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41 obraje
m.1 manufacture (fabricación), anything made by art.2 manufactory, workshop (taller).3 sawmill, timber yard (aserradero). (Andes)4 textile plant (textil). (Andes)5 manufacturing.* * *1 manufacturing* * *SM1) Cono Sur (=aserradero) sawmill, timberyard2) Méx (=carnicería) pork butcher's, pork butcher's shop3) And (=fábrica textil) textile plant* * *( RPl)obraje maderero logging camp* * *obraje nmRP mill, factory obraje maderero timber operation* * *m Méxbutcher’s -
42 verre
verre [vεʀ]1. masculine nouna. ( = substance) glassb. ( = objet) [de vitre, cadre] glass ; [de lunettes] lensc. ( = récipient) glass• ajouter un verre de lait (recette) ≈ add one cup of milkd. ( = boisson) drink• boire or prendre un verre to have a drink2. compounds► verres fumés [de lunettes] tinted lenses* * *vɛʀnom masculin1) ( matière) glassde or en verre — glass (épith)
des débris de verre — broken glass [U]
2) ( récipient) glass3) ( contenu) glass, glassful4) ( boisson) drink5) ( plaque) glass•Phrasal Verbs:* * *vɛʀ nm1) (= matière) glassverre de lampe — lamp glass, lamp chimney
2) (= récipient) glassboire un verre; prendre un verre — to have a drink
3) [lunettes] lens sgverres fumés — smoked lenses, smoked glass
* * *verre nm1 ( matière) glass; de or en verre glass ( épith); fabriquer du verre to make ou manufacture glass; industrie du verre glass industry; travail du verre glasswork; des débris de verre broken glass ¢;2 ( récipient) glass; verre à eau/vin/cognac water/wine/brandy glass; verres et couverts glassware and cutlery; lever son verre à la santé de qn to raise one's glass to sb; remplir/vider son verre to fill/empty one's glass; ⇒ casser;3 ( contenu) glass, glassful; j'ai bu un grand verre de jus de fruit I drank a large glass(ful) of fruit juice; un verre d'eau/de vin a glass of water/wine;4 ( boisson) drink; offrir un verre à qn to buy sb a drink; prendre un verre to have a drink; un petit verre a quick drink; avoir bu un verre de trop to have had one too many; boire le verre de l'amitié to toast one's friendship;5 ( plaque) glass; monter une gravure/photo sous verre to mount an engraving/a photograph under glass; changer le verre d'un cadre to change the glass in a frame; mettre qch sous verre to put sth under glass;6 Phys ( lentille) lens; verre concave/convexe concave/convex lens; verres de lunettes spectacle lenses; verre grossissant magnifying glass.verre antireflets anti-glare glass; verre armé wired glass; verre blanc white glass; verre cathédrale cathedral glass; en verre consigné returnable bottle; verre de contact contact lens; verre correcteur corrective lens; verre à dents toothglass; verre dépoli frosted glass; verre doseur measuring glass; verre feuilleté laminated glass; verre filé spun glass; verre filtrant light protective glass; verre flotté float glass; verre fumé ( pour lunettes) tinted lens; ( pour vitrage) tinted glass; verre gradué measuring jug; verre de lampe lamp chimney; verre de montre Chimie watch-glass; verre à moutarde cheap glass; verre optique optical glass; en verre perdu nonreturnable; verre à pied stemmed glass; verre plat flat glass; verre progressif varifocal lens; verre de silice silica ou quartz glass; verre soufflé blown glass; verre textile textile glass.[vɛr] nom masculin1. [matériau] glassverre dépoli frosted ou ground glassverre trempé tempered ou toughened glass2. [protection] glass3. [récipient] glassverre à eau [droit] tumblera. [en chimie] graduated vesselb. [pour la cuisine] measuring glass4. [contenu]je bois ou prends juste un petit verre I'll just have a quick oneverre de glass of, glassful of5. GÉOLOGIE————————verres nom masculin pluriela. [les verres] varifocal lensesb. [les lunettes elles-mêmes] varifocals2. [bouteilles] empties————————de verre locution adjectivaleglass (modificateur)————————en verre locution adjectivale[bibelot] glass (modificateur)————————sous verre locution adjectivale[photo, fleurs] glass-framed————————sous verre locution adverbiale -
43 Berthollet, Claude-Louis
SUBJECT AREA: Textiles[br]b. 9 November 1748 Talloise, near Lake Annecy, Franced. 6 November 1822 Arceuil, France[br]French chemist who made important innovations in textile chemistry.