-body. These hollow cells appear to have been Fairbairn’s invention. The
-size of the tube grows slightly larger at the middle by the Britannia
-tower, where externally the tubes are 30 feet high, and 26 internally,
-while they are 22¾ feet and 18¾ feet at the abutments. The width is 14
-feet, 8 inches externally, and 13 feet 5 inches inside.
-
-At the Britannia tower the tubes are placed solidly on their bed,
-but at the abutments, and at the land towers, the tubes rest on
-roller-beds. This arrangement was adopted to permit of expansion and
-contraction. Iron, of course, solid and unyielding as it appears, is
-yet very susceptible to warmth, and the effect of the sun’s rays on
-this massive iron structure is very marked. A rise of temperature
-causes it to expand in a comparatively short time, and it is said that
-the tubes occasionally move two and a-half inches as the sun gleams
-upon them. Mr. Edwin Clark observed the effect of the sun on the iron,
-which appears in a small degree to be always moving as the temperature
-varies. Well, therefore, that the able engineer planned an arrangement
-allowing for this constant expansion and contraction of the iron mass.
-
-[Illustration: THE BRITANNIA TUBULAR BRIDGE.]
-
-The Britannia Bridge was a great triumph for Robert Stephenson. He
-appears first to have seized the idea, and, assisted no doubt by
-Fairbairn’s experiments and by able coadjutors, he carried it through
-to a successful completion. He was of course the son of George
-Stephenson, who had done so much for the locomotive, and according to
-Smiles, “he almost worshipped his father’s memory, and was ever ready
-to attribute to him the chief merit of his own achievements as an
-engineer.”
-
-“It was his thorough training,” Mr. Smiles once heard him remark, “his
-example, and his character, which made me the man I am.” Further, in an
-address as President of the Institution of Civil Engineers, in January,
-1856, he said: “All I know, and all I have done is primarily due to the
-parent whose memory I cherish and revere.”
-
-That father had died before the Britannia Bridge was completed, though
-he had been present at the floating of the first tube at Conway. The
-great engineer passed away on the 12th of August, 1848, at the age of
-sixty-seven, and his distinguished son Robert, who had no children,
-only survived him by eleven years.
-
-But before he died he had designed, and Mr. A. M. Ross, who had
-assisted at the Conway Bridge, had assisted in carrying out the
-celebrated Victoria Tubular Bridge over the great St. Lawrence River at
-Montreal.
-
-This bridge was for the Grand Trunk Railway of Canada, and for immense
-length and vastness of proportions, combined with magnificent strength,
-is one of the wonders of the world. It is five times as long as the
-Britannia Bridge, being not far short of two miles. It has a big
-central span of 330 feet, and twenty-four spans of 242 feet. The iron
-tubes are suspended sixty feet above the water beneath.
-
-[Illustration: VICTORIA TUBULAR BRIDGE, MONTREAL.]
-
-One great difficulty in the problem was the ice. Immense quantities
-come down in the spring, and to resist this enormous pressure the piers
-are most massive, containing thousands of tons each of solid masonry.
-These piers are based on the solid rock, the two central towers being
-eighteen feet in width and the others fifteen feet. To protect them
-from the ice, huge guards made of stone blocks clamped with rivets
-built up in the form of an incline were placed before the piers on the
-up-stream side. The bridge was begun in July, 1854, and occupied four
-and a-half years in construction, it being completed in December,
-1859, about two months after its designer had died.
-
-Gigantic though this structure is, and great as is the honour which it
-reflects on Robert Stephenson and the resident and joint engineer Mr.
-Ross, yet with the exception of the remarkable and massive ice-guards
-to the piers, it does not differ materially from the Britannia and
-Conway Tubular Bridges. These were the first famous examples of the new
-principle.
-
-Why, then, are massive tubular bridges not more generally built?
-Because they led to another and very natural development in
-bridge-building, a development whereby great strength for long spans is
-gained, with, however, a marked saving both in labour and in material.
-That development was the lattice bridge.
-
-
-
-
-CHAPTER III.
-
-LATTICE AND SUSPENSION BRIDGES.
-
-
-“The expense of a tubular bridge would be too great.”
-
-“But if we could get the strength without the expense.”
-
-“What mean you?”
-
-“By iron lattice work we could, I think, gain the stiffness and support
-needed, without such great cost of labour and material. In other words,
-I propose a lattice or trellis work girder, instead of a solid sided,
-or a tubular girder.”
-
-“That is, you would have the sides of lattice or trellis work, instead
-of solid plates?”
-
-“Exactly. I would use bars of iron placed diagonally. These lattice or
-trellis bridges are developed from the tubular bridges, also from the
-loose wooden lattice bridges of America. We make a web of iron instead
-of a solid sheet. The same kind of structures are largely used over the
-wide rivers of India. Sir John MacNeill designed the first in iron, and
-it was built in 1843 on the Dublin and Drogheda Railway with a span
-of eighty-four feet. I consider they will be among the most popular
-bridges of the future for longish spans.”
-
-The engineer’s prediction has come true; for lattice bridges have
-undoubtedly been very widely adopted. We may suppose that he was
-advising the directors of a proposed railway, and we doubt not but that
-he carried the day.
-
-A fine specimen of a lattice bridge is that across the Thames near
-Charing Cross, for the South-Eastern Railway. It has a total length
-of more than a quarter of a mile—viz., 1365 feet, and six of its nine
-spans are 154 feet wide. Two principal girders, fourteen feet deep,
-are connected transversely by other girders which carry the rails and
-project on the other side to support a footpath. The two main girders
-are nearly fifty feet apart and one weighs 190 tons.
-
-The sides have upper and lower booms made of plate iron connected by
-perpendicular bars, between which are a couple of bars crossing each
-other diagonally at an angle of forty-five degrees, and fixed to the
-booms by bolts of five and seven inches in diameter.
-
-The old Hungerford Bridge stood here previously, and its two piers of
-brickwork were used for the new bridge. Other piers are huge cylinders
-of cast iron ten feet across, but fourteen feet in diameter in the
-ground. Thus they are broadly based. These piers are filled with
-concrete and also brickwork, and are topped with bearing-blocks of
-granite. They are formed of plates of cast iron bolted together, and
-they were sunk into the ground many feet below high-water by combined
-forces; divers scooped out the mud and gravel and clay from within the
-cylinders; water was pumped out and heavy weights pressed them down.
-The piers became fixed on the London clay, but when filled were heavily
-weighted to drive them down again, and finally they were forced to a
-depth of over sixty-two feet below high-water mark.
-
-But before lattice girder bridges had become so popular, another class
-had come into use, and afford some splendid specimens of engineering
-skill. These are suspension bridges, and, perhaps of all kinds, they
-are the most picturesque. Their graceful sweeps and curves yield
-perhaps a more pleasing sight for the eye than the solid, rigid,
-straight lines of the girder bridges.
-
-It was the genius of Thomas Telford which gave a great impetus to
-this class of bridge. Like Stephenson after him, he had to bridge the
-surging Menai Straits, but for a carriage road, not a line of rails;
-and at length, after various plans had been suggested and abandoned, he
-proposed the Suspension Bridge.
-
-Now, in its simplest form, a suspension bridge has been known for ages.
-It is merely a pathway, or even a small movable car, suspended from a
-rope or ropes across a chasm. Ulloa describes suspension bridges built
-by the Peruvians in South America. Four stout cables span a river, and
-on these four is placed the platform of sticks and branches, while two
-other ropes connected with the platform are useful as hand rails. Such
-bridges sway with the wind and move with the passenger, but for light
-loads they appear to be perfectly safe.
-
-In Telford’s Menai Bridge the carriage-way is hung from four huge
-chains or cables, each chain made up of four others, and passing over
-high piers. The chains are anchored on the landward side, sixty feet
-in pits, and grafted by iron frames to the rocks. The chains are so
-complex and so strong, that parts may be removed for repair without
-imperilling the safety of the structure. The length of the span thus
-gained is 560 feet, and it is 150 feet above high-water. The remainder
-of the bridge is composed of arches of stone, of 52½ feet span.
-
-The piers from which the great span is suspended rise above the
-carriage-way fifty-two feet, and are topped by blocks of cast-iron,
-which can move on rollers to permit the chains passing over them
-to expand and contract freely with the temperature. There are two
-carriage-roads, and also a footpath. The roads are separated by iron
-lattice work, which also gives them stability and decreases vibration.
-
-[Illustration: THE CLIFTON BRIDGE.]
-
-In its day, this stupendous bridge was as great a wonder as its later
-companion over the same Straits—the Britannia Tubular. Six years were
-occupied in building, and it was opened in 1825. Why, then, did not
-Stephenson construct a similar bridge when, twenty years or so later,
-he had to solve a similar problem?
-
-The answer is, that suspension bridges are not—or were not—considered
-sufficiently strong and rigid for railway work. In America, however,
-they have been used for this purpose; witness the famous Niagara
-Suspension Bridge, 2⅓ miles below the Falls, and with a superb span
-of 822 feet; but American engineers appear to stiffen the roadway
-considerably, so as to distribute the stress of the rushing train over
-a large portion of the cable. The Niagara Bridge is not supported by
-plate-link chains, but by four immense wire cables, stretching from
-cliff to cliff over the roaring rapids. Four thousand distinct wires
-make up each cable, which pass over lofty piers, and from them hangs
-the railway by numerous rods.
-
-[Illustration: THE BROOKLYN BRIDGE.]
-
-Probably the famous Brooklyn Bridge is the largest suspension bridge in
-the world, even as the Clifton Suspension Bridge, in England, is one
-of the most interesting. The Brooklyn Bridge has a magnificent central
-span of 1595½ feet over the East River between Brooklyn and New York;
-further, there are two land spans of 930 feet, which, together with the
-approaches, make up a total of about a mile and a furlong. The cables,
-four in number, are each composed of 5000 steel wires, and measure
-15¾ inches in diameter. They are anchored to solid stone structures
-at either end, measuring 119 feet by 132 feet, and weighing 60,000
-tons; while the towers from which the main span is suspended rise to
-the height of 276 feet, and are embedded in the ground 80 feet below
-high-water. It has been estimated that the weight hung between these
-towers is nearly 7000 tons.
-
-The roadway of the bridge is divided into five thoroughfares. Those on
-the outer sides are for vehicles, and are 19 feet wide; the centre is
-for foot passengers, and is 15½ feet in width; while the two others are
-for tramway traffic. The bridge was opened in 1883, and affords a great
-triumph of engineering skill.
-
-Much smaller, but none the less interesting, is the Suspension Bridge
-at Clifton. As far back as 1753, Alderman William Vick, of Bristol,
-left a sum of £1000 to build a bridge at Clifton. The sum was to lie
-at compound interest until £10,000 was reached. However, the money
-was increased by subscriptions, and in 1830 an Act of Parliament was
-obtained for its construction.
-
-The work coming into the hands of Mr. I. K. Brunel, he designed a
-bridge of 702 feet span, and 250 feet above high-water. The piers and
-abutments were built, but lack of cash, which forms an obstacle to so
-many brilliant enterprises, stopped the progress of the bridge for
-nearly fourteen years.
-
-Then it occurred that the Hungerford Suspension Bridge was to be
-removed to make way for the Charing Cross Railway Bridge, so the chains
-were purchased at a comparatively small cost, and the work at Clifton
-proceeded, and was finally completed.
-
-Three chains on either side suspend long wrought-iron girders, which
-help to stiffen the platform; and cross girders between support the
-floor. The chains pass over rollers on the piers, and are ultimately
-anchored to plates bedded in brickwork abutting on rock. The platform
-is hung by upright rods from the chains, and hand-railing is used with
-lattice-work, to assist in rendering it rigid. The roadway, twenty
-feet wide, is made of creosoted wood, five inches thick, while the
-pathways on either side are made with wood half as thick. Between the
-piers the weight of the structure, including the chains, amounts to
-nearly a thousand tons.
-
-In all these suspension bridges, however large, the principles are much
-the same. The platform, or roadway, is hung from chains or cables,
-which pass over piers and are anchored fast at the ends. Some are
-stiffened with girders and bracing to prevent undue undulation. The
-chains take a graceful and definite curve, that of the Menai Bridge
-dipping fifty-seven feet. The strain is the greatest at the lower part,
-and is increased, should the chain be drawn flatter over the same
-space. These bridges became widely adopted.
-
-But there came a time when none of the bridges in vogue seemed to give
-what was required. A new principle was wanted. Where was it to be found?
-
-
-
-
-CHAPTER IV.
-
-THE GREATEST BRIDGE IN THE WORLD.
-
-
-“Have you heard the news? The Tay Bridge is blown down!”
-
-“Yes. A terrible disaster. I should think they would give up their
-scheme of bridging the Firth of Forth after that.”
-
-“Not they! The scheme may be altered, but bridge it they will.
-Engineers never give in.”
-
-The comments of these newspaper readers were right. The Tay Bridge,
-the longest in the world, had been blown down one wild December night
-in 1879, and girders, towers, and the train which was rushing over it,
-were suddenly hurled into the surging flood.
-
-At that time a scheme was in hand to bridge the Forth for the North
-British Railway system, and Sir Thomas Bouch had proposed two
-suspension bridges hung by steel chains. But ultimately a new design
-altogether was adopted, the plan being by Sir Benjamin Baker and Sir
-John Fowler.
-
-It was the new principle—or, rather, a remarkable development of an old
-principle—for which the bridge-making world was waiting: the principle,
-namely, of the cantilever.
-
-A cantilever is, in fact, a bracket; and Sir Benjamin Baker has
-described it as such. It is a strong support, built out from a firm
-base, and is like a powerful and magnified bracket upholding a shelf.
-
-In the Forth Bridge there are two huge spans, 1700 feet wide, crossed
-by these cantilevers; bridging channels of some 200 feet deep.
-
-The longest spans on the Tay Bridge were 245 feet; it was over two
-miles long, and had ninety spans. It was an iron girder bridge, and was
-opened on the 31st of May, 1878. Not to be beaten, however, after the
-panic had subsided, another and more stable bridge was constructed,
-also a girder, but not so high in elevation, and sixty feet further
-up the river. It was opened in 1887, and is 10,779 feet long, with 85
-piers, the navigable channel being under four of the spans, the centre
-spans being 245 feet wide.
-
-It will be seen at once that the cantilevers at the Forth Bridge cover
-very much wider spans; and the channel being so deep, the impossibility
-of building piers will also be obvious. The best place for the bridge
-was marked by the projection of the Inverkeithing peninsula on the
-north shore, and also the Inchgarvie rock in the channel itself. The
-peninsula brought the two shores together, reducing the space to be
-bridged, and the rock gave firm support for a pier. Still there were
-the two immense spans of 1700 feet to be crossed, and the engineers
-decided on the cantilever principle. Thus, though the Tay Bridge was
-the longest in the world, the Forth presented by far the greatest
-spans—viz., the two main spans of 1700 feet each, in addition to which
-there are two of 675 feet each, and fifteen of 168 feet each.
-
-The total length of this magnificent bridge, which Sir Benjamin Baker
-rightly claimed was the most wonderful in the world, is somewhat over
-1½ miles in length, or 8296 feet, including the piers, while almost a
-mile is bridged by the huge and superb cantilevers. This is, perhaps,
-the great marvel. The clear space under the centre is no less than 152
-feet at high-water, while the highest portion is 361 feet above the
-same mark.
-
-And now, how was this great bridge constructed? Workshops were erected
-at South Queensferry, and the mammoth cantilevers were put up there
-piece by piece. They were fitted together and then taken plate by plate
-to the bridge itself. The shops were lit by electricity, and furnished
-with appliances for bending, cutting, moulding, holing, and planing
-plates. The workshops were surrounded by quite a maze of railways.
-
-But what of the piers, without which all these preparations would be
-unavailing? Now the foundations of piers are usually laid by means of
-cofferdams; that is, piles of timber are driven down through the water
-into the bed of the river close together, and the interstices filled
-with clay; or a casing of iron may be used instead. The water in the
-enclosure thus formed can be pumped out and excavation proceeded with,
-and the foundations laid. Cofferdams are sometimes made of iron boxes
-or caissons with interstices fitted with felt, and caissons of this
-kind about 12½ feet long and 7 feet wide were used in constructing the
-Victoria Embankment on the Thames.
-
-But with certain of the piers for the Forth Bridge the water was
-too deep for timber cofferdams, and the usual diving-bell was not
-sufficiently large. The piers were to be of immense size, no less than
-55 feet in diameter, and the diving-bell of ordinary size would not
-cover that great width.
-
-Huge caissons were therefore made, 70 feet wide, constructed of iron
-plates and rising in height, according to the depth of water, up to 150
-feet. The lower part of the immense caisson or tank was fitted as a
-water-tight division and filled with compressed air, the object being
-to resist the pressure of the water. Two shafts communicated with this
-air-tight division or mining chamber, one for the removal of the earth
-excavated, and the other for the men to pass up and down. The escape
-of the air through the shafts was prevented by the use of an air-lock,
-working on the same principle as a water-lock on rivers or canals.
-There were two doors in the lock, one communicating with the shaft and
-the other with the outside air. When the latter was closed and the lock
-filled with compressed air by opening a valve or tap, the door of the
-shaft could be opened and the man could descend to his work below.
-
-That work consisted chiefly of excavation in the bed of the river.
-Drills, hydraulic cutters, and dynamite blasting were all utilised
-until huge holes, many feet below the river bed, were hollowed out. As
-the caisson was filled with concrete above the air-tight chamber where
-the men worked it was exceedingly heavy, and sank by its own weight
-into the space prepared.
-
-The mining chamber was lit by electricity, and was about seven feet
-high. The mud of the river bed was mixed with water and blown away by
-the compressed air which seems to have been about 33 lbs. to the square
-inch. The caissons were sunk down to rock or boulder clay, and when
-they had reached the required distance the mining chamber was filled
-with concrete, and the same material used to the level of the water;
-the piers were then built up with huge stones placed in cement, the
-whole forming a magnificent mass of concrete and masonry, carried down
-in some cases to about 40 feet below the bed of the river.
-
-[Illustration: THE FORTH BRIDGE.]
-
-The three chief piers consist of groups of four columns of masonry,
-each gradually tapering from 55 feet in diameter to 49 feet at the top,
-and about 36 feet high. From these rise the huge cantilevers connected
-together by girders 350 feet in length.
-
-The centre of these three main piers rests on the island of Inchgarvie;
-the two others are known as the Fife and the Queensferry piers
-respectively, and are placed on the side of the deep water channels. In
-addition to these three main piers are several others, some in shallow
-water and some on land. The part of the bridge which they carry is
-an ordinary girder of steel leading to the immense cantilevers. For
-founding the shallow water piers, cofferdams were used; the caissons
-with compressed air chambers being for the deep water structures.
-
-They were put together on shore, launched, floated, steered to the
-desired position, and sunk. One proved cranky and turned over, and was
-only brought right after much expense and difficulty.
-
-The cantilevers are bolted down to each pier by numbers of huge steel
-ties, 24 feet in length and 2½ inches in diameter, embedded in the
-masonry, there being 48 of these bolts or ties to each column. And now
-as to these cantilevers.
-
-Four huge tubular shafts, two on each side, rise from the group of
-columns forming each pier, to the height of 350 feet. From these
-shafts, which slope slightly inward, project the cantilevers, the upper
-and lower parts being strongly braced together by diagonal ties. In
-shape the gigantic brackets taper towards a point, the width decreasing
-as much as from 120 feet at the commencement of the piers to 32 feet at
-the ends. The wind, it is believed, will be more effectually resisted
-by this means.
-
-The cantilevers are hung back to back, one to some extent
-counter-weighing the other. The component parts consist of cylinders
-of steel or struts for resisting compression—these are the lower
-parts; and ties of lattice-work made of steel plates for resisting
-tension,—placed above.
-
-Thus, then, from each of the three chief piers two pairs of gigantic
-brackets project, each pair placed side by side and braced together,
-and forming one composite cantilever jutting to the north and one to
-the south. The rails run on sleepers placed lengthwise and fixed in
-troughs of steel, so that should a train run off the line the wheels
-will be caught by these supports.
-
-It is calculated that there are about 45,000 tons of steel in the
-bridge, and 120,000 cubic yards of masonry in the piers. The contract
-price was £1,600,000, which works out at about £215 per foot; and the
-contractors, who were able to obtain an admirable organisation of some
-2000 men to carry out the magnificent design, were Messrs. Tancred,
-Arrol, & Co. Some special tools for use in the work were planned by Sir
-William Arrol. The bridge was opened by the Prince of Wales on the 4th
-of March, 1890.
-
-The success of this magnificent structure has assured the wider
-adoption of the cantilever principle. Long-span bridges, in several
-cases, have since been built on this design. Its engineers may claim
-indeed to have widened the scope and possibilities of bridge-building.
-
-Still, when another bridge was wanted over the Thames, at a busy spot,
-crowded with shipping and near the historic Tower of London, another
-kind of structure was adopted. What was it?
-
-
-
-
-CHAPTER V.
-
-THE TOWER BRIDGE.
-
-
-“Why should they not have a drawbridge?”
-
-“What! To draw up from each bank of the river?”
-
-“No, I did not mean that exactly. Could they not get piers farther in
-towards the centre of the stream, and let the drawbridge rise and fall
-from them?”
-
-“The river is too crowded for many piers.”
-
-“It is. But I cannot help thinking a drawbridge—a bascule bridge as the
-engineers call it—is the best solution of the difficulty.”
-
-“Well, a bridge is wanted sufficiently low to spring from the flat
-banks of the Thames for foot passengers and carriage traffic, and yet
-sufficiently high to permit tall ships to pass underneath.”
-
-“And apparently these two requirements are incompatible.”
-
-“Not altogether,” remarks a third speaker.
-
-“You are partly right in your idea of a drawbridge. That is Sir Horace
-Jones’s idea. And, further, there is literally to be a high and also
-a low-level bridge; for there are to be two levels—that is, two
-roadways—one at a high, and one at a low, level across the middle span.”
-
-“And is the low level to be a drawbridge—a roadway that can be drawn up
-to permit vessels to pass? Is that so?”
-
-“Exactly. And this drawbridge will be in two parts, one on either side;
-they will be worked from two massive piers giving a clear span of 200
-feet in the middle of the stream, through which span big vessels can
-pass. The usual traffic of the river will be able to pass even when the
-drawbridges are down.”
-
-“And above the bascules or drawbridges will run the high-level bridge?”
-
-“Yes, a girder bridge for footpaths, and people will reach it by lifts
-and staircases in the piers—which, by-the-by, will be more like huge
-towers. These towers will also contain the machinery for raising and
-lowering the drawbridges.”
-
-“And what sort of bridge will be used for the other spans—that is, to
-cross the river between the piers and the shore?”
-
-“Suspension bridges; so that the Tower Bridge as it will be called,
-for it will cross the Thames by the Tower of London, will embody
-the suspension, the bascule (or drawbridge), and the girder bridge
-principles, while in the centre will be two levels.”
-
-“It promises to be a splendid piece of work.”
-
-“It does. And it is very much needed, for the congestion of traffic on
-London Bridge is terrible.”
-
-“And people have often to come round a long way to reach it.”
-
-The promise of the Tower Bridge, as set forth by these speakers, has
-been amply fulfilled. It is indeed a fine piece of work; and although
-it does not embody any new idea, yet in its combination and development
-of old principles and in its size it is very remarkable. It was opened
-in June, 1894, and is, or was at the time of building, the biggest
-bascule bridge in the world.
-
-Within its handsome Gothic towers are steel columns of immense
-strength, constituting the chief supports of the suspension bridges
-and of the high-level footways. The architect was the late Sir Horace
-Jones, and the engineer Mr. J. Wolfe Barry, while the cost was,
-including land, about £1,170,000.
-
-The problem was to combine a low-level bridge providing for ordinary
-town traffic with a high level, under which ships could pass, and it
-was accomplished by a union of principles. In its oldest shape the
-drawbridge was probably a huge piece of timber, which was hauled up
-and let down by chains over the moats of castles. In the Tower Bridge
-there are two of such huge “flaps” or leaves, each about 100 feet long,
-one rising and falling from each pier and meeting in the centre. Large
-bascule bridges are usually constructed in this manner, and there is an
-excellent specimen over the Ouse, for the passage of the North-Eastern
-railway; one man at each half of the bridge can raise it in less than
-two minutes. Another fine bascule may be seen at Copenhagen.
-
-The bascules are raised and lowered by chains, which, in the case of
-the Tower Bridge, are worked by superb hydraulic power from the massive
-pier towers. When drawn up, which is done in less than five minutes,
-the bascules are even with the sides of the towers, and full space is
-given for the vessels to pass.
-
-The two side spans of the bridge, crossed by the suspension bridges,
-are wider than the centre, being 270 feet each, and the total length
-of the whole bridge is 800 feet between the abutments. There are also
-piers on the shoreward side for carrying the chains of the suspension
-bridges at each extremity.
-
-The massive tower piers, sunk 27 feet below the river bed, are built of
-gray granite, and are also fitted with strong break-waters to resist
-the action of the tide. The high-level bridges across the central
-span are for foot passengers, and are 135 feet over high-water mark.
-The bascule bridges, when closed for vehicular traffic, are 29½ feet
-above high water, while the side suspension spans are 27 feet. The
-roadway is 50 feet wide, which is also the width of the approaches. The
-foot passenger traffic is never stopped, as persons can pass by the
-hydraulic lifts or the stairways in the tower piers to the high-level
-bridges above.
-
-Sir Horace Jones died before the great work was completed, and was
-succeeded by Mr. G. D. Stevenson, who had been his assistant. Sir
-William Arrol & Co. supplied the iron and steel, and Sir William
-Armstrong the hydraulic machinery. Various contractors carried out
-different portions of the mighty work, which occupied about eight
-years in building. Near by stands the ancient Tower of London, looking
-not unkindly on the great constructive effort to which it has given its
-name.
-
-Sometimes a bridge is made movable by swinging it round on a pivot
-instead of drawing it up on a hinge or axis; and sometimes, as in
-the case of a bridge over the Arun for the Brighton and South Coast
-Railway, it is made to slide on wheels backwards and forwards from
-the abutment. Floating or pontoon bridges are made by placing planks
-on pontoons, or boats anchored by cables. The longest in the world is
-probably at Calcutta, across the Hooghly. It is 1530 feet in length,
-there being twenty-eight pontoons in pairs. These are of iron, 160 feet
-long, and with ends shaped like wedges; they support a road-way of
-3-inch timbers, forty-eight feet wide, and raised on tressel work. An
-opening can be made for ships by removing four pontoons and floating
-them clear of the passage way.
-
-Great bridges present some of the most remarkable triumphs of the
-engineer. They rank beside the express locomotive and the ocean liner
-as among the great constructive achievements of mankind. Daring in
-design, and bold in execution and in sweep of span, they have been
-developed along several principles; and so solidly have they been
-built, so sound are the laws of their being, that it seems as though
-they will live as long as the everlasting hills.
-
-[Illustration]
-
-
-
-
-[Illustration]
-
-
-REMARKABLE TUNNELS AND THEIR CONSTRUCTION.
-
-
-
-
-CHAPTER I.
-
-HOW BRUNEL MADE A BORING-SHIELD.
-
-
-“I watched the worm at work and took my idea from that tiny creature!”
-
-“A worm! Was it an ordinary worm?”
-
-“Oh no, it was the naval wood-worm—_Teredo Navalis_; it can bore its
-way through the hardest timber. I was in a dockyard and I saw the
-movements of this animal as it cut its way through the wood, and the
-idea struck me that I could produce some machine of the kind for
-successful tunnelling.”
-
-“Well, it has been brilliantly successful.”
-
-“I looked at the animal closely, and found that it was covered with
-a couple of valvular shells in front; these shells seem to act as a
-shield, and after many attempts I elaborated the boring-shield which
-was used in hollowing out the Thames Tunnel.”
-
-This statement, which we can imagine to have been made by Sir Marc
-Isambard Brunel to a friend, is no doubt in substance quite true. A
-writer in the “Edinburgh Encyclopædia” says, that Sir M. I. Brunel
-informed him, “that the idea upon which his new plan of tunnelling is
-founded, was suggested to him by the operations of the _Teredo_, a
-testaceous worm, covered with a cylindrical shell, which eats its way
-through the hardest wood.”
-
-Two or three attempts had already been made to drive a tunnel under the
-Thames, but they had ended in failure. In 1823, Brunel came forward
-with another proposal, and he ultimately succeeded.
-
-This illustrious engineer must not be confounded with his son—who was
-also a celebrated engineer—Isambard Kingdom Brunel. There were two
-Brunels, father and son, even as there were two Stephensons, George and
-Robert.
-
-Sir Marc Isambard Brunel, the father, whose most notable enterprise
-was the Thames Tunnel, was a French farmer’s son, and after various
-experiences in France and America settled in England in 1799, and
-married the daughter of William Kingdom of Plymouth. He had already
-succeeded as an engineer so well as to be appointed chief engineer of
-New York, and a scheme for manufacturing block-pulleys by machinery for
-vessels was accepted by the British Government, who paid him £17,000
-for the invention. He was also engaged in the construction of Woolwich
-Arsenal and Chatham Dockyard, etc., and in 1823 he came forward with
-another proposal for the Thames Tunnel.
-
-In that same year, his son, Isambard Kingdom Brunel, entered his
-father’s office, and assisted in the construction of the tunnel. The
-son subsequently became engineer to the Great Western Railway, and
-designed the _Great Western_ steamship.
-
-But though Brunel’s proposal for the tunnel was made public in 1823,
-the work was not actually commenced until March, 1825. It was to cross
-under the river from Wapping to Rotherhithe, and present two archways.
-And if you had been down by the Rotherhithe bank of the Thames about
-the latter date, you would have been surprised to see that instead of
-hollowing out a shaft, proceedings began by raising a round tower.
-
-A space was traced out, some 50 feet across, and bricklayers began to
-build a circular hollow tower about 3 feet thick and 42 feet high.
-
-This tower was strengthened by iron bars, etc., and then the excavation
-commenced within. The soil was dug out and raised by an engine at the
-top, which also pumped out water. And as the hollow proceeded, the
-great shaft or tube of masonry sank gradually into it. Bricklayers
-added to its summit until it reached a total height of 65 feet, which
-in due course was sunk into the ground.
-
-Thus, then, the engineer had, to commence with, a strong and reliable
-brickwork shaft, 3 feet thick, by which men and materials could ascend
-and descend in safety. A smaller shaft was also sunk deeper for
-drainage.
-
-And now the actual boring of the tunnel commenced. It was to be 38 feet
-wide and 22½ feet in height. On New Year’s Day, 1826, the boring-shield
-was placed below in the shaft. The shield was composed of 36 cells, 3
-cells in height and 12 in breadth, with a workman to each.
-
-The huge “shield” was placed before the earth to be excavated, and
-a front board being removed, the soil behind it was dug out to a
-specified extent, and the board was propped against the fresh surface
-thus made. When the boards had all been placed thus, the cells were
-pushed forward into the hollow then made. This was accomplished by
-means of screws at the top and bottom of the shield, and which were set
-against the completed brickwork behind.
-
-For, while the labourers were working in front, the bricklayers behind
-built up the sides and roof, and formed the floor of the tunnel, the
-soil at the roof being supported by the shield until the masons had
-completed their task.
-
-For nine feet, the tunnel proceeded through clay, but then came an
-unwelcome change. Wet, loose sand prevailed, and the work progressed
-with peril for thirty-two days, when firmer ground was reached. Six
-months passed and substantial headway was made, the tunnel being
-completed to the extent of 260 feet.
-
-Then, on the 14th of September, the startling intelligence came that
-the engineer feared the river would burst in at the next tide. He had
-found a cavity over the shield. Sure enough, at high tide, when the
-river was brimming full, the workmen heard the ominous rattle of earth
-falling on their shield, while gushes of water followed.
-
-So excellent were the precautions, however, that no disastrous effects
-followed, and Father Thames himself rolled earth or clay into the hole
-and stopped it up. It was a warning, and emphasised the fear that
-haunted the men’s minds all through the hazardous undertaking—the fear
-that the river would break through and drown the tunnel.
-
-In October, another small irruption took place, and was successfully
-combated. Then, in the following January (1827), some clay fell, but
-still no overwhelming catastrophe occurred. The ground grew so moist,
-however, that it was examined on the other side. That is, the river
-bed was inspected by the agency of a diving-bell, and some ominous
-depressions were found. These were promptly filled by bags of clay.
-
-It may be asked, Why had Brunel not gone deeper? Why had he not placed
-a greater thickness of earth or clay between his work and the waters of
-the Thames?
-
-The answer is this—He had been informed by geologists that quicksand
-prevailed lower down, and the shaft that he sank for drainage below
-the level of the proposed tunnel, indicated that this view might be
-correct. In fact, when he got down 80 feet, the soil gave way, and
-water and sand rushed upwards. He was therefore apparently between the
-Thames and the quicksand. The Tower Subway, constructed in 1869, and
-driven through the solid London clay, is, however, 60 feet deep where
-it commences at Tower Hill.
-
-Work went steadily forward at Brunel’s tunnel until the 18th of May.
-Mr. Beamish, the assistant engineer, was in the cutting on that day,
-and as the tide rose he observed the water increase about the shield;
-clay showed itself and gravel appeared. He had the clay closed up, and
-went to encourage the pumpers. Suddenly, before he could get into the
-cells, a great rush of sludge and water drove the men out of the cells,
-extinguished the lights, floated the cement casks and boxes, and poured
-forward and ever forward, filling the tunnel with the roaring of the
-flood.
-
-The Thames had broken in with a vengeance this time, and drowned the
-tunnel.
-
-
-
-
-CHAPTER II.
-
-UNDER THE RIVER.
-
-
-Happily no one lost his life.
-
-The men retreated before the advancing wave, and as they went they met
-Brunel. But the great engineer could do nothing just then, except,
-like them, to retreat. The lights yet remaining flashed on the roaring
-water, and then suddenly went out in darkness.
-
-The foot of the staircase was reached, and it was found thronged with
-the retreating workers. Higher and higher grew the surging flood;
-Brunel ordered great speed; and scarcely were the men’s feet off the
-lower stair when it was torn away.
-
-On gaining the top, cries were heard; some calling for a rope, others
-for a boat. Some one was below in the water! Brunel himself slipped
-down an iron rod, another followed, and each fastening a rope to the
-body of a man they found in the flood, he was soon drawn out of
-danger. On calling the roll, every worker answered to his name. No life
-was lost.
-
-So far, good; but what was to be done now? The tunnel was full of
-water. To pump it dry was impossible, for the tide poured in from the
-Thames.
-
-Again the diving-bell was used, and the hole was found in the bed of
-the river. To stop it bags of clay, with hazel sticks, were employed;
-and so difficult was the task that three thousand bags were utilised
-in the process, and more than a month elapsed before the water was
-subdued. Two months more passed before the earth washed in was removed,
-and Brunel could examine the work.
-
-He found it for the most part quite sound, though near the shield it
-had been shorn of half its thickness of bricks. The chain of the shield
-was snapped in twain, and irons belonging to the same apparatus had
-been forced into the earth.
-
-The men now proceeded with their task, and exhibited a cool courage
-deserving of all praise. Earth and water frequently fell; foul gases
-pervaded the stifling air, and sometimes exploded, or catching
-fire, they would now and again dance over the water; and again and
-again labourers would be carried away insensible from the poisonous
-atmosphere. Complaints, such as skin eruptions, sickness, and
-headaches, were common. Yet, in spite of every difficulty, the men
-worked on in that damp and dripping and fœtid mine, haunted ever with
-the dread of another flood.
-
-And it came. On the 12th of August, 1828, some fifteen months after the
-previous disaster, the ground bulged out, a large quantity fell, and a
-violent rush of water followed; one man being washed out of his cell to
-the wooden staging behind.
-
-[Illustration: THE THAMES TUNNEL.]
-
-The flow was so great that Brunel ordered all to retire. The water rose
-so fast that when they had retreated a few feet it was up to their
-waists, and finally Brunel had to swim to the stairs, and the rush of
-water carried him up the shaft. Unhappily, about half-a-dozen lives
-were lost at this catastrophe, and those who were rescued—about a dozen
-in number—were extricated in an exhausted or fainting state. The roar
-of the water in the shaft made a deafening noise; the news soon spread,
-and the scene became very distressing as the relatives of the men
-arrived.
-
-Once more the hole in the bed of the Thames had to be stopped. Down
-went the diving-bell, but it had to descend twice before the gap was
-discovered. It was a hole some seven feet long, and four thousand tons
-of earth, chiefly bags of clay, were used in filling it. Again the
-tunnel was entered, and again the intrepid engineer found the work
-sound.
-
-But, alas, another difficulty had presented itself—one more difficult
-to conquer even than stopping up huge holes in the bed of the Thames.
-The tunnel was being cut by a Company, and its money had gone; nay,
-more, its confidence had well nigh gone also. Work could not proceed
-without money, and for seven years silence and desolation reigned in
-those unfinished halls beneath the river.
-
-Then the Government agreed to advance money, and work was again
-commenced. But it proceeded very slowly, some weeks less than a foot
-being cut, during others again three feet nine inches. The ground was
-in fact a fluid mud, and the bed of the river had to be artificially
-formed before the excavation could proceed in comparative safety.
-Further, the tunnel was far deeper than any other work in the
-neighbourhood, and all the water drained there—a difficulty which was
-obviated by the construction of a shaft on the other side of the river.
-
-The shield had also to be replaced. It had been so battered about by
-the flood that another was necessary. As it kept up the earth above,
-and also in front, the change was both arduous and perilous. But it was
-accomplished without loss of life.
