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41 basis Bessemer cast iron
Техника: томасовский чугунУниверсальный англо-русский словарь > basis Bessemer cast iron
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42 basis Bessemer pig iron
Техника: томасовский чугунУниверсальный англо-русский словарь > basis Bessemer pig iron
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43 acid-bessemer pig iron
Англо русский политехнический словарь > acid-bessemer pig iron
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44 basic Bessemer pig iron
< metal> ■ Thomasroheisen nEnglish-german technical dictionary > basic Bessemer pig iron
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45 acid-bessemer pig iron
English-Russian dictionary of mechanical engineering and automation > acid-bessemer pig iron
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46 basic Bessemer pig iron
surówka tomasowskasurówka zasadowaEnglish-Polish dictionary for engineers > basic Bessemer pig iron
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47 basic Bessemer pig iron
метал.English-Russian scientific dictionary > basic Bessemer pig iron
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48 Mushet, Robert Forester
SUBJECT AREA: Metallurgy[br]b. 8 April 1811 Coleford, Gloucestershire, Englandd. 19 January 1891 Cheltenham, Gloucestershire, England[br]English steelmaker who invented the first alloy steel.[br]Mushet acquired his metallurgical knowledge in his father's ironworks at Coleford in the Forest of Dean. In 1848 his attention seems to have been drawn to the use of manganese in ironworking, in the form of spiegeleisen, an alloy of iron and manganese derived from a Prussian iron ore consisting essentially of a double carbonate of iron and manganese. This alloy came into its own in 1856 with the invention of the Bessemer steelmaking process, for Mushet found that if molten spiegeleisen was added to the Bessemer iron the quality of the product was greatly improved. Mushet patented this process, but when he failed to pay the stamp duty due in 1859 his rights lapsed. Bessemer independently discovered the use of spiegeleisen, although Mushet continued to maintain his priority.Mushet's most important discovery was that of tungsten steel, the forerunner of a long line of alloy steels. While working a small crucible steelworks at Coleford, he was asked by a Scottish manufacturer to make a hard-metal tool, but he found that the metal was unsatisfactory. After experiments, he found that an alloy steel containing about 8 per cent tungsten possessed remarkable properties. It proved to be self-hardening, i.e. after forging and being allowed to cool, it was found to have become hardened, without the need for the heat treatment that was normally required. Also, unlike other hardened steels, it did not lose its hardness when heated even to dull-red heat. It would thus remain hard in a cutting tool that had run hot through deep cutting. Mushet's tungsten steel was brought into use in 1868 and was of great benefit to engineers, who were making increasing demands on cutting machines.[br]Further ReadingBiographical notice, 1878, Journal of the Iron and Steel Institute: 1–4.LRDBiographical history of technology > Mushet, Robert Forester
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49 Adamson, Daniel
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Steam and internal combustion engines[br]b. 1818 Shildon, Co. Durham, Englandd. January 1890 Didsbury, Manchester, England[br]English mechanical engineer, pioneer in the use of steel for boilers, which enabled higher pressures to be introduced; pioneer in the use of triple-and quadruple-expansion mill engines.[br]Adamson was apprenticed between 1835 and 1841 to Timothy Hackworth, then Locomotive Superintendent on the Stockton \& Darlington Railway. After this he was appointed Draughtsman, then Superintendent Engineer, at that railway's locomotive works until in 1847 he became Manager of Shildon Works. In 1850 he resigned and moved to act as General Manager of Heaton Foundry, Stockport. In the following year he commenced business on his own at Newton Moor Iron Works near Manchester, where he built up his business as an iron-founder and boilermaker. By 1872 this works had become too small and he moved to a 4 acre (1.6 hectare) site at Hyde Junction, Dukinfield. There he employed 600 men making steel boilers, heavy machinery including mill engines fitted with the American Wheelock valve gear, hydraulic plant and general millwrighting. His success was based on his early recognition of the importance of using high-pressure steam and steel instead of wrought iron. In 1852 he patented his type of flanged seam for the firetubes of Lancashire boilers, which prevented these tubes cracking through expansion. In 1862 he patented the fabrication of boilers by drilling rivet holes instead of punching them and also by drilling the holes through two plates held together in their assembly positions. He had started to use steel for some boilers he made for railway locomotives in 1857, and in 1860, only four years after Bessemer's patent, he built six mill engine boilers from steel for Platt Bros, Oldham. He solved the problems of using this new material, and by his death had made c.2,800 steel boilers with pressures up to 250 psi (17.6 kg/cm2).He was a pioneer in the general introduction of steel and in 1863–4 was a partner in establishing the Yorkshire Iron and Steel Works at Penistone. This was the first works to depend entirely upon Bessemer steel for engineering purposes and was later sold at a large profit to Charles Cammell \& Co., Sheffield. When he started this works, he also patented improvements both to the Bessemer converters and to the engines which provided their blast. In 1870 he helped to turn Lincolnshire into an important ironmaking area by erecting the North Lincolnshire Ironworks. He was also a shareholder in ironworks in South Wales and Cumberland.He contributed to the development of the stationary steam engine, for as early as 1855 he built one to run with a pressure of 150 psi (10.5 kg/cm) that worked quite satisfactorily. He reheated the steam between the cylinders of compound engines and then in 1861–2 patented a triple-expansion engine, followed in 1873 by a quadruple-expansion one to further economize steam. In 1858 he developed improved machinery for testing tensile strength and compressive resistance of materials, and in the same year patents for hydraulic lifting jacks and riveting machines were obtained.He was a founding member of the Iron and Steel Institute and became its President in 1888 when it visited Manchester. The previous year he had been President of the Institution of Civil Engineers when he was presented with the Bessemer Gold Medal. He was a constant contributor at the meetings of these associations as well as those of the Institution of Mechanical Engineers. He did not live to see the opening of one of his final achievements, the Manchester Ship Canal. He was the one man who, by his indomitable energy and skill at public speaking, roused the enthusiasm of the people in Manchester for this project and he made it a really practical proposition in the face of strong opposition.[br]Principal Honours and DistinctionsPresident, Institution of Civil Engineers 1887.President, Iron and Steel Institute 1888. Institution of Civil Engineers Bessemer Gold Medal 1887.Further ReadingObituary, Engineer 69:56.Obituary, Engineering 49:66–8.Obituary, Proceedings of the Institution of Civil Engineers 100:374–8.H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (provides an illustration of Adamson's flanged seam for boilers).R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (covers the development of the triple-expansion engine).RLH -
50 process
1) процесс2) (технологический) процесс; (технологическая) обработка3) технологический приём; способ4) технология5) режим; ход (процесса)6) обрабатывать, подвергать обработке7) подвергать анализу, анализировать•to design process — разрабатывать технологию-
acetone-acetylene process
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acetylene process
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Acheson process
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acid Bessemer process
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acid process
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acid reclaiming process
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acyclic process
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Adapti investment casting process
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additive process
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adiabatic process
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Aero case process
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aerobic process
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age-dependent process
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air blast process
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air-sand process
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Alcan process
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Al-Dip process
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alfin process
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alkali reclaiming process
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alkaline process
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Allis-Chalmers agglomeration reduction process
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ALT process
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aluminothermic process
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anaerobic process
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anamorphotic process
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annealing-in-line process
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anode process
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anodic electrode process
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AOD process
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aqua-cast process
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ARBED-ladle-treatment process
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arc-air process
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arc-remelting process
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argon-oxygen-decarburization process
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ASEA-SKF process
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autoregressive process
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averaging process
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Azincourt process
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azo coupling process
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background process
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bag process
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BAP process
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Barrow process
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Basett process
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basic Bessemer process
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basic oxygen process
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basic process
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basic-arc process
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batch process
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biofiltration process
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bipolar process
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bipolar-FET process
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bipolar-MOS process
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BISRA degassing process
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black-heart process
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Blackodising process
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blast-furnace process
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Blaw-Knox process
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bleaching process
