shape+steel

толщина отгружаемого проката

delivery stock height

фасонный прокат — shape steel-rolled stock

прокат квадратного сечения — square stock

рулонный прокат — coiled stock

круглыйь прокат — round stock

сталь

steel

* * *

сталь ж.
steel

азоти́ровать сталь — nitride steel

алити́ровать сталь — aluminize steel

вакууми́ровать сталь — treat (molten) steel under vacuum

вари́ть сталь жарг. — make steel

ворони́ть сталь — blue steel

выплавля́ть сталь — make steel

гофрирова́ть сталь — corrugate steel

закаля́ть сталь — harden steel; ( охлаждать в целях закалки) quench steel

ката́ть сталь в горя́чем состоя́нии — hot-roll steel

ката́ть сталь в холо́дном состоя́нии — cold-roll steel

леги́ровать сталь — alloy steel

нагарто́вывать сталь — work-harden steel

нагрева́ть сталь — reheat steel

науглеро́живать сталь — carburize steel

нормализова́ть сталь — normalize steel

обраба́тывать сталь термомехани́ческий — ausform steel

омедня́ть сталь — copper-plate steel

отжига́ть сталь — anneal steel

отпуска́ть сталь — temper steel

оцинко́вывать сталь — galvanize steel

пакети́ровать сталь — fagot steel

передува́ть сталь — overblow steel

пережига́ть сталь — burn steel

плакирова́ть сталь — clad steel

подверга́ть сталь термообрабо́тке — heat-treat steel

поставля́ть сталь по механи́ческим сво́йствам — market steel on the basis of physical specifications

поставля́ть сталь по хими́ческому соста́ву — market steel on the basis of chemical specifications

продува́ть сталь по́лностью — blow steel fully

разлива́ть сталь (в изло́жницы) — cast steel, pour [teem] steel into moulds

расчисля́ть сталь — deoxidize steel

рифли́ть сталь — checker steel

стабилизи́ровать сталь — stabilize steel

трави́ть сталь — pickle steel

успока́ивать сталь — kill steel

хроми́ровать сталь хими́ческим спо́собом — chromate steel

хроми́ровать сталь электролити́ческим спо́собом — chrome-plate steel

цементи́ровать сталь — case-harden steel

авиацио́нная сталь — aircraft steel

автома́тная сталь — free-cutting steel

алма́зная сталь — extra-hard steel

армату́рная сталь — reinforcing-bar steel; ( вид проката) reinforcing bars

аустени́тная сталь — abstenitic steel

бессеме́ровская сталь — Bessemer steel

бруско́вая сталь уст. — (square) bar steel

быстроре́жущая сталь — high-speed steel

була́тная сталь — Damascus steel, damascene

высоколеги́рованная сталь — high-alloy steel

высокоуглеро́дистая, высокомарганцо́вистая и т. п. сталь — high-carbon, high-manganese, etc. steel

дама́сская сталь — Damascus steel, damascene

дина́мная сталь — dynamo steel

дисперсио́нно-тверде́ющая сталь — precipitation-hardening steel

доэвтекто́идная сталь — hypoeutectoid steel

жаропро́чная сталь — high-temperature steel

жаросто́йкая сталь — heat-resistant steel

заклё́почная сталь — rivet steel

заэвтекто́идная сталь — hypereutectoid steel

износосто́йкая сталь — wear-resisting steel

инструмента́льная сталь — tool steel

квадра́тная сталь — squares

кипя́щая сталь — брит. rimming steel; амер. rimmed steel

ки́слая сталь — acid steel

кислотосто́йкая сталь — acid resisting steel

кла́панная сталь — valve steel

конве́ртерная сталь — converter steel

конструкцио́нная сталь — structural steel

ко́рпусная сталь — hull plate

коррозио́нно-сто́йкая сталь — corrosion-resistant steel

коте́льная сталь — boiler steel

кремни́стая сталь — silicon steel

кру́глая сталь — rounds

леги́рованная сталь — alloyed [alloy-treated] steel

малоуглеро́дистая сталь — low-carbon steel

ма́рганцевая сталь — manganese steel

марте́новская сталь — open-hearth steel

мартенси́тная сталь — martensitic steel

мартенситностаре́ющая сталь — maraging steel

многосло́йная сталь — ply steel

мя́гкая сталь — mild [soft] steel

недораски́сленная сталь — rising steel

нелеги́рованная сталь — plain (carbon) steel

нема́рочная сталь — off-grade steel

нержаве́ющая сталь — stainless steel

низколеги́рованная сталь — low-alloyed steel

низкоуглеро́дистая сталь — low-carbon steel

о́бручная сталь — hoop iron

основна́я сталь — basic steel

перли́тная сталь — pearlitic steel

сталь пове́рхностной прока́ливаемости — shallow-hardening steel

подши́пниковая сталь — bearing steel

полосова́я сталь ( не путать со стально́й полосо́й) — strip steel (not to be confused with steel strip)

