Powering the Industrial Revolution
In Britain one of the most dramatic changes of the Industrial Revolution was the harnessing of power. Until the reign of George Ⅲ(1760-1820), available sources of power for work and travel had not increased since the Middle Ages. There were three sources of power: animal or human muscles; the wind, operating on sail or windmill; and running water. Only the last of these was suited at all to the continuous operating of machines, and although waterpower abounded in Lancashire and Scotland and ran grain mills as well as textile mills, it had one great disadvantage: streams flowed where nature intended them to, and water-driven factories had to be located on their banks whether or not the location was desirable for other reasons. Furthermore, even the most reliable waterpower varied with the seasons and disappeared in a drought. The new age of machinery, in short, could not have been born without a new source of both movable and constant power.
The source had long been known but not exploited. Early in the eighteenth century, a pump had come into use in which expanding steam raised a piston in a cylinder, and atmospheric pressure brought it down again when the steam condensed inside the cylinder to form a vacuum. This "atmospheric engine," invented by Thomas Savery and vastly improved by his partner, Thomas Newcomen, embodied revolutionary principles, but it was so slow and wasteful of fuel that it could not be employed outside the coal mines for which it had been designed. In the 1760s, James Watt perfected a separate condenser for the steam, so that the cylinder did not have to be cooled at every stroke; then he devised a way to make the piston turn a wheel and thus convert reciprocating (back and forth) motion into rotary motion. He thereby transformed an inefficient pump of limited use into a steam engine of a thousand uses. The final step came when steam was introduced into the cylinder to drive the piston backward as well as forward, thereby increasing the speed of the engine and cutting its fuel consumption.
Watt's steam engine soon showed what it could do. It liberated industry from dependence on running water. The engine eliminated water in the mines by driving efficient pumps, which made possible deeper and deeper mining. The ready availability of coal inspired William Murdoch during the 1790s to develop the first new form of nighttime illumination to be discovered in a millennium and a half. Coal gas rivaled smoky oil lamps and flickering candles, and early in the new century, well-to-do Londoners grew accustomed to gaslit houses and even streets. Iron manufacturers, which had starved for fuel while depending on charcoal, also benefited from ever-increasing supplies of coal: blast furnaces with steam-powered bellows turned out more iron and steel for the new machinery. Steam became the motive force of the Industrial Revolution as coal and iron ore were the raw materials.
By 1800 more than a thousand steam engines were in use in the British Isles, and Britain retained a virtual monopoly on steam engine production until the 1830s. Steam power did not merely spin cotton and roll iron; early in the new century, it also multiplied ten times over the amount of paper that a single worker could produce in a day. At the same time, operators of the first printing presses run by steam rather than by hand found it possible to produce a thousand pages in an hour rather than thirty. Steam also promised to eliminate a transportation problem not fully solved by either canal boats or turnpikes. Boats could carry heavy weights, but canals could not cross hilly terrain; turnpikes could cross the hills, but the roadbeds could not stand up under great weights. These problems needed still another solution, and the ingredients for it lay close at hand. In some industrial regions, heavily laden wagons, with flanged wheels, were being hauled by horses along metal rails; and the stationary steam engine was puffing in the factory and mine. Another generation passed before inventors succeeded in combining these ingredients, by putting the engine on wheels and the wheels on the rails, so as to provide a machine to take the place of the horse. Thus the railroad age sprang from what had already happened in the eighteenth century.
Paragraph 1: In Britain one of the most dramatic changes of the Industrial Revolution was the harnessing of power. Until the reign of George Ⅲ(1760-1820), available sources of power for work and travel had not increased since the Middle Ages. There were three sources of power: animal or human muscles; the wind, operating on sail or windmill; and running water. Only the last of these was suited at all to the continuous operating of machines, and although waterpower abounded in Lancashire and Scotland and ran grain mills as well as textile mills, it had one great disadvantage: streams flowed where nature intended them to, and water-driven factories had to be located on their banks whether or not the location was desirable for other reasons. Furthermore, even the most reliable waterpower varied with the seasons and disappeared in a drought. The new age of machinery, in short, could not have been born without a new source of both movable and constant power.
