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1 nickel-based alloy
English-Russian dictionary of mechanical engineering and automation > nickel-based alloy
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2 nickel-based alloy
Автоматика: сплав на никелевой основе -
3 nickel-based alloy
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4 nickel-base alloy
= nickel-based alloy сплав на никелевой основеEnglish-Russian dictionary of mechanical engineering and automation > nickel-base alloy
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5 alloy
1) сплав || сплавлять2) легирующий элемент || легировать•- abrasion-resisting alloy
- acid-resistant alloy
- addition alloy
- age-hardening alloy
- aging alloy
- air-hardening alloy
- air-melted alloy
- alkali metal alloy
- alkaline earth alloy
- alkaline earth metal-aluminum alloy
- alkali-resistant alloy
- alkali-resisting alloy
- all-alpha alloy
- all-beta alloy
- alpha alloy
- alpha iron alloy
- alpha+beta alloy
- alpha-beta alloy
- alpha-phase alloy
- alpha-titanium alloy
- aluminum alloy of iron
- aluminum alloy
- aluminum casting alloy
- aluminum piston alloy
- aluminum-base alloy
- aluminum-bearing alloy
- aluminum-copper alloy
- aluminum-copper-magnesium alloy
- aluminum-copper-magnesium-nickel alloy
- aluminum-copper-silicon alloy
- aluminum-copper-silicon-magnesium alloy
- aluminum-magnesium alloy
- aluminum-magnesium-silicon alloy
- aluminum-manganese alloy
- aluminum-manganese-magnesium alloy
- aluminum-nickel-iron alloy
- aluminum-silicon alloy
- aluminum-zinc-silicon alloy
- anticorrosion alloy
- antifriction alloy
- as-cast alloy
- austenitic alloy
- barium-aluminum alloy
- bearing alloy
- beryllium alloy of iron
- beryllium-copper alloy
- beryllium-copper-aluminum alloy
- beta alloy
- beta-phase alloy
- beta-titanium alloy
- binary alloy
- bismuth alloy
- body-centered cubic alloy
- boron-bearing alloy
- brass brazing alloy
- brazing alloy
- cadmium alloy
- cadmium-nickel alloy
- cadmium-silver alloy
- carbide-strengthened alloy
- carbon-bearing alloy
- carbon-free alloy
- cast alloy
- castable alloy
- casting alloy
- chrome alloy
- chrome-base alloy
- chrome-bearing alloy
- chrome-nickel alloy
- chromium-nickel-tungsten alloy
- chromium-rich alloy
- chromium-tantalum alloy
- chromium-titanium alloy
- chromium-tungsten-zirconium alloy
- chromium-yttrium alloy
- close-packed alloy
- cobalt alloy
- cobalt-base alloy
- cobalt-bearing alloy
- cobalt-chromium alloy
- cobalt-chromium-nickel alloy
- cobalt-chromium-tungsten-molybdenum alloy
- coinage alloy
- columbium alloy
- columbium-base alloy
- columbium-molybdenum-titanium alloy
- column's alloys
- commercial alloy
- complex alloy
- constant-modulus alloy
- constructional alloy
- controlled-expansion alloy
- copper alloy
- copper-base alloy
- copper-bearing alloy
- copper-free alloy
- copper-gold alloy
- copper-lead alloy
- copper-silver alloy
- copper-tin alloy
- copper-zinc alloy
- corrosion-resistant alloy
- corrosion-resisting alloy
- creep-resistant alloy
- cupronickel alloy
- die-casting alloy
- difficult-to-extrude alloy
- dilute alloy
- disordered alloy
- dispersion-hardened alloy
- dispersion-strengthened alloy
- ductile alloy
- duplex alloy
- electrically conductive alloy
- electrically superconducting alloy
- electrical-resistance alloy
- electrical-resistant alloy
- embrittlement-resistant alloy
- eutectic alloy
- eutectoid alloy
- extra-hard alloy
- extrahigh tensile alloy
- face-centered cubic alloy
- ferrite alloy
- ferromagnetic alloy
- ferrous alloy
- fine-grained alloy
- forging alloy
- foundry alloy
- four-component alloy
- four-part alloy
- free-cutting alloy
- free-machining alloy
- fusible alloy
- G.-P. zone alloy
- gamma-iron alloy
- gamma-phase alloy
- gold-base alloy
- graphitized alloy
- Guthrie's alloy
- hard alloy
- hard magnetic alloy
- hard superconducting alloy
- hard-facing alloy
- heat-resistant alloy
- heat-resisting alloy
- heat-sensitive alloy
- heat-treatable alloy
- heat-treated alloy
- heavy alloy
- heterogeneous alloy
- Heusler alloy
- hexagonal alloy
- high alloy
- high-carbon alloy
- high-chrome alloy
- high-cobalt alloy
- high-coercivity alloy
- high-damping alloy
- high-density alloy
- high-ductile alloy
- high-expansion alloy
- high-initial-permeability alloy
- high-melting alloy
- high-melting point alloy
- high-melting-temperature alloy
- high-nickel alloy
- high-permeability alloy
- high-resistance alloy
- high-strength alloy
- high-temperature alloy
- high-tensile alloy
- high-yield alloy
- homogeneous alloy
