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1 ladle
ladle ['leɪdəl]1 noun(a) (for soup) louche f∎ Metallurgy foundry ladle poche f de fonderieservir (à la louche) -
2 ladle metallurgy
ковшевая металлургия
Процесс дегазации для стали, выполняемый в ковше.
[ http://www.manual-steel.ru/eng-a.html]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > ladle metallurgy
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3 ladle metallurgy
Ковшевая металлургия.Процесс дегазации для стали, выполняемый в ковше. -
4 ladle metallurgy
Металлургия: ковшевая металлургия -
5 ladle metallurgy
rafinacja kadziowa -
6 ladle metallurgy furnace
English-Spanish metallurgy dictionary > ladle metallurgy furnace
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7 ladle metallurgy
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8 ladle metallurgy
• металлургия f ковшевая -
9 Pattinson, Hugh Lee
SUBJECT AREA: Metallurgy[br]b. 25 December 1796 Alston, Cumberland, Englandd. 11 November 1858 Scot's House, Gateshead, England[br]English inventor of a silver-extraction process.[br]Born into a Quaker family, he was educated at private schools; his studies included electricity and chemistry, with a bias towards metallurgy. Around 1821 Pattinson became Clerk and Assistant to Anthony Clapham, a soap-boiler of Newcastle upon Tyne. In 1825 he secured appointment as Assay Master to the lords of the manor of Alston. There he was able to pursue the subject of special interest to him, and in January 1829 he devised a method of separating silver from lead ore; however, he was prevented from developing it because of a lack of funds.Two years later he was appointed Manager of Wentworth Beaumont's lead-works. There he was able to continue his researches, which culminated in the patent of 1833 enshrining the invention by which he is best known: a new process for extracting silver from lead by skimming crystals of pure lead with a perforated ladle from the surface of the molten silver-bearing lead, contained in a succession of cast-iron pots. The molten metal was stirred as it cooled until one pot provided a metal containing 300 oz. of silver to the ton (8,370 g to the tonne). Until that time, it was unprofitable to extract silver from lead ores containing less than 8 oz. per ton (223 g per tonne), but the Pattinson process reduced that to 2–3 oz. (56–84 g per tonne), and it therefore won wide acceptance. Pattinson resigned his post and went into partnership to establish a chemical works near Gateshead. He was able to devise two further processes of importance, one an improved method of obtaining white lead and the other a new process for manufacturing magnesia alba, or basic carbonate of magnesium. Both processes were patented in 1841.Pattinson retired in 1858 and devoted himself to the study of astronomy, aided by a 7½ in. (19 cm) equatorial telescope that he had erected at his home at Scot's House.[br]Principal Honours and DistinctionsVice-President, British Association Chemical Section 1838. Fellow of the Geological Society, Royal Astronomical Society and Royal Society 1852.BibliographyPattinson wrote eight scientific papers, mainly on mining, listed in Royal Society Catalogue of Scientific Papers, most of which appeared in the PhilosophicalMagazine.Further ReadingJ.Percy, Metallurgy (volume on lead): 121–44 (fully describes Pattinson's desilvering process).Lonsdale, 1873, Worthies of Cumberland, pp. 273–320 (contains details of his life). T.K.Derry and T.I.Williams, 1960, A Short History ofTechnology, Oxford: Oxford University Press.LRD -
10 Junghans, Siegfried
SUBJECT AREA: Metallurgy[br]b. 1887d. 1954[br]German pioneer of the continuous casting of metals.[br]Junghans was of the family that owned Gebrüder Junghans, one of the largest firms in the German watch-and clockmaking industry. From 1906 to 1918 he served in the German Army, after which he took a course in metallurgy and analytical chemistry at the Technical High School in Stuttgart. Junghans was then given control of the brassworks owned by his family. He wanted to make castings simply and cheaply, but he found that he lacked the normal foundry equipment. By 1927, formulating his ideas on continuous casting, he had conceived a way of overcoming this deficiency and began experiments. By the time the firm was taken over by Wieland-Werke AG in 1931, Junghans had achieved positive results. A test plant was erected in 1932, and commercial production of continuously cast metal followed the year after. Wieland told Junghans that a brassfounder who had come up through the trade would never have hit on the idea: it took an outsider like Junghans to do it. He was made Technical Director of Wielands but left in 1935 to work privately on the development of continuous casting for all metals. He was able to license the process for non-ferrous metals during 1936–9 in Germany and other countries, but the Second World War interrupted his work; however, the German government supported him and a production plant was built. In 1948 he was able to resume work on the continuous casting of steel, which he had been considering since 1936. He pushed on in spite of financial difficulties and produced the first steel by this process at Schorndorf in March 1949. From 1950 he made agreements with four firms to work towards the pilot plant stage, and this was achieved in 1954 at Mannesmann's Huckingen works. The aim of continuous casting is to bypass the conventional processes of casting molten steel into ingots, reheating the ingots and shaping them by rolling them in a large mill. Essentially, in continuous casting, molten steel is drawn through the bottom of a ladle and down through a water-cooled copper mould. The unique feature of Junghans's process was the vertically reciprocating mould, which prevented the molten metal sticking as it passed through. A continuous length of steel is taken off and cooled until it is completely solidified into the required shape. The idea of continuous casting can be traced back to Bessemer, and although others tried to apply it later, they did not have any success. It was Junghans who, more than anybody, made the process a reality.[br]Further ReadingK.Sperth and A.Bungeroth, 1953, "The Junghans method of continuous casting of steel", Metal Treatment and Drop Forging, Mayn.J.Jewkes et al., 1969, The Sources of Invention, 2nd edn, London: Macmillan, pp. 287 ff.LRD -
11 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
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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
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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
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hot-metal-and-scrap process
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hot-type process
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hydrogasification process
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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
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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
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inductoslag-melting process
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ingot casting direct rolling process
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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
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isoentropic process
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isometric process
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isoplanar process
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isothermal process
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iterative process
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jet-expanding process
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Kaldo process
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katadyn process
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Kawasaki-bottom-oxygen-process process
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Kawasaki-Gas-Lime-Injection process
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K-BOP process
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KEK process
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KG-LI process
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kiln-reduction process
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KIVCET cyclone smelting process
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KIVCET process
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knit-deknit process
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koetherizing process
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KR process
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kraft process
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lance bubbling equilibrium process
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LBE process
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LD-AB process
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LD-AC process
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LD-AOD process
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LD-argon bottom process
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LD-argon oxygen decarburization process
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LD-CB process
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LD-circle lance process