Paragraph 2: The source had long been known but not exploited. Early in the eighteenth century, a pump had come into use in which expanding steam raised a piston in a cylinder, and atmospheric pressure brought it down again when the steam condensed inside the cylinder to form a vacuum. This "atmospheric engine," invented by Thomas Savery and vastly improved by his partner, Thomas Newcomen, embodied revolutionary principles, but it was so slow and wasteful of fuel that it could not be employed outside the coal mines for which it had been designed. In the 1760s, James Watt perfected a separate condenser for the steam, so that the cylinder did not have to be cooled at every stroke; then he devised a way to make the piston turn a wheel and thus convert reciprocating (back and forth) motion into rotary motion. He thereby transformed an inefficient pump of limited use into a steam engine of a thousand uses. The final step came when steam was introduced into the cylinder to drive the piston backward as well as forward, thereby increasing the speed of the engine and cutting its fuel consumption.
1. Which of the sentences below best expresses the essential information in the highlighted sentence in the passage? Incorrect choices change the meaning in important ways or leave out essential information.
○ Running water was the best power source for factories since it could keep machines operating continuously, but since it was abundant only in Lancashire and Scotland, most mills and factories that were located elsewhere could not be water driven.
○ The disadvantage of using waterpower is that streams do not necessarily flow in places that are the most suitable for factories, which explains why so many water-powered grain and textile mills were located in undesirable places.
○ Since machines could be operated continuously only where running water was abundant, grain and textile mills, as well as other factories, tended to be located only in Lancashire and Scotland.
○ Running water was the only source of power that was suitable for the continuous operation of machines, but to make use of it, factories had to be located where the water was, regardless of whether such locations made sense otherwise.
2. Which of the following best describes the relation of paragraph 2 to paragraph 1?
○Paragraph 2 shows how the problem discussed in paragraph 1 arose.
○Paragraph 2 explains how the problem presented in paragraph 1 came to be solved.
○Paragraph 2 provides a more technical discussion of the problem introduced in paragraph 1.
○Paragraph 2 shows why the problem discussed in paragraph 1 was especially important to solve.
3. The word "exploited" in the passage is closest in meaning to
○utilized
○recognized
○examined
○fully understood
4. The word "vastly" in the passage is closet in meaning to
○quickly
○ultimately
○greatly
○initially
5. According to paragraph 2, the "atmospheric engine" was slow because
○it had been designed to be used in coal mines
○the cylinder had to cool between each stroke
○it made use of expanding steam to raise the piston in its cylinder
○it could be operated only when a large supply of fuel was available
Paragraph 2: The source had long been known but not exploited. Early in the eighteenth century, a pump had come into use in which expanding steam raised a piston in a cylinder, and atmospheric pressure brought it down again when the steam condensed inside the cylinder to form a vacuum. This "atmospheric engine," invented by Thomas Savery and vastly improved by his partner, Thomas Newcomen, embodied revolutionary principles, but it was so slow and wasteful of fuel that it could not be employed outside the coal mines for which it had been designed. In the 1760s, James Watt perfected a separate condenser for the steam, so that the cylinder did not have to be cooled at every stroke; then he devised a way to make the piston turn a wheel and thus convert reciprocating (back and forth) motion into rotary motion. He thereby transformed an inefficient pump of limited use into a steam engine of a thousand uses. The final step came when steam was introduced into the cylinder to drive the piston backward as well as forward, thereby increasing the speed of the engine and cutting its fuel consumption.
6. According to paragraph 2, Watt's steam engine differed from earlier steam engines in each of the following ways EXCEPT:
○ It used steam to move a piston in a cylinder.
○ It worked with greater speed.
○ It was more efficient in its use of fuel.
○ It could be used in many different ways.
Paragraph 3: Watt's steam engine soon showed what it could do. It liberated industry from dependence on running water. The engine eliminated water in the mines by driving efficient pumps, which made possible deeper and deeper mining. The ready availability of coal inspired William Murdoch during the 1790s to develop the first new form of nighttime illumination to be discovered in a millennium and a half. Coal gas rivaled smoky oil lamps and flickering candles, and early in the new century, well-to-do Londoners grew accustomed to gaslit houses and even streets. Iron manufacturers, which had starved for fuel while depending on charcoal, also benefited from ever-increasing supplies of coal: blast furnaces with steam-powered bellows turned out more iron and steel for the new machinery. Steam became the motive force of the Industrial Revolution as coal and iron ore were the raw materials.
