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1 Institute of Gas Technology
Англо-русский словарь нормативно-технической терминологии > Institute of Gas Technology
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2 Institute of Gas Technology
Большой англо-русский и русско-английский словарь > Institute of Gas Technology
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3 Institute of Gas Technology
Англо-русский словарь нефтегазовой промышленности > Institute of Gas Technology
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4 Institute of Gas Technology
Нефть: Институт технологии газа (США)Универсальный англо-русский словарь > Institute of Gas Technology
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5 Institute
╜ Institute of Gas Technology Institute of Geological Sciences Institute of Petroleum American Institute of Chemical Engineers American Institute of Chemists American Institute of Mining and Metallurgical Engineers American Geological Institute American National Standards Institute American Petroleum Institute Massachusetts Institute of Technology National Lubricating Grease Institute National Petroleum Institute Singapore Institute of Standards and Industrial ResearchInstitute: ~ of Bankers Институт банкиров (Великобритания)~ of Chartered Accountants Институт дипломированных бухгалтеров (Великобритания)Большой англо-русский и русско-английский словарь > Institute
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6 institute
1. институт2. учреждение3. устав, кодекс4. учреждать, основыватьAmerican institute of Mining and Metallurgical Engineers — Американский институт горных инженеров и инженеров-металлургов
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- Institute of Geological Sciences
- Institute of Petroleum
- American Institute of Chemical Engineers
- American Institute of Chemists
- American Institute of Mining and Metallurgical Engineers
- American Geological Institute
- American National Standards Institute
- American Petroleum Institute
- Massachusetts Institute of Technology
- National Lubricating Grease Institute
- National Petroleum Institute
- Singapore Institute of Standards and Industrial Research* * *• кодекс• уставАнгло-русский словарь нефтегазовой промышленности > institute
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7 Институт технологии газа
Большой англо-русский и русско-английский словарь > Институт технологии газа
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8 IGT
[Institute of Gas Technology] — Институт технологии газа
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сокр.[Institute of Gas Technology] Институт технологии газа ( США)* * * -
9 IGT
1) Медицина: impaired glucose tolerance (нарушение толерантности к глюкозе), НТГ, нарушенная толерантность к глюкозе2) Военный термин: Inspector General of Transportation, Inspector General to the Forces for Training, Interdepartmental Group on Terrorism3) Техника: instrument guide tube, insulated-gate tetrode, interactive graphics terminal, промыленные газовые турбины (industrial gas turbines)4) Религия: Independent Gospel Team5) Полиграфия: прибор для тестирования бумаги6) Сокращение: ingot, impaired glucose tolerance7) Вычислительная техника: intelligent graphics terminal8) Нефть: Institute of Gas Technology, induced gamma ray tool, Институт технологии газа (США; Institute of Gas Technology)9) Сетевые технологии: intelligent graphical terminal, интеллектуальный графический терминал10) Чат: In Good Taste11) NYSE. International Game Technology -
10 IGT
1. Institute of Gas Technology - Институт технологии газа;2. instrument guide tube - направляющая труба измерительных приборов;3. insulated-gate tetrode - тетрод с изолированным затвором;4. intelligent graphics terminal - интеллектуальный графический терминал;5. interactive graphics terminal - терминал интерактивной графики, интерактивный графический терминал -
11 GTI
1) Общая лексика: Всемирная Добровольная Организация Спасения Тигров2) Спорт: Grand Tourer Injection, Grand Touring Injection3) Техника: ground test instrumentation4) Юридический термин: Getting Teenagers Involved5) Политика: ГИП, Глобальная инициатива прозрачности, Global Transparency Initiative6) Сокращение: German Tank Improvement, Global Trade Information Services, Inc.7) Университет: Graduates To Industry, Grounded Theory Institute8) Сетевые технологии: Gateway Transaction Interface10) Международная торговля: Global Teamwork Information -
