-
1 конструкционный материал
1) Naval: construction material2) Engineering: constructional material, engineering material, structural material3) Metallurgy: bearing material4) Industrial economy: engineering structural material5) Automation: architectural material, material of construction6) Quality control: hardware materialУниверсальный русско-английский словарь > конструкционный материал
-
2 конструкционный материал
Русско-английский словарь по машиностроению > конструкционный материал
-
3 материал
fabric, absorbent material, material, matter, medium, stuff, substance* * *материа́л м.1. material2. ( сырьё) stockабрази́вный материа́л — abrasive (material)классифици́ровать абрази́вный материа́л (напр. методом ситового анализа) — grade an abrasive (material) (e. g., by the use of screens or sieves)автокла́вный материа́л — steam-cured [steam(-and-pressure) cured] materialагломери́рованный материа́л — sintered materialакти́вный материа́л — active material1. ( для лазеров) laser [lasing] material, laser [lasing] mediumвыра́щивать акти́вный материа́л (напр. из расплава) — grow a laser material (e. g., from melt)2. ( для мазеров) maser [masing] material, maser [masing] mediumакусти́ческий материа́л — acoustical materialамортизи́рующий материа́л — damping materialанизотро́пный материа́л — anisotropic materialантикоррозио́нный материа́л — anticorrosive materialасбе́стовый руло́нный материа́л — asbestos blanketасбестоцеме́нтный материа́л — cementitious [asbestos-cement] materialби́тумный материа́л — asphaltic material, asphaltic productбуто́вочный материа́л — fillerвиброизоляцио́нный материа́л — vibrated insulating materialвоздухововлека́ющий материа́л — air-entraining agentволокни́стый материа́л — fibrous materialволокно́вый материа́л ( в порошковой металлургии) — fibrous materialвоспламеня́ющийся материа́л — inflammable materialвоспроизводя́щий материа́л яд. физ. — breeder materialвсплыва́ющий материа́л — floatable materialвспомога́тельный материа́л1. физ. accessory material2. ( для уплотнения) auxiliary materialвспу́чивающий материа́л — bloating agent, bloaterматериа́л в технологи́ческом проце́ссе — in-process materialвысокоогнеупо́рный материа́л — high refractoryвысу́шиваемый материа́л — dryable materialвя́жущий материа́л — binding material, binderвя́жущий, возду́шный материа́л — airbinderвя́жущий, гидравли́ческий материа́л — hydraulic binding materialвя́жущий, ги́псовый материа́л — alabaster binding materialвя́жущий, магнезиа́льный материа́л — magnesia binding materialвя́жущий, минера́льный материа́л — mineral binding materialвя́жущий, органи́ческий материа́л — organic binding materialвязкоупру́гий материа́л — viscoelastic materialгерметизи́рующий материа́л — sealing material; ( обволакивающий) encapsulant; ( заливающий) potting compoundгидроизоляцио́нный материа́л — hydraulic insulating materialгорю́чий материа́л — combustible materialгу́бчатый материа́л — sponge materialдефици́тный материа́л — scarce materialдиспе́рсно-упрочнё́нный материа́л — dispersion-hardened materialдиэлектри́ческий материа́л — dielectricматериа́л для уплотне́ния швов — joint-sealing materialматериа́л для я́дерного реа́ктора — nuclear [pile] materialдо́норный материа́л — donor materialдоро́жно-строи́тельный материа́л — roadbuilding materialдуби́льный материа́л — tanning materialжаропро́чный материа́л — high-temperature [beat-proof] materialжаросто́йкий материа́л — beat-resisting materialжё́сткий материа́л — inflexible [rigid, stiff] materialжирова́льный материа́л — tanner grease, tanning oilзакла́дочный материа́л горн. — stowage materialзапра́вочный материа́л — fettling material; ( в производстве огнеупоров) make-up materialзащи́тный материа́л яд. физ. — shielding [protective] materialзвукозаглуша́ющий материа́л — sound-damping materialзвукоизоляцио́нный материа́л — sound insulator, sound-insulating materialзвукоизоляцио́нный, нама́зываемый материа́л — troweled-on acoustical materialзвукоизоляцио́нный, напыля́емый материа́л — sprayed-on acoustical materialзвукопоглоща́ющий материа́л — sound-absorbing material, acoustical absorbentзвукопоглоща́ющий, моноли́тный