- Wellesley College in 1886
- Edison's First Phonograph
- Edison in his Library
- Birthplace of Charles Goodyear
- Natives Drying Rubber
- Tapping a Rubber Tree
- Kitchen in which Goodyear made his Experiments
- Charles Goodyear
- Daniel Webster
- A Monk Copying Manuscript Books
- Franklin's Printing Press
- The Earliest Printers at Work
- Curved Stereotype Plate
- Sextuple Perfecting Press
- Silhouettes of Grandfather and Grandmother
- The Old Way of Reaping
- McCormick's Reaping Machine
- The First Type of McCormick Reaper
- Euclid Avenue, Cleveland, Ohio
The Opera House, a new and handsome building, is on Euclid avenue. There are, besides, an Academy of Music and the Globe Theatre and several minor theatres. The business portion of Euclid avenue extends from the Park to Erie street, beyond which it is lined with handsome residences, elegant cottages and superb villas, the grounds around each being more and more extensive as it approaches the country. It is one of the finest avenues in the world, and is not less than ten miles in length, embracing during its course several suburbs which a generation since were remote from the city, and are now considerably surprised to find themselves brought so near it. Euclid avenue crosses the other streets diagonally, and was evidently one of the original roads leading into the city before it attained its present dimensions. The majority of the streets are parallel with the lake front, which pursues a course from the northeast to the southwest. But Euclid avenue runs directly eastward for about three miles, to Doane's Corners, one of the historic spots in the neighborhood of Cleveland, and then turns to the northeast, following nearly parallel to the course of the lake. Prospect street runs parallel to Euclid avenue, and is only second to it in the beauty and elegance of its residences. St. Clair street is also a favorite suburban avenue, extending parallel to the lake, a little distance from it, far out into the country, and containing many handsome residences. - General View of the Poughkeepsie Bridge
The new bridge at Poughkeepsie has three of these cantilevers, connected by two fixed spans, as shown in the illustration. The fixed spans have horizontal lower chords, and really extend beyond each pier and up the inclined portions, to where the bottom chord of the cantilever is horizontal. At these points the junctions between the spans are made, and arranged in such a way, by means of movable links, that expansion and contraction due to changes of temperature can take place. The fixed spans are 525 feet long. Their upper chord, where the tracks are placed, is 212 feet above water. These spans required stagings to build them upon. These stagings were 220 feet above water, and rested on piles, driven through 60 feet of water and 60 feet of mud, making the whole height of the temporary staging 332 feet, or within 30 feet of the height of Trinity Church steeple, in New York. The time occupied in building one of these stagings and then erecting the steel-work upon it was about four months. The cantilever spans were erected without any stagings at all below, and entirely from the two overhead travelling scaffolds, shown in the engraving. These scaffolds were moved out daily from the place of beginning over the piers, until they met in the centre. The workmen hoisted up the different pieces of steel from a barge in the river below and put them into place, using suspended planks to walk upon. The time saved by this method was so great that one of these spans of 548 feet long was erected in less than four weeks, or one-seventh of the time which would have been required if stagings had been used. - Erection of a Cantilever
The new bridge at Poughkeepsie has three of these cantilevers, connected by two fixed spans, as shown in the illustration. The fixed spans have horizontal lower chords, and really extend beyond each pier and up the inclined portions, to where the bottom chord of the cantilever is horizontal. At these points the junctions between the spans are made, and arranged in such a way, by means of movable links, that expansion and contraction due to changes of temperature can take place. The fixed spans are 525 feet long. Their upper chord, where the tracks are placed, is 212 feet above water. These spans required stagings to build them upon. These stagings were 220 feet above water, and rested on piles, driven through 60 feet of water and 60 feet of mud, making the whole height of the temporary staging 332 feet, or within 30 feet of the height of Trinity Church steeple, in New York. The[35] time occupied in building one of these stagings and then erecting the steel-work upon it was about four months. The cantilever spans were erected without any stagings at all below, and entirely from the two overhead travelling scaffolds, shown in the engraving. These scaffolds were moved out daily from the place of beginning over the piers, until they met in the centre. The workmen hoisted up the different pieces of steel from a barge in the river below and put them into place, using suspended planks to walk upon. The time saved by this method was so great that one of these spans of 548 feet long was erected in less than four weeks, or one-seventh of the time which would have been required if stagings had been used. - Pope's Cantilever in Process of Erection
