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Watermill |
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) Watermill of Braine-le-Château, Belgium (12th century) This article is about a type of structure. For other locational uses see: Milldam A watermill is a structure that uses a water wheel or turbine to drive a mechanical process such as flour or lumber production, or metal shaping (rolling, grinding or wire drawing). A watermill that generates electricity is usually called a hydroelectric plant. HistoryIndiaThe first use of the water wheel may possibly have occurred in 4th century BC India. According to Terry S. Reynolds, "Joseph Needham noted in 1965 that certain ancient Indian texts from around 350 BC mentioned a cakkavattaka (turning wheel) which commentaries explained as arahatta-ghatĩ-yanta (machine with wheel-pots attached)", on which basis Needham "suggested that the machine in question was a noria and that it was the first water powered prime mover." However, Reynolds also writes that "the term used in Indian texts is ambiguous and does not clearly indicate a water-powered device. In fact, as Thorkild Schiøler has noted, it is far more likely that these passages refer to some type of tread- or hand-operated water-lifting device, instead of a water-powered water-lifting wheel."[1]Irrigation water for crops was provided by using water raising wheels, some driven by the force of the current in the river from which the water was being raised. This kind of water raising device was used in ancient India.[2] Around 1150, the astronomer Bhaskara Achārya observed water-raising wheels and imagined such a wheel lifting enough water to replenish the stream driving it, effectively, a perpetual motion machine.[3] The construction of water works and aspects of water technology in India is described in Arabic and Persian works. During medieval times, the diffusion of Indian and Persian irrigation technologies gave rise to an advanced irrigation system which bought about economic growth and also helped in the growth of material culture.[4] Greco-Roman world) Hold back your hand from the mill, you grinding girls; even if the cockcrow heralds the dawn, sleep on. For Demeter has imposed the labours of your hands on the nymphs, who leaping down upon the topmost part of the wheel, rotate its axle; with encircling cogs,[6] it turns the hollow weight of the Nisyrian millstones. If we learn to feast toil-free on the fruits of the earth, we taste again the golden age. However, Lewis has argued that the water wheel, probably at least the vertical kind, was included in post portions of the Philo of Byzantium, who wrote in the 3rd century BC, and parts of whose work survives in Arabic and Latin translations, including that of Vitruvius. An early exapmle is mentioned in Strabo's Geography near the palace at Cabira of Mithradates VI Eupator, King of Pontus from 120 BC to 71 BC and 67 BC to 66 BC. The fulling mill and mills for pounding grain (to dehusk it) seem also to have been used in the Roman Empire.[7] The Romans used both fixed and floating water wheels and introduced water power to other provinces of the Roman Empire. So-called 'Greek Mills' used water wheels with a horizontal wheel (and vertical shaft). A "Roman Mill" features a vertical wheel (on a horizontal shaft). Greek style mills are the older and simpler of the two designs, but only operate well with high water velocities and with small diameter millstones. Roman style mills are more complicated as they require gears to transmit the power from a shaft with a horizontal axis to one with a vertical axis. An example of a Roman era watermill would be the early 4th century site at Barbegal (q.v.) in southern France, where 16 overshot waterwheels were used to power an enormous flour mill. There was also a mill on the Janiculum (q.v.) hill at Rome. Nevertheless Roman mills were few in number. ChinaThe different variety of watermill was known in China during the Han dynasty (202 BC - 220 AD), but initially only in order to pound grain (to dehusk it).In the text known as the Xin Lun written by Huan Tan about 20 AD (during the usurpation of Wang Mang), it states that the legendary mythological king known as Fu Xi was the one responsible for the pestle and mortar, or tilt-hammer device (see trip hammer). Although the author speaks of the mythological Fu Xi, a passage of his writing suggests that the waterwheel was in widespread use by the 1st century AD in China (Wade-Giles spelling): Fu Hsi invented the pestle and mortar, which is so useful, and later on it was cleverly improved in such a way that the whole weight of the body could be used for treading on the tilt-hammer (tui), thus increasing the efficiency ten times. Afterwards the power of animals—donkeys, mules, oxen, and horses—was applied by means of machinery, and water-power too used for pounding, so that the benefit was increased a hundredfold.[8] In 31 AD, a Chinese engineer named Du Shi (Wade-Giles: Tu Shih) "invented the first water-powered bellows. This was a complicated machine containing gears, axles, and levers that was powered by a waterwheel".[9] In essence, Du Shi's invention aided the forging of cast iron smelted from the blast furnace. Du Shi's invention was continued by Chinese living in subsequent dynastic periods of China, although the bellows of his device were improved upon in later periods (from leather bellows to wooden-fan bellows).[10] Early Chinese mills had horizontal wheels. Islamic world
