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1 жаропрочная сталь
1) Naval: heat-resisting steel2) Engineering: creep-resisting steel, heat-resistant steel, high-temperature steel, oxidation-resisting steel, refractory steel3) Metallurgy: heat-resistant4) Makarov: heat steel -
2 жаростойкая сталь
1) Engineering: oxidation-resisting steel, refractory steel, rust-resisting steel2) Automobile industry: heat-resistant steel3) Metallurgy: heat-resistant4) Oil: high-temperature steel5) Makarov: heat steel6) Combustion gas turbines: heat-resisting steel -
3 окалиностойкая сталь
Универсальный русско-английский словарь > окалиностойкая сталь
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4 жаростойкая сталь
oxidation-resisting steel, heat-resistant steel, high-temperature steel, refractory steel, scale-resistant steel* * *Русско-английский политехнический словарь > жаростойкая сталь
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5 жаропрочная сталь
creep-resisting steel, heat-resistant steel, high-temperature steel, refractory steel* * *Русско-английский политехнический словарь > жаропрочная сталь
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6 жаропрочная сталь
heat-resistant steel, high-temperature steel, refractory steel -
7 жаростойкая сталь
heat-resistant steel, high-temperature steel, refractory steel -
8 hitzebeständiger Stahl
m1. heat-resistant steel2. heat-resisting steel3. refractory steel -
9 жаростойкая сталь
oxidation-resisting steel, refractory steelРусско-английский исловарь по машиностроению и автоматизации производства > жаростойкая сталь
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10 жаропрочный сплав
жаропрочный сплав
1. Жароупорный сплав.
2. Сплав, имеющий чрезвычайно высокую точку плавления.
3. Сплав, труднообрабатываемый при высоких температурах.
[ http://www.manual-steel.ru/eng-a.html]Тематики
EN
Русско-английский словарь нормативно-технической терминологии > жаропрочный сплав
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11 стальной пояс
Refractory materials: steel zone -
12 кислотный огнеупор
кислотный огнеупор
Кремнесодержащие керамические материалы с высокой температурой плавления типа кирпича на основе кремнезема, используемые в металлургическом производстве.
[ http://www.manual-steel.ru/eng-a.html]Тематики
EN
Русско-английский словарь нормативно-технической терминологии > кислотный огнеупор
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13 огнеупор для сталеплавильного производства
Silicates: steel-works refractoryУниверсальный русско-английский словарь > огнеупор для сталеплавильного производства
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14 бетон
* * *бето́н м.
concreteарми́ровать бето́н — reinforce concreteвакууми́ровать бето́н — compact [consolidate] concrete by vacuumвиброуплотня́ть бето́н — compact [consolidate] concrete by vibrationвспе́нивать бето́н — foam the concreteвспу́чивать бето́н — bloat (the) concreteбето́н выделя́ет во́ду — the concrete bleedsвыде́рживать бето́н — cure the concreteзагла́живать бето́н — ( с помощью гладилки) float the concrete; ( с помощью тёрки) trowel the concreteобжима́ть бето́н ( при предварительном напряжении) — transfer the stress from the reinforcing steel to the concrete, apply a compressive prestress to the concreteобраба́тывать бето́н в автокла́ве — autoclave (the) concreteотде́лывать бето́н буча́рдой — bush-hammer the concrete (surface)подава́ть бето́н к ме́сту укла́дки — convey concrete to the job [to the point of placement]пригота́вливать бето́н на стройплоща́дке — mix the concrete on the jobпроекти́ровать бето́н — proportion [design] a concrete mix(ture)проекти́ровать соста́в бето́на см. проектировать бетонпропа́ривать бето́н — steam-cure (the) concreteпропа́ривать бето́н в автокла́ве — autoclave (the) concreteразра́внивать бето́н — screed [rub] the concrete (with a flying screed)распределя́ть бето́н (напр. в опалубке) — spread (the) concreteбето́н рассла́ивается — the concrete mix segregatesснима́ть [среза́ть] изли́шки бето́на — strike off excess concreteснима́ть фо́рму с бето́на — demould the concreteсопряга́ть ра́нее уло́женный бето́н