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1 specialized machinery
Деловая лексика: спецтехника -
2 спецтехника
1) General subject: custom machinery (AD), custom vehicles (о транспортных средствах - АД)2) Automobile industry: special vehicles3) Transport: specialty vehicles4) Business: special machines, special-purpose machines, specialized machinery -
3 Clark, Edward
SUBJECT AREA: Domestic appliances and interiors[br]fl. 1850s New York State, USA[br]American co-developer of mass-production techniques at the Singer sewing machine factory.[br]Born in upstate New York, where his father was a small manufacturer, Edward Clark attended college at Williams and graduated in 1831. He became a lawyer in New York City and from then on lived either in the city or on his rural estate near Cooperstown in upstate New York. After a series of share manipulations, Clark acquired a one-third interest in Isaac M. Singer's company. They soon bought out one of Singer's earlier partners, G.B.Zeiber, and in 1851, under the name of I.M.Singer \& Co., they set up a permanent sewing machine business with headquarters in New York.The success of their firm initially rested on marketing. Clark introduced door-to-door sales-people and hire-purchase for their sewing machines in 1856 ($50 cash down, or $100 with a cash payment of $5 and $3 a month thereafter). He also trained women to demonstrate to potential customers the capabilities of the Singer sewing machine. At first their sewing machines continued to be made in the traditional way, with the parts fitted together by skilled workers through hand filing and shaping so that the parts would fit only onto one machine. This resembled European practice rather than the American system of manufacture that had been pioneered in the armouries in that country. In 1856 Singer brought out their first machine intended exclusively for home use, and at the same time manufacturing capacity was improved. Through increased sales, a new factory was built in 1858–9 on Mott Street, New York, but it soon became inadequate to meet demand.In 1863 the Singer company was incorporated as the Singer Manufacturing Co. and began to modernize its production methods with special jigs and fixtures to help ensure uniformity. More and more specialized machinery was built for making the parts. By 1880 the factory, then at Elizabethport, New Jersey, was jammed with automatic and semi-automatic machine tools. In 1882 the factory was producing sewing machines with fully interchangeable parts that did not require hand fitting in assembly. Production rose from 810 machines in 1853 to half a million in 1880. A new family model was introduced in 1881. Clark had succeeded Singer, who died in 1875, as President of the company, but he retired in 1882 after he had seen through the change to mass production.[br]Further ReadingNational Cyclopaedia of American Biography.D.A.Hounshell, 1984, From the American System to Mass Production, 1800–1932. The Development of Manufacturing Technology in the United States, Baltimore (a thorough account of Clark's role in the development of Singer's factories).F.B.Jewell, 1975, Veteran Sewing Machines. A Collector's Guide, Newton Abbot.RLH -
4 Ellington, Edward Bayzard
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 2 August 1845 London, Englandd. 10 November 1914 London, England[br]English hydraulic engineer who developed a direct-acting hydraulic lift.[br]Ellington was educated at Denmark Hill Grammar School, London, after which he became articled to John Penn of Greenwich. He stayed there until 1868, working latterly in the drawing office after a period of erecting plant and attending trials on board ship. For some twelve months he superintended the erection of Glengall Wharf, Old Kent Road, and the machinery used therein.In 1869 he went into partnership with Bryan Johnson of Chester, the company being known as Johnson \& Ellington, manufacturing mining and milling machinery. Under Ellington's influence, the firm specialized in the manufacture of hydraulic machinery. In 1874 the company acquired the right to manufacture the Brotherhood three-cylinder hydraulic engine; the company became the Hydraulic Engineering Company Ltd of Chester. Ellington developed a direct-acting hydraulic lift with a special balance arrangement that was smooth-acting and economical in water. He described the lift in a paper that was read to the Institution of Mechanical Engineers (IMechE) in 1882.Soon after Ellington joined the Chester firm, an Act of Parliament was passed, mainly due to his efforts, for the distribution of water under high pressure for the working of passenger and goods lifts and other hydraulic machinery in large towns. In 1872 he initiated the first hydraulic mains company at Hull, thus proving the practicability of the system of a high-pressure water-mains supply. Ellington remained as engineer to the Hull company until he was appointed a director in 1875. He was general manager and engineer of the General Hydraulic Power Company, which operated in London and had subsidiaries in Liverpool (opened in 1889), Manchester (1894) and Glasgow (1895). He maintained an interest in all these companies, as general manager and engineer, until his death.In 1895 he read another paper, "On hydraulic power in towns", to the Institution of Mechanical Engineers. In 1911 he became President of the IMechE; his Presidential Address was on the education of young engineers. In 1913 he delivered the Thomas Hawksley Lecture on "Water as a mechanical agent". He was Chairman of the Building Committee during the extension of the Institution's headquarters. Ellington was also a Member of Council of the Institution of Civil Engineers, a member of the Société des Ingé-nieurs Civils de France and a Governor of Imperial College of Science and Technology.[br]Principal Honours and DistinctionsMember of the Institution of Mechanical Engineers 1875; Member of Council 1898– 1903; President 1911–12.IMcNBiographical history of technology > Ellington, Edward Bayzard