The most notable invention of latter days in bridge construction is that of the cantilever bridge, which is a system devised to dispense with staging, or false works, where from the great depth, or the swift current, of the river, this would be difficult, or, as in the case of the Niagara River, impossible to make. The first design of which we have any record was that of a bridge planned by Thomas Pope, a ship carpenter of New York, who, in 1810, published a book giving his designs for an arched bridge of timber across the North River at Castle Point, of 2,400 feet span. Mr. Pope called this an arch, but his description clearly shows it to have been what we now call a cantilever. As was the fashion of the day, he indulged in a poetical description: "Like half a Rainbow rising on yon shore, While its twin partner spans the semi o'er, And makes a perfect whole that need not part Till time has furnish'd us a nobler art." Note : This bridge was never built - it would be impossible in wood. - View of Thomas Pope's Proposed Cantilever (1810)
The most notable invention of latter days in bridge construction is that of the cantilever bridge, which is a system devised to dispense with staging, or false works, where from the great depth, or the swift current, of the river, this would be difficult, or, as in the case of the Niagara River, impossible to make. The first design of which we have any record was that of a bridge planned by Thomas Pope, a ship carpenter of New York, who, in 1810, published a book giving his designs for an arched bridge of timber across the North River at Castle Point, of 2,400 feet span. Mr. Pope called this an arch, but his description clearly shows it to have been what we now call a cantilever. As was the fashion of the day, he indulged in a poetical description: "Like half a Rainbow rising on yon shore, While its twin partner spans the semi o'er, And makes a perfect whole that need not part Till time has furnish'd us a nobler art." - Kinzua Viaduct; Erie Railway.
Valleys and ravines are now crossed by viaducts of iron and steel, of which the Kinzua viaduct, illustrated here, is an example. A branch line from the Erie, connecting that system with valuable coal-fields, strikes the valley of the Kinzua, a small creek, about 15 miles southwest of Bradford, Pa. At the point suitable for crossing, this ravine is about half a mile wide and over 300 feet deep. At first it was proposed to run down and cross the creek at a low level by some of the devices heretofore illustrated in this article. But finally the engineering firm of Clarke, Reeves & Co. agreed to build the viaduct, shown above, for a much less sum than any other method of crossing would have cost. This viaduct was built in four months. It is 305 feet high and about 2,400 feet long. The skeleton piers were first erected by means of their own posts, and afterward the girders were placed by means of a travelling scaffold on the top, projecting over about 80 feet. No staging of any kind was used, nor even ladders, as the men climbed up the diagonal rods of the piers, as a cat will run up a tree. - Beginning a Tunnel
Tunnels are neither so long nor so frequent upon American railways as upon those of Europe. The longest are from two to two and a half miles long, except one, the Hoosac, about four miles. Sometimes they are unavoidable. The ridge called Bergen Hill, west of Hoboken, N. J., is a case in point. This is pierced by the tunnels of the West Shore, of the Delaware, Lackawanna, and Western, and of the Erie, the last two of which, are placed at different levels to enable one road to pass over the other. It is by our system of using sharp curves that we avoid tunnels. It may be said, in general terms, that American engineers have shown more skill in avoiding the necessity of tunnels than could possibly be shown in constructing them. When we are obliged to use tunnels, or to make deep cuttings in rocks, our labors are greatly assisted by the use of power-drills worked by compressed air and by the use of high explosives, such as dynamite, giant powder, rend-rock, etc. Rocks can now be removed in less than half the time formerly required, when ordinary blasting-powder was used in hand-drilled holes. - Steam Excavator
On the prairies of the West the road-bed is thrown up from ditches on each side, either by men with wheelbarrows and carts, or by means of a ditching-machine, which can move 3,000 yards of earth daily. In this case the track follows immediately after the embankment, and the men live in cars fitted up as boarding-shanties, and moved forward as fast as required. - Making an Embankment
After the railway line has been finally located, the next duty of the engineers is to prepare the work for letting. Land-plans are made, from which the right of way is secured. From the sections, the quantities are taken out. Plans of bridges and culverts are made; and a careful specification of all the works on the line is drawn up. The works are then let, either to one large contractor or to several smaller ones, and the labor of construction begins. The duties of the engineers are to stake out the work for the contractors, make monthly returns of its progress, and see that it is well done and according to the specifications and contract. The line is divided into sections, and an engineer, with his assistants, is placed in charge of each. Where the works are heavy, the contractors build shanties for their men and teams near the heavy cuttings or embankments. It is the custom to take out heavy cuttings by means of the machine called a steam shovel, which will dig as many yards in a day as 500 men. - Snow-sheds, Selkirk Mountains, Canadian Pacific