-
-Three more irruptions of water occurred: the third in August, 1837,
-the fourth in November, 1837, and the fifth in March, 1838. But the
-engineer was more prepared for Father Thames’ unpleasant visits, and a
-platform had been constructed by which the men could escape. Unhappily,
-one life was lost, however, on the fourth occasion. A great rush of
-soil also occurred in April, 1840, accompanied by a sinking of the
-shore at Wapping over some seven hundred feet of surface. Happily this
-occurred at low tide, and the chasm was filled with gravel and bags of
-clay before the river rose high.
-
-At length, on the 13th of August, 1841, Brunel descended the shaft at
-Wapping, and entering a small cutting, passed through the shield in
-the tunnel, amidst the cheers of the workmen. After all these years
-of arduous toil, of anxious solicitude, and of hair-breadth escapes,
-the end was near, and a passage under the Thames was cut. It was not
-completed and open to the public, however, until the 25th of March,
-1843, and then for foot passengers only.
-
-The approaches for carriages remained to be constructed, and would have
-been expensive works. They were to be immense circular roads, but they
-were never made. Perhaps that deficiency contributed to the commercial
-failure of the great engineering enterprise. In any case, the tunnel
-never paid; the Company dissolved; and the tunnel passed over to the
-East London Railway, who run trains through it. Its length is 1300
-feet, while between it and the river there is a thickness of soil of
-some fifteen feet.
-
-Though a failure as a business, yet the tunnel was a great engineering
-triumph. It was a marvel of perseverance, and of determined, arduous,
-skilful toil against overwhelming difficulties. Eighteen years
-passed before it was completed; and if the seven be deducted during
-which the work was stopped, still eleven remain as the period of its
-construction. Work occupying such a length of time must be costly.
-Could it be shortened? Would tunnel-making machinery be developed and
-improved so as to expedite the labour of years?
-
-
-
-
-CHAPTER III.
-
-THROUGH THE ALPS.
-
-
-“Cut through the Alps? It is an impossibility; and it would never pay!”
-
-“Yet they are about to do it. Sommeiller, an engineer, has invented, or
-obtained, a rock-boring machine which promises to lighten the labour
-considerably; and then, of course, they will shatter great quantities
-of earth by explosives.”
-
-“And what part of the Alps?”
-
-“Through Mont Cenis. The tunnel will be about 7½ miles long, and the
-mountain over it will rise 5400 feet at one point.”
-
-“And when do they expect to finish it?”
-
-“I cannot say. They will begin on the southern—that is, the
-Italian—side first, and later on the French side. Through the tunnel
-will pass one of the principal routes from the West to the East.”
-
-This conversation, we may suppose, took place in 1857, the year when
-the tunnel was commenced. For four years hand work was used, though
-blasting was in operation from the first; but in 1861 drilling by
-machinery was brought into play, and the rate of progress became much
-greater.
-
-The machine was the first practical boring apparatus for rock, and
-was used first in making the Mont Cenis Tunnel. With explosives, as
-gun-cotton, dynamite, etc., the time occupied in cutting tunnels has
-been much reduced. Thus the Mont Cenis Tunnel occupied about thirteen
-years, and cost three millions of pounds. The St. Gotthard—another
-Alpine subway—occupied eight years, though it is 9¼ miles in length;
-and the Arlberg—yet another Alpine tunnel—a little over 6 miles long,
-occupied something more than three years.
-
-Further, the railway of which the St. Gotthard Tunnel forms part, has
-been commercially very successful. This tunnel was commenced in 1872
-and completed in 1880, the same year that saw the beginning of the
-Arlberg.
-
-Tunnels through hard rock do not always need a lining of brickwork; but
-if the soil be clay, or loose earth of any kind, the lining of brick
-or stone must be brought up close to the scene of actual excavation.
-The Mont Cenis is lined with stone or brick almost entirely, about 900
-feet, however, being without such lining.
-
-And now, how was the actual work of tunnelling carried on? It will be
-seen at once that the problem was quite different from that of boring
-fifteen feet under the Thames, and sometimes through watery mud. In
-boring through mountains the quickest way of cutting and carting away
-rock is one of the chief points to be considered. At the Mont Cenis
-Tunnel the blasting took place by driving a series of shot holes into
-the soil, all over the surface to be cut, filling them with explosives,
-and firing them simultaneously in rings. Such explosives may be fired
-by a time-fuse or by electricity, giving the workmen ample time to
-escape out of reach. The shaken and shattered soil can then be cleared
-away.
-
-The blast holes in this small-shot system are about 1 to 1½ inch in
-diameter, and from 1½ to 7 or 9 feet in the rock. The explosive is
-forced to the end of each, and the hole is then tamped—that is, closed
-with clay or sand—and fired in due time.
-
-[Illustration: BORING MACHINE USED FOR THE MONT CENIS TUNNEL.]
-
-The cutters for boring in rock are often diamond drills, the cutting
-edges being furnished with a kind of diamond found in Brazil, of a
-black colour and of great hardness. These are placed round the edge
-of a cylinder of steel, to which iron pipes can be screwed as the
-edge cuts its way deeper in the rock. The stuff cut out as the drill
-revolves finds its way through the cylinder and the piping. There are,
-however, a great number of boring machines of different kinds, hard
-steel sometimes taking the place of the opaque diamonds for cutting
-purposes. The compressed air with which many of the machines are
-worked assisted in the St. Gotthard in the ventilation of the tunnel,
-frequently a great consideration, as the space is so small and the gas
-from explosions often so great.
-
-The Mont Cenis Tunnel marks a transition period in tunnelling. During
-the four years that hand labour was used, the average rate of progress
-was but nine inches a-day on either side; but when the rock-drills
-worked by compressed air were introduced, the speed was five times as
-great. Still further, at the Arlberg Tunnel through the Tyrolese Alps
-the average rate of progress was 9·07 yards per day, and the cost £108
-per lineal yard; while the cost of the Mont Cenis was £226 per lineal
-yard. These figures show immense progress in economy and in speed.
-
-The St. Gotthard Tunnel was begun in 1872, and the machine drills were
-used throughout. A heading was first cut about eight feet square, and
-the hollow thus gained was afterwards enlarged and finally sunk to the
-desired level. Several Ferroux drills were used, placed on a carriage,
-and an average charge of 1¾ lbs. of dynamite placed in the holes made.
-After firing, the compressed air was discharged and the shattered soil
-was cleared away.
-
-In the Arlberg Tunnel a chief heading was driven, and then shafts
-opened up enabling smaller headings to be driven on both hands. Drills
-worked by hydraulic power were used, as well as drills worked by air,
-and, after the explosions, water spray was thrown out to assist in
-clearing and purifying the air. Ventilators also were used, which
-injected air at the rate of more than 8000 cubic feet per minute.
-Speedy transit of the earth excavated and the materials for masonry
-were also effected, it being estimated that some 900 tons of earth had
-to be taken out of each end, and about 350 tons of masonry had to be
-brought in, every day.
-
-Tunnels through huge thicknesses of rock or under rivers can only
-be cut from the two opposite ends. Where possible, however, other
-shafts have been sunk along the line the subway was to take, and thus
-excavation might continue at several places along the line of route,
-the shafts being used for ventilation and for the conveyance of the
-excavated soil.
-
-But the use of machine drills and of blasting explosives, with improved
-appliances for ventilation, have, with possibly some rare exceptions,
-rendered these methods obsolete. According to Pliny the tunnel for
-draining Lake Fucino was the greatest work of his day. It was over
-3½ miles long, and cut under Monte Salviano. Forty shafts were sunk
-in cutting it, also sloping galleries, and huge copper buckets were
-used to carry away the earth. It is stated that this tunnel—some ten
-feet high, by six wide—occupied 30,000 men eleven years. Compare this
-with the Arlberg, or even the Gotthard, double and treble the length,
-occupying much less time. Sir Benjamin Baker has calculated that the
-Fucino tunnel could now be cut in eleven months.
-
-Gunpowder gave some advance on old Roman methods of tunnelling. The
-improved explosives and rock-drills have gone further.
-
-Even as the Mont Cenis shows a transition period, so the Arlberg may
-be said to emphasise a triumph of the methods then indicated. So great
-have been the improvements of the rock-boring machinery, of the power
-of the blasts, and the speedy ventilation following the explosions, and
-of the quick transit of materials, that we shall most likely hear no
-more of sinking numerous shafts along the route.
-
-But what of subaqueous tunnels? Violent explosives are hardly suitable
-for excavation a few feet under a turbid river. What is to be done,
-when cutting under a full and treacherous stream?
-
-
-
-
-CHAPTER IV.
-
-UNDER WATER AGAIN.
-
-
-“How to cross the Thames at Blackwall, far east of the Tower Bridge?”
-That was a problem which the citizens of London had to face in the
-latter part of the nineteenth century.
-
-An immense population dwelt on either side, and some means of easy
-communication became a pressing necessity. Should it be effected by
-means of a bridge, fixed or floating, or by means of a tunnel?
-
-Finally a tunnel was decided upon, with sloping approaches on either
-side. Its entire length was to be 6200 feet including the approaches;
-but herein lay the danger and the difficulty—it was to be driven only
-seven feet below the bed of the river, and through loose soil and
-gravel.
-
-How then was this perilous task to be accomplished? If the great river
-burst through Brunel’s fifteen feet, would it not be much more likely
-to rush through this seven feet of loose soil?
-
-But the engineers in charge had an appliance in hand, which was unknown
-to Brunel—viz., a compressed air chamber, a piece of apparatus which
-has facilitated several great engineering achievements, besides the
-Blackwall Tunnel.
-
-When the excavation of the tunnel was commenced, a stout apartment
-was formed at the end of the cutting, into which air was pumped until
-it exerted a pressure of some thirty-five pounds to a square inch, in
-addition to its usual weight.
-
-This is generally reckoned at an average of 14·7 pounds to a square
-inch. We are so used to this pressure that we do not feel it; but let
-us enter a room where the air has been much more compressed, as in
-this air-chamber, and serious consequences would be likely to ensue,
-especially at first.
-
-The human body, however, has a wonderful power of adaptability, and
-after a time some men get used to the change and can work in the
-compressed air without injury. But at first it may cause bleeding from
-the nose and ears, sometimes indeed affecting the hearing more or less
-seriously, and also causing great pain.
-
-The reason for using this compressed air chamber was to keep out Father
-Thames. The great pressure of the air resisted the great pressure of
-the water, and held up the seven feet of soil between.
-
-Powerful engines were maintained at work to provide for the pressure
-of the air, and the chamber in which the compressed air was kept was
-entered and left by the workmen through an “air-lock”—that is, a small
-ante-chamber having two doors, one leading to the compressed air and
-the other to the ordinary atmosphere, and neither being opened at the
-same time.
-
-The men, then, worked in this compressed air chamber, which prevented
-irruptions of the river. But the method of excavation was also another
-safeguard, both against irruptions of water and of earth.
-
-In essence, it was much the same as that pursued in boring the tunnel
-for the South London Electric Railway; that, however, was through thick
-clay and about 10½ feet in diameter, and this was 27 feet across, and
-through loose and stony stuff. The shield, instead of containing as in
-Brunel’s time a number of cells, consisted of an immense iron cylinder,
-weighing some 250 tons; closed in front, but having a door in the
-closed part; the rim of the cylinder round this part having a sharp
-edge for cutting into the soil.
-
-[Illustration: THE ENTRANCE TO THE AIR-LOCK.
-
-(_Men waiting to enter the Compressed Air-Chamber through the Door._)]
-
-The door being opened, the men found themselves face to face with the
-earth to be excavated. They cut away as well as they could, perhaps
-about 2½ feet deep, throwing the earth into trucks in the compressed
-air chamber; these trucks would be afterwards hauled away through the
-air-lock by electricity, and the huge iron cylinder would be pushed
-forward by means of hydraulic power. Twenty-eight hydraulic “jacks”
-were employed, and they forced forward the 250 ton cylinder with its
-cutting edge, when the men would resume working through the door as
-before.
-
-Behind them, the hole of the tunnel thus cut out was being lined.
-First, it was built round with iron plates a couple of inches thick.
-This plating was fixed in segments, and formed a huge pipe a little
-smaller than the actual hollow in the earth. Through holes in the
-immense piping, liquid cement was forced, thus plugging up the space
-entirely between the earth and the iron, and forming an outer ring of
-cement.
-
-Within, the tunnel was completed by a facing of glazed tiles, placed on
-a thickness of 14 inches of concrete. A road-way was laid 16 feet wide,
-flanked by footpaths of 3 feet, 2 inches, on either side. The subway is
-lighted by electricity, and staircases on the banks lead down to it for
-foot passengers. The stairways give entrance to the tunnel not far from
-the river, and much nearer than the commencement of the carriage-way
-approaches.
-
-At the northern side, the slope down commences near the East India
-Dock entrance, and turns out of the East India Dock Road. The slope
-is fairly gradual—about one in thirty-four—and it passes under the
-Blackwall line of the Great Eastern Railway, and near to Poplar
-Station. The part of the tunnel near to this point—that is the part
-between the river and the open slope—was executed by what is called
-“cut and cover” work—that is, a huge trench was dug, then arched in and
-covered over.
-
-“Cut and cover” work also took place on the south side; and there, at
-the foot of an immense excavation ninety feet down, and with its sides
-held up by huge timbers, might have been seen a river of water which
-had drained in and was being pumped up quickly by powerful machinery.
-
-Not far distant, the shaft was being sunk for the staircase. In
-principle, the sinking of the shaft was conducted much as Brunel’s
-shaft at the Thames Tunnel, only it was built up of iron instead of
-brick. Imagine a big gasometer with a scaffold near the top, where men
-are busy building the walls higher and higher by adding on plate after
-plate of iron. On reaching the scaffold you find that there are two
-great cylinders of iron, one standing inside the other, and concrete
-is being filled in between them. Men also are down below digging out
-the earth which is being swung up in iron buckets; and as the soil is
-gradually removed, the immense double iron and concrete cylinder slowly
-sinks by its own weight.
-
-In this manner, the great shaft was sunk nearly ninety feet, and within
-it the staircase has been built, giving entrance for foot passengers,
-not far from the river. Thus, on either side are sloping entrances to
-the tunnel, and also, nearer the water, stairways of descent down great
-shafts.
-
-Engineers have also found their way beneath other great English
-rivers—the Severn and the Mersey. Much water had to be dealt with
-in the cutting of the Severn Tunnel. This important work, four and
-one-third miles long, was driven in some places forty-five feet under
-sandstone, and at the Salmon Pool—a hollow in the river bed—the tunnel
-was thirty feet under soil called trias marl. Much greater space,
-therefore, exists here between the tunnel and river than at Blackwall.
-But the river burst through. The work was begun in 1873, and completed
-in 1886.
-
-Six years after its commencement the tunnel was drowned, so to speak,
-for a long time by a large spring of water which burst out from
-limestone, and arrangements had to be made to provide for this flood.
-It is now conducted by a subsidiary tunnel or channel to a huge shaft,
-where it is raised by pumps of sufficient strength. Then there was the
-perilous Salmon Pool to be dealt with. The river burst through here,
-and the rent had to be stopped with clay. The tunnel is twenty-six
-feet wide by twenty feet high, and is cut through Pennant stone,
-shale, and marl. It is lined with Staffordshire vitrified bricks
-throughout—seventy-five million bricks it is estimated being used. The
-works are ventilated by a huge fan, and pumping continually proceeds,
-something like twenty-six million gallons of water, it is said, being
-raised in the twenty-four hours. The tunnel, of which the engineers
-were Messrs. Hawkshaw, Son, Hayter & Richardson, and Mr. T. A. Walker,
-Contractor, is for the use of the Great Western Railway, and saves
-that Company’s Welsh and Irish trains to Milford a long way round by
-Gloucester.
-
-[Illustration: THE BORING MACHINE USED IN THE PRELIMINARY CONSTRUCTION
-OF THE ENGLISH CHANNEL TUNNEL.]
-
-In cutting the Mersey Tunnel, which was completed in 1886, machinery
-was used for some of the work. The machine bored partly to a diameter
-of seven feet four inches, but hand labour had to be largely depended
-upon. The plan pursued was to sink a shaft on either side of the
-river and drive a heading, sloping upward through the sandstone to
-the centre; this heading acting as a drain for any water which might
-appear. The thickness between the arch of the tunnel and the river bed
-is thirty feet at its least, and the tunnel, which occupied about six
-years in construction, and of which the engineers were Messrs. Brunlees
-& Fox, is provided with pumps raising some thirteen million gallons
-of water daily. As in the case of the Severn Tunnel, ventilation is
-provided for by huge fans.
-
-A boring machine was also used in the preliminary efforts for the
-construction of a tunnel under the English Channel. Holes, seven
-feet across and to the length of 2000 yards, have been bored by a
-compressed air machine, working with two arms furnished with teeth of
-steel. The construction of the tunnel is held to be quite feasible from
-an engineering point of view, and it is believed that it would pass
-through strata impervious to water, such as chalk marl and grey chalk.
-
-Still, the huge tunnel at Blackwall, which was carried out by Mr.
-Binnie, Chief Engineer of the London County Council, with Mr. Greathead
-and Sir Benjamin Baker as Consulting Engineers, is probably one of the
-most daring and stupendous enterprises of the kind ever undertaken. To
-hollow out a subway hundreds of feet long under the Thames, only seven
-feet from the bed of the great river, and through loose gravelly soil,
-was a great triumph. It was achieved not by uncalculating bravery, but
-by a wise combination of cool courage, superb skill, and admirable
-foresight.
-
-To design effectively, to provide for contingencies, to be daunted
-by no difficulties—these qualities help to produce the Triumphs of
-Engineers, as well as do great inventive skill, the power of adapting
-principles to varying circumstances, and high-spirited enterprise in
-planning and conducting noble and useful works. These works may well
-rank among the great achievements of man’s effort and the wonders of
-the world.
-
-
-THE END.
-
-
-LORIMER AND GILLIES, PRINTERS, EDINBURGH.
-
-*** END OF THE PROJECT GUTENBERG EBOOK ENGINEERS AND THEIR TRIUMPHS:
-THE STORY OF THE LOCOMOTIVE, THE STEAMSHIP, BRIDGE BUILDING, TUNNEL
-MAKING ***
-
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-<p style='text-align:center; font-size:1.2em; font-weight:bold'>The Project Gutenberg eBook of Engineers and their triumphs: the story of the locomotive, the steamship, bridge building, tunnel making, by F. M. Holmes</p>
-<div style='display:block; margin:1em 0'>
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world at no cost and with almost no restrictions
-whatsoever. You may copy it, give it away or re-use it under the terms
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-country where you are located before using this eBook.
-</div>
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-<p style='display:block; margin-top:1em; margin-bottom:1em; margin-left:2em; text-indent:-2em'>Title: Engineers and their triumphs: the story of the locomotive, the steamship, bridge building, tunnel making</p>
-<p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em'>Author: F. M. Holmes</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Release Date: October 1, 2022 [eBook #69084]</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Language: English</p>
-  <p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em; text-align:left'>Produced by: Fiona Holmes and the Online Distributed Proofreading Team at http://www.pgdp.net (This file was produced from images generously made available by The Internet Archive/American Libraries.)</p>
-<div style='margin-top:2em; margin-bottom:4em'>*** START OF THE PROJECT GUTENBERG EBOOK ENGINEERS AND THEIR TRIUMPHS: THE STORY OF THE LOCOMOTIVE, THE STEAMSHIP, BRIDGE BUILDING, TUNNEL MAKING ***</div>
-
-<div class="transnote">
-<h2>Transcriber’s Notes</h2>
-
-<p>Hyphenation has been standardised.</p>
-
-<p>The Transcriber has constructed a ‘List of Illustrations’, as none was
- supplied.</p>
-
-<p><a href="#Page_132" title="">Page 132</a>&#8212;changed possibilites to <strong>possibilities</strong></p>
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-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_iii"></a>[iii]</span></p>
-<div class="figcenter">
-<a id="i_frontis"><img src="images/i_frontis.jpg" alt="" width="550" height="382" /></a>
-<p class="caption center">THE TOWER BRIDGE, LONDON, SHOWING THE BASCULES RAISED.</p></div>
-</div>
-
-<p class="p4"></p>
-
-<div class="chapter">
-<h1> ENGINEERS<br />
-
-AND<br />
-
-THEIR TRIUMPHS:</h1>
-
-<p class="center"> <em>THE STORY OF THE LOCOMOTIVE—THE STEAMSHIP—BRIDGE
-    BUILDING—TUNNEL MAKING.</em></p>
-<p class="p2"></p>
-<p class="center p80"> BY</p>
-
-<p class="center"> F. M. HOLMES,</p>
-
-<p class="center p60"> AUTHOR OF “FOUR HEROES OF INDIA,” ETC.</p>
-
-<p class="p2"></p>
-<div class="figcenter">
-<a id="i_003"><img src="images/i_003.jpg" alt="" width="100" height="100" /></a>
-</div>
-
-<p class="p2"></p>
-<p class="center p60"> FLEMING H. REVELL COMPANY</p>
-
-<p class="center p60"> NEW YORK&#160;&#160;&#160;CHICAGO&#160;&#160;&#160;TORONTO</p>
-
-<p class="center p80"> <em>Publishers of Evangelical Literature.</em>
-</p>
-</div>
-
-<hr class="chap2 x-ebookmaker-drop" />
-<p class="p4"></p>
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_v"></a>[v]</span></p>
-<div class="figcenter">
-<a id="i_005"><img src="images/i_005.jpg" alt="" width="600" height="336" /></a>
-</div>
-</div>
-
-<p class="p2"></p>
-<p class="center">PREFACE.</p>
-<hr class="r5 x-ebookmaker-drop" />
-
-<p class="drop-cap"><span class="smcap">Without</span> attempting to be exhaustive, this little
-book aims at describing in a purely popular
-and non-technical manner some of the great
-achievements of engineers, more particularly
-during the nineteenth century.</p>
-
-<p>The four departments chosen have been selected not
-in pursuance of any comprehensive plan, but because
-they present some of the more striking features of
-constructional effort. The term Engineering, however,
-includes the design and supervision of numerous
-works, such as roads and canals, docks and break-waters,
-machinery and mining, as well as steam-engines
-and steamships, bridges and tunnels.</p>
-
-<p>Information, in certain cases, has been gained at
-first-hand, and I have to acknowledge the courtesy
-of the managers of the Cunard and White Star Steamship
-Companies, Messrs. Maudslay, Sons &amp; Field, and
-others, in supplying various particulars.</p>
-
-<p>The narrative concerning Henry Bell and the steamship
-<em>Comet</em>, and of his connection with Fulton, is chiefly <span class="pagenum"><a id="Page_vi"></a>[vi]</span>
-based on a letter from Bell himself in the <cite>Caledonian
-Mercury</cite> in 1816.</p>
-
-<p>The statement that Mr. Macgregor Laird was so
-largely instrumental in founding the British and
-American Steam Navigation Company is made on
-the authority of his daughter, Miss Eleanor Bristow
-Laird. An article on “The Genesis of the Steamship,”
-which I wrote in the <cite>Gentleman’s Magazine</cite>,
-brought a letter from that lady in which she declares
-that her father was the prime mover in founding the
-Company. He had had experience, in the Niger
-Expedition of 1832-33, of the behaviour of steamships
-both at sea and in the river, and from the date of his
-return to England she asserts he advocated the establishment
-of steam communication between England and
-America, against the active opposition of Dr. Lardner
-and others. “Macgregor Laird’s claim to the foremost
-place amongst all those (not excepting Brunel) who
-worked for the same object,” writes Miss Laird, “was
-clearly shown in a letter from the late Mr. Archibald
-Hamilton of 17 St. Helen’s Place, E.C., to the editor
-of the <cite>Shipping and Mercantile Gazette</cite>, in which
-paper it was published on 15th May, 1873.”</p>
-
-<p>It is not a little curious to note how, in many of these
-great undertakings, several minds seem to have been
-working to the same end at about the same time. It
-was so with George Stephenson and others with regard
-to the locomotive, with Miller and Symington, Bell
-and Fulton, with regard to the steamship, with Laird
-and Brunel as regards transatlantic steam navigation,
-with Robert Stephenson and William Fairbairn as
-regards the tubular bridge.</p>
-
-<p>This volume does not seek to be the special advocate
-of any, or to enter into any minute details, but simply
-endeavours to gather up the more salient features and
-weave them into a connected and popular narrative.</p>
-
-<p class="right">F. M. HOLMES.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="figcenter">
-<p><span class="pagenum"><a id="Page_vii"></a>[vii]</span></p>
-
-<a id="i_007"><img src="images/i_007.jpg" alt="" width="600" height="326" /></a>
-
-
-<div class="chapter">
-<h2 class="nobreak">CONTENTS.</h2>
-</div>
-</div>
-<hr class="r5 x-ebookmaker-drop" />
-<table>
-<tr>
-  <td class="tdc" colspan="3">THE STORY OF THE LOCOMOTIVE.</td>
-</tr><tr>
-<th class="chap">CHAPTER</th>
-<th></th>
-<th class="pag">PAGE</th>
-</tr>
-
-<tr>
-  <td class="chn">I.</td>
-  <td class="cht"><span class="allsmcap">FIRST STEPS,</span></td>
-  <td class="right"><a href="#Page_9">9</a></td>
-</tr><tr>
-  <td class="chn">II.</td>
-  <td class="cht"><span class="allsmcap">GLANCING BACKWARDS AND STRUGGLING FORWARDS,</span></td>
-  <td class="right"><a href="#Page_19">19</a></td>
-</tr><tr>
-  <td class="chn">III.</td>
-  <td class="cht"><span class="allsmcap">FIFTEEN MILES AN HOUR,</span></td>
-  <td class="right"><a href="#Page_28">28</a></td>
-</tr><tr>
-  <td class="chn">IV.</td>
-  <td class="cht"><span class="allsmcap">A MARVEL OF MECHANISM,</span></td>
-  <td class="right"><a href="#Page_36">36</a></td>
-</tr><tr>
-  <td class="chn">V.</td>
-  <td class="cht"><span class="allsmcap">A MILE A MINUTE,</span> </td>
-  <td class="right"><a href="#Page_46">46</a></td>
-</tr>
-<tr>
-  <td class="tdc" colspan="3">THE STORY OF THE STEAMSHIP.</td>
-</tr><tr>
-  <td class="chn">I.</td>
-  <td class="cht"><span class="allsmcap">THE “COMET” APPEARS,</span></td>
-  <td class="right"><a href="#Page_53">53</a></td>
-</tr><tr>
-  <td class="chn">II.</td>
-  <td class="cht"><span class="allsmcap">TO THE NARROW SEAS,</span> </td>
-  <td class="right"><a href="#Page_60">60</a></td>
-</tr><tr>
-  <td class="chn">III.</td>
-  <td class="cht"><span class="allsmcap">ON THE OPEN OCEAN,</span></td>
-  <td class="right"><a href="#Page_68">68</a></td>
-</tr><tr>
-  <td class="chn">IV.</td>
-  <td class="cht"><span class="allsmcap">THE OCEAN RACE,</span> </td>
-  <td class="right"><a href="#Page_74">74</a></td>
-</tr><tr>
-  <td class="chn">V.</td>
-  <td class="cht"><span class="allsmcap">BEFORE THE FURNACE,</span> </td>
-  <td class="right"><a href="#Page_85">85</a></td>
-</tr><tr>
-  <td class="tdc" colspan="3">FAMOUS BRIDGES AND THEIR BUILDERS.</td>
-</tr><tr>
-  <td class="chn">I.</td>
-  <td class="cht"><span class="allsmcap">“THE BRIDGE BY THE EARTHEN HOUSE,”</span></td>
-  <td class="right"><a href="#Page_101">101</a></td>
-</tr><tr>
-  <td class="chn">II.</td>
-  <td class="cht"><span class="allsmcap">A NEW IDEA—THE BRITANNIA TUBULAR,</span> </td>
-  <td class="right"><a href="#Page_108">108</a><span class="pagenum"><a id="Page_viii"></a>[viii]</span></td>
-</tr><tr>
-  <td class="chn">III.</td>
-  <td class="cht"><span class="allsmcap">LATTICE AND SUSPENSION BRIDGES,</span></td>
-  <td class="right"><a href="#Page_119">119</a></td>
-</tr><tr>
-  <td class="chn">IV.</td>
-  <td class="cht"><span class="allsmcap">THE GREATEST BRIDGE IN THE WORLD,</span> </td>
-  <td class="right"><a href="#Page_125">125</a></td>
-</tr><tr>
-  <td class="chn">V.</td>
-  <td class="cht"><span class="allsmcap">THE TOWER BRIDGE,</span> </td>
-  <td class="right"><a href="#Page_133">133</a></td>
-</tr><tr>
-  <td class="tdc" colspan="3"> REMARKABLE TUNNELS AND THEIR<br />
-    CONSTRUCTION.</td>
-</tr><tr>
-  <td class="chn">I.</td>
-  <td class="cht"><span class="allsmcap">HOW BRUNEL MADE A BORING-SHIELD,</span></td>
-  <td class="right"><a href="#Page_137">137</a></td>
-</tr><tr>
-  <td class="chn">II.</td>
-  <td class="cht"><span class="allsmcap">UNDER THE RIVER,</span> </td>
-  <td class="right"><a href="#Page_141">141</a></td>
-</tr><tr>
-  <td class="chn">III.</td>
-  <td class="cht"><span class="allsmcap">THROUGH THE ALPS,</span></td>
-  <td class="right"><a href="#Page_147">147</a></td>
-</tr><tr>
-  <td class="chn">IV.</td>
-  <td class="cht"><span class="allsmcap">UNDER WATER AGAIN,</span> </td>
-  <td class="right"><a href="#Page_153">153</a></td>
-</tr>
-</table>
-
-<div class="figcenter">
-<a id="i_008"><img src="images/i_008.jpg" alt="" width="150" height="209" /></a>
-</div>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="List_of_Illustrations">List of Illustrations</h2>
-</div>
-
-<table id="ILLUSTRATIONS">
-<tr>
-  <td class="tdl">The Tower Bridge, London, showing the bascules raised.</td>
-  <td class="tdr"><a href="#Page_iii"> iii</a></td>
-</tr><tr>
-  <td class="tdl">George Stephenson.</td>
-  <td class="tdr"><a href="#Page_11">11</a></td>
-</tr><tr>
-  <td class="tdl">“Puffing Billy,” the oldest locomotive engine in
-    existence. </td>
-  <td class="tdr"><a href="#Page_13"> 13</a></td>
-</tr><tr>
-  <td class="tdl">James Watt.</td>
-  <td class="tdr"><a href="#Page_21">21</a></td>
-</tr><tr>
-  <td class="tdl">Edward Pease.</td>
-  <td class="tdr"><a href="#Page_27"> 27</a></td>
-</tr><tr>
-  <td class="tdl">The compound locomotive “Greater Britain.”</td>
-  <td class="tdr"><a href="#Page_41">41</a></td>
- </tr><tr>
-  <td class="tdl">Back and front view of the locomotive “Greater Britain.”</td>
-  <td class="tdr"><a href="#Page_44">44</a></td>
-</tr><tr>
-  <td class="tdl">The “Flying Dutchman.”</td>
-  <td class="tdr"><a href="#Page_50">50</a></td>
- </tr><tr>
-  <td class="tdl">Bell’s “Comet.”</td>
-  <td class="tdr"><a href="#Page_55">55</a></td>
-</tr><tr>
-  <td class="tdl">Robert Fulton.</td>
-  <td class="tdr"><a href="#Page_59">59</a></td>
- </tr><tr>
-  <td class="tdl">The ice-bound “Britannia” at Boston.</td>
-  <td class="tdr"><a href="#Page_77">77</a></td>
-</tr><tr>
-  <td class="tdl">Isambard Kingdom Brunel.</td>
-  <td class="tdr"><a href="#Page_80">80</a></td>
- </tr><tr>
-  <td class="tdl">The “Great Eastern.”</td>
-  <td class="tdr"><a href="#Page_83">83</a></td>
-</tr><tr>
-  <td class="tdl">High and low pressure cylinders of the “Campania’s” engines.</td>
-  <td class="tdr"><a href="#Page_87">87</a></td>
- </tr><tr>
-  <td class="tdl">The “Campania.”</td>
-  <td class="tdr"><a href="#Page_89">89</a></td>
-</tr><tr>
-  <td class="tdl">Stoke Hole.</td>
-  <td class="tdr"><a href="#Page_93">93</a></td>
- </tr><tr>
-  <td class="tdl">Promenade deck of the “Paris.”</td>
-  <td class="tdr"><a href="#Page_99">99</a></td>
-</tr><tr>
-  <td class="tdl">Pontypridd Bridge.</td>
-  <td class="tdr"><a href="#Page_102">102</a></td>
- </tr><tr>
-  <td class="tdl">The Post Bridge, Dartmoor.</td>
-  <td class="tdr"><a href="#Page_105">105</a></td>
-</tr><tr>
-  <td class="tdl">Robert Stephenson.</td>
-  <td class="tdr"><a href="#Page_111">111</a></td>
- </tr><tr>
-  <td class="tdl">The Britannia Tubular Bridge.</td>
-  <td class="tdr"><a href="#Page_115">115</a></td>
-</tr><tr>
-  <td class="tdl">Victoria Tubular Bridge, Montreal.</td>
-  <td class="tdr"><a href="#Page_117">117</a></td>
- </tr><tr>
-  <td class="tdl">The Clifton Bridge.</td>
-  <td class="tdr"><a href="#Page_122">122</a></td>
- </tr><tr>
-  <td class="tdl">The Brooklyn Bridge.</td>
-  <td class="tdr"><a href="#Page_123">123</a></td>
-</tr><tr>
-  <td class="tdl">The Forth Bridge.</td>
-  <td class="tdr"><a href="#Page_129">129</a></td>
- </tr><tr>
-  <td class="tdl">The Thames Tunnel.</td>
-  <td class="tdr"><a href="#Page_143">143</a></td>
-</tr><tr>
-  <td class="tdl">Boring machine used for the Mont Cenis Tunnel.</td>
-  <td class="tdr"><a href="#Page_149">149</a></td>
- </tr><tr>
-  <td class="tdl">The entrance to the air-lock.</td>
-  <td class="tdr"><a href="#Page_155">155</a></td>
-</tr><tr>
-  <td class="tdl">The boring machine used in the preliminary
-    construction of the English Channel Tunnel.</td>
-  <td class="tdr"><a href="#Page_159">159</a></td>
-</tr>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_9"></a>[9]</span></p>
-
-<div class="figcenter">
-<a id="i_009"><img src="images/i_009.jpg" alt="" width="600" height="280" /></a>
-</div>
-
-<hr class="chap1 x-ebookmaker-drop" />
-<p class="center p140">ENGINEERS AND THEIR TRIUMPHS.</p>
-<hr class="chap1 x-ebookmaker-drop" />
-
-
-<p class="center p140"><span class="smcap">The Story of the Locomotive.</span></p>
-
-<hr class="r5 x-ebookmaker-drop" />
-
-<h2 class="nobreak">CHAPTER I.</h2>
-</div>
-
-<p class="center">FIRST STEPS.</p>
-
-
-<p class="drop-cap"><span class="smcap">“I think</span> I could make a better engine than
-that.”</p>
-
-<p>“Do you? Well, some’ing’s wanted; hauling
-coal by horses is very expensive.”</p>
-
-<p>“Ay, it is, and I think an engine could do it
-better.”</p>
-
-<p>“Mr. Blackett’s second engine burst all to pieces;
-d’ye mind that?”</p>
-
-<p>“How came that about?”</p>
-
-<p>“Tommy Waters, who put it together, could not make
-it go, so he got a bit fractious and said she should move.
-He did some’ing to the safety-valve and she did begin
-to work, but then she burst all to pieces.”</p>
-
-<p>“Ay, ay, but this one is an improvement.”</p>
-
-<p>“It had need be. Even the third was a perfect
-plague.”</p>
-
-<p><span class="pagenum"><a id="Page_10"></a>[10]</span></p>
-
-<p>“What! you mean Mr. Blackett’s third engine?”</p>
-
-<p>“Ay. It used to draw eight or nine truck loads at
-about a mile an hour, or a little less; but it often got
-cranky and stood still.”</p>
-
-<p>“Stood still!”</p>
-
-<p>“Ay; we thought she would never stick to the road,
-so we had a cogged wheel to work into a rack-work rail
-laid along the track, and somehow she was always
-getting off the rack-rail.”</p>
-
-<p>“And now you find that the engine is heavy enough
-herself to grip the rail.”</p>
-
-<p>“Ay, that was Will Hedley’s notion; he’s a viewer
-at the colliery. And it is a great improvement. Why,
-that third engine, I say, was a perfect nuisance. Chaps
-used to sing out to the driver: ‘How do you get on?’”</p>
-
-<p>“‘Get on,’ sez he, ‘I don’t get on; I on’y get off!’”</p>
-
-<p>“It was always goin’ wrong, and horses was always
-having to be got out to drag it along.”</p>
-
-<p>“How did Hedley find out that a rack-rail was not
-needful?”</p>
-
-<p>“Well, he had a framework put upon wheels and
-worked by windlasses which were geared to the wheels.
-Men were put to work these windlasses which set the
-wheels going; and, lo and behold, she moved! The
-wheels, though smooth, kept to the rails, though they
-were smooth also, and the framework went along without
-slipping. ‘Crikey!’ says Hedley, ‘no cogged wheels,
-no chains, no legs for me! We can do without ’em all.