- homogenized alloy
- hot-strength alloy
- hypereutectic alloy
- hypereutectoid alloy
- hypoeutectic alloy
- hypoeutectoid alloy
- ignition alloy
- industrial alloy
- intermediate-strength alloy
- intermetallic alloy
- internally oxidized alloy
- iron alloy
- iron-aluminum-nickel alloy
- iron-bearing alloy
- iron-carbon alloy
- iron-chrome alloy
- iron-chromium-aluminum alloy
- iron-chromium-nickel alloy
- iron-cobalt alloy
- iron-cobalt-molybdenum alloy
- iron-cobalt-nickel alloy
- iron-cobalt-tungsten alloy
- iron-manganese alloy
- iron-nickel alloy
- iron-nickel-aluminum alloy
- iron-nickel-chromium alloy
- iron-nickel-cobalt alloy
- jet alloy
- lead alloy
- lead-antimony alloy
- lead-antimony-tin alloy
- lead-base alloy
- lead-bearing alloy
- lead-bismuth alloy
- lead-calcium alloy
- lead-tin alloy
- lean alloy
- Lichtenberg's alloy
- light alloy
- low alloy
- low-carbon alloy
- low-chrome alloy
- low-density alloy
- low-ductile alloy
- low-expansion alloy
- low-melting alloy
- low-nickel alloy
- low-permeability alloy
- low-quality alloy
- low-resistance alloy
- low-strength alloy
- low-temperature alloy
- low-tensile alloy
- low-yield alloy
- magnesium alloy
- magnesium-aluminum alloy
- magnesium-aluminum-zinc alloy
- magnesium-bearing alloy
- magnesium-manganese alloy
- magnesium-manganese-thorium alloy
- magnesium-thorium-zirconium alloy
- magnesium-zinc-zirconium alloy
- magnetic alloy
- magnetically hard alloy
- magnetically soft alloy
- master alloy
- medium alloy
- medium-carbon alloy
- medium-chrome alloy
- medium-nickel alloy
- medium-strength alloy
- memory alloy
- Mishima alloy
- molybdenum-titanium alloy
- multilayer brazing alloy
- multiphase alloy
- natural aging alloy
- nickel alloy
- nickel aluminide alloy
- nickel-base alloy
- nickel-based alloy
- nickel-cadmium alloy
- nickel-chrome-molybdenum alloy
- nickel-chromium alloy
- nickel-cobalt alloy
- nickel-copper alloy
- nickel-iron alloy
- nickel-molybdenum alloy
- nickel-molybdenum-iron alloy
- nickel-rich alloy
- nickel-silicon alloy
- noble metal alloy
- no-coolant alloy
- nonaging alloy
- noncorrosive alloy
- nonferrous metal alloy
- non-heat-treatable alloy
- nonmagnetic alloy
- nonordered alloy
- nonoxidizable alloy
- nonscaling alloy
- nonsparking alloy
- one-phase alloy
- ordered alloy
- oxidation-resistant alloy
- oxidation-resisting alloy
- palladium-silver alloy
- peritectic alloy
- peritectoid alloy
- permanent-magnet alloy
- phosphorous-copper alloy
- piston alloy
- plating alloy
- platinum alloy
- platinum-cobalt alloy
- platinum-metal alloy
- platinum-rhodium alloy
- plural-phase alloy
- polyphase alloy
- powder metallurgical alloy
- powder-brazing alloy
- precipitation hardening alloy
- preferred-orientation alloy
- preformed brazing alloy
- preliminary alloy
- process alloy
- pyrophoric alloy
- quasi-binary alloy
- quasi-eutectic alloy
- quasi-eutectoid alloy
- quaternary alloy
- quinary alloy
- random alloy
- random-orientation alloy
- rare-earth alloy
- rare-earth metal master alloy
- reduction alloy
- refractory alloy
- resistance alloy
- rich alloy
- Rose's alloy
- ruthenium-palladium alloy
- sand-cast alloy
- scale-resisting alloy
- self-fluxing brazing alloy
- semicommercial alloy
- semiconducting alloy
- shape memory alloy
- sheet alloy
- silicon alloy
- silicon-aluminum alloy
- silver brazing alloy
- single-phase alloy
- sintered alloy
- sintered hard alloy
- soft-magnetic alloy
- solder alloy
- solid solution alloy
- solution-treated alloy
- sparking alloy
- spelter-brazing alloy
- spring alloy
- stable alloy
- steam corrosion-resistant alloy
- steel alloy
- strain-hardened alloy
- structural alloy
- substitute alloy
- substitutional alloy
- superconducting alloy
- superconductive alloy
- superconductor alloy
- supercooled alloy
- superhard alloy
- superplastic alloy
- supersaturated alloy
- supersaturated substitutional alloy
- tailored alloy
- tantalum alloy of iron
- tantalum alloy
- tantalum-base alloy
- tantalum-tungsten alloy
- temperature compensation alloy
- ternary alloy
- thallium-lead alloy
- thermomagnetic alloy
- three-component alloy
- three-part alloy
- three-phase alloy
- tin-base alloy
- tin-bearing alloy
- titanium alloy
- titanium-aluminum-manganese alloy
- titanium-aluminum-molybdenum alloy
- titanium-aluminum-tin alloy
- titanium-aluminum-vanadium alloy
- titanium-base alloy
- tough alloy
- transition alloy
- tungsten alloy
- two-component alloy
- two-phase alloy
- type-metal alloy
- unsaturated alloy
- untarnishable alloy
- vacuum alloy