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5 Herbert, Edward Geisler
[br]b. 23 March 1869 Dedham, near Colchester, Essex, Englandd. 9 February 1938 West Didsbury, Manchester, England[br]English engineer, inventor of the Rapidor saw and the Pendulum Hardness Tester, and pioneer of cutting tool research.[br]Edward Geisler Herbert was educated at Nottingham High School in 1876–87, and at University College, London, in 1887–90, graduating with a BSc in Physics in 1889 and remaining for a further year to take an engineering course. He began his career as a premium apprentice at the Nottingham works of Messrs James Hill \& Co, manufacturers of lace machinery. In 1892 he became a partner with Charles Richardson in the firm of Richardson \& Herbert, electrical engineers in Manchester, and when this partnership was dissolved in 1895 he carried on the business in his own name and began to produce machine tools. He remained as Managing Director of this firm, reconstituted in 1902 as a limited liability company styled Edward G.Herbert Ltd, until his retirement in 1928. He was joined by Charles Fletcher (1868–1930), who as joint Managing Director contributed greatly to the commercial success of the firm, which specialized in the manufacture of small machine tools and testing machinery.Around 1900 Herbert had discovered that hacksaw machines cut very much quicker when only a few teeth are in operation, and in 1902 he patented a machine which utilized this concept by automatically changing the angle of incidence of the blade as cutting proceeded. These saws were commercially successful, but by 1912, when his original patents were approaching expiry, Herbert and Fletcher began to develop improved methods of applying the rapid-saw concept. From this work the well-known Rapidor and Manchester saws emerged soon after the First World War. A file-testing machine invented by Herbert before the war made an autographic record of the life and performance of the file and brought him into close contact with the file and tool steel manufacturers of Sheffield. A tool-steel testing machine, working like a lathe, was introduced when high-speed steel had just come into general use, and Herbert became a prominent member of the Cutting Tools Research Committee of the Institution of Mechanical Engineers in 1919, carrying out many investigations for that body and compiling four of its Reports published between 1927 and 1933. He was the first to conceive the idea of the "tool-work" thermocouple which allowed cutting tool temperatures to be accurately measured. For this advance he was awarded the Thomas Hawksley Gold Medal of the Institution in 1926.His best-known invention was the Pendulum Hardness Tester, introduced in 1923. This used a spherical indentor, which was rolled over, rather than being pushed into, the surface being examined, by a small, heavy, inverted pendulum. The period of oscillation of this pendulum provided a sensitive measurement of the specimen's hardness. Following this work Herbert introduced his "Cloudburst" surface hardening process, in which hardened steel engineering components were bombarded by steel balls moving at random in all directions at very high velocities like gaseous molecules. This treatment superhardened the surface of the components, improved their resistance to abrasion, and revealed any surface defects. After bombardment the hardness of the superficially hardened layers increased slowly and spontaneously by a room-temperature ageing process. After his retirement in 1928 Herbert devoted himself to a detailed study of the influence of intense magnetic fields on the hardening of steels.Herbert was a member of several learned societies, including the Manchester Association of Engineers, the Institute of Metals, the American Society of Mechanical Engineers and the Institution of Mechanical Engineers. He retained a seat on the Board of his company from his retirement until the end of his life.[br]Principal Honours and DistinctionsManchester Association of Engineers Butterworth Gold Medal 1923. Institution of Mechanical Engineers Thomas Hawksley Gold Medal 1926.BibliographyE.G.Herbert obtained several British and American patents and was the author of many papers, which are listed in T.M.Herbert (ed.), 1939, "The inventions of Edward Geisler Herbert: an autobiographical note", Proceedings of the Institution of Mechanical Engineers 141: 59–67.ASD / RTSBiographical history of technology > Herbert, Edward Geisler
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6 Wilkinson, David