In all countries, old and new, mountainous and level, the rule should be to keep the level of track well above the surface of the ground, in order to insure good drainage and freedom from snow-drifts. The question of avoidance of obstruction by snow is a very serious one upon the Rocky Mountain lines, and they could not be worked without the device of snow-sheds—another purely American invention. There are said to be six miles of staunchly built snow-sheds on the Canadian Pacific and sixty miles on the Central Pacific Railway. The quantity of snow falling is enormous, sometimes amounting to 250,000 cubic yards, weighing over 100,000 tons, in one slide. It is stated by the engineers of the Canadian Pacific, that the force of the air set in motion by these avalanches has mown down large trees, not struck by the snow itself. Their trunks, from one to two feet in diameter, remain, split as if struck by lightning. - Engineers in Camp
A full surveying party consists of the front flag-man, with his corps of axe-men to cut away trees and bushes; the transit-man, who records the distances and angles of the line, assisted by his chain-men and flag-men; and lastly the leveller, who takes and records the levels, with his rod-men and axe-men. The chief of the party exercises a general supervision over all, and is sometimes assisted by a topographer, who sketches in his book the contours of the hills and direction and size of the watercourses. One tent contains the cook, the commissary, and the provisions; another tent or two the working party, and another the superior engineers, with their drawing instruments and boards. In a properly regulated party the map and profile of the day's work should be plotted before going to bed, so as to see if all is right. If it turns out that the line can be improved and easier grades got, or other changes made, now is the time to do it. - A Switchback
Another American invention is the switchback. By this plan the length of line required to ease the gradient is obtained by running backward and forward in a zigzag course, instead of going straight up the mountain. As a full stop has to be made at the end of every piece of line, there is no danger of the train running away from its brakes. This device was first used among the hills of Pennsylvania over forty years ago, to lower coal cars down into the Nesquehoning Valley. It was afterwards used on the Callao, Lima, and Oroya Railroad in Peru, by American engineers, with extraordinary daring and skill. It was employed to carry the temporary tracks of the Cascade Division of the Northern Pacific Railroad over the "Stampede" Pass, with grades of 297 feet per mile, while a tunnel 9,850 feet long was being driven through the mountains. - A Sharp Curve—Manhattan Elevated Railway, 110th Street, New York
Equally valuable improvements were made in cars, both for passengers and freight. Instead of the four-wheeled English car, which on a rough track dances along on three wheels, we owe to Ross Winans, of Baltimore, the application of a pair of four-wheeled swivelling trucks, one under each end of the car, thus enabling it to accommodate itself to the inequalities of a rough track and to follow its locomotive around the sharpest curves. There are, on our main lines, curves of less than 300 feet radius, while, on the Manhattan Elevated, the largest passenger traffic in the world is conducted around curves of less than 100 feet radius. There are few curves of less than 1,000 feet radius on European railways. - Rail Making
- The Last Span - ready to join
- Pioneer Wagons
About 1820, the State of Illinois was being rapidly settled by people from the eastern states. Prior to this time, very few white settlements had been made in the state. These early pioneers, drawn from the population of the eastern states, were composed of almost all nationalities. They pushed their way across the mountains of Pennsylvania and Virginia in crude wagons, drawn by oxen, bringing with them their household goods and a few milk cows. - Early Settler Homestead
About 1820, the State of Illinois was being rapidly settled by people from the eastern states. Prior to this time, very few white settlements had been made in the state. These early pioneers, drawn from the population of the eastern states, were composed of almost all nationalities. They pushed their way across the mountains of Pennsylvania and Virginia in crude wagons, drawn by oxen, bringing with them their household goods and a few milk cows. They came into Illinois, built new homes, and laid out new fields on the broad, unsettled prairies. - Cattle