7. In paragraph 3, the author mentions William Murdoch's invention of a new form of nighttime illumination in order to
○indicate one of the important developments made possible by the introduction of Watt's steam engine
○make the point that Watt's steam engine was not the only invention of importance to the Industrial Revolution
○illustrate how important coal was as a raw material for the Industrial Revolution
○provide an example of another eighteenth-century invention that used steam as a power source
8. The phrase "grew accustomed to" in the passage is closest in meaning to
○began to prefer
○wanted to have
○became used to
○insisted on
Paragraph 4: By 1800 more than a thousand steam engines were in use in the British Isles, and Britain retained a virtual monopoly on steam engine production until the 1830s. Steam power did not merely spin cotton and roll iron; early in the new century, it also multiplied ten times over the amount of paper that a single worker could produce in a day. At the same time, operators of the first printing presses run by steam rather than by hand found it possible to produce a thousand pages in an hour rather than thirty. Steam also promised to eliminate a transportation problem not fully solved by either canal boats or turnpikes. Boats could carry heavy weights, but canals could not cross hilly terrain; turnpikes could cross the hills, but the roadbeds could not stand up under great weights. These problems needed still another solution, and the ingredients for it lay close at hand. In some industrial regions, heavily laden wagons, with flanged wheels, were being hauled by horses along metal rails; and the stationary steam engine was puffing in the factory and mine. Another generation passed before inventors succeeded in combining these ingredients, by putting the engine on wheels and the wheels on the rails, so as to provide a machine to take the place of the horse. Thus the railroad age sprang from what had already happened in the eighteenth century.
9. The word "retained" in the passage is closest in meaning to
○gained
○established
○profited from
○maintained
10. According to paragraph 4, which of the following statements about steam engines is true?
○They were used for the production of paper but not for printing.
○By 1800, significant numbers of them were produced outside of Britain.
○They were used in factories before they were used to power trains.
○They were used in the construction of canals and turnpikes.
11. According to paragraph 4, providing a machine to take the place of the horse involved combining which two previously separate ingredients?
○Turnpikes and canals
○Stationary steam engines and wagons with flanged wheels
○Metal rails in roadbeds and wagons capable of carrying heavy loads
○Canal boats and heavily laden wagons
Paragraph 3: Watt's steam engine soon showed what it could do. It liberated industry from dependence on running water. The engine eliminated water in the mines by driving efficient pumps, which made possible deeper and deeper mining. The ready availability of coal inspired William Murdoch during the 1790s to develop the first new form of nighttime illumination to be discovered in a millennium and a half. Coal gas rivaled smoky oil lamps and flickering candles, and early in the new century, well-to-do Londoners grew accustomed to gaslit houses and even streets. Iron manufacturers, which had starved for fuel while depending on charcoal, also benefited from ever-increasing supplies of coal: blast furnaces with steam-powered bellows turned out more iron and steel for the new machinery. Steam became the motive force of the Industrial Revolution as coal and iron ore were the raw materials.
12.Look at the four squares [] that indicate where the following sentence could be added to the passage.
The factories did not have to go to the streams when power could come to the factories.
Where would the sentence best fit?
13. Directions: An introductory sentence for a brief summary of the passage is provided below. Complete the summary by selecting the THREE answer choices that express the most important ideas in the passage. Some sentences do not belong in the summary because they express ideas that are not presented in the passage or are minor ideas in the passage. This question is worth 2 points.
The Industrial Revolution would not have been possible without a new source of power that was efficient, movable, and continuously available.
●
●
●
Answer Choices
○In the early eighteenth century, Savery and Newcomen discovered that expanding steam could be used to raise a piston in a cylinder.
○Watt's steam engine played a leading role in greatly increasing industrial production of all kinds.
○Until the 1830s, Britain was the world's major producer of steam engines.
○In the mid-1700s James Watt transformed an inefficient steam pump into a fast, flexible, fuel-efficient engine.
○In the 1790s William Murdoch developed a new way of lighting houses and streets using coal gas.