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 5 January 1771 Smithfield (now Slatersville), Rhode Island, USAd. 3 February 1852 Caledonia Springs, Ontario, Canada[br]American mechanical engineer and inventor of a screw-cutting lathe.[br]David Wilkinson was the third son of Oziel Wilkinson (1744–1815), a blacksmith who c.1783 established at Pawtucket, Rhode Island, a plant for making farm tools and domestic utensils. This enterprise he steadily expanded with the aid of his sons, until by 1800 it was regarded as the leading iron and machinery manufacturing business in New England. At the age of 13, David Wilkinson entered his father's workshops. Their products included iron screws, and the problem of cutting the threads was one that engaged his attention. After working on it for some years he devised a screw-cutting lathe, for which he obtained a patent in 1798. In about 1800 David and his brother Daniel established their own factory at Pawtucket, known as David Wilkinson \& Co., where they specialized in the manufacture of textile machinery. Later they began to make cast cannon and installed a special boring machine for machining them. The firm prospered until 1829, when a financial crisis caused its collapse. David Wilkinson set up a new business in Cohoes, New York, but this was not a success and from 1836 he travelled around finding work chiefly in canal and bridge construction in New Jersey, Ohio and Canada. In 1848 he petitioned Congress for some reward for his invention of the screw-cutting lathe of 1798; he was awarded $10,000.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (provides a short account of David Wilkinson and his work).R.S.Woodbury, 1961, History of the Lathe to 1850, Cleveland, Ohio (includes a description of Wilkinson's screw-cutting lathe).RTS -
7 специализированное оборудование
1) Engineering: special-purpose equipment, specialist equipment2) Construction: specialized equipment3) Automation: dedicated equipment, special-purpose hardware, special-purpose machinery4) Makarov: specialty equipmentУниверсальный русско-английский словарь > специализированное оборудование
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8 system
1) система; способ; метод2) устройство; строй3) классификация4) учение5) сеть (дорог) -
9 specialize
A vi se spécialiser ; to specialize in se spécialiser en [subject, field] ; to specialize in maintenance/construction se spécialiser dans l'entretien/la construction ; we specialize in repairing computers/training staff notre spécialité consiste à réparer les ordinateurs/former le personnel ; a company specializing in machinery/chemicals une entreprise spécialisée dans les machines/les produits chimiques. -
10 Bullard, Edward Payson
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 18 April 1841 Uxbridge, Massachusetts, USAd. 22 December 1906 Bridgeport, Connecticut, USA[br]American mechanical engineer and machine-tool manufacturer who designed machines for boring.[br]Edward Payson Bullard served his apprenticeship at the Whitin Machine Works, Whitinsville, Massachusetts, and worked at the Colt Armory in Hartford, Connecticut, until 1863; he then entered the employ of Pratt \& Whitney, also in Hartford. He later formed a partnership with J.H.Prest and William Parsons manufacturing millwork and tools, the firm being known as Bullard \& Prest. In 1866 Bullard organized the Norwalk Iron Works Company of Norwalk, Connecticut, but afterwards withdrew and continued the business in Hartford. In 1868 the firm of Bullard \& Prest was dissolved and Bullard became Superintendent of a large machine shop in Athens, Georgia. He later organized the machine tool department of Post \& Co. at Cincinnati, and in 1872 he was made General Superintendent of the Gill Car Works at Columbus, Ohio. In 1875 he established a machinery business in Beekman Street, New York, under the name of Allis, Bullard \& Co. Mr Allis withdrew in 1877, and the Bullard Machine Company was organized.In 1880 Bullard secured entire control of the business and also became owner of the Bridgeport Machine Tool Works, Bridgeport, Connecticut. In 1883 he designed his first vertical boring and turning mill with a single head and belt feed and a 37 in. (94 cm) capacity; this was the first small boring machine designed to do the accurate work previously done on the face plate of a lathe. In 1889 Bullard gave up his New York interests and concentrated his entire attention on manufacturing at Bridgeport, the business being incorporated in 1894 as the Bullard Machine Tool Company. The company specialized in the construction of boring machines, the design being developed so that it became essentially a vertical turret lathe. After Bullard's death, his son Edward Payson Bullard II (b. 10 July 1872 Columbus, Ohio, USA; d. 26 June 1953 Fairfield, Connecticut, USA) continued as head of the company and further developed the boring machine into a vertical multi-spindle automatic lathe which he called the "Mult-au-matic" lathe. Both father and son were members of the American Society of Mechanical Engineers.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven: Yale University Press; repub. 1926, New York and 1987, Bradley, Ill.: Lindsay Publications Inc. (describes Bullard's machines).RTS -
11 Lobnitz, Frederick
