A Second Industrial Revolution would occur late in the 19th century and involve the development of the steel industry and giant corporations. The initial focus of industrialization was on textiles; cloth was needed by almost everyone. Individual families, usually farm wives and daughters, would master one part of the process—spinning, dyeing, weaving and so forth.
The Industrial Revolution — The term Industrial Revolution, like similar historical concepts, is more convenient than precise. It is convenient because history requires division into periods for purposes of understanding and instruction and because there were sufficient innovations at the turn of the 18th and 19th centuries to justify the choice of The industrial revolution and how it as one of the periods.
The term is imprecise, however, because the Industrial Revolution has no clearly defined beginning or end. The term Industrial Revolution must thus be employed with some care.
It is used below to describe an extraordinary quickening in the rate of growth and change and, more particularly, to describe the first years of this period of time, as it will be convenient to pursue the developments of the 20th century separately.
The Industrial Revolution, in this sense, has been a worldwide phenomenon, at least in so far as it has occurred in all those parts of the world, of which there are very few exceptions, where the influence of Western civilization has been felt.
Beyond any doubt it occurred first in Britain, and its effects The industrial revolution and how it only gradually to continental Europe and North America. Equally clearly, the Industrial Revolution that eventually transformed these parts of the Western world surpassed in magnitude the achievements of Britain, and the process was carried further to change radically the socioeconomic life of Asia, Africa, Latin Americaand Australasia.
The reasons for this succession of events are complex, but they were implicit in the earlier account of the buildup toward rapid industrialization. Partly through good fortune and partly through conscious effort, Britain by the early 18th century came to possess the combination of social needs and social resources that provided the necessary preconditions of commercially successful innovation and a social system capable of sustaining and institutionalizing the processes of rapid technological change once they had started.
This section will therefore be concerned, in the first place, with events in Britain, although in discussing later phases of the period it will be necessary to trace the way in which British technical achievements were diffused and superseded in other parts of the Western world.
Power technology An outstanding feature of the Industrial Revolution has been the advance in power technology.
At the beginning of this period, the major sources of power available to industry and any other potential consumer were animate energy and the power of wind and water, the only exception of any significance being the atmospheric steam engines that had been installed for pumping purposes, mainly in coal mines.
It is to be emphasized that this use of steam power was exceptional and remained so for most industrial purposes until well into the 19th century.
Steam did not simply replace other sources of power: The same sort of scientific inquiry that led to the development of the steam engine was also applied to the traditional sources of inanimate energy, with the result that both waterwheels and windmills were improved in design and efficiency.
Numerous engineers contributed to the refinement of waterwheel constructionand by the middle of the 19th century new designs made possible increases in the speed of revolution of the waterwheel and thus prepared the way for the emergence of the water turbine, which is still an extremely efficient device for converting energy.
Windmills Meanwhile, British windmill construction was improved considerably by the refinements of sails and by the self-correcting device of the fantail, which kept the sails pointed into the wind.
Spring sails replaced the traditional canvas rig of the windmill with the equivalent of a modern venetian blind, the shutters of which could be opened or closed, to let the wind pass through or to provide a surface upon which its pressure could be exerted.
In mills equipped with these sails, the shutters were controlled on all the sails simultaneously by a lever inside the mill connected by rod linkages through the windshaft with the bar operating the movement of the shutters on each sweep.
The control could be made more fully automatic by hanging weights on the lever in the mill to determine the maximum wind pressure beyond which the shutters would open and spill the wind. Conversely, counterweights could be attached to keep the shutters in the open position.
With these and other modifications, British windmills adapted to the increasing demands on power technology.
But the use of wind power declined sharply in the 19th century with the spread of steam and the increasing scale of power utilization. Windmills that had satisfactorily provided power for small-scale industrial processes were unable to compete with the production of large-scale steam-powered mills.
Steam engines Although the qualification regarding older sources of power is important, steam became the characteristic and ubiquitous power source of the British Industrial Revolution. Little development took place in the Newcomen atmospheric engine until James Watt patented a separate condenser inbut from that point onward the steam engine underwent almost continuous improvements for more than a century.