[br]Berthollet qualified as a medical doctor and pursued chemical researches, notably into "muriatic acid" (chlorine), then recently discovered by Scheele. He was one of the first chemists to embrace the new system of chemistry advanced by Lavoisier. Berthollet held several official appointments, among them inspector of dye works (from 1784) and Director of the Manufacture Nationale des Gobelins. These appointments enabled him to continue his researches and embark on a series of publications on the practical applications of chlorine, prussic acid (hydrocyanic acid) and ammonia. He clearly demonstrated the benefits of the French practice of appointing scientists to the state manufactories.There were two practical results of Berthollet's studies of chlorine. First, he produced a powerful explosive by substituting potassium chlorate, formed by the action of chlorine on potash, in place of nitre (potassium nitrate) in gunpowder. Then, mainly from humanitarian motives, he followed up Scheele's observation of the bleaching properties of chlorine water, in order to release for cultivation the considerable areas of land that had hitherto been required by the old bleaching process. The chlorine method greatly speeded up bleaching; this was a vital factor in the revolution in the textile industries.After a visit to Egypt in 1799, Berthollet carried out many experiments on dyeing, seeking to place this ancient craft onto a scientific basis. His work is summed up in his Eléments de l'art de la teinture, Paris, 1791.[br]Bibliography1791, Eléments de Van de la teinture, Paris (covers his work on dyeing).Berthollet published two books of importance in the early history of physical chemistry: 1801, Recherches sur les lois de l'affinité, Paris.1803, Essai de statique chimique, Paris.Annales de Chimie.Further ReadingE.F.Jomard, 1844, Notice sur la vie et les ouvrages de Claude-Louis Berthollet, Annecy.E.Farber, 1961, Great Chemists, New York: Interscience, pp. 32–4 (includes a short biographical account).LRDBiographical history of technology > Berthollet, Claude-Louis
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44 Bodmer, Johann Georg
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Railways and locomotives, Steam and internal combustion engines, Textiles, Weapons and armour[br]b. 9 December 1786 Zurich, Switzerlandd. 30 May 1864 Zurich, Switzerland[br]Swiss mechanical engineer and inventor.[br]John George Bodmer (as he was known in England) showed signs of great inventive ability even as a child. Soon after completing his apprenticeship to a local millwright, he set up his own work-shop at Zussnacht. One of his first inventions, in 1805, was a shell which exploded on impact. Soon after this he went into partnership with Baron d'Eichthal to establish a cotton mill at St Blaise in the Black Forest. Bodmer designed the water-wheels and all the machinery. A few years later they established a factory for firearms and Bodmer designed special machine tools and developed a system of interchangeable manufacture comparable with American developments at that time. More inventions followed, including a detachable bayonet for breech-loading rifles and a rifled, breech-loading cannon for 12 lb (5.4 kg) shells.Bodmer was appointed by the Grand Duke of Baden to the posts of Director General of the Government Iron Works and Inspector of Artillery. He left St Blaise in 1816 and entered completely into the service of the Grand Duke, but before taking up his duties he visited Britain for the first time and made an intensive five-month tour of textile mills, iron works, workshops and similar establishments.In 1821 he returned to Switzerland and was engaged in setting up cotton mills and other engineering works. In 1824 he went back to England, where he obtained a patent for his improvements in cotton machinery and set up a mill near Bolton incorporating his ideas. His health failing, he was obliged to return to Switzerland in 1828, but he was soon busy with engineering works there and in France. In 1833 he went to England again, first to Bolton and four years later to Manchester in partnership with H.H.Birley. In the next ten years he patented many more inventions in the fields of textile machinery, steam engines and machine tools. These included a balanced steam engine, a mechanical stoker, steam engine valve gear, gear-cutting machines and a circular planer or vertical lathe, anticipating machines of this type later developed in America by E.P. Bullard. The metric system was used in his workshops and in gearing calculations he introduced the concept of diametral pitch, which then became known as "Manchester Pitch". The balanced engine was built in stationary form and in two locomotives, but although their running was remarkably smooth the additional complication prevented their wider use.After the death of H.H.Birley in 1846, Bodmer removed to London until 1848, when he went to Austria. About 1860 he returned to his native town of Zurich. He remained actively engaged in all kinds of inventions up to the end of his life. He obtained fourteen British patents, each of which describes many inventions; two of these patents were extended beyond the normal duration of fourteen years. Two others were obtained on his behalf, one by his brother James in 1813 for his cannon and one relating to railways by Charles Fox in 1847. Many of his inventions had little direct influence but anticipated much later developments. His ideas were sound and some of his engines and machine tools were in use for over sixty years. He was elected a Member of the Institution of Civil Engineers in 1835.