- vacuum annealed alloy
- vacuum-arc-refining alloy
- vacuum-induction-melting alloy
- vacuum-remelted alloy
- virgin alloy
- wear-resistant alloy
- wear-resisting alloy
- welding alloy
- Wood's alloy
- work-hardening alloy
- wrought alloy
- zinc alloy
- zinc-aluminum alloy
- zinc-base alloy
- zinc-bearing alloy
- zinc-copper alloy
- zirconium alloy of ironEnglish-Russian dictionary of mechanical engineering and automation > alloy
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6 alloy
сплав; припой; легирующий элемент; примесь; сплавлять; легироватьberyllium filamented reinforced alloy — сплав, армированный нитями бериллия
boron-fiber reinforced aluminum alloy — алюминиевый сплав, армированный борволокном
differentially solidified nickel-based alloy alloy — дифференциально закристаллизованный сплав на никелевой основе
high-melting point brazing alloy — тугоплавкий [жаропрочный] припой
stainless-steel-wire reinforced aluminum alloy — алюминиевый сплав, армированный проволокой из нержавеющей стали
steel-fiber reinforced aluminum alloy — сплав алюминия, армированный стальной нитью
tungsten reinforced oxidation resistant columbium alloy — стойкий к окислению ниобиевый сплав, армированный вольфрамом
— - chromium alloy -
7 alloy
1. сплавaged alloyAl-Li alloyaluminum-lithium alloyaluminum-magnesium alloybinary alloycast alloycryogenic alloydirectionally solidified alloyforged alloyhigh-damping alloylow-density alloynickel-based alloypowder alloyrapid-solidification alloyrapidly solidified alloyRSR alloyshape memory alloysingle-crystal alloysuperplastic alloyto build of riveted aluminum alloyuniform alloy -
8 сплав на никелевой основе
Универсальный русско-английский словарь > сплав на никелевой основе
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9 Chevenard, Pierre Antoine Jean Sylvestre
SUBJECT AREA: Metallurgy[br]b. 31 December 1888 Thizy, Rhône, Franced. 15 August 1960 Fontenoy-aux-Roses, France[br]French metallurgist, inventor of the alloys Elinvar and Platinite and of the method of strengthening nickel-chromium alloys by a precipitate ofNi3Al which provided the basis of all later super-alloy development.[br]Soon after graduating from the Ecole des Mines at St-Etienne in 1910, Chevenard joined the Société de Commentry Fourchambault et Decazeville at their steelworks at Imphy, where he remained for the whole of his career. Imphy had for some years specialized in the production of nickel steels. From this venture emerged the first austenitic nickel-chromium steel, containing 6 per cent chromium and 22–4 per cent nickel and produced commercially in 1895. Most of the alloys required by Guillaume in his search for the low-expansion alloy Invar were made at Imphy. At the Imphy Research Laboratory, established in 1911, Chevenard conducted research into the development of specialized nickel-based alloys. His first success followed from an observation that some of the ferro-nickels were free from the low-temperature brittleness exhibited by conventional steels. To satisfy the technical requirements of Georges Claude, the French cryogenic pioneer, Chevenard was then able in 1912 to develop an alloy containing 55–60 per cent nickel, 1–3 per cent manganese and 0.2–0.4 per cent carbon. This was ductile down to −190°C, at which temperature carbon steel was very brittle.By 1916 Elinvar, a nickel-iron-chromium alloy with an elastic modulus that did not vary appreciably with changes in ambient temperature, had been identified. This found extensive use in horology and instrument manufacture, and even for the production of high-quality tuning forks. Another very popular alloy was Platinite, which had the same coefficient of thermal expansion as platinum and soda glass. It was used in considerable quantities by incandescent-lamp manufacturers for lead-in wires. Other materials developed by Chevenard at this stage to satisfy the requirements of the electrical industry included resistance alloys, base-metal thermocouple combinations, magnetically soft high-permeability alloys, and nickel-aluminium permanent magnet steels of very high coercivity which greatly improved the power and reliability of car magnetos. Thermostatic bimetals of all varieties soon became an important branch of manufacture at Imphy.During the remainder of his career at Imphy, Chevenard brilliantly elaborated the work on nickel-chromium-tungsten alloys to make stronger pressure vessels for the Haber and other chemical processes. Another famous alloy that he developed, ATV, contained 35 per cent nickel and 11 per cent