In April, 1869, a charter was granted by the state of Illinois to the East St. Louis Stock Yards Company. This company was authorized to issue stock to an amount not to exceed $200,000. The original charter of the company, which later operated the National Stock Yards, fixed the capital stock thereof at $1,000,000, which was, subsequently, raised, by a vote of the stock holders, to an amount of $250,000, to meet the requirements of the rapidly growing business. When the National Stock Yards were completed, they were more convenient than were any others of their kind in the country. - The Summer that the rain came not
The great drouths caused the price of corn to fluctuate but the aggregate corn yield kept on increasing with increased acreage and usually the year following a drouth was one of superabundance of corn. Such was the year of 1895 following the drouth of 1894. The proportion of cattle per thousand population steadily increased. Meanwhile our cattle markets became centralized and were always full to overflowing. Everybody wondered where the cattle came from. - Captain John Smith’s Map of New England
The Pilgrims were familiar with Capt. John Smith’s account of a voyage in which he had surveyed the coast from Cape Cod to Penobscot Bay in 1614. He had even offered his services as guide and military captain, but Myles Standish got the job. Undoubtedly they did bring with them his Description of New England (London, 1616), in which the following map was published. Capt. Smith, who had already gained some fame and fortune in Virginia, dedicated to Prince Charles this effort in which the term “New England” first appeared: “... it being my chance to range some other parts of America, whereof I here present your highness the description in a map, my humble suit [in original, “sure”] is you would please to change their barbarous names for such English, as posterity may say Prince Charles was their godfather.” Several English place-names were incorporated in the map, but posterity disregarded most of them, a noteworthy exception being “Plimouth.” Smith notes that the Indians called the site “... Accomack, an excellent good harbor, good land, and no want of any thing but industrious people,” recalling that “After much kindness, upon a small occasion we fought also with 40 or 50 of those [Indians]; though some were hurt and some slain, yet within an hour after, they became friends.” - Samuel de Champlain’s Map of Plymouth Harbor
Although the Pilgrims were the first Europeans to establish a permanent colony in northeastern North America, they did not come to an unknown land. As early as 1605, Samuel de Champlain had mapped Plymouth Harbor, in the course of a three-year expedition during which he explored the coast from Nova Scotia to Martha’s Vineyard. The quality of his detailed and accurate observations on the land and people appears in this map, and in his notes on the visit: “There came to us two or three canoes, which had just been fishing for cod and other fish which are found there in large numbers. These they catch with hooks made of a piece of wood, to which they attach a bone in the shape of a spear and fasten it very securely. The whole has a fang-shape, and the line attached to it is made out of the bark of a tree. They gave me one of their hooks, which I took out of curiosity. In it the bone was fastened on by hemp, like that in France, as it seemed to me, and they told me that they gathered this plant without being obliged to cultivate it, and indicated that it grew to the height of four or five feet. This canoe went back on shore to give notice to their fellow inhabitants, who caused columns of smoke to arise on our account. We saw eighteen or twenty savages, who came to the shore and began to dance. Our canoe landed in order to give them some bagatelles, at which they were greatly pleased. Some of them came to us and begged us to go to their river. We weighed anchor to do so, but were unable to enter on account of the small amount of water, it being low tide, and were accordingly obliged to anchor at the mouth. I went ashore, where I saw many others, who received us very cordially. I made also an examination of the river, but saw only an arm of water extending a short distance inland, where the land is only in part cleared. Running into this is merely a brook not deep enough for boats except at full tide. The circuit of the bay is about a league. On one side of the entrance to this bay there is a point which is almost an island, covered with wood, principally pines, and adjoins sandbanks, which are very extensive. On the other side, the land is high. There are two islets in this bay, which are not seen until one has entered, and around which it is almost entirely dry at low tide. This place is very conspicuous from the sea, for the coast is very low, excepting the cape at the entrance to the bay. We named it the Port du Cap. St. Louis...”. - Reconstruction of coal-forming swamp
Coal is a combustible rock that was formed by the accumulation and partial decay of vegetation. When coal was forming millions of years ago, most of the state was a low coastal plain bordered on the west and southwest by a shallow sea. A large variety of plants grew in great swamps which covered this coastal plain. When the plants died, they accumulated in the swamps to form thick masses of peat that were eventually covered by shallow seas and buried beneath mud and sand. Periodically, the region was above sea level, new swamps developed, new peat deposits accumulated, and more sediments were laid down. This process occurred repeatedly until over 3,000 feet of sediments had been deposited. Then the sediments were slowly compacted and hardened so that sandstones, shales, limestones, and coals were formed. - Extent of the main glacial advances