материа́л — monolithic sound-acoustical materialзерни́стый материа́л — granular materialизоляцио́нный материа́л — insulating material, insulator, insulatingизотро́пный материа́л — isotropic materialине́ртный материа́л — inert materialинструмента́льный материа́л — tool materialионообме́нный материа́л — ion-exchange materialисхо́дный материа́л — source materialкерами́ческий материа́л1. ceramic [sintered] material2. ( изделие) стр. (structural) clay productкислотосто́йкий материа́л — acid-proof materialкислотоупо́рный материа́л — acid-proof materialклассифици́рованный материа́л — classified [graded] materialкоксу́ющийся уноси́мый материа́л — charring ablative materialкомпозицио́нный материа́л — composite materialконструкцио́нный материа́л — structural material, material of constructionконструкцио́нный, неру́дный материа́л — nonmetallic construction of materialконта́ктный материа́л — contact materialкоррозионносто́йкий материа́л — corrosion-resistant [rust-resisting] materialкристалли́ческий материа́л — crystalline materialкро́вельный материа́л — roofing materialкро́вельный, руло́нный материа́л — roll (roofing) materialкро́ющий материа́л — covering material, coatingкусково́й материа́л — lump materialлакокра́сочный материа́л — paintwork materialлитьево́й материа́л — (injection-)moulding materialлюминесци́рующий материа́л — fluorescent materialмагни́тно-жё́сткий материа́л — hard magnetic materialмагни́тно-мя́гкий материа́л — soft magnetic materialмагни́тно-твё́рдый материа́л — hard magnetic materialмагни́тный материа́л — magnetic materialмагнитоопти́ческий материа́л — magneto-opticmaterialмагнитострикцио́нный материа́л — magnetostrictive materialмаслосто́йкий материа́л — oil-resistant materialма́тричный материа́л полигр. — flongмашинострои́тельный материа́л — engineering materialметаллокерами́ческий материа́л — cement, sintered powder metalметаллокерами́ческий, магни́тный материа́л — magnetic cermetметаллокерами́ческий, по́ристый материа́л — porous cermetметаллокерами́ческий, фрикцио́нный материа́л — friction cermetмногосло́йный материа́л — multilayer materialмо́лотый материа́л — comminuted [ground] materialморозосто́йкий материа́л — frost-proof materialнаби́вочный материа́л — ( уплотнительный) packing, stuffing; ( подливочный) paddingнабо́рный материа́л — type matterматериа́л нава́лом — bulk materialматериа́л накла́дки — facing [lining] materialнасыпно́й материа́л — bulk materialнеакти́вный материа́л — inert materialневоспламеня́ющийся материа́л — non-flammable materialнегати́вный материа́л кфт. — negative materialнемагни́тный материа́л — non-magnetic materialнеметалли́ческий материа́л — non-metallic materialнеодноро́дный материа́л — heterogeneous materialнепо́ристый материа́л — non-porous materialнесжима́емый материа́л — incompressible materialнизкосо́ртный материа́л — low-grade materialобё́рточный материа́л — wrapping material, wrap (per)обжига́емый материа́л — calcinable materialоби́вочный материа́л — upholstery materialобкла́дочный материа́л полигр. — furnitureоблицо́вочный материа́л — ( внешний) facing material; ( внутренний) lining materialобогащё́нный материа́л — enriched materialобрабо́танный материа́л — finished stock, finished materialобти́рочный материа́л — cleaning [wiping] material, wiping ragsогнезащи́тный материа́л — fire-proof materialогнесто́йкий материа́л — fire-resistant materialогнеупо́рный материа́л — refractoryогнеупо́рный, торкрети́рованный материа́л — sprayed refractoryоднокомпоне́нтный материа́л — single materialодноро́дный материа́л — homogeneous materialоднофа́зовый материа́л — single-phase materialозоносто́йкий материа́л — ozone-resisting materialоптоакусти́ческий материа́л — optoacoustic materialоседа́ющий материа́л — settling materialматериа́л основа́ния печа́тной пла́ты — base materialотде́лочный материа́л — leather finishing agentпарамагни́тный материа́л — paramagnetic materialперви́чный материа́л — raw materialпеча́тный материа́л полигр. — printed matterпласти́чный материа́л — plastic materialподкисля́ющий материа́л — acidifierподкле́ечный материа́л — adhesive backerпо́довый