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1 pig-and-ore process
Metallurgy: P.&O.Универсальный русско-английский словарь > pig-and-ore process
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2 0. pig-and-ore process
Metallurgy: P.&Универсальный русско-английский словарь > 0. pig-and-ore process
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3 рудный процесс
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4 proces rudowy
• pig-and-ore process -
5 proces surówkowy
• pig-and-ore process -
6 рудный процесс
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7 рудный процесс
pig-and-ore process метал.Русско-английский научно-технический словарь Масловского > рудный процесс
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8 Roheisen-Erz-Verfahren
n < metall> ■ pig iron-ore process; pig-and-ore process; ore processGerman-english technical dictionary > Roheisen-Erz-Verfahren
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9 процесс
operation, making, procedure, process* * *проце́сс м.
processоформля́ть проце́сс аппарату́рно — implement [instrument, mechanize] a processпроце́сс происхо́дит — a process occursпроце́сс протека́ет … — a process runs …реализова́ть проце́сс — implement a process; вчт., киб. instrument [mechanize] a processаддити́вный проце́сс — additive processадиабати́ческий проце́сс — adiabatic processаммиа́чно-со́довый проце́сс — Solvay processпроце́сс Ая́кс [Ая́кс-проце́сс] ( разновидность мартеновского процесса) — Ajax processбездо́менный проце́сс — direct ore-reduction processбессеме́ровский проце́сс — Bessemer processвагра́ночный проце́сс — cupola processвероя́тностный проце́сс — probabilistic processветвя́щийся проце́сс — branching processвосстанови́тельный проце́сс — reduction processпроце́сс выра́щивания криста́ллов, эпитаксиа́льный — epitaxial(-growth) processвычисли́тельный проце́сс — computational processпроце́сс гальванопокры́тия, щелочно́й — alkaline plating processдо́менный проце́сс — blast-furnace processидеа́льный проце́сс — ideal processизобари́ческий проце́сс — isobaric [constant-pressure] processизотерми́ческий проце́сс — isothermal [constant-temperature] processизохори́ческий проце́сс — isochoric [constant-volume] processизоэнтропи́ческий проце́сс — isentropic processитерацио́нный проце́сс вчт. — iterative processквазистациона́рный проце́сс — quasi-stationary processкинети́ческий проце́сс — rate processкислоро́дно-конве́ртерный проце́сс — basic oxygen [oxygen-converter] processконве́ртерный проце́сс — converter processконкури́рующие проце́ссы — competitive processesма́рковский проце́сс мат. — Markov(ian) processмарте́новский проце́сс — open-hearth processмарте́новский, ки́слый проце́сс — acid open-hearth processмарте́новский, основно́й проце́сс — basic open-hearth processмодели́руемый проце́сс — prototype processнеобрати́мый проце́сс — irreversible processнепреры́вный проце́сс — continuous processнеравнове́сный проце́сс — nonequilibrium processнестациона́рный проце́сс — non-steady processнеустанови́вшийся проце́сс — unsteady-state processобжига́тельно-восстанови́тельный проце́сс — roasting reduction processобрати́мый проце́сс — reversible processобра́тный проце́сс — inverse processокисли́тельно-восстанови́тельный проце́сс — redox processокисли́тельный проце́сс — oxidizing processпроце́сс ОЛП — OLP converter process (oxygen-lime-powder)оптима́льный проце́сс — optimal processпроце́сс перено́са — transport [transfer] processперехо́дный проце́сс — transient (process)по́сле оконча́ния перехо́дных проце́ссов … — after all transients have died out …периоди́ческий проце́сс — periodic processпроце́сс пла́вки с наво́дкой одного́ шла́ка — single-slag processпозити́вный проце́сс кфт. — positive processполитропи́ческий проце́сс — polytropic processпоследуби́льные проце́ссы — post tanningпроце́сс произво́дства — production processпроце́сс произво́дства ста́ли — steel-making processпроце́сс пряде́ния, непреры́вный — continuous spinning processравнове́сный проце́сс — equilibrium processрегули́руемый проце́сс — controlled processрегуля́рный проце́сс — regular processро́торный проце́сс ( в производстве стали) — rotor processру́дный проце́сс — pig-and-ore processпроце́сс сгора́ния — combustion (process)случа́йный проце́сс — random processстациона́рный проце́сс — stationary processстохасти́ческий проце́сс — stochastic processтехнологи́ческий проце́сс — хим. process; маш. manufacturing [production] methodвнедря́ть технологи́ческий проце́сс — bring in a new processтехнологи́ческий проце́сс ведё́тся [осуществля́ется] с центра́льного пу́льта — the process is run from a central control roomтехнологи́ческий, непреры́вный проце́сс — continuous processтехнологи́ческий, периоди́ческий проце́сс — batch processтипово́й проце́сс хим. — unit processтома́совский проце́сс — basic Bessemer processуправля́емый проце́сс — controlled processпроце́сс усредне́ния — averaging (process)установи́вшийся проце́сс — steady-state processциркуляцио́нный проце́сс хим. — a process with (a) recycleэкзотерми́ческий проце́сс — exothermic [exoergic] processзкзоэнергети́ческий проце́сс — exothermic [exoergic] processэндотерми́ческий проце́сс — endothermic [endoergic] processэргоди́ческий проце́сс мат. — ergodic process -