Extent of the main glacial advances which began with the Nebraskan (a—the oldest) and ended with the late Wisconsinan (f—the youngest). Diagram “d” shows the major stream development during the time between the Illinoian and the earliest Wisconsinan glaciers. The heavy lines on the diagrams indicate major stream valleys that were present during these times. a. Inferred limit of NEBRASKAN glaciation b. Inferred limit of KANSAN glaciation c. ILLINOIAN glacial advance d. SANGAMONIAN major drainage e. Maximum WISCONSINAN glacial advance f. Late WISCONSINAN Valparaiso front and Kankakee Flood - Abraham Lincoln
President-Elect - The Residence of Abraham Lincoln
- An eye sketch of the Falls of Niagara
AN EYE SKETCH of the FALLS of NIAGARA I.Weld del. Neele sculpt. London Published by J. Stockdale Piccadilly 16th. Novr. 1798. - View of the Falls of Niagara
View of the FALLS of Niagara J. Scott Published Dec.14 1798, by J. Stockdale - View of the Lesser Fall of Niagara
VIEW of the Lesser FALL of NIAGARA I.Weld del. J. Scott sculpt. Published Dec. 22, 1798, by J. Stockdale Picadilly. - View of Bethlehem a Moravian settlement
VIEW of BETHLEHEM a Moravian settlement. I. Weld del. J. Dadley sculpt. Published Dec. 12 1798, by I. Stockdale, Picadilly. Bethlehem is the principal settlement, in North America, of the Moravians, or United Brethren. It is most agreeably situated on a rising ground, bounded on one side by the river Leheigh, which falls into the Delaware, and on the other by a creek, which has a very rapid current, and affords excellent seats for a great number of mills. The town is regularly laid out, and contains about eighty strong built stone dwelling houses and a large church. Three of the dwelling houses are very spacious buildings, and are appropriated respectively to the accommodation of the unmarried young men of the society, of the unmarried females, and of the widows. In these houses different manufactures are carried on, and the inmates of each are subject to a discipline approaching somewhat to that of a monastic institution. They eat together in a refectory; they sleep in dormitories; they attend morning and evening prayers in the chapel of the house; they work for a certain number of hours in the day; and they have stated intervals allotted to them for recreation. - View of the Horse-Shoe Fall of Niagara
VIEW of the HORSE-SHOE FALL of NIAGARA I.Weld del. Neele Scupt. Published by J. Stockdale Picadilly. - Orientation of a house to the sun
In the first place, you see three broad, concentric circles, on the outside of which the rising and setting sun is depicted for both midsummer and midwinter day. The figures, 30°–50°, alongside of the sun represent degrees of north latitude, wherever you may happen to live, which, with the exception of most of Florida and southern Texas, cover the United States. The short arrows show the direction of the sun’s rays at sunrise and sunset. The inner circle represents your horizon, and the degrees marked upon it show the points of sunrise and sunset, north or south of the direct east and west line. These angular distances, in terms of degrees, are called amplitudes, north or south, and must not be confused with the degrees of latitude on the earth’s surface, indicated by the numbers along side of the sun, though intimately dependent upon them. The amplitude of the horizon point, where the sun rises and sets from time to time during the year, always depends upon the latitude on the earth’s surface where you happen to live, as may be seen by following with your eye the direction of the arrows of latitude through the amplitude circle. Starting from the number indicating the latitude where you live, trace the arrow until it touches the amplitude circle. You can then read the degree on it which shows how far north or south of the east and west line the sun rises or sets. We are indebted to Professor Philip Fox, of the Dearborn Astronomical Observatory at Evanston, Illinois, for determining these points. The two outer circles are sun-dials for midsummer and midwinter day at the 40th degree of north latitude; and, if you imagined them pivoted on their rising and setting points and tipped up from the south to represent the slanting path of the sun during the day, they show the direction from which the sun is shining during successive hours of the day (or night on the other side of the world). The shaded portions of these circles represent night, which for all northern latitudes is short in summer and long in winter, as the day is short in winter and long in summer. If you examine the hour spaces on the winter dial of your winter night, you will find them exactly like those on the summer dial of your summer day. So also your winter day hours are spaced like your summer night hours. South of the equator, people have precisely the same experiences only in the reverse order. New Zealanders, we fancy, wear straw hats in January and fur caps in July. If you liked summer well enough and cared to move, you could live in a perpetual summer on our little globe. It is probable, however, that, like most people, you rather prefer the change of seasons, in spite of occasional extremes. - Catching The Cougar