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LD-CL process
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LD-combination blow process
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LD-HC top and botton blowing process
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LDK process
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LD-Kawasaki-Gas process
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LD-KG process
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LD-OB process
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LD-OTB process
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LD-oxygen bottom process
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LD-oxygen-top-bottom process
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lift-off process
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liquefaction process
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liquid gas plug process
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liquid-phase process
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loop transfer process
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lost core process
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low-waste technological process
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LSI process
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LVR process
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LVS process
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Mannesmann powder process
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mapping process
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Markovian process
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Markov process
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masking process
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matte fuming process
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melting process
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mercast process
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Midland-Ross process
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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
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monolithic process
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MOS process
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MOSFET process
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motion-picture process
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moving average process
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narrowband random process
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Neely process
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negative-positive process
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Nitemper process
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no pickle process
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nonflow process
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non-Gaussian process
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Nord-Fuvo process
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Nu-iron process
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OBM process
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OG process
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OLP converter process
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one-way process
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open-hearth process
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orbitread process
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ore process
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Orthoflow cracking process
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Orthoforming process
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orthogonal increment process
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oxidation process
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oxide-isolated process
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oxygen-blow process
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oxygen-gas process
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oxygen-lancing process
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oxygen-steelmaking process
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packaging process
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pad-batch dyeing process
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pad-dry dyeing process
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pad-jig dyeing process
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pad-roll dyeing process
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pad-steam dyeing process
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pad-steam vat-print process
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PAMCO-hot-alloy process
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parent process
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PCR process
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Perrin process
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PHA process
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phonon process
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photoelectric process
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photomechanical process
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photovoltaic process
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pig iron-scrap process
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pig-and-ore process
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pigment padding dying process
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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
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plasma process
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plasma-arc process
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Plasmamelt process
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Plasmared process
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plaster mold process
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plastic wirecut process
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polytropic process
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powder silicon ribbon process
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power-press process
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prepolymer process
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prepress processes
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pressure-driven membrane process
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primuline process
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propane-acid process
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pulsating mixing process
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Purex process
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pushbench process
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Q-BOP process
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QDT process
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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
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rapid solidification plasma deposition process
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rayon continuous process
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receiving process
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reclamator reclaiming process
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recurrent process
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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
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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
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R-N direct-reduction process
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roasting-sintering process
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roast-leaching process
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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
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screen printed process
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self-developing process
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self-healing process
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semibatch process
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semiconductor process
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sending process
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Sendzimir coating process
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sequential process
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silicon-gate MOS process
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silicon-gate process
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silk-screen process
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single-pumpdown process
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SIP process
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skein spinning process
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Skinner multiple-hearth process
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slag minimum process