SUBJECT AREA: Ports and shipping[br]b. 7 September 1863 Renfrew, Scotlandd. 7 December 1932 Crookston, Renfrewshire, Scotland[br]Scottish shipbuilder, expert in dredge technology.[br]Lobnitz was the son of Henry Christian Lobnitz. His father was born in Denmark in 1831, and had worked for some years in both England and Scotland before becoming a naturalized British subject. Ultimately Henry joined the Clyde shipyard of James Henderson \& Son and worked there until his death, by which time he was sole proprietor and the yard was called Lobnitz \& Co. By this time the shipyard was the acknowledged world leader in rock-cutting machinery.Frederick was given the opportunity to travel in Europe during the late 1870s and early 1880s. He studied at Bonn, Heidelberg and at the Zurich Polytechnic, and also served an apprenticeship at the Fairfield Shipyard of John Elder \& Co. of Glasgow. One of his first tasks was to supervise the construction and commissioning of a subaqueous rock excavator, and then he was asked to direct rock excavations at the Suez Canal.In 1888 Frederick Lobnitz was made a partner of the company by his father and was to remain with them until his death, at which time he was Chairman. By this time the shipyard was a private limited company and had continued to enhance its name in the specialized field of dredging. At that time the two greatest dredge builders in the world (and deadly rivals) were situated next to each other on the banks of the Clyde at Renfrew; in 1957 they merged as Simons-Lobnitz Ltd. In 1915 Lobnitz was appointed Deputy Director for Munitions in Scotland and one year later he became Director, a post he held until 1919. Having investigated the running of munitions factories in France, he released scarce labour for the war effort by staffing the plants under his control with female and unskilled labour.[br]Principal Honours and DistinctionsKnighted 1920. Officier de la Légion d'honneur.Further ReadingFred M.Walker, 1984, Song of the Clyde. A History of Clyde Shipbuilding Cambridge: PSL.Lobnitz \& Co., n.d., Romance of Dredging.FMW -
12 Rittinger, Peter von
SUBJECT AREA: Mining and extraction technology[br]b. 23 January 1811 Neutitschein, Moravia (now Now Jicin, Czech Republic)d. 7 December 1872 Vienna, Austria[br]Austrian mining engineer, improver of the processing of minerals.[br]After studying law, philosophy and politics at the University of Olmutz (now Olomouc), in 1835 Rittinger became a fellow of the Mining Academy in Schemnitz (now Banská Štiavnica), Slovakia. In 1839, the year he finished at the academy, he published a book on perspective drawing. The following year, he became Inspector of Mills at the ore mines in Schemnitz, and in 1845 he was engaged in coal mining in Bohemia and Moravia. In 1849 he joined the mining administration at Joachimsthal (now Jáchymov), Bohemia. In these early years he contributed his first important innovations for the mining industry and thus fostered his career in the government's service. In 1850 he was called to Vienna to become a high-ranked officer in various ministries. He was responsible for the construction of buildings, pumping installations and all sorts of machinery in the mining industry; he reorganized the curricula of the mining schools, was responsible for the mint and became head of the department of mines, forests and salt-works in the Austrian empire.During all his years of public service, Rittinger continued his concern with technological innovations. He improved the processing of ores by introducing in 1844 the rotary washer and the box classifier, and later his continuously shaking concussion table which, having been exhibited at the Vienna World Fair of 1873, was soon adopted in other countries. He constructed water-column pumps, invented a differential shaft pump with hydraulic linkage to replace the heavy iron rods and worked on centrifugal pumps. He was one of the first to be concerned with the transfer of heat, and he developed a system of using exhaust steam for heating in salt-works. He kept his eye on current developments abroad, using his function as official Austrian commissioner to the world exhibitions, on which he published frequently as well as on other matters related to technology. With his systematic handbook on mineral processing, first published in 1867, he emphasized his international reputation in this specialized field of mining.[br]Principal Honours and DistinctionsKnighted 1863. Order of the Iron Crown 1863. Honorary Citizen of Joachimsthal 1864. President, Austrian Chamber of Engineers and Architects 1863–5.Bibliography1849, Der Spitzkasten-Apparat statt Mehlrinnen und Sümpfen…bei der nassen Aufbereitung, Freiberg.1854, Theoretisch-praktische Anleitung zur Rader-Verzahnung, Vienna.1855, Theoretisch-praktische Abhandlung über ein für alle Gattungen von Flüssigkeiten anwendbares neues Abdampfverfahren, Vienna.1861, Theorie und Bau der Rohrturbinen, Prague.1867, Lehrbuch der Aufbereitungskunde, Berlin (with supplements, 1870–73).Further ReadingH.Kunnert, 1972, "Peter Ritter von Rittinger. Lebensbild eines grossen Montanisten", Der Anschnitt 24:3–7 (a detailed description of his life, based on source material).J.Steiner, 1972, "Der Beitrag von Peter Rittinger zur Entwicklung der Aufbereitungstechnik". Berg-und hüttenmännische Monatshefte 117: 471–6 (an evaluation of Rittinger's achievements for the processing of ores).WK
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