○The availability of steam engines was a major factor in the development of railroads, which solved a major transportation problem.#p#副标题#e#
参考答案:
1. ○4
2. ○2
3. ○1
4. ○3
5. ○2
6. ○1
7. ○1.
8. ○3
9. ○4
10. ○3
11. ○2
12. ○3
13. Watt's steam engine played …
In the mid-1700s James Watt…
The availability of steam…
参考翻译:驱动工业革命
在英国,工业革命带来的最大的变化之一就是动力的运用。从中世纪到乔治三世统治时期,用于劳作及行驶的动力一直没有得到发展。当时的驱动力仅限于三种:动物或人力;风力,用于航行或者风车;流水产生的动力。其中只有水力可以用于支持持续运转的机器,尽管在当时的兰开夏和苏格兰地区水力资源极其丰富,被用于谷物作坊和纺织厂,但这种动力存在一个极大的缺陷:水的流向是由自然因素决定的,因此,不论适不适合工厂选址,利用水利生产的工厂都必须建造在能够提供水资源动力的岸边。再者,即便是最可靠的水资源也会受到季节变化和因干旱而枯竭的影响。总之,没有可持续提供动力并且可移动的能源就没有新机械化时代的产生。
一直以来,人们很早就了解这种能源,不过没能成功开发。在18世纪早期,泵曾被用于在气缸中使蒸汽推动活塞,气缸内部的蒸汽被压缩形成真空环境,大气压又使得活塞下降,这一由托马斯o赛佛瑞发明并由他的同伴托马斯o纽科门对其进行改良的"大气引擎",被赋予了革命性的工作原理。但其效率低下且浪费燃料,无法在煤矿以外的地区使用,这与最初的设计期望背道而驰。18世纪60年代,詹姆士o瓦特完善了分离的蒸汽冷凝器,因此不必每次活塞运动后都要冷却气缸;随后,他又发明了一种新的方法,使得活塞可以旋转运动,即从原来的往复运动演变成为循环运动,原本效率低下运用范围有限的活塞式结构从此演变成为得到广泛运用的蒸汽模式。最终,蒸汽被运用于汽缸中将活塞推回,从而加快了机器的运转速度并降低了能源消耗。
瓦特发明的蒸汽机很快地施展了拳脚,把依赖水源的工业解放了出来。通过驱动高效率的泵,引擎可将矿井中的水排出,矿井就能挖掘得更深。煤的便利使用激发了威廉o默多克在18世纪90年代发明了1 500年以来首例夜间照明设备。。新世纪伊始,煤气灯在与冒烟的油灯和忽闪的蜡烛的比较中尽占优势,经济富裕的伦敦人也开始习惯了煤气作家用照明甚至街道照明。依赖于木炭供应的铁匠们急需燃料,他们也受益于越来越多的煤炭供应。配备有蒸汽动力的鼓风炉使得越来越多的钢铁供应成为可能。蒸汽成为了工业革命中的主要动力,当时的煤矿和铁矿成为了是工业的主要原材料。
19世纪时,英国已经拥有上千台蒸汽发动机,直到19世纪30年代以前,英国在蒸汽机的生产方面一直处于实质性垄断地位。蒸汽机不仅可以用于织布、炼铁,19世纪早期,蒸汽机的使用同样大大提高了造纸的效率,蒸汽动力生产的产量是一个工人一天产量的10倍。那时,第一个利用蒸汽发动的印刷机的印刷厂1小时就能完成1 000页的印量,而手动印刷机只能完成30页的工作量。。蒸汽动力还实现了运河及收费公路无法完全解决的运输问题。货船的确可以负荷重物,但人们无法利用运河在多山的区域实现运输,虽然利用公路可以穿实现在多山区域的运输,但路面的承载能力有限。这些问题都需要其他解决方法,解决问题所需要的条件其实唾手可得。在一些工业地区,四轮马车用于承载重物,它们配备有带凸的车轮,通过马力拉车在铁轨上行驶;静止的蒸汽发动机广泛运用于工厂和矿井之中。直到过了一代,另一批发明家们才将这些条件成功地组合在一起,给车轮配备上蒸汽动力,让轮子在铁路上运转,利用机器替代了原有的马。这就是铁路时代从18世纪既有条件发展起来的过程。
微信扫描下方二维码,第一时间知晓