- Horse-boat at Empy’s Ferry, Osnabruck, Ontario
Paddle-wheels for driving boats through the water were used long before steam-engines were thought of. They were worked by hand and foot-power without, however, any advantage over the old-fashioned oar. The horse-boat, in a variety of forms, has been in use for many years, and is not yet quite obsolete. In its earlier form two horses, one on each side of a decked scow, were hitched to firmly braced upright posts at which they tugged for all they were worth without ever advancing beyond their noses, but communicating motion to the paddle-wheels by the movable platform on which they trod. For larger boats four or five horses were harnessed to horizontal bars converging towards the centre, and moved around the deck in a circle, the paddles receiving their impulse through a set of cog-wheels. - C. P. R. grain elevator at Fort William, Ontario
The farmer sells his crop of wheat to the grain-dealer, and carts it, say, to Brandon, where the purchaser takes delivery of it at his elevator. Let us examine this thing somewhat minutely, taking by way of illustration one of the elevators belonging to the Canadian Pacific Railway Company at Montreal. It is a medium-sized one, having capacity for storing about 600,000 bushels of grain. The same company’s elevators at Fort William and Port Arthur are much larger, having capacity for 1,500,000 bushels. In Chicago and Buffalo there are elevators of three millions of bushels capacity; but, whether larger or smaller, in their main features they are all alike. The elevator is a wooden structure of great strength. Its massive stone foundations rest on piles imbedded in concrete. The framework is so thoroughly braced and bolted together as to give it the rigidity of a solid cube, enabling it to resist the enormous pressure to which it is subjected when filled with 18,000 tons of wheat. The building is 210 feet long, 80 feet wide, and 142 feet in height from basement to the peak of the roof. Including the steam-engine (built at the C. P. R. works) of 240 horse-power, the entire cost of this elevator was $150,000. It consists of three distinct compartments—for receiving, storing, and delivering grain. On the ground floor are two lines of rails by which the cars have ingress and egress. The general appearance of this flat is that of a bewildering array of ponderous posts and beams, shafting, cog-wheels, pulleys and belts, blocks and tackle, chutes, and the windlasses for hauling in and out the cars, for a locomotive with its dangerous sparks may not cross the threshold. Beneath this, in the basement, are the receiving tanks, thirty-five feet apart from centre to centre, corresponding to the length of the cars. Of these there are nine, enabling that number of cars to be simultaneously unloaded. This is quickly done by a shovel worked by machinery, with the aid of two men, the grain falling through an iron grating in the floor into the tank. The elevator has nine “legs.” The leg is an upright box, 12 inches by 24 inches, extending from the bottom of the tank to the top of the building; inside of it is a revolving belt with buckets attached 15½ inches apart. The belt is 256 feet long, and as it makes 36 revolutions per minute, each bucket containing one-third of a bushel, each leg is able to raise 5,250 bushels per hour. A car is unloaded and its contents hoisted into the upper regions in fifteen minutes. When all the legs are at work 30,000 bushels are handled in an hour. - The Round House
The Round House is the place where the railroad engines are kept when they are not working. The engines are turned around on a big turn table so each can be run on the different tracks which all lead to the turn-table in the centre. - The Fireman's dog
The Fireman's dog goes to every fire, running beside the horses, barking a command to hurry. He gets to the fire hydrant first and sits there panting until the Firemen come up to attach the hose and turn on the water. - The Fire Alarm
The Fire Alarm is sounded by a big gong in the station from street alarm boxes near where the fire occurs. The firemen know these alarm stations so well that they seldom look for the address, but dash off quickly to the correct place. - The Hoze nozzle
The Hoze nozzle has been taken up to the roof of a building next the one afire and the firemen are sending the water into the upper floors of the burning building. The hose nozzle is very difficult for the firemen to hold. - The brave fireman
The brave fireman rescues many people who are caught in burning buildings, in this way risking his life that others may be saved from the smoke and flames. Many people owe their lives to the bravery of the firemen. - The Alarm
- The Automobile Fire Engine
The Automobile Fire Engine can go to the fires very swiftly. Many times the saving of a few minutes by the firemen in reaching a fire means stopping the blaze before it becomes too great.