-Smooth wheels will grip smooth rails.’ And he proved
-it too by several experiments.”</p>
-
-<p>“Then Mr. Blackett had this engine built?”</p>
-
-<p>“Ay, and it be, as you say, a great improvement.
-But that steam blowing off there, after it have done its
-work, frights the horses on the Wylam Road ter’ble, and
-makes it a perfect nuisance.”</p>
-
-<p>“Has nothing been done to alter it?”</p>
-
-<p>“Mr. Blackett has given orders to stop the engine
-when any horses comes along, and the men don’t like
-that because it loses time. He thinks he is going<span class="pagenum"><a id="Page_11"></a>[11]</span>
-to let the steam escape gradual like, by blowing it off
-into a cask first.”</p>
-
-<p>“Umph! very wasteful.”</p>
-
-<p>“Oh, ay; it be wasteful; and many a one about
-here sez of Mr. Blackett that a fool and his money are
-soon parted.”</p>
-
-<p>“No,” said the first speaker, shaking his head thoughtfully,
-“Mr. Blackett is no fool. But I think I could
-build a better engine than that.”</p>
-
-<div class="figcenter">
-<a id="i_011"><img src="images/i_011.jpg" alt="" width="268" height="400" /></a>
-<p class="caption center">GEORGE STEPHENSON.</p></div>
-
-<p>The tone in which these words were uttered was not
-boastful, but quiet and thoughtful.</p>
-
-<p>“You are Geordie Stephenson, the engine-wright of
-the Killingworth Collieries, ’beant you?”</p>
-
-<p>“Ay; and we have to haul coal some miles to the
-Tyne where it can be shipped. So you do away with
-all rack-work rails and all cogged wheels, do you?”</p>
-
-<p><span class="pagenum"><a id="Page_12"></a>[12]</span></p>
-
-<p>“Ay, ay, Geordie, that’s so—smooth wheels on
-smooth rails.”</p>
-
-<p>This conversation, imaginary though to some extent
-it be, yet embodies some important facts. Jonathan
-Foster, Mr. Blackett’s engine-wright, informed Mr.
-Samuel Smiles, who mentions the circumstance in his
-“Lives of the Engineers,” that George Stephenson
-“declared his conviction that a much more effective
-engine might be made, that should work more steadily
-and draw the load more effectively.”</p>
-
-<p>Geordie had studied the steam-engine most diligently.
-Born at Wylam—some eight miles distant from Newcastle,
-about thirty years previously—he had become
-a fireman of a steam-engine and had been wont to take
-it to pieces in his leisure. He was now thinking over the
-subject of building a locomotive engine, and he decided
-to see what had already been accomplished. He would
-profit by the failures and successes of others. So he went
-over to Wylam to see Mr. Blackett’s engines, and to Coxlodge
-Colliery to see Mr. Blenkinsop’s from Leeds; and
-here again it is said, that after watching the machine
-haul sixteen locomotive waggons at a speed of about
-three miles an hour, he expressed the opinion that “he
-thought he could make a better engine than that, to
-go upon legs.”</p>
-
-<p>A man named Brunton did actually take out a patent
-in 1813 for doing this. The legs were to work alternately,
-like a living creature’s. The idea which seems
-to have troubled the early inventors of the locomotive,
-was that smooth wheels would not grip smooth
-rails to haul along a load. And it was Blenkinsop
-of Leeds who took out a patent in 1811 for a rack-work
-rail into which a cog-wheel from his engine
-should work.</p>
-
-<p>Thus William Hedley’s idea of trusting to the weight
-of the engine to grip the rails, and abolishing all the
-toothed wheels and legs and rack-work for this purpose
-on a fairly level rail, was the first great step toward
-making the locomotive a practicable success.</p>
-
-<p><span class="pagenum"><a id="Page_13"></a>[13]<br /><a id="Page_14"></a>[14]</span></p>
-<div class="figcenter">
-<a id="i_013"><img src="images/i_013.jpg" alt="" width="650" height="437" /></a>
-<p class="caption center"> “PUFFING BILLY,” THE OLDEST LOCOMOTIVE ENGINE IN EXISTENCE.<br />
-(<em>At present in South Kensington Museum.</em>)</p></div>
-
-<p><span class="pagenum"><a id="Page_15"></a>[15]</span></p>
-
-<p>The idea that Stephenson invented the locomotive is
-a mistake. But just as James Watt improved the
-crude steam pumps and engines he found in existence,
-so George Stephenson of immortal memory developed
-and made practicable the locomotive. For, in spite of
-Hedley’s discovery or invention, all locomotives were
-partial failures until Stephenson took the matter in
-hand.</p>
-
-<p>Nevertheless, William Hedley’s “Puffing Billy” must
-be regarded as one of the first practicable railway engines
-ever built. It is still to be seen in the South Kensington
-Museum, London. Patented in 1813, it began
-regular work at Wylam in that year, and continued
-in use until 1872. It was probably this engine which
-Stephenson saw when he said to Jonathan Foster that
-he could make a better, and it was no doubt the first
-to work by smooth wheels on smooth rails. Altogether
-it has been looked upon as the “father” of the enormous
-number of locomotives which have followed.</p>
-
-<p>Mr. Blackett was a friend of Richard Trevithick;
-and among the various inventors and improvers of the
-locomotive engine Richard Trevithick, a tin-miner in
-Cornwall, must have a high place.</p>
-
-<p>Trevithick was a pupil of Murdock, who was assistant
-of James Watt. Murdock had made a model successfully
-of a locomotive engine at Redruth. Others also
-had attempted the same thing. Savery had suggested
-something of the kind; Cugnot, a French engineer,
-built one in Paris about 1763; Oliver Evans, an
-American, made a steam carriage in 1772; William
-Symington, who did so much for the steamboat, constructed
-a model of one in 1784. So that many minds
-had been at work on the problem.</p>
-
-<p>But Richard Trevithick was really the first Englishman
-who used a steam-engine on a railway. He had
-not much money and he persuaded his cousin, Andrew
-Vivian, to join him in the enterprise. In 1802 they
-took out a patent for a steam-engine to propel carriages.</p>
-
-<p><span class="pagenum"><a id="Page_16"></a>[16]</span></p>
-
-<p>But before this he had made a locomotive to travel
-along roads, and on Christmas Eve, 1801, the wonderful
-sight could have been seen of this machine carrying
-passengers for the first time. It is indeed believed to
-have been the first occasion on which passengers were
-conveyed by the agency of steam—the pioneer indeed
-of a mighty traffic.</p>
-
-<p>The machine was taken to London and exhibited in
-certain streets, and at length, in 1808, it was shown on
-ground where now, curiously enough, the Euston Station
-of the London and North-Western Railway stands.
-Did any prevision of the extraordinary success of the
-locomotive flash across the engineer’s brain? Before
-the infant century had run its course what wonderful
-developments of the strange new machine were to
-be seen on that very spot!</p>
-
-<p>Much interest was aroused by the exhibition of this
-machine, and Sir Humphrey Davy, a fellow Cornishman,
-is reported to have written to a friend—“I shall
-soon hope to hear that the roads of England are the
-haunts of Captain Trevithick’s dragons—a characteristic
-name.”</p>
-
-<p>His letter tends to show that the idea then was that
-the engine should run on the public roads, and not on a
-specially prepared track like a railway. Had not this
-idea been modified, and the principle of a railroad
-adopted, it is hardly too much to say that the extraordinary
-development of the locomotive would not have
-followed.</p>
-
-<p>Trevithick’s first engine appears to have burst. At
-all events, in the year 1803 or 1804, he built, and began
-to run, a locomotive on a horse tramway in South
-Wales. It appears that he had been employed to
-build a forge-engine here, and thus the opportunity
-was presented for the trial of a machine to haul along
-minerals. This, it is believed, was the first railway
-locomotive, and its builder was Richard Trevithick.</p>
-
-<p>The trial, however, was not very successful. Trevithick’s
-engine was too heavy for the tramway on which <span class="pagenum"><a id="Page_17"></a>[17]</span>
-it ran, and the proprietors were not prepared to put
-down a stronger road. Furthermore, it once alarmed
-the good folk, unused then to railway accidents, by
-actually running off its rail, though only travelling at
-about four or five miles an hour. It had to be ignominiously
-brought home by horses. That settled the
-matter. It became a pumping engine, and as such
-answered very well.</p>
-
-<p>In this locomotive, however, it should be noted Trevithick
-employed a device which, a quarter of a century
-later, Stephenson made so valuable that we might call
-it the very life-blood of the Locomotive. We mean the
-device of turning the waste steam into the funnel (after
-it has done its work by driving the piston), and thus
-forcing a furnace draught and increasing the fire.
-Stephenson, however, sent the steam through a small
-nozzled pipe which made of it a veritable steam-blast,
-while Trevithick, apparently, simply discharged the
-steam into the chimney.</p>
-
-<p>Disgusted it would seem by the failure, the inventor
-turned his attention to other things. Trevithick appears
-to have lingered on the very brink of success, and then
-turned aside. Another effort and he might have
-burst the barrier. But it was not to be; though if any
-one man deserve the title, Inventor of the Locomotive,
-that man is the Cornish genius Trevithick.
-Readers who may desire fuller information of Trevithick
-and his inventions will find it in his “Life” by
-Francis Trevithick, C.E., published in 1872.</p>
-
-<p>It must be borne in mind that Stephenson found
-the imaginary hindrance that smooth wheels would not
-grip smooth rails, cleared away for him by Hedley’s
-experiment, whereas Trevithick had to contend against
-this difficulty. He strove to conquer it by roughing
-the circumference of his wheels by projecting bolts, so
-that they might grip in that way. That is, his patent
-provided for it, if he did not actually carry out the
-plan.</p>
-
-<p>It is very significant that this imaginary fear should<span class="pagenum"><a id="Page_18"></a>[18]</span>
-have hindered the development of the locomotive.
-The idea seems to have prevailed that, no matter how
-powerful the engine, it could not haul along very
-heavy loads unless special provision were made for
-its “bite” or grip of the rails. Another difficulty
-with which Trevithick had to contend was one of cost.
-It is said that one of his experiments failed in London
-for that reason. This was apparently the locomotive
-for roads, as distinct from the locomotive for rails. A
-machine may be an academic triumph, but the question
-of cost must be met if the machine is to become a
-commercial and industrial success.</p>
-
-<p>Mr. Blenkinsop of Leeds then took out his patent in
-1811 for a rack-work rail and cogged wheel; but
-before this Mr. Blackett of Wylam had obtained a
-plan of Trevithick’s engine and had one constructed.
-He had met Trevithick at London, and it was as early
-as 1804 that he obtained the plan. The engines, therefore,
-of Mr. Blackett which Stephenson saw, came, so to
-speak, in direct line from Trevithick, except that Mr.
-Blackett’s second engine was a combination of Blenkinsop’s
-and Trevithick’s.</p>
-
-<p>Some progress was made, but when on that memorable
-day George Stephenson, the engine-wright of Killingworth,
-said, “I think I could build a better engine
-than that,” no very effective or economical working
-locomotive was in existence.</p>
-
-<p>Back therefore went George Stephenson to his home.
-He had seen what others had done, and with his knowledge
-of machinery and his love for engine work he would now
-try what he could do.</p>
-
-<p>Would he succeed?</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_19"></a>[19]</span></p>
-
-<h2 class="nobreak" id="CHAPTER_II">CHAPTER II.</h2>
-</div>
-
-<p class="center">GLANCING BACKWARDS AND STRUGGLING FORWARDS.</p>
-
-
-<p class="drop-cap"><span class="smcap">“My</span> lord, will you spend the money to build a
-Travelling Engine?”</p>
-
-<p>“Why? what would it do?”</p>
-
-<p>“Haul coals to the Tyne, my lord. The
-present system of hauling by horses is very costly.”</p>
-
-<p>“It is. But how would you manage it by a Travelling
-Engine?” Thereupon George Stephenson the
-engine-wright proceeded to explain.</p>
-
-<p>In some such manner as this we can imagine that
-Stephenson opened up the subject to Lord Ravensworth,
-the chief partner in the Killingworth Colliery;
-and he won his lordship over.</p>
-
-<p>Stephenson had already improved the colliery
-engines, and Lord Ravensworth had formed a high
-opinion of his abilities. So after consideration he gave
-the required consent.</p>
-
-<p>Now, let us endeavour to imagine the position. The
-steam engine, of which the locomotive is one form,
-had been invented years before. The Marquis of
-Worcester made something of a steam engine which
-apparently was working at Vauxhall, South-west
-London, in 1656. It is said that he raised water forty
-feet, and by this we may infer that his apparatus was
-a steam-pump. He describes it in his work “Century
-of Inventions,” about 1655, and he is generally accredited
-with being the inventor of the steam engine. It was,
-however, a very primitive affair, the boiler being the
-same vessel as that in which the steam accomplished
-its work.</p>
-
-<p>Captain Savery took the next step. He was the
-first to obtain a patent for applying steam power to
-machinery. This was in 1698, and he used a boiler
-distinct from the vessel where the steam was to exert<span class="pagenum"><a id="Page_20"></a>[20]</span>
-its power. Savery’s engines appear to have been used
-to drain mines.</p>
-
-<p>His engines acted in this way—the steam was
-condensed in a vessel and produced a vacuum which
-raised the water; then the steam pressing upon it
-raised it further in another receptacle.</p>
-
-<p>An obvious improvement was the introduction of the
-piston. This was Papin’s idea, and he used it first in
-1690. Six years later an engine was constructed by
-Savery, Newcomen (a Devonshire man), and Cawley,
-in which the “beam” was introduced, and also the
-ideas of a distinct boiler separate from a cylinder in
-which worked a piston. This machine was in operation
-for about seventy years. The beam worked on an axle
-in its centre—something like a child’s “see-saw,” and
-one end being attached to the piston moving in the
-cylinder, it was worked up and down, the other end of
-the beam being fastened to the pump-rod, which was
-thus alternately raised and depressed.</p>
-
-<p>The upward movement of the piston having been
-effected by a rush of steam from the boiler upon its
-head, the steam was cut off and cold water run in upon
-it from a cistern. The steam was thus condensed by
-the water and a vacuum caused, and the piston was
-pressed down by the weight of the atmosphere—of
-course dragging down its end of the beam, and raising
-the pump-rod. The steam was then turned on again
-and pushed up the piston, and consequently the end
-of the beam also. Thus the engine continued to work,
-the turning of the cocks to admit steam and water
-being performed by an attendant. The engine was,
-however, made self-acting in this respect, and Smeaton
-improved this form of engine greatly. The beam is
-still used in engines for pumping.</p>
-
-<p>Nevertheless, improved though it became, it was still
-clumsy and almost impracticable. It was the genius of
-James Watt which changed it from a slow, awkward,
-cumbrous affair into a most powerful, practicable, and
-useful machine.</p>
-
-<p><span class="pagenum"><a id="Page_21"></a>[21]</span></p>
-
-<p>His great improvements briefly were these: he condensed
-the steam in a separate vessel from the cylinder,
-and thus avoided cooling it and the consequent loss of
-steam power; secondly, he used the steam to push back
-the piston as well as to push it forward (this is called
-the “double-acting engine,” and is now always used);
-thirdly, he introduced the principle of using the steam
-expansively, causing economy in working; and fourthly,
-he enabled a change to be made of the up and down
-motion of the piston into a circular motion by the introduction
-of the crank.</p>
-
-<div class="figcenter">
-<a id="i_021"><img src="images/i_021.jpg" alt="" width="278" height="400" /></a>
-<p class="caption center"> JAMES WATT.</p></div>
-
-<p>The use of the steam expansively is to stop its rush
-to the cylinder when the piston has only partially
-accomplished its stroke, leaving the remainder of the<span class="pagenum"><a id="Page_22"></a>[22]</span>
-stroke to be driven by the expansion of the steam.
-In early engines the steam was admitted by conical
-valves, worked by a rod from the beam. Murdock,
-we may add in parenthesis, is believed to have invented
-the slide-valve which came into use as locomotives
-were introduced, and of which there are now
-numerous forms. The valve is usually worked by an
-“eccentric” rod on the shaft of the engine.</p>
-
-<p>Watt was the author of many other inventions and
-improvements of the steam engine. Indeed, although
-Savery and Newcomen and others are entitled to great
-praise, it was Watt who gave it life, so to speak, and
-made it, in principle and essence, very much that which
-we now possess. There have, indeed, been improvements
-as to the boiler, as to expansive working, and
-in various details, since his day; but, apart from the
-distinctive forms of the locomotive and the marine
-engine, the machine as a whole is in principle much as
-Watt left it.</p>
-
-<p>The centre of all things in a steam engine is usually
-the cylinder. Here the piston is moved backward and
-forward, and thence gives motion as required to other
-parts of the machine.</p>
-
-<p>The cylinder is in fact an air-tight, round box, fitted
-with a close-fitting, round plate of metal, to which is
-fixed the piston-rod. Now, it must be obvious that if
-the steam be admitted at one end of the cylinder it
-will, as it rushes in, push the metal plate and the piston
-outward, and if this steam be cut off, and the steam
-admitted to the other end of the cylinder, it will push
-the metal plate and piston back again.</p>
-
-<p>But what is to be done with the steam after it has
-accomplished its work? It may be permitted to spurt
-out into the air, or into a separate vessel, where it may
-be condensed. In the locomotive, under Stephenson’s
-able handling, this escape of steam was created into
-a steam-blast in the chimney to stimulate the fire. In
-compound and triple-expansion engines the steam is
-used—or expanded, it is called—in two or three<span class="pagenum"><a id="Page_23"></a>[23]</span>
-cylinders respectively. When steam is condensed, it
-may be returned to the boiler as water.</p>
-
-<p>It was the repairing of a Newcomen engine that
-seems to have started Watt on his inventions and
-improvements of the steam engine. He was then
-a mathematical instrument maker at Glasgow. As
-a boy he had suffered from poor health, but had
-been very observant and studious; and it is said
-that his aunt chided him on one occasion for wasting
-time in playing with her tea-kettle. He would watch
-the steam jetting from its spout, and would count the
-water-drops into which the steam would condense when
-he held a cup over the white cloud.</p>
-
-<p>Delicate though he was in health, he studied much,
-and came, indeed, to make many other articles besides
-mathematical instruments. When, therefore, the Newcomen
-engine needed repair, it was not unnatural that
-it should be brought to him. It appears to have been
-a working model used at Glasgow University. He
-soon repaired the machine; but, in examining it, he
-became possessed with the idea that it was very
-defective, and he pondered long over the problem—How
-it might be improved. What was wanting in
-it? How could the steam be condensed without cooling
-the cylinder?</p>
-
-<p>Suddenly, one day, so the story goes, the idea struck
-him, when loitering across the common with bent brows,
-that if steam were elastic, it would spurt into any
-vessel empty of air. Impatiently, he hastened home
-to try the experiment. He connected the cylinder
-of an engine with a separate vessel, in which the air
-was exhausted, and found that his idea was correct;
-the steam did rush into it. Consequently the steam
-could be condensed in a separate vessel, and the heat
-of the cylinder maintained and the loss of power
-prevented. This invention seems simple enough; yet
-it increased the power of an engine threefold, and
-is at the root of Watt’s fame. We must remember
-that the inventions which in process of time may<span class="pagenum"><a id="Page_24"></a>[24]</span>
-appear the simplest and the most commonplace, may be
-the most difficult to originate. And it may fairly
-be urged—If it were so very simple, and so very
-obvious, why was it not invented before? The supposition
-is that in those days it was not so simple.
-It is possible that the great elasticity of steam was
-not sufficiently understood. In any case, the discovery
-and its application are regarded as his greatest invention.</p>
-
-<p>Yet ten years elapsed before he constructed a real
-working steam engine, and so great we may suppose
-were the difficulties he encountered, including poorness
-of health, that once he is reported to have exclaimed:
-“Of all things in the world, there is nothing so foolish
-as inventing.”</p>
-
-<p>But a brilliant triumph succeeded. Eventually Watt
-became partner with Mr. Matthew Boulton, and the
-firm of Boulton &amp; Watt manufactured the engine at
-Soho Ironworks, Birmingham. Mining proprietors
-soon discovered the value of the new machine, and
-Newcomen’s engine was superseded for pumping.</p>
-
-<p>Watt continued to improve the machine, and together
-with Boulton also greatly improved the workmanship
-of constructing engines and machinery. In
-a patent taken out in 1784, he “described a steam
-locomotive”; but for some reason he did not prosecute
-the idea. It is possible that the notion of building a
-special road for it to run upon did not occur to him, or
-appear very practicable.</p>
-
-<p>His work was done, and it was a great work; but it
-was left for others to develop the steam engine into
-forms for hauling carriages on land or propelling ships
-upon the sea. Trevithick, Stephenson, and others did
-the one; Symington, Bell, and others did the second.
-Watt died in 1819, and though so delicate in youth, he
-lived to his eighty-fourth year.</p>
-
-<p>The steam engine, therefore, as Watt left it, was
-practically as Stephenson came to know it. He would
-be acquainted with it chiefly as a pumping machine.<span class="pagenum"><a id="Page_25"></a>[25]</span>
-But he saw what others had done to adopt it as a locomotive,
-and he now set to work.</p>
-
-<p>Stephenson’s first engine did not differ very materially
-from some of those which had preceded it. He
-was, so to speak, feeling his way. The machine had
-a round, wrought-iron boiler, eight feet long, with two
-upright cylinders placed on the top of it. At the end
-of the pistons from the cylinders were cross-rods connected
-with cogged wheels below by other rods. These
-cogged wheels gave motion to the wheels running on
-the rails by cogs not very far from the axles. Stephenson
-abandoned the cogged rail, and adopted smooth
-wheels and smooth rails; but he did not connect the
-driving-wheel direct with the piston, the intervening
-cogged wheels being thought necessary to unite the
-power of the two cylinders.</p>
-
-<p>In adopting the principle of smooth wheels on smooth
-rails, it is said that Stephenson proved by experiment
-that the arrangement would work satisfactorily. Mr.
-Smiles writes that Robert Stephenson informed him,
-“That his father caused a number of workmen to
-mount upon the wheels of a waggon moderately
-loaded, and throw their entire weight upon the
-spokes on one side, when he found that the waggon
-could thus be easily propelled forward without the
-wheels slipping. This, together with other experiments,
-satisfied him of the expediency of adopting
-smooth wheels on his engine, and it was so finished
-accordingly.” Thus it may be said that this obstacle—imaginary
-though it largely proved to be—was cleared
-away from Stephenson’s first engine.</p>
-
-<p>Ten months were occupied in building the machine,
-and at last came the day of its trial. This was the
-25th of July, 1814. Would it work?</p>
-
-<p>Jolting and jerking along, it did work, hauling eight
-carriages at a speed of about four or six miles an hour—as
-fast as a brisk man could walk. Then came the
-question—Would it prove more economical than horse-power?</p>
-
-<p><span class="pagenum"><a id="Page_26"></a>[26]</span></p>
-
-<p>Calculations therefore were made, and after a time it
-was found that “Blucher” as the engine was called,
-though we believe its real name was “My Lord,” was
-about as expensive as horse-power.</p>
-
-<p>The locomotive needed something more, some magic
-touch to render it less clumsy and more effective.
-What was it?</p>
-
-<p>Then came the first great practicable improvement
-after the smooth wheels on smooth rails. It was the
-steam-blast in the funnel, by which the draught in the
-furnace was greatly increased. Indeed, the faster the
-engine ran the more furiously the fire would burn, the
-more rapid would be the production of steam, and the
-greater the power of the engine.</p>
-
-<p>At first Stephenson had allowed his waste steam from
-the cylinders to blow off into the air. So great was the
-nuisance caused by this arrangement that a law-suit
-was threatened if it were not abated.</p>
-
-<p>What was to be done with that troublesome waste
-steam? Now, whether Stephenson originated the idea
-or adapted what Trevithick had done, we cannot say,
-but at all events he achieved the object, wherever he
-gained the idea. He turned his exhaust steam through
-a pipe into the funnel, and at a stroke increased the
-power of his engine two-fold.</p>
-
-<p>But that expedient was not alone. Stephenson had
-watched the working of “Blucher” to some purpose,
-and he decided to build another engine with improvements.</p>
-
-<p>The cumbersome cog-wheels must go; they complicated
-the machine terribly, and prevented its practicability.
-Therefore in his second engine he introduced
-direct connection between the pistons and the wheels.
-There were a couple of upright cylinders as before, with
-cross-rods attached to the piston-ends, and connecting
-rods from the end of each cross-rod, reaching down to
-the wheels. But to overcome the difficulty of one
-wheel being at some time higher than the other on the
-poorly constructed railway of that period, a joint was<span class="pagenum"><a id="Page_27"></a>[27]</span>
-introduced in the cross-rod, so that if, perchance, the
-two wheels should not be always on exactly the same
-level, no undue strain should be placed on the cross-rod.
-Furthermore, the two pairs of wheels were combined
-first by a chain, but afterwards by connecting rods.
-This may be called the locomotive of 1815, the year in
-which the patent was taken out.</p>
-
-<div class="figcenter">
-<a id="i_027"><img src="images/i_027.jpg" alt="" width="318" height="400" /></a>
-<p class="caption center"> EDWARD PEASE.</p></div>
-
-
-<p>The engine accomplished its work more satisfactorily
-than before, and was placed daily on the rails to
-haul coal from the mine to the shipping point. But
-still its economy over horse-power was not so great as
-to cause its wide adoption. And it was still little
-better, if anything, than a mere coal haul.</p>
-
-<p>Nevertheless Stephenson persevered. He was appointed
-engineer to the Stockton and Darlington
-Railway—an enterprise largely promoted by Mr.<span class="pagenum"><a id="Page_28"></a>[28]</span>
-Edward Pease. It was opened on the 27th of September,
-1825, and a local paper writes as follows:—</p>
-
-<p>“The signal being given, the engine started off with
-this immense train of carriages, and such was its
-velocity, that in some parts the speed was frequently
-12 miles an hour; and at that time the number of
-passengers was counted to be 450, which, together with
-the coals, merchandise, and carriages, would amount to
-near 90 tons. The engine, with its load, arrived at
-Darlington, a distance of 8¾ miles, in 65 minutes. The
-6 waggons loaded with coals, intended for Darlington,
-were then left behind; and obtaining a fresh supply of
-water, and arranging the procession to accommodate a
-band of music and numerous passengers from Darlington,
-the engine set off again, and arrived at Stockton
-in 3 hours and 7 minutes, including stoppages, the
-distance being nearly 12 miles.”</p>
-
-<p>Stephenson became a partner in a business for constructing
-locomotives at Newcastle, and three engines
-were made for the Stockton and Darlington Railway.
-Nevertheless they appear to have been used chiefly if
-not almost entirely for hauling coal; for the passenger-coach
-called the <em>Experiment</em> was hauled by a horse,
-and the journey occupied about two hours.</p>
-
-<p>The locomotive was not even yet a brilliant success
-over horse-power. What was to be the next step?</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_III">CHAPTER III.</h2>
-</div>
-
-<p class="center">FIFTEEN MILES AN HOUR.</p>
-
-
-<p class="drop-cap"><span class="smcap">Five</span> hundred pounds for the best locomotive
-engine!</p>
-
-<p>So ran the announcement one day in the year
-1829. The Liverpool and Manchester Railway
-was nearly completed, but yet the directors had not<span class="pagenum"><a id="Page_29"></a>[29]</span>
-fully decided what power they would employ to haul
-along their waggons.</p>
-
-<p>Horse-power had at length been finally abandoned,
-and numbers of schemes had been poured in upon the
-managers. But the contest seemed at last to resolve
-itself chiefly into a rivalry between fixed and locomotive
-engines. Principally, if not entirely, swayed however by
-the arguments of George Stephenson, the directors
-yielded to the hint of a Mr. Harrison, and offered a
-£500 prize.</p>
-
-<p>The engine was to satisfy certain conditions. Its
-weight was not to be above six tons; it was to burn its
-own smoke, haul twenty tons at a rate of ten miles an
-hour, be furnished with two safety valves, rest on
-springs and on six wheels, while its steam pressure
-must not be more than fifty lbs. to the square inch.
-The cost was not to exceed £550.</p>
-
-<p>Stephenson, who was the engineer of the Railway,
-decided to compete. He was now in a very different
-position from that which he occupied when he built
-his second locomotive in 1815. His appointment as
-engineer to the Stockton and Darlington Railway had
-greatly aided his advancement, and when it was decided
-to build a railway between the two busy cities of
-Manchester and Liverpool it was not unnatural that he
-should take part in the undertaking.</p>
-
-<p>The idea of constructing rail, or tram ways, was not
-new. Railways of some kind were used in England
-about two hundred years before, that is, about the
-beginning of the seventeenth century. Thus Roger
-North writes:—“The manner of the carriage is by
-laying rails of timber from the colliery to the river,
-exactly straight and parallel; and bulky carts are
-made with four rollers fitting those rails, whereby the
-carriage is so easy that one horse will draw down four
-or five chaldron of coals, and is an immense benefit to
-the coal merchants.”</p>
-
-<p>It is said that the word tramway is derived from
-tram, which was wont to mean a beam of timber and<span class="pagenum"><a id="Page_30"></a>[30]</span>
-also a waggon. In any case, such rough ways were
-introduced in mining districts, for, as may be readily
-believed, one horse could draw twenty times the load
-upon them that it could on an ordinary road.</p>
-
-<p>The old ways were first made of wood, then of wood
-faced with iron, then altogether of iron.</p>
-
-<p>Now, in making his railway between Liverpool and
-Manchester, Stephenson had many difficulties to encounter.
-He decided that the line should be as direct
-as possible. But to accomplish this, he would have to
-pierce hills, build embankments, raise viaducts, and,
-hardest of all, construct a firm causeway across a
-treacherous bog called Chat Moss.</p>
-
-<p>“He will never do it,” said some of the most famous
-engineers of the day. “It is impossible!”</p>
-
-<p>Impossible it certainly seemed to be. Chat Moss
-was like a sponge, and how was an engineer to build a
-solid road for heavy trains over four miles of soppy
-sponge! A person could not trust himself upon it
-in safety, and when men did venture, they fastened
-flat boards to their feet, something after the fashion
-of snow-shoes, and floundered along upon them.</p>
-
-<p>Stephenson began by taking the levels of the Moss
-in a similar manner. Boards were placed upon the
-spongy moss, and a footpath of heather followed. Then
-came a temporary railroad. On this ran the trucks
-containing the material for a permanent path, which
-were pushed by boys who learned to trot along easily
-on the narrow rails.</p>
-
-<p>Drains were dug on either side of the proposed road,
-and tar-barrels covered with clay were fitted into a
-sewer underneath the line in the middle of the Moss.
-Heather, hurdles, tree branches, etc., were spread on the
-surface, and in some parts an embankment of dry moss
-itself was laid down. Ton after ton of it disappeared
-until the directors became alarmed, and the desperate
-expedient of abandoning the works was considered.</p>
-
-<p>But Stephenson was an Englishman out and out.
-He never knew when he was beaten. “Keep on<span class="pagenum"><a id="Page_31"></a>[31]</span>
-filling,” he ordered; and in spite of all criticism and
-all alarm, he kept his hundreds of navvies hard at
-work, pouring in load after load of dry turf.</p>
-
-<p>It must be borne in mind, however, that Stephenson
-did not continue blindly at his task. He had good
-reason for what he did. His persistence was a patient,
-intelligent perseverance, and not a stupid obstinacy.
-His main arguments seem to have been two. He
-judged that if he constructed a sufficiently wide road,
-it would float on the moss, even as ice or a raft of wood
-floats on water and bears heavy weights; and secondly,
-he seems to have been animated by the idea, that, if
-necessary, he could pour in enough solid or fairly solid
-stuff to reach the bottom and rise up to the surface in
-a hard mass.</p>
-
-<p>Both ideas seem to have been realised in different
-parts of the bog. Joy took the place of despair, and
-triumph exulted over discouragement, as at length the
-solid mass appeared through the surface. Furthermore,
-the expense was found to be none so costly after
-all. No doubt any quantity of turf could be obtained
-from the surrounding parts of the Moss and dried.</p>
-
-<p>At another part of the railway called Parr Moss an
-embankment about a mile and a-half was formed by
-pouring into it stone and clay from a “cutting” in
-the neighbourhood. In some places twenty-five feet
-of earth was thus concealed beneath the Moss. The
-eye of the engineer had as it were pierced through
-the bog and seen that his solid bank was steadily being
-built up there.</p>
-
-<p>Before, however, the road across Chat Moss was fairly
-opened, the trial of locomotives for the prize of £500 had
-taken place. The fateful day was the 1st day of October,
-1829, and the competition was held at Rainhill. A
-grand stand was erected, and the side of the railway
-was crowded. Thousands of spectators were present.
-The future of the locomotive was to be decided on this
-momentous occasion.</p>
-
-<p>Now, hitherto the difficulty in the locomotive had<span class="pagenum"><a id="Page_32"></a>[32]</span>
-been to supply a steady and sufficient supply of steam
-to work the engine quickly and attain high speed and
-power. Partly, this had been accomplished by Stephenson’s
-device of the steam-blast in the funnel. But something
-more was needed.</p>
-
-<p>That requirement was found in the tubular boiler.
-If the long locomotive boiler were pierced with tubes
-from end to end, it is clear that the amount of heating
-surface offered to the action of the fire would be greatly
-increased. It was this idea which was utilised in the
-“Rocket,” the engine with which Stephenson competed
-at Rainhill, and utilised more perfectly than ever
-before.</p>
-
-<p>Trevithick himself seems to have invented something
-of the kind, and M. Seguin, the engineer of the St.
-Etienne and Lyons Railway utilised a similar method.
-But Henry Booth, the secretary of the railway which
-Stephenson was then building, invented a tubular
-boiler without, it is said, knowing anything of Seguin’s
-plan, and Stephenson who had already experimented
-in the same direction, adopted Booth’s method.</p>
-
-<p>At first it was a failure. The boiler, fitted with
-tubes through which the hot air could pass, leaked
-disastrously, and Stephenson’s son, Robert, wrote to
-his father in despair. But again George said “persevere,”
-and he suggested a plan for conquering the
-difficulty. Again, it was a simple, but as the event
-proved, an effective plan.</p>
-
-<p>The copper tubes were merely to be fitted tightly to
-holes bored in the boiler and soldered in. The heat
-caused the copper to expand and the result was a very
-strong and water-tight boiler. There were twenty-five
-of these tubes, each three inches in diameter, and placed
-in the lower portion of the boiler, leading from the
-furnace to the funnel. Water also surrounded the
-furnace. Further, the nozzles of the steam-blast pipes
-were contracted so as to increase the power of the blast,
-and consequently raise the strength of the draught to
-the fire.</p>
-
-<p><span class="pagenum"><a id="Page_33"></a>[33]</span><br /><span class="pagenum"><a id="Page_34"></a>[34]</span></p>
-<div class="figcenter">
-<a id="i_033"><img src="images/i_033.jpg" alt="" width="490" height="650" /></a>
-<p class="caption center"> “THE ROCKET.”</p></div>
-
-<p><span class="pagenum"><a id="Page_35"></a>[35]</span></p>
-<p>The cylinders were not placed at the top of the
-boiler, but at the sides in a slanting direction, one end
-being about level with the boiler roof. They occupied
-a position mid-way between the old situation upright
-on the roof and their present position below, or at the
-lower portion. The pistons acted directly on the driving
-wheels by means of a connecting rod, and the
-entire weight of the engine with water supply was
-but 4½ tons.</p>
-
-<p>On the day of trial only four engines competed.
-Many had been constructed, but either were not completed
-in time, or for various reasons could not be
-exhibited. The famous four were:—The “Novelty”
-by Messrs. Braithwaite and Ericsson; The “Rocket”
-by Messrs. R. Stephenson &amp; Co.; The “Perseverance”
-by Mr. Burstall; and The “Sanspareil” by Mr. Timothy
-Hackworth. Each engine seems to have run separately,
-and the length of the course was two miles. The test
-was that the engine should run thirty miles, backwards
-and forwards, on the two mile level course, at not less
-than ten miles an hour, dragging three times its own
-weight.</p>
-
-<p>The “Novelty” at first appears to have beaten the
-“Rocket,” for she ran at times at the rate of twenty-four
-miles an hour; while the first trip of the “Rocket”
-covered a dozen miles in fifty-three minutes. The
-engineers of the “Novelty” used bellows to force the
-fire, but on the second day these bellows gave way, and
-the engine could not do its work. The boiler of the
-“Sanspareil” also showed defects, but Stephenson’s
-“Rocket” calmly stood the strain. Practicable as
-usual, Stephenson’s work was as good in its results, nay,
-even better than before, for he hooked the “Rocket”
-to a carriage load of thirty people, and rushed them
-along at the then surprising speed of between twenty-four
-to thirty miles an hour. Mr. Burstall’s “Perseverance”
-could not cover more than six miles an
-hour.</p>
-
-<p>The competitions continued, but the “Novelty,”<span class="pagenum"><a id="Page_36"></a>[36]</span>
-although running at the rate of twenty-four and even
-twenty-eight miles an hour, broke down again and yet
-again; its boiler plates appear to have gone wrong on
-one occasion; while the “Sanspareil” also failed, and
-furthermore blew a good deal of its fuel into the air
-because of the arrangement of its steam-blast.</p>
-
-<p>But the more the “Rocket” was tried, the more practicable
-and reliable the engine appeared to be. On the
-8th of October it gained a speed of 29 miles an hour,
-its steam pressure being about 50 lbs. to the square
-inch, and its average speed was fifteen miles an hour—that
-is, five miles an hour over the conditions required.