Muslim engineers in the medieval Islamic world employed water wheels as early as the 7th century, excavation of a canal in the Basra region discovered remains of a water wheel dating from this period. Hama in Syria still preserves one of its large wheels, on the river Orontes, although they are no longer in use. [11] The largest had a diameter of about 20 metres and its rim was divided into 120 compartments. Another wheel that is still in operation is found at Murcia in Spain, La Nora, and although the original wheel has been replaced by a steel one, the Moorish system during al-Andalus is otherwise virtually unchanged. The flywheel mechanism, which is used to smooth out the delivery of power from a driving device to a driven machine, was invented by Ibn Bassal (fl. 1038-1075) of al-Andalus, who pioneered the use of the flywheel in the chain pump (saqiya) and noria.[12] The industrial uses of watermills in the Islamic world date back to the 7th century, while horizontal-wheeled and vertical-wheeled water mills were both in widespread use by the 9th century. A variety of industrial watermills were first invented in the Islamic world, including gristmills, hullers, paper mills, sawmills, shipmills, stamp mills, steel mills, sugar mills, and tide mills. By the 11th century, every province throughout the Islamic world had these industrial watermills in operation, from al-Andalus and North Africa to the Middle East and Central Asia.[13] Muslim engineers also invented crankshafts and water turbines, first employed gears in watermills and water-raising machines, and pioneered the use of dams as a source of water power, used to provide additional power to watermills and water-raising machines.[14] Fulling mills, paper mills and steel mills spread from Islamic Spain to Christian Spain in the 12th century. Industrial water mills were also employed in the first large factory complexes built in al-Andalus between the 11th and 13th centuries.[15] Muslim engineers pioneered two solutions to achieve the maximum output from a water mill. The first solution was to mount them to piers of bridges to take advantage of the increased flow. The second solution was the shipmill, a unique type of water mill powered by water wheels mounted on the sides of ships moored in midstream. This was first employed along the Tigris and Euphrates rivers in 10th century Iraq, where large shipmills made of teak and iron could produce 10 tons of flour from corn every day for the granary in Baghdad.[16] By the 13th century, what we call water raising machine technology lifted off with the works of al-Jazari and Taqi al-Din. They both carried out a number of experiments, building fantastic machines, which led to the invention of automated machinery and this has made an enormous impact on civilisation today. Al-Jazari invented the most efficient water-raising machines in his time, which included water wheels with cams on their axle used to operate automata, the first water powered saqiya chain pump,[17] the first crankshaft and connecting rod mechanism,[18][19] the first suction pipes and suction pump, the first use of the double-action principle, the first reciprocating piston engine, the earliest valve operations, and the use of a system of gears. These inventions were important to the development of modern machinery, including the steam engine, modern reciprocating pumps,[20] internal combustion engine,[21] artificial heart,[22] bicycle, bicycle pump, etc.[23] Such advances made it possible for many industrial tasks that were previously driven by manual labour in ancient times to be mechanized and driven by machinery instead in the medieval Islamic world. The transfer of these technologies to medieval Europe later laid the foundations for the Industrial Revolution in 18th century Europe.[24] Medieval EuropeIn a 2005 survey the scholar Adam Lucas identified the following first appearances of various industrial mill types in Western Europe. Noticeable is the preeminent role of France in the introduction of new innovative uses of waterpower. However, he has drawn attention to the dearth of studies of the subject in several other countries. However he points to a lack of studies in other regions.