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slip-casting process
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slow down process
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SLPM process
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SL-RN metallization process
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SL-RN reduction process
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solid source diffusion process
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solution regrowth process
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solvent extraction-electrowinning process
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solvent plug process
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SOS process
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spin-draw-texturizing process
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spinylock process
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sponge iron process
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spontaneous process
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Stanal process
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stationary random process
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STB process
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steady-flow process
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steam-blow process
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steelmaking process
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Stelmor process
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step and repeat process
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stochastic process
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stuffer box process
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submerged arc process
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subtractive process
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suck-and-blow process
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Sulf BT process
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Sulfinuz process
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Sumitomo-slag all recycling process
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Sumitomo-top-bottom process
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Sursulf process
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system process
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TBM process
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T-die process
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Technamation process
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thermal DeNOx process
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Therm-i-Vac process
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Thermo-Flow process
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thermoplastic process
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Thomas process
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Thorex process
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three-color process
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Thyssen-blast-metallurgy process
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Tifran process
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tightly coupled processes
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time-varying process
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trichromatic process
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triplex process
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Tropenas converter process
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Tufftride process
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Tufftride TF1 process
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uncertain process
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user process
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vacuum arc remelting process
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vacuum casting process
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vacuum deoxidation process
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vacuum induction refining process
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vacuum stream-droplet process
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vacuum-arc degassing process
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vacuum-carbodeoxidation process
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vacuum-carbonate process
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vacuum-induction melting process
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vacuum-melting process
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vacuum-metallothermic process
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vacuum-oxygen-decarburization process
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VAD process
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VAR process
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VAW process
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VHSIC process
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vigom process
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VIR process
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viscose process
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visual process
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VLSI process
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VOD process
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waiting process
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water gas process
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waterfall process
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wet process
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white-heart process
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Zinal process
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zinc distilling process -
12 LMF
1) Биология: lipid-mobilizing fraction2) Медицина: Митогенный фактор Т-лимфоцитов3) Техника: liquid metal facility, liquid metal fuel4) Религия: LOVE MOTHER and FATHER5) Металлургия: установка внепечной обработки (ladle metallurgy facility), установка доводки металла6) Иммунология: lymphocyte mitogenic factor7) Глоссарий компании Сахалин Энерджи: land management file8) Полимеры: low and medium frequency9) Нефтеперерабатывающие заводы: ТМС (топливо маловязкое судовое)10) Общественная организация: Lake Michigan Federation -
13 pourer
pourer ['pɔ:rə(r)]∎ this teapot isn't a good pourer cette théière verse mal
См. также в других словарях:
Ladle metallurgy — Ladle metallurgy. См. Ковшевая металлургия. (Источник: «Металлы и сплавы. Справочник.» Под редакцией Ю.П. Солнцева; НПО Профессионал , НПО Мир и семья ; Санкт Петербург, 2003 г.) … Словарь металлургических терминов
Ladle — Ladle. См. Ковш. (Источник: «Металлы и сплавы. Справочник.» Под редакцией Ю.П. Солнцева; НПО Профессионал , НПО Мир и семья ; Санкт Петербург, 2003 г.) … Словарь металлургических терминов
ladle — /ˈleɪdl / (say laydl) noun 1. a spoon with a deep bowl, often at an angle to its handle, which is used for serving liquids: a soup ladle. 2. Metallurgy a bucket like container for transferring molten metal. –verb (t) (ladled, ladling) 3. to dip… …
Ladle — may refer to: * Ladle (spoon), a type of spoon used to serve soup and other liquids * Ladle (metallurgy), a foundry ladle used to carry and pour molten metal … Wikipedia
Ladle (metallurgy) — In foundry work a ladle is a container used to transport and pour out molten metals. It needs to be: *Strong enough to contain a heavy load of metal. *Heat resistant like a furnace. *Heat insulated as much as can be managed, to avoid losing heat… … Wikipedia
metallurgy — metallurgic, metallurgical, adj. metallurgically, adv. metallurgist /met l err jist/ or, esp. Brit., /meuh tal euhr jist/, n. /met l err jee/ or, esp. Brit., /meuh tal euhr jee/, n. 1. the technique or science of working or heating metals so as… … Universalium
Lip-pour ladle — Lip pour ladle. См. Литейный ковш. (Источник: «Металлы и сплавы. Справочник.» Под редакцией Ю.П. Солнцева; НПО Профессионал , НПО Мир и семья ; Санкт Петербург, 2003 г.) … Словарь металлургических терминов
Ковшевая металлургия — Ladle metallurgy Ковшевая металлургия. Процесс дегазации для стали, выполняемый в ковше. (Источник: «Металлы и сплавы. Справочник.» Под редакцией Ю.П. Солнцева; НПО Профессионал , НПО Мир и семья ; Санкт Петербург, 2003 г.) … Словарь металлургических терминов
Ковш — Ladle Ковш. Металлический резервуар, футерованный огнеупорами, используемый для транспортировки и заливки расплавленного металла. (Источник: «Металлы и сплавы. Справочник.» Под редакцией Ю.П. Солнцева; НПО Профессионал , НПО Мир и семья ; Санкт… … Словарь металлургических терминов
Литейный ковш — Lip pour ladle Литейный ковш. Ковш, из которого расплавленный металл выливается через край, как вода из ведра. (Источник: «Металлы и сплавы. Справочник.» Под редакцией Ю.П. Солнцева; НПО Профессионал , НПО Мир и семья ; Санкт Петербург, 2003 г.) … Словарь металлургических терминов
steel — steellike, adj. /steel/, n. 1. any of various modified forms of iron, artificially produced, having a carbon content less than that of pig iron and more than that of wrought iron, and having qualities of hardness, elasticity, and strength varying … Universalium