12 Townes, Charles Hard
SUBJECT AREA: Electronics and information technology[br]b. 28 July 1915 Greenville, South Carolina, USA[br]American physicist who developed the maser and contributed to the development of the laser.[br]Charles H.Townes entered Furman University, Greenville, at the early age of 16 and in 1935 obtained a BA in modern languages and a BS in physics. After a year of postgraduate study at Duke University, he received a master's degree in physics in 1936. He then went on to the California Institute of Technology, where he obtained a PhD in 1939. From 1939 to 1947 he worked at the Bell Telephone Laboratories, mainly on airborne radar, although he also did some work on radio astronomy. In 1948 he joined Columbia University as Associate Professor of Physics and in 1950 was appointed a full professor. He was Director of the University's Radiation Laboratory from 1950 to 1952, and from 1952 to 1955 he was Chairman of the Physics Department.To meet the need for an oscillator generating very short wavelength electromagnetic radiation, Townes in 1951 realized that use could be made of the different natural energy levels of atoms and molecules. The practical application of this idea was achieved in his laboratory in 1953 using ammonia gas to make the device known as a maser (an acronym of microwave amplification by stimulated emission of radiation). The maser was developed in the next few years and in 1958, in a joint paper with his brother-in-law Arthur L. Schawlow, Townes suggested the possibility of a further development into optical frequencies or an optical maser, later known as a laser (an acronym of light amplification by stimulated emission of radiation). Two years later the first such device was made by Theodore H. Maiman.In 1959 Townes was given leave from Columbia University to serve as Vice-President and Director of Research at the Institute for Defense Analyses until 1961. He was then appointed Provost and Professor of Physics at the Massachusetts Institute of Technology. In 1967 he became University Professor of Physics at the University of California, where he has extended his research interests in the field of microwave and infra-red astronomy. He is a member of the National Academy of Sciences, the Institute of Electrical and Electronics Engineers and the American Astronomical Society.[br]Principal Honours and DistinctionsNobel Prize for Physics 1964. Foreign Member, Royal Society of London. President, American Physical Society 1967. Townes has received many awards from American and other scientific societies and institutions and honorary degrees from more than twenty universities.BibliographyTownes is the author of many scientific papers and, with Arthur L.Schawlow, ofMicrowave Spectroscopy (1955).1980, entry, McGraw-Hill Modern Scientists and Engineers, Part 3, New York, pp. 227– 8 (autobiography).1991, entry, The Nobel Century, London, p. 106 (autobiography).Further ReadingT.Wasson (ed.), 1987, Nobel Prize Winners, New York, pp. 1,071–3 (contains a short biography).RTS -
13 British
British ['brɪtɪʃ]∎ the British les Britanniques mpl, les Anglais mplbritannique, anglais;∎ British goods produits mpl anglais;∎ British the best of British (luck)! bonne chance!►► the British Academy = organisme public d'aide à la recherche dans le domaine des lettres;formerly Aviation & Commerce British Aerospace British Aerospace f (principale société de construction aéronautique et spatiale britannique);British Antarctic Territory territoire m de l'Antarctique britannique;Military British Army of the Rhine = forces armées britanniques établies en Allemagne de l'Ouest après la Seconde Guerre mondiale;Cinema British Board of Film Classification = organisme britannique délivrant les visas de sortie pour les films;Radio & Television the British Broadcasting Corporation la BBC;British Columbia la Colombie-Britannique;∎ in British Columbia en Colombie-Britannique;1 noun= habitant ou natif de la Colombie-Britanniquede la Colombie-Britannique;the British Commonwealth le Commonwealth;Administration the British Council = organisme public chargé de promouvoir la langue et la culture anglaises;History the British East India Company la Compagnie britannique des Indes orientales;the British Embassy l'ambassade f de Grande-Bretagne;History the British Empire l'Empire m britannique;British English anglais m britannique;Cinema British