материа́л — bottoms materialподо́швенный материа́л кож. — solingподсо́бный материа́л — incidental materialподшихто́вочный материа́л — feed-adjusting [charge-adjusting] materialпозити́вный материа́л кфт. — positive materialполиме́рный материа́л — polymeric materialполирова́льный материа́л — polish, polishing compoundполупроводнико́вый материа́л — semiconducting [semiconductor] materialпо́ристый материа́л — porous materialпорошкообра́зный материа́л — powder(ed) materialпоса́дочный материа́л — planting stockпосевно́й материа́л — seed grain, seedsприро́дный материа́л — natural materialприса́дочный материа́л — filler materialпробе́льный материа́л — spacing materialпробе́льный и обкла́дочный материа́л — furnitureпробе́льный, междустро́чный материа́л — leadsпробе́льный, поло́сный материа́л — leads and slogsпробе́льный, стро́чной материа́л — quads and spacesпроводнико́вый материа́л — conducting materialпроизво́дственные, вспомога́тельные материа́лы — indirect materialsпроизво́дственные, основны́е материа́лы — direct materialsпрока́тный материа́л — rolled stockпрокла́дочный материа́л — sealing [packing, leak-proofing] materialпротивоприга́рный материа́л литейн. — parting material, parting paintпро́фильный материа́л — section material, sections, shapes; ( полученный методом прессования) extrusionsпрутко́вый материа́л — bar material, bar stockпсевдопласти́чный материа́л — pseudo-plastic materialпьезорезисти́вный материа́л — piezoresistive materialрекла́мный материа́л — advertising matterсверхпроводя́щий материа́л — superconductorсветочувстви́тельный материа́л кфт. — light-sensitive materialсегнетоэлектри́ческий материа́л — ferroelectric materialсеменно́й материа́л — seed grain, seedsматериа́л с избира́тельным поглоще́нием — frequency-selective damping materialсиликатобето́нный материа́л — silicate concrete materialскле́иваемый материа́л — adherendсланцезо́льный материа́л — ash-shale [cinder-shale] materialслежа́вшийся материа́л — packed materialсма́зочный материа́л — lubricantсма́зочный, идеа́льный материа́л — ideal lubricantсма́зочный, промы́шленный материа́л — industrial lubricantсма́зочный материа́л с противозади́рной приса́дкой — anti-galling [anti-scoring] lubricantматериа́л с ма́лым коэффицие́нтом расшире́ния — low-expansion materialсме́шиваемый материа́л ( способный смешиваться с другим) — miscible materialматериа́л с непрямоуго́льной петлё́й (гистере́зиса) — non-square-loop materialсоставно́й материа́л — composite materialспечё́нный материа́л — sintered materialматериа́л с прямоуго́льной петлё́й (гистере́зиса) — square-loop [square BH-loop] materialматериа́л с со́бственной проводи́мостью — intrinsic materialстекловолокни́стый материа́л — glass-fibre materialстрои́тельный материа́л — building materialматериа́л с у́зкой запрещё́нной зо́ной — narrow-gap materialматериа́л с широ́кой запрещё́нной зо́ной — wide-gap materialсыпу́чий материа́л — loose [granular] materialсыро́й материа́л — raw materialта́рный материа́л — container materialтеплозащи́тный уноси́мый материа́л — ablative beat shield materialтеплоизоляцио́нный материа́л — beat-insulating materialтермомагни́тный материа́л — thermomagnetimaterialтермопласти́чный материа́л — thermoplastic materialтонколистово́й материа́л — sheet materialтонкоплё́ночный материа́л — thin-film materialтрасси́рующий материа́л ( в дефектоскопии) — flaw-detecting materialупако́вочный материа́л — packaging materialуплотня́ющий материа́л — sealing [packing, leak-proofing] material, sealantупру́гий материа́л — elastic materialупру́го-пласти́ческий материа́л — elasto-plastic materialустано́вочные материа́лы — wiring accessoriesфа́зовый материа́л — phase materialферромагни́тный материа́л — ferromagnetic materialфильтру́ющий материа́л — filter mediumфлоти́рующийся материа́л — flotable materialфлюсу́ющий материа́л — fluxing agentформо́вочный материа́л — moulding materialфотографи́ческий материа́л — photographic materialфотоупру́гий материа́л — photoelastic materialфотоэмиссио́нный материа́л — photoemissive materialфутеро́вочный материа́л — lining materialхру́пкий материа́л — brittle materialшиноремо́нтный материа́л — tyre repair materialши́хтовый твё́рдый материа́л — cold-charge [solid charge] materialшлакобразу́ющий материа́л — slag-forming materialшлифова́льный материа́л — grinding materialштукату́рный отде́лочный материа́л — fine stuffщёлочесто́йкий материа́л — alkali-resisting materialэкрани́рующий материа́л — shielding materialэлектроизоляцио́нный материа́л — electrical insulating materialэлектроопти́ческий материа́л — electrooptic materialэлектропроводя́щий материа́л — current-conducting materialэлектротехни́ческий материа́л — electrotechnical material -
