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1 Design Engineering Practice
Универсальный русско-английский словарь > Design Engineering Practice
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2 design engineering practice
Универсальный русско-английский словарь > design engineering practice
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3 Shell Design Engineering Practice
Sakhalin R: DEPУниверсальный русско-английский словарь > Shell Design Engineering Practice
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4 Design and engineering practice
Sakhalin energy glossary: DEPУниверсальный русско-английский словарь > Design and engineering practice
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5 методика проектирования
1) Engineering: design technique2) Economy: design procedure3) Architecture: design practice4) Sakhalin energy glossary: Design Engineering Practice (Shell)5) Quality control: design policyУниверсальный русско-английский словарь > методика проектирования
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6 Практика выполнения работ по проектированию компании Шелл
Sakhalin R: Shell Design Engineering PracticeУниверсальный русско-английский словарь > Практика выполнения работ по проектированию компании Шелл
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7 практика выполнения инженерно-конструкторских работ
Sakhalin R: design engineering practiceУниверсальный русско-английский словарь > практика выполнения инженерно-конструкторских работ
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8 практика проектирования кожухов
Sakhalin energy glossary: shell design engineering practice (DEP)Универсальный русско-английский словарь > практика проектирования кожухов
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9 практика проектирования корпусов
Sakhalin energy glossary: shell design engineering practice (DEP)Универсальный русско-английский словарь > практика проектирования корпусов
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10 практика проектирования оболочек
Sakhalin energy glossary: shell design engineering practice (DEP)Универсальный русско-английский словарь > практика проектирования оболочек
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11 проектирование
- projection
- projecting
- project management
- project engineering
- planning
- laying-out
- laying
- engineering
- drafting
- development work
- development
- designing work
- designing procedure
- designing practice
- designing
- design work
- design study
- design procedure
- design practice
- design planning
- design engineering
- design
- construction
проектирование
Процесс разработки и выпуска проектной документации, необходимой для строительства объекта
[Терминологический словарь по строительству на 12 языках (ВНИИИС Госстроя СССР)]
проектирование
(ITIL Service Design)
Деятельность или процесс, который идентифицирует требования и далее определяет решение, способное удовлетворить этим требованиям.
См. тж. проектирование услуг.
[Словарь терминов ITIL версия 1.0, 29 июля 2011 г.]EN
design
(ITIL Service Design) An activity or process that identifies requirements and then defines a solution that is able to meet these requirements.
See also service design.
[Словарь терминов ITIL версия 1.0, 29 июля 2011 г.]Тематики
- проектирование, документация
EN
- construction
- design
- design engineering
- design planning
- design practice
- design procedure
- design study
- design work
- designing
- designing practice
- designing procedure
- designing work
- development
- development work
- drafting
- engineering
- laying
- laying-out
- planning
- project engineering
- project management
- projecting
- projection
DE
FR
3.21 проектирование (design): Все связанные виды инженерной деятельности, необходимые для разработки проекта трубопровода, включая как конструирование, так и подбор материалов и защиту от коррозии.