полуспоко́йная сталь — semikilled steel

прока́тная, углова́я сталь — angles

прока́тная, углова́я неравнобо́кая сталь — unequal angles

прока́тная, углова́я равнобо́кая сталь — equal angles

проста́я сталь — plain steel

про́фильная сталь — steel shapes

пружи́нная сталь — spring steel

прутко́вая сталь — rod steel; ( вид проката) rods

ре́льсовая сталь — rail steel

ро́слая сталь — rising steel

самозака́ливающаяся сталь — air-hardening steel

сва́рочная сталь — weld steel

сталь сквозно́й прока́ливаемости — through-hardening steel

споко́йная сталь — killed steel

судострои́тельная сталь — shipbuilding steel

текстуро́ванная сталь — grain-oriented steel

ти́гельная сталь — crucible steel

толстолистова́я сталь — plate steel; ( вид проката) (steel) plate

толстолистова́я, фасо́нная сталь — sketch plate(s)

тонколистова́я сталь — sheet steel; ( вид проката) steel sheet

то́почная сталь — fire-box steel

трансформа́торная сталь — transformer steel

тру́бная сталь — pipe steel

углеро́дистая сталь — carbon steel

фасо́нная сталь — structural shape(s)

ферри́тная сталь — ferritic steel

хро́мистая сталь — chromium steel

цеме́нтная сталь — cement steel

шве́ллерная сталь — channels

шестигра́нная сталь — hexagonal steel, hexagons

шта́мповая сталь — die steel

штри́псовая сталь — skelp steel

электри́ческая сталь — electrical steel (см. тж. электросталь)

электротехни́ческая сталь — electrical-sheet [silicon-sheet] steel

искажение профиля

shape deterioration

фасонный профиль — shape

профиль волока — shape die

профиль стали — steel shape

профиль труба — shaped tube

профиль канавки — groove shape

стальной профиль

steel section

профиль проката — section

профиль стали — steel shape

профиль окна — window section

профиль рельса — rail section

тонкий профиль — thin section

профиль стали

steel shape

сортовая сталь

steel shape

çelik profili

steel shape

фасонная сталь

1) Naval: fashion

2) Engineering: shape, structural shape, structural shapes

3) Construction: shaped bars

4) Automobile industry: section, section iron, shaped iron

5) Mechanics: figured steel

6) Automation: fashioned iron, fashioned steel, figured iron

7) Makarov: section steel, shaped steel, steel shape

сортовая сталь

1) Naval: section iron, shape iron

2) Engineering: section, steel bar, steel shape

3) Construction: finished iron, profiled iron, profiled steel, section steel, sectional steel

4) Railway term: structural steel

5) Automobile industry: shaped iron

6) Oil: commercial steel

7) Automation: fashioned steel

8) Cement: structural-grade steel

Baustahl

m < mat> (Stahlprofile; z.B. L, T, U, I) ■ structural steel; sectional steel; steel shape

m < metall> (0,03% bis 0,2% Kohlenstoff; ein relativ weicher Massenstahl) ■ structural steel; low-carbon steel; plain carbon steel; carbon steel pract ; structural carbon steel

m < metall> (mittlerer C-Gehalt; 0,3 - 0,55 % C; für Maschinenbauzwecke) ■ medium-carbon steel; machinery steel

Baustahl

m

1. construction steel

2. mild steel

m

[mittlerer Kohlenstoffgehalt]

machinery steel

m

[niedriger Kohlenstoffgehalt]

1. carbon steel coll.

2. low-carbon steel

3. plain carbon steel

4. structural (carbon) steel

m

[Stahlprofile]

1. sectional steel

2. steel shape

(Stahlprofile)

structural steel

профиль сталь

1. merchant steel

литая сталь — cast steel

кислая сталь — acid steel

покрытый сталью — steeled

сталь армко — armco steel

сталь для ЗК — gear steel

2. steel shape

никелированная сталь — nickel-clad steel

светлотянутая сталь — bright-drawn steel

упругоподатливая сталь — resilient steel

холоднокатаная сталь — cold-rolled steel

цементуемая сталь — case-hardening steel

acier profilé

m

1) rolled shape

2) rolled steel section, steel section, structural shape, shear steel

Junghans, Siegfried

SUBJECT AREA: Metallurgy

[br]

b. 1887

d. 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 Reading

K.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

предварительный профиль

first shape

фасонный профиль — shape

профиль волока — shape die

профиль стали — steel shape

профиль труба — shaped tube

профиль канавки — groove shape

сложный профиль

intricate shape

фасонный профиль — shape

профиль волока — shape die

профиль стали — steel shape

профиль труба — shaped tube

профиль канавки — groove shape

штампованный профиль

formed shape

фасонный профиль — shape

профиль волока — shape die

профиль стали — steel shape

профиль труба — shaped tube

профиль канавки — groove shape

شكل

شَكَّلَ \ constitute: to make up: Seven days constitute a week. form: to shape or make: The children formed a circle round her. I formed a good opinion of him. make up: to form jointly: This machine is made up of sixty different parts. Let’s make up a team to play football. model: to shape sth: We enjoy modelling (animals) out of clay in our art lessons. (modelar). mould (mold): to form a soft material into a certain shape: He moulded the clay into the form of a man’s head. shape: to give (sth.) a form: The potter shaped the clay with his fingers. \ See Also كون (كَوَّنَ)‏ \ شَكَّل الحديد بالإحماء والطّرق \ forge: to shape (an iron or steel object) by hammering it when it is hot.