-These results appear to have been accomplished with a
-weight of waggons of thirteen tons behind it. When
-detached it ran at the rate of thirty-five miles an hour.</p>
-
-<p>In short, the “Rocket” was the only locomotive
-which fulfilled all the conditions specified for the
-competition, and the prize was duly awarded to
-Stephenson and Booth.</p>
-
-<p>The battle of the locomotive was won. Men could
-see that the machine was feasible and practicable;
-that it was a new force with immense possibilities
-before it.</p>
-
-<p>How have those possibilities been realised?</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_IV">CHAPTER IV.</h2>
-</div>
-
-<p class="center">A MARVEL OF MECHANISM.</p>
-
-
-<p class="drop-cap"><span class="smcap">“The</span> time is coming when it will be cheaper for a
-working man to travel on a railway than to
-walk on foot.”</p>
-
-<p>So prophesied George Stephenson some few
-years before his successful competition at Rainhill; and
-by his success on that fateful day, he had brought the
-time appreciably nearer. The directors of the Liverpool<span class="pagenum"><a id="Page_37"></a>[37]</span>
-and Manchester Railway no longer debated as to
-what form of traction they should adopt.</p>
-
-<p>But Stephenson did not rest on his laurels. Every
-new engine showed some improvement. The “Arrow”
-sped over Chat Moss at about 27 miles an hour, on the
-occasion of the first complete journey along the line, on
-the 14th of June, 1830; and when, on the public opening
-of the railway on the 15th of September, 1830, Mr.
-William Huskisson, M.P., was unhappily knocked down
-by the “Rocket,” George Stephenson himself took the
-maimed body in the “Northumbrian,” fifteen miles in
-twenty-five minutes—that is, he drove the engine at the
-speed of thirty-six miles an hour.</p>
-
-<p>The sad death of Mr. Huskisson has often been
-referred to, but we may tell the story again, following
-the account given by Mr. Smiles, who had the advantage
-of the assistance of Robert Stephenson in the preparation
-of his biography.</p>
-
-<p>The engines it appears halted at Parkside, some
-seventeen miles from Liverpool, to obtain water. The
-“Northumbrian,” with a carriage containing the Duke
-of Wellington and some friends, stood on one line, so
-that all the trains might pass him in review on the
-other. Mr. Huskisson had descended from the carriage
-and was standing on the rail on which the “Rocket”
-was rapidly approaching. There had been some coolness
-between the Duke and Mr. Huskisson, but at this time
-the Duke extended his hand and Mr. Huskisson hurried
-to grasp it, when the bystanders cried “Get in! get in.”</p>
-
-<p>Mr. Huskisson became flurried and endeavoured to
-go round the carriage door which was open and hung
-over the rail; but while doing this, the “Rocket”
-struck him and he fell, his leg being doubled over the
-rail and immediately crushed. Unfortunately he died
-that evening at Eccles Parsonage.</p>
-
-<p>This sad event cast a gloom over the otherwise
-rejoicing day; but the wonderful speed at which the
-wounded man was conveyed, proved a marvellous object
-lesson as to what the locomotive could accomplish.</p>
-
-<p><span class="pagenum"><a id="Page_38"></a>[38]</span></p>
-
-<p>In the “Planet,” put upon the line shortly after the
-opening, the cylinders were placed horizontally and
-within the fire box. The engine drew eighty tons from
-Liverpool to Manchester against a strong wind in two
-and a-half hours, while on another occasion with a
-company of voters, it sped from Manchester to Liverpool,
-thirty-one miles, in an hour. But next year the
-“Samson,” which was still further improved, and the
-wheels of which were coupled so as to secure greater
-grip on the rails, hauled 150 tons at twenty miles an
-hour with a smaller consumption of fuel.</p>
-
-<p>The locomotive had now become one of the wonders
-of the world. Since then its speed has been doubled.
-But all the improvements (with possibly one exception—that
-of the compound cylinder which is at present
-only partially in use) have been more in details than in
-principles. Thus the 70 or 80 ton express engine,
-which covers mile after mile at the rate of a mile a
-minute without a wheeze or a groan, is not very
-different essentially from George Stephenson’s locomotives,
-though its steam pressure is very much
-higher.</p>
-
-<p>There are, for instance, the multitubular boiler, the
-furnace surrounded by water and communicating with
-the boiler, the horizontal cylinders acting directly on
-the driving wheels, and the steam-blast by which
-the waste steam is spouted up the chimney, creating
-a draught in the furnace.</p>
-
-<p>These may be regarded as the more important of the
-essential principles, although there is diversity of details,
-more especially for the different work required. But
-the steam pressure is now much greater. Let us glance
-at a typical English locomotive. You might not think
-it, but the machine has about five thousand different
-parts, all put together as Robert Stephenson said “as
-carefully as a watch.”</p>
-
-<p>At first sight you will probably not see the cylinders.
-The tendency in many engines now seems to be to place
-them inside the wheels, for it is urged that the placing<span class="pagenum"><a id="Page_39"></a>[39]</span>
-of the heavier parts of the mechanism near to the
-centre lessens oscillation, and protects the machinery
-more effectually. Against this, it is said that the placing
-of the cylinders in that position increases the cost
-and the complication of the driving axle, and renders
-the pistons and valves more inaccessible for the purposes
-of repair. Both forms have their advocates, and
-the outside-cylinder form may be seen on the London
-and South-Western and some other railways, while the
-inside may be seen on the North-Western and others.</p>
-
-<p>The boiler is of course the long, round body of the
-locomotive, and in English machines it is placed on
-a strong plate frame. Then as to the driving-wheels.
-Express engines, such as the splendid “eight-feet
-singles” of the Great Northern, have often, as the
-name implies, but one large driving-wheel on either
-side, and for great speeds this form is held to possess
-certain advantages. Certainly the performances of
-Mr. Patrick Stirling’s expresses would indicate that
-this is the case.</p>
-
-<p>With steam raising the safety valve at a pressure
-of 140 lbs. to the square inch, the engines will whisk
-a score of carriages out of King’s Cross up the northern
-height of London at forty miles an hour, and then without
-a stop rush on to Grantham at near sixty. Standing
-on the platform at King’s Cross, with a large part
-of the immense driving-wheel hidden below you as
-it rests on the rail, you do not realise its tremendous
-size. Yet, let the engine-driver open the throttle, as
-it is called—that is, turn on the steam to the cylinders—and
-that huge wheel will revolve, and with its neighbour
-on the other side, haul after them that heavy
-train of carriages, and, gathering speed as they go, they
-will soon be rushing up the incline at forty miles an
-hour, and then on at sixty. It is a marvel of
-mechanism!</p>
-
-<p>But then the compound engines that Mr. F. W.
-Webb, the engineer of the North-Western, builds for
-that Company can also perform remarkable things.<span class="pagenum"><a id="Page_40"></a>[40]</span>
-The compound is the great modern improvement
-(some engineers might doubt whether improvement
-be the correct word) in the locomotive, effecting,
-it is said, an economy of from ten to fifteen per
-cent. in fuel. Now the compounding principle has
-been developed to such an extent in marine steam
-engines that it revolutionised steam navigation. But
-the application of the principle has not been so great
-in the case of the locomotive.</p>
-
-<p>Briefly, the principle is this—the steam is sent out
-from the boiler at a high pressure, say 160 to 180
-lbs. to the square inch, and is used in one or
-in a pair of high-pressure cylinders, and then used
-again, by means of its expanding power, in a larger,
-low-pressure cylinder. Mr. John Nicholson, of the
-Great Eastern Railway, suggested a compound locomotive
-before even the compound marine engine had
-been made, and his design was successful; but in 1881
-Mr. Webb, of the North-Western, patented a compound
-locomotive, with two small high-pressure, and one large
-low-pressure cylinders, the latter twenty-six inches in
-diameter. Placed between the front wheels, the bright
-boss of this cylinder may be seen in shining steel as it
-flies over the rails.</p>
-
-<p>The argument is that the compound burns less fuel
-and is more powerful than a non-compound of the same
-weight; but against this is launched the objection that
-the compound is more expensive to build, to repair, and
-to maintain. Still further it is argued, that a fast-speeding
-locomotive has not the time in its hurrying
-life to expand its steam in the tick of time between
-each stroke of the piston.<span class="pagenum"><a id="Page_41"></a>[41]</span></p>
-
-<div class="figcenter">
-<a id="i_041"><img src="images/i_041.jpg" alt="" width="650" height="338" /></a>
-<p class="caption center">THE COMPOUND LOCOMOTIVE “GREATER BRITAIN.”</p>
-<p class="caption center"><em>By kind permission of Mr. F. W. Webb, L. &amp; N. W. Railway.</em></p>
-</div>
-
-<p>Mr. Worsdell’s compounds on the North-Eastern<span class="pagenum"><a id="Page_42"></a>[42]</span>
-Railway have but two cylinders, one high and the
-other low-pressure. The one is eighteen and the other
-twenty-six inches across. Instead of the steam alternating
-between the two cylinders, it all passes first
-to the high-pressure and then, through a pipe in the
-smoke-box, to the larger low-pressure cylinder. These
-<span class="pagenum"><a id="Page_43"></a>[43]</span>locomotives, it is said, are not under the objection
-alleged against the other compounds—viz., that they
-have more parts, and are more costly to build and
-maintain. Yet it is claimed for them that they are
-more economical and more powerful than non-compounds.</p>
-
-<p>When doctors disagree who shall decide? The cost
-or speed might decide; but at present it seems doubtful
-on which side the balance does really fall. Engines
-of the three types have done splendid work. A Worsdell
-compound, built by Mr. Worsdell, of the North-Eastern
-Railway, is reported to have rushed down the
-incline to Berwick one day at seventy-six miles an
-hour for some miles at a time. Then the “Greater
-Britain,” a massive North-Western compound engine,
-turned out at the Crewe works in 1891, and weighing
-seventy-five tons, can whirl along with ease a heavy
-twenty-five coach express at an average of over fifty
-miles an hour, with a comparatively small consumption
-of fuel.</p>
-
-<p>This locomotive was described in the <cite>Engineer</cite> newspaper
-as the most remarkable that had been built in
-England for several years. Its axle bearings are of
-great length, and its parts are very substantial, so
-that it ought to keep out of the repairing shops for
-long spells of time. It was specially planned for both
-fast and heavy passenger traffic to Scotland, and its
-work on its trial trip was so good that it was confidently
-expected it would answer expectations. In
-working, the engine has been found to develop great
-speed and power, easily running at over fifty miles an
-hour with what is called a double train—viz., twenty-five
-coaches, behind it. Indeed, it has run at fifty-five
-miles with this heavy train. Its stated speed
-ranges from thirty to fifty-five miles an hour, with
-a low consumption of fuel.</p>
-
-<p>This last is a matter of very great importance to
-engineers and railway directors; and when we state
-that, according to Mr. Bowen Cooke, the North-Western<span class="pagenum"><a id="Page_44"></a>[44]</span>
-engines altogether burn 3095 tons of coal per day, any
-small saving per hour would be eagerly welcomed.</p>
-
-<p>Now, it is claimed that the compounds have consumed
-about six pounds of coal per mile less than others on the
-same work, and that they also haul along loads which
-would require two of the other type. If so, the saving
-in the North-Western coal-bill must be enormous.</p>
-
-<div class="figcenter">
-<a id="i_044"><img src="images/i_044.jpg" alt="" width="650" height="525" /></a>
-<p class="caption center">BACK AND FRONT VIEW OF THE LOCOMOTIVE “GREATER BRITAIN.”</p></div>
-
-<p>A great feature in this engine is a combustion
-chamber placed within the barrel of the boiler. This
-chamber catches all the gases from the furnace, and
-causes the heat generated by them to be used to the
-utmost for the production of steam. Though heavier
-than any engine previously built, yet it is so made that
-no greater weight than usual rests upon any of the<span class="pagenum"><a id="Page_45"></a>[45]</span>
-wheels, thus throwing no extra strain on the railway or
-the bridges. The two couples of driving-wheels are
-placed before the furnace, and an additional couple of
-small wheels behind the furnace, and beneath the foot-plate
-where the driver and fireman stand. The weight
-therefore is evenly distributed, with another pair of
-wheels to bear the burden. The front wheels are fitted
-with the radial axle-box patented by Mr. Webb, so
-that, although the engine is of great length, yet it can
-speed round curves with perfect safety.</p>
-
-<p>Yet this engine, though one of the most remarkable
-developments of the locomotive, is in essence and in
-principle but very like the “Rocket.” The difference lies
-in its innumerable details, exhibiting so much engineering
-skill and ingenuity, in the compound cylinders, in
-higher pressure steam, and in its marvellous power and
-speed combined.</p>
-
-<p>On the other hand, the Great Northern runs daily
-from Grantham to London at fifty-three and fifty-four
-miles an hour average; while it was reported in the
-<cite>Engineer</cite> of the 10th of March, 1888, that a Great
-Northern train from Manchester to London, when running
-from Grantham to London, covered one mile in
-forty-six seconds, that is, at the rate of seventy-eight
-and a-quarter miles an hour, and two miles following
-each other were run in forty-seven seconds each, that
-is, seventy-six miles an hour. We doubt, indeed, if any
-railway in the world can show regular faster daily running
-than some of the Great Northern expresses between
-London and Grantham. The average speed of
-their Manchester train over this ground is slightly
-over fifty-four miles an hour. Then there are the
-Great Western expresses, the “Dutchman” and the
-“Zulu,” at only slightly less speeds, to say nothing of
-the fine performances of the Midland. We may take
-it, therefore, that the compound locomotives, excellent
-as their work has been, have not really beaten their
-rivals in point of speed.</p>
-
-<p>Compounds are used largely on the North-Western,<span class="pagenum"><a id="Page_46"></a>[46]</span>
-the Great Eastern, and the North-Eastern, and should
-they prove to be really more economical in working,
-while maintaining at least equal power and speed with
-their rivals, we have no doubt but that they will
-prevail.</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_V">CHAPTER V.</h2>
-</div>
-
-<p class="center">A MILE A MINUTE.</p>
-
-
-<p class="drop-cap"><span class="smcap">“The</span> express is to be quickened, my lord. Mr.
-Thompson, the general manager, has given
-instructions to that effect.”</p>
-
-<p>So spoke the station master at Carlisle, on
-the 17th of March, 1894, to Lord Rosebery.</p>
-
-<p>His lordship had very recently been appointed Prime
-Minister, and was on his way to Edinburgh to deliver
-a great public speech. The train, presumably, was
-late, or he, through stress of business probably, had
-left too little margin of time. However, by the
-instructions of Mr. Thompson, the general manager of
-the Caledonian Railway, the express was accelerated,
-and it rushed over 101 miles in 105 minutes, one of
-the quickest locomotive runs, we imagine, that have
-ever been recorded. The train arrived fifteen minutes
-before it was due, and Lord Rosebery was enabled to
-keep his engagement.</p>
-
-<p>This run was approximately at the rate of a mile a
-minute, and maintained for an hour and three-quarters.
-Only some two years or so previously a somewhat similar
-run was made. An officer of the Guards found that
-he had lost the south-going mail train at Stirling. He
-had been on leave in Scotland, and was bound to
-report himself in London next morning.</p>
-
-<p>What was he to do? Did he sit down and moan, or
-fly to the telegraph office and endeavour to excuse
-himself? Not he. He promptly engaged a special<span class="pagenum"><a id="Page_47"></a>[47]</span>
-train, which flying over the metals, actually caught
-the mail at Carlisle, having covered 118 miles in 126
-minutes; that is, again, approximately a mile a minute,
-and maintained for slightly over two hours.</p>
-
-<p>Now, in order to attain high average speed, some
-parts of the journey, say very easy inclines or levels,
-must be covered at a much higher rate. Thus, to
-obtain an average of fifty-two miles an hour—which is
-probably the regular average of our best English
-expresses—the pace will most likely be sometimes at
-the rate of seventy, or it may be seventy-six, miles per
-hour.</p>
-
-<p>The United States have claimed to run the fastest
-regular train. This is the “Empire State Express”
-of the New York Central, which bursts away from New
-York to Buffalo, a trip of 140 miles, at the average
-rate of 52-12/100 miles per hour, but running eighty
-miles at the rate of 56¾ miles an hour. It is also
-said that, in August, 1891, a train on the New York
-portion of the Reading road ran a mile in less than
-forty seconds, and covered a dozen miles at an average
-of barely 43½ seconds per mile.</p>
-
-<p>English expresses could certainly accomplish these
-average speeds, but the fact is very high speeds do not
-pay. They wear everything to pieces. Then there is
-the coal consumption. American railway engineers—according
-to the <cite>Engineer</cite> newspaper—“seem to be
-unable to get on with less than 100 lbs. per square foot
-(of fire grate area) as a minimum;” while, from the
-same paper, we learn that the average rate of burning
-of Mr. Webb’s remarkable North-Western engine, the
-“Greater Britain,” was but “a little over seventy-three
-lbs. per square foot per hour,” or, altogether, 1500 lbs.
-per hour.</p>
-
-<p>The rails also are greatly worn by continuous high
-speeds. Engineers have been equal to this difficulty,
-and rails are now made of steel, and even steel sleepers
-are constructed on which the rails repose. But still
-the wear and tear, especially to engines, of continuous<span class="pagenum"><a id="Page_48"></a>[48]</span>
-high speeds, is very great. The reason why the famous
-“Race to Edinburgh” was stopped was doubtless
-because of the needless wear and tear. Surely an
-average of fifty to fifty-two miles an hour is fast
-enough for all ordinary purposes. If greater speed
-can be obtained without too great a cost, well and
-good; but if not, the public must be content.</p>
-
-<p>Nevertheless, during that famous “Race” in the
-summer of 1888, some magnificent engine work was
-accomplished. Thus, for instance, the North-Western
-and their partners actually ran from Euston to Edinburgh,
-400 miles, in 427 minutes. Then the Great
-Northern and their partners, the East Coast route,
-next day covered 393 miles in 423 minutes, this journey
-including 124½ miles from Newcastle to Edinburgh
-covered in 123 minutes. This speed is, of course, more
-than a mile a minute, and kept up for slightly over two
-hours.</p>
-
-<p>The third-class passenger was at the root of the
-matter. Companies are finding out they must consult
-his convenience; and the beginning of the “Race” was
-probably the announcement that the “Flying Scotchman”—the
-10 o’clock morning train from King’s
-Cross—would carry third-class passengers. Hitherto it
-had beaten its rival, the West Coast route (run by the
-North-Western and its partner, the Caledonian), as to
-speed, but had conveyed only first and second-class
-passengers.</p>
-
-<p>Thereupon the West Coast announced that they
-would reach Edinburgh in nine hours. As this route
-is harder for engines—for it climbs the Cumbrian
-Hills, and is, moreover, seven miles longer—this would
-mean faster running and harder work than its rivals.
-The Great Northern, which according to its well-deserved
-reputation probably tops the world for speed,
-could not brook this, so the East Coast route reduced
-its time from nine hours to eight hours and a-half.</p>
-
-<p>So the contest stood for about a month, when the
-West Coast calmly announced the same time for its<span class="pagenum"><a id="Page_49"></a>[49]</span>
-journey. Thenceforward the blows fell thick and fast.
-It was a battle of giants, but fought with good temper
-and gentlemanly honour on both sides.</p>
-
-<p>The West Coast were arriving at Edinburgh at half-past
-six. “The Flying Scotchman,” by the East Coast
-route, thereupon drew up in the Scotch capital at six
-o’clock. Then the West Coast ran to Edinburgh in
-eight hours, stretching away from Euston to Crewe,
-158½ miles in 178 minutes, without a stop—probably
-the longest run without a break ever made. The
-Caledonian Company, the North-Western’s partner,
-then ran from Carlisle to Edinburgh, 100¾ miles, in
-104 minutes. The North-Western thereupon actually
-ran from Preston to Carlisle, over the Cumberland
-Hills, ninety miles in ninety minutes—a magnificent
-performance hard indeed to beat, if, in fact, it ever
-has been really beaten; while, later on, the same
-Company ran from Euston to Crewe in 167 minutes
-instead of their remarkable 178 minutes a few days
-previously. This, with the other accelerations, gave
-the West Coast their record run of 400 miles in 427
-minutes of running time, which took place on the 13th of
-August. But the East Coast had also accelerated, the
-North-Eastern covering 205 miles in 235 minutes, and
-the Great Northern rendering an equally good, if not
-better, performance, the whole 393 miles being covered
-in 423 minutes. Some of the miles on the East Coast
-route sped by at the rate of seventy-six an hour.</p>
-
-<p>To accomplish these runs the weight of trains was
-cut down, and the times of stoppages reduced or
-abolished altogether. But the expense was too great.
-It did not really “pay” in convenience or in money,
-and to these judgments companies must bow. But
-considering that the Great Northern reaches Grantham,
-105¼ miles, in 115 minutes as a daily occurrence, an
-approximate running of near a mile a minute, and
-that the North-Western can run at an average of
-fifty-five miles an hour, the locomotive has amply
-justified George Stephenson’s prophecy when he made<span class="pagenum"><a id="Page_50"></a>[50]</span>
-“Blucher,” that there was no limit to the speed of
-the locomotive, provided the work could be made to
-stand.</p>
-
-<p>Mr. C. R. Deacon also prophesied a few years since
-in an American magazine that a hundred miles an hour
-would be the express speed of the future, provided that
-passengers would give up luxurious cars and dining and
-sleeping carriages. At present it seems questionable if
-they will do so.</p>
-
-<div class="figcenter">
-<a id="i_050"><img src="images/i_050.jpg" alt="" width="650" height="392" /></a>
-<p class="caption center">THE “FLYING DUTCHMAN.”</p></div>
-
-<p>But speed is by no means the monopoly of the North.
-Other companies beside the owners of the East and
-West Coast routes to Scotland can run expresses equally
-or almost as fast. There is the “Flying Dutchman,” for
-instance, of the Great Western. It daily covers the 77¼
-miles from London to Swindon in 87 minutes. And
-the tale is told by Mr. W. M. Acworth, on the authority
-of an inspector who was in charge of the train, that a
-famous Great Western engine, the “Lord of the Isles,”
-which was in the Exhibition of 1851, actually whirled
-a train from Swindon to London, 77¼ miles in 72
-minutes.</p>
-
-<p><span class="pagenum"><a id="Page_51"></a>[51]</span></p>
-
-<p>Some of those older engines could run bravely. Mr.
-Acworth reports that “a Bristol and Exeter tank-engine
-with 9 feet driving wheels, a long extinct
-species,” pelted down a steep incline at the speed of
-80 miles an hour, many years since, and it has never
-been surpassed. The fastest speed during the Race to
-Edinburgh days seems to have been 76 miles, but perhaps
-the weight of the trains may have accounted for
-this. Mr. Acworth himself is believed to have accomplished
-the fastest bit of advertised journeying in the
-world. He went down on the “Dutchman,” and leaving
-Paddington at 11.46, he caught the return train at
-Swindon and was back at 2.45, having covered 154½
-miles, with five minutes for refreshments, in 177
-minutes. The line is easier on the up journey to
-London, and mile after mile sped by at a rate of over
-60 miles an hour. From 56½ to 58 seconds was the
-chronograph’s record again and again, while on the
-down journey to Swindon he records a burst of 34½
-miles in 34 minutes.</p>
-
-<p>The gradients of the railway form of course a most
-important factor in the question of speed. The Midland
-has one of the hardest roads in England for steep
-slopes, yet its magnificent engines bring its heavy
-trains from Leicester, 99¾ miles in 122 minutes. Considering
-the high levels the locomotives have to climb,
-only to sink again to low flats, as about the Ouse at
-Bedford, this performance is really as fine as some of
-the superb running of the Great Northern.</p>
-
-<p>The Southern lines out of London have no long
-distances to cover as the Northern, unless it may be
-the South-Western to Plymouth. The South-Western
-to Bournemouth and Exeter, and the mail trains on the
-South-Eastern, Chatham and Dover, and the Brighton
-trains can also show some excellent work as regards
-speed.</p>
-
-<p>The government of a large railway now has grown
-to something like the rule of a small state. Sir George
-Findlay, the general manager of the North-Western<span class="pagenum"><a id="Page_52"></a>[52]</span>
-Company, in his evidence before the Labour Commission
-in 1892, deposed that the capital raised for
-British railways amounted to the vast sum of 897
-millions of pounds; that the receipts were 80 millions
-yearly, that much more than half of this immense
-amount, namely 43 millions, yearly was paid in wages,
-and that half-a-million of men directly or indirectly
-were given employment.</p>
-
-<p>To such enormous dimensions has the railway developed.
-And the locomotive engine is the centre and
-soul of it all. Stephenson got it, so to speak, on its
-right lines of working, and it has run along them ever
-since, until in its great capacity for speed, its power for
-drawing heavy loads, and its strength and beauty of
-construction it may fairly be called one of the wonders
-of the world.</p>
-
-<div class="figcenter">
-<a id="i_052"><img src="images/i_052.jpg" alt="an engine on tracks" width="300" height="227" /></a>
-</div>
-
-<hr class="chap2 x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_53"></a>[53]</span></p>
-
-
-<div class="figcenter">
-<a id="i_053"><img src="images/i_053.jpg" alt="a steamship" width="500" height="232" /></a>
-</div>
-
-<p class="p140"><span class="smcap">The Story of the Steamship.</span></p>
-
-<hr class="r5 x-ebookmaker-drop" />
-
-<h2 class="nobreak" id="CHAPTER_I-2">CHAPTER I.</h2>
-</div>
-<p class="center">THE “COMET” APPEARS.</p>
-
-
-<p class="drop-cap"><span class="smcap">“If</span> only people could reach the place easier, I could
-do more business.”</p>
-
-<p>So mused Henry Bell of Glasgow about the
-year 1810. He was an ingenious and enterprising
-man, and he had established a hotel or bathing-house
-at Helensburgh on the Clyde. But he wanted
-more visitors, and he puzzled his brain to discover how
-he could offer facilities for them to reach the place.</p>
-
-<p>He tried boats, worked by paddles, propelled by
-hand; but these proved a failure. They had been in
-use years before, though perhaps he knew it not. Tradition
-says that boats fitted with paddle wheels and
-worked by oxen in the boat, were known to the
-Egyptians, but perhaps tradition is wrong. The
-Romans and the Chinese also are said to have known
-wheel boats, the wheels worked by men or by animals—in
-the case of the Chinese apparently by men alone.
-A similar kind of boat appears to have been tried on
-the Thames in the seventeenth century; but whether
-Bell knew of these things or not, his experiments of<span class="pagenum"><a id="Page_54"></a>[54]</span>
-the same kind did not answer. What was to be
-done?</p>
-
-<p>He determined to build a steamboat. At first sight
-there does not seem to be much connection between
-baths and steamboats, but apparently it was the
-ownership of the one which led Henry Bell to build
-the other, and to become the first man in Great Britain
-who used a steamboat for what may be called public
-and commercial purposes.</p>
-
-<p>She was a queer craft. Her funnel was bent and
-was used also as a mast, and she poured forth quantities
-of thick smoke. But she was successful, and laboured
-along at the rate of five miles an hour. Up and down
-the river she plied, and whatever else she did, or did
-not, she made the good folk of those days understand
-that steam could be applied to navigation.</p>
-
-<p>She was called the <em>Comet</em>, not because, even in the
-opinion of her owner, she resembled a blazing meteor,
-but because, to use Bell’s own words, “she was built
-and finished the same year that a comet appeared in
-the north-west part of Scotland.”</p>
-
-<p>“Whatever made you think of starting a steamship?”
-we can imagine a friend asking him as they stood on
-the bank and watched the <em>Comet</em> with her paddles
-shaped like malt shovels, splashing up the water.</p>
-
-<p>“Partly it was Miller’s experiments, and partly it was
-a letter from Fulton. You know, Fulton has put the
-<em>Clermont</em> successfully on American waters. He had been
-over here talking with Symington, who had a steamer on
-the Forth and Clyde Canal you remember, and he wrote to
-me also asking about machinery and requesting me to
-inquire about Miller’s boats, and send him drawings.”</p>
-
-<p>“And did you?”</p>
-
-<p>“Oh ay, I did; but when he replied afterwards that
-he had made a steamboat from the drawings though
-requiring some improvements, I thought how absurd it
-was to send my opinions to other countries and not put
-them into practice in our own.”</p>
-
-<p>“So you made the <em>Comet</em>?”</p>
-
-<p><span class="pagenum"><a id="Page_55"></a>[55]</span></p>
-
-<p>“Well, I made a number of models before I was
-satisfied; but when I was convinced the idea would
-work, I made a contract with John Wood &amp; Co., of
-Port-Glasgow, and they built me this boat, which I
-fitted up with engine and paddles, as you see. John
-Robertson actually set up the engine. We will go
-aboard presently, and you shall see her.”</p>
-
-<div class="figcenter">
-<a id="i_055"><img src="images/i_055.jpg" alt="" width="600" height="522" /></a>
-<p class="caption center">BELL’S “COMET.”</p></div>
-
-<p>They did so, and this is something of what they saw.
-They found a small vessel, forty feet long and ten and
-a-half wide, and only about twenty-five tons burthen.
-The furnace was bricked round, and the boiler, instead
-of being in the centre, was seated on one side of the
-ship, with the engine beside it. But the funnel was
-bent and rose aloft in the middle, and it answered the
-purpose of a mast—to carry sail.</p>
-
-<p><span class="pagenum"><a id="Page_56"></a>[56]</span></p>
-
-<p>“But look at the machinery,” we can imagine Bell
-saying to his friend. “We have one single cylinder,
-you see. The piston is attached to a crank on an axle.
-This axle carries a big cog wheel, which, working two
-more placed on the paddle axles, causes them to
-revolve.”</p>
-
-<p>“And the paddles?”</p>
-
-<p>“Well, you see, we have now two sets on each side,
-and each paddle is shaped something like a malt
-shovel; but I think I shall alter them, and have paddle
-wheels soon.”</p>
-
-<p>Bell carried out his improvement, and in a short
-time he did adopt the better form of paddle wheel.
-The improved <em>Comet</em>, with a new engine, attained
-six or seven miles an hour. But before this, Mr.
-Hutchison, a brewer, built another boat, bigger than the
-<em>Comet</em>, and her engine was of ten horse-power, while
-the <em>Comet’s</em> was but three. She travelled at an
-average of nine miles an hour, and her fares were but
-a-third of those charged by coach.</p>
-
-<p>The news of the steamers on the Clyde became noised
-abroad, and steamboats began to appear on other British
-rivers. The success of the new venture became
-assured.</p>
-
-<p>But how had it been brought about? Bell had
-referred to the labours of others, and, indeed, his was
-not the first steamboat, though, doubtless, it was the
-first in Britain to ply for passengers.</p>
-
-<p>The truth is, that as with the locomotive, several
-minds were working towards the same object. And
-among those early steamboat seekers Patrick Miller, of
-Dalswinton, and William Symington, of Wanlockhead
-Mines, are entitled to high place.</p>
-
-<p>Indeed, Symington is said to have built the “first
-practically successful steamboat” in the world. She
-was called the <em>Charlotte Dundas</em>, and, in 1802, she
-tugged two barges, together of about 140 tons, nineteen
-and a-half miles, in six hours, with a strong wind
-against her.</p>
-
-<p><span class="pagenum"><a id="Page_57"></a>[57]</span></p>
-
-<p>She was built under the patronage of Lord Dundas,
-and was intended to be used for towing on the Forth
-and Clyde Canal, but the proprietors of the canal would
-not adopt this new method of propulsion; they feared
-that the wash from the wheels would damage the canal
-banks. So the <em>Charlotte Dundas</em>, successful though
-she was to a certain extent, had to be beached and
-broken up. But Fulton and Bell both inspected her,
-and we may infer that what they saw, influenced their
-subsequent action.</p>
-
-<p>The engine of the <em>Charlotte Dundas</em> was of the
-“double action” character, introduced by Watt, and it
-turned a crank in the paddle wheel shaft. The wheel
-was placed at the stern; and boats with their wheels
-thus placed are still made for use in particular places.
-Thus Messrs. Yarrow built one in 1892, to voyage in
-the shallow rivers and lagoons on the west coast of
-Africa; the idea being that a screw-propeller would
-have been likely to become fouled with weeds.</p>
-
-<p>The <em>Charlotte Dundas</em>, we say, has been regarded as
-the “first practically successful steamboat ever built.”
-No doubt it was so, and the credit must be largely given
-to William Symington. But his success, and that which
-crowned the labours of others, were rendered possible
-by the inventions and improvements of James Watt.</p>
-
-<p>Others had experimented before Symington. Thus,
-if royal records in Spain may be trusted, a certain
-Blasco de Garay exhibited a steam vessel, in 1543,
-at Barcelona. He placed a large cauldron of boiling
-water in the ship, and a wheel on each side. Certain
-opinions concerning it were favourable, and Blasco was
-rewarded; but the invention was kept secret, and
-appears to have died.</p>
-
-<p>Then, in 1655, the Marquis of Worcester is said to
-have invented something like navigation by steam.
-Later on, Jonathan Hulls took out a patent for a
-paddle steam vessel in 1736; and among others, in
-England, France, and America, the Marquis de Jouffroy
-made a steamer which was tried at Lyons, in 1783.<span class="pagenum"><a id="Page_58"></a>[58]</span>
-Then, in 1787, Patrick Miller is said to have patented
-paddle wheels in Britain.</p>
-
-<p>Miller was a retired gentleman at Dalswinton, in
-Dumfriesshire, who took much interest in mechanical
-affairs. He experimented with paddle wheels, and he
-also endeavoured to improve naval building. At first
-the wheels appear to have been turned by men, and
-there came a day when a double boat of Miller’s,
-worked by a couple of wheels with two men to turn
-each wheel, sailed with a Custom House boat, and the
-need of more efficient motive power to revolve the
-wheels became very marked. Then the idea of steam
-navigation was born, or re-born.</p>
-
-<p>There was a gentleman named Taylor, living with
-Miller, as tutor to his sons, and he often took part in
-the experiments with the boats. It is said that Taylor
-suggested the use of steam to propel the vessel, and
-that Miller doubted its practicability. However, he
-decided, at length, to try it, and in those summer days
-of 1787 the subject was much talked of at Dalswinton.
-Taylor mentioned the matter to Symington, who, it
-seems, was a friend of his, but it is not quite clear
-whether he had himself thought of this use of steam.
-However, in October, 1788, the experiment was tried on
-Dalswinton lake.</p>
-
-<p>A boy was there who afterwards became Lord
-Brougham, and Robert Burns was also there; and, no
-doubt, the experiment was watched with much interest.</p>
-
-<p>It appears to have been successful, and next year a
-bigger boat was tried on the Forth and Clyde Canal,
-again with some success. But whether Mr. Miller
-thought he had now spent enough money on these
-experiments—and Carlyle says Miller “spent his life
-and his estate on that adventure, and died <em>quasi</em>-bankrupt
-and broken-hearted”—or whether he was
-satisfied with the results attained, he abandoned all
-further effort. Possibly he did not see any opportunity
-of utilising the invention further. At all events, the
-development of the steamboat made practically no progress<span class="pagenum"><a id="Page_59"></a>[59]</span>
-until Symington commenced his experiments
-under Lord Dundas.</p>
-
-<p>Russell is of opinion that the invention of steam
-navigation was the joint production of these three men.
-“The creation of the steamship,” says he, “appears to
-have been an achievement too gigantic for any single
-man. It was produced by one of those happy combinations
-in which individuals are but tools, working out
-each his part in a great system, of the whole of which no
-single one may have comprehended all the workings.”</p>
-
-<div class="figcenter">
-<a id="i_059"><img src="images/i_059.jpg" alt="" width="295" height="400" /></a>
-<p class="caption center">ROBERT FULTON.</p></div>
-
-<p>To these three, however, must be added Henry Bell,
-in Britain, and Robert Fulton, in America. They
-carried the great enterprise further on, to something
-like assured success.</p>
-
-<p>Miller’s boats had two hulls, and the paddle wheels<span class="pagenum"><a id="Page_60"></a>[60]</span>
-revolved between. Symington placed his wheel astern.
-Bell placed his paddles on either side.</p>
-
-<p>“Ah, she will work!” we can imagine the spectators
-saying, as they watched that strange craft, the <em>Charlotte
-Dundas</em>, with her double rudder, tugging along her
-barges.</p>
-
-<p>“Ay, she will work, but the canal folk won’t let her;
-they think the wash from the wheels will wear away
-the bank!”</p>
-
-<p>“Then I will take the idea where it won’t be so
-hindered,” said another. “We are not afraid of our river
-banks in America.”</p>
-
-<p>That man, whom we imagine said this, and who
-appears, without doubt, to have inspected the <em>Charlotte
-Dundas</em>, was Robert Fulton, who, with his companion,
-Livingstone, claim to have invented steamboats in the
-United States.</p>
-
-<p>This, then, in brief, seems to be the story. While
-bearing in mind the efforts of others, yet it would seem
-that Miller, Taylor, and Symington invented steam
-navigation, utilising improvements of Watt on the
-steam engine; but Fulton, in America, and Bell, in
-Britain, seeing something of these experiments, developed
-them to assured success.</p>
-
-<p>What were Fulton’s adventures?</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_II-2">CHAPTER II.</h2>
-</div>
-
-<p class="center">TO THE NARROW SEAS.</p>
-
-
-<p class="drop-cap"><span class="smcap">“I should</span> not like to risk my money in the
-thing.”</p>
-
-<p>“Nor I, she will never pay.”</p>
-
-<p>“I reckon she will burst up before the day is
-over.”</p>
-
-<p>“Well, she is about to start now.”<span class="pagenum"><a id="Page_61"></a>[61]</span>
-A few minutes more, and the smiles on the faces of
-the speakers changed to expressions of astonishment.