Film Institute = organisme britannique de promotion du cinéma (aide à la réalisation notamment);formerly British Gas = société de production et de distribution du gaz;(former) British Honduras (l'ex) Honduras m britannique;∎ in British Honduras au Honduras britannique;British Institute of Management = organisme britannique dont la fonction est de renseigner et de conseiller les entreprises en matière de gestion, ainsi que de promouvoir l'enseignement de cette discipline;the British Isles les îles fpl Britanniques;∎ in the British Isles aux îles Britanniques;British Legion = organisme d'aide aux anciens combattants;British Library = la bibliothèque nationale britannique;Sport the British Lions = équipe de rugby à quinze constituée des joueurs sélectionnés dans les quatre équipes nationales (Angleterre, pays de Galles, Écosse et Irlande);British Museum = grand musée et bibliothèque londoniens;British Nuclear Fuels = entreprise publique de production de combustibles nucléaires;the British Open = important championnat de golf qui se tient chaque année en Grande-Bretagne;formerly British Rail = société des chemins de fers britanniques, ≃ SNCF f;British Standards Institution = association britannique de normalisation;formerly British Steel = société britannique de production d'acier;British Summer Time = heure d'été britannique;British Technology Group = organisme privé britannique commercialisant des innovations technologiques élaborées par des universités ou des inventeurs;formerly British Telecom = société britannique de télécommunications;Physics British thermal unit calorie f britannique, ≃ 1055,06 joules mplⓘ BRITISH COUNCIL Le British Council est chargé de promouvoir la langue et la culture anglaises, et de renforcer les liens culturels avec les autres pays.ⓘ THE BRITISH EAST INDIA COMPANY Fondée en 1600 pour contrôler le commerce dans les colonies, la Compagnie joua, à partir du XVIIIème siècle, un rôle de plus en plus politique en Inde, pour finalement devenir l'agent de l'impérialisme britannique; elle disparut dans les années 1870.ⓘ BRITISH GAS/TELECOM/RAIL Plusieurs services britanniques autrefois publics ont été successivement privatisés. En 1984, les résaux de télécommunications sont rachetés par British Telecom. Cet opérateur privé en assure le monopole jusqu'en 1991, lorsque le marché est ouvert à la concurrence. British Telecom devient alors BT et partage le marché avec plusieurs autres compagnies. British Gas est privatisé en 1986 et a pris le nom de Centrica. British Rail est partagé dans les années 90 entre Railtrack, propriétaire des stations et lignes de chemin de fer, et plusieurs petites compagnies qui assurent le trafic ferroviaire. -
14 TIDE
1) Военный термин: tactical international data exchange, total information distribution equipment2) Техника: timer demodulator3) Религия: Trinity Institute Of Discipleship Enhancement4) Сокращение: Tactical Information Data Exchange5) Вычислительная техника: Technical Information Database6) Деловая лексика: Technology And Information Delivered For Empowerment, Technology Insertion Demonstration And Evaluation7) НАСДАК: Tidelands Oil and Gas Corporation -
15 tide
1) Военный термин: tactical international data exchange, total information distribution equipment2) Техника: timer demodulator3) Религия: Trinity Institute Of Discipleship Enhancement4) Сокращение: Tactical Information Data Exchange5) Вычислительная техника: Technical Information Database6) Деловая лексика: Technology And Information Delivered For Empowerment, Technology Insertion Demonstration And Evaluation7) НАСДАК: Tidelands Oil and Gas Corporation -
16 Haber, Fritz
SUBJECT AREA: Chemical technology[br]b. 9 December 1868 Breslau, Germany (now Wroclaw, Poland)d. 29 January 1934 Basel, Switzerland[br]German chemist, inventor of the process for the synthesis of ammonia.