[br]Bibliography1845, "The advantages of working stationary and marine engines with high-pressure steam, expansively and at great velocities; and of the compensating, or double crank system", Minutes of the Proceedings of the Institution of Civil Engineers 4:372–99.1846, "On the combustion of fuel in furnaces and steam-boilers, with a description of Bodmer's fire-grate", Minutes of the Proceedings of the Institution of Civil Engineers 5:362–8.Further ReadingObituary, 1868–9, Minutes of the Proceedings of the Institution of Civil Engineers 28:573–608.H.W.Dickinson, 1929–30, "Diary of John George Bodmer, 1816–17", Transactions of the Newcomen Society 10:102–14.D.Brownlie, 1925–6, John George Bodmer, his life and work, particularly in relation to the evolution of mechanical stoking', Transactions of the Newcomen Society 6:86–110.W.O.Henderson (ed.), 1968, Industrial Britain Under the Regency: The Diaries of Escher, Bodmer, May and de Gallois 1814–1818, London: Frank Cass (a more complete account of his visit to Britain).RTS -
45 Dickson, J.T.
[br]b. c.1920 Scotland[br]Scottish co-inventor of the polyester fibre, Terylene.[br]The introduction of one type of artificial fibre encouraged chemists to look for more. J.T.Dickson and J.R. Whinfield discovered one such fibre in 1941 when they derived polyester from terephthalic acid and ethylene glycol. Dickson, a 21-year-old Edinburgh graduate, was working under Whinfield at the Calico Printers' Association research laboratory at Broad Oak Print Works in Accrington. He was put onto fibre research: probably in April, but certainly by 5 July 1941, a murky-looking resin had been synthesized, out of which Dickson successfully drew a filament, which was named "Terylene" by its discoverers. Owing to restrictions imposed in Britain during the Second World War, this fibre was developed initially by the DuPont Company in the USA, where it was marketed under the name "Dacron". When Imperial Chemical Industries (ICI) were able to manufacture it in Britain, it acquired the brand name "Terylene" and became very popular. Under the microscope, Terylene appears identical to nylon: longitudinally, it is completely devoid of any structure and the filaments appear as glass rods with a perfectly circular cross-section. The uses of Terylene are similar to those of nylon, but it has two advantages. First, it can be heat-set by exposing the fabric to a temperature about 30°C higher than is likely to be encountered in everyday use, and therefore can be the basis for "easy-care" clothing such as drip-dry shirts. It can be blended with other fibres such as wool, and when pressed at a high temperature the creases are remarkably durable. It is also remarkably resistant to chemicals, which makes it particularly suitable for industrial purposes under conditions where other textile materials would be degraded rapidly. Dickson later worked for ICI.[br]Further ReadingFor accounts of the discovery of Terylene, see: J.R.Whinfield, 1953, Textile Research Journal (May). R.Collins, 1991, "Terylene", Historian 30 (Spring).Accounts of the introduction of svnthetic fibres are covered in: D.S.Lyle, 1982, Modern Textiles, New York.S.R.Cockett, An Introduction to Man-Made Fibres.G.R.Wray, Modern Yarn Production.RLH -
46 Kay (of Bury), John
SUBJECT AREA: Textiles[br]b. 16 July 1704 Walmersley, near Bury, Lancashire, Englandd. 1779 France[br]English inventor of the flying shuttle.[br]John Kay was the youngest of five sons of a yeoman farmer of Walmersley, near Bury, Lancashire, who died before his birth. John was apprenticed to a reedmaker, and just before he was 21 he married a daughter of John Hall of Bury and carried on his trade in that town until 1733. It is possible that his first patent, taken out in 1730, was connected with this business because it was for an engine that made mohair thread for tailors and twisted and dressed thread; such thread could have been used to bind up the reeds used in looms. He also improved the reeds by making them from metal instead of cane strips so they lasted much longer and could be made to be much finer. His next patent in 1733, was a double one. One part of it was for a batting machine to remove dust from wool by beating it with sticks, but the patent is better known for its description of the flying shuttle. Kay placed boxes to receive the shuttle at either end of the reed or sley. Across the open top of these boxes was a metal rod along which a picking peg could slide and drive the shuttle out across the loom. The pegs at each end were connected by strings to a stick that was held in the right hand of the weaver and which jerked the shuttle out of the box. The shuttle had wheels to make it "fly" across the warp more easily, and ran on a shuttle race to support and guide it. Not only was weaving speeded up, but the weaver could produce broader cloth without any aid from a second