-The boat was actually “walking the waters like a thing
-of life,” and gathering speed as she drew away from the
-pier.</p>
-
-<p>“Why, stranger, this thing’s going to succeed.”</p>
-
-<p>“It does look so.”</p>
-
-<p>Still the speakers gazed, and still the vessel continued
-to glide along. And shouts and applause burst from
-the thronging crowd around. The “thing” was succeeding
-indeed.</p>
-
-<p>They were watching the trial trip of the first practically
-successful steamboat in America, the <em>Clermont</em>.
-Fulton had been successful, and together with his
-companion, Livingstone—after whose residence the
-vessel was named—had launched a satisfactory steamer
-in America, five years before the <em>Comet</em> appeared in
-Britain. Yet the <em>Clermont’s</em> engines were made in
-Britain by Boulton &amp; Watt, and men from their works
-helped in mounting the machinery.</p>
-
-<p>Colden, Fulton’s biographer, describing this trial
-trip, says:—</p>
-
-<p>“The minds of the most incredulous were changed
-in a few minutes—before the boat had made the progress
-of a quarter of a mile the greatest unbeliever
-must have been converted. The man who, while he
-looked on the expensive machine, thanked his stars
-that he had more wisdom than to waste his money on
-such idle schemes, changed the expression of his features
-as the boat moved from the wharf and gained her
-speed; his complacent smile gradually stiffened into an
-expression of wonder; the jeers of the ignorant, who
-had neither sense nor feeling enough to repress their
-contemptuous ridicule and rude jokes, were silenced for
-the moment by a vulgar astonishment, which deprived
-them of the power of utterance, till the triumph of
-genius extorted from the incredulous multitude which
-crowded the shores shouts and acclamations of congratulations
-and applause.”</p>
-
-<p><span class="pagenum"><a id="Page_62"></a>[62]</span></p>
-
-<p>The scene of the vessel’s exploit was the famous
-river Hudson, and she came to make several trips
-between New York and Albany as a passenger boat.
-She performed the journey from Albany to New York
-in thirty-two hours, and back in thirty hours; her
-average speed being five miles an hour. Steamers now
-perform the passage in about eight hours.</p>
-
-<p>The boat caused great astonishment at the time.
-Colden says she was described by some who saw her
-but indistinctly at night as “a monster moving on the
-water, defying the winds and tide, and breathing flames
-and smoke.” He states:—“She had the most terrific
-appearance from other vessels which were navigating
-the river when she was making her passage. The first
-steamboats, as others yet do, used dry pine-wood for
-fuel, which sends forth a column of ignited vapour,
-many feet above the flue, and whenever the fire is
-stirred a galaxy of sparks fly off, which, in the night,
-have an airy, brilliant, and beautiful appearance. This
-uncommon light first attracted the attention of the
-crews of other vessels. Notwithstanding the wind and
-tide were adverse to its approach, they saw, with
-astonishment, that it was rapidly coming towards them;
-and when it came so near that the noise of the machinery
-and the paddles was heard, the crews in some
-instances shrunk beneath their decks from the terrific
-sight; and others left their vessels to go on shore;
-while others, again, prostrated themselves and besought
-Providence to protect them from the approach of the
-horrible monster which was marching on the tides, and
-lighting its path by the fires which it vomited.”</p>
-
-<p>Compare this with the stately passenger boats of the
-end of the century, gliding along four or five times as
-fast, but with little noise and less smoke, and beaming
-forth brilliant electric light from every saloon window.</p>
-
-<p>The <em>Clermont</em> was 133 feet long, 18 feet wide, and
-7 feet deep. The cylinder of her engine was 24 inches
-in diameter, and her piston had a stroke of four feet;
-her paddle wheels were at first too large, or at all<span class="pagenum"><a id="Page_63"></a>[63]</span>
-events dipped too deeply in the water. When improved
-they appear to have been fifteen feet in diameter. Her
-engines were 18 horse-power, and the tonnage was but
-160.</p>
-
-<p>Fulton was busily engaged in constructing steam
-vessels until he died in 1815. One of his efforts was
-the building of a steam war vessel; and so greatly were
-his efforts esteemed that both Houses of the United
-States Legislature testified their respect for him by
-wearing mourning apparel on the occasion of his death.</p>
-
-<p>His work was developed by Mr. R. L. Stevens, whose
-father, indeed, had a steamer ready, only a few weeks
-after the success of the <em>Clermont</em>. Mr. R. L. Stevens
-came to grasp the idea that the form of the hull of
-steamships could be much improved by giving them
-fine lines instead of full round bows. Stevens, it is
-said, was able to obtain a speed of thirteen miles an
-hour; and he also, it is stated, used a different form of
-engine from that adopted by Fulton.</p>
-
-<p>The engines of those early steamboats were, as a
-rule, a sort of beam engine. The famous <em>Comet</em> was
-engined in that manner. John Robertson, who actually
-set up the <em>Comet’s</em> engines, lived to place them subsequently
-in South Kensington Museum. A beam, or
-lever, which worked on a pivot at its centre, was
-placed between the piston on one side, and the connecting
-rod—which was fastened to the crank—on the
-other. Thus, one end of the beam, or lever, was
-attached to the piston rod, and the other to the end of
-the connecting rod which drove the crank and the
-wheel.</p>
-
-<p>A development apparently of this beam-engine
-arrangement was the side-lever engine—a form of
-which marine engineers were also fond. The side
-lever seems, in fact, to have been a sort of double beam
-engine. The cylinder was placed upright, and a cross-piece
-was fixed to the end of the piston rod. From
-either end of this cross-piece a rod was connected with
-a beam or lever on either side of the machinery below.<span class="pagenum"><a id="Page_64"></a>[64]</span>
-These levers worked on pivots at their centres, and
-their other ends were joined by a cross-piece united by
-a rod to the crank-shaft above. The idea in the side-lever
-engines appears to have been to obtain equal
-strength on both sides for each paddle wheel. Marine
-engineers did not apparently at first grasp the idea of
-a direct-acting engine—that is, simply one connecting
-rod between the piston and the crank which pulled
-round the wheel; perhaps the sizes and arrangements
-of those early steamboats did not permit of this. But
-in the development of the locomotive, the direct-acting
-engine did not appear at once. In any case, even the
-first vessels of the celebrated Cunard Line were of the
-cumbrous side-lever type.</p>
-
-<p>Now, when Fulton had made his <em>Clermont</em> in 1807,
-and Bell had put his <em>Comet</em> on the Clyde, some of the
-English speaking people on both sides of the Atlantic
-began, we say, to see that there was a future before the
-new invention. In 1809, the <em>Accommodation</em> ploughed
-the waters of the great St. Lawrence, and two years
-later a steamer startled the dwellers on the mighty
-Mississippi. The <em>Elizabeth</em> also followed the <em>Comet</em> on
-the Clyde in 1813.</p>
-
-<p>She was bigger than her predecessor, but only of
-thirty-three tons; she was fifty-eight feet long, and her
-engine of ten horse-power. She was built by the
-constructors of the <em>Comet</em>, Wood &amp; Company, of Port-Glasgow,
-under the direction of Mr. Thompson, who had
-been connected with some of Bell’s experiments.</p>
-
-<p>The next step was the introduction of steamers on
-the Thames. All things gravitate to London, steamboats
-among the rest. Passing by some experiments,
-in which the names of a Mr. Dawson and a Mr.
-Lawrence appear, we find that George Dodd brought
-a steamboat from the Clyde to the Thames by sea,
-using both sails and steam, about the year 1813 or
-1814. It is said that Dawson had a steamer plying
-between London and Gravesend in 1813, and that
-Lawrence, of Bristol, after using a steamer on the<span class="pagenum"><a id="Page_65"></a>[65]</span>
-Severn brought her through the canals to the Thames,
-but was obliged to take her back because of the
-antagonism of the watermen. It is said also that
-the <em>Marjorie</em>, built by William Denny, of Dumbarton,
-was brought to the Thames about 1815 in six days
-from Grangemouth, having been purchased by some
-London merchants.</p>
-
-<p>However this may be, the name of George Dodd
-should take a high place, perhaps next to that of
-Bell, for the enterprise and effort he showed in seeking
-to establish steam vessels. His sphere was chiefly the
-Thames, though he appears to have been also animated
-with the idea of using them upon the sea. The vessel
-he brought round from the Clyde was named first the
-<em>Glasgow</em> and afterwards the <em>Thames</em>, and was of about
-seventy-five tons, with nine feet paddle-wheels, and
-some fourteen or sixteen horse-power. He had some
-rough weather in the Irish Sea, and an account of the
-voyage is given in his book on steamboats. This, presumably
-in 1813, was the first steamship voyage at sea,
-as distinguished from steamers’ voyages on rivers.</p>
-
-<p>Such great progress had the introduction of steamboats
-made in 1818, that according to Dodd there were
-in that year eighteen on the Clyde, two on the Tay,
-two at Dundee, two at Cork, two on the Tyne, two on
-the Trent, two on the Mersey, four on the Humber,
-three on the Yare, one on the Avon, the Severn, the
-Orwell, six on the Forth, and actually two intended to
-run from Dublin to Holyhead. There may have been
-more than these, but they seem at all events to be the
-chief. Apparently there were, or had been, several on
-the Thames. Two, the <em>London</em> and the <em>Richmond</em>,
-according to Dodd’s book, were plying between London
-and Twickenham, and had carried 10,000 persons in
-four months. No wonder the watermen were alarmed.</p>
-
-<p>Other vessels also had appeared on the royal river.
-The <em>Majestic</em> even had got as far as Margate, and had
-ventured across to Calais. The <em>Regent</em> had been
-burned off Whitstable, and the <em>Caledonia</em>, which had<span class="pagenum"><a id="Page_66"></a>[66]</span>
-actually two engines, had steamed across to Flushing.
-Dodd further designed a vessel which seems to have
-gone to Margate in about seven and a-half hours,
-speeding along at about ten or eleven miles an hour.
-No wonder that Bell could say—“I will venture to
-affirm that history does not afford an instance of such
-rapid improvement in commerce and civilisation as
-that which will be effected by steam vessels.” The
-<em>Richmond</em> was a little boat of 50 tons, and 17 indicated
-horse-power. She was engined by Messrs. Maudslay &amp;
-Field, of London, and presumably was the first steamer
-engined on the Thames. She ran from London to
-Richmond. In the next year Messrs. Maudslay engined
-the <em>Regent</em> of 112 tons and 42 indicated horse-power,
-and intended to ply between London and Margate;
-while, in 1817, this famous firm engined three vessels,
-including the <em>Quebec</em> of 500 tons and 100 indicated
-horse-power, intended for Quebec and Montreal. Since
-then they have engined hundreds of vessels, including
-screw-propeller ironclads of 20,000 horse-power.</p>
-
-<p>Dodd, alas, though he worked so hard for the establishment
-of the steamship, does not seem to have profited
-by his labour. Like some other ingenious men he
-unhappily fell into poverty.</p>
-
-<p>The next in order of succession, who apparently
-became the most prominent and among the most
-useful in the story of the steamship, was David Napier.
-Russell avers that from 1818 to about 1830 he “effected
-more for the improvement of steam navigation than
-any other man.” David Napier ran the <em>Rob Roy</em>, a
-steamer of 90 tons and 30 horse-power, fitted with
-his own engines, between Greenock and Belfast. It
-appears that at one of the worst seasons he sailed
-in a vessel plying between the two ports,—sometimes
-taking a week to cover the journey, afterwards made in
-nine hours by steam,—and eagerly watched the effect
-of the heaving waves on the ship as she was tossed
-by the storm. Then, assured that there was no overwhelming
-difficulty for steamers, he started the <em>Rob Roy</em>.<span class="pagenum"><a id="Page_67"></a>[67]</span>
-He also experimented upon the best shape
-of hull, and, without apparently any communication
-with Stevens across the Atlantic, came to adopt a
-wedge-shaped bow, instead of a rounded fore front
-as common in sailing ships.</p>
-
-<p>In 1819 he put the <em>Talbot</em> on the Channel between
-Dublin and Holyhead. She was built by Wood &amp;
-Company, and was one of the most perfect vessels
-of the kind then constructed. She had two engines
-of 60 horse-power combined, and was 150 tons burthen.
-She was followed by the <em>Ivanhoe</em>, and in 1821 steam vessels
-were regularly used to carry the mails.</p>
-
-<p>Gradually the length of vessels increased without the
-beam being proportionately widened. The builders of
-those early boats did not at first realise the practicability
-and usefulness of altering the form of vessels for
-steamers. David Napier altered the bow, and gradually
-the vessels were lengthened. The idea came gradually
-to be grasped that as a steamer was forced forward
-along the line of its keel, and not by a power exerted
-upon it from without and in various quarters, its form
-might advantageously be changed. Moreover, it would
-seem that the best form for steamers is also the best for
-fast sailers. Russell is of opinion “that the fastest
-schooners, cutters, smugglers, yachts, and slavers”
-approach more nearly to the form of the best steamers
-than any other class of sailing vessels. However this
-may be, the shape of a steamer as well as its machinery
-has much to do with its speed, and David Napier
-appears to have contributed largely to these results in
-Britain.</p>
-
-<p>Steamers had now sped out from the rivers into the
-narrow seas around Great Britain. The next step
-would be into the wide and open ocean. Who would
-venture to take it?</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_68"></a>[68]</span></p><h2 class="nobreak" id="CHAPTER_III-2">CHAPTER III.</h2>
-</div>
-
-<p class="center">ON THE OPEN OCEAN.</p>
-
-
-<p class="drop-cap"><span class="smcap">Why</span> should not the Great Western end at New
-York?</p>
-
-<p>That was Brunel’s idea, and it had an
-immense effect on the establishment of transatlantic
-steamships.</p>
-
-<p>Brunel was the engineer of the Great Western Railway,
-and he audaciously desired his line to end, not at
-Bristol or Penzance, but, conquering the sea, he wished
-to plant his foot in the Empire city itself.</p>
-
-<p>Still he was not the first, nor the only one, in the
-field. To the <em>Savannah</em> belongs the honour of being
-the first steamship to cross the Atlantic. Yet she was
-not altogether a steamship.</p>
-
-<p>Mr. Scarborough, of Savannah—a port of the state
-of Georgia—purchased a sailing ship of about 300 tons
-and 100 feet long, launched her at New York in 1818,
-intending her to ply between the two places, and had
-her fitted with machinery.</p>
-
-<p>Why he changed his mind and sent her to Europe,
-we cannot say. Apparently he could not trust to steam
-alone, for the paddle wheels were so constructed that
-they could be folded up on deck when not in use, and
-the shaft also was jointed for that purpose. Then in
-the following May she started forth for Liverpool—the
-precursor of a mighty fleet of magnificent ships which
-have followed since.</p>
-
-<p>She reached the Mersey in twenty-five days—vessels
-now perform the journey in about six. But she used
-steam on only eighteen days out of the twenty-five.
-Several times during the journey the paddle wheels
-were taken on deck, this operation occupying about
-half-an-hour. Possibly this was done when the wind
-was very favourable for sails, and so saved the fuel,
-which was pitch-pine.</p>
-
-<p><span class="pagenum"><a id="Page_69"></a>[69]</span></p>
-
-<p>Apparently Mr. Scarborough was not satisfied with
-the venture, for, after failing to sell the ship in Russia,
-whither she voyaged, she touched at different ports and
-returned home. The machinery was taken out, and she
-winged her way henceforth by sails alone.</p>
-
-<p>England next did something of the same kind. The
-<em>Falcon</em> steam yacht, a little vessel of 175 tons, voyaged
-to India in 1824, mostly, however, by the power of sails.
-In the next year the <em>Enterprize</em>, engined by Messrs.
-Maudslay &amp; Field, made the passage by steam to Calcutta
-from London in the net time of 103 days—ten
-being used in stoppages, and the entire voyage thus
-occupying 113 days. She was a vessel of 500 tons, 122
-feet keel, and 27 feet broad, while her engines were
-of 240 indicated power. Then the <em>Royal William</em>,
-hailing from Quebec, made the transatlantic passage in
-1831, principally by steam, in twenty-six days. In
-1835 Messrs. Willcox &amp; Anderson began to run steamships
-to Peninsular ports—an undertaking which blossomed
-out afterwards into the celebrated Peninsular
-and Oriental Steamship Company.</p>
-
-<p>Then in 1838 two steamships, the <em>Sirius</em> and the
-<em>Great Western</em>, crossed the Atlantic, the latter in fourteen
-and a-half days. Brunel had had his wish, and in
-1836 he had formed the Great Western Steamship
-Company, and the vessel of the same name had been
-commenced. Others also were in the field, notably
-Messrs. Laird of Birkenhead, and the British and American
-Steam Navigation Company was founded. The
-<em>Sirius</em>, which had been built on the Thames, was purchased
-by them and prepared for her voyage.</p>
-
-<p>The prime mover in this matter is said to have been
-Mr. Macgregor Laird. He had witnessed the work
-of steamships in the Niger Expedition of 1832-33 both
-on sea and river, and from the time of his return he
-advocated the establishment of steamships between
-Great Britain and America.</p>
-
-<p>The <em>Sirius</em> left Cork on the 5th of April, and arrived
-at New York eighteen days afterwards. She carried<span class="pagenum"><a id="Page_70"></a>[70]</span>
-seven passengers, and close at her heels followed Brunel’s
-<em>Great Western</em>, which had left Bristol three days later.
-The two ships were received with loud acclaim, a vast
-crowd of spectators beholding their arrival. The vessels
-proved beyond possibility of doubt that the transatlantic
-voyage by steamships was possible, and, at a stroke, the
-duration of the passage was reduced by almost one-half.
-It has since been reduced to less than a quarter.</p>
-
-<p>The <em>Sirius</em> made on an average about 161 miles
-a-day, or slightly less than seven miles an hour. She
-apparently, however, had been originally built for plying
-between London and Cork; while the <em>Great Western</em>,
-which had presumably been especially built for the
-transatlantic traffic, was both larger and more powerful.
-Her average speed was about 208 miles a-day, that is
-between eight and nine miles an hour; while returning,
-the speed was a little better, averaging about 213 miles
-per day. The return voyage of the <em>Sirius</em> was also
-better than her outward passage.</p>
-
-<p>The engines of the <em>Great Western</em> were side-lever,
-and were built by Messrs. Maudslay &amp; Field, of London.
-The cylinders were 73½ inches diameter, and the pistons
-had a big stroke of seven feet. The wheels’ diameter
-was no less than 28¾ feet, while the steam was generated
-in four boilers. Her tonnage was 1340—the largest
-Maudslay’s had yet engined, with 750 indicated horse-power.
-She voyaged many times across the Atlantic, her
-fastest eastward passage being 12 days, 7½ hours. The
-variation in her coal consumption was very remarkable.
-Thus, on her first voyage 655 tons were burnt, but on
-her return journey she consumed 263 tons less. No
-doubt this was owing to the greater use she was able to
-make of the wind.</p>
-
-<p>The proprietors of the two vessels soon began to
-build others. The owners of the <em>Great Western</em> laid
-down the <em>Great Britain</em>, and the proprietors of the
-<em>Sirius</em> began the <em>British Queen</em>. She had paddle
-wheels of 31 feet diameter, and her piston stroke was
-the same as the <em>Great Western</em>, 7 feet. Her engines<span class="pagenum"><a id="Page_71"></a>[71]</span>
-were 500 horse-power, and her cylinders 77½ inches in
-diameter. She was 275 feet long, 40 feet wide, and 27
-feet deep. From Portsmouth to New York she crossed
-in 14 days, 8 hours.</p>
-
-<p>Satisfactory as these results were, the pecuniary
-returns unfortunately were not so favourable. The
-<em>Great Western</em>, it is said, continued running at a loss,
-but others were withdrawn. Something seemed wanting
-to make the venture a commercial success. What
-was it?</p>
-
-<p>Meantime Willcox &amp; Anderson’s steamers plied with
-remarkable regularity to the Peninsula, and this regularity
-aroused some attention. The Government of the
-day applied to the proprietors to submit a scheme for
-carrying the mails. It seems that previously Willcox
-&amp; Anderson had proposed this, but it had come to
-nothing. The end of the matter was, however, that
-the first mail contract was signed with them, the 22nd
-of August, 1837. To carry out their bargain, Captain
-Richard Bourne and Messrs. Willcox &amp; Anderson
-founded the Peninsula Company, and three years later
-it was expanded to the Peninsular and Oriental Steam
-Navigation Company—popularly known as the P. &amp; O.—and
-incorporated by Royal Charter. The mail service
-was the keystone of the enterprise.</p>
-
-<p>The first steamer, built in 1829, was the <em>William
-Fawcett</em>, a small vessel of 206 gross tonnage, and but
-60 horse-power. In 1842 the proprietors owned the
-<em>Hindostan</em>, of 2017 gross tonnage, and 520 horse-power.
-She was a paddle-wheel vessel, and opened the Indian
-Mail Service. The commencement of this service
-marks another stage in the history of steam navigation.
-About fifty years later the Company owned about half-a-hundred
-ships, two being of 8000 horse-power and
-7000 tonnage.</p>
-
-<p>Some two years after the <em>Hindostan</em> first steamed
-to India, Brunel’s <em>Great Britain</em> was finished. She
-was a very remarkable vessel, and the wonder of her
-time. In the first place, she was built of iron, and,<span class="pagenum"><a id="Page_72"></a>[72]</span>
-secondly, she was propelled by a screw, though at first
-it was intended that she should have paddle-wheels,
-and the engines for these wheels had been partly
-made.</p>
-
-<p>Barges and light vessels had been built of iron since
-about 1790, or earlier, and the Lairds of Birkenhead,
-among others, had built an iron vessel about 1829.
-It is said that the <em>Aglaia</em> was the first iron steamer
-built on the Clyde in 1832. As for the screw-propeller,
-John Ericsson was successful with the <em>Francis B.
-Ogden</em> in 1836, and three years later Sir Francis
-Pettit Smith clearly showed, in the vessel appropriately
-called the <em>Archimedes</em>, the value and the
-feasibility of the new system.</p>
-
-<p>Brunel, therefore, ever open to improvements, combined
-these two alterations in the <em>Great Britain</em>. It
-was in 1839, probably after Sir Pettit Smith’s success,
-that the change was made as regards the screw for
-this vessel, though the paddle-wheel engines had been
-begun. The superiority of the screw-propeller over
-the paddle-wheels are said to be these:—the engines
-occupy less room, and are lighter—two very important
-considerations. Then there is greater wear and tear on
-paddle-wheels, and consequently the screw vessels are less
-expensive. But most important of all, the screw being
-deep in the water, the vessel is much more suitable for
-ocean traffic. In the heaving billows of the sea one
-wheel may be buried deep on one side of the ship, and
-the other whirling round high in the air, and not propelling
-the vessel; whereas the screw, being always
-immersed, except possibly in severe pitching, is more
-constantly efficient for the whole of the vessel.</p>
-
-<p>Nevertheless, paddle-boats have their advantages.
-They need less water to work in, are started more
-easily, and stopped sooner. Further, it is said they
-are less liable to cause sea-sickness, as they do not roll
-so much. In a word, the difference seems to be this:
-paddle vessels are better suited as passenger boats on
-the shallower waters; screw vessels for deep sea and<span class="pagenum"><a id="Page_73"></a>[73]</span>
-long distance voyages, though whether the adoption of
-twin-screws,—which it appears need not be immersed
-so deeply in the water as one screw,—will bring screw
-vessels into use on shallower waters remains to be
-seen.</p>
-
-<p>But when the <em>Great Britain</em> was being built the
-greater efficiency of the screw-propeller for ocean voyages
-was not widely understood. She was a fine vessel,
-over 320 feet long, 51 feet wide, and 32½ feet deep.
-Her screw was successful; but on her fourth voyage
-to New York she became stranded in Dundrum Bay,
-and lay aground for nearly a year.</p>
-
-<p>Incidentally, however, this catastrophe seems to have
-given great impetus to iron shipbuilding; for after
-being floated, she was discovered to have suffered but
-comparatively slight damage. She was seen in dock
-by many persons interested in shipping, and they became
-impressed with the practicability and usefulness
-of iron for shipbuilding.</p>
-
-<p>Unfortunate <em>Great Britain</em>! She passed through
-many vicissitudes. Her owners got into difficulties,
-and after some alterations, she ran to Australia, and
-at length she wheezed her way to the Falkland Islands,
-where, it is said, she served as a hulk—a sorry end to
-a successful beginning.</p>
-
-<p>The engines of the early screw vessels appear to have
-very much resembled those for paddle-wheels ships.
-Thus the <em>Rattler</em>, engined by Messrs. Maudslay for
-the Admiralty about the year 1841, had upright
-cylinders, with a crank-shaft overhead and wheels to
-give speed to the screw.</p>
-
-<p>In the meantime, however, the commercial difficulty
-of transatlantic steam traffic was being solved. The
-something lacking had been supplied. What was it?</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_74"></a>[74]</span></p><h2 class="nobreak" id="CHAPTER_IV-2">CHAPTER IV.</h2>
-</div>
-
-<p class="center">THE OCEAN RACE.</p>
-
-
-<p class="drop-cap"><span class="smcap">“This</span> is the very opportunity I have been wanting!”</p>
-
-<p>The speaker was looking at a paper setting
-forth that the British Government were open
-to consider contracts for the carrying of the letters
-by steamships between Great Britain and America.
-Encouraged, no doubt, by the success attending the
-conveyance of the mails by similar means to the Peninsula,
-the Government were now going farther afield.</p>
-
-<p>The practicability of ocean steam traffic had been
-amply demonstrated; but some of those early steamships
-did not “pay,” and to that test, after all, such
-undertakings must come. Now, the man into whose
-hands the circular had fallen was of great intelligence
-and remarkable energy. He was a merchant and
-owner of ships, and agent for the East India Company
-at Halifax, Nova Scotia. His name has since
-become known the wide world over. It was Samuel
-Cunard.</p>
-
-<p>Apparently he had cherished the idea of establishing
-transatlantic steam traffic for some years—since 1830 it
-is said—and now, here was the opportunity. The
-British Government would, of course, give a handsome
-sum for carrying the mails, and that sum would
-form a backbone to the enterprise.</p>
-
-<p>Over came Cunard to London in 1838. Mr. Melvill,
-the secretary of the East India Company, gave him
-a letter of introduction to Mr. Robert Napier, the
-eminent engineer at Glasgow. Thither then went the
-indomitable merchant, and was heartily welcomed.
-Napier knew Mr. George Burns, who was partner with
-Mr. David MacIver in a coasting trade, and the upshot
-of the matter was that capital of considerably over<span class="pagenum"><a id="Page_75"></a>[75]</span>
-a quarter of a million (£270,000) was subscribed
-through Mr. Burns’s influence.</p>
-
-<p>The first great step thus taken, Mr. Cunard made
-a good offer to the Government, and although another
-offer was made by the owners of the <em>Great Western</em>,
-Cunard got the contract, the tender being regarded as
-much more favourable. The subsidy was eventually
-£81,000 per annum. The contract was for seven years,
-and was signed by the three gentlemen mentioned—Cunard,
-Burns, and MacIver.</p>
-
-<p>These three divided the labour. Cunard ruled at
-London, MacIver at Liverpool, and Burns at Glasgow.
-Napier was to engine the new vessels. It was decided
-that their names were all to end in “ia,” and nearly
-every one of the now historic fleet has rejoiced in
-a title of that ending. There is a sailor’s superstition
-that it is unlucky if the vessels of a fleet are not named
-with some uniformity; but we doubt if the superstition
-influenced the Cunard Company. In any case, they
-broke another superstition by starting their first ship
-on a Friday! She was a mail ship, and she had to go.
-The Cunard Company meant business.</p>
-
-<p>But about their fleet. Their first order was for four
-vessels, all of about the same size and power. The
-<em>Britannia</em> was the first, and her sisters were the
-<em>Caledonia</em>, the <em>Columbia</em>, and the <em>Acadia</em>. They
-were paddle steamers, the value of the screw not
-having then been clearly and widely demonstrated,
-all of them about 207 feet long, 35⅓ feet broad,
-22½ feet deep, and 1154 tons burthen. The engines—side-lever,
-of course, in those days—were of 740
-horse-power. The boilers had return-flues, and were
-heated by a dozen furnaces.</p>
-
-<p>They would look now quite out of fashion, like a
-lady’s dress of a past age. They appeared something
-like sailing ships, with the straight funnels added.</p>
-
-<p>The <em>Britannia</em> began the service by starting from
-Liverpool on the 4th of July, 1840, and, attaining a
-speed of about 8½ knots per hour, she made the passage<span class="pagenum"><a id="Page_76"></a>[76]</span>
-to Halifax in 12 days, 10 hours, and returned in 10
-days. Her average consumption of fuel was about
-thirty-eight tons daily.</p>
-
-<p>The Bostonians gave the <em>Britannia</em> quite an ovation.
-A grand banquet, followed by speeches, celebrated the
-great occasion. But they gave even more practical
-appreciation of their favour subsequently, for when, in
-the winter season, the vessel became ice-bound in the
-harbour, they cut a seven-mile passage for her through
-the ice, at their own cost.</p>
-
-<p>The Cunarders were successful, and the conveyance
-of the mails by steamship became quite established.
-The white-winged clipper ships fought hard against the
-Cunarders, but they had to yield. Three years later
-the Company put another vessel on the route—the
-<em>Hibernia</em>—and in 1845 the <em>Cambria</em>. These were of
-greater size and developed a little better speed than
-their forerunners. It has always been the policy of the
-owners to improve their ships as they went on building,
-and even thus early that policy ruled.</p>
-
-<p>The establishment of the Cunard Company marks a
-most important step in ocean steam navigation.
-Further, in the same year, 1840, in which the
-Cunarders began to run, the Pacific Steam Navigation
-Company was established. Ten years later saw the
-foundation of the Collins and the Inman Lines. The
-Collins, an American Line, boasted that they would
-run “the Cunarders off the Atlantic.” They were very
-fine vessels, and they were the first fleet to fully
-adopt the upright stem and discard the bowsprit.
-But the Cunarders were ready for the fierce competition.
-They had actually put on six new vessels, and
-their new postal contract of 1847 had stipulated for a
-weekly, instead of a fortnightly service; while the
-subsidy was much increased. It was to be £173,340
-annually instead of £81,000.</p>
-
-<p><span class="pagenum"><a id="Page_77"></a>[77]<br /><a id="Page_78"></a>[78]</span></p>
-<div class="figcenter">
-<a id="i_077"><img src="images/i_077.jpg" alt="" width="650" height="368" /></a>
-<p class="caption center">THE ICE-BOUND “BRITANNIA” AT BOSTON.</p>
-<p class="caption center"><em>By permission of The Cunard Steamship Co.</em></p></div>
-
-<p>The echoes of that fierce struggle between the
-Cunarders’ and the Collins’ boats have now died away,
-or have been quite lost in the other clamorous cries of<span class="pagenum"><a id="Page_79"></a>[79]</span>
-that wonder of the world, the development of the
-transatlantic steamship traffic; but apparently partisanship
-ran very high. The Collins’ seem to have
-been slightly the faster vessels, coming from America
-in 9 days 17 hours, but occupying nearly two more
-days to return. Alas, disaster overtook them. The
-<em>Arctic</em> perished by collision; the <em>Pacific</em> was lost at
-sea, and no one knows the story of her death, for she
-was never heard of more. Bad management, and
-extravagance surged over the remaining vessels, and
-the fine ships went as old iron!</p>
-
-<p>But the Inman line had also begun to run, about
-1850. These ships, like the <em>Great Britain</em>, were built
-of iron and propelled by a screw. The first was the
-<em>City of Glasgow</em>, and several famous “Cities” followed;
-though years afterwards the Inman line became the
-“American,” and the appellation “City” was dropped,
-the ships being simply known as <em>Paris</em>, <em>New York</em>,
-<em>Berlin</em>, etc. The Inman line had the distinction of
-being the first, apart from the <em>Great Britain</em>, to use
-iron screw steamers regularly on the Atlantic. Other
-lines soon followed, the Anchor, the Allan, and the
-Guion, while the Cunarders, not to be beaten, came
-along in due course with iron and screw steamers.</p>
-
-<p>But great changes were at hand. To mark these
-changes let us look at what may be called the culminating
-ship of the old type of steamers—the <em>Great
-Eastern</em>.</p>
-
-<p>This historical vessel was the largest ever built. She
-was 680 feet long, by 83 feet broad, and her hull was
-60 feet high, 70 feet including bulwarks. But the
-steam pressure of her engines was only from 15 to
-25 lbs. She was fitted with both screw-propeller and
-paddle wheels. Her screw-propeller engines were of
-4000 indicated horse-power, and paddle of 2600, but
-they could together work up to 11,000 horse-power.</p>
-
-<p>Commenced at Millwall early in 1854, she was not
-launched until near upon four years later. The launching
-itself was a difficult and expensive business, costing<span class="pagenum"><a id="Page_80"></a>[80]</span>
-£60,000, and only effected after various attempts
-extending over nearly three months. The total cost of
-the vessel has been estimated at £732,000.</p>
-
-<div class="figcenter">
-<a id="i_080"><img src="images/i_080.jpg" alt="" width="432" height="600" /></a>
-<p class="caption center">ISAMBARD KINGDOM BRUNEL.</p>
-<p class="caption center"><em>By permission of Messrs. Graves &amp; Co.</em></p></div>
-
-<p>It will be seen at once that so large an outlay
-required an immense business to yield a satisfactory
-return, and indeed, financial difficulties hampered her<span class="pagenum"><a id="Page_81"></a>[81]</span>
-success almost from the very commencement, even
-before she was launched.</p>
-
-<p>She was planned, in 1852, by the great engineer,
-I. K. Brunel, and by Scott Russell. In the life of
-Brunel by his son, it is stated:—“It was, no doubt, his
-connection with the Australian Mail Company that led
-Mr. Brunel to work out into practical shape the idea of
-a great ship for the Indian or Australian service.”</p>
-
-<p>The Eastern Steam Navigation Company desired a
-vessel to trade to Australia and back, large enough to
-carry a sufficiency of coal for the outward and homeward
-journey, and yet to have space for a goodly
-number of passengers and a bulky amount of cargo.</p>
-
-<p>That was the idea, and we perhaps can hardly realise
-what a difficulty this question of coal carrying capacity
-was in those days, before the problem had been solved
-by high-pressure steam boilers, triple expansion engines,
-improved condensation, and quick passages. Even so
-great a philosopher as Dr. Lardner could not believe in
-1835 that a steamship could voyage from Liverpool to
-New York without stopping—we presume for fresh
-fuel.</p>
-
-<p>The <em>Great Eastern</em>, therefore, was planned to carry
-15,000 tons of coal; whereas now the large Atlantic
-liner <em>Paris</em> needs only 2700 tons for her Atlantic trip.
-The difference is most striking, for the <em>Paris</em> is one of
-the largest steamships afloat, but her working steam
-pressure is 150 lbs. instead of the 15 or 25 lbs. of the
-<em>Great Eastern</em>.</p>
-
-<p>This immense vessel was also planned to carry some
-5000 persons, or about 500 less if any large number
-were to require state-rooms, and finally she was to
-convey 5000 tons of cargo. The idea of water-tight
-compartments was anticipated in her case, even to the
-extent of longitudinal ones, and she had half-a-dozen
-masts of which five were of iron.</p>
-
-<p>When at length she was launched, the directors’
-minds misgave them as to an Australian trip, and they
-determined to cross the Atlantic instead, for a trial<span class="pagenum"><a id="Page_82"></a>[82]</span>
-voyage. She started on the 8th of September, 1859, but
-alas! when off Hastings some steam pipes burst.
-Several persons were killed and wounded, and the
-voyage ended at Portland.</p>
-
-<p>Next year she tried again and crossed in eleven days,
-after which she made several voyages with success—on
-one occasion conveying soldiers to Canada. Unfortunately
-for the owners, however, she did not pay.</p>
-
-<p>Then in 1865 she began to be engaged in submarine
-telegraph work, by which she will most likely be best
-remembered, and two years later she was chartered to
-convey passengers from America to Havre for the
-French Exhibition, but this scheme failed.</p>
-
-<p>Then for some years from 1869 she was successfully
-engaged in cable-laying, in the Red Sea, the Atlantic,
-and the Mediterranean, etc., after which she came down
-to be a coal hulk in 1884, stationed at Gibraltar.</p>
-
-<p>At length she was sold for £26,200 at London, by
-auction, and was on view in the Thames, and also in
-the Mersey. At this latter river her huge sides were
-used as an advertising “board” for a Liverpool business
-house. Again in November, 1888, she was sold by
-auction, this time for breaking up, and it is said that
-the total proceeds of the sale which lasted five days
-was £58,000, more than double what she had previously
-brought!</p>
-
-<p>“A ship before her time,” says some one, thinking of
-the huge vessels of the last decade of the nineteenth
-century. That is true, but the immense space required
-for coal, and her low-pressure engines, had also something
-to do with her comparative failure. The problem
-which the <em>Great Eastern</em> failed to solve has been
-met in other ways—viz., by the use of high-pressure
-steam and compound, triple-expansion and even quadruple-expansion
-engines. That is, the steam, working
-at 150 or 160 lbs. pressure, instead of the 25 lbs. of the
-<em>Great Eastern</em>, is passed through two, three, and even
-four cylinders respectively, and the economy in coal
-consumption is astounding. Thus the use of triple<span class="pagenum"><a id="Page_83"></a>[83]</span>
-expansion engines has brought the saving in coal down
-from 4 lbs. per indicated horse-power to less than 1½ lbs.</p>
-
-<p>There have been many other improvements also,
-such as the use of steel instead of iron, the parts being
-thus stronger and yet lighter; the circular tubular
-boiler enabling high-pressure steam to be economically
-produced and maintained; the use of surface condensers,
-by which the exhaust steam is quickly reduced to water
-and returned to a “hot well” ready for the boilers, to be
-speedily again raised to high pressure steam; and a
-forced draught by which the furnaces are made to roar
-furiously and heat the water in the boilers speedily.</p>
-
-<div class="figcenter">
-<a id="i_083"><img src="images/i_083.jpg" alt="" width="650" height="540" /></a>
-<p class="caption center">THE “GREAT EASTERN.”</p></div>
-
-<p>But these things were not all attained in a day.