4 конструкционный материал
Русско-английский политехнический словарь > конструкционный материал
-
5 строительный материал
1) Engineering: building material, constructional material, fabric2) Mathematics: structural material3) Railway term: engineering material4) Business: construction material5) Automation: material of construction6) Gold mining: industrial mineralУниверсальный русско-английский словарь > строительный материал
-
6 керамический материал
1. ceramic materialпечатный материал, подсчитываемый по площади — area material
2. стр. clay productлистовой материал — sheet material; plate material
облицовочный материал — facing material; lining material
Русско-английский большой базовый словарь > керамический материал
-
7 Nervi, Pier Luigi
[br]b. 21 June 1891 Sondrio, Italyd. 9 January 1979 (?), Italy[br]Italian engineer who played a vital role in the use and adaptation of reinforced concrete as a structural material from the 1930s to the 1970s.[br]Nervi early established a reputation in the use of reinforced concrete with his stadium in Florence (1930–2). This elegant concrete structure combines graceful curves with functional solidity and is capable of seating some 35,000 spectators. The stadium was followed by the aircraft hangars built for the Italian Air Force at Orvieto and Ortebello, in which he spanned the vast roofs of the hangars with thin-shelled vaults supported by precast concrete beams and steel-reinforced ribs. The structural strength and subtle curves of these ribbed roofs set the pattern for Nervi's techniques, which he subsequently varied and elaborated on to solve problems that arose in further commissions.Immediately after the Second World War Italy was short of supplies of steel for structural purposes so, in contrast to the USA, Britain and Germany, did not for some years construct any quantity of steel-framed rectangular buildinngs used for offices, housing or industrial use. It was Nervi who led the way to a ferroconcrete approach, using a new type of structure based on these materials in the form of a fine steel mesh sprayed with cement mortar and used to roof all kinds of structures. It was a method that resulted in expressionist curves instead of rectangular blocks, and the first of his great exhibition halls at Turin (1949), with a vault span of 240 ft (73 m), was an early example of this technique. Nervi continued to create original and beautiful ferroconcrete structures of infinite variety: for example, the hall at the Lido di Roma, Ostia; the terme at Chianciano; and the three buildings that he designed for the Rome Olympics in 1960. The Palazzetto dello Sport is probably the most famous of these, for which he co-operated with the architect Annibale Vitellozzi to construct a small sports palace seating 5,000 spectators under a concrete "big top" of 194 ft (59 m) diameter, its enclosing walls supported by thirtysix guy ropes of concrete; inside, the elegant roof displays a floral quality. In 1960 Nervi returned to Turin to build his imaginative Palace of Labour for the centenary celebrations of Garibaldi and Victor Emmanuel in the city. This vast hall, like the Crystal Palace in England a century earlier (see Paxton), had to be built quickly and be suitable for later adaptation. It was therefore constructed partly in steel, and the metal supporting columns rose to palm-leaf capitals reminiscent of those in ancient Nile palaces.Nervi's aim was always to create functional buildings that simultaneously act by their