chromium and was free from the problem of stress-induced cracking in steam that had hitherto inhibited the development of high-power steam turbines. Between 1912 and 1917, Chevenard recognized the harmful effects of traces of carbon on this type of alloy, and in the immediate postwar years he found efficient methods of scavenging the residual carbon by controlled additions of reactive metals. This led to the development of a range of stabilized austenitic stainless steels which were free from the problems of intercrystalline corrosion and weld decay that then caused so much difficulty to the manufacturers of chemical plant.Chevenard soon concluded that only the nickel-chromium system could provide a satisfactory basis for the subsequent development of high-temperature alloys. The first published reference to the strengthening of such materials by additions of aluminium and/or titanium occurs in his UK patent of 1929. This strengthening approach was adopted in the later wartime development in Britain of the Nimonic series of alloys, all of which depended for their high-temperature strength upon the precipitated compound Ni3Al.In 1936 he was studying the effect of what is now known as "thermal fatigue", which contributes to the eventual failure of both gas and steam turbines. He then published details of equipment for assessing the susceptibility of nickel-chromium alloys to this type of breakdown by a process of repeated quenching. Around this time he began to make systematic use of the thermo-gravimetrie balance for high-temperature oxidation studies.[br]Principal Honours and DistinctionsPresident, Société de Physique. Commandeur de la Légion d'honneur.Bibliography1929, Analyse dilatométrique des matériaux, with a preface be C.E.Guillaume, Paris: Dunod (still regarded as the definitive work on this subject).The Dictionary of Scientific Biography lists around thirty of his more important publications between 1914 and 1943.Further Reading"Chevenard, a great French metallurgist", 1960, Acier Fins (Spec.) 36:92–100.L.Valluz, 1961, "Notice sur les travaux de Pierre Chevenard, 1888–1960", Paris: Institut de France, Académie des Sciences.ASDBiographical history of technology > Chevenard, Pierre Antoine Jean Sylvestre
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10 composite
композиционный материал, композит, смесь; см. тж. material; композиционный, составной, сложный3D composite — композиционный материал с трёхмерной ориентацией наполнителя [с трёхмерным армированием]
3-dimensional composite — композиционный материал с трёхмерной ориентацией наполнителя [с трёхмерным армированием]
aligned short fiber thermoset composite — композиционный термореактивный пластик, армированный упорядоченными короткими волокнами
aluminum particle filled epoxy composite — композиционный эпоксипласт, наполненный алюминиевыми частицами
bidirectional wire plastic composite — композиционный пластик с двунаправленным армированием проволокой
carbon fiber-reinforced resin composite — композиционный пластик, армированный углеволокном, углепластик
carbon filament-reinforced resin composite — композиционный пластик, армированный углеволокном, углепластик
carbon-base fabric reinforced composite — композиционный материал, армированный углеродной тканью; углетекстолит
discontinuous fiber (reinforced) composite — композиционный материал, армированный коротким волокном
explosive-bonded wire-reinforced sheet composite — листовой композиционный материал, армированный проволокой методом взрыва
fabric reinforced plastic composite — композиционный пластик, армированный тканью, текстолит
nonmetallic fibrous reinforced composite — композиционный материал, армированный неметаллическим волокном
particle filled epoxy composite — композиционный эпоксипласт, наполненный частицами
plasma sprayed metal-matrix composite — композиционный материал с плазменно напылённой металлической матрицей
rectangular array fibrous composite — композиционный материал с прямоугольным расположением (упрочняющих) волокон
refractory fiber reinforced composite — композиционный материал, армированный тугоплавким волокном
short fiber reinforced composite — композиционный материал, армированный коротким волокном
staple fiber reinforced composite — композиционный материал, армированный штапельным волокном
steel reinforced epoxy composite — композиционный эпоксид, армированный сталью
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11 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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