[br]Haber's father was a manufacturer of dyestuffs, so he studied organic chemistry at Berlin and Heidelberg universities to equip him to enter his father's firm. But his interest turned to physical chemistry and remained there throughout his life. He became Assistant at the Technische Hochschule in Karlsruhe in 1894; his first work there was on pyrolysis and electrochemistry, and he published his Grundrisse der technischen Electrochemie in 1898. Haber became famous for thorough and illuminating theoretical studies in areas of growing practical importance. He rose through the academic ranks and was appointed a full professor in 1906. In 1912 he was also appointed Director of the Institute of Physical Chemistry and Electrochemistry at Dahlem, outside Berlin.Early in the twentieth century Haber invented a process for the synthesis of ammonia. The English chemist and physicist Sir William Crookes (1832–1919) had warned of the danger of mass hunger because the deposits of Chilean nitrate were becoming exhausted and nitrogenous fertilizers would not suffice for the world's growing population. A solution lay in the use of the nitrogen in the air, and the efforts of chemists centred on ways of converting it to usable nitrate. Haber was aware of contemporary work on the fixation of nitrogen by the cyanamide and arc processes, but in 1904 he turned to the study of ammonia formation from its elements, nitrogen and hydrogen. During 1907–9 Haber found that the yield of ammonia reached an industrially viable level if the reaction took place under a pressure of 150–200 atmospheres and a temperature of 600°C (1,112° F) in the presence of a suitable catalyst—first osmium, later uranium. He devised an apparatus in which a mixture of the gases was pumped through a converter, in which the ammonia formed was withdrawn while the unchanged gases were recirculated. By 1913, Haber's collaborator, Carl Bosch had succeeded in raising this laboratory process to the industrial scale. It was the first successful high-pressure industrial chemical process, and solved the nitrogen problem. The outbreak of the First World War directed the work of the institute in Dahlem to military purposes, and Haber was placed in charge of chemical warfare. In this capacity, he developed poisonous gases as well as the means of defence against them, such as gas masks. The synthetic-ammonia process was diverted to produce nitric acid for explosives. The great benefits and achievement of the Haber-Bosch process were recognized by the award in 1919 of the Nobel Prize in Chemistry, but on account of Haber's association with chemical warfare, British, French and American scientists denounced the award; this only added to the sense of bitterness he already felt at his country's defeat in the war. He concentrated on the theoretical studies for which he was renowned, in particular on pyrolysis and autoxidation, and both the Karlsruhe and the Dahlem laboratories became international centres for discussion and research in physical chemistry.With the Nazi takeover in 1933, Haber found that, as a Jew, he was relegated to second-class status. He did not see why he should appoint staff on account of their grandmothers instead of their ability, so he resigned his posts and went into exile. For some months he accepted hospitality in Cambridge, but he was on his way to a new post in what is now Israel when he died suddenly in Basel, Switzerland.[br]Bibliography1898, Grundrisse der technischen Electrochemie.1927, Aus Leben und Beruf.Further ReadingJ.E.Coates, 1939, "The Haber Memorial Lecture", Journal of the Chemical Society: 1,642–72.M.Goran, 1967, The Story of Fritz Haber, Norman, OK: University of Oklahoma Press (includes a complete list of Haber's works).LRD -
17 Coolidge, William David
[br]b. 23 October 1873 Hudson, Massachusetts, USAd. 3 February 1975 New York, USA[br]American physicist and metallurgist who invented a method of producing ductile tungsten wire for electric lamps.[br]Coolidge obtained his BS from the Massachusetts Institute of Technology (MIT) in 1896, and his PhD (physics) from the University of Leipzig in 1899. He was appointed Assistant Professor of Physics at MIT in 1904, and in 1905 he joined the staff of the General Electric Company's research laboratory at Schenectady. In 1905 Schenectady was trying to make tungsten-filament lamps to counter the competition of the tantalum-filament lamps then being produced by their German rival Siemens. The first tungsten lamps made by Just and Hanaman in Vienna in 1904 had been too fragile for general use. Coolidge and his life-long collaborator, Colin G. Fink, succeeded in 1910 by hot-working directly dense sintered tungsten compacts into wire. This success was the result of a flash of insight by Coolidge, who first perceived that fully recrystallized tungsten wire was always brittle and that only partially work-hardened wire retained a measure of ductility. This grasped, a process was developed which induced ductility into the