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Bochumer-Verein process
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boiling process
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bonding process
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bottom-argon-process process
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broadband random process
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bromoil transfer process
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bromoil process
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bubble-column process
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bubble-hearth process
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buffer-slag process
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Calmes process
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Canadizing process
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carbon mold process
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carbon process
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carbon-arc process
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carbon-in-leach process
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carbon-in-pulp process
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carbothermic process
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carbro process
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carrier-gas degassing process
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cascade process
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cast shell process
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catalytic DENO process
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cathodic process
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CC-CR process
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CC-DR process
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CC-HCR process
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cementation process
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cementation-in-pulp process
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cementing process
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centrifugal spinning process
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cermet process
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CESM process
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CEVAM process
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charge transfer process
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chemical vapor deposition process
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chemical-bonding process
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Chenot process
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china process
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cine exposure process
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cine process
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CLC process
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clean burn process
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cloudburst process
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CLU process
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CMOS process
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CNC process
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CO2 silicate process
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coal reduction process
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coal to gas process
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coal-gas-sumitomo process
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coal-oxygen-injection process
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COIN process
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cold box process
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cold doping process
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cold process
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cold scrap process
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cold type process
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collodion process
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color process
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concurrent processes
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consteel process
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consumable electrode vacuum arc melting process
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contact process
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continuous annealing process
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continuous casting-cleaning rolling process
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continuous casting-direct rolling process
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continuous casting-hot charging and rolling process
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continuous electroslag melting process
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continuous metal cast process
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continuous-on-line control process
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continuous-time process
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controlled pressure pouring process
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controlled process
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converter process
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cooking process
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coppering process
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copying process
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coupled cathodic-anodic process
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cracking process
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Creusot Loire Uddenholm process
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critical process
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cumulative process
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cuprammonium process
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curing process
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CVD process
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cyclic process
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Cyclosteel process
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Czochralski process
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daguerre photographic process
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dense-media process
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Desco process
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deterministic process
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developing process
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DH degassing process
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diabatic process
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diazo process
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diffused planar process
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diffusion process
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diffusion transfer process
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dip-forming process
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direct iron process
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direct process
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direct reduction process
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direct-sintering process
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discrete-time process
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discrete process
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DLM process
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Domnarvet process
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Dored process
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double-crucible process
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double-epi process
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doubling process
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D-process
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DR process
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drop-molding process
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dry adiabatic process
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dry process
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dry-blanch-dry process
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duplex process
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easy drawing process
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EBM process
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EBR process
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EF-AOD process
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electric furnace-argon oxygen decarburization process
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electroarc process
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electrocatalytic process
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electrocolor process
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electrodialysis reversal process
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electroflux-remelting process
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electromembrane process
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electron-beam-melting process
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electron-beam-refining process
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electrophotoadhesive process
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electrophotographic process
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electroslag refining process
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electroslag remelting process
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electroslag remelt process
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electrostatographic process
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electrostream process
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Elo-Vac process
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elquench process
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endothermic process
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energy efficient process
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entropy process
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enzymatic process
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EPIC process
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epidemic process
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epitaxial growth process
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epitaxy growth process
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ergodic process
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ESR process
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Estel process
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etching process
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exoergic process
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exothermic process
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extrusion-molded neck process
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ferroprussiate process
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Ferrox process
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filming process
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filtration-chlorination process
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Finkl-Mohr process
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FIOR process
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first process
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fixed-bed MTG process
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flash steel direct reduction process
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float process
