So the factory system, which at first threatened to take away the occupation of thousands who had formerly devoted their time to making yarn and cloth by hand labor, developed new occupations and new industries, and brought portions of the hitherto scattered people into groups, and these groups in time developed better accommodations for themselves and their families in homes, in comforts of life, in educational facilities, and in hours of labor; and in doing this they also supplied the masses with cloth at a less cost of labor than they had formerly expended in obtaining it.
Meantime man was learning another important lesson, one which was to develop even more rapidly the art of manufacturing. He found through a long series of experiments that power could be generated by heating water until it turned into an expansive vapor which he called steam, and that this expansive force could be controlled in such manner as to put in operation a machine which he called the steam engine, which could in turn transmit its power to that machinery formerly operated exclusively by the power of the waterfall.
This discovery again revolutionized the manufacturing industry, which had hitherto been limited in the scope of its operations by the supply of water power so located that the raw material could be transported to it and the finished products in turn transported thence to market. With this new force, steam, by which the manufacturing machinery could be made entirely independent of the waterfall, the factories were located at points convenient to the natural supply of fuel and manufacturing material or to the market for the finished products. Where this was not practicable the factories were located at places to which the materials could be readily and cheaply carried by water transportation, either on some navigable stream or the sea-coast.
Another important contribution made by steam power to the development of the manufacturing industry was the decrease in cost of transportation. Before the development of the railway and the steamship the material of manufacture, unless produced within a short distance of some navigable water, canals, rivers, lakes or oceans, was of comparatively little value. It was not always practicable to plant the factory in the section which most readily produced the wool or cotton or flax or hemp or silk, or to place it alongside the iron or copper mine; and even if this were done the manufactured material was valueless unless it could be transported to those requiring it. Even the lighter articles of manufacture, such as wool or cotton or fibers or silk, could not be transported any considerable distance without greatly increasing the cost to the manufacturer, and thus proportionately advancing the cost of the manufactured article. But when, in the middle of the nineteenth century, the railways began to penetrate the continents and the steamships began to cross the ocean and extend their tours to the commercially undeveloped sections of the world, the manufacturers found new sources of supply open to them and quantities of raw material reaching them from distant lands at such comparatively low cost as to enable them to enlarge their output, increase the variety of their productions and reduce the cost of both the necessities and conveniences and luxuries which they were offering to the public. The railways of the world grew from 25,000 miles in 1850 to 500,000 miles in 1900 and 600,000 in 1909. The tonnage of steam vessels on the navigable waters of the world grew from less than one million tons in 1850 to 24 million in 1909; and the carrying power of the sail and steam vessels of the world, measured in sail tons, grew from 15 million tons in 1850 to 100 million in 1909. The general reduction in freight rates meantime is illustrated by the fact that the price of transporting wheat from Chicago to New York by rail
fell from 33½ cents per bushel in 1872 to 10 cents per bushel in 1900, and the charge for transporting wheat from New York to Liverpool fell from 17 cents per bushel in 1875 to 3 cents per bushel in 1905; and similar reductions were made in the charges for transporting manufacturers’ materials.
Thus the application of steam to manufacturing and transportation multiplied the power of production. The area over which it could be performed was greatly enlarged, the cost of materials was reduced through cheaper transportation, new devices and processes were developed as a result of the competition, cheaper raw material was obtained from countries where plentiful supplies and cheap labor give low prices, and the opportunity of locating the factory near the place of production or at some convenient meeting point between the various places of production—all these contributed to reduction of cost and increase of supplies of material of manufacture. The great iron and steel works of western Pennsylvania, and northern Ohio, Indiana and Illinois, for example, are located not at the iron mines or the coal fields, but at places between these two fields to which these materials can be cheaply carried from their respective places of production. The iron ore is chiefly produced in the Lake Superior region and carried at a very low cost by vessels especially constructed for this purpose to the southern shores of Lake Erie. The coal is chiefly produced in western Pennsylvania and central Ohio, Indiana and Illinois. The cost of transporting the coal from the mine to the lake shore, or the ore from the lake shore to the mine, or both coal and ore to some mutually convenient meeting point by river or canal or railroads constructed for this purpose across a comparatively level country, is extremely small, less in many cases than that of carrying material to the waterfall which is not infrequently located at places difficult of access. The vessels carrying the manufactures of the United States
or the manufacturing countries of Europe to South America, Africa and the Orient, bring back at a very low cost the india rubber, the tin, the fibers, the wool, the silk, the Egyptian cotton of those distant countries; and the manufacturer who a century ago was limited in his supply of raw materials to the immediate vicinity of his factory may now bring his material from all parts of the world, while the area in which he may sell his products has been correspondingly enlarged.
One very recent contribution to the convenience and cheapness of manufacture is found in the transmission of power in the form of electricity. Formerly the machines of the factory were operated by power obtained from the steam engine or the water wheel through lines of shafting, gearing, belts, friction pulleys, etc. This made it necessary that the factory operated by water power be placed alongside the waterfall, or at least within a comparatively short distance of the source of power. Recent inventions have made it possible to transform power into electricity, carry that electricity hundreds of miles on a wire, and transform it back into power for the operation of the machinery of the factory or the transportation of the raw material or the finished product. This has increased greatly the value of the world’s water power in its relation to manufacturing. Formerly only a small part of the waterfalls of the world were used at all, largely because of their comparative inaccessibility and the cost of transporting the raw material to them and the finished product from them. Now that power, generated at any point, however inaccessible for freight handling, may be transmitted in the form of electricity on a simple piece of wire to any convenient point within a hundred or even two hundred miles of the place of production, and by a simple process applied to the operations of machines small or large, simple or complex, the possibilities of the waterfall in supplying power for the manufacturer are greatly enlarged.
Not only is this true of the waterfalls now in existence but of those which may be brought into existence, for now that man has found a way to use the power thus generated he may readily increase the number of waterfalls by constructing dams at many places, and using the water over and over again in its flow from the place of origin to the ocean level. The great quantities of water stored up in the form of snow and ice in the mountain ranges of the world, and gradually liberated by melting may supply almost untold quantities of power as they flow down the mountain sides used not merely once but many times. The manufacturing power of Italy, Switzerland and southern France is now being greatly augmented by this process.
Another possibility of the use of this new distributor of power, electricity, is the multiplying of workshops and the return in some instances and certain articles to household or small shop manufacture. It is now so easy to introduce the electric wire and a small electric motor into the household or the shop adjoining the household and to so operate small machines for the various processes in many of the manufacturing industries, that this new use of electricity for the transmission of power is already making visible changes in the factory systems of the world, and promises still greater changes. In many lines of manufacture in which the machinery occupies small space and requires little power and the quantity of material handled is not great, such as watch and clock making, the manufacture of clothing, boots and shoes, toys, etc., a part or all of the work can now be performed in the household or small shop through the power generated miles away and brought into the workman’s home on a simple piece of wire.