person. This invention was later adapted for the power loom. Kay moved to Colchester and entered into partnership with a baymaker named Solomon Smith and a year later was joined by William Carter of Ballingdon, Essex. His shuttle was received with considerable hostility in both Lancashire and Essex, but it was probably more his charge of 15 shillings a year for its use that roused the antagonism. From 1737 he was much involved with lawsuits to try and protect his patent, particularly the part that specified the method of winding the thread onto a fixed bobbin in the shuttle. In 1738 Kay patented a windmill for working pumps and an improved chain pump, but neither of these seems to have been successful. In 1745, with Joseph Stell of Keighley, he patented a narrow fabric loom that could be worked by power; this type may have been employed by Gartside in Manchester soon afterwards. It was probably through failure to protect his patent rights that Kay moved to France, where he arrived penniless in 1747. He went to the Dutch firm of Daniel Scalongne, woollen manufacturers, in Abbeville. The company helped him to apply for a French patent for his shuttle, but Kay wanted the exorbitant sum of £10,000. There was much discussion and eventually Kay set up a workshop in Paris, where he received a pension of 2,500 livres. However, he was to face the same problems as in England with weavers copying his shuttle without permission. In 1754 he produced two machines for making card clothing: one pierced holes in the leather, while the other cut and sharpened the wires. These were later improved by his son, Robert Kay. Kay returned to England briefly, but was back in France in 1758. He was involved with machines to card both cotton and wool and tried again to obtain support from the French Government. He was still involved with developing textile machines in 1779, when he was 75, but he must have died soon afterwards. As an inventor Kay was a genius of the first rank, but he was vain, obstinate and suspicious and was destitute of business qualities.[br]Bibliography1730, British patent no. 515 (machine for making mohair thread). 1733, British patent no. 542 (batting machine and flying shuttle). 1738, British patent no. 561 (pump windmill and chain pump). 1745, with Joseph Stell, British patent no. 612 (power loom).Further ReadingB.Woodcroft, 1863, Brief Biographies of Inventors or Machines for the Manufacture of Textile Fabrics, London.J.Lord, 1903, Memoir of John Kay, (a more accurate account).Descriptions of his inventions may be found in A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; R.L. Hills, 1970, Power in theIndustrial Revolution, Manchester; and C.Singer (ed.), 1957, A History ofTechnology, Vol. III, Oxford: Clarendon Press. The most important record, however, is in A.P.Wadsworth and J. de L. Mann, 1931, The Cotton Trade and IndustrialLancashire, Manchester.RLH -
47 Lister, Samuel Cunliffe, 1st Baron Masham
SUBJECT AREA: Textiles[br]b. 1 January 1815 Calverly Hall, Bradford, Englandd. 2 February 1906 Swinton Park, near Bradford, England[br]English inventor of successful wool-combing and waste-silk spinning machines.[br]Lister was descended from one of the old Yorkshire families, the Cunliffe Listers of Manningham, and was the fourth son of his father Ellis. After attending a school on Clapham Common, Lister would not go to university; his family hoped he would enter the Church, but instead he started work with the Liverpool merchants Sands, Turner \& Co., who frequently sent him to America. In 1837 his father built for him and his brother a worsted mill at Manningham, where Samuel invented a swivel shuttle and a machine for making fringes on shawls. It was here that he first became aware of the unhealthy occupation of combing wool by hand. Four years later, after seeing the machine that G.E. Donisthorpe was trying to work out, he turned his attention to mechanizing wool-combing. Lister took Donisthorpe into partnership after paying him £12,000 for his patent, and developed the Lister-Cartwright "square nip" comber. Until this time, combing machines were little different from Cartwright's original, but Lister was able to improve on this with continuous operation and by 1843 was combing the first fine botany wool that had ever been combed by machinery. In the following year he received an order for fifty machines to comb all qualities of wool. Further combing patents were taken out with Donisthorpe in 1849, 1850, 1851 and 1852, the last two being in Lister's name only. One of the important features of these patents was the provision of a gripping device or "nip" which held the wool fibres at one end while the rest of the tuft was being combed. Lister was soon running nine combing mills. In the 1850s Lister had become involved in disputes with others who held combing patents, such as his associate Isaac Holden and the Frenchman Josué Heilmann. Lister