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float-and-sink process
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float-zone process
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flow process
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fluid iron ore reduction process
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fluid-bed MTG process
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fluidized roasting process
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fluid-sand process
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FMC coke process
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foaming process
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foehn process
-
food-machinery and chemical coke process
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foreground process
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Foren process
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FOS process
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freeze concentration process
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fuel-oxygen-scrap process
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full-mold process
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fusion-casting process
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Futacuchi process
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Gaussian process
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Gero mold degassing process
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Gero vacuum casting process
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GGS process
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girbitol process
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gradual reduction process
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growing process
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growth process
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gypsum-sulfuric acid process
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Hall electrolytic process
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Harris process
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hazardous process
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H-coal process
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heat-transfer process
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heavy-media process
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hibernating process
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HI-GAS process
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high-frequency induction process
-
HIP process
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H-iron process
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Hoope process
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hot isostatic pressing process
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hot process
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hot-metal process
-
hot-metal-and-scrap process
-
hot-type process
-
hydrogasification process
-
hydrotype process
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HyL process
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IC-DR process
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image process
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imbibition process
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immiscible displacement process
-
implantation process
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impurity doping process
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in-bulk process
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inchrome process
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in-draw process
-
inductoslag-melting process
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ingot casting direct rolling process
-
injection molding process
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in-line process
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Inred process
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interpolation process
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investment process
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ion-implantation process
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irreversible process
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isentropic process
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ISM process
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isobaric process
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isochoric process
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isoenthalpic process
-
isoentropic process
-
isometric process
-
isoplanar process
-
isothermal process
-
iterative process
-
jet-expanding process
-
Kaldo process
-
katadyn process
-
Kawasaki-bottom-oxygen-process process
-
Kawasaki-Gas-Lime-Injection process
-
K-BOP process
-
KEK process
-
KG-LI process
-
kiln-reduction process
-
KIVCET cyclone smelting process
-
KIVCET process
-
knit-deknit process
-
koetherizing process
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KR process
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kraft process
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lance bubbling equilibrium process
-
LBE process
-
LD-AB process
-
LD-AC process
-
LD-AOD process
-
LD-argon bottom process
-
LD-argon oxygen decarburization process
-
LD-CB process
-
LD-circle lance process
-
LD-CL process
-
LD-combination blow process
-
LD-HC top and botton blowing process
-
LDK process
-
LD-Kawasaki-Gas process
-
LD-KG process
-
LD-OB process
-
LD-OTB process
-
LD-oxygen bottom process
-
LD-oxygen-top-bottom process
-
lift-off process
-
liquefaction process
-
liquid gas plug process
-
liquid-phase process
-
loop transfer process
-
lost core process
-
low-waste technological process
-
LSI process
-
LVR process
-
LVS process
-
Mannesmann powder process
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mapping process
-
Markovian process
-
Markov process
-
masking process
-
matte fuming process
-
melting process
-
mercast process
-
Midland-Ross process
-
Midrex process
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migration process
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miscible displacement process
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miscible plug process
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mixed autoregressive-moving average process
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moist adiabatic process
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Molynutz process
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monochrome process
-
monolithic process
-
MOS process
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MOSFET process
-
motion-picture process
-
moving average process
-
narrowband random process
-
Neely process
-
negative-positive process
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Nitemper process
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no pickle process
-
nonflow process
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non-Gaussian process
-
Nord-Fuvo process
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Nu-iron process
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OBM process
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OG process
-
OLP converter process
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one-way process
-
open-hearth process
-
orbitread process
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ore process
-
Orthoflow cracking process
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Orthoforming process
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orthogonal increment process
-
oxidation process
-
oxide-isolated process
-
oxygen-blow process
-
oxygen-gas process
-
oxygen-lancing process
-
oxygen-steelmaking process
-
packaging process
-
pad-batch dyeing process
-
pad-dry dyeing process
-
pad-jig dyeing process
-
pad-roll dyeing process
-
pad-steam dyeing process
-
pad-steam vat-print process
-
PAMCO-hot-alloy process
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parent process
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PCR process
-
Perrin process
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PHA process
-
phonon process
-
photoelectric process
-
photomechanical process
-
photovoltaic process
-
pig iron-scrap process
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pig-and-ore process
-
pigment padding dying process
-
pigment padding process
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pigment process
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pinatype process
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planar process
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plasma etching process
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plasma etch process
-
plasma process
-
plasma-arc process
-
Plasmamelt process
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Plasmared process
-
plaster mold process
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plastic wirecut process
-
polytropic process
-
powder silicon ribbon process
-
power-press process
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prepolymer process
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prepress processes
-
pressure-driven membrane process
-
primuline process
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propane-acid process
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pulsating mixing process
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Purex process
-
pushbench process
-
Q-BOP process
-
QDT process
-
quality basic oxygen process process
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quasi-independent processes
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quick and direct tapping process
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ram process
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random process
-
rapid solidification plasma deposition process
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rayon continuous process
-
receiving process
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reclamator reclaiming process
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recurrent process
-
redox process
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reducing process
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reduction-smelting process
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relaxation process
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repetitive process
-
reproduction process
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reversal process
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reversible process
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RH process
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RH-OB process
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ribbon process
-
R-N direct-reduction process
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roasting-sintering process
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roast-leaching process
-
robot-controlled process
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rongalit-potash process
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rotor process
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rustless process
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sample process
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schoop process
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scrap-and-pig process
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scrap-conditioning process
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scrap-ore process
-
screen printed process
-
self-developing process
-
self-healing process
-
semibatch process
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semiconductor process
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sending process
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Sendzimir coating process
-
sequential process
-
silicon-gate MOS process
-
silicon-gate process
-
silk-screen process
-
single-pumpdown process
-
SIP process
-
skein spinning process
-
Skinner multiple-hearth process