10 процесс
м. processпроцесс протекает … — a process runs …
после окончания переходных процессов … — after all transients have died out …
технологический процесс — process; manufacturing method
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11 скрап-рудный передел
1) Engineering: pig-and-ore process, scrap-ore process2) Metallurgy: scrap-ore processingУниверсальный русско-английский словарь > скрап-рудный передел
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12 скрап-рудный процесс
1) Engineering: pig-and-ore process, scrap-ore process2) Metallurgy: scrap-ore processingУниверсальный русско-английский словарь > скрап-рудный процесс
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13 рудный процесс
Engineering: ore process, pig-and-ore process -
14 Bessemer, Sir Henry
SUBJECT AREA: Metallurgy[br]b. 19 January 1813 Charlton (near Hitchin), Hertfordshire, Englandd. 15 January 1898 Denmark Hill, London, England[br]English inventor of the Bessemer steelmaking process.[br]The most valuable part of Bessemer's education took place in the workshop of his inventor father. At the age of only 17 he went to London to seek his fortune and set himself up in the trade of casting art works in white metal. He went on to the embossing of metals and other materials and this led to his first major invention, whereby a date was incorporated in the die for embossing seals, thus preventing the wholesale forgeries that had previously been committed. For this, a grateful Government promised Bessemer a paid position, a promise that was never kept; recognition came only in 1879 with a belated knighthood. Bessemer turned to other inventions, mainly in metalworking, including a process for making bronze powder and gold paint. After he had overcome technical problems, the process became highly profitable, earning him a considerable income during the forty years it was in use.The Crimean War presented inventors such as Bessemer with a challenge when weaknesses in the iron used to make the cannon became apparent. In 1856, at his Baxter House premises in St Paneras, London, he tried fusing cast iron with steel. Noticing the effect of an air current on the molten mixture, he constructed a reaction vessel or converter in which air was blown through molten cast iron. There was a vigorous reaction which nearly burned the house down, and Bessemer found the iron to be almost completely decarburized, without the slag threads always present in wrought iron. Bessemer had in fact invented not only a new process but a new material, mild steel. His paper "On the manufacture of malleable iron and steel without fuel" at the British Association meeting in Cheltenham later that year created a stir. Bessemer was courted by ironmasters to license the process. However, success was short-lived, for they found that phosphorus in the original iron ore passed into the metal and rendered it useless. By chance, Bessemer had used in his trials pig-iron, derived from haematite, a phosphorus-free ore. Bessemer tried hard to overcome the problem, but lacking chemical knowledge he resigned himself to limiting his process to this kind of pig-iron. This limitation was removed in 1879 by Sidney Gilchrist Thomas, who substituted a chemically basic lining in the converter in place of the acid lining used by Bessemer. This reacted with the phosphorus to form a substance that could be tapped off with the slag, leaving the steel free from this harmful element. Even so, the new material had begun to be applied in engineering, especially for railways. The open-hearth process developed by Siemens and the Martin brothers complemented rather than competed with Bessemer steel. The widespread use of the two processes had a revolutionary effect on mechanical and structural engineering and earned Bessemer around £1 million in royalties before the patents expired.[br]Principal Honours and DistinctionsKnighted 1879. FRS 1879. Royal Society of Arts Albert Gold Medal 1872.Bibliography1905, Sir Henry Bessemer FRS: An Autobiography, London.LRD -
15 Darby, Abraham
SUBJECT AREA: Metallurgy[br]b. 1678 near Dudley, Worcestershire, Englandd. 5 May 1717 Madely Court, Coalbrookdale, Shropshire, England[br]English ironmaster, inventor of the coke smelting of iron ore.