bought up the Heilmann machine patents and afterwards other types until he obtained a complete monopoly of combing machines before the patents expired. His invention stimulated demand for wool by cheapening the product and gave a vital boost to the Australian wool trade. By 1856 he was at the head of a wool-combing business such as had never been seen before, with mills at Manningham, Bradford, Halifax, Keighley and other places in the West Riding, as well as abroad.His inventive genius also extended to other fields. In 1848 he patented automatic compressed air brakes for railways, and in 1853 alone he took out twelve patents for various textile machines. He then tried to spin waste silk and made a second commercial career, turning what was called "chassum" and hitherto regarded as refuse into beautiful velvets, silks, plush and other fine materials. Waste silk consisted of cocoon remnants from the reeling process, damaged cocoons and fibres rejected from other processes. There was also wild silk obtained from uncultivated worms. This is what Lister saw in a London warehouse as a mass of knotty, dirty, impure stuff, full of bits of stick and dead mulberry leaves, which he bought for a halfpenny a pound. He spent ten years trying to solve the problems, but after a loss of £250,000 and desertion by his partner his machine caught on in 1865 and brought Lister another fortune. Having failed to comb this waste silk, Lister turned his attention to the idea of "dressing" it and separating the qualities automatically. He patented a machine in 1877 that gave a graduated combing. To weave his new silk, he imported from Spain to Bradford, together with its inventor Jose Reixach, a velvet loom that was still giving trouble. It wove two fabrics face to face, but the problem lay in separating the layers so that the pile remained regular in length. Eventually Lister was inspired by watching a scissors grinder in the street to use small emery wheels to sharpen the cutters that divided the layers of fabric. Lister took out several patents for this loom in his own name in 1868 and 1869, while in 1871 he took out one jointly with Reixach. It is said that he spent £29,000 over an eleven-year period on this loom, but this was more than recouped from the sale of reasonably priced high-quality velvets and plushes once success was achieved. Manningham mills were greatly enlarged to accommodate this new manufacture.In later years Lister had an annual profit from his mills of £250,000, much of which was presented to Bradford city in gifts such as Lister Park, the original home of the Listers. He was connected with the Bradford Chamber of Commerce for many years and held the position of President of the Fair Trade League for some time. In 1887 he became High Sheriff of Yorkshire, and in 1891 he was made 1st Baron Masham. He was also Deputy Lieutenant in North and West Riding.[br]Principal Honours and DistinctionsCreated 1st Baron Masham 1891.Bibliography1849, with G.E.Donisthorpe, British patent no. 12,712. 1850, with G.E. Donisthorpe, British patent no. 13,009. 1851, British patent no. 13,532.1852, British patent no. 14,135.1877, British patent no. 3,600 (combing machine). 1868, British patent no. 470.1868, British patent no. 2,386.1868, British patent no. 2,429.1868, British patent no. 3,669.1868, British patent no. 1,549.1871, with J.Reixach, British patent no. 1,117. 1905, Lord Masham's Inventions (autobiography).Further ReadingJ.Hogg (ed.), c. 1888, Fortunes Made in Business, London (biography).W.English, 1969, The Textile Industry, London; and C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press (both cover the technical details of Lister's invention).RLHBiographical history of technology > Lister, Samuel Cunliffe, 1st Baron Masham
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48 Mercer, John
SUBJECT AREA: Textiles[br]b. 21 February 1791 Great Harwood, Lancashire, Englandd. 30 November 1866 Oakenshaw, Lancashire, England[br]English pioneer in textile chemistry.[br]Mercer began work at the age of 9 as a bobbinwinder and then a hand-loom weaver. He had no formal education in chemistry but taught himself and revealed remarkable ability in both theoretical and applied aspects of the subject. He became the acknowledged "father of textile chemistry" and the Royal Society elected him Fellow in 1850. His name is remembered in connection with the lustrous "mercerized" cotton which, although not developed commercially until 1890, arose from his discovery, c. 1844, of the effect of caustic soda on cotton linters. He also discovered that cotton could be dissolved in a solution of copper oxide in ammonia, a phenomenon later exploited in the manufacture of artificial silk. As a youth, Mercer experimented at home with dyeing processes and soon acquired sufficient skill to set up as an independent dyer. Most of his working life was, however, spent with the