-
slag minimum process
-
slip-casting process
-
slow down process
-
SLPM process
-
SL-RN metallization process
-
SL-RN reduction process
-
solid source diffusion process
-
solution regrowth process
-
solvent extraction-electrowinning process
-
solvent plug process
-
SOS process
-
spin-draw-texturizing process
-
spinylock process
-
sponge iron process
-
spontaneous process
-
Stanal process
-
stationary random process
-
STB process
-
steady-flow process
-
steam-blow process
-
steelmaking process
-
Stelmor process
-
step and repeat process
-
stochastic process
-
stuffer box process
-
submerged arc process
-
subtractive process
-
suck-and-blow process
-
Sulf BT process
-
Sulfinuz process
-
Sumitomo-slag all recycling process
-
Sumitomo-top-bottom process
-
Sursulf process
-
system process
-
TBM process
-
T-die process
-
Technamation process
-
thermal DeNOx process
-
Therm-i-Vac process
-
Thermo-Flow process
-
thermoplastic process
-
Thomas process
-
Thorex process
-
three-color process
-
Thyssen-blast-metallurgy process
-
Tifran process
-
tightly coupled processes
-
time-varying process
-
trichromatic process
-
triplex process
-
Tropenas converter process
-
Tufftride process
-
Tufftride TF1 process
-
uncertain process
-
user process
-
vacuum arc remelting process
-
vacuum casting process
-
vacuum deoxidation process
-
vacuum induction refining process
-
vacuum stream-droplet process
-
vacuum-arc degassing process
-
vacuum-carbodeoxidation process
-
vacuum-carbonate process
-
vacuum-induction melting process
-
vacuum-melting process
-
vacuum-metallothermic process
-
vacuum-oxygen-decarburization process
-
VAD process
-
VAR process
-
VAW process
-
VHSIC process
-
vigom process
-
VIR process
-
viscose process
-
visual process
-
VLSI process
-
VOD process
-
waiting process
-
water gas process
-
waterfall process
-
wet process
-
white-heart process
-
Zinal process
-
zinc distilling process -
51 Martin, Pierre Emile
SUBJECT AREA: Metallurgy[br]b. 18 August 1824 Bourges, Franced. 23 May 1915 Fourchambault, France[br]French metallurgist, pioneer of open-hearth steelmaking.[br]His father Emile owned an iron-and steelworks at Sireuil, near Angoulême, and, through this, Pierre became interested in improving the steelmaking process. In England, C.W. Siemens had developed the regenerative principle of waste-heat recovery that produced a much higher furnace temperature. In 1863, the Martins applied this process in an open-hearth furnace built under licence from Siemens, with the aid of his engineers. They melted a mixture of pig-and wrought iron to produce steel with the required carbon content. Martin exhibited the product at the Paris Exhibition of 1867 and was awarded a gold medal. The open-hearth process was for a long time known as the Siemens-Martin process, but Martin did not share in the profits which others gained from its successful adoption. He had difficulty in obtaining patent rights as it was claimed that the principles of the process were already known and in use. The costs of litigation brought Martin to the brink of poverty, from which relief came only late in life, when in 1907 the Comité des Forges de France opened a subscription for him that was generously supported. A week before his death, the Iron and Steel Institute of London bestowed on him their Bessemer gold medal.[br]Principal Honours and DistinctionsIron and Steel Institute Bessemer Gold Medal 1915.Further ReadingObituary, 1915, Journal of the Iron and Steel Institute 91:466.LRD -
52 Thomas, Sidney Gilchrist
SUBJECT AREA: Metallurgy[br]b. 16 April 1850 London, Englandd. 1 February 1885 Paris, France[br]English inventor of basic steelmaking.[br]Thomas was educated at Dulwich College and from the age of 17, for the next twelve years, he made his living as a police-court clerk, although he studied chemistry in his spare time as an evening student at Birkbeck College, London. While there, he heard of the difficulties encountered by the Bessemer steelmaking process, which at that time was limited to using phosphorus-free iron. Any of this element present in the iron was oxidized to phosphoric acid, which would not react with the acidic lining in the converter, with the result that it would remain in the iron and render it too brittle to use. Unfortunately, phosphoric iron ores are more common than those free of this harmful element. Thomas was attracted by the view that a fortune awaited anyone who could solve this problem, and was not discouraged by the failure of several august figures in the industry, including Siemens and Lowthian Bell.Thomas's knowledge of chemistry taught him that whereas an acidic lining allowed the phosphorus to remain in the iron, a basic lining would react with it to form part of the slag, which could then be tapped off. His experiments to find a suitable material were conducted in difficult conditions, in his spare time with meagre apparatus. Finally he found that a converter lined with dolomite, a form of limestone, would succeed, and he appealed to his cousin Percy Carlyle Gilchrist, Chemist at the Blaenavon Ironworks in Monmouthshire, for help in carrying out pilot-scale trials. In 1879 he gave up his police-court job to devote himself to the work, and in the same year they patented the Thomas- Gilchrist process. The first licence to use it was granted to Bolckow, Vaughan \& Co. of Middlesborough, and there the first steel was made in a basic Bessemer converter on 4 April 1879. The process was rapidly taken up and spread widely in Europe and beyond and was applied to other furnaces. Thomas made a fortune, but his health did not long allow him to enjoy it, for he died at the early age of 34.[br]BibliographyL.G.Thompson, 1940, Sidney Gilchrist Thomas, an Invention and Its Consequences, London: Faber.T.G.Davies, 1978, Blaenavon and Sidney Gilchrist Thomas, Sheffield: Historical Metallurgy Society.LRDBiographical history of technology > Thomas, Sidney Gilchrist
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53 ore
1. руда 2. рудный минерал
ores as fillings жильные руды
ores as intense replacements метасоматические руды
ore in place рудный массив
ore in sight достоверные запасы руды
ore of igneous origin руда магматического происхождения
acicular iron ore игольчатая железная руда
aggregated ore массивная сульфидная руда (в которой сульфиды составляют 20% и больше от общего объёма)
alveolar ore ячеистая руда
antimony ore сурьмяная руда
assured ore достоверные запасы руды
band(ed) ore полосчатая руда
base ore бедная руда
beach ore пляжевая [прибрежная] россыпь; пляжевый концентрат
bean ore бобовая (железная) руда, пизолитовый железняк
Bessemer ore бессемеровская (железная) руда
bird's-eye ore пятнистая руда, руда с «птичьим глазом»
bismuth ore висмутовая руда
black ore частично разложившийся медьсодержащий пирит
black-band ore разновидность глинистого железняка
black iron ore магнетит
black lead ore чёрная разновидность церуссита
blistered copper ore почкообразная разновидность халькопирита
block ore блоковая руда
blocked-out ore подготовленная к выемке руда
blue copper ore азурит, синий малахит (см. тж. azurite)
blue lead ore уст. синевато-серая разновидность галенита
bog ore болотная руда
bog iron ore болотная железная руда, лимонит
bonanza ore бонанцовая руда
botryoidal iron ore гроздевидная железная руда
brass ore 1. см. aurichalcite 2. pl. комплексные сфалерит-халькопиритовые руды
brittle silver ore хрупкая серебряная руда, стефанит (см. тж. stephanite)
brown iron ore лимонит; бурый железняк
brown manganese ore манганит, бурая руда марганца
brush ore железная руда сталактитового строения
calcareous iron — железная руда, содержащая карбонат кальция
canary ore жёлтая землистая серебросодержащая свинцовая руда (состоящая из пироморфита, биндгеймита и массикота)
carbonate ore руда, содержащая значительное количество карбонатной группы chrome
iron ore хромит (см. тж. chromite)
Clinton ore руда клинтонского типа (красная железная руда, содержащая органические ископаемые остатки; приуроченная к формации Клинтон)
cobalt ore кобальтовая руда
cocarde [cockade] ore кокардовая [кольчатая] руда
cogwheel ore свинцовая блёклая руда
compact iron ore сплошная железная руда
complex ore 1. полиметаллическая руда 2. сложная труднообогатимая руда
coon-tail ore руда «енотовый хвост»
copper ore медная руда
copper pitch ore хризоколла (см. тж. chrysocolla)
coral ore разновидность киновари (содержащая примесь фосфатов, глины и органических веществ)
crop ore обогащенная оловянная руда высшего качества
crude ore необогащённая руда
crust ore корковая руда
crystalline iron ore кристаллическая железная руда; железная руда,образованная в результате перекристаллизации
cube ore фармакосидерит, Fe3(As04)2
developed ore подсечённая выработками руда; подготовленные запасы рудного месторождения
developing ore частично подготовленная для выемки руда; подготавливаемые запасы рудного месторождения
disseminated ore вкрапленная руда
drag ore рудная брекчия, брекчированная руда
dredgy ore порода, пронизанная тонкими рудными прожилками
dressed ore обогащенная руда
dry ore 1. серебряная руда с малым содержанием свинца 2. сухая руда
dry-bone ore 1. галмей (землистая пористая разновидность смитсонита) 2. каламин
dust ore выветрелая руда
earthy iron ore пористая (землистая) железная руда
earthy lead ore землистая разновидность церус сита
earthy red iron ore красная охра
efflorescent ore выветрелая руда; руда с выцветами на обнажённой поверхности или по плоскостям отдельности
expected ore ожидаемая [предполагаемая] руда
extension ore 1. продолжение рудного тела (зоны оруденения) 2. возможные (неразведанные) запасы руды
fahl ore блёклая медная руда
fausted ore рудные высевки, отвал малопроцентной руды
feather ore волокнистый джемсонит, перистая руда
fibrous iron ore железная руда с волокнистой текстурой
fine ore рудная мелочь, мелкозернистая руда
fine iron ore порошкообразная железная руда
flag ore слоистый гематит, богатый кремнезёмом; плитняковая руда
flaxseed ore оолитовая руда; оолитовая железная РУДа
float ore 1. валунная руда 2. отторженные от коренных выходов обломки жильного материала
fluxing ore флюксующаяся руда
fossil ore руда, содержащая обломки остатков ископаемых организмов; руда с окаменелостями
free-milling ore легко обрабатываемая при обогащении руда
friable iron ore выветрелая землистая железная руда
future ore геологические предпосылки открытия рудной залежи; прогноз оруденения
galenical iron ore железная руда с содержанием сернистого свинца
geological ore см. possible ore
gold ore золотая руда, золотосодержащий кварц
gray manganese ore 1. манганит (см. тж. manganite) 2. пиролюзит (см. тж. pyrolusite)
green lead ore пироморфит (см. тж. pyromorphite)
halo ore краевая руда (руда ореола или внешней части зоны минерализации)
hard ore твёрдая руда
hard cobalt ore скуттерудит (мышьяково-кобальтовый колчедан; см. тж. skutterudite)
hematite iron ore кровавик, красная железная руда, гематит
hidden ore скрытая руда
high-grade ore высокосортная руда
horseflesh ore борнит (см. тж. bornite)
horsetail ore рудное тело, заключающее серию мелких жил, ответвляющихся от главной жилы
hortonolite-dunite ore гортонолито-дунитовая руда
impregnation ore импрегнированная руда
indicated ore подсчитанные запасы руды
inferred ore прогнозные запасы руды
iron ore железная руда, железняк
kidney ore почковидная руда, «стеклянная голова» (разновидность гематита)
knock-back ore руда, смешанная с баритом
lacustrine iron ore озёрный бурый железняк
lake ore озёрная руда, вад, бурый железняк; лимонит, отложившийся на дне озера
lean ore бедная руда
light red silver ore прустит, светло-красная серебряная руда
liver ore куприт, красная медная руда (разновидность киновари)
lode ore рудная жила
low-grade ore низкосортная руда
lump ore кусковая руда
magnetic iron ore магнетит; магнитный железняк, магнитная железная руда
manganese ore марганцевая руда
marsh ore болотная руда
meadow ore луговая руда
mercuric horn ore ртутная роговая руда, каломель, природная хлористая ртуть
micaceous iron ore железная слюдка (разновидность гематита)
milling ore руда, требующая обогащения; второсортная руда
minette ore оолитовая железная руда, оолитовый лимонит
mock ore сфалерит, цинковая обманка (см. тж. sphalerite)
morass ore см. bog iron ore
mottled ore грубопятнистая руда
needle ore игольчатая руда (см. тж. aikinite l.)