Operation of a watermill) Roblin's Mill, a watermill, at Black Creek Pioneer Village in Toronto ) Watermills in Bosnia ) The interior of a functional water mill Watermills can be divided into two kinds, one with a horizontal waterwheel on a vertical axle, and the other with a vertical wheel on a horizontal axle. The oldest of these were horizontal mills in which the force of the water, striking a simple paddle wheel set horizontally in line with the flow turned a runner stone balanced on the rynd which is atop a shaft leading directly up from the wheel. The bedstone does not turn. The problem with this type of mill arose from the lack of gearing; the speed of the water directly set the maximum speed of the runner stone which, in turn, set the rate of milling. Most watermills in Britain and the United States of America had a vertical waterwheel, one of three kinds: undershot, overshot and breast-shot. This produced rotary motion around a horizontal axis, which could be used (with cams) to lift hammers in a forge, fulling stocks in a fulling mill and so on. However, in corn mills rotation about a vertical axis was required to drive its stones. The horizontal rotation was converted into the vertical rotation by means of gearing, which also enabled the runner stones to turn faster than the waterwheel. The usual arrangement in British and American corn mills has been for the waterwheel to turn a horizontal shaft on which is also mounted a large pit wheel. This meshes with the wallower, mounted on a vertical shaft, which turns the (larger) great spur wheel (mounted on the same shaft). This large face wheel, set with pegs, in turn, turned a smaller wheel (such as a lantern gear) known as a stone nut, which was attached to the shaft that drove the runner stone. The number of runner stones that could be turned depended directly upon the supply of water available. In many mills the great spur wheel turned only one stone, but there might be several mills under one roof. As waterwheel technology improved mills became more efficient, and by the 19th century, it was common for the great spur wheel to drive several stone nuts, so that a single water wheel could drive as many as four stones.[27] Each step in the process increased the gear ratio which increased the maximum speed of the runner stone. Adjusting the sluice gate and thus the flow of the water past the main wheel allowed the miller to compensate for seasonal variations in the water supply. Finer speed adjustment was made during the milling process by tentering, that is, adjusting the gap between the stones according to the water flow, the type of grain being milled, and the grade of flour required. ) Dalgarven Mill, Ayrshire, Scotland ) A Breastshot waterwheel at Dalgarven Mill A unique type of water mill is the tide mill. This mill might be of any kind, undershot, overshot or horizontal but it does not employ a river for its power source. Instead a mole or causeway is built across the mouth of a small bay. At low tide, gates in the mole are opened allowing the bay to fill with the incoming tide. At high tide the gates are closed, trapping the water inside. At a certain point a sluice gate in the mole can be opened allowing the draining water to drive a mill wheel or wheels. This is particularly effective in places where the tidal differential is very great, such as the Bay of Fundy in Canada where the tides can rise fifty feet, or the now derelict village of Tide Mills in the UK. Other water mills can be set beneath large bridges where the flow of water between the stanchions is faster. At one point London bridge had so many water wheels beneath it that bargemen complained that passage through the bridge was impaired. A final, rather elegant, water wheel innovation places the wheel in a boat anchored in midstream. The flow of the river past the boat turns the wheel and drives the millstone. "Run of the river" schemes do not divert water at all and usually involve undershot wheels, and some types of water wheel (usually overshot steel wheels) mount a toothed annular ring near the outer edge that drives machinery from a spur gear rather than taking power from the central axle. However, the basic mode of operation remains the same; gravity drives machinery through the motion of flowing water.
Types of watermills
See also
Notes1. ^ Reynolds, p. 14. 2. ^ Pacey, pp. 10. 3. ^ Pacey, pp. 36. 4. ^ Iqtidar Husain Siddiqui, "Water Works and Irrigation System in India during Pre-Mughal Times", Journal of the Economic and Social History of the Orient, Vol. 29, No. 1 (Feb., 1986), pp. 52–77. 5. ^ Lewis, p. vii. 6. ^ The translation of this word is crucial to the interpretation of the passage. Traditionally, it has been translated as 'spoke' (e.g. Reynolds, p. 17), but Lewis (p. 66) points out that, while its primary meaning is 'ray' (as a sunbeam), its only concrete meaning is 'cog'. Since a horizontal-wheeled corn mill does not need gearing (and hence has no cogs), the mill must have been vertically-wheeled. 7. ^ Lewis, passim. 8. ^ Needham, p. 392. 9. ^ Woods, p. 51. 10. ^ Needham, p. 376. 11. ^ al-Hassani, Woodcock and Saoud (2006) Muslim Heritage in Our World, FSTC Publishing, p.115. 