calico-printing firm of Oakenshaw Print Works in which he eventually became a partner, and it was there that most of his experimental work was done. The association was a very appropriate one, for it was a member of this firm's staff who first recognized Mercer's potential talent and took the trouble in his spare time to teach him reading, writing and arithmetic. Mercer developed manganese-bronze colours and researched into catalysis and the ferrocyanides. Among his innovations was the chlorination of wool in order to make it print as easily as cotton. It was many years later that it was realized that this treatment also conferred valuable shrink-resisting qualities. Becoming interested in photochemistry, he devised processes for photographic printing on fabric. Queen Victoria was presented with a handkerchief printed in this way when she visited the Great Exhibition of 1851, of which Mercer was a juror. A photograph of Mercer himself on cloth is preserved in the Museum of Science and Industry in Manchester. He presented papers to the British Association and was a member of the Chemical Society.[br]Principal Honours and DistinctionsFRS 1850.Further ReadingObituary, Manchester Memoirs, Manchester Literary and Philosophical Society.Dictionary of National Biography.E.A.Parnell, 1886. The Life and Labours of John Mercer, F.R.S., London (biography). 1867, biography, Journal of the Chemical Society.A.E.Musson and E.Robinson, 1969, Science and Technology in the Industrial Revolution, Manchester (includes a brief reference to Mercer's work).RLH -
49 Murray, Matthew
SUBJECT AREA: Land transport, Mechanical, pneumatic and hydraulic engineering, Railways and locomotives, Steam and internal combustion engines[br]b. 1765 near Newcastle upon Tyne, Englandd. 20 February 1826 Holbeck, Leeds, England[br]English mechanical engineer and steam engine, locomotive and machine-tool pioneer.[br]Matthew Murray was apprenticed at the age of 14 to a blacksmith who probably also did millwrighting work. He then worked as a journeyman mechanic at Stockton-on-Tees, where he had experience with machinery for a flax mill at Darlington. Trade in the Stockton area became slack in 1788 and Murray sought work in Leeds, where he was employed by John Marshall, who owned a flax mill at Adel, located about 5 miles (8 km) from Leeds. He soon became Marshall's chief mechanic, and when in 1790 a new mill was built in the Holbeck district of Leeds by Marshall and his partner Benyon, Murray was responsible for the installation of the machinery. At about this time he took out two patents relating to improvements in textile machinery.In 1795 he left Marshall's employment and, in partnership with David Wood (1761– 1820), established a general engineering and millwrighting business at Mill Green, Holbeck. In the following year the firm moved to a larger site at Water Lane, Holbeck, and additional capital was provided by two new partners, James Fenton (1754–1834) and William Lister (1796–1811). Lister was a sleeping partner and the firm was known as Fenton, Murray \& Wood and was organized so that Fenton kept the accounts, Wood was the administrator and took charge of the workshops, while Murray provided the technical expertise. The factory was extended in 1802 by the construction of a fitting shop of circular form, after which the establishment became known as the "Round Foundry".In addition to textile machinery, the firm soon began the manufacture of machine tools and steam-engines. In this field it became a serious rival to Boulton \& Watt, who privately acknowledged Murray's superior craftsmanship, particularly in foundry work, and resorted to some industrial espionage to discover details of his techniques. Murray obtained patents for improvements in steam engines in 1799, 1801 and 1802. These included automatic regulation of draught, a mechanical stoker and his short-D slide valve. The patent of 1801 was successfully opposed by Boulton \& Watt. An important contribution of Murray to the development of the steam engine was the use of a bedplate so that the engine became a compact, self-contained unit instead of separate components built into an en-gine-house.Murray was one of the first, if not the very first, to build machine tools for sale. However, this was not the case with the planing machine, which he is said to have invented to produce flat surfaces for his slide valves. Rather than being patented, this machine was kept secret, although it was apparently in use before 1814.In 1812 Murray was engaged by John Blenkinsop (1783–1831) to build locomotives for his rack railway from Middleton Colliery to Leeds (about 3 1/2 miles or 5.6 km). Murray was responsible for their design and they were fitted with two double-acting cylinders and cranks at right angles, an important step in the development of the steam locomotive. About six of these locomotives were built for the Middleton and other colliery railways and some were in use for over twenty years. Murray also supplied engines for many early steamboats. In addition, he built some hydraulic machinery and in 1814 patented a hydraulic press for baling cloth.Murray's son-in-law, Richard Jackson, later became a partner in the firm, which was then styled Fenton, Murray \& Jackson. The firm went out of business in 1843.