needle iron ore игольчатый железняк, игольчатый гетит
needle tin ore игольчатый касситерит
nodular ore почковидная [конкреционная] руда
nodular iron ore почковидная [конкреционная] железная руда
octahedral copper ore куприт (см. тж. cuprite)
octahedral iron ore магнетит (см. тж. magnetite)
olive ore оливенит, мышьяково-медная руда (см. тж. olivenite)
oolitic iron ore оолитовая железная руда, оолитовый лимонит
oxidized ore окисленная руда
paramagnetic ore парамагнитная руда (руда, содержащая парамагнитные минералы)
pay ore промышленная [коммерческая] руда
peachblossom ore эритрит (см. тж. erithrite)
peacock (copper) ore пёстрая [«павлинья»] медная руда
pea (iron) ore гороховая руда (пизолитовый лимонит; разновидность бобовой руды)
pencil ore грифельная руда
phosphatic iron ore железная руда, содержащая фосфор
picked ore вкрапленная руда
pipe ore железная руда в виде вертикальных столбов в глине
pisolitic iron ore бобовая (железная) руда, пизолитовый железняк
pitch ore 1. урановая смолка 2. смоляная медная руда
pitchy iron ore питтицит (водный арсенат и сульфат железа непостоянного состава)
plumbum ore свинцовая руда
plush-copper ore халькотрихит (волосовидный куприт)
porphyry ore порфировая (вкрапленная) руда
positive ore достоверные (подсчитанные) запасы руды
possible ore возможные (неразведанные) запасы руды
potential ore потенциальные запасы руды
powder ore порошковая руда
powdery iron ore порошкообразная железная руда
primary ore первичная руда
probable ore 1. предполагаемые запасы руд 2. прогнозные руды, прогнозные запасы
prospective ore перспективные запасы руды
proved ore установленные запасы руды
purple ore пурпуровая руда
purple copper ore борнит (см. тж. bornite)
radium ore радиевая руда
rattlesnake ore пятнистая руда, состоящая из карнотита и ваноксита (руда типа "гремучей змеи")
raw ore необогащённая руда; сырая руда
rebellious ore 1. упорное золото; золото в рубашке 2. трудно поддающаяся обработке руда
red ore красная руда (гематит и метахьюэттит)
red copper ore красная медная руда, куприт (см. тж. cuprite)
red iron ore красный железняк, железный блеск, гематит, α-Fе2О3
red lead ore крокоит, PbCrO4
red manganese ore красная марганцевая руда (родонит, родохрозит и примеси)
red silver ore красная серебряная руда (прустит, пираргирит)
red zinc ore цинкит, (Zn, Mn)0
refractory ore руда, извлечение металла из которой требует больших затрат
refuse ore отвал, моечные отходы руд, остатки после обогащения руд
replacement ore руда замещения
rich ore 1. руда с высоким содержанием металла 2. обогащенная руда
ring ore кокардовая [кольчатая] руда
rock ore руда на месте залегания
shining ore железные блеск, гематит, красный железняк, α-Fе2О3
shipping ore первоклассная руда, пригодная для выхода на рынок без предварительного обогащения
silver lead ore серебросодержащий галенит
slaggy brown iron ore шлаковидный бурый железняк
small ore порошкообразная [размельчённая] руда
small iron ore порошкообразная железная руда
soft iron ore мягкая железная руда
solid ore руда на месте залегания или в жиле; крепкая нетронутая руда
sparry iron ore сидерит
specimen ore особенно богатое или хорошо раскристаллизованное рудное тело
specular iron ore железный блеск, красный железняк, гематит, спекулярит
sphere ore кокардовая [кольчатая] руда
steel ore железная руда, пригодная для производства стали
sulfide ore сульфидная руда
sulfur ore серная руда; самородная сера; пирит
swamp ore болотная железная руда, лимонит
tile ore черепитчатая руда (разновидность куприта)
tin ore касситерит, оловянный камень (см. тж. cassiterit)
titanic iron ore ильменит, титанистый железняк (см. тж. ilmenite)
titaniferous iron ore железная руда с содержанием титана, титанистая железная руда
turkey-fat ore оранжевая разновидность смитсонита, «индюшачья» руда (США)
unmagnetic ore немагнитная руда
uranium ores урановые руды (пригодные для разработки)
vanadium ores ванадиевые руды
velvet copper ore леттсомит, цианотрихит, бархатная медная руда (см. тж. cyanotrichite)
visible ore руда, которую можно наблюдать в естественном или искусственном разрезе
water-bearing iron ore водонасыщенная железная РУДа
wheel ore бурнонит (кристаллы-двойники, образующие концентрические рисунки; см. тж. bour-nonite)
white iron ore сидерит, железный шпат, шпатовый железняк (см. тж. siderite)
white lead ore церуссит, белая свинцовая руда, углекислый свинец (см. тж. cerussite)
white silver — серебросодержащий тетраэдрит
wood iron ore деревянистый железняк
yellow ore жёлтая руда (карнотит и халькопирит)
yellow copper ore см. chalcopyrite
yellow lead ore см. wulfenite
zinc ore см. zincite
* * *• рудно -
54 Hall, Joseph
SUBJECT AREA: Metallurgy[br]b. 1789d. 1862[br]English ironmaker who invented the wet puddling process.[br]Hall was a practical man with no theoretical background: his active years were spent at Bloomfield Ironworks, Tipton, Staffordshire. Around 1816 he began experimenting in the production of wrought iron. At that time, blast-furnace or cast iron was converted to wrought iron by the dry puddling process invented by Henry Cort in 1784. In this process, the iron was decarburized (i.e. had its carbon removed) by heating it in a current of air in a furnace with a sand bed. Some of the iron combined with the silica in the sand to form a slag, however, so that no less than 2 tons of cast iron were needed to produce 1 ton of wrought. Hall found that if bosh cinder was charged into the furnace, a vigorous reaction occurred in which the cast iron was converted much more quickly than before, to produce better quality wrought iron, a ton of which could be formed by no more than 21 cwt (1,067 kg) of cast iron. Because of the boiling action, the process came to be known as pig boiling. Bosh cinder, essentially iron oxide, was formed in the water troughs or boshes in which workers cooled their tools used in puddling and reacted with the carbon in the cast iron. The advantages of pig boiling over dry puddling were striking enough for the process to be widely used by the late 1820s. By mid-century it was virtually the only process used for producing wrought iron, an essential material for mechanical and civil engineering during the Industrial Revolution. Hall reckoned that if he had patented his invention he would have "made a million". As luck would have it, the process that he did patent in 1838 left his finances unchanged: this was for the roasting of cinder for use as the base of the puddling furnace, providing better protection than the bosh cinder for the iron plates that formed the base.[br]Bibliography1857, The Iron Question Considered in Connection with Theory, Practice and Experience with Special Reference to the Bessemer Process, London.Further ReadingJ.Percy, 1864, Metallurgy. Iron and Steel, London, pp. 670 ff. W.K.V.Gale, Iron and Steel, London: Longmans, pp. 46–50.LRD -