12. ^ Ahmad Y Hassan, Flywheel Effect for a Saqiya. 13. ^ Adam Robert Lucas (2005), "Industrial Milling in the Ancient and Medieval Worlds: A Survey of the Evidence for an Industrial Revolution in Medieval Europe", Technology and Culture 46 (1), p. 1-30 [10]. 14. ^ Ahmad Y Hassan, Transfer Of Islamic Technology To The West, Part II: Transmission Of Islamic Engineering 15. ^ Adam Robert Lucas (2005), "Industrial Milling in the Ancient and Medieval Worlds: A Survey of the Evidence for an Industrial Revolution in Medieval Europe", Technology and Culture 46 (1), p. 1-30 [11]. 16. ^ Donald Routledge Hill, "Mechanical Engineering in the Medieval Near East", Scientific American, May 1991, p. 64-69. (cf. Donald Routledge Hill, Mechanical Engineering) 17. ^ Ahmad Y Hassan, Al-Jazari and the History of the Water Clock 18. ^ Paul Vallely, How Islamic Inventors Changed the World, The Independent, 11 March 2006. 19. ^ Ahmad Y Hassan. The Crank-Connecting Rod System in a Continuously Rotating Machine. 20. ^ Ahmad Y Hassan. The Origin of the Suction Pump - Al-Jazari 1206 A.D. 21. ^ Donald Routledge Hill (1998). Studies in Medieval Islamic Technology II, p. 231-232. 22. ^ Ancient Discoveries: Machines of the East DVD, The History Channel. 23. ^ What the Ancients Did for Us, Episode 1, "The Islamic World", BBC & Open University. 24. ^ Adam Robert Lucas (2005), "Industrial Milling in the Ancient and Medieval Worlds: A Survey of the Evidence for an Industrial Revolution in Medieval Europe", Technology and Culture 46 (1), p. 1-30. 25. ^ Adam Robert Lucas, 'Industrial Milling in the Ancient and Medieval Worlds. A Survey of the Evidence for an Industrial Revolution in Medieval Europe', Technology and Culture, Vol. 46, (Jan. 2005), pp. 1-30 (17). 26. ^ Webster's New Twentieth Century Dictionary of the English Language Unabridged (1952) states: leet, n. A leat; a flume. [Obs.]. 27. ^ Gauldie. 28. ^ Gauldie. 29. ^ Dictionary definition of "tailrace". References
External links
A milldam is a dam constructed on a waterway to create a millpond. Water passing through a dam's spillway is used to turn a water wheel and provide energy to the many varieties of watermill. ..... Click the link for more information. water wheel is a hydropower system; a machine for extracting power from the flow of water. Water wheels and hydropower was widely used in the Middle Ages, powering most industry in Europe, along with the windmill. ..... Click the link for more information. water turbine is a rotary engine that takes energy from moving water. Water turbines were developed in the nineteenth century and were widely used for industrial power prior to electrical grids. Now they are mostly used for electric power generation. ..... Click the link for more information. An ingredient used in many foods, flour is a fine powder made by grinding cereals or other edible starchy plant seeds suitable for grinding. It is most commonly made from wheat—the word "flour" used without qualification implies wheatflour—but also maize (now called ..... Click the link for more information. worldwide view of the subject. Please [ improve this article] or discuss the issue on the talk page. Lumber or timber is a term used to describe wood, either standing or that has been processed for use — from the time trees are felled, to its ..... Click the link for more information. A rolling mill is a machine or factory for shaping metal by passing it between a pair of rolls. Rolling mills are often incorporated into integrated steelworks, but also exist as separate plants and can be used for other metals, and other materials. ..... Click the link for more information. Wire drawing is a manufacturing process used to reduce or change the cross section of a wire by using a series of draw plates or dies. Rod or wire stock is drawn through one or more tapered wire drawing dies. ..... Click the link for more information. Electricity (from New Latin ēlectricus, "amberlike") is a general term for a variety of phenomena resulting from the presence and flow of electric charge. This includes many well-known physical phenomena such as lightning, electromagnetic fields and electric currents, ..... Click the link for more information. Hydropower or hydraulic power is the force or energy of moving water. It may be captured for some useful purpose. Prior to the widespread availability of commercial electric power, hydropower was used for irrigation, and operation of various machines, such as ..... Click the link for more information. The 4th century BC started the first day of 400 BC and ended the last day of 301 BC. It is considered part of the Classical era, epoch, or historical period. OverviewThis century marks the height of Classical Greek civilization in all of its aspects...... Click the link for more information. This page is currently protected from editing until disputes have been resolved. Protection is not an endorsement of the current [ version] ([ protection log]). ..... Click the link for more information. Joseph Terence Montgomery Needham (December 9, 1900–March 24 1995) was a British biochemist best known for his works on the history of Chinese science. He was elected a fellow of both the Royal Society and the British Academy. ..... Click the link for more information. 