-The introduction of the compound marine engines in
-1854-56 by John Elder, marks the first great step of the
-new departure. In 1856 he engined vessels for the<span class="pagenum"><a id="Page_84"></a>[84]</span>
-Pacific Steam Navigation Company, on the compound
-principle, which proved very satisfactory.</p>
-
-<p>Again in 1870, the appearance of the White Star
-liner <em>Oceanic</em>, marked a new development. Her yacht-like
-shape, great length, and general symmetry of form
-commenced a marked change in Atlantic liners.</p>
-
-<p>It was in 1867 that Mr. T. H. Ismay bought the
-interest of the managing owner of the White Star line—a
-set of sailing clippers, dating from the rush to the
-Australian gold diggings—and began to introduce iron
-vessels instead of wooden clipper ships. In 1869 he
-established the Oceanic Steam Navigation Company—popularly
-known as the White Star—and was later on
-joined by Mr. William Imrie. The Company was
-started with so much wisdom and boldness that the
-£1000 shares were privately taken up at once. The
-order for the new steamers was given to Harland &amp;
-Wolff, of Belfast, because, it is said, an influential share-holder
-had had satisfactory dealings with them before.</p>
-
-<p>The <em>Oceanic</em> was of 3600 tons burthen, and with
-engines of 3000 horse-power. The accommodation for
-first-class passengers was placed amidships, where the
-motion of the vessel is said to be felt the least, and
-altogether she embodied improvements which made
-her the type of many of the Atlantic passenger ships
-since. The earlier White Stars were fitted with compound
-engines, and reduced the passage to about 8½
-days.</p>
-
-<p>But when the White Stars <em>Germanic</em> and <em>Britannic</em>
-appeared in 1877, then a marked advance indeed was
-made in the Atlantic record. The <em>Britannic</em> astonished
-the world by speeding from Queenstown to New York
-in 7 days, 10 hours, and 50 minutes, and since then she
-has beaten her own record. Her sister ship <em>Germanic</em>
-also did as well, and the fierce race for the blue ribbon
-of the Atlantic may be said to have begun.</p>
-
-<p>It was even prophesied that the time across the
-water might be reduced to six days. How has that
-been fulfilled?</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_85"></a>[85]</span></p>
-
-<h2 class="nobreak" id="CHAPTER_V-2">CHAPTER V.</h2>
-</div>
-
-<p class="center">BEFORE THE FURNACE.</p>
-
-
-<p class="drop-cap"><span class="smcap">“The</span> record’s broken again, Jemmy! The White
-Star has come home a couple of hours earlier!”</p>
-
-<p>“She has, has she? Well, it will be the
-Cunard’s turn next week. It’s wonderful what
-they get out of the Cunard’s engines.”</p>
-
-<p>“They do; but I’m thinking the American’s <em>New
-York</em> will be doin’ the fastest bit.”</p>
-
-<p>“Well, well, it may be. They’re all main powerful
-vessels. Do you mind when the Guion’s <em>Alaska</em> came
-home in 6 days, 18 hours, 37 minutes?”</p>
-
-<p>“I do, and about ten years later, I suppose, some
-ships were doing it in about a day less time!”</p>
-
-<p>“Ay, ay, and I see they’re goin’ ahead down south
-too.”</p>
-
-<p>“Yes, there’s fast steaming all over the world,
-Jemmy!”</p>
-
-<p>“I told you what would happen when the compound
-engine came into use. I said, ‘Mark my words, now
-they’ve got the compound engine, they will go ahead’—and
-they have.”</p>
-
-<p>Jemmy’s prediction has been amply verified, for
-almost every year since the compound engine came
-largely into use, has witnessed a greater speed in
-ocean steamers.</p>
-
-<p>And the speed has not been obtained at sacrifice of
-comfort. On the contrary, an ocean passenger steamer
-belonging to any of the great passenger lines is something
-like a floating palace.</p>
-
-<p>After the <em>Britannic</em> and <em>Germanic</em> appeared, line
-after line put forth fine vessels; and in 1889 was
-launched the White Star steamer <em>Teutonic</em>, which for
-some time held the proud position of the fastest ship
-on the Atlantic. She had crossed in 5 days, 16 hours,
-31 minutes. The average of several trips, both for<span class="pagenum"><a id="Page_86"></a>[86]</span>
-herself and her sister <em>Majestic</em>, was 5 days, 18 hours,
-6 minutes. And they were run very close by the
-American liners, <em>Paris</em> and <em>New York</em>. These four
-vessels were among the first propelled by twin-screws.
-Engineers began to see that it was better to use great
-power in two shafts and two propellers than in one.</p>
-
-<p>In July, 1892, the fine Inman (now called American)
-liner <em>Paris</em> crossed the Atlantic in 5 days, 15 hours,
-and 58 minutes, and in October of the same year the
-same vessel steamed from Liverpool, touching as usual
-at Queenstown, in 6 days, 2 hours, and 24 minutes—including
-the time at the Irish port. This was then
-the quickest time on record for the entire journey.
-From Queenstown to Sandy Hook the time was 5
-days, 14 hours, and 24 minutes, a gain of 1 hour and
-34 minutes on her voyage in the previous July. Her
-best day’s run was 530 knots.</p>
-
-<p>The contest, therefore, between the two White Stars
-and the two Inmans has been very close, the record
-time resting now with the one and then with the
-other.</p>
-
-<p>But the Cunard Company, not to be beaten, put on
-the <em>Campania</em> in 1893, and in April of that year she
-made the fastest maiden trip then on record, one day
-indeed compassing 545 knots in the 24 hours.</p>
-
-<p>The <em>Campania</em> is 625 feet long by 65¼ feet broad,
-and 43 feet deep from the upper deck. Her gross
-tonnage is 12,950. She is fitted with a cellular double
-bottom extending fore and aft, and also with sixteen
-bulkheads, so arranged that the vessel would float even
-if two, or in some cases three, compartments were open
-to the ocean.</p>
-
-<p>She is a twin-screw vessel, fitted with two sets of
-very powerful triple-expansion engines. They are
-seated in two separate engine-rooms with a dividing
-bulkhead and water-tight doors.</p>
-
-<p>Each set of engines has five inverted cylinders—viz.,
-two high-pressure, one intermediate, and two low-pressure—all
-arranged to work on three cranks set at<span class="pagenum"><a id="Page_87"></a>[87]</span>
-an angle of 120 degrees to each other. Her indicated
-horse-power is 30,000. The boiler-rooms are doubly
-cased, the space between being fitted with nonconducting
-material for sound and heat.</p>
-
-<div class="figcenter">
-<a id="i_087"><img src="images/i_087.jpg" alt="" width="431" height="600" /></a>
-<p class="caption center">HIGH AND LOW PRESSURE CYLINDERS OF THE “CAMPANIA’S” ENGINES.</p></div>
-
-<p>In this huge vessel four decks rise tier above tier,
-beside erections on the upper deck, known as promenade
-and shade decks. These four principal decks are
-the orlop, the lowest of all, used for cargo, stores,
-and machinery; the lower, the main, and the upper<span class="pagenum"><a id="Page_88"></a>[88]</span>
-decks, the last three being devoted entirely to passengers.</p>
-
-<p>Imagine yourself on the upper deck. Before you
-stretches the long vista of its length, like some far-reaching
-walk ashore; a circuit of the vessel four
-times makes a mile. Above rises the shade deck with
-the navigating apparatus, and surrounded by the
-twenty lifeboats of the vessel; above again is the
-captain’s bridge, where are placed the telegraph and
-wheel house, while higher still is perched the crow’s
-nest or look-out box, on the foremast, and about 100
-feet from the water-level. Give a glance, too, at the
-huge funnels, 120 feet high, and so large that when in
-the builder’s yard a coach full of passengers was driven
-with four horses through one of them.</p>
-
-<p>Descending then, the grand staircase, which is sufficiently
-wide for six persons to walk down abreast, and
-admiring the polished panelling, the rich Japanese
-paper, and the lounges on the landings, we enter the
-superb dining-saloon 100 feet long by 62 feet broad.
-Four huge tables run almost along its length, with
-smaller tables in the corners, while the wood-carving,
-carpeting, gold decorated roof, costly mirrors, and
-upholstering in rich red velvet are of the most
-sumptuous description.</p>
-
-<p>From this magnificent hall you can wander on
-through other apartments of great splendour, drawing-room,
-library, smoking, music room, bath-rooms, and
-numbers of state-rooms. There are single berth, double
-berth, and three and four berth cabins—the old wooden
-benches for beds, however, being replaced by iron bed-steads
-throughout the ship. The electric light glows
-everywhere, being distributed by some fifty miles of
-wire.</p>
-
-<p><span class="pagenum"><a id="Page_89"></a>[89]<br /><a id="Page_90"></a>[90]</span></p>
-
-<div class="figcenter">
-<a id="i_089"><img src="images/i_089.jpg" alt="" width="600" height="385" /></a>
-<p class="caption center">THE “CAMPANIA.”</p>
-<p class="caption center"><em>By permission of The Cunard Steamship Co.</em></p>
-</div>
-
-<p>The second-class accommodation differs but in degree
-from the magnificence of the saloon, while the steerage
-passengers are berthed on the lower deck, but have the
-privilege of walking on the upper deck. An additional
-idea of the size of the ship may be gained when we learn
-<span class="pagenum"><a id="Page_91"></a>[91]</span>that the crew consists of over 420 persons—viz., 190
-engineers, 179 stewards, and 54 sailing hands, while the
-vessel’s full complement of passengers brings up the
-total number of persons aboard to 1600 souls—quite a
-floating town indeed.</p>
-
-<p>About five years after the birth of the <em>Teutonic</em> the
-newspapers recorded, in May, 1894, that the <em>Lucania</em>,
-sister ship to the <em>Campania</em>, and one of the newest Cunarders,
-had performed the journey across the Atlantic in
-5 days, 13 hours, and 28 minutes. Her average speed
-was 22¼ knots, or 25·7 land miles per hour, marking one
-of the quickest runs then ever recorded; and about the
-same time came the news that the P. &amp; O. steamer
-<em>Himalaya</em> had completed a mail transit from Bombay
-of 12½ days, and as her voyage to Bombay had been
-just over 13 days—the best outward passage—she had
-completed a round mail transit to Bombay and back,
-excluding stoppages, of 25½ days.</p>
-
-<p>A little later, in the same year, the torpedo-boat
-destroyer, <em>Hornet</em>, built by Messrs. Yarrow &amp; Co.,
-of Poplar, for the British Navy, achieved, it is said,
-about 27 knots; that is, roughly speaking, near to
-29 or 30 miles an hour, which speed proclaimed her
-to be then one of the fastest steamships in the world.
-She was fitted with the Yarrow water-tube boilers,
-which are both light and strong, while the consumption
-of coal was said to be remarkably small. She has
-two sets of triple-expansion inverted engines.</p>
-
-<p>Again, a short time later, Messrs. Thorneycroft, of
-Chiswick, obtained similar results with the <em>Daring</em>,
-another boat of the same kind built for the British
-Government, and fitted with the Thorneycroft improved
-water-tube boilers. These, it is claimed, will
-raise steam from cold water in fifteen minutes. She
-passed the measured mile on the Maplin at the high
-speed of 29¼ miles an hour.</p>
-
-<p>In the same summer a Company put on a fine
-steamer for service on the Thames and the English
-Channel, called <em>La Marguerite</em>, which developed, it<span class="pagenum"><a id="Page_92"></a>[92]</span>
-is said, a speed of 25 miles an hour, which would
-make her one of the fastest passenger vessels then
-afloat.</p>
-
-<p>Another Company has also a noteworthy vessel running
-on the Estuary of the Thames—viz., the <em>London
-Belle</em>, plying from London Bridge to Clacton-on-Sea.
-She is a triple-expansion paddle boat, and the first
-river steamer fitted with three crank triple-expansion
-paddle engines. She was built by Denny of Dumbarton,
-and can develop a speed of 19½ knots—<em>i.e.</em>, twenty-three
-statute miles per hour, and is worked with great
-economy of coal consumption.</p>
-
-<p>An example of a quadruple-expansion engine steamer
-may be found in the <em>Tantallon Castle</em>, one of the
-newest vessels for voyaging to South Africa. She is
-456 feet long, over 50 broad, with a gross tonnage of
-5636. She is fitted with quadruple-expansion engines
-of 7500 horse-power, and the stoke holes are well
-ventilated by large fans speeding round with great
-swiftness.</p>
-
-<p>Improvements in steamship building had gone
-steadily on; and it is safe to say that a pound of coal,
-after the compounding principle came fully into use,
-did four or five times the work it accomplished before
-high pressure engines were fully utilised.</p>
-
-<p>Let us enter the engine-room of a big liner, and
-see for ourselves. It is a triumph of engineering.
-Still, at first, you cannot understand anything of the
-complicated mass of machinery. Then you notice
-three large cylinders—for these are triple-expansion
-engines—with pistons shooting in and out downwards,
-and attached by connecting rods to the cranks of
-the propeller shaft below. The cranks are bent at
-different angles so that they can never all be in the
-same position at once. There is a maze of machinery
-and shining rods, bewildering to the uninitiated eye.
-But you gradually notice how absolutely regular every
-part is in its action, and how beautifully one part fits
-with another.</p>
-
-<p><span class="pagenum"><a id="Page_93"></a>[93]</span></p>
-
-<p>Then go before the furnace; you find yourself in front of a huge
-structure, at the bottom of which is the long fire box; above rises the
-heat box communicating with tubes over the furnaces, with the water
-circulating between. The water, indeed, is beneath the furnace, about
-parts of the heat box, between and above the tubes. The object is,
-of course, to obtain as great heating surface as possible. The tubes
-communicate with the funnel at their other end. Boilers are made of
-a “mild” steel which has, it is said, a most remarkable tenacity of
-28 tons to the square inch. Consequently they are able to bear great
-pressure of steam.</p>
-
-<div class="figcenter">
-<a id="i_093"><img src="images/i_093.jpg" alt="" width="333" height="350" /></a>
-<p class="caption center">STOKE HOLE.</p></div>
-
-<p><span class="pagenum"><a id="Page_94"></a>[94]</span></p>
-
-<p>Hot distilled water is admitted to the boiler from
-the surface condenser. This is a “box,” riddled with
-tubes, through which cold sea water is pumped. The
-waste steam, having done its work in the cylinders,
-is passed into this “box,” is condensed by touching
-the chilly tubes of sea water, and can be run off or
-pumped to a hot cistern, whence it is used to feed
-the boiler and be turned once more to steam. About
-4000 tons of water an hour pass through the surface
-condensers of a large liner when she is at full work.</p>
-
-<p>The largest steamers require over 150 men to work
-the furnaces and machinery, and the attention given is
-hard and unremitting. In some of the fast Atlantic
-greyhounds the strain is terribly severe, especially when
-the sea is beginning to run high. The rollers may be
-but 20 feet, yet these are quite high enough even for a
-splendid ocean racer to contend with and yet maintain
-her speed.</p>
-
-<p>Now her bows are pointing sky high, and her stern
-is deeply submerged; now she takes a header plump
-into the trough of the sea, and the engines race
-round; the propeller is suddenly raised out of water.
-But blow high, or blow low, on she goes, and the
-engineers are always busy. The furnaces roar with
-ceaseless rage. For days and nights the fires are
-kept at glowing heat. A forced blast maintains the
-draught; the steam condensed back into warm water
-is supplied to the boilers; half-naked men work hour
-after hour to rake the fires, clean them, pile on the fuel,
-and keep the most powerful head of steam the boilers
-can stand.</p>
-
-<p>When the furnace doors are opened tongues of flame
-leap forth, and the heat is enough to make a man
-sick. But with head turned away, the stoker stirs
-up the fire with his huge “slice” or fire rake, and
-cleans out the clinker clogging the bars.</p>
-
-<p>Then on go the coals! One layer, shot in from
-the shovel with unerring precision and skilful experience,
-right at the back; then another just in front<span class="pagenum"><a id="Page_95"></a>[95]</span>
-of the first, and so on till the long furnace is filled.
-Bang! the furnace door clangs, and the man reels
-away, sick and exhausted, with tingling eyes and
-heaving chest. Then coal has to be brought from
-the bunkers to the furnaces, tons of it per day, and
-if the ship rolls too much for the barrows to be used,
-the fuel must be carried in baskets.</p>
-
-<p>There is an engineer in charge of each stoke hole,
-and two on the platform in each engine room; as a
-rule, the staff are on duty in turns—four hours out of
-every twelve. But if the weather be bad they may
-have harder times.</p>
-
-<p>No matter how hot the machinery becomes, the
-engineers must not reduce speed, except it be to prevent
-disaster. Oil is swabbed on in bucketfuls, so to
-speak, but at every thrust the polished steel may gleam
-dry and smoking. Then on goes the water, as if there
-actually was a conflagration, and meantime a mixture
-of oil and sulphur is dabbed on. The water flies off
-in steam, so hot are the bearings, so terrific the friction
-of the incessant speed; and at last, down comes the
-reluctant order, wrung out of the chief like gold from a
-miser—“Slow her down.”</p>
-
-<p>It is done—dampers are clapped on furnaces, steam
-pressure dropped a little, and engines reduced to half
-speed; the three great cranks of the high, intermediate,
-and low pressure cylinders move round easily, and the
-tremendous noise gradually sinks to a murmur, compared
-with the previous rush and roar. The machinery
-cools. But when quite safe, on is piled the speed once
-more, and again the cranks fly round, and the mighty
-engines work their hardest to drive the mammoth ship
-through the surging green rollers.</p>
-
-<p>So superbly are these marine engines built, and so
-excellently are they maintained, being continually overhauled,
-so as to be kept in the pink of perfection, that,
-as years go on, they seem to “warm to their work” and
-do even better than at first.</p>
-
-<p>On the completion of the 200th round voyage<span class="pagenum"><a id="Page_96"></a>[96]</span>
-of the celebrated “White Stars,” <em>Germanic</em> and
-<em>Britannic</em>, about January, 1894, they seemed steaming
-as regularly and as fast, or faster than ever. Thus, on
-the 198th outward trip of the <em>Germanic</em>, in September,
-1893, she made the fastest westward passage, but one,
-she had ever accomplished. During their lives, it was
-said these vessels had maintained remarkable uniformity
-in speed, and each vessel had steamed 200
-times 6200 nautical miles, that is nearly a million
-and a-half statute miles, with the original engines and
-boilers—a performance, in all probability, without
-parallel in the world.</p>
-
-<p>Those people who care for figures may be interested
-in knowing that the <em>Britannic</em> had been 91,741 hours
-under steam, and 85,812 hours actually under weigh.
-Her engines had made 280 million revolutions, and
-maintained an average speed of 15 knots, or 17¼ statute
-miles an hour, while she had burnt 406,000 tons of coal.
-During their nineteen years of life the two vessels had
-carried 100,000 saloon, and over 260,000 steerage
-passengers, in safety and in comfort.</p>
-
-<p>This is a record of which all concerned, builders,
-owners, and working staff, may well be proud. It
-augurs first-class, honest work, and superb engineering
-skill. Since the construction of these ships, however,
-vessels surpassing them in speed have, of course, been
-built, among which may be mentioned the same line’s
-<em>Teutonic</em> and <em>Majestic</em>.</p>
-
-<p>The well-known Cunarders, <em>Umbria</em> and <em>Etruria</em>,
-have also done some very fine work, indicating great
-excellence of construction. Thus, on her eighty-second
-voyage, the <em>Umbria</em> steamed from Queenstown to Sandy
-Hook in 5 days, 22 hours; or, allowing for detention
-through fog, 5 days, 18½ hours, which is within three
-or four hours of the White Stars’ and American’s time.</p>
-
-<p>The story of the British warship <em>Calliope</em>, at Samoa,
-will also show how marvellously well ships’ engines can
-be built. Some difficulties had arisen between the
-United States and Germany as to Samoa, and several<span class="pagenum"><a id="Page_97"></a>[97]</span>
-warships had gathered there. Some weeks of bad
-weather had occurred, and then, on the 15th of March,
-1889, the wind began to blow with tremendous force.
-Down came the top masts from the warships—taken
-down as a precaution; steam was raised in the boilers in
-case anchors should not hold, and spars were made
-secure. But no man among the sailors expected such
-a hurricane as ensued.</p>
-
-<p>Rain fell at midnight, and the wind increased. Huge
-waves rolled in from the South Pacific, and the vessels
-tugged madly at their anchor chains and pitched fearfully
-up and down, like corks. Then the <em>Eber</em>, one of
-the German ships, began to drag her anchors; and the
-<em>Vandalia</em>, one of the Americans, followed suit. But
-by their steam power they kept off a dangerous reef,
-and also prevented themselves from colliding with their
-neighbours.</p>
-
-<p>Still higher and higher blew the hurricane, and the
-rain fell with tropic severity. Three hours after midnight
-the situation had become terrible. Almost every
-vessel was dragging her anchors, and the danger of
-collision was constant.</p>
-
-<p>The scene of the occurrence was a small bay before
-Apia, the capital of Samoa. But there is a coral reef
-extending in front of the bay for about two miles, and
-in the centre of the reef an opening about a quarter of
-a mile wide. The ships, therefore, were shut up in a
-comparatively small space, from which the way of escape
-was this gateway through the reef. The tide rushed in
-with great rapidity, swamping the land a hundred feet
-or so above high-water mark.</p>
-
-<p>As morning dawned and wore on to-day, the <em>Eber</em>
-collided with the <em>Nipsic</em> and then with the <em>Olga</em>, and,
-finally, was dashed by the huge waves, like a toy, upon
-the reef, and rolled over into deep water. Only
-five men struggled to shore and were saved. Other sad
-disasters occurred; and then, shortly before noon, the
-<em>Vandalia</em> and the <em>Calliope</em> were tossed perilously near
-together, and also toward the dangerous reef. In<span class="pagenum"><a id="Page_98"></a>[98]</span>
-endeavouring to steam away, the <em>Vandalia</em> collided
-with the <em>Calliope</em>, and was much damaged. Then, with
-splendid courage, Captain Kane determined to steam
-right away to sea—to remain would but risk another
-collision, or a wreck on the reef. Sea-room he must
-have at any cost!</p>
-
-<p>“Lift all anchors!” was the thrilling order, and
-then—“Full speed ahead!” Round swung the vessel’s
-head to the wind, and though the powerful engines
-were working “all they knew” to force the ship along,
-the steamer stood still, as if aghast at being asked to
-break through these tremendous waves.</p>
-
-<p>But she stood for a moment only. The superb
-engines began to tell; the quickly-whirling screw
-churned up the heavy water at the stern, and slowly
-the good ship made headway through the huge billows.
-They crashed over her stern and poured over her decks,
-as if in anger at her defiance. But on went the coal to
-her furnaces, and the thick smoke reeled off from the
-funnel in volumes. The strain quivered through every
-limb of the ship, but her captain kept her at it, and inch
-by inch she forced her way through the pounding seas.</p>
-
-<p>“This manœuvre of the gallant British ship,” says an
-eye-witness, Mr. John P. Dunning, of the Associated
-U.S. Press, “is regarded as one of the most daring in
-naval annals. It was the one desperate chance offered
-her commander to save his vessel and the three hundred
-lives aboard. An accident to the machinery at this
-critical moment would have meant certain death to all.
-Every pound of steam which the <em>Calliope</em> could possibly
-carry was crowded on, and down in the fire-rooms the
-men worked as they never had worked before. To clear
-the harbour, the <em>Calliope</em> had to pass between the
-<em>Trenton</em> (an American warship) and the reef, and it
-required the most skilful seamanship to avoid a collision
-with the <em>Trenton</em>, on the one hand, or total destruction
-upon the reef, on the other. The <em>Trenton’s</em> fires had
-gone out by that time, and she lay helpless almost in
-the path of the <em>Calliope</em>.”</p>
-
-<p><span class="pagenum"><a id="Page_99"></a>[99]</span></p>
-
-<div class="figcenter">
-<a id="i_099"><img src="images/i_099.jpg" alt="" width="485" height="450" /></a>
-<p class="caption center">PROMENADE DECK OF THE “PARIS.”</p></div>
-
-<p>But the dreaded collision did not take place. And as
-the <em>Calliope</em> passed near to the <em>Trenton</em>, a great shout
-was given for the British vessel, and the Englishmen
-responded with a noble cheer. Captain Kane, who
-subsequently was appointed to the <em>Inflexible</em>, said
-afterwards:</p>
-
-<p>“Those ringing cheers of the American flag-ship
-pierced deep into my heart, and I shall ever remember
-that mighty outburst of fellow-feeling which, I felt,
-came from the bottom of the hearts of the gallant
-Admiral and his men. Every man on board the <em>Calliope</em>
-felt as I did; it made us work to win. I can only say,
-‘God bless America and her noble sailors!’”</p>
-
-<p>The <em>Calliope</em> did win. Her superb machinery and<span class="pagenum"><a id="Page_100"></a>[100]</span>
-the fine seamanship with which she was handled were
-successful, and she returned to the harbour when the
-storm had subsided. Happily the brave men of the
-<em>Trenton</em> also survived, though fourteen vessels were
-wrecked and nearly 150 lives were lost.</p>
-
-<p>Strongly and staunchly as are built the Government
-ships, many of the great liners are their equals in these
-respects. Indeed, several of them are now retained by
-the Government to be used as armed cruisers should
-occasion require. The fittings and accommodation on
-many a large liner are also luxurious in the extreme.
-There are library and smoking-room, superb saloons
-and state-rooms, drawing-rooms, music-rooms, and tea-rooms,
-bath-rooms, etc. In short, they are floating
-hotels of a most sumptuous character.</p>
-
-<p>A modern steamship, with its multitude of comforts
-and conveniences for passengers and its complexities of
-machinery for fast and safe steaming, is a great triumph
-of engineering skill. Patience and forethought, the
-persevering development of sound principles, and the
-application of new ideas, have all contributed to this
-great achievement.</p>
-
-<p>From the <em>Comet</em> to the <em>Campania</em> is a marvellous
-development within a century. And it has not been
-accomplished along one line, but upon many. The use
-of steel, of many-tubed and strong boilers, of high pressure
-steam, which would have frightened Henry Bell
-out of his senses, the forced draught and the surface
-condensers, the screw propeller, the direct-acting and
-the triple and quadruple expansion engines, have all
-contributed to the noble results. Steamships, with their
-complex, beautiful, and powerful machinery, may rank
-among the most wonderful things that mankind has
-ever made.</p>
-
-<hr class="chap2 x-ebookmaker-drop" />
-
-<div class="figcenter">
-<a id="i_101"><img src="images/i_101.jpg" alt="train going over long bridge" width="450" height="169" /></a>
-</div>
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_101"></a>[101]</span></p>
-
-<p class="p140">FAMOUS BRIDGES AND THEIR BUILDERS.</p>
-
-
-<hr class="r5 x-ebookmaker-drop" />
-
-<h2 class="nobreak" id="CHAPTER_I-3">CHAPTER I.</h2>
-</div>
-
-<p class="center">“THE BRIDGE BY THE EARTHEN HOUSE.”</p>
-
-
-<p class="drop-cap"><span class="smcap">“You</span> will not try again, surely?”</p>
-
-<p>“Ay, I shall indeed!”</p>
-
-<p>“What! after two failures?”</p>
-
-<p>“Yes; I see the mistakes now. This bridge
-fell because it had too much weight on its haunches.”</p>
-
-<p>“Haunches! you mean the two side-curves of the
-arch were too heavy.”</p>
-
-<p>“Ay; you’ve heard the proverb no doubt that ‘An
-arch never sleeps.’ That is, should too great a weight
-fall on the crown or top part, the arch will fall at the
-sides outwardly, and the crown will sink; while, curiously
-enough, if it be built with too little weight on the
-crown, as this was, the crown will be forced upwards,
-and the sides will fall inwards.”</p>
-
-<p>“Then you mean to build your third bridge with less
-weight proportionately on its haunches?”</p>
-
-<p>“Exactly so.”</p>
-
-<p>“Well, I wish you good luck, friend Edwards, for we
-need a bridge sorely over the brawling Taff.”</p>
-
-<p>“You shall have it, neighbour. I shall succeed this
-time. I have gripped the right principle at last.”</p>
-
-<p><span class="pagenum"><a id="Page_102"></a>[102]</span></p>
-
-<p>He had indeed, for the bridge he then built lasts to
-this day. It was the famous Pontypridd bridge over
-the Taff on the Llantrissant and Merthyr road, and
-was called the Pont y du Prydd, or the bridge by the
-earthen house, for a mud hut stood near.</p>
-
-<div class="figcenter">
-<a id="i_102"><img src="images/i_102.jpg" alt="" width="550" height="461" /></a>
-<p class="caption center">PONTYPRIDD BRIDGE.</p>
-<p class="caption center"><cite>From Encyclopædia Britannica.</cite></p></div>
-
-<p>About the year 1745 it was determined to build a
-bridge over the rushing Taff, and William Edwards, a
-self-taught mason of the country, undertook the task.
-The first bridge he built was of three arches, which, in
-less than three years, was dashed away by a great flood.
-The water rose so high as to surge over the parapet.</p>
-
-<p>It must have been a sore disappointment to the
-hard worker to see his structure suddenly swept to
-ruins. But he was a shrewd, common-sense, observing
-man, and, nothing daunted, he tried again. This
-time he determined to build one bold arch of 140 feet.
-The object was to obviate the necessity of raising piers
-for more arches, and so obstructing the water; these<span class="pagenum"><a id="Page_103"></a>[103]</span>
-former piers having caused, or assisted in causing, the
-destruction of his first bridge.</p>
-
-<p>But the second gave way from the proportionally
-heavy weights on the haunches, as Edwards, we imagine,
-told his friend, and once more he had to face ruins.
-Yet a third time he tried, and the third time he was
-successful. Generations have come and gone, the children
-who played about its abutments have grown grey
-and have passed away, but still the country mason’s
-bridge of 140 feet span stands its ground and serves the
-community.</p>
-
-<p>He reduced the heavy weight on the sides by making
-openings in the spandrels—that is, the part above the
-curve of the arch; while, instead of filling up the interior
-space with rubble, he used charcoal. But the arch is
-very steep, and a chain and drag is kept to assist any
-horse when descending.</p>
-
-<p>These bridges illustrate the principle of the arch.
-Passing by the fact that it is evidently safer to span a
-swelling river by a bridge of wide, rather than of several
-narrow arches, three powers or forces act on the row
-of stones or bricks forming the arch. There is first the
-force that would carry the stone downward—that is,
-the force of its own weight and of anything that might
-be placed upon it. But then there are stones or bricks
-pressing against it on either side, and in its turn it
-presses upon them. When, therefore, every part presses
-equally, one not heavier or weaker than the others, a
-support for all is gained by the contiguous pressure and
-by the balance of forces.</p>
-
-<p>Long bridges were sometimes built in this way, and
-the longest in England in the Middle Ages was at
-Burton, over the Trent. It was 1545 feet long, and
-had 36 arches. It was not superseded till 1864, when
-a new bridge was built.</p>
-
-<p>In an arched bridge, the higher it rises in proportion
-to the width of the arch, the easier is its construction,
-and the less is the stress upon its parts; moreover, any
-inaccuracy in design or in building is likely to be less<span class="pagenum"><a id="Page_104"></a>[104]</span>
-harmful. We are not surprised, therefore, that Edwards,
-in his third attempt, decided upon that form.</p>
-
-<p>One of the widest arches in the world is that of the
-famous Grosvenor Bridge at Chester. It has a span of
-200 feet, with a rise of 42 feet. An arch, however,
-in the Washington Aqueduct extends to 220 feet span,
-while the central span in the Southwark Bridge,
-designed by Rennie, is 240 feet. This last, however, is
-of cast-iron.</p>
-
-<p>The principle of the arch, however, does not appear
-first in the history of bridge building. Bridges are as
-old as mankind; that is, no one knows when first men
-began to cross streams and chasms by placing the
-trunk of a tree from one side to the other, and thus
-bridging the gulf.</p>
-
-<p>Then, possibly, the next step was to build up a pile
-of stones in the centre of the stream—taking the stones
-there by coracle or canoe—and placing a tree trunk
-from the side to the central heap.</p>
-
-<p>Yet another development would most likely be a
-simple cantilever bridge—though these early builders
-would not have known that Frenchified word. But
-they knew that after embedding a tree trunk firmly on
-each side of the bank so that a considerable portion
-should project over the stream, they could place a
-third log from one end to the other, and thus get a
-bridge much longer than when made of one tree trunk
-alone.</p>
-
-<p>This principle, known so long ago, was used and
-immensely developed in the construction of the famous
-Forth Bridge, one of the most remarkable structures of
-the nineteenth century. This cantilever principle is
-very important in bridge building, and it is said that
-there exists an ancient bridge on this principle across
-the Sutlej in India with a span of 200 feet.<span class="pagenum"><a id="Page_105"></a>[105]<br /><a id="Page_106"></a>[106]</span></p>
-
-<div class="figcenter">
-<a id="i_105"><img src="images/i_105.jpg" alt="" width="550" height="268" /></a>
-<p class="caption center">THE POST BRIDGE, DARTMOOR.</p>
-<p class="caption center">(<em>An example of an early bridge, of “slab” construction.</em>)</p>
-</div>
-
-<p>A further variety of early bridges was the “slab”
-bridge, consisting of slabs of granite placed from side to
-side, or from the sides of the bank to heaps of stones
-piled up in the stream. A good example of such a<span class="pagenum"><a id="Page_107"></a>[107]</span>
-bridge may be seen at “Post Bridge” over the Dart on
-Dartmoor. Ages ago this bridge was built, and as we
-study it and compare it with the modern structure not
-far distant, we wonder how the ancient Britons—if
-those sturdy individuals are really responsible for it—could
-raise and place those huge slabs of stone without
-engineering apparatus. Probably it was done with
-levers and rollers, and there must have been many
-shoulders to the wheel in the process. Certainly they
-had plenty of granite at hand on wild Dartmoor.</p>
-
-<p>But passing by all these early forms of bridges—which
-it will be noticed are built of a few large pieces
-of material—it was left to the Romans, at all events in
-Europe, to largely adopt the arch as a principle of
-construction.</p>
-
-<p>Now, here we are dealing with an altogether different
-principle. The arch is made up of a number of comparatively
-small pieces of material bound together by
-mortar, or cement, or even clamps, and by the power of
-gravitation.</p>
-
-<p>We doubt if that idea is realised by half the people
-using the multitudinous arches abounding to-day; yet
-it is true. Or to put it in another way, the various
-parts are arranged so that they keep up each other
-by pressure.</p>
-
-<p>If you take two cards, or bricks, or slabs of stone and
-lean them together at the top, while the other ends
-may be far apart, you will find they will bear a certain
-amount of weight. Here you have the principle of the
-arch in its simplest form; and it may be that out of
-that primitive performance the arch has grown. This
-kind of triangular arch is to be met with in ancient
-structures in Great Britain. The flanks or haunches of
-an arch are its sides, from the first stone to the keystone;
-and the crown is its highest part; while the
-central wedge-shaped piece of stone or brick is called
-the keystone.</p>
-
-<p>The stones or bricks are cemented together when
-being built over a framework of timber, called the<span class="pagenum"><a id="Page_108"></a>[108]</span>
-centering, and when the keystone is placed and the
-arch is complete it ought to remain firm.</p>
-
-<p>But should too great a weight fall on the crown the
-bridge will fall outwardly at the sides, and the crown
-will sink; while, curiously enough, if it be built with
-too little weight on the crown, it will be, as it were,
-forced upwards, and the sides will fall inwards, as in the
-case of the second of the famous Pontypridd bridges,
-which actually did this. The material in the middle of
-the arch was less in proportion than that over the sides
-or “haunches,” and these heavier weights on the sides
-caused the crown to be forced upwards.</p>
-
-<p>Two causes combined to make changes in bridge
-building. These were the needs of railways and the
-introduction of iron as a building material. The first
-iron bridge was constructed over the Severn, near an
-appropriately named place, Ironbridge, in 1779. It
-had an arch of near upon a hundred feet span.</p>
-
-<p>When, however, very wide span bridges were required,
-the question arose of the superiority of wrought-iron
-over cast-iron for such structures. The Menai Strait
-had to be crossed for the Chester and Holyhead Railway,
-and the greatest existing cast-iron span was
-Rennie’s Southwark Bridge, where 240 feet had been
-reached. But over the Conway and the Menai Strait,
-spans of 400 feet were involved. How were these
-yawning gulfs to be bridged?</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_II-3">CHAPTER II.</h2>
-</div>
-
-<p class="center">A NEW IDEA—THE BRITANNIA TUBULAR.</p>
-
-
-<p class="drop-cap"><span class="smcap">“We</span> must cross the Strait at the Britannia Rock—that
-is settled.”</p>
-
-<p>“And where is the Britannia Rock?”</p>
-
-<p>“Nearly in mid-channel. It seems placed
-there for the purpose.”</p>
-
-<p><span class="pagenum"><a id="Page_109"></a>[109]</span></p>
-
-<p>And the great engineer smiled.</p>
-
-<p>“What are the distances?”</p>
-
-<p>“From coast to coast the span of the Strait is some
-1100 feet, with that rock in the centre. Now the problem
-is, to build a bridge across that gulf of surging
-water strong enough to bear heavy trains at high
-speeds, and sufficiently above the water to prevent any
-interference with navigation.”</p>
-
-<p>“And how will you manage it?”</p>
-
-<p>“First I thought of large cast-iron arches, but they
-will not do. I doubt if they would stand the strain;
-and moreover we should impede navigation by raising
-scaffolding during the building. At length I came to
-the idea of a tube bridge.”</p>
-
-<p>“What! a tube bridge! I’ve never heard of it!”</p>
-
-<p>“No, it is a new idea. By reconsidering a design I
-had made for a small bridge over the Lea at Ware in
-1841, and thinking over the matter, I came to the idea
-that a bridge consisting of a hollow beam or tube might
-solve the difficulty.”</p>
-
-<p>“A huge hollow girder, so to speak!” exclaimed his
-friend.</p>
-
-<p>“Exactly so. Accordingly,” the engineer continued,
-“I had drawings prepared and calculations made, by
-which to ascertain the strength of such a bridge, and
-they were so satisfactory that I decided on attempting
-one.”</p>
-
-<p>“It is like constructing one huge hollow beam of iron
-by rivetting plates together. Can it be done?” remarked
-his friend.</p>
-
-<p>“The making of the high-level bridge over the
-Tyne, in which I had a part—the bridge between
-Newcastle and Gateshead, you know—was a transition
-between an arched bridge and a girder bridge. A
-girder of course is a beam, it may be of iron or wood,
-and the little bridge at Ware has been built of girders
-made of plates of wrought-iron rivetted together.