[br]Darby's father, John, was a farmer who also worked a small forge to produce nails and other ironware needed on the farm. He was brought up in the Society of Friends, or Quakers, and this community remained important throughout his personal and working life. Darby was apprenticed to Jonathan Freeth, a malt-mill maker in Birmingham, and on completion of his apprenticeship in 1699 he took up the trade himself in Bristol. Probably in 1704, he visited Holland to study the casting of brass pots and returned to Bristol with some Dutch workers, setting up a brassworks at Baptist Mills in partnership with others. He tried substituting cast iron for brass in his castings, without success at first, but in 1707 he was granted a patent, "A new way of casting iron pots and other pot-bellied ware in sand without loam or clay". However, his business associates were unwilling to risk further funds in the experiments, so he withdrew his share of the capital and moved to Coalbrookdale in Shropshire. There, iron ore, coal, water-power and transport lay close at hand. He took a lease on an old furnace and began experimenting. The shortage and expense of charcoal, and his knowledge of the use of coke in malting, may well have led him to try using coke to smelt iron ore. The furnace was brought into blast in 1709 and records show that in the same year it was regularly producing iron, using coke instead of charcoal. The process seems to have been operating successfully by 1711 in the production of cast-iron pots and kettles, with some pig-iron destined for Bristol. Darby prospered at Coalbrookdale, employing coke smelting with consistent success, and he sought to extend his activities in the neighbourhood and in other parts of the country. However, ill health prevented him from pursuing these ventures with his previous energy. Coke smelting spread slowly in England and the continent of Europe, but without Darby's technological breakthrough the ever-increasing demand for iron for structures and machines during the Industrial Revolution simply could not have been met; it was thus an essential component of the technological progress that was to come.Darby's eldest son, Abraham II (1711–63), entered the Coalbrookdale Company partnership in 1734 and largely assumed control of the technical side of managing the furnaces and foundry. He made a number of improvements, notably the installation of a steam engine in 1742 to pump water to an upper level in order to achieve a steady source of water-power to operate the bellows supplying the blast furnaces. When he built the Ketley and Horsehay furnaces in 1755 and 1756, these too were provided with steam engines. Abraham II's son, Abraham III (1750–89), in turn, took over the management of the Coalbrookdale works in 1768 and devoted himself to improving and extending the business. His most notable achievement was the design and construction of the famous Iron Bridge over the river Severn, the world's first iron bridge. The bridge members were cast at Coalbrookdale and the structure was erected during 1779, with a span of 100 ft (30 m) and height above the river of 40 ft (12 m). The bridge still stands, and remains a tribute to the skill and judgement of Darby and his workers.[br]Further ReadingA.Raistrick, 1989, Dynasty of Iron Founders, 2nd edn, Ironbridge Gorge Museum Trust (the best source for the lives of the Darbys and the work of the company).H.R.Schubert, 1957, History of the British Iron and Steel Industry AD 430 to AD 1775, London: Routledge \& Kegan Paul.LRD -
16 Riley, James
SUBJECT AREA: Metallurgy[br]b. 1840 Halifax, Englandd. 15 July 1910 Harrogate, England[br]English steelmaker who promoted the manufacture of low-carbon bulk steel by the open-hearth process for tin plate and shipbuilding; pioneer of nickel steels.[br]After working as a millwright in Halifax, Riley found employment at the Ormesby Ironworks in Middlesbrough until, in 1869, he became manager of the Askam Ironworks in Cumberland. Three years later, in 1872, he was appointed Blast-furnace Manager at the pioneering Siemens Steel Company's works at Landore, near Swansea in South Wales. Using Spanish ore, he produced the manganese-rich iron (spiegeleisen) required as an additive to make satisfactory steel. Riley was promoted in 1874 to be General Manager at Landore, and he worked with William Siemens to develop the use of the latter's regenerative furnace for the production of open-hearth steel. He persuaded Welsh makers of tin plate to use sheets rolled from lowcarbon (mild) steel instead of from charcoal iron and, partly by publishing some test results, he was instrumental in influencing the Admiralty to build two naval vessels of mild steel, the Mercury and the Iris.In 1878 Riley moved north on his appointment as General Manager of the Steel Company of Scotland, a firm closely associated with Charles Tennant that was formed in 1872 to make steel by the Siemens process. Already by 1878, fourteen Siemens melting furnaces had been erected, and in that year 42,000 long tons of ingots were produced at the company's Hallside (Newton) Works, situated 8 km (5 miles) south-east of Glasgow. Under Riley's leadership, steelmaking in open-hearth furnaces was initiated at a second plant situated at Blochairn. Plates and sections for all aspects of shipbuilding, including boilers, formed the main products; the company also supplied the greater part of the steel for the Forth (Railway) Bridge. Riley was associated with technical modifications which improved the performance of steelmaking furnaces using Siemens's principles. He built a gasfired cupola for melting pig-iron, and constructed the first British "universal" plate mill using three-high rolls (Lauth mill).At the request of French interests, Riley