55 бессемеровский чугун
Большой англо-русский и русско-английский словарь > бессемеровский чугун
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56 бессемеровский чугун
Англо-русский словарь технических терминов > бессемеровский чугун
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57 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 -
58 Talbot, Benjamin
SUBJECT AREA: Metallurgy[br]b. 19 September 1864 Wellington, Shropshire, Englandd. 16 December 1947 Solberge Hall, Northallerton, Yorkshire, England[br]Talbot, William Henry Fox English steelmaker and businessman who introduced a technique for producing steel "continuously" in large tilting basic-lined open-hearth furnaces.[br]After spending some years at his father's Castle Ironworks and at Ebbw Vale Works, Talbot travelled to the USA in 1890 to become Superintendent of the Southern Iron and Steel Company of Chattanooga, Tennessee, where he initiated basic open-hearth steelmaking and a preliminary slag washing to remove silicon. In 1893 he moved to Pennsylvania as Steel Superintendent at the Pencoyd works; there, six years later, he began his "continuous" steelmaking process. Returning to Britain in 1900, Talbot marketed the technique: after ten years it was in successful use in Britain, continental Europe and the USA; it promoted the growth of steel production.Meanwhile its originator had joined the Cargo Fleet Iron Company Limited on Teesside, where he was made Managing Director in 1907. Twelve years later he assumed, in addition, the same position in the allied South Durham Steel and Iron Company Limited. While remaining Managing Director, he was appointed Deputy Chairman of both companies in 1925, and Chairman in 1940. The companies he controlled survived the depressed 1920s and 1930s and were significant contributors to British steel output, with a capacity of more than half a million tonnes per year.[br]Principal Honours and DistinctionsPresident, Iron and Steel Institute 1928, and (British) National Federation of Iron and Steel Manufacturers. Iron and Steel Institute (London) Bessemer Gold Medal 1908. Franklin Institute (Philadelphia), Elliott Cresson Gold Medal, and John Scott Medal 1908.Bibliography1900, "The open-hearth continuous steel process", Journal of the Iron and Steel Institute 57 (1):33–61.1903, "The development of the continuous open-hearth process", Journal of the Iron and Steel Institute 63(1):57–73.1905, "Segregation in steel ingots", Journal of the Iron and Steel Institute 68(2):204–23. 1913, "The production of sound steel by lateral compression of the ingot whilst its centre is liquid", Journal of the Iron and Steel Institute 87(1):30–55.Further ReadingG.Boyce, 1986, entry in Dictionary of Business Biography, Vol. V, ed. J.Jeremy, Butterworth.W.G.Willis, 1969, South Durham Steel and Iron Co. Ltd, South Durham Steel and Iron Company Ltd (includes a few pages specifically on Talbot, and a portrait photo). J.C.Carr and W.Taplin, 1962, History of the British Steel Industry, Cambridge, Mass.: Harvard University Press (mentions Talbot's business attitudes).JKA -
59 steel
сталь || стальной- abrasion-resistant steel
- acid Bessemer steel
- acid electric steel
- acid open-hearth steel
- acid steel
- acid-resisting steel
- age-hardenable steel
- ageing steel
- aircraft structural steel
- air-hardened steel
- air-hardening steel
- air-melted steel
- alkaliproof steel
- alkali-resistant steel
- alloy steel
- alloy tool steel
- alloyed steel
- alphatized steel
- aluminized steel
- aluminum grain-refined steel
- aluminum steel
- aluminum-coated steel
- aluminum-nickel steel
- aluminum-stabilized steel
- anchor steel
- angle steel
- annealed steel
- anticorrosion steel
- arc-furnace steel
- armco steel
- ausaging steel
- ausforming steel
- austenitic manganese steel
- austenitic Ni-Cr stainless steel
- austenitic stainless steel
- austenitic steel
- austenitic-carbidic steel
- austenitic-intermetallic steel
- automatic steel
- automobile steel
- axle steel
- bainitically heat-treated steel
- balanced steel
- ball bearing steel
- banding steel
- bandsaw steel
- bar steel
- basic Bessemer steel
- basic converter steel
- basic open-hearth steel
- basic oxygen steel
- bearing steel
- bearing-grade steel
- beaten steel
- beryllium steel
- Bessemer steel
- blanking steel
- blister steel
- blue steel
- boiler steel
- boron steel
- bottle-top steel
- bottom-run steel
- bright drawing steel
- bright steel
- bright-drawn steel
- bright-finished steel
- bronze steel
- bulb steel
- bulb-angle steel
- burned steel
- capped steel
- carbon nitrided steel
- carbon steel
- carbon tool steel
- carbonized steel
- carbon-martensite steel
- carbon-molybdenum steel
- carbon-vacuum deoxidized steel
- carburized steel
- carburizing steel
- case-hardened steel
- case-hardening steel
- cast steel
- cemented steel
- chain steel
- chilled steel
- chisel steel
- chrome steel
- chrome-manganese steel
- chrome-molybdenum steel
- chrome-nickel steel
- chrome-nickel-alloy steel
- chrome-nickel-molibdenum steel
- chrome-plated steel
- chrome-tungsten steel
- chrome-vanadium steel
- chromium steel
- chromium tool steel
- chromium-aluminum steel
- chromium-cobalt steel
- chromium-copper steel
- chromium-manganese steel
- chromium-molibdenum steel
- chromium-nickel steel
- chromium-nickel-molybdenum steel
- chromium-silicon steel
- chromium-tungsten steel
- chromium-tungsten-vanadium steel
- chromized steel
- clad steel
- cobalt steel
- cobalt-nickel steel
- coiled steel
- cold work steel
- cold-drawn steel
- cold-heading steel
- cold-rolled steel
- columbium-stabilized steel
- commercial forging steel