wire by hot-working at temperatures below those required for full recrystallization, so that an elongated fibrous grain structure was progressively developed. Sintered tungsten ingots were swaged to bar at temperatures around 1,500°C and at the end of the process ductile tungsten filament wire was drawn through diamond dies around 550°C. This process allowed General Electric to dominate the world lamp market. Tungsten lamps consumed only one-third the energy of carbon lamps, and for the first time the cost of electric lighting was reduced to that of gas. Between 1911 and 1914, manufacturing licences for the General Electric patents had been granted for most of the developed work. The validity of the General Electric monopoly was bitterly contested, though in all the litigation that followed, Coolidge's fibering principle was upheld. Commercial arrangements between General Electric and European producers such as Siemens led to the name "Osram" being commonly applied to any lamp with a drawn tungsten filament. In 1910 Coolidge patented the use of thoria as a particular additive that greatly improved the high-temperature strength of tungsten filaments. From this development sprang the technique of "dispersion strengthening", still being widely used in the development of high-temperature alloys in the 1990s. In 1913 Coolidge introduced the first controllable hot-cathode X-ray tube, which had a tungsten target and operated in vacuo rather than in a gaseous atmosphere. With this equipment, medical radiography could for the first time be safely practised on a routine basis. During the First World War, Coolidge developed portable X-ray units for use in field hospitals, and between the First and Second World Wars he introduced between 1 and 2 million X-ray machines for cancer treatment and for industrial radiography. He became Director of the Schenectady laboratory in 1932, and from 1940 until 1944 he was Vice-President and Director of Research. After retirement he was retained as an X-ray consultant, and in this capacity he attended the Bikini atom bomb trials in 1946. Throughout the Second World War he was a member of the National Defence Research Committee.[br]Bibliography1965, "The development of ductile tungsten", Sorby Centennial Symposium on the History of Metallurgy, AIME Metallurgy Society Conference, Vol. 27, ed. Cyril Stanley Smith, Gordon and Breach, pp. 443–9.Further ReadingD.J.Jones and A.Prince, 1985, "Tungsten and high density alloys", Journal of the Historical Metallurgy Society 19(1):72–84.ASDBiographical history of technology > Coolidge, William David
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18 Lucas, Anthony Francis
SUBJECT AREA: Mining and extraction technology[br]b. 9 September 1855 Spalato, Dalmatia, Austria-Hungary (now Split, Croatia)d. 2 September 1921 Washington, DC, USA[br]Austrian (naturalized American) mining engineer who successfully applied rotary drilling to oil extraction.[br]A former Second Lieutenant of the Austrian navy (hence his later nickname "Captain") and graduate of the Polytechnic Institute of Graz, Lucas decided to stay in Michigan when he visited his relatives in 1879. He changed his original name, Lucie, into the form his uncle had adopted and became a naturalized American citizen at the age of 30. He worked in the lumber industry for some years and then became a consulting mechanical and mining engineer in Washington, DC. He began working for a salt-mining company in Louisiana in 1893 and became interested in the geology of the Mexican Gulf region, with a view to prospecting for petroleum. In the course of this work he came to the conclusion that the hills in this elevated area, being geological structures distinct from the surrounding deposits, were natural reservoirs of petroleum. To prove his unusual theory he subsequently chose Spindle Top, near Beaumont, Texas, where in 1899 he began to bore a first oil-well. A second drill-hole, started in October 1900, was put through clay and quicksand. After many difficulties, a layer of rock containing marine shells was reached. When the "gusher" came out on 10 January 1901, it not only opened up a new era in the oil and gas business, but it also led to the future exploration of the terrestrial crust.Lucas's boring was a breakthrough for the rotary drilling system, which was still in its early days although its principles had been established by the English engineer