Alleyne, Sir John Gay Newton

SUBJECT AREA: Metallurgy

[br]

b. 8 September 1820 Barbados

d. 20 February 1912 Falmouth, Cornwall, England

[br]

English iron and steel manufacturer, inventor of the reversing rolling mill.

[br]

Alleyne was the heir to a baronetcy created in 1769, which he succeeded to on the death of his father in 1870. He was educated at Harrow and at Bonn University, and from 1843 to 1851 he was Warden at Dulwich College, to the founder of which the family claimed to be related.

Alleyne's business career began with a short spell in the sugar industry at Barbados, but he returned to England to enter Butterley Iron Works Company, where he remained for many years. He was at first concerned with the production of rolled-iron girders for floors, especially for fireproof flooring, and deck beams for iron ships. The demand for large sections exceeded the capacity of the small mills then in use at Butterley, so Alleyne introduced the welding of T-sections to form the required H-sections.

In 1861 Alleyne patented a mechanical traverser for moving ingots in front of and behind a rolling mill, enabling one person to manipulate large pieces. In 1870 he introduced his major innovation, the two-high reversing mill, which enabled the metal to be passed back and forth between the rolls until it assumed the required size and shape. The mill had two steam engines, which supplied the motion in opposite directions. These two inventions produced considerable economies in time and effort in handling the metal and enabled much heavier pieces to be processed.

During Alleyne's regime, the Butterley Company secured some notable contracts, such as the roof of St Paneras Station, London, in 1868, with the then-unparalleled span of 240 ft (73 m). The manufacture and erection of this awe-inspiring structure was a tribute to Alleyne's abilities. In 1872 he masterminded the design and construction of the large railway bridge over the Old Maas at Dordrecht, Holland. Alleyne also devised a method of determining small quantities of phosphorus in iron and steel by means of the spectroscope. In his spare time he was a skilled astronomical observer and metalworker in his private workshop.

[br]

Bibliography

1875, "The estimation of small quantities of phosphorus in iron and steel by spectrum analysis", Journal of the Iron and Steel Institute: 62.

Further Reading

Obituary, 1912, Journal of the Iron and Steel Institute: 406–8.

LRD

Gibbons, John

SUBJECT AREA: Metallurgy

[br]

fl. 1800–50 Staffordshire, England

[br]

English ironmaster who introduced the round hearth in the blastfurnace.

[br]

Gibbons was an ironmaster in the Black Country, South Staffordshire, in charge of six blast furnaces owned by the family business. Until Gibbons's innovation in 1832, small changes in the form of the furnace had at times been made, but no one had seriously questioned the square shape of the hearth. Gibbons noticed that a new furnace often worked poorly by improved as time went on. When it was "blown out", i.e. taken out of commission, he found that the corners of the hearth had been rounded off and the sides gouged out, so that it was roughly circular in shape. Gibbons wisely decided to build a blast furnace with a round hearth alongside an existing one with a traditionally shaped hearth and work them in exactly the same conditions. The old furnace produced 75 tons of iron in a week, about normal for the time, while the new one produced 100 tons. Further improvements followed and in 1838 a fellow ironmaster in the same district, T. Oakes, considerably enlarged the furnace, its height attaining no less than 60ft (18m). As a result, output soared to over 200 tons a week. Most other ironmasters adopted the new form with enthusiasm and it proved to be the basis for the modern blast furnace. Gibbons made another interesting innovation: he began charging his furnace with the "rubbish", slag or cinder, from earlier ironmaking operations. It contained a significant amount of iron and was cheaper to obtain than iron ore, as it was just lying around in heaps. Some ironmasters scorned to use other people's throw-outs, but Gibbons sensibly saw it as a cheap source of iron; it was a useful source for some years during the nineteenth century but its use died out when the heaps were used up. Gibbons published an account of his improvements in ironmaking in a pamphlet entitled Practical Remarks on the Construction of the Staffordshire Blast Furnace.

[br]

Bibliography

1839, Practical Remarks on the Construction of the Staffordshire Blast Furnace, Birmingham; reprinted 1844.

Further Reading

J.Percy, 1864, Metallurgy. Iron and Steel, London, p. 476. W.K.V.Gale, 1969, Iron and Steel, London: Longmans, pp. 44–6.

LRD