-Therefore, you see, I am not unused to wrought-iron
-girders, and what they will bear.”</p>
-
-<p><span class="pagenum"><a id="Page_110"></a>[110]</span></p>
-
-<p>“Why, it is like a huge extension of the primitive
-log-bridge of our ancestors.”</p>
-
-<p>“If you like,” replied the engineer, laughing.</p>
-
-<p>Robert Stephenson—for he it is whom we suppose to
-be speaking to his friend on this gigantic engineering
-enterprise—became satisfied by reflection that the
-principles involved in constructing an immense tubular
-beam were but a development of those commonly in
-use; and Sir William Fairbairn was entrusted with the
-duty of experimenting as to the strength of tubes, the
-directors of the Railway Company voting a sum of
-money for the purpose.</p>
-
-<p>Sir William, then Mr., Fairbairn concluded that
-rectangular tubes were the strongest, and a model was
-made of the suggested bridge. It proved successful,
-and indicated that the tube would be able to stand the
-strain of a heavy train passing rapidly over it.</p>
-
-<p>In September, 1846, Mr. Fairbairn read a paper on
-the subject at the meeting of the British Association
-at Southampton, as also did Professor Hodgkinson, a
-mathematician, who had verified Fairbairn’s experiments.
-Not long afterwards Stephenson became satisfied
-that chains were not needed to assist in supporting
-the bridge, and that his tubes would be strong enough
-to support themselves entirely between the piers.</p>
-
-<p>Work therefore went forward. Some 1500 men were
-engaged on the Britannia Bridge, and the quiet shores
-of the Menai Straits resounded with the busy hum of
-hammers and machinery. Cottages of wood were built
-for the men, and workshops for the punching and
-rivetting of the plates for the gigantic tubes.</p>
-
-<p>The design included two abutments of masonry on
-either side of the Strait, and three towers or huge piers,
-one of which, the centre pier, was to rise from the
-Britannia Rock, 230 feet high. There are four spans,
-two over the water of 460 feet each, and two of 230 feet
-each over the land. Two tubes, quite independent of
-each other, but lying side by side, form the bridge
-across. Each tube or beam is 1510 feet long, and<span class="pagenum"><a id="Page_111"></a>[111]</span>
-weighs 4680 tons. Its weight at one of the long spans
-is 1587 tons.</p>
-
-<p>Now how could these gigantic tubes be put together
-and raised to their positions? Here was a problem
-almost as great as the original one of the bridge itself,
-and it troubled the engineer sorely.</p>
-
-<div class="figcenter">
-<a id="i_111"><img src="images/i_111.jpg" alt="" width="270" height="400" /></a>
-<p class="caption center">ROBERT STEPHENSON.</p></div>
-
-<p>“Often at night,” he declared, “I would lie tossing
-about, seeking sleep in vain. The tubes filled my head.
-I went to bed with them, and got up with them. In the
-gray of the morning, when I looked across Gloucester
-Square, it seemed an immense distance across to the
-houses on the opposite side. It was nearly the same
-length as the span of my tubular bridge.”</p>
-
-<p>The principle adopted was to construct the shorter
-tubes on scaffolds in the places which they were to<span class="pagenum"><a id="Page_112"></a>[112]</span>
-occupy. This could be done, for such scaffolding would
-not impede navigation. But scaffolding could not be
-built for the large tubes across the great spans of water.
-What then was to be done?</p>
-
-<p>It was decided to build them on platforms on the
-shore quite close to the water, and float them when
-ready on pontoons to their places between the piers, raising
-them to their position by hydraulic power. Such a
-task would be hazardous enough. It was first tried at
-Conway, where a similar bridge was being built by
-Robert Stephenson, being indeed part of the same
-railway. The Britannia was, however, a much greater
-enterprise, though the span of the Conway is 400
-feet. The Conway bridge, indeed, is but of one span,
-and contains two tubes.</p>
-
-<p>The experience at Conway was of great benefit to
-the gigantic undertaking at the Menai Strait. The
-floating of the first tube was to take place on the 19th
-of June, 1849, in the evening; but owing to some of
-the machinery having given way, the great event was
-put off to the next night. The shores were crowded
-with spectators. When the tube was finished it could
-be transferred to the pontoons; for the tubes had been
-built at high-water mark. When the pontoons were
-fairly afloat on this fateful evening, they were held and
-guided by leading strings of mighty strength. Stephenson
-himself directed in person, from a point of vantage
-at the roof of the tube. Thence he gave the signals
-which had been agreed upon, whilst a crew of sailors,
-directed by Captain Claxton, manned the strange
-barque.</p>
-
-<p>A pontoon is a light, buoyant boat, and the tube
-was supported on sets of these, their speed increasing
-terribly as they approached their place by the
-towers. The idea was, as related by Mr. Edwin Clark,
-Stephenson’s assistant, that they should strike a “butt”
-properly, underneath the Anglesey Tower, “on which,
-as upon a centre, the tube was to be veered round into
-its position across the opening. This position was<span class="pagenum"><a id="Page_113"></a>[113]</span>
-determined by a twelve-inch line, which was to be paid
-out to a fixed mark from the Llanfair capstan. The
-coils of the rope unfortunately over-rode each other
-upon this capstan, so that it could not be paid out.”</p>
-
-<p>Destruction seemed imminent. The capstan was
-actually dragged from the platform, and the tube
-seemed likely to be swept away. Then Mr. Rolfe,
-the captain of the capstan, shouted to the spectators,
-and threw out a spare twelve-inch rope. Seizing this,
-the crowd, with right good-will, rushed it up the field,
-and clung tightly to it, checking the voyage of the
-mighty tube. It was brought to the “butt,” and duly
-turned round.</p>
-
-<p>A recess had been left in the masonry of the tower,
-and the end near the Britannia pier was drawn into
-it by means of a chain. The Anglesey end followed.
-Then the tide gradually sank, the pontoons sank with
-it, and the tube subsided also to a shelf which had
-been made at either end. The first stage was accomplished;
-the mighty tube was in position to be raised.</p>
-
-<p>Shouts of rejoicing burst from the sympathetic
-crowds, and the boom of cannon joined its congratulatory
-note at the grand success. But the further
-stages remained. At midnight the pontoons were all
-cleared away, and the huge, hollow beam hung silent
-over the surging water. It rested on the shelves or
-beds prepared for it at either end. The second great
-operation, of course, was to haul it up the towers to
-its permanent position. This was to be performed by
-hydraulic machinery of great power, and Mr. Stephenson’s
-instructions were to raise it a short distance at
-a time, and then build under it.</p>
-
-<p>He took every imaginable precaution against accident
-or failure; and well was it that he did so, for an accident
-happened which, but for the careful building
-under the tube in the towers as it was raised, would
-have been most calamitous. The accident occurred
-while Mr. Stephenson was absent in London. One
-day, suddenly, while the machinery was at work<span class="pagenum"><a id="Page_114"></a>[114]</span>
-raising the tube, the bottom burst from one of the
-hydraulic presses, and down fell the tube on to the
-bed provided for it.</p>
-
-<p>Though the fall was but nine inches, tons weight of
-metal castings were crushed, and the mighty tube
-itself was strained and slightly bent. But it was
-serviceable still, and the fact that it stood the strain
-so well showed its great strength. It weighed some
-five thousand tons, and for such an immense weight
-to fall even three-quarters of a foot was a very severe
-test.</p>
-
-<p>But for Stephenson’s wise precaution in lifting it
-slowly, and building underneath it as it was raised,
-the tube would have crashed to the bottom of
-the water. As it was, the accident cost £5000; but
-the tube was soon being hauled upward again. In due
-course the others followed, and on the 5th of March,
-1850, Robert Stephenson inserted the final rivet in the
-last tube, and the bridge was complete. He crossed
-over with about a thousand persons, three locomotives
-whirling them along.</p>
-
-<p>The tubes of the bridge are made of iron plates, and
-at the top and bottom are a number of small cells or
-tubes—instead of thick iron plating—which assist in
-giving strength to the whole gigantic tube. Thus it
-may be said the floor and roof are tubular, as well as
-the body. These hollow cells appear to have been
-Fairbairn’s invention. The size of the tube grows
-slightly larger at the middle by the Britannia tower,
-where externally the tubes are 30 feet high, and 26
-internally, while they are 22¾ feet and 18¾ feet at the
-abutments. The width is 14 feet, 8 inches externally,
-and 13 feet 5 inches inside.</p>
-
-<p>At the Britannia tower the tubes are placed solidly
-on their bed, but at the abutments, and at the land
-towers, the tubes rest on roller-beds. This arrangement
-was adopted to permit of expansion and contraction.
-Iron, of course, solid and unyielding as it appears,
-is yet very susceptible to warmth, and the effect of the<span class="pagenum"><a id="Page_115"></a>[115]</span>
-sun’s rays on this massive iron structure is very marked.
-A rise of temperature causes it to expand in a comparatively
-short time, and it is said that the tubes
-occasionally move two and a-half inches as the sun
-gleams upon them. Mr. Edwin Clark observed the
-effect of the sun on the iron, which appears in a small
-degree to be always moving as the temperature varies.
-Well, therefore, that the able engineer planned an
-arrangement allowing for this constant expansion and
-contraction of the iron mass.</p>
-
-<div class="figcenter">
-<a id="i_115"><img src="images/i_115.jpg" alt="" width="650" height="503" /></a>
-<p class="caption center">THE BRITANNIA TUBULAR BRIDGE.</p></div>
-
-<p>The Britannia Bridge was a great triumph for Robert
-Stephenson. He appears first to have seized the idea,
-and, assisted no doubt by Fairbairn’s experiments and
-by able coadjutors, he carried it through to a successful
-completion. He was of course the son of George
-Stephenson, who had done so much for the locomotive,
-and according to Smiles, “he almost worshipped his<span class="pagenum"><a id="Page_116"></a>[116]</span>
-father’s memory, and was ever ready to attribute to
-him the chief merit of his own achievements as an
-engineer.”</p>
-
-<p>“It was his thorough training,” Mr. Smiles once
-heard him remark, “his example, and his character,
-which made me the man I am.” Further, in an
-address as President of the Institution of Civil
-Engineers, in January, 1856, he said: “All I know,
-and all I have done is primarily due to the parent
-whose memory I cherish and revere.”</p>
-
-<p>That father had died before the Britannia Bridge was
-completed, though he had been present at the floating
-of the first tube at Conway. The great engineer passed
-away on the 12th of August, 1848, at the age of sixty-seven,
-and his distinguished son Robert, who had no
-children, only survived him by eleven years.</p>
-
-<p>But before he died he had designed, and Mr. A. M.
-Ross, who had assisted at the Conway Bridge, had
-assisted in carrying out the celebrated Victoria Tubular
-Bridge over the great St. Lawrence River at Montreal.</p>
-
-<p>This bridge was for the Grand Trunk Railway of
-Canada, and for immense length and vastness of proportions,
-combined with magnificent strength, is one
-of the wonders of the world. It is five times as long as
-the Britannia Bridge, being not far short of two miles.
-It has a big central span of 330 feet, and twenty-four
-spans of 242 feet. The iron tubes are suspended sixty
-feet above the water beneath.<span class="pagenum"><a id="Page_117"></a>[117]</span></p>
-
-<div class="figcenter">
-<a id="i_117"><img src="images/i_117.jpg" alt="" width="600" height="344" /></a>
-<p class="caption center">VICTORIA TUBULAR BRIDGE, MONTREAL.</p></div>
-
-<p>One great difficulty in the problem was the ice.<span class="pagenum"><a id="Page_118"></a>[118]</span>
-Immense quantities come down in the spring, and to
-resist this enormous pressure the piers are most massive,
-containing thousands of tons each of solid masonry.
-These piers are based on the solid rock, the two central
-towers being eighteen feet in width and the others
-fifteen feet. To protect them from the ice, huge
-guards made of stone blocks clamped with rivets built
-up in the form of an incline were placed before the piers
-on the up-stream side. The bridge was begun in July,
-1854, and occupied four and a-half years in construction,<span class="pagenum"><a id="Page_119"></a>[119]</span>
-it being completed in December, 1859, about two months
-after its designer had died.</p>
-
-<p>Gigantic though this structure is, and great as is the
-honour which it reflects on Robert Stephenson and the
-resident and joint engineer Mr. Ross, yet with the
-exception of the remarkable and massive ice-guards
-to the piers, it does not differ materially from the
-Britannia and Conway Tubular Bridges. These were
-the first famous examples of the new principle.</p>
-
-<p>Why, then, are massive tubular bridges not more
-generally built? Because they led to another and very
-natural development in bridge-building, a development
-whereby great strength for long spans is gained, with,
-however, a marked saving both in labour and in material.
-That development was the lattice bridge.</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_III-3">CHAPTER III.</h2>
-</div>
-
-<p class="center">LATTICE AND SUSPENSION BRIDGES.</p>
-
-
-<p class="drop-cap"><span class="smcap">“The</span> expense of a tubular bridge would be too
-great.”</p>
-
-<p>“But if we could get the strength without
-the expense.”</p>
-
-<p>“What mean you?”</p>
-
-<p>“By iron lattice work we could, I think, gain the
-stiffness and support needed, without such great cost
-of labour and material. In other words, I propose
-a lattice or trellis work girder, instead of a solid sided,
-or a tubular girder.”</p>
-
-<p>“That is, you would have the sides of lattice or trellis
-work, instead of solid plates?”</p>
-
-<p>“Exactly. I would use bars of iron placed diagonally.
-These lattice or trellis bridges are developed from the
-tubular bridges, also from the loose wooden lattice
-bridges of America. We make a web of iron instead<span class="pagenum"><a id="Page_120"></a>[120]</span>
-of a solid sheet. The same kind of structures are
-largely used over the wide rivers of India. Sir John
-MacNeill designed the first in iron, and it was built in
-1843 on the Dublin and Drogheda Railway with a span
-of eighty-four feet. I consider they will be among the
-most popular bridges of the future for longish spans.”</p>
-
-<p>The engineer’s prediction has come true; for lattice
-bridges have undoubtedly been very widely adopted.
-We may suppose that he was advising the directors
-of a proposed railway, and we doubt not but that he
-carried the day.</p>
-
-<p>A fine specimen of a lattice bridge is that across
-the Thames near Charing Cross, for the South-Eastern
-Railway. It has a total length of more than a quarter
-of a mile—viz., 1365 feet, and six of its nine spans are
-154 feet wide. Two principal girders, fourteen feet
-deep, are connected transversely by other girders which
-carry the rails and project on the other side to support
-a footpath. The two main girders are nearly fifty feet
-apart and one weighs 190 tons.</p>
-
-<p>The sides have upper and lower booms made of plate
-iron connected by perpendicular bars, between which
-are a couple of bars crossing each other diagonally at
-an angle of forty-five degrees, and fixed to the booms
-by bolts of five and seven inches in diameter.</p>
-
-<p>The old Hungerford Bridge stood here previously,
-and its two piers of brickwork were used for the new
-bridge. Other piers are huge cylinders of cast iron ten
-feet across, but fourteen feet in diameter in the ground.
-Thus they are broadly based. These piers are filled
-with concrete and also brickwork, and are topped with
-bearing-blocks of granite. They are formed of plates
-of cast iron bolted together, and they were sunk into
-the ground many feet below high-water by combined
-forces; divers scooped out the mud and gravel and
-clay from within the cylinders; water was pumped out
-and heavy weights pressed them down. The piers
-became fixed on the London clay, but when filled
-were heavily weighted to drive them down again, and<span class="pagenum"><a id="Page_121"></a>[121]</span>
-finally they were forced to a depth of over sixty-two
-feet below high-water mark.</p>
-
-<p>But before lattice girder bridges had become so
-popular, another class had come into use, and afford
-some splendid specimens of engineering skill. These
-are suspension bridges, and, perhaps of all kinds, they
-are the most picturesque. Their graceful sweeps and
-curves yield perhaps a more pleasing sight for the eye
-than the solid, rigid, straight lines of the girder bridges.</p>
-
-<p>It was the genius of Thomas Telford which gave a
-great impetus to this class of bridge. Like Stephenson
-after him, he had to bridge the surging Menai Straits,
-but for a carriage road, not a line of rails; and at
-length, after various plans had been suggested and
-abandoned, he proposed the Suspension Bridge.</p>
-
-<p>Now, in its simplest form, a suspension bridge has
-been known for ages. It is merely a pathway, or even
-a small movable car, suspended from a rope or ropes
-across a chasm. Ulloa describes suspension bridges
-built by the Peruvians in South America. Four stout
-cables span a river, and on these four is placed the platform
-of sticks and branches, while two other ropes connected
-with the platform are useful as hand rails. Such
-bridges sway with the wind and move with the passenger,
-but for light loads they appear to be perfectly
-safe.</p>
-
-<p>In Telford’s Menai Bridge the carriage-way is hung
-from four huge chains or cables, each chain made up of
-four others, and passing over high piers. The chains
-are anchored on the landward side, sixty feet in pits,
-and grafted by iron frames to the rocks. The chains
-are so complex and so strong, that parts may be
-removed for repair without imperilling the safety of the
-structure. The length of the span thus gained is 560
-feet, and it is 150 feet above high-water. The
-remainder of the bridge is composed of arches of stone,
-of 52½ feet span.</p>
-
-<p>The piers from which the great span is suspended
-rise above the carriage-way fifty-two feet, and are topped<span class="pagenum"><a id="Page_122"></a>[122]</span>
-by blocks of cast-iron, which can move on rollers to permit
-the chains passing over them to expand and
-contract freely with the temperature. There are two
-carriage-roads, and also a footpath. The roads are
-separated by iron lattice work, which also gives them
-stability and decreases vibration.</p>
-
-<div class="figcenter">
-<a id="i_122"><img src="images/i_122.jpg" alt="" width="600" height="560" /></a>
-<p class="caption center">THE CLIFTON BRIDGE.</p></div>
-
-<p>In its day, this stupendous bridge was as great a wonder
-as its later companion over the same Straits—the
-Britannia Tubular. Six years were occupied in building,
-and it was opened in 1825. Why, then, did not
-Stephenson construct a similar bridge when, twenty
-years or so later, he had to solve a similar problem?</p>
-
-<p>The answer is, that suspension bridges are not—or
-were not—considered sufficiently strong and rigid for
-railway work. In America, however, they have been
-used for this purpose; witness the famous Niagara
-Suspension Bridge, 2⅓ miles below the Falls, and<span class="pagenum"><a id="Page_123"></a>[123]</span>
-with a superb span of 822 feet; but American
-engineers appear to stiffen the roadway considerably, so
-as to distribute the stress of the rushing train over
-a large portion of the cable. The Niagara Bridge is
-not supported by plate-link chains, but by four immense
-wire cables, stretching from cliff to cliff over the roaring
-rapids. Four thousand distinct wires make up each
-cable, which pass over lofty piers, and from them hangs
-the railway by numerous rods.</p>
-
-<div class="figcenter">
-<a id="i_123"><img src="images/i_123.jpg" alt="" width="607" height="396" /></a>
-<p class="caption center">THE BROOKLYN BRIDGE.</p></div>
-
-<p>Probably the famous Brooklyn Bridge is the largest
-suspension bridge in the world, even as the Clifton
-Suspension Bridge, in England, is one of the most
-interesting. The Brooklyn Bridge has a magnificent
-central span of 1595½ feet over the East River between
-Brooklyn and New York; further, there are two land
-spans of 930 feet, which, together with the approaches,
-make up a total of about a mile and a furlong. The
-cables, four in number, are each composed of 5000 steel
-wires, and measure 15¾ inches in diameter. They are
-anchored to solid stone structures at either end, measuring<span class="pagenum"><a id="Page_124"></a>[124]</span>
-119 feet by 132 feet, and weighing 60,000 tons;
-while the towers from which the main span is suspended
-rise to the height of 276 feet, and are embedded
-in the ground 80 feet below high-water. It has been
-estimated that the weight hung between these towers
-is nearly 7000 tons.</p>
-
-<p>The roadway of the bridge is divided into five
-thoroughfares. Those on the outer sides are for
-vehicles, and are 19 feet wide; the centre is for foot passengers,
-and is 15½ feet in width; while the two
-others are for tramway traffic. The bridge was opened
-in 1883, and affords a great triumph of engineering skill.</p>
-
-<p>Much smaller, but none the less interesting, is the
-Suspension Bridge at Clifton. As far back as 1753,
-Alderman William Vick, of Bristol, left a sum of £1000
-to build a bridge at Clifton. The sum was to lie at
-compound interest until £10,000 was reached. However,
-the money was increased by subscriptions, and in
-1830 an Act of Parliament was obtained for its construction.</p>
-
-<p>The work coming into the hands of Mr. I. K. Brunel,
-he designed a bridge of 702 feet span, and 250 feet
-above high-water. The piers and abutments were
-built, but lack of cash, which forms an obstacle to so
-many brilliant enterprises, stopped the progress of the
-bridge for nearly fourteen years.</p>
-
-<p>Then it occurred that the Hungerford Suspension
-Bridge was to be removed to make way for the Charing
-Cross Railway Bridge, so the chains were purchased at
-a comparatively small cost, and the work at Clifton proceeded,
-and was finally completed.</p>
-
-<p>Three chains on either side suspend long wrought-iron
-girders, which help to stiffen the platform; and
-cross girders between support the floor. The chains
-pass over rollers on the piers, and are ultimately
-anchored to plates bedded in brickwork abutting on
-rock. The platform is hung by upright rods from the
-chains, and hand-railing is used with lattice-work, to
-assist in rendering it rigid. The roadway, twenty feet<span class="pagenum"><a id="Page_125"></a>[125]</span>
-wide, is made of creosoted wood, five inches thick, while
-the pathways on either side are made with wood half as
-thick. Between the piers the weight of the structure,
-including the chains, amounts to nearly a thousand
-tons.</p>
-
-<p>In all these suspension bridges, however large, the
-principles are much the same. The platform, or roadway,
-is hung from chains or cables, which pass over piers
-and are anchored fast at the ends. Some are stiffened
-with girders and bracing to prevent undue undulation.
-The chains take a graceful and definite curve, that of
-the Menai Bridge dipping fifty-seven feet. The strain
-is the greatest at the lower part, and is increased, should
-the chain be drawn flatter over the same space. These
-bridges became widely adopted.</p>
-
-<p>But there came a time when none of the bridges in
-vogue seemed to give what was required. A new principle
-was wanted. Where was it to be found?</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_IV-3">CHAPTER IV.</h2>
-</div>
-
-<p class="center">THE GREATEST BRIDGE IN THE WORLD.</p>
-
-
-<p class="drop-cap"><span class="smcap">“Have</span> you heard the news? The Tay Bridge is
-blown down!”</p>
-
-<p>“Yes. A terrible disaster. I should think
-they would give up their scheme of bridging
-the Firth of Forth after that.”</p>
-
-<p>“Not they! The scheme may be altered, but bridge
-it they will. Engineers never give in.”</p>
-
-<p>The comments of these newspaper readers were
-right. The Tay Bridge, the longest in the world, had
-been blown down one wild December night in 1879,
-and girders, towers, and the train which was rushing
-over it, were suddenly hurled into the surging flood.</p>
-
-<p><span class="pagenum"><a id="Page_126"></a>[126]</span></p>
-
-<p>At that time a scheme was in hand to bridge the
-Forth for the North British Railway system, and Sir
-Thomas Bouch had proposed two suspension bridges
-hung by steel chains. But ultimately a new design
-altogether was adopted, the plan being by Sir Benjamin
-Baker and Sir John Fowler.</p>
-
-<p>It was the new principle—or, rather, a remarkable
-development of an old principle—for which the bridge-making
-world was waiting: the principle, namely, of
-the cantilever.</p>
-
-<p>A cantilever is, in fact, a bracket; and Sir Benjamin
-Baker has described it as such. It is a strong support,
-built out from a firm base, and is like a powerful
-and magnified bracket upholding a shelf.</p>
-
-<p>In the Forth Bridge there are two huge spans, 1700
-feet wide, crossed by these cantilevers; bridging channels
-of some 200 feet deep.</p>
-
-<p>The longest spans on the Tay Bridge were 245 feet;
-it was over two miles long, and had ninety spans. It
-was an iron girder bridge, and was opened on the 31st
-of May, 1878. Not to be beaten, however, after the
-panic had subsided, another and more stable bridge
-was constructed, also a girder, but not so high in
-elevation, and sixty feet further up the river. It was
-opened in 1887, and is 10,779 feet long, with 85 piers,
-the navigable channel being under four of the spans,
-the centre spans being 245 feet wide.</p>
-
-<p>It will be seen at once that the cantilevers at the
-Forth Bridge cover very much wider spans; and the
-channel being so deep, the impossibility of building
-piers will also be obvious. The best place for the
-bridge was marked by the projection of the Inverkeithing
-peninsula on the north shore, and also
-the Inchgarvie rock in the channel itself. The peninsula
-brought the two shores together, reducing the
-space to be bridged, and the rock gave firm support
-for a pier. Still there were the two immense spans
-of 1700 feet to be crossed, and the engineers decided
-on the cantilever principle. Thus, though the Tay<span class="pagenum"><a id="Page_127"></a>[127]</span>
-Bridge was the longest in the world, the Forth presented
-by far the greatest spans—viz., the two main
-spans of 1700 feet each, in addition to which there are
-two of 675 feet each, and fifteen of 168 feet each.</p>
-
-<p>The total length of this magnificent bridge, which
-Sir Benjamin Baker rightly claimed was the most
-wonderful in the world, is somewhat over 1½ miles in
-length, or 8296 feet, including the piers, while almost a
-mile is bridged by the huge and superb cantilevers.
-This is, perhaps, the great marvel. The clear space
-under the centre is no less than 152 feet at high-water,
-while the highest portion is 361 feet above the same
-mark.</p>
-
-<p>And now, how was this great bridge constructed?
-Workshops were erected at South Queensferry, and
-the mammoth cantilevers were put up there piece by
-piece. They were fitted together and then taken plate
-by plate to the bridge itself. The shops were lit by
-electricity, and furnished with appliances for bending,
-cutting, moulding, holing, and planing plates. The
-workshops were surrounded by quite a maze of railways.</p>
-
-<p>But what of the piers, without which all these
-preparations would be unavailing? Now the foundations
-of piers are usually laid by means of cofferdams;
-that is, piles of timber are driven down through the
-water into the bed of the river close together, and the
-interstices filled with clay; or a casing of iron may be
-used instead. The water in the enclosure thus formed
-can be pumped out and excavation proceeded with, and
-the foundations laid. Cofferdams are sometimes made
-of iron boxes or caissons with interstices fitted with
-felt, and caissons of this kind about 12½ feet long and
-7 feet wide were used in constructing the Victoria
-Embankment on the Thames.</p>
-
-<p>But with certain of the piers for the Forth Bridge
-the water was too deep for timber cofferdams, and the
-usual diving-bell was not sufficiently large. The piers
-were to be of immense size, no less than 55 feet in<span class="pagenum"><a id="Page_128"></a>[128]</span>
-diameter, and the diving-bell of ordinary size would not
-cover that great width.</p>
-
-<p>Huge caissons were therefore made, 70 feet wide,
-constructed of iron plates and rising in height, according
-to the depth of water, up to 150 feet. The lower
-part of the immense caisson or tank was fitted as a
-water-tight division and filled with compressed air, the
-object being to resist the pressure of the water. Two
-shafts communicated with this air-tight division or
-mining chamber, one for the removal of the earth
-excavated, and the other for the men to pass up and
-down. The escape of the air through the shafts was
-prevented by the use of an air-lock, working on the
-same principle as a water-lock on rivers or canals.
-There were two doors in the lock, one communicating
-with the shaft and the other with the outside air.
-When the latter was closed and the lock filled with
-compressed air by opening a valve or tap, the door of
-the shaft could be opened and the man could descend
-to his work below.</p>
-
-<p>That work consisted chiefly of excavation in the bed
-of the river. Drills, hydraulic cutters, and dynamite
-blasting were all utilised until huge holes, many feet
-below the river bed, were hollowed out. As the caisson
-was filled with concrete above the air-tight chamber
-where the men worked it was exceedingly heavy, and
-sank by its own weight into the space prepared.</p>
-
-<p>The mining chamber was lit by electricity, and was
-about seven feet high. The mud of the river bed was
-mixed with water and blown away by the compressed
-air which seems to have been about 33 lbs. to the
-square inch. The caissons were sunk down to rock or
-boulder clay, and when they had reached the required
-distance the mining chamber was filled with concrete,
-and the same material used to the level of the water;
-the piers were then built up with huge stones placed in
-cement, the whole forming a magnificent mass of concrete
-and masonry, carried down in some cases to about
-40 feet below the bed of the river.</p>
-
-<p><span class="pagenum"><a id="Page_129"></a>[129]</span><br /><span class="pagenum"><a id="Page_130"></a>[130]</span></p>
-
-<div class="figcenter">
-<a id="i_129"><img src="images/i_129.jpg" alt="" width="600" height="341" /></a>
-<p class="caption center">THE FORTH BRIDGE.</p></div>
-
-<p><span class="pagenum"><a id="Page_131"></a>[131]</span>The three chief piers consist of groups of four
-columns of masonry, each gradually tapering from 55
-feet in diameter to 49 feet at the top, and about 36 feet
-high. From these rise the huge cantilevers connected
-together by girders 350 feet in length.</p>
-
-<p>The centre of these three main piers rests on the
-island of Inchgarvie; the two others are known as the
-Fife and the Queensferry piers respectively, and are
-placed on the side of the deep water channels. In
-addition to these three main piers are several others,
-some in shallow water and some on land. The part of
-the bridge which they carry is an ordinary girder of
-steel leading to the immense cantilevers. For founding
-the shallow water piers, cofferdams were used; the
-caissons with compressed air chambers being for the
-deep water structures.</p>
-
-<p>They were put together on shore, launched, floated,
-steered to the desired position, and sunk. One proved
-cranky and turned over, and was only brought right
-after much expense and difficulty.</p>
-
-<p>The cantilevers are bolted down to each pier by
-numbers of huge steel ties, 24 feet in length and 2½
-inches in diameter, embedded in the masonry, there
-being 48 of these bolts or ties to each column. And
-now as to these cantilevers.</p>
-
-<p>Four huge tubular shafts, two on each side, rise from
-the group of columns forming each pier, to the height
-of 350 feet. From these shafts, which slope slightly
-inward, project the cantilevers, the upper and lower
-parts being strongly braced together by diagonal ties.
-In shape the gigantic brackets taper towards a point,
-the width decreasing as much as from 120 feet at the
-commencement of the piers to 32 feet at the ends.
-The wind, it is believed, will be more effectually
-resisted by this means.</p>
-
-<p>The cantilevers are hung back to back, one to some
-extent counter-weighing the other. The component
-parts consist of cylinders of steel or struts for resisting
-compression—these are the lower parts; and ties of<span class="pagenum"><a id="Page_132"></a>[132]</span>
-lattice-work made of steel plates for resisting tension,—placed
-above.</p>
-
-<p>Thus, then, from each of the three chief piers two
-pairs of gigantic brackets project, each pair placed side
-by side and braced together, and forming one composite
-cantilever jutting to the north and one to the south.
-The rails run on sleepers placed lengthwise and fixed in
-troughs of steel, so that should a train run off the line
-the wheels will be caught by these supports.</p>
-
-<p>It is calculated that there are about 45,000 tons of
-steel in the bridge, and 120,000 cubic yards of masonry
-in the piers. The contract price was £1,600,000, which
-works out at about £215 per foot; and the contractors,
-who were able to obtain an admirable organisation of
-some 2000 men to carry out the magnificent design,
-were Messrs. Tancred, Arrol, &amp; Co. Some special tools
-for use in the work were planned by Sir William Arrol.
-The bridge was opened by the Prince of Wales on the
-4th of March, 1890.</p>
-
-<p>The success of this magnificent structure has assured
-the wider adoption of the cantilever principle. Long-span
-bridges, in several cases, have since been built on
-this design. Its engineers may claim indeed to have
-widened the scope and possibilities of bridge-building.</p>
-
-<p>Still, when another bridge was wanted over the
-Thames, at a busy spot, crowded with shipping and
-near the historic Tower of London, another kind of
-structure was adopted. What was it?</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_133"></a>[133]</span></p>
-
-<h2 class="nobreak" id="CHAPTER_V-4">CHAPTER V.</h2>
-</div>
-
-<p class="center">THE TOWER BRIDGE.</p>
-
-
-<p class="drop-cap"><span class="smcap">“Why</span> should they not have a drawbridge?”</p>
-
-<p>“What! To draw up from each bank of
-the river?”</p>
-
-<p>“No, I did not mean that exactly. Could
-they not get piers farther in towards the centre of
-the stream, and let the drawbridge rise and fall from
-them?”</p>
-
-<p>“The river is too crowded for many piers.”</p>
-
-<p>“It is. But I cannot help thinking a drawbridge—a
-bascule bridge as the engineers call it—is the best
-solution of the difficulty.”</p>
-
-<p>“Well, a bridge is wanted sufficiently low to spring
-from the flat banks of the Thames for foot passengers
-and carriage traffic, and yet sufficiently high to permit
-tall ships to pass underneath.”</p>
-
-<p>“And apparently these two requirements are incompatible.”</p>
-
-<p>“Not altogether,” remarks a third speaker.</p>
-
-<p>“You are partly right in your idea of a drawbridge.
-That is Sir Horace Jones’s idea. And, further, there
-is literally to be a high and also a low-level bridge;
-for there are to be two levels—that is, two roadways—one
-at a high, and one at a low, level across the middle
-span.”</p>
-
-<p>“And is the low level to be a drawbridge—a roadway
-that can be drawn up to permit vessels to pass?
-Is that so?”</p>
-
-<p>“Exactly. And this drawbridge will be in two parts,
-one on either side; they will be worked from two
-massive piers giving a clear span of 200 feet in the
-middle of the stream, through which span big vessels
-can pass. The usual traffic of the river will be able to
-pass even when the drawbridges are down.”</p>
-
-<p><span class="pagenum"><a id="Page_134"></a>[134]</span></p>
-
-<p>“And above the bascules or drawbridges will run the
-high-level bridge?”</p>
-
-<p>“Yes, a girder bridge for footpaths, and people
-will reach it by lifts and staircases in the piers—which,
-by-the-by, will be more like huge towers. These
-towers will also contain the machinery for raising and
-lowering the drawbridges.”</p>
-
-<p>“And what sort of bridge will be used for the other
-spans—that is, to cross the river between the piers and
-the shore?”</p>
-
-<p>“Suspension bridges; so that the Tower Bridge as
-it will be called, for it will cross the Thames by the
-Tower of London, will embody the suspension, the
-bascule (or drawbridge), and the girder bridge principles,
-while in the centre will be two levels.”</p>
-
-<p>“It promises to be a splendid piece of work.”</p>
-
-<p>“It does. And it is very much needed, for the congestion
-of traffic on London Bridge is terrible.”</p>
-
-<p>“And people have often to come round a long way to
-reach it.”</p>
-
-<p>The promise of the Tower Bridge, as set forth by
-these speakers, has been amply fulfilled. It is indeed
-a fine piece of work; and although it does not embody
-any new idea, yet in its combination and development
-of old principles and in its size it is very remarkable.
-It was opened in June, 1894, and is, or was at the time
-of building, the biggest bascule bridge in the world.</p>
-
-<p>Within its handsome Gothic towers are steel columns
-of immense strength, constituting the chief supports of
-the suspension bridges and of the high-level footways.