By keeping the cylinder permanently hot and the condenser permanently cold, a great economy on energy used could be effected. This brilliantly simple idea could not be immediately incorporated in a full-scale engine because the engineering of such machines had hitherto been crude and defective.
The backing of a Birmingham industrialist, Matthew Boultonwith his resources of capital and technical competence, was needed to convert the idea into a commercial success. During the quarter of a century in which Boulton and Watt exercised their virtual monopoly over the manufacture of improved steam engines, they introduced many important refinements.
Basically they converted the engine from a single-acting i. The rotary action engine was quickly adopted by British textile manufacturer Sir Richard Arkwright for use in a cotton mill, and although the ill-fated Albion Mill, at the southern end of Blackfriars Bridge in London, was burned down inwhen it had been in use for only five years and was still incomplete, it demonstrated the feasibility of applying steam power to large-scale grain milling.
Many other industries followed in exploring the possibilities of steam power, and it soon became widely used.
This development came quickly once these patents lapsed in The Cornish engineer Richard Trevithick introduced higher steam pressuresachieving an unprecedented pressure of pounds per square inch 10 kilograms per square centimetre in with an experimental engine at Coalbrookdale, which worked safely and efficiently.
Almost simultaneously, the versatile American engineer Oliver Evans built the first high-pressure steam engine in the United States, using, like Trevithick, a cylindrical boiler with an internal fire plate and flue.
Trevithick quickly applied his engine to a vehicle, making the first successful steam locomotive for the Penydarren tramroad in South Wales in The success, however, was technological rather than commercial because the locomotive fractured the cast iron track of the tramway: Meanwhile, the stationary steam engine advanced steadily to meet an ever-widening market of industrial requirements.
High-pressure steam led to the development of the large beam pumping engines with a complex sequence of valve actions, which became universally known as Cornish engines ; their distinctive characteristic was the cutoff of steam injection before the stroke was complete in order to allow the steam to do work by expanding.
These engines were used all over the world for heavy pumping duties, often being shipped out and installed by Cornish engineers.
|Development of industries||Explore the latest strategic trends, research and analysis We stand on the brink of a technological revolution that will fundamentally alter the way we live, work, and relate to one another.|
|Popular 'Economics, Politics, & Society' Terms||It followed on from the First Industrial Revolution that began in Britain in the late 18th century that then spread throughout Western Europe and North America. It was characterized by the build out of railroadslarge-scale iron and steel production, widespread use of machinery in manufacturing, greatly increased use of steam power, widespread use of the telegraphuse of petroleum and the beginning of electrification.|
|Child Labor||Because not all women worked, and because children usually contributed more to the family budget than their mothers, for the average family the wife contributed only around seven percent of total family income. Childcare Women workers used a variety of methods to care for their children.|
Trevithick himself spent many years improving pumping engines in Latin America. Cornish engines, however, were probably most common in Cornwall itself, where they were used in large numbers in the tin and copper mining industries. Another consequence of high-pressure steam was the practice of compoundingof using the steam twice or more at descending pressures before it was finally condensed or exhausted.Jul 06, · The First Industrial Revolution used water and steam power to mechanize production.
The Second used electric power to create mass production. The Third used electronics and information technology to automate production. The story of the Industrial Revolution begins on the small island of Great Britain. By the early 18th century, people there had used up most of their trees for building houses and ships and for cooking and heating.
Industrial Revolution, in modern history, the process of change from an agrarian and handicraft economy to one dominated by industry and machine manufacturing.
This process began in Britain in the 18th century and from there spread to other parts of . Sep 18, · The Industrial Revolution marked a major turning point in Earth’s ecology and humans’ relationship with their environment.
The Industrial Revolution dramatically changed every aspect of human life and lifestyles. The impact on the world’s psyche would not begin to register until the early s, some years after its beginnings.
The Industrial Revolution did not occur in Britain merely because Britain had the most advanced technology, but because this technology was situated in a country with a secure financial system, global trade networks, lots of raw materials, including coal, a relatively stable political system with the capacity to direct economic development, and a skilled workforce augmented by skilled foreign.
The Industrial Revolution occurred when agrarian societies became more industrialized and urban. Learn where and when the Industrial Revolution started, and the inventions that made it possible.