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1 масса по химической шкале
1) General subject: mass on the chemical scale2) Engineering: chemical mass, chemical scale mass, mass on chemical scaleУниверсальный русско-английский словарь > масса по химической шкале
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2 управляющ конкурсной массой
Бизнес, юриспруденция. Русско-английский словарь > управляющ конкурсной массой
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3 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 -
4 Klic, Karol (Klietsch, Karl)
[br]b. 31 May 1841 Arnau, Bohemia (now Czech Republic)d. 16 November 1826 Vienna, Austria[br]Czech inventor of photogravure and rotogravure.[br]Klic, sometimes known by the germanized form of his name Karl Klietsch, gained a knowledge of chemistry from his chemist father. However, he inclined towards the arts, preferring to mix paints rather than chemicals, and he trained in art at the Academy of Painting in Prague. His father thought to combine the chemical with the artistic by setting up his son in a photographic studio in Brno, but the arts won and in 1867 Klic moved to Vienna to practise as an illustrator and caricaturist. He also acquired skill as an etcher, and this led him to print works of art reproduced by photography by means of an intaglio process. He perfected the process c.1878 and, through it, Vienna became for a while the world centre for high-quality art reproductions. The prints were made by hand from flat plates, but Klic then proposed that the images should be etched onto power-driven cylinders. He found little support for rotary gravure, or rotogravure, on the European continent, but learning that Storey Brothers, textile printers of Lancaster, England, were working in a similar direction, he went there in 1890 to perfect his idea. Rotogravure printing on textiles began in 1893. They then turned to printing art reproductions on paper by rotogravure and in 1895 formed the Rembrandt Intaglio Printing Company. Their photogra-vures attracted worldwide attention when they appeared in the Magazine of Art. Klic saw photogravure as a small-scale medium for the art lover and not for mass-circulation publications, so he did not patent his invention and thought to control it by secrecy. That had the usual result, however, and knowledge of the process leaked out from Storey's, spreading to other countries in Europe and, from 1903, to the USA. Klic lived on in a modest way in Vienna, his later years troubled by failing sight. He hardly earned the credit for the invention, let alone the fortune reaped by others who used, and still use, photogravure for printing long runs of copy such as newspaper colour supplements.[br]Further ReadingObituary, 1927, Inland Printer (January): 614.Karol Klic. vynálezu hlubotisku, 1957, Prague (the only full-length biography; in Czech, with an introduction in English, French and German).S.H.Horgan, 1925, "The invention of photogravure", Inland Printer (April): 64 (contains brief details of his life and works).G.Wakeman, 1973, Victorian Book Illustration, Newton Abbot: David \& Charles, pp. 126–8.LRDBiographical history of technology > Klic, Karol (Klietsch, Karl)
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5 серийное производство
1) General subject: batch production, manufacturing, mass production, produce on the line, repetition work, manufacturing production, production chain, serial production2) Military: batch series line production, large-scale production (напр. оружия)3) Engineering: full production, full-scale production, lot production, quantity production, routine fabrication, serial publication, series fabrication4) Construction: line production, series manufacture5) Railway term: commercialize, production in lot6) Economy: duplicate production, production in lot sizes, production manufacturing, repetitive manufacturing, serial operation, serial work, series manufacturing7) Accounting: production in lots8) Information technology: serial manufacture9) Food industry: batch process10) Mechanics: batch repetition work, batch work, batch-oriented production11) Advertising: batch series production12) Business: batch manufacturing, large output, large quantity manufacture, large-scale manufacture, large-scale manufacturing, large-scale production, mass manufacturing, production run, series production13) Production: volume production14) Industrial economy: serial manufacturing (англ. термин взят из United States Patent No. 5229948)15) Automation: batch( - lot) manufacturing, batch mode, batch processing, batch production work, batchwork, discrete batch manufacturing, mixed operation, mixed production16) Quality control: building in series18) Chemical weapons: batch production/serial production19) Makarov: batch production (партиями), full-scale production (в противовес экспериментальному или опытному), quantity production (в противовес экспериментальному или опытному), series production (партиями)Универсальный русско-английский словарь > серийное производство
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6 производство