-The architect was the late Sir Horace Jones, and the
-engineer Mr. J. Wolfe Barry, while the cost was, including
-land, about £1,170,000.</p>
-
-<p>The problem was to combine a low-level bridge providing
-for ordinary town traffic with a high level,
-under which ships could pass, and it was accomplished
-by a union of principles. In its oldest shape the drawbridge
-was probably a huge piece of timber, which was
-hauled up and let down by chains over the moats of<span class="pagenum"><a id="Page_135"></a>[135]</span>
-castles. In the Tower Bridge there are two of such huge
-“flaps” or leaves, each about 100 feet long, one rising
-and falling from each pier and meeting in the centre.
-Large bascule bridges are usually constructed in this
-manner, and there is an excellent specimen over the
-Ouse, for the passage of the North-Eastern railway;
-one man at each half of the bridge can raise it in less
-than two minutes. Another fine bascule may be seen
-at Copenhagen.</p>
-
-<p>The bascules are raised and lowered by chains, which,
-in the case of the Tower Bridge, are worked by superb
-hydraulic power from the massive pier towers. When
-drawn up, which is done in less than five minutes, the
-bascules are even with the sides of the towers, and full
-space is given for the vessels to pass.</p>
-
-<p>The two side spans of the bridge, crossed by the
-suspension bridges, are wider than the centre, being
-270 feet each, and the total length of the whole bridge
-is 800 feet between the abutments. There are also
-piers on the shoreward side for carrying the chains of
-the suspension bridges at each extremity.</p>
-
-<p>The massive tower piers, sunk 27 feet below the
-river bed, are built of gray granite, and are also fitted
-with strong break-waters to resist the action of the tide.
-The high-level bridges across the central span are for
-foot passengers, and are 135 feet over high-water mark.
-The bascule bridges, when closed for vehicular traffic,
-are 29½ feet above high water, while the side suspension
-spans are 27 feet. The roadway is 50 feet wide, which
-is also the width of the approaches. The foot passenger
-traffic is never stopped, as persons can pass by the
-hydraulic lifts or the stairways in the tower piers to
-the high-level bridges above.</p>
-
-<p>Sir Horace Jones died before the great work was
-completed, and was succeeded by Mr. G. D. Stevenson,
-who had been his assistant. Sir William Arrol &amp; Co.
-supplied the iron and steel, and Sir William Armstrong
-the hydraulic machinery. Various contractors carried
-out different portions of the mighty work, which occupied<span class="pagenum"><a id="Page_136"></a>[136]</span>
-about eight years in building. Near by stands the
-ancient Tower of London, looking not unkindly on the
-great constructive effort to which it has given its name.</p>
-
-<p>Sometimes a bridge is made movable by swinging
-it round on a pivot instead of drawing it up on a
-hinge or axis; and sometimes, as in the case of a
-bridge over the Arun for the Brighton and South
-Coast Railway, it is made to slide on wheels backwards
-and forwards from the abutment. Floating or pontoon
-bridges are made by placing planks on pontoons, or
-boats anchored by cables. The longest in the world
-is probably at Calcutta, across the Hooghly. It is
-1530 feet in length, there being twenty-eight pontoons
-in pairs. These are of iron, 160 feet long, and with
-ends shaped like wedges; they support a road-way of
-3-inch timbers, forty-eight feet wide, and raised on
-tressel work. An opening can be made for ships by
-removing four pontoons and floating them clear of the
-passage way.</p>
-
-<p>Great bridges present some of the most remarkable
-triumphs of the engineer. They rank beside the
-express locomotive and the ocean liner as among the
-great constructive achievements of mankind. Daring
-in design, and bold in execution and in sweep of span,
-they have been developed along several principles; and
-so solidly have they been built, so sound are the laws of
-their being, that it seems as though they will live as
-long as the everlasting hills.</p>
-
-<div class="figcenter">
-<a id="i_136"><img src="images/i_136.jpg" alt="a bridge" width="500" height="187" /></a>
-</div>
-
-<hr class="chap2 x-ebookmaker-drop" />
-
-<div class="chapter">
-<div class="figcenter">
-<a id="i_137"><img src="images/i_137.jpg" alt="men laying new rail lines" width="500" height="271" /></a>
-
-<p><span class="pagenum"><a id="Page_137"></a>[137]</span></p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p class="p140">REMARKABLE TUNNELS AND THEIR
-CONSTRUCTION.</p>
-</div>
-</div>
-
-<hr class="r5 x-ebookmaker-drop" />
-
-<h2 class="nobreak" id="CHAPTER_I-4">CHAPTER I.</h2>
-</div>
-
-<p class="center">HOW BRUNEL MADE A BORING-SHIELD.</p>
-
-
-<p class="drop-cap"><span class="smcap">“I watched</span> the worm at work and took my idea
-from that tiny creature!”</p>
-
-<p>“A worm! Was it an ordinary worm?”</p>
-
-<p>“Oh no, it was the naval wood-worm—<em>Teredo
-Navalis</em>; it can bore its way through the hardest
-timber. I was in a dockyard and I saw the movements
-of this animal as it cut its way through the wood, and
-the idea struck me that I could produce some machine
-of the kind for successful tunnelling.”</p>
-
-<p>“Well, it has been brilliantly successful.”</p>
-
-<p>“I looked at the animal closely, and found that it was
-covered with a couple of valvular shells in front; these
-shells seem to act as a shield, and after many attempts
-I elaborated the boring-shield which was used in
-hollowing out the Thames Tunnel.”</p>
-
-<p>This statement, which we can imagine to have been
-made by Sir Marc Isambard Brunel to a friend, is
-no doubt in substance quite true. A writer in the<span class="pagenum"><a id="Page_138"></a>[138]</span>
-“Edinburgh Encyclopædia” says, that Sir M. I. Brunel
-informed him, “that the idea upon which his new plan
-of tunnelling is founded, was suggested to him by the
-operations of the <em>Teredo</em>, a testaceous worm, covered
-with a cylindrical shell, which eats its way through
-the hardest wood.”</p>
-
-<p>Two or three attempts had already been made to
-drive a tunnel under the Thames, but they had ended
-in failure. In 1823, Brunel came forward with another
-proposal, and he ultimately succeeded.</p>
-
-<p>This illustrious engineer must not be confounded
-with his son—who was also a celebrated engineer—Isambard
-Kingdom Brunel. There were two Brunels,
-father and son, even as there were two Stephensons,
-George and Robert.</p>
-
-<p>Sir Marc Isambard Brunel, the father, whose most
-notable enterprise was the Thames Tunnel, was a
-French farmer’s son, and after various experiences in
-France and America settled in England in 1799, and
-married the daughter of William Kingdom of Plymouth.
-He had already succeeded as an engineer so
-well as to be appointed chief engineer of New York, and
-a scheme for manufacturing block-pulleys by machinery
-for vessels was accepted by the British Government,
-who paid him £17,000 for the invention. He was also
-engaged in the construction of Woolwich Arsenal and
-Chatham Dockyard, etc., and in 1823 he came forward
-with another proposal for the Thames Tunnel.</p>
-
-<p>In that same year, his son, Isambard Kingdom
-Brunel, entered his father’s office, and assisted in the
-construction of the tunnel. The son subsequently
-became engineer to the Great Western Railway, and
-designed the <em>Great Western</em> steamship.</p>
-
-<p>But though Brunel’s proposal for the tunnel was
-made public in 1823, the work was not actually commenced
-until March, 1825. It was to cross under the
-river from Wapping to Rotherhithe, and present two
-archways. And if you had been down by the Rotherhithe
-bank of the Thames about the latter date, you<span class="pagenum"><a id="Page_139"></a>[139]</span>
-would have been surprised to see that instead of
-hollowing out a shaft, proceedings began by raising a
-round tower.</p>
-
-<p>A space was traced out, some 50 feet across, and
-bricklayers began to build a circular hollow tower
-about 3 feet thick and 42 feet high.</p>
-
-<p>This tower was strengthened by iron bars, etc., and
-then the excavation commenced within. The soil was
-dug out and raised by an engine at the top, which also
-pumped out water. And as the hollow proceeded, the
-great shaft or tube of masonry sank gradually into it.
-Bricklayers added to its summit until it reached a
-total height of 65 feet, which in due course was sunk
-into the ground.</p>
-
-<p>Thus, then, the engineer had, to commence with, a
-strong and reliable brickwork shaft, 3 feet thick, by
-which men and materials could ascend and descend in
-safety. A smaller shaft was also sunk deeper for
-drainage.</p>
-
-<p>And now the actual boring of the tunnel commenced.
-It was to be 38 feet wide and 22½ feet in height. On
-New Year’s Day, 1826, the boring-shield was placed
-below in the shaft. The shield was composed of 36
-cells, 3 cells in height and 12 in breadth, with a workman
-to each.</p>
-
-<p>The huge “shield” was placed before the earth to
-be excavated, and a front board being removed, the
-soil behind it was dug out to a specified extent, and
-the board was propped against the fresh surface thus
-made. When the boards had all been placed thus, the
-cells were pushed forward into the hollow then made.
-This was accomplished by means of screws at the top
-and bottom of the shield, and which were set against
-the completed brickwork behind.</p>
-
-<p>For, while the labourers were working in front, the
-bricklayers behind built up the sides and roof, and
-formed the floor of the tunnel, the soil at the roof
-being supported by the shield until the masons had
-completed their task.</p>
-
-<p><span class="pagenum"><a id="Page_140"></a>[140]</span></p>
-
-<p>For nine feet, the tunnel proceeded through clay,
-but then came an unwelcome change. Wet, loose sand
-prevailed, and the work progressed with peril for
-thirty-two days, when firmer ground was reached.
-Six months passed and substantial headway was made,
-the tunnel being completed to the extent of 260 feet.</p>
-
-<p>Then, on the 14th of September, the startling intelligence
-came that the engineer feared the river would
-burst in at the next tide. He had found a cavity over
-the shield. Sure enough, at high tide, when the river
-was brimming full, the workmen heard the ominous
-rattle of earth falling on their shield, while gushes of
-water followed.</p>
-
-<p>So excellent were the precautions, however, that no
-disastrous effects followed, and Father Thames himself
-rolled earth or clay into the hole and stopped it up.
-It was a warning, and emphasised the fear that haunted
-the men’s minds all through the hazardous undertaking—the
-fear that the river would break through and
-drown the tunnel.</p>
-
-<p>In October, another small irruption took place, and
-was successfully combated. Then, in the following
-January (1827), some clay fell, but still no overwhelming
-catastrophe occurred. The ground grew so moist,
-however, that it was examined on the other side.
-That is, the river bed was inspected by the agency of a
-diving-bell, and some ominous depressions were found.
-These were promptly filled by bags of clay.</p>
-
-<p>It may be asked, Why had Brunel not gone deeper?
-Why had he not placed a greater thickness of earth or
-clay between his work and the waters of the Thames?</p>
-
-<p>The answer is this—He had been informed by
-geologists that quicksand prevailed lower down, and
-the shaft that he sank for drainage below the level of
-the proposed tunnel, indicated that this view might be
-correct. In fact, when he got down 80 feet, the soil
-gave way, and water and sand rushed upwards. He
-was therefore apparently between the Thames and the
-quicksand. The Tower Subway, constructed in 1869,<span class="pagenum"><a id="Page_141"></a>[141]</span>
-and driven through the solid London clay, is, however,
-60 feet deep where it commences at Tower Hill.</p>
-
-<p>Work went steadily forward at Brunel’s tunnel until
-the 18th of May. Mr. Beamish, the assistant engineer,
-was in the cutting on that day, and as the tide rose he
-observed the water increase about the shield; clay
-showed itself and gravel appeared. He had the clay
-closed up, and went to encourage the pumpers.
-Suddenly, before he could get into the cells, a great
-rush of sludge and water drove the men out of the
-cells, extinguished the lights, floated the cement casks
-and boxes, and poured forward and ever forward, filling
-the tunnel with the roaring of the flood.</p>
-
-<p>The Thames had broken in with a vengeance this
-time, and drowned the tunnel.</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak" id="CHAPTER_II-4">CHAPTER II.</h2>
-</div>
-
-<p class="center">UNDER THE RIVER.</p>
-
-
-<p class="drop-cap"><span class="smcap">Happily</span> no one lost his life.</p>
-
-<p>The men retreated before the advancing
-wave, and as they went they met Brunel.
-But the great engineer could do nothing just
-then, except, like them, to retreat. The lights yet
-remaining flashed on the roaring water, and then
-suddenly went out in darkness.</p>
-
-<p>The foot of the staircase was reached, and it was
-found thronged with the retreating workers. Higher
-and higher grew the surging flood; Brunel ordered
-great speed; and scarcely were the men’s feet off the
-lower stair when it was torn away.</p>
-
-<p>On gaining the top, cries were heard; some calling
-for a rope, others for a boat. Some one was below in
-the water! Brunel himself slipped down an iron rod,
-another followed, and each fastening a rope to the
-body of a man they found in the flood, he was soon<span class="pagenum"><a id="Page_142"></a>[142]</span>
-drawn out of danger. On calling the roll, every
-worker answered to his name. No life was lost.</p>
-
-<p>So far, good; but what was to be done now? The
-tunnel was full of water. To pump it dry was impossible,
-for the tide poured in from the Thames.</p>
-
-<p>Again the diving-bell was used, and the hole was
-found in the bed of the river. To stop it bags of clay,
-with hazel sticks, were employed; and so difficult was
-the task that three thousand bags were utilised in the
-process, and more than a month elapsed before the
-water was subdued. Two months more passed before
-the earth washed in was removed, and Brunel could
-examine the work.</p>
-
-<p>He found it for the most part quite sound, though
-near the shield it had been shorn of half its thickness
-of bricks. The chain of the shield was snapped in
-twain, and irons belonging to the same apparatus had
-been forced into the earth.</p>
-
-<p>The men now proceeded with their task, and exhibited
-a cool courage deserving of all praise. Earth and
-water frequently fell; foul gases pervaded the stifling
-air, and sometimes exploded, or catching fire, they
-would now and again dance over the water; and again
-and again labourers would be carried away insensible
-from the poisonous atmosphere. Complaints, such as
-skin eruptions, sickness, and headaches, were common.
-Yet, in spite of every difficulty, the men worked on in
-that damp and dripping and fœtid mine, haunted ever
-with the dread of another flood.</p>
-
-<p>And it came. On the 12th of August, 1828, some
-fifteen months after the previous disaster, the ground
-bulged out, a large quantity fell, and a violent rush of
-water followed; one man being washed out of his cell
-to the wooden staging behind.<span class="pagenum"><a id="Page_143"></a>[143]<br /><a id="Page_144"></a>[144]</span></p>
-
-<div class="figcenter">
-<a id="i_143"><img src="images/i_143.jpg" alt="" width="600" height="405" /></a>
-<p class="caption center">THE THAMES TUNNEL.</p></div>
-
-<p>The flow was so great that Brunel ordered all to
-retire. The water rose so fast that when they had
-retreated a few feet it was up to their waists, and
-finally Brunel had to swim to the stairs, and the rush
-of water carried him up the shaft. Unhappily, about
-<span class="pagenum"><a id="Page_145"></a>[145]</span>half-a-dozen lives were lost at this catastrophe, and
-those who were rescued—about a dozen in number—were
-extricated in an exhausted or fainting state. The
-roar of the water in the shaft made a deafening noise;
-the news soon spread, and the scene became very
-distressing as the relatives of the men arrived.</p>
-
-<p>Once more the hole in the bed of the Thames had to
-be stopped. Down went the diving-bell, but it had to
-descend twice before the gap was discovered. It was a
-hole some seven feet long, and four thousand tons of earth,
-chiefly bags of clay, were used in filling it. Again the
-tunnel was entered, and again the intrepid engineer
-found the work sound.</p>
-
-<p>But, alas, another difficulty had presented itself—one
-more difficult to conquer even than stopping up huge
-holes in the bed of the Thames. The tunnel was being
-cut by a Company, and its money had gone; nay, more,
-its confidence had well nigh gone also. Work could
-not proceed without money, and for seven years silence
-and desolation reigned in those unfinished halls beneath
-the river.</p>
-
-<p>Then the Government agreed to advance money,
-and work was again commenced. But it proceeded
-very slowly, some weeks less than a foot being cut,
-during others again three feet nine inches. The ground
-was in fact a fluid mud, and the bed of the river had
-to be artificially formed before the excavation could
-proceed in comparative safety. Further, the tunnel
-was far deeper than any other work in the neighbourhood,
-and all the water drained there—a difficulty
-which was obviated by the construction of a shaft on
-the other side of the river.</p>
-
-<p>The shield had also to be replaced. It had been so
-battered about by the flood that another was necessary.
-As it kept up the earth above, and also in front, the
-change was both arduous and perilous. But it was
-accomplished without loss of life.</p>
-
-<p>Three more irruptions of water occurred: the third
-in August, 1837, the fourth in November, 1837, and<span class="pagenum"><a id="Page_146"></a>[146]</span>
-the fifth in March, 1838. But the engineer was more
-prepared for Father Thames’ unpleasant visits, and
-a platform had been constructed by which the men
-could escape. Unhappily, one life was lost, however,
-on the fourth occasion. A great rush of soil also
-occurred in April, 1840, accompanied by a sinking of
-the shore at Wapping over some seven hundred feet
-of surface. Happily this occurred at low tide, and the
-chasm was filled with gravel and bags of clay before
-the river rose high.</p>
-
-<p>At length, on the 13th of August, 1841, Brunel
-descended the shaft at Wapping, and entering a small
-cutting, passed through the shield in the tunnel,
-amidst the cheers of the workmen. After all these
-years of arduous toil, of anxious solicitude, and of hair-breadth
-escapes, the end was near, and a passage under
-the Thames was cut. It was not completed and open
-to the public, however, until the 25th of March, 1843,
-and then for foot passengers only.</p>
-
-<p>The approaches for carriages remained to be constructed,
-and would have been expensive works. They
-were to be immense circular roads, but they were never
-made. Perhaps that deficiency contributed to the
-commercial failure of the great engineering enterprise.
-In any case, the tunnel never paid; the Company dissolved;
-and the tunnel passed over to the East London
-Railway, who run trains through it. Its length is 1300
-feet, while between it and the river there is a thickness
-of soil of some fifteen feet.</p>
-
-<p>Though a failure as a business, yet the tunnel was
-a great engineering triumph. It was a marvel of perseverance,
-and of determined, arduous, skilful toil
-against overwhelming difficulties. Eighteen years
-passed before it was completed; and if the seven be
-deducted during which the work was stopped, still eleven
-remain as the period of its construction. Work occupying
-such a length of time must be costly. Could it be
-shortened? Would tunnel-making machinery be developed
-and improved so as to expedite the labour of years?</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_147"></a>[147]</span></p>
-
-<h2 class="nobreak" id="CHAPTER_III-4">CHAPTER III.</h2>
-</div>
-
-<p class="center">THROUGH THE ALPS.</p>
-
-
-<p class="drop-cap"><span class="smcap">“Cut</span> through the Alps? It is an impossibility;
-and it would never pay!”</p>
-
-<p>“Yet they are about to do it. Sommeiller,
-an engineer, has invented, or obtained, a rock-boring
-machine which promises to lighten the labour
-considerably; and then, of course, they will shatter
-great quantities of earth by explosives.”</p>
-
-<p>“And what part of the Alps?”</p>
-
-<p>“Through Mont Cenis. The tunnel will be about
-7½ miles long, and the mountain over it will rise 5400
-feet at one point.”</p>
-
-<p>“And when do they expect to finish it?”</p>
-
-<p>“I cannot say. They will begin on the southern—that
-is, the Italian—side first, and later on the French
-side. Through the tunnel will pass one of the principal
-routes from the West to the East.”</p>
-
-<p>This conversation, we may suppose, took place in
-1857, the year when the tunnel was commenced. For
-four years hand work was used, though blasting was in
-operation from the first; but in 1861 drilling by machinery
-was brought into play, and the rate of progress
-became much greater.</p>
-
-<p>The machine was the first practical boring apparatus
-for rock, and was used first in making the Mont Cenis
-Tunnel. With explosives, as gun-cotton, dynamite, etc.,
-the time occupied in cutting tunnels has been much
-reduced. Thus the Mont Cenis Tunnel occupied about
-thirteen years, and cost three millions of pounds. The
-St. Gotthard—another Alpine subway—occupied eight
-years, though it is 9¼ miles in length; and the Arlberg—yet
-another Alpine tunnel—a little over 6 miles long,
-occupied something more than three years.</p>
-
-<p>Further, the railway of which the St. Gotthard Tunnel
-forms part, has been commercially very successful.<span class="pagenum"><a id="Page_148"></a>[148]</span>
-This tunnel was commenced in 1872 and completed in
-1880, the same year that saw the beginning of the
-Arlberg.</p>
-
-<p>Tunnels through hard rock do not always need a
-lining of brickwork; but if the soil be clay, or loose
-earth of any kind, the lining of brick or stone must be
-brought up close to the scene of actual excavation.
-The Mont Cenis is lined with stone or brick almost
-entirely, about 900 feet, however, being without such
-lining.</p>
-
-<p>And now, how was the actual work of tunnelling
-carried on? It will be seen at once that the problem
-was quite different from that of boring fifteen feet
-under the Thames, and sometimes through watery mud.
-In boring through mountains the quickest way of cutting
-and carting away rock is one of the chief points to
-be considered. At the Mont Cenis Tunnel the blasting
-took place by driving a series of shot holes into the
-soil, all over the surface to be cut, filling them with
-explosives, and firing them simultaneously in rings.
-Such explosives may be fired by a time-fuse or by electricity,
-giving the workmen ample time to escape out
-of reach. The shaken and shattered soil can then be
-cleared away.</p>
-
-<p>The blast holes in this small-shot system are about
-1 to 1½ inch in diameter, and from 1½ to 7 or 9 feet in
-the rock. The explosive is forced to the end of each,
-and the hole is then tamped—that is, closed with clay
-or sand—and fired in due time.<span class="pagenum"><a id="Page_149"></a>[149]<br /><a id="Page_150"></a>[150]</span></p>
-
-<div class="figcenter">
-<a id="i_149"><img src="images/i_149.jpg" alt="" width="600" height="349" /></a>
-<p class="caption center"> BORING MACHINE USED FOR THE MONT CENIS TUNNEL.</p></div>
-
-<p>The cutters for boring in rock are often diamond
-drills, the cutting edges being furnished with a kind
-of diamond found in Brazil, of a black colour and of
-great hardness. These are placed round the edge of a
-cylinder of steel, to which iron pipes can be screwed as
-the edge cuts its way deeper in the rock. The stuff
-cut out as the drill revolves finds its way through the
-cylinder and the piping. There are, however, a great
-number of boring machines of different kinds, hard
-steel sometimes taking the place of the opaque diamonds<span class="pagenum"><a id="Page_151"></a>[151]</span>
-for cutting purposes. The compressed air with
-which many of the machines are worked assisted in the
-St. Gotthard in the ventilation of the tunnel, frequently
-a great consideration, as the space is so small and the
-gas from explosions often so great.</p>
-
-<p>The Mont Cenis Tunnel marks a transition period in
-tunnelling. During the four years that hand labour
-was used, the average rate of progress was but nine
-inches a-day on either side; but when the rock-drills
-worked by compressed air were introduced, the speed
-was five times as great. Still further, at the Arlberg
-Tunnel through the Tyrolese Alps the average rate
-of progress was 9·07 yards per day, and the cost £108
-per lineal yard; while the cost of the Mont Cenis was
-£226 per lineal yard. These figures show immense
-progress in economy and in speed.</p>
-
-<p>The St. Gotthard Tunnel was begun in 1872, and the
-machine drills were used throughout. A heading was
-first cut about eight feet square, and the hollow thus
-gained was afterwards enlarged and finally sunk to the
-desired level. Several Ferroux drills were used, placed
-on a carriage, and an average charge of 1¾ lbs. of dynamite
-placed in the holes made. After firing, the compressed
-air was discharged and the shattered soil was
-cleared away.</p>
-
-<p>In the Arlberg Tunnel a chief heading was driven,
-and then shafts opened up enabling smaller headings
-to be driven on both hands. Drills worked by hydraulic
-power were used, as well as drills worked by air, and,
-after the explosions, water spray was thrown out to
-assist in clearing and purifying the air. Ventilators
-also were used, which injected air at the rate of more
-than 8000 cubic feet per minute. Speedy transit of
-the earth excavated and the materials for masonry were
-also effected, it being estimated that some 900 tons
-of earth had to be taken out of each end, and about
-350 tons of masonry had to be brought in, every day.</p>
-
-<p>Tunnels through huge thicknesses of rock or under
-rivers can only be cut from the two opposite ends.<span class="pagenum"><a id="Page_152"></a>[152]</span>
-Where possible, however, other shafts have been sunk
-along the line the subway was to take, and thus excavation
-might continue at several places along the line
-of route, the shafts being used for ventilation and for
-the conveyance of the excavated soil.</p>
-
-<p>But the use of machine drills and of blasting explosives,
-with improved appliances for ventilation, have,
-with possibly some rare exceptions, rendered these
-methods obsolete. According to Pliny the tunnel for
-draining Lake Fucino was the greatest work of his day.
-It was over 3½ miles long, and cut under Monte Salviano.
-Forty shafts were sunk in cutting it, also sloping
-galleries, and huge copper buckets were used to
-carry away the earth. It is stated that this tunnel—some
-ten feet high, by six wide—occupied 30,000 men
-eleven years. Compare this with the Arlberg, or even
-the Gotthard, double and treble the length, occupying
-much less time. Sir Benjamin Baker has calculated
-that the Fucino tunnel could now be cut in eleven
-months.</p>
-
-<p>Gunpowder gave some advance on old Roman methods
-of tunnelling. The improved explosives and rock-drills
-have gone further.</p>
-
-<p>Even as the Mont Cenis shows a transition period, so
-the Arlberg may be said to emphasise a triumph of the
-methods then indicated. So great have been the improvements
-of the rock-boring machinery, of the power
-of the blasts, and the speedy ventilation following the
-explosions, and of the quick transit of materials, that
-we shall most likely hear no more of sinking numerous
-shafts along the route.</p>
-
-<p>But what of subaqueous tunnels? Violent explosives
-are hardly suitable for excavation a few feet under a
-turbid river. What is to be done, when cutting under
-a full and treacherous stream?</p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum"><a id="Page_153"></a>[153]</span></p>
-
-<h2 class="nobreak" id="CHAPTER_IV-4">CHAPTER IV.</h2>
-</div>
-
-<p class="center">UNDER WATER AGAIN.</p>
-
-
-<p class="drop-cap"><span class="smcap">“How</span> to cross the Thames at Blackwall, far east
-of the Tower Bridge?” That was a problem
-which the citizens of London had to face in
-the latter part of the nineteenth century.</p>
-
-<p>An immense population dwelt on either side, and
-some means of easy communication became a pressing
-necessity. Should it be effected by means of a bridge,
-fixed or floating, or by means of a tunnel?</p>
-
-<p>Finally a tunnel was decided upon, with sloping
-approaches on either side. Its entire length was to be
-6200 feet including the approaches; but herein lay the
-danger and the difficulty—it was to be driven only seven
-feet below the bed of the river, and through loose soil
-and gravel.</p>
-
-<p>How then was this perilous task to be accomplished?
-If the great river burst through Brunel’s fifteen feet,
-would it not be much more likely to rush through this
-seven feet of loose soil?</p>
-
-<p>But the engineers in charge had an appliance in
-hand, which was unknown to Brunel—viz., a compressed
-air chamber, a piece of apparatus which has
-facilitated several great engineering achievements,
-besides the Blackwall Tunnel.</p>
-
-<p>When the excavation of the tunnel was commenced,
-a stout apartment was formed at the end of the
-cutting, into which air was pumped until it exerted
-a pressure of some thirty-five pounds to a square inch,
-in addition to its usual weight.</p>
-
-<p>This is generally reckoned at an average of 14·7
-pounds to a square inch. We are so used to this pressure
-that we do not feel it; but let us enter a room
-where the air has been much more compressed, as in
-this air-chamber, and serious consequences would be
-likely to ensue, especially at first.</p>
-
-<p><span class="pagenum"><a id="Page_154"></a>[154]</span></p>
-
-<p>The human body, however, has a wonderful power of
-adaptability, and after a time some men get used to the
-change and can work in the compressed air without
-injury. But at first it may cause bleeding from the
-nose and ears, sometimes indeed affecting the hearing
-more or less seriously, and also causing great pain.</p>
-
-<p>The reason for using this compressed air chamber
-was to keep out Father Thames. The great pressure
-of the air resisted the great pressure of the water, and
-held up the seven feet of soil between.</p>
-
-<p>Powerful engines were maintained at work to provide
-for the pressure of the air, and the chamber in which
-the compressed air was kept was entered and left by
-the workmen through an “air-lock”—that is, a small
-ante-chamber having two doors, one leading to the
-compressed air and the other to the ordinary atmosphere,
-and neither being opened at the same time.</p>
-
-<p>The men, then, worked in this compressed air chamber,
-which prevented irruptions of the river. But the
-method of excavation was also another safeguard, both
-against irruptions of water and of earth.</p>
-
-<p>In essence, it was much the same as that pursued in
-boring the tunnel for the South London Electric Railway;
-that, however, was through thick clay and about 10½
-feet in diameter, and this was 27 feet across, and through
-loose and stony stuff. The shield, instead of containing
-as in Brunel’s time a number of cells, consisted of an
-immense iron cylinder, weighing some 250 tons; closed
-in front, but having a door in the closed part; the rim
-of the cylinder round this part having a sharp edge for
-cutting into the soil.<span class="pagenum"><a id="Page_155"></a>[155]</span></p>
-
-<div class="figcenter">
-<a id="i_155"><img src="images/i_155.jpg" alt="" width="600" height="419" /></a>
-<p class="caption center">THE ENTRANCE TO THE AIR-LOCK.</p>
-<p class="caption center">(<em>Men waiting to enter the Compressed Air-Chamber through the Door.</em>)</p></div>
-
-<p>The door being opened, the men found themselves
-face to face with the earth to be excavated. They cut
-away as well as they could, perhaps about 2½ feet deep,
-throwing the earth into trucks in the compressed air
-chamber; these trucks would be afterwards hauled away
-through the air-lock by electricity, and the huge iron
-cylinder would be pushed forward by means of hydraulic<span class="pagenum"><a id="Page_156"></a>[156]</span>
-power. Twenty-eight hydraulic “jacks” were employed,<span class="pagenum"><a id="Page_157"></a>[157]</span>
-and they forced forward the 250 ton cylinder
-with its cutting edge, when the men would resume
-working through the door as before.</p>
-
-<p>Behind them, the hole of the tunnel thus cut out was
-being lined. First, it was built round with iron plates
-a couple of inches thick. This plating was fixed in segments,
-and formed a huge pipe a little smaller than the
-actual hollow in the earth. Through holes in the
-immense piping, liquid cement was forced, thus
-plugging up the space entirely between the earth and
-the iron, and forming an outer ring of cement.</p>
-
-<p>Within, the tunnel was completed by a facing of
-glazed tiles, placed on a thickness of 14 inches of
-concrete. A road-way was laid 16 feet wide, flanked by
-footpaths of 3 feet, 2 inches, on either side. The subway
-is lighted by electricity, and staircases on the
-banks lead down to it for foot passengers. The stairways
-give entrance to the tunnel not far from the river,
-and much nearer than the commencement of the
-carriage-way approaches.</p>
-
-<p>At the northern side, the slope down commences
-near the East India Dock entrance, and turns out of
-the East India Dock Road. The slope is fairly gradual—about
-one in thirty-four—and it passes under the
-Blackwall line of the Great Eastern Railway, and near
-to Poplar Station. The part of the tunnel near to this
-point—that is the part between the river and the open
-slope—was executed by what is called “cut and cover”
-work—that is, a huge trench was dug, then arched in
-and covered over.</p>
-
-<p>“Cut and cover” work also took place on the south
-side; and there, at the foot of an immense excavation
-ninety feet down, and with its sides held up by huge
-timbers, might have been seen a river of water which
-had drained in and was being pumped up quickly by
-powerful machinery.</p>
-
-<p>Not far distant, the shaft was being sunk for the
-staircase. In principle, the sinking of the shaft was
-conducted much as Brunel’s shaft at the Thames<span class="pagenum"><a id="Page_158"></a>[158]</span>
-Tunnel, only it was built up of iron instead of brick.
-Imagine a big gasometer with a scaffold near the top,
-where men are busy building the walls higher and
-higher by adding on plate after plate of iron. On reaching
-the scaffold you find that there are two great cylinders
-of iron, one standing inside the other, and concrete is
-being filled in between them. Men also are down
-below digging out the earth which is being swung up in
-iron buckets; and as the soil is gradually removed, the
-immense double iron and concrete cylinder slowly sinks
-by its own weight.</p>
-
-<p>In this manner, the great shaft was sunk nearly
-ninety feet, and within it the staircase has been built,
-giving entrance for foot passengers, not far from the
-river. Thus, on either side are sloping entrances to
-the tunnel, and also, nearer the water, stairways of
-descent down great shafts.</p>
-
-<p>Engineers have also found their way beneath other
-great English rivers—the Severn and the Mersey.
-Much water had to be dealt with in the cutting of the
-Severn Tunnel. This important work, four and one-third
-miles long, was driven in some places forty-five
-feet under sandstone, and at the Salmon Pool—a
-hollow in the river bed—the tunnel was thirty feet
-under soil called trias marl. Much greater space,
-therefore, exists here between the tunnel and river
-than at Blackwall. But the river burst through. The
-work was begun in 1873, and completed in 1886.</p>
-
-<p>Six years after its commencement the tunnel was
-drowned, so to speak, for a long time by a large spring
-of water which burst out from limestone, and arrangements
-had to be made to provide for this flood. It is
-now conducted by a subsidiary tunnel or channel to a
-huge shaft, where it is raised by pumps of sufficient
-strength. Then there was the perilous Salmon Pool to
-be dealt with. The river burst through here, and the
-rent had to be stopped with clay. The tunnel is
-twenty-six feet wide by twenty feet high, and is cut
-through Pennant stone, shale, and marl. It is lined<span class="pagenum"><a id="Page_159"></a>[159]</span>
-with Staffordshire vitrified bricks throughout—seventy-five
-million bricks it is estimated being used. The
-works are ventilated by a huge fan, and pumping
-continually proceeds, something like twenty-six million
-gallons of water, it is said, being raised in the twenty-four
-hours. The tunnel, of which the engineers were
-Messrs. Hawkshaw, Son, Hayter &amp; Richardson, and
-Mr. T. A. Walker, Contractor, is for the use of the
-Great Western Railway, and saves that Company’s
-Welsh and Irish trains to Milford a long way round by
-Gloucester.</p>
-
-<div class="figcenter">
-<a id="i_159"><img src="images/i_159.jpg" alt="" width="600" height="171" /></a>
-<p class="caption center">THE BORING MACHINE USED IN THE PRELIMINARY CONSTRUCTION
-OF THE ENGLISH CHANNEL TUNNEL.</p></div>
-
-<p>In cutting the Mersey Tunnel, which was completed
-in 1886, machinery was used for some of the work.
-The machine bored partly to a diameter of seven feet
-four inches, but hand labour had to be largely depended
-upon. The plan pursued was to sink a shaft on either
-side of the river and drive a heading, sloping upward
-through the sandstone to the centre; this heading
-acting as a drain for any water which might appear.
-The thickness between the arch of the tunnel and the
-river bed is thirty feet at its least, and the tunnel,
-which occupied about six years in construction, and of
-which the engineers were Messrs. Brunlees &amp; Fox, is
-provided with pumps raising some thirteen million
-gallons of water daily. As in the case of the Severn
-Tunnel, ventilation is provided for by huge fans.</p>
-
-<p>A boring machine was also used in the preliminary
-efforts for the construction of a tunnel under the<span class="pagenum"><a id="Page_160"></a>[160]</span>
-English Channel. Holes, seven feet across and to the
-length of 2000 yards, have been bored by a compressed
-air machine, working with two arms furnished with
-teeth of steel. The construction of the tunnel is held
-to be quite feasible from an engineering point of view,
-and it is believed that it would pass through strata
-impervious to water, such as chalk marl and grey
-chalk.</p>
-
-<p>Still, the huge tunnel at Blackwall, which was
-carried out by Mr. Binnie, Chief Engineer of the
-London County Council, with Mr. Greathead and
-Sir Benjamin Baker as Consulting Engineers, is probably
-one of the most daring and stupendous enterprises
-of the kind ever undertaken. To hollow out a subway
-hundreds of feet long under the Thames, only seven
-feet from the bed of the great river, and through loose
-gravelly soil, was a great triumph. It was achieved not
-by uncalculating bravery, but by a wise combination of
-cool courage, superb skill, and admirable foresight.</p>
-
-<p>To design effectively, to provide for contingencies,
-to be daunted by no difficulties—these qualities help
-to produce the Triumphs of Engineers, as well as do
-great inventive skill, the power of adapting principles
-to varying circumstances, and high-spirited enterprise
-in planning and conducting noble and useful works.
-These works may well rank among the great achievements
-of man’s effort and the wonders of the world.</p>
-
-
-<p class="center">THE END.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<p class="p2"></p>
-
-<p class="center">LORIMER AND GILLIES, PRINTERS, EDINBURGH.</p>
-
-<p class="p2"></p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="figcenter">
-<a id="i_back"><img src="images/i_back.jpg" alt="" width="323" height="500" /></a>
-</div>
-
-<div style='display:block; margin-top:4em'>*** END OF THE PROJECT GUTENBERG EBOOK ENGINEERS AND THEIR TRIUMPHS: THE STORY OF THE LOCOMOTIVE, THE STEAMSHIP, BRIDGE BUILDING, TUNNEL MAKING ***</div>
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