Robert Beart in his patent of 1884. It proved to have advantages over the pile-driving of pipes. A pipe with a simple cutter at the lower end was driven with a constantly revolving motion, grinding down on the bottom of the well, thus gouging and chipping its way downward. To deal with the quicksand he adopted the use of large and heavy casings successively telescoped one into the other. According to Fauvelle's method, water was forced through the pipe by means of a pump, so the well was kept full of circulating liquid during drilling, flushing up the mud. When the salt-rock was reached, a diamond drill was used to test the depth and the character of the deposit.When the well blew out and flowed freely he developed a preventer in order to save the oil and, even more importantly at the time, to shut the well and to control the oil flow. This assembly, patented in 1903, consisted of a combined system of pipes, valves and casings diverting the stream into a horizontal direction.Lucas's fame spread around the world, but as he had to relinquish the larger part of his interest to the oil company supporting the exploration, his financial reward was poor. One year after his success at Spindle Top he started oil exploration in Mexico, where he stayed until 1905, when he resumed his consulting practice in Washington, DC.[br]Bibliography1899, "Rock-salt in Louisiana", Transactions of the American Institution of Mining Engineers 29:462–74.1902, "The great oil-well near Beaumont, Texas", Transactions of the AmericanInstitution of Mining Engineers 31:362–74.Further ReadingR.S.McBeth, 1918, Pioneering the Gulf Coast, New York (a very detailed description of Lucas's important accomplishments in the development of the oil industry).R.T.Hill, 1903, "The Beaumont oil-field, with notes on other oil-fields of the Texas region", Transactions of the American Institution of Mining Engineers 33:363–405;Transactions of the American Institution of Mining Engineers 55:421–3 (contain shorter biographical notes).WK -
19 Ransome, Robert
SUBJECT AREA: Agricultural and food technology[br]b. 1753 Wells, Norfolk, Englandd. 1830 England[br]English inventor of a self-sharpening ploughshare and all-metal ploughs with interchangeable pans.[br]The son of a Quaker schoolmaster, Ransome served his apprenticeship with a Norfolk iron manufacturer and then went into business on his own in the same town, setting up one of the first brass and iron foundries in East Anglia. At an early stage of his career he was selling into Norfolk and Suffolk, well beyond the boundaries to be expected from a local craftsman. He achieved this through the use of forty-seven agents acting on his behalf. In 1789, with one employee and £200 capital, he transferred to Ipswich, where the company was to remain and where there was easier access to both raw materials and his markets. It was there that he discovered that cooling one part of a metal share during its casting could result in a self-sharpening share, and he patented the process in 1785.Ransome won a number of awards at the early Bath and West shows, a fact which demonstrates the extent of his markets. In 1808 he patented an all-metal plough made up of interchangeable parts, and the following year was making complete ploughs for sale. With interchangeable parts he was able to make composite ploughs suitable for a wide variety of conditions and therefore with potential markets all over the country.In 1815 he was joined by his son James, and at about the same time by William Cubitt. With the expertise of the latter the firm moved into bridge building and millwrighting, and was therefore able to withstand the agricultural depression which began to affect other manufacturers from about 1815. In 1818, under Cubitt's direction, Ransome built the gas-supply system for the town of Ipswich. In 1830 his grandson James Ransome joined the firm, and it was under his influence that the agricultural side was developed. There was a great expansion in the business after 1835.[br]Further ReadingJ.E.Ransome, 1865, Ploughs and Ploughing at the Royal Agricultural College at Cirencester in 1865, in which he outlined the accepted theories of the day.J.B.Passmore, 1930, The English Plough, Reading: University of Reading (provides a history of plough development from the eighth century to the in ter-war period).Ransome's Royal Records 1789–1939, produced by the company; D.R.Grace and D.C.Phillips, 1975, Ransomes of Ipswich, Reading: Institute of Agricultural History, Reading University (both provide information about Ransome in a more general account about the company and its products; Reading University holds the company archives).AP -