- commercial quality steel
- commercial steel
- common steel
- composite steel
- compound steel
- concrete-prestressing steel
- concrete-reinforcing steel
- constructional steel
- consumable electrode vacuum-melted steel
- controlled rimming steel
- converted steel
- converter steel
- copper steel
- copper-bearing steel
- copper-chromium steel
- copperclad steel
- copper-nickel steel
- copper-plated steel
- corrosion-resistant steel
- corrosion-resisting steel
- corrugated sheet steel
- CQ steel
- creep-resisting steel
- crucible steel
- crude steel
- cutlery-type stainless steel
- cyanided steel
- damascus steel
- damask steel
- DDQ steel
- dead-hard steel
- dead-melted steel
- dead-soft steel
- deep drawing quality steel
- deep drawing steel
- deep-hardening steel
- degasified steel
- deoxidized steel
- diamond tread steel
- die steel
- direct-process steel
- dirty steel
- dopped steel
- double-reduced steel
- double-refined steel
- double-shear steel
- drawn steel
- drill steel
- duplex steel
- dynamo sheet steel
- dynamo steel
- easily deformable steel
- EDD steel
- effervescent steel
- electric furnace steel
- electric steel
- electric tool steel
- electrical furnace steel
- emergency steel
- eutectoid steel
- exotic steel
- exposed quality steel
- extra deep drawing steel
- extrafine steel
- extrahard steel
- extrahigh tensile steel
- extrasoft steel
- face-hardened steel
- fagoted steel
- fashioned steel
- fast-finishing steel
- fast-machine steel
- faulty steel
- ferrite steel
- ferritic stainless steel
- ferritic steel
- fiery steel
- figured steel
- file steel
- fine steel
- fine-grained steel
- finished steel
- first quality steel
- flange steel
- flat steel
- flat-bulb steel
- flat-rolled steel
- forge steel
- forged steel
- forging die steel
- forging steel
- free-cutting steel
- free-machining steel
- fully deoxidized steel
- fully finished steel
- galvanized steel
- gear steel
- general purpose steel
- glass-hard steel
- grade steel
- graphitic steel
- graphitizable steel
- gun barrels steel
- gun steel
- Hadfield steel
- half-hard steel
- Halvan tool steel
- hammered steel
- hard cast steel
- hard steel
- hard-chrome steel
- hardened steel
- hard-grain steel
- heat-resistant steel
- heat-treated steel
- heavily alloyed steel
- heavy-fagoted steel
- heavy-melting steel
- hexagonal steel
- high-alloy steel
- high-carbon steel
- high-chromium steel
- high-cobalt steel
- high-creep strength steel
- high-ductility steel
- high-elastic limit steel
- higher-carbon steel
- high-grade steel
- high-hardenability core steel
- high-hardenability steel
- high-manganese steel
- high-nickel steel
- high-permeability steel
- high-quality steel
- high-resistance steel
- high-speed steel
- high-strength low alloy steel
- high-strength steel
- high-sulphur steel
- high-temperature steel
- high-tensile steel
- hollow drill steel
- hot die steel
- hot-brittle steel
- hot-rolled steel
- hot-work steel
- hot-working die steel
- hot-working steel
- HSLA steel
- H-steel
- hypereutectoid steel
- hyperpearlitic steel
- hypoeutectoid steel
- hypopearlitic steel
- Indian steel
- induction furnace steel
- induction vacuum melted steel
- ingot steel
- intermediate-alloy steel
- iron-chromium stainless steel
- irreversible steel
- killed steel
- knife steel
- knife-blade steel
- lead-coated steel
- leaded steel
- lean alloy steel
- ledeburitic steel
- light gage steel
- liquid-compressed steel
- loman steel
- low earing steel
- low-alloy steel
- low-alloyed steel
- low-carbon steel
- low-ductility steel
- low-expansion steel
- low-hardenability steel
- low-hardening steel
- low-manganese steel
- low-nickel steel
- low-phosphorus steel
- low-texture steel
- machine-tool steel
- magnet steel
- mandrel steel
- manganese steel
- manganese-killed steel
- manganese-silicon steel
- maraging steel
- martempering steel
- martensitic steel
- mechanically capped steel
- medium alloy steel
- medium-carbon steel
- medium-hard steel
- medium-strength steel
- medium-temper steel
- merchant steel
- mild steel
- milling steel
- mixed steel
- molybdenum steel
- needled steel
- nickel steel
- nickel-chrome steel
- nickel-chrome-molybdenum steel
- nickel-chromium steel
- nickel-chromium-molybdenum steel
- nickel-clad steel
- nickel-molybdenum steel
- nitrided steel
- nonaging steel
- noncorrosive steel
- nondeforming steel
- nonhardening steel
- nonmagnetic steel
- nonpiping steel
- nonrustic steel
- nonshrinking steel
- nonstrain-aging steel
- normal steel
- octagon steel
- oil-hardening steel
- open-hearth steel
- open-poured steel
- ordinary steel
- oriented steel
- overblown steel
- overheated steel
- over-reduced steel
- oxidation-resisting steel
- paragon steel
- pearlitic steel
- perished steel
- permanent-magnet steel
- PH steel
- piled steel
- pipe steel
- piped steel
- plain carbon steel
- plain steel
- planished sheet steel
- planished steel
- plate steel
- plow steel
- pneumatic steel
- polished sheet steel
- polished steel
- pot steel
- powder metallurgical compacted steel
- powdered metal high-speed steel
- precipitation-hardening steel
- precision steel
- pressure vessel steel
- primary steel
- puddle steel
- puddled steel
- punching steel
- purified steel
- PV steel
- QT steel
- quality steel
- quenched-and-tempered steel
- quick-cutting steel
- quick-speed steel
- rail steel
- railway structural steel
- rapid machining steel
- rapid steel
- raw steel
- red-hard steel
- refined steel
- refining steel
- refractory steel
- reinforcing steel
- rephosphorized steel
- resilient steel
- resulphurized steel
- rimmed steel
- rimming steel
- rising steel
- rivet steel
- rolled section steel
- rolled steel
- roller-bearing steel
- rose steel
- round steel
- rustless steel
- rust-resisting steel
- saw steel
- scrap steel
- screw steel
- secondary steel
- section steel
- selenium steel
- self-hardening steel
- semideoxidized steel
- semifinished steel
- semikilled steel
- shallow-hardening steel
- shape steel
- shear steel
- shearing steel
- sheet steel
- shock-resisting steel
- Siemens-Martin steel
- silchrome steel
- silicon steel
- silicon-killed steel
- silicon-manganese steel
- silver steel
- simple steel
- skelp steel
- slowly cooled steel
- soft steel