Источник: ГОСТ Р 54382-2011: Нефтяная и газовая промышленность. Подводные трубопроводные системы. Общие технические требования оригинал документа
Русско-английский словарь нормативно-технической терминологии > проектирование
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12 Hopkinson, John
[br]b. 27 July 1849 Manchester, Englandd. 27 August 1898 Petite Dent de Veisivi, Switzerland[br]English mathematician and electrical engineer who laid the foundations of electrical machine design.[br]After attending Owens College, Manchester, Hopkinson was admitted to Trinity College, Cambridge, in 1867 to read for the Mathematical Tripos. An appointment in 1872 with the lighthouse department of the Chance Optical Works in Birmingham directed his attention to electrical engineering. His most noteworthy contribution to lighthouse engineering was an optical system to produce flashing lights that distinguished between individual beacons. His extensive researches on the dielectric properties of glass were recognized when he was elected to a Fellowship of the Royal Society at the age of 29. Moving to London in 1877 he became established as a consulting engineer at a time when electricity supply was about to begin on a commercial scale. During the remainder of his life, Hopkinson's researches resulted in fundamental contributions to electrical engineering practice, dynamo design and alternating current machine theory. In making a critical study of the Edison dynamo he developed the principle of the magnetic circuit, a concept also arrived at by Gisbert Kapp around the same time. Hopkinson's improvement of the Edison dynamo by reducing the length of the field magnets almost doubled its output. In 1890, in addition to-his consulting practice, Hopkinson accepted a post as the first Professor of Electrical Engineering and Head of the Siemens laboratory recently established at King's College, London. Although he was not involved in lecturing, the position gave him the necessary facilities and staff and student assistance to continue his researches. Hopkinson was consulted on many proposals for electric traction and electricity supply, including schemes in London, Manchester, Liverpool and Leeds. He also advised Mather and Platt when they were acting as contractors for the locomotives and generating plant for the City and South London tube railway. As early as 1882 he considered that an ideal method of charging for the supply of electricity should be based on a two-part tariff, with a charge related to maximum demand together with a charge for energy supplied. Hopkinson was one the foremost expert witnesses of his day in patent actions and was himself the patentee of over forty inventions, of which the three-wire system of distribution and the series-parallel connection of traction motors were his most successful. Jointly with his brother Edward, John Hopkinson communicated the outcome of his investigations to the Royal Society in a paper entitled "Dynamo Electric Machinery" in 1886. In this he also described the later widely used "back to back" test for determining the characteristics of two identical machines. His interest in electrical machines led him to more fundamental research on magnetic materials, including the phenomenon of recalescence and the disappearance of magnetism at a well-defined temperature. For his work on the magnetic properties of iron, in 1890 he was awarded the Royal Society Royal Medal. He was a member of the Alpine Club and a pioneer of rock climbing in Britain; he died, together with three of his children, in a climbing accident.[br]Principal Honours and DistinctionsFRS 1878. Royal Society Royal Medal 1890. President, Institution of Electrical Engineers 1890 and 1896.Bibliography7 July 1881, British patent no. 2,989 (series-parallel control of traction motors). 27 July 1882, British patent no. 3,576 (three-wire distribution).1901, Original Papers by the Late J.Hopkinson, with a Memoir, ed. B.Hopkinson, 2 vols, Cambridge.Further ReadingJ.Greig, 1970, John Hopkinson Electrical Engineer, London: Science Museum and HMSO (an authoritative account).—1950, "John Hopkinson 1849–1898", Engineering 169:34–7, 62–4.GW -
13 практика проектирования
1) Atomic energy: engineering design2) Sakhalin energy glossary: design practice3) Programming: engineering practice (напр. программного обеспечения)Универсальный русско-английский словарь > практика проектирования
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14 технология проектирования
1) Architecture: design techniques2) Sakhalin energy glossary: (внутренняя) Design and engineering practice (фирмы Shell)Универсальный русско-английский словарь > технология проектирования
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15 (внутренняя) технология проектирования
Sakhalin energy glossary: Design and engineering practice (фирмы Shell)Универсальный русско-английский словарь > (внутренняя) технология проектирования
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16 Методика Проектирования, Строительства и поддержания действующих Объектов (на базе практики компании