[br]Principal Honours and DistinctionsSociety of Arts Gold Medal 1809 (for machine for hackling flax).Further ReadingL.T.C.Rolt, 1962, Great Engineers, London (contains a good short biography).E.Kilburn Scott (ed.), 1928, Matthew Murray, Pioneer Engineer, Leeds (a collection of essays and source material).C.F.Dendy Marshall, 1953, A History of Railway Locomotives Down to the End of theYear 1831, London.L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (provides information on Murray's machine-tool work).Some of Murray's correspondence with Simon Goodrich of the Admiralty has been published in Transactions of the Newcomen Society 3 (1922–3); 6(1925–6); 18(1937– 8); and 32 (1959–60).RTS -
50 аппаратное производство
1) Textile: woolen manufacture2) Electrical engineering: apparatus manufacturingУниверсальный русско-английский словарь > аппаратное производство
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51 брак
1) General subject: alliance, chip, defective articles, discard, double harness, flaw (товара), flawed article, foozle (в работе), market value, marriage, match, matrimony, refuse, rejections, rejects, shoddy workmanship, splice, spoilage, spousal, throw out, throws, waster, wastrel, wedlock (children born in wedlock - законнорождённые дети), reject rate, faulty workmanship, unsoundness, espousal2) Naval: fag end3) Colloquial: write-off4) Engineering: bad quality, defective products, faulty production, scrap, substandard production5) Bookish: (законный) wedlock6) Construction: below proof7) Religion: Matrimonum ( "marriage", сокр. Matr.)8) Law: marriage state, matrimonial state, reject, waste9) Commerce: brack10) Economy: bad work11) Accounting: abnormal spoilage, defect, penalty12) Australian slang: quickie13) Automobile industry: penalty (производственный), scrapped parts, throw-out, throw-outs14) Cinema: flop16) Metallurgy: refused material, rejected material17) Textile: shorts18) Jargon: hitch-up19) Oil: throw-away, throwaway20) Cartography: bastard22) Advertising: defective work, lemon, wastage23) Business: faulty goods24) Production: defective goods25) EBRD: reject item27) Automation: (неисправимый) scrap, (неисправимый) scrappage28) Plastics: spoiled casting29) leg.N.P. damaged or defective articles of manufacture (business law), factory rejects (business law), marriage (family law), spoil (in this sense; business law), waste (in this sense; business law)30) Makarov: bed, chips, defect (дефект в изделии), faulty work, monks-and-friars, reject (об изделии), rejected product, settlement, spoilage (об изделии), substandard items, waste (неисправимый)31) Gold mining: offline -
52 выделка
1) General subject: fabric, manufacture, manufacturing, milling, workmanship3) Textile: embossing -
53 готовое изделие
1) General subject: end product, off the peg product, off-the-peg product2) Naval: off-the shelf item3) Engineering: end item, finished article, finished material, purchased item4) Mathematics: a finished product5) Economy: article of manufacture, complete product, final product, manufactured product, ready-made product, released product6) Accounting: finished product7) Forestry: finished work8) Textile: finished fabric, fully processed product, fully-manufactured article9) Sowing: seaming10) Business: ready made, ready-to-wear11) Production: non-development item13) Automation: finished piece14) Chemical weapons: non-developmental item (ГИ)15) Makarov: purchased item (покупное) -
54 мануфактурное производство
1) Economy: manufacturing system2) Textile: cloth manufactureУниверсальный русско-английский словарь > мануфактурное производство
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55 обработка
1) General subject: adaptation, cultivation, elaboration, handling, manufacture, manufacturing, medication, processing, refinement, treatment (чем-либо), work, working, working up, working-out2) Naval: reduction (наблюдений)3) Medicine: manipulation, therapy treatable4) Obsolete: preparation5) Military: handing, (механическая) machining, message output processing, processing (информации, данных), processing (информации. данных), reduction (данных)6) Engineering: blading (стругом), cutting, machining, process (технологическая), processing (переработка), roughing, sizing, steaming, tillage, tooling, treating (придание нужных свойств), treatment (придание нужных свойств), turning7) Agriculture: (предпосевная) cultivation, development, dressing (земли)8) Law: handling (документов, грузов)10) Accounting: processing (данных)11) Statistics: analysis12) Automobile