4th century BC - 3rd century BC 380s BC 370s BC 360s BC - 350s BC - 340s BC 330s BC 320s BC 353 BC 352 BC 351 BC - 350 BC - 349 BC 348 BC 347 BC Politics State leaders - Sovereign states ..... Click the link for more information. Noria are machines for lifting water into an aqueduct using energy derived from the water's flow. It consists of an undershot waterwheel to which are fixed a series of containers that lift water from the river to the aqueduct at a higher level. ..... Click the link for more information. Hydropower or hydraulic power is the force or energy of moving water. It may be captured for some useful purpose. Prior to the widespread availability of commercial electric power, hydropower was used for irrigation, and operation of various machines, such as ..... Click the link for more information. prime mover is an English translation of the Latin Primum Mobile. The original latin refers to a "first cause" of motion in the theological sense, and was used during the scholastic era to explain how God was the cause of all movement and hence of all life in the world. ..... Click the link for more information. Ancient India may refer to:
..... Click the link for more information. perpetual motion, taken literally, refers to movement that goes on forever. This is possible in the current theoretical understanding of physics as in Newton's First Law of Motion. ..... Click the link for more information. al-‘Arabiyyah in written Arabic (Kufic script): Pronunciation: /alˌʕa.raˈbij.ja/ Spoken in: Algeria, Bahrain, Egypt, Iraq, Jordan, Kuwait, Lebanon, Libya, Mauritania, Morocco, Oman, ..... Click the link for more information. fɒːɾˈsiː in Perso-Arabic script (Nasta`liq style): Pronunciation: [fɒːɾˈsiː] Spoken in: Iran, Afghanistan, Tajikistan and areas of Uzbekistan and Pakistan. ..... Click the link for more information. The term ancient Greece refers to the periods of Greek history in Classical Antiquity, lasting ca. 750 BC[1] (the archaic period) to 146 BC (the Roman conquest). It is generally considered to be the seminal culture which provided the foundation of Western Civilization. ..... Click the link for more information. Ancient Rome was a civilization that grew from a small agricultural community founded on the Italian Peninsula circa the 9th century BC to a massive empire straddling the Mediterranean Sea. ..... Click the link for more information. The 1st century BC started the first day of 100 BC and ended the last day of 1 BC. It is considered part of the Classical era, epoch, or historical period. An alternative name for this century is the last century BC. ..... Click the link for more information.
..... Click the link for more information. Dêmêtêr /də'miː.tɚ/ (Greek: Δημήτηρ ..... Click the link for more information. nymph is any member of a large class of female entities in human form, that is either bound to a particular location, or landform, or is part of the retinue of a god, such as Dionysus, Hermes, or Pan, or a goddess, generally Artemis. ..... Click the link for more information. Nisyros (Greek: Νίσυρος; also transliterated Nissiros; Italian: Nisiro) is a volcanic Greek island and municipality located in the Aegean Sea. ..... Click the link for more information. Golden age stems from Greek mythology. It refers to the highest age in the Greek spectrum of Iron, Bronze, Silver and Golden ages, or to a time in the beginnings of Humanity which was perceived as an ideal state, or utopia, when mankind was pure and immortal. ..... Click the link for more information. Philo of Byzantium (ca. 280 BCE - ca. 220 BCE), also known as Philo Mechanicus, a Greek writer on mechanics, flourished during the latter half of the 2nd century B.C. He was probably younger than Ctesibius, though some place him a century earlier. ..... Click the link for more information. The 3rd century BC started the first day of 300 BC and ended the last day of 201 BC. It is considered part of the Classical era, epoch, or historical period. The first few decades of the century are characterized by a balance of power between the Greek Hellenistic kingdoms ..... Click the link for more information. This article is copied from an article on Wikipedia® - the free encyclopedia created and edited by online user community. The text was not checked or edited by anyone on our staff. Although the vast majority of the Wikipedia® encyclopedia articles provide accurate and timely information please do not assume the accuracy of any particular article. This article is distributed under the terms of GNU Free Documentation License. How to thank TFD for its existence? Tell a friend about us, add a link to this page, add the site to iGoogle, or visit webmaster's page for free fun content. |
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| You may as well take him around after breakfast; go by the common and the Highwood, and back by the watermill and the river; that will show his paces. He did not, like the crowd of school-boy artisans, construct little windmills on the angle of a barn or watermills across the neighboring brook. |
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Watermill