aesthetic qualities as an effective educational influence. Functionalism for Nervi never became "brutalism". In consequence, his work is admired by the lay public as well as by architects. He collaborated with many of the outstanding architects of the day: with Gio Ponti on the Pirelli Building in Milan (1955–9); with Zehrfuss and Breuer on the Y-plan UNESCO Building in Paris (1953–7); and with Marcello Piacentini on the 16,000-seat Palazzo dello Sport in Rome. Nervi found time to write a number of books on building construction and design, lectured in the Universities of Rio de Janiero and Buenos Aires, and was for many years Professor of Technology and Technique of Construction in the Faculty of Architecture at the University of Rome. He continued to design new structures until well into the 1970s.[br]Principal Honours and DistinctionsRIBA Royal Gold Medal 1960. Royal Institute of Structural Engineers Gold Medal 1968. Honorary Degree Edinburgh University, Warsaw University, Munich University, London University, Harvard University. Member International Institute of Arts and Letters, Zurich; American Academy of Arts and Sciences; Royal Academy of Fine Arts, Stockholm.Bibliography1956, Structures, New York: Dodge.1945, Scienza o Arte del Costruire?, Rome: Bussola.Further ReadingP.Desideri et al., 1979, Pier Luigi Nervi, Bologna: Zanichelli.A.L.Huxtable, 1960, Masters of World Architecture; Pier Luigi Nervi, New York: Braziller.DY -
8 Hennébique, François
[br]b. 25 April 1842 Neuville-Saint-Vaast, near Arras, Franced. 20 March 1921 Paris, France[br]French engineer who contributed to the development of reinforced concrete.[br]Hennébique was an important leader in experimenting with various ways of reinforcing concrete with iron and steel. He set up his own firm in 1867, so acquiring valuable experience in the number of commissions that he carried out when using this material. He patented his own invention in 1892; this was for a method of using hooked connections for reinforcing-bars of iron and steel. England lagged behind France in developing the use of reinforced concrete as a structural material: it was Hennébique who was most influential in changing this situation. He had used his new method of reinforcement in the construction of the Spinning Mills at Tourcoing in France in 1895, and he was commissioned by Weaver \& Co., who wished to build a new flour mill in Swansea: the mill was completed in 1898. Soon after, both Hennébique and Coignet established London offices for developing their constructional techniques in England.[br]Further ReadingLe Béton armé 1898–1921 (monthly journal published by the Hennébique Company in Paris).P.Collins, 1959, Concrete: A Vision of a New Architecture (a study of Auguste Perret and his predecessors), Faber.C.C.Stanley, 1979, Highlights in the History of Concrete, Cement and Concrete Association.DY -
9 сопротивление материалов
1) Naval: resistance of materials, strength of material2) Engineering: structural resistance3) Rare: antitypy4) Construction: mechanics of materials, theory of strength of materials5) Mathematics: strength of materials6) Atomic energy: strength of the materialsУниверсальный русско-английский словарь > сопротивление материалов
-
10 Bessemer, Sir Henry
SUBJECT AREA: Metallurgy[br]b. 19 January 1813 Charlton (near Hitchin), Hertfordshire, Englandd. 15 January 1898 Denmark Hill, London, England[br]English inventor of the Bessemer steelmaking process.[br]The most valuable part of Bessemer's education took place in the workshop of his inventor father. At the age of only 17 he went to London to seek his fortune and set himself up in the trade of casting art works in white metal. He went on to the embossing of metals and other materials and this led to his first major invention, whereby a date was incorporated in the die for embossing seals, thus preventing the wholesale forgeries that had previously been committed. For this, a grateful Government promised Bessemer a paid position, a promise that was never kept; recognition came only in 1879 with a belated knighthood. Bessemer