20 Roberts, Richard
[br]b. 22 April 1789 Carreghova, Llanymynech, Montgomeryshire, Walesd. 11 March 1864 London, England[br]Welsh mechanical engineer and inventor.[br]Richard Roberts was the son of a shoemaker and tollkeeper and received only an elementary education at the village school. At the age of 10 his interest in mechanics was stimulated when he was allowed by the Curate, the Revd Griffith Howell, to use his lathe and other tools. As a young man Roberts acquired a considerable local reputation for his mechanical skills, but these were exercised only in his spare time. For many years he worked in the local limestone quarries, until at the age of 20 he obtained employment as a pattern-maker in Staffordshire. In the next few years he worked as a mechanic in Liverpool, Manchester and Salford before moving in 1814 to London, where he obtained employment with Henry Maudslay. In 1816 he set up on his own account in Manchester. He soon established a reputation there for gear-cutting and other general engineering work, especially for the textile industry, and by 1821 he was employing about twelve men. He built machine tools mainly for his own use, including, in 1817, one of the first planing machines.One of his first inventions was a gas meter, but his first patent was obtained in 1822 for improvements in looms. His most important contribution to textile technology was his invention of the self-acting spinning mule, patented in 1825. The normal fourteen-year term of this patent was extended in 1839 by a further seven years. Between 1826 and 1828 Roberts paid several visits to Alsace, France, arranging cottonspinning machinery for a new factory at Mulhouse. By 1826 he had become a partner in the firm of Sharp Brothers, the company then becoming Sharp, Roberts \& Co. The firm continued to build textile machinery, and in the 1830s it built locomotive engines for the newly created railways and made one experimental steam-carriage for use on roads. The partnership was dissolved in 1843, the Sharps establishing a new works to continue locomotive building while Roberts retained the existing factory, known as the Globe Works, where he soon after took as partners R.G.Dobinson and Benjamin Fothergill (1802–79). This partnership was dissolved c. 1851, and Roberts continued in business on his own for a few years before moving to London as a consulting engineer.During the 1840s and 1850s Roberts produced many new inventions in a variety of fields, including machine tools, clocks and watches, textile machinery, pumps and ships. One of these was a machine controlled by a punched-card system similar to the Jacquard loom for punching rivet holes in plates. This was used in the construction of the Conway and Menai Straits tubular bridges. Roberts was granted twenty-six patents, many of which, before the Patent Law Amendment Act of 1852, covered more than one invention; there were still other inventions he did not patent. He made his contribution to the discussion which led up to the 1852 Act by publishing, in 1830 and 1833, pamphlets suggesting reform of the Patent Law.In the early 1820s Roberts helped to establish the Manchester Mechanics' Institute, and in 1823 he was elected a member of the Literary and Philosophical Society of Manchester. He frequently contributed to their proceedings and in 1861 he was made an Honorary Member. He was elected a Member of the Institution of Civil Engineers in 1838. From 1838 to 1843 he served as a councillor of the then-new Municipal Borough of Manchester. In his final years, without the assistance of business partners, Roberts suffered financial difficulties, and at the time of his death a fund for his aid was being raised.[br]Principal Honours and DistinctionsMember, Institution of Civil Engineers 1838.Further ReadingThere is no full-length biography of Richard Roberts but the best account is H.W.Dickinson, 1945–7, "Richard Roberts, his life and inventions", Transactions of the Newcomen Society 25:123–37.W.H.Chaloner, 1968–9, "New light on Richard Roberts, textile engineer (1789–1864)", Transactions of the Newcomen Society 41:27–44.RTS
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