industry: processing (главным образом химическая или термическая)14) Metallurgy: conditioning (напр. пульпы реагентами), contour (листа штамповкой), handling (напр. проб)15) Music: musical adaptation or treatment16) Polygraphy: preparing17) Telecommunications: interpretation18) Theatre: mastering (окончательная обработка сведенной аудиозаписи)19) Textile: conditioning, run20) Information technology: cooking, elaboration (описания объекта в языке программирования)21) Oil: processing (химическая или термическая), treating, treatment (воды, бурового раствора)22) Astronautics: dressing23) Metrology: processing (например, данных)24) Ecology: evaluation (данных), laboring (почвы), refuse treatment25) Drilling: cond (conditioning; бурового раствора)26) EBRD: conversion (продукции), handling (грузов)28) Programming: catching29) Automation: handling (данных), (механическая) machining, process work, production, production work, working (см. тж. work)31) Robots: handling (информации), manipulation (информации)32) Cables: treatment (придание нужных свойств)33) Medical appliances: cleaning34) Makarov: cultivation (почвы), development (фотоматериалов), digesting, digestion, dressing (птицы, рыбы), finish operation, handling (почвы), management (почвы), operation, processing (напр. данных), processing (напр., данных), processing (перерабатывание), retrieval (информации), treatment (придание нужных св-в)35) Security: processing (информации или сигналов), treatment (напр. информации)36) SAP.tech. editing, hdlg, prcssg -
56 полуфабрикат
1) General subject: half-stock, prepack, semi-product, intermediate product, semi-finished product, premade2) Engineering: half-blank, half-finished material, half-finished product, half-stuff, half-way product, preformed material, semifinished item, semifinished product, semimanufactured article, semimanufactured product, semiprocessed product, semiproduct, stuff, stuft3) Construction: blank, semifinished goods4) Railway term: half manufactured5) Economy: intermediate, semifinished article, semifinished piece, semiprocessed unit, work in process6) Metallurgy: semifinished material, semimanufactured material7) Textile: semi-manufactured, semi-manufactured article8) Oil: half stock, half stuff9) Food industry: junk food (Осторожнее с употреблением! Касается только замороженных готовых блюд.), prepared food, uncooked food10) Mechanics: buffer stock, half product, partially-finished unit, semifinished workpiece, subproduct11) Cellulose: first stuff12) Ecology: by-product (промежуточный продукт в промышленности)13) Taxes: semi-manufacture14) Production: part finished item (PF) (изделие, которое обрабатывается на какой-либо стадии производства)15) Industrial economy: unfinished product16) Automation: in-process part, semicompleted part, semifinished part18) Cables: semi-finished products19) Makarov: crude product, half-prepared product, semi-manufactured product20) Gold mining: half-finished21) Logistics: semiprepared product22) Cement: raw material -
57 сетевязание
1) Engineering: netting2) Textile: fish netting, net making, net manufacture -
58 трикотажное производство
1) Engineering: knitting art, knitwear manufacture2) Textile: hosieryУниверсальный русско-английский словарь > трикотажное производство
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59 фабричное клеймо
1) General subject: brand, manufacture mark, mark (крест - вместо подписи неграмотного: John Smith - his mark)2) Law: chop3) Metallurgy: manufacturer's mark, trade mark4) Textile: trademark die5) Advertising: factory mark6) Patents: manufacturing mark, works mark -
60 Abaca
ABACA, or MANILA HEMPA fibre obtained from the leaf stalks of the "musa textilis", a plant in the Philippine Islands, Sumatra, Java and Borneo. It is strong, has great durability, varies from 40-in. to 140-in. in length, yellowish-white in colour, and has a lustrous appearance. It is light, but rather stiff in handle. The yield of the fibre is only about 11/2 per cent of the weight of the green leaves. In India the inner fibres of the leaf stalk are much used for making fine cloths, the outer and coarser fibres being used in the manufacture of matting for floor covering, cordage, canvas, etc. The fibre (fine quality) is also used as weft in some fabrics for upholstery, chiefly on account of its colour and lustre. There are many grades, ranging from fine to coarse, obtained from these several species of banana and pineapple plants. Manila hats are made from these fibres. The fibres are tied end to end and woven without being spun into yarns. It is a tall plant, growing from 16 to 22 feet, and has a stem up to 12-in. diameter. This is one of the most important fibres cultivated in the tropics. Although called Manila Hemp it is quite unlike true hemp. Others names are "Cebu Hemp" and "Davao Hemp" (see textile fibres)
См. также в других словарях:
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