fabrication, generation, manufacture, making, manufacturing, production, trade* * *произво́дство с.1. productionсвё́ртывать произво́дство ( обычно постепенно) — phase out [phase back] productionсня́тый с произво́дства — out of production2. ( добыча) production3. ( изготовление) manufacture; ( из полуфабрикатов) fabricationпроизво́дство по за́мкнутому ци́клу — captive manufacture4. ( отрасль) industryпроизво́дство без вы́хода на ры́нок — captive productionбонда́рное произво́дство — cooperageбума́жное произво́дство — papermakingпроизво́дство в о́пытных масшта́бах — pilot productionпроизво́дство в промы́шленных масшта́бах — production in quantity, commercial productionвспомога́тельное произво́дство1. auxiliary process(es)2. ( подразделение завода) auxiliary departmentпроизво́дство га́за — (особ. природного) gas production; (особ. искусственного) gas generationдо́менное произво́дство — blast-furnace processедини́чное произво́дство — individual [single-unit, piece-work] productionкни́жное произво́дство — book productionпроизво́дство ко́жи — leather manufactureкоксохими́ческое произво́дство — cake and by-product processконве́ртерное произво́дство — converter process(es)крупносери́йное произво́дство — large-lot [large-scale] productionкузне́чно-пре́ссовое произво́дство — press forgingкузне́чно-штампо́вочное произво́дство — press forging; ( объёмная штамповка) die forgingлесохими́ческое произво́дство — wood chemical industryлистопрока́тное произво́дство — ( толстого листа) plate rolling; ( тонкого листа) sheet rollingлите́йное произво́дство — foundryмарте́новское произво́дство — open-hearth processма́ссовое произво́дство — mass productionмелкосери́йное произво́дство — small-lot [small-scale] productionмоде́льное произво́дство — pattern-makingнепреры́вное произво́дство — continuous processпроизво́дство о́буви — shoe makingо́пытное произво́дство — pilot(-scale) productionполузаводско́е произво́дство хим. — pilot-scale processпото́чное произво́дство — flow(-line) [in-line] productionпрока́тное произво́дство — rollingсва́рочное произво́дство — welding fabrication; ( раздел техники) welding engineeringсери́йное произво́дство — ( в противовес экспериментальному или опытному) quantity [full-scale] production; ( партиями) batch [series] productionпроизво́дство ста́ли — steelmakingтексти́льное произво́дство — textile manufactureпроизво́дство тепла́ — heat generation, heat productionтруболите́йное произво́дство — pipe castingтрубопрока́тное произво́дство — pipe rollingтрубосва́рочное произво́дство — pipe weldingфабри́чное произво́дство — manufacturing, manufactureпроизво́дство фо́сфорной кислоты́ экстракцио́нным спо́собом — production of phosphoric acid by the wet processхлопчатобума́жное произво́дство — cotton manufactureпроизво́дство чугуна́ — iron makingшве́йное произво́дство — clothing [garment] manufactureшо́рно-седе́льное произво́дство — saddleryшту́чное произво́дство — individual productionпроизво́дство электри́ческой эне́ргии — generation of electrical energy, electricity production -
7 Weston, Edward
SUBJECT AREA: Electricity[br]b. 9 May 1850 Oswestry, Englandd. 20 August 1936 Montclair, New Jersey, USA[br]English (naturalized American) inventor noted for his contribution to the technology of electrical measurements.[br]Although he developed dynamos for electroplating and lighting, Weston's major contribution to technology was his invention of a moving-coil voltmeter and the standard cell which bears his name. After some years as a medical student, during which he gained a knowledge of chemistry, he abandoned his studies. Emigrating to New York in 1870, he was employed by a manufacturer of photographic chemicals. There followed a period with an electroplating company during which he built his first dynamo. In 1877 some business associates financed a company to build these machines and, later, arc-lighting equipment. By 1882 the Weston Company had been absorbed into the United States Electric Lighting Company, which had a counterpart in Britain, the Maxim Weston Company. By the time Weston resigned from the company, in 1886, he had been granted 186 patents. He then began the work in which he made his greatest contribution, the science of electrical measurement.The Weston meter, the first successful portable measuring instrument with a pivoted coil, was made in 1886. By careful arrangement of the magnet, coil and control springs, he achieved a design with a well-damped movement, which retained its calibration. These instruments were produced commercially on a large scale and the moving-coil principle was soon adopted by many manufacturers. In 1892 he invented manganin, an alloy with a small negative temperature coefficient, for use as resistances in his voltmeters.The Weston standard cell was invented in 1892. Using his chemical knowledge he produced a cell, based on mercury and cadmium, which replaced the Clark cell as a voltage reference source. The Weston cell became the recognized standard at the International Conference on Electrical Units and Standards held in London in 1908.[br]Principal Honours and DistinctionsPresident, AIEE 1888–9. Franklin Institute Elliott Cresson Medal 1910, Franklin medal 1924.Bibliography29 April 1890, British patent no. 6,569 (the Weston moving-coil instrument). 6 February 1892, British patent no. 22,482 (the Weston standard cell).Further ReadingD.O.Woodbury, 1949, A Measure of Greatness. A Short Biography of Edward Weston, New York (a detailed account).C.N.Brown, 1988, in Proceedings of the Meeting on the History of Electrical Engineering, IEE, 17–21 (describes Weston's meter).H.C.Passer, 1953, The Electrical Manufacturers: 1875–1900, Cambridge, Mass.GW -
8 вспомогательное производство
1. auxiliary process2. auxiliary departmentпроизводство газа — gas production; gas generation
кузнечно-штамповочное производство — press forging; die forging
листопрокатное производство — plate rolling; sheet rolling
сварочное производство — welding fabrication; welding engineering
серийное производство — quantity production; batch production
Русско-английский большой базовый словарь > вспомогательное производство
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