с но́вым — bond fresh [new] concrete to hardened [set] concreteбето́н схватывает(ся) — the concrete setsбето́н тверде́ет — the concrete hardensукла́дывать бето́н — place concreteукла́дывать бето́н в опа́лубку — place concrete against formsуплотня́ть бето́н — compact [consolidate] concrete; ( до заполнения всего пространства внутри опалубки) ram concrete in placeуплотня́ть бето́н вакууми́рованием — compact [consolidate] concrete by vacuumуплотня́ть бето́н вручну́ю — consolidate the concrete by hand (tamping)уплотня́ть бето́н центрифуги́рованием — consolidate concrete by spinning [centrifuging]ута́птывать бето́н — boot (the) concreteарми́рованный бето́н — reinforced concreteатмосферосто́йкий бето́н — weather-resistant concreteаэродро́мный бето́н — airfield-grade concreteбето́н без воздухововлека́ющих доба́вок — nonair-entraining concreteбезоса́дочный бето́н — no-slump concreteбеспесча́ный бето́н — no-sand concreteбыстротверде́ющий бето́н — fast hardening [early strength] concreteводонепроница́емый бето́н — watertight concreteгидротехни́ческий бето́н — hydraulic concreteграви́йный бето́н — gravel concreteдоро́жный бето́н — road [pavement] concreteжаросто́йкий бето́н — heat-resistant concreteжароупо́рный бето́н — high-temperature concreteжё́сткий бето́н — dry [harsh] concreteжи́рный бето́н — rich concreteземляно́й бето́н — earth concreteизвестняко́вый бето́н — limestone concreteкислотоупо́рный бето́н — acid-resisting concreteкрупнозерни́стый бето́н — coarse (aggregate) concreteлё́гкий бето́н — light-weight concreteлито́й бето́н — mushy concrete, concrete of slush consistencyмелкозерни́стый бето́н — fine (aggregate) concreteмолодо́й бето́н — green concreteмоноли́тный бето́н — monolithic [(cast-)in-situ, poured-in-place] concreteбето́н на гра́вии — gravel aggregate concreteбето́н на грани́тном ще́бне — granite concreteнадво́дный бето́н — above-water concreteбето́н на кли́нкере — clinker concreteбето́н на коте́льном шла́ке — slag [breeze] concreteбето́н на неоргани́ческих вя́жущих — inorganic-bonding agent concreteбето́н на органи́ческих вя́жущих — organic-bonding agent concreteбето́н на песча́но-грави́йной сме́си — sand-and-gravel concreteбето́н на портландцеме́нте — Portland-cement concreteбето́н на ще́бне — crushed-stone concreteнеарми́рованный бето́н — plain [mass] concreteогнеупо́рный бето́н — refractory concreteопи́лочный бето́н — sawdust concreteосо́бо лё́гкий бето́н — very light concreteосо́бо тяжё́лый бето́н — extra heavy [heavy weight] concreteотде́лочный бето́н — finishing concreteпесча́ный бето́н — fine (aggregate) concreteпло́тный бето́н — dense concreteподво́дный бето́н — underwater concreteподзе́мный бето́н — underground concreteпредвари́тельно напряжё́нный бето́н — prestressed concreteра́ковистый бето́н — honeycombing concreteбето́н с акти́вным заполни́телем — reactive-aggregate concreteбето́н с больши́м содержа́нием цеме́нта — rich concreteсбо́рный бето́н — precast [prefabricated] concreteбето́н с воздухововлека́ющими доба́вками — air-entraining concreteбето́н с волокни́стым заполни́телем — fibrous concreteбето́н с доба́вкой льда — ice concreteбето́н с за́данными сво́йствами — controlled-quality concreteбето́н с заполни́телем из твё́рдой поро́ды — hard rock concreteсилика́тный бето́н — lime concreteбето́н с кру́пным заполни́телем — coarse (aggregate) concreteбето́н с лё́гким заполни́телем — light-weight-aggregate concreteслои́стый бето́н — sandwich concreteбето́н с ма́лым содержа́нием цеме́нта — lean concreteбето́н с обнажё́нным заполни́телем — exposed aggregate concreteстрои́тельный бето́н — structural concreteтеплоизоляцио́нный бето́н — insulating concreteтермоизоляцио́нный бето́н — insulating concreteтова́рный бето́н — ready-mixed concreteто́щий бето́н — lean concreteтяжё́лый бето́н — heavy-weight concreteбето́н, уплотнё́нный центрифуги́рованием — spun [centrifuged] concreteхоло́дный бето́н — cold-weather concreteцеме́нтный бето́н — cement concreteциклопи́ческий бето́н — cyclopean concreteщебё́ночный бето́н — stone concreteяче́истый бето́н — cellular concrete* * * -
15 железобетон
reinforced concrete, ferroconcrete устар.* * *железобето́н м.