investigated the properties of steels containing various proportions of nickel; the report that he read before the Iron and Steel Institute in 1889 successfully brought to the notice of potential users the greatly enhanced strength that nickel could impart and its ability to yield alloys possessing substantially lower corrodibility.The Steel Company of Scotland paid dividends in the years to 1890, but then came a lean period. In 1895, at the age of 54, Riley moved once more to another employer, becoming General Manager of the Glasgow Iron and Steel Company, which had just laid out a new steelmaking plant at Wishaw, 25 km (15 miles) south-east of Glasgow, where it already had blast furnaces. Still the technical innovator, in 1900 Riley presented an account of his experiences in introducing molten blast-furnace metal as feed for the open-hearth steel furnaces. In the early 1890s it was largely through Riley's efforts that a West of Scotland Board of Conciliation and Arbitration for the Manufactured Steel Trade came into being; he was its first Chairman and then its President.In 1899 James Riley resigned from his Scottish employment to move back to his native Yorkshire, where he became his own master by acquiring the small Richmond Ironworks situated at Stockton-on-Tees. Although Riley's 1900 account to the Iron and Steel Institute was the last of the many of which he was author, he continued to contribute to the discussion of papers written by others.[br]Principal Honours and DistinctionsPresident, West of Scotland Iron and Steel Institute 1893–5. Vice-President, Iron and Steel Institute, 1893–1910. Iron and Steel Institute (London) Bessemer Gold Medal 1887.Bibliography1876, "On steel for shipbuilding as supplied to the Royal Navy", Transactions of the Institute of Naval Architects 17:135–55.1884, "On recent improvements in the method of manufacture of open-hearth steel", Journal of the Iron and Steel Institute 2:43–52 plus plates 27–31.1887, "Some investigations as to the effects of different methods of treatment of mild steel in the manufacture of plates", Journal of the Iron and Steel Institute 1:121–30 (plus sheets II and III and plates XI and XII).27 February 1888, "Improvements in basichearth steel making furnaces", British patent no. 2,896.27 February 1888, "Improvements in regenerative furnaces for steel-making and analogous operations", British patent no. 2,899.1889, "Alloys of nickel and steel", Journal of the Iron and Steel Institute 1:45–55.Further ReadingA.Slaven, 1986, "James Riley", in Dictionary of Scottish Business Biography 1860–1960, Volume 1: The Staple Industries (ed. A.Slaven and S. Checkland), Aberdeen: Aberdeen University Press, 136–8."Men you know", The Bailie (Glasgow) 23 January 1884, series no. 588 (a brief biography, with portrait).J.C.Carr and W.Taplin, 1962, History of the British Steel Industry, Harvard University Press (contains an excellent summary of salient events).JKA -
17 плавка
melting operation, ( металла) founding, fusing, fusion, heat, ( продукт плавления) melt, melting, melting process, (чугуна, электростали, цветных металлов, ферросплавов) smelt, smelting, tap* * *пла́вка ж.1. (чугуна, ферросплавов и цветных металлов) smelting; ( стали) melting2. ( цикл от заправки плавильной печи до выпуска) heatвести́ пла́вку с доба́вками руды́ — ore down the heatвести́ пла́вку с доба́вками чугуна́ — pig up the heatдоводи́ть пла́вку — finish the heatпередува́ть пла́вку — overblow the heatподверга́ть пла́вке на … — smelt smth. for …шлак подверга́ется пла́вке на чернову́ю медь — slag is smelted for blister copperпродува́ть пла́вку — blow the heatавтоге́нная пла́вка — autogenous smeltingбро́совая пла́вка — off-beat, lost beatвагра́ночная пла́вка — cupola beatвзве́шенная пла́вка — flash smeltingпла́вка в кипя́щем сло́е — fluid bed [jet] smeltingвосстанови́тельная пла́вка — reduction smeltingгарниса́жная пла́вка — autocrucible meltingдугова́я пла́вка — arc meltingзахоло́женная пла́вка — cold beatзо́нная пла́вка — zone meltingиндукцио́нная пла́вка — induction meltingлу́ночная пла́вка — button meltingпла́вка на блейште́йн — lead matte smeltingпла́вка на концентра́т — concentrating smeltingпла́вка на роште́йн — raw matte smeltingпла́вка на штейн — matte smeltingпла́вка, не попа́вшая в ана́лиз — diverted beatогнева́я пла́вка — fuel-fired smeltingотража́тельная пла́вка — reverberatory process, reverberatory smeltingперегре́тая пла́вка — hot beatпири́тная пла́вка — pyretic smeltingполупири́тная пла́вка — semi-pyretic smeltingраздели́тельная пла́вка — top-and-bottom smeltingраскислё́нная пла́вка — deoxidized heatсты́лая пла́вка — stickerти́гельная пла́вка — crucible processтяжелове́сная пла́вка — heavy-weight beatуше́дшая пла́вка — off-beatцикло́нная пла́вка — cyclone smeltingша́хтная пла́вка — blast smeltingшлаку́ющая пла́вка ( в цветной металлургии) — slag smeltingпла́вка шли́хов — concentrate smeltingэлектроннолучева́я пла́вка — electron-beam melting -
18 плавка
1. ж. smelting; melting2. ж. heatподвергать плавке на … — smelt smth. for …
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