Sakhalin energy glossary: Design and Engineering Practice (SGSI)Универсальный русско-английский словарь > Методика Проектирования, Строительства и поддержания действующих Объектов (на базе практики компании
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17 методика проектирования, строительства и поддержания действующих объектов
Sakhalin energy glossary: (на базе практики компании Design and Engineering Practice (SGSI)Универсальный русско-английский словарь > методика проектирования, строительства и поддержания действующих объектов
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18 Matteucci, Felice
SUBJECT AREA: Steam and internal combustion engines[br]b. 1803 Italyd. 1887 Italy[br]Italian engineer, co-inventor of internal-combustion engines.[br]A distinguished hydraulic engineer, Matteucci is more widely known for his work on early internal-combustion engines. In 1851, during a landreclamation project in Florence, he became acquainted with Eugenio Barsanti. Together they succeeded in designing and producing a number of the first type of gas engines to produce a vacuum within a closed cylinder, atmospheric pressure then being utilized to produce the power stroke. The principle was demonstrated by Cecil in 1820 and was used by Samuel Brown in 1827 and by N.A. Otto in 1867. The company Società Promotrice del Nuovo Motore Barsanti e Matteucci was formed in 1860, but ill health forced Matteucci to resign in 1862, and in 1864 Barsanti, whilst negotiating mass production of engines with Cockerill of Seraing, Belgium, contracted typhoid and later died. Efforts to continue the business in Italy subsequently failed and Matteucci returned to his engineering practice.[br]Bibliography13 May 1852, British Provisional Patent no. 1,072 (the Barsanti and Matteucci engine). 12 June 1857, British patent no. 1,655 (contained many notable improvements to the design).Further ReadingThe Engineer (1858) 5:73–4 (for an account of the Italian engine).Vincenzo Vannacci, 1955, L'invenzione del motore a scoppio realizzota dai toscani Barsanti e Matteucci 1854–1954, Florence.KAB -
19 расчёт регламента скорости
Engineering: speed practice designУниверсальный русско-английский словарь > расчёт регламента скорости
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20 Kapp, Gisbert Johann Eduard Karl
SUBJECT AREA: Electricity[br]b. 2 September 1852 Mauer, Vienna, Austriad. 10 August 1922 Birmingham, England[br]Austrian (naturalized British in 1881) engineer and a pioneer of dynamo design, being particularly associated with the concept of the magnetic circuit.[br]Kapp entered the Polytechnic School in Zurich in 1869 and gained a mechanical engineering diploma. He became a member of the engineering staff at the Vienna International Exhibition of 1873, and then spent some time in the Austrian navy before entering the service of Gwynne \& Co. of London, where he designed centrifugal pumps and gas exhausters. Kapp resolved to become an electrical engineer after a visit to the Paris Electrical Exhibition of 1881 and in the following year was appointed Manager of the Crompton Co. works at Chelmsford. There he developed and patented the dynamo with compound field winding. Also at that time, with Crompton, he patented electrical measuring instruments with over-saturated electromagnets. He became a naturalized British subject in 1881.In 1886 Kapp's most influential paper was published. This described his concept of the magnetic circuit, providing for the first time a sound theoretical basis for dynamo design. The theory was also developed independently by J. Hopkinson. After commencing practice as a consulting engineer in 1884 he carried out design work on dynamos and also electricity-supply and -traction schemes in Germany, Italy, Norway, Russia and Switzerland. From 1891 to 1894 much of his time was spent designing a new generating station in Bristol, officially as Assistant to W.H. Preece. There followed an appointment in Germany as General Secretary of the Verband Deutscher Electrotechniker. For some years he edited the Electrotechnische Zeitschrift and was also a part-time lecturer at the Charlottenberg Technical High School in Berlin. In 1904 Kapp was invited to accept the new Chair of Electrical Engineering at the University of Birmingham, which he occupied until 1919. He was the author of several books on electrical machine and transformer design.[br]Principal Honours and DistinctionsInstitution of Civil Engineers Telford Medal 1886 and 1888. President, Institution of Electrical Engineers 1909.Bibliography10 October 1882, with R.E.B.Crompton, British patent no. 4,810; (the compound wound dynamo).1886, "Modern continuous current dynamo electric machines and their engines", Proceedings of the Institution of Civil Engineers 83: 123–54.Further ReadingD.G.Tucker, 1989, "A new archive of Gisbert Kapp papers", Proceedings of the Meeting on History of Electrical Engineering, IEE 4/1–4/11 (a transcript of an autobiography for his family).D.G.Tucker, 1973, Gisbert Kapp 1852–1922, Birmingham: Birmingham University (includes a bibliography of his most important publications).GWBiographical history of technology > Kapp, Gisbert Johann Eduard Karl
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