брит. ferroconcrete, reinforced concrete; амер. reinforced concreteзакла́дывать что-л. в железобето́н — embed smth. in reinforced concreteпропа́ривать железобето́н — cure reinforced concrete by steamуплотня́ть железобето́н — compact reinforced concreteформова́ть железобето́н — form reinforced concreteжаросто́йкий железобето́н — refractory reinforced concreteлё́гкий железобето́н — light-weight reinforced concreteжелезобето́н на лё́гких заполни́телях — light-weight aggregate reinforced concreteпредвари́тельно напряжё́нный железобето́н — prestressed reinforced concreteсбо́рный железобето́н — prefabricated [precast] reinforced concreteжелезобето́н с перекрё́стной армату́рой — two-way reinforced concreteтяжё́лый железобето́н — heavy reinforced concreteяче́истый железобето́н — wire-mesh reinforced concrete* * * -
16 titani
[Swahili Word] titani[English Word] titanium[Part of Speech] noun[Class] 9[Dialect] recent[English Definition] a silvery gray light strong metallic element found combined in ilmenite and rutile and used especially in alloys (as steel) and combined in refractory materials and in coatings (identified circa 1796)[Terminology] chemistry------------------------------------------------------------ -
17 бетон
м. concreteзаглаживать бетон — float the concrete; trowel the concrete
уплотнять бетон — compact concrete; ram concrete in place
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18 фасонный
прил. shaped -
19 Le Chatelier, Henri Louis
SUBJECT AREA: Metallurgy[br]b. 8 November 1850 Paris, Franced. 17 September 1926 Miribel-les-Echelle, France[br]French inventor of the rhodium—platinum thermocouple and the first practical optical pyrometer, and pioneer of physical metallurgy.[br]The son of a distinguished engineer, Le Chatelier entered the Ecole Polytechnique in 1869: after graduating in the Faculty of Mines, he was appointed Professor at the Ecole Supérieure des Mines in 1877. After assisting Deville with the purification of bauxite in unsuccessful attempts to obtain aluminium in useful quantities, Le Chatelier's work covered a wide range of topics and he gave much attention to the driving forces of chemical reactions. Between 1879 and 1882 he studied the mechanisms of explosions in mines, and his doctorate in 1882 was concerned with the chemistry and properties of hydraulic cements. The dehydration of such materials was studied by thermal analysis and dilatometry. Accurate temperature measurement was crucial and his work on the stability of thermocouples, begun in 1886, soon established the superiority of rhodium-platinum alloys for high-temperature measurement. The most stable combination, pure platinum coupled with a 10 per cent rhodium platinum positive limb, became known as Le Chatelier couple and was in general use throughout the industrial world until c. 1922. For applications where thermocouples could not be used, Le Chatelier also developed the first practical optical pyrometer. From hydraulic cements he moved on to refractory and other ceramic materials which were also studied by thermal analysis and dilatometry. By 1888 he was systematically applying such techniques to metals and alloys. Le Chatelier, together with Osmond, Worth, Genet and Charpy, was a leading member of that group of French investigators who established the new science of physical metallurgy between 1888 and 1900. Le Chatelier was determining the recalescence points in steels in 1888 and was among the first to study intermetallic compounds in a systematic manner. To facilitate such work he introduced the inverted microscope, upon which metallographers still depend for the routine examination of polished and etched metallurgical specimens under incident light. The principle of mobile equilibrium, developed independently by Le Chatelier in 1885 and F.Braun in 1886, stated that if one parameter in an equilibrium situation changed, the equilibrium point of the system would move in a direction which tended to reduce the effect of this change. This provided a useful qualitative working tool for the experimentalists, and was soon used with great effect by Haber in his work on the synthesis of ammonia.[br]Principal Honours and DistinctionsGrand Officier de la Légion d'honneur. Honorary Member of the Institute of Metals 1912. Iron and Steel Institute Bessemer Medal.Further ReadingF.Le Chatelier, 1969, Henri Le Chatelier.C.K.Burgess and H.L.Le Chatelier, The Measurement of High Temperature.ASDBiographical history of technology > Le Chatelier, Henri Louis