- special steel
- special treatment steel
- spheroidized steel
- spotty steel
- spring steel
- stabilized steel
- stainless clad steel
- stainless steel
- standard steel
- stock steel
- strain-aged steel
- stress-relieved annealed steel
- strip steel
- strong steel
- structural steel
- super-corrosion-resistant stainless steel
- superduty steel
- surface-hardening steel
- surgical steel
- tap steel
- tapped-on-carbon steel
- T-bulb steel
- tee-bulb steel
- tempered steel
- tensile strength steel
- ternary steel
- thermostrengthened steel
- Thomas steel
- through-hardening steel
- titanium steel
- titanium-stabilized steel
- tool steel
- Tor steel
- transformation induced plasticity steel
- transformer steel
- treated steel
- TRIP steel
- tube steel
- tungsten steel
- turbohearth steel
- two-ply steel
- tyre steel
- ultrastrong steel
- unkilled steel
- unsound steel
- vacuum carbon deoxidized steel
- vacuum degased steel
- vacuum-cast steel
- vacuum-induction melted steel
- vacuum-remelted steel
- valve steel
- vanadium steel
- water-hardening steel
- wear-resisting alloy steel
- weathering steel
- weld steel
- weldable steel
- welding steel
- wild steel
- wire rope steel
- Wootz steel
- wrought steelEnglish-Russian dictionary of mechanical engineering and automation > steel
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60 Saniter, Ernest Henry
SUBJECT AREA: Metallurgy[br]b. 1863 Middlesbrough, Englandd. 2 November 1934 Rotherham, Yorkshire[br]English chemist and metallurgist who introduced a treatment to remove sulphur from molten iron.[br]Saniter spent three years as a pupil in J.E.Stead's chemical laboratory in Middlesbrough, and then from 1883 was employed in the same town as Assistant Chemist at the new North-Eastern Steelworks. In 1890 he became Chief Chemist to the Wigan Coal and Iron Company in Lancashire. There he devised a desulphurizing treatment for molten iron and steel, based upon the presence of abundant lime together with calcium chloride. Between 1898 and 1904 he was in the Middlesbrough district once more, employed by Dorman Long \& Co. and Bell Brothers in experiments which led to the establishment of Teesside's first large-scale basic open-hearth steel plant. Calcium fluoride (fluorspar), mentioned in Saniter's 1892 patent, soon came to replace the calcium chloride; with this modification, his method retained wide applicability throughout the era of open-hearth steel. In 1904 Saniter became chief metallurgist to Steel, Peech \& Tozer Limited of Sheffield, and he remained in this post until 1928. Throughout the last forty years of his life he participated in the discussion of steelmaking developments and practices.[br]Principal Honours and DistinctionsVice-President, Iron and Steel Institute 1927–34. Iron and Steel Institute (London) Bessemer Gold Medal 1910.Bibliography1892. "A new process for the purification of iron and steel from sulphur", Journal of the Iron and Steel Institute 2:216–22.1893. "A supplementary paper on a new process for desulphurising iron and steel", Journal of the Iron and Steel Institute 1:73–7. 29 October 1892, British patent no. 8,612.15 October 1892, British patent no. 8,612A. 29 July 1893, British patent no. 17, 692.28 October 1893, British patent no. 23,534.Further ReadingK.C.Barraclough, 1990, Steelmaking: 1850–1900 458, London: Institute of Metals, 271– 8.JKA
См. также в других словарях:
bessemer iron — noun or bessemer pig Usage: usually capitalized B Etymology: after H. Bessemer : a cast iron that contains not more than 0.10 percent of phosphorus and is suitable for the manufacture of Bessemer steel by the acid process * * * Bessemer iron or… … Useful english dictionary
bessemer pig — noun see bessemer iron * * * Bessemer iron or Bessemer pig noun Pig iron suitable for making Bessemer steel • • • Main Entry: ↑Bessemer … Useful english dictionary
Iron — I ron ([imac] [u^]rn), n. [OE. iren, AS. [=i]ren, [=i]sen, [=i]sern; akin to D. ijzer, OS. [=i]sarn, OHG. [=i]sarn, [=i]san, G. eisen, Icel. [=i]sarn, j[=a]rn, Sw. & Dan. jern, and perh. to E. ice; cf. Ir. iarann, W. haiarn, Armor. houarn.] [1913 … The Collaborative International Dictionary of English
Bessemer — is the name, or part of the name, of several places in the United States: *Bessemer, Alabama *Bessemer, Michigan *Bessemer Township, Michigan *Bessemer City, North Carolina *Bessemer, Pennsylvania *Bessemer Bend, WyomingOther things or people… … Wikipedia
Bessemer process — [bes′ə mər] n. [after Sir Henry Bessemer (1813 98), Eng engineer who developed it] a method of making steel by blasting air through molten pig iron in a large container (Bessemer converter) to burn away the carbon and other impurities … English World dictionary
Bessemer steel — Bes se*mer steel Steel made directly from cast iron, by burning out a portion of the carbon and other impurities that the latter contains, through the agency of a blast of air which is forced through the molten metal; so called from Sir Henry… … The Collaborative International Dictionary of English
Bessemer — in reference to the process for decarbonizing and desiliconizing pig iron by passing air through the molten metal, 1856, named for engineer and inventor Sir Harry Bessemer (1813 1898) who invented it … Etymology dictionary
Bessemer [2] — Bessemer, Sir Henry, Techniker, geb. 1813 in Hertfordshire, gest. 15. März 1898 in London, kam in seinem 18. Jahr mit seinen Eltern nach London, konstruierte eine Maschine zur Herstellung von Bronzestaub zum Vergolden und widmete sich fortan… … Meyers Großes Konversations-Lexikon
Iron City — Bessemer, Alabama and Pittsburgh, Pennsylvania … Eponyms, nicknames, and geographical games
Bessemer, Sir Henry — born Jan. 19, 1813, Charlton, Hertfordshire, Eng. died March 15, 1898, London British inventor and engineer. Son of a metallurgist, he set up his own casting business at 17. At that time the only iron based construction materials were cast iron… … Universalium
Bessemer process — The Bessemer process was the first inexpensive industrial process for the mass production of steel from molten pig iron. The process is named after its inventor, Henry Bessemer, who took out a patent on the process in 1855. The process was… … Wikipedia