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20 Rosenhain, Walter
SUBJECT AREA: Metallurgy[br]b. 24 August 1875 Berlin, Germanyd. 17 March 1934 Kingston Hill, Surrey, England[br]German metallurgist, first Superintendent of the Department of Metallurgy and Metallurgical Chemistry at the National Physical Laboratory, Teddington, Middlesex.[br]His family emigrated to Australia when he was 5 years old. He was educated at Wesley College, Melbourne, and attended Queen's College, University of Melbourne, graduating in physics and engineering in 1897. As an 1851 Exhibitioner he then spent three years at St John's College, Cambridge, under Sir Alfred Ewing, where he studied the microstructure of deformed metal crystals and abandoned his original intention of becoming a civil engineer. Rosenhain was the first to observe the slip-bands in metal crystals, and in the Bakerian Lecture delivered jointly by Ewing and Rosenhain to the Royal Society in 1899 it was shown that metals deformed plastically by a mechanism involving shear slip along individual crystal planes. From this conception modern ideas on the plasticity and recrystallization of metals rapidly developed. On leaving Cambridge, Rosenhain joined the Birmingham firm of Chance Brothers, where he worked for six years on optical glass and lighthouse-lens systems. A book, Glass Manufacture, written in 1908, derives from this period, during which he continued his metallurgical researches in the evenings in his home laboratory and published several papers on his work.In 1906 Rosenhain was appointed Head of the Metallurgical Department of the National Physical Laboratory (NPL), and in 1908 he became the first Superintendent of the new Department of Metallurgy and Metallurgical Chemistry. Many of the techniques he introduced at Teddington were described in his Introduction to Physical Metallurgy, published in 1914. At the outbreak of the First World War, Rosenhain was asked to undertake work in his department on the manufacture of optical glass. This soon made it possible to manufacture optical glass of high quality on an industrial scale in Britain. Much valuable work on refractory materials stemmed from this venture. Rosenhain's early years at the NPL were, however, inseparably linked with his work on light alloys, which between 1912 and the end of the war involved virtually all of the metallurgical staff of the laboratory. The most important end product was the well-known "Y" Alloy (4% copper, 2% nickel and 1.5% magnesium) extensively used for the pistons and cylinder heads of aircraft engines. It was the prototype of the RR series of alloys jointly developed by Rolls Royce and High Duty Alloys. An improved zinc-based die-casting alloy devised by Rosenhain was also used during the war on a large scale for the production of shell fuses.After the First World War, much attention was devoted to beryllium, which because of its strength, lightness, and stiffness would, it was hoped, become the airframe material of the future. It remained, however, too brittle for practical use. Other investigations dealt with impurities in copper, gases in aluminium alloys, dental alloys, and the constitution of alloys. During this period, Rosenhain's laboratory became internationally known as a centre of excellence for the determination of accurate equilibrium diagrams.[br]Principal Honours and DistinctionsFRS 1913. President, Institute of Metals 1828–30. Iron and Steel Institute Bessemer Medal, Carnegie Medal.Bibliography1908, Glass Manufacture.1914, An Introduction to the Study of Physical Metallurgy, London: Constable. Rosenhain published over 100 research papers.Further ReadingJ.L.Haughton, 1934, "The work of Walter Rosenhain", Journal of the Institute of Metals 55(2):17–32.ASD
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