turned to other inventions, mainly in metalworking, including a process for making bronze powder and gold paint. After he had overcome technical problems, the process became highly profitable, earning him a considerable income during the forty years it was in use.The Crimean War presented inventors such as Bessemer with a challenge when weaknesses in the iron used to make the cannon became apparent. In 1856, at his Baxter House premises in St Paneras, London, he tried fusing cast iron with steel. Noticing the effect of an air current on the molten mixture, he constructed a reaction vessel or converter in which air was blown through molten cast iron. There was a vigorous reaction which nearly burned the house down, and Bessemer found the iron to be almost completely decarburized, without the slag threads always present in wrought iron. Bessemer had in fact invented not only a new process but a new material, mild steel. His paper "On the manufacture of malleable iron and steel without fuel" at the British Association meeting in Cheltenham later that year created a stir. Bessemer was courted by ironmasters to license the process. However, success was short-lived, for they found that phosphorus in the original iron ore passed into the metal and rendered it useless. By chance, Bessemer had used in his trials pig-iron, derived from haematite, a phosphorus-free ore. Bessemer tried hard to overcome the problem, but lacking chemical knowledge he resigned himself to limiting his process to this kind of pig-iron. This limitation was removed in 1879 by Sidney Gilchrist Thomas, who substituted a chemically basic lining in the converter in place of the acid lining used by Bessemer. This reacted with the phosphorus to form a substance that could be tapped off with the slag, leaving the steel free from this harmful element. Even so, the new material had begun to be applied in engineering, especially for railways. The open-hearth process developed by Siemens and the Martin brothers complemented rather than competed with Bessemer steel. The widespread use of the two processes had a revolutionary effect on mechanical and structural engineering and earned Bessemer around £1 million in royalties before the patents expired.[br]Principal Honours and DistinctionsKnighted 1879. FRS 1879. Royal Society of Arts Albert Gold Medal 1872.Bibliography1905, Sir Henry Bessemer FRS: An Autobiography, London.LRD -
11 керамический материал
1) Engineering: body, ceramic material2) Construction: clay product (изделие), structural clay product (изделие)3) Railway term: stoneware4) Astronautics: ceramics, sintered material5) Silicates: ceramic bodyУниверсальный русско-английский словарь > керамический материал
-
12 Perret, Auguste
[br]b. 12 February 1874 Ixelles, near Brussels, Belgiumd. 26 February 1954 Le Havre (?), France[br]French architect who pioneered and established building design in reinforced concrete in a style suited to the modern movement.[br]Auguste Perret belonged to the family contracting firm of A. \& G.Perret, which early specialized in the use of reinforced concrete. His eight-storey building at 25 bis Rue Franklin in Paris, built in 1902–3, was the first example of frame construction in this material and established its viability for structural design. Both ground plan and façade are uncompromisingly modern, the simplicity of the latter being relieved by unobtrusive faience decoration. The two upper floors, which are set back, and the open terrace roof garden set a pattern for future schemes. All of Perret's buildings had reinforced-concrete structures and this was clearly delineated on the façade designs. The concept was uncommon in Europe at the time, when eclecticism still largely ruled, but was derived from the late nineteenth-century skyscraper façades built by Louis Sullivan in America. In 1905–6 came Perret's Garage Ponthieu in Paris; a striking example of exposed concrete, it had a central façade window glazed in modern design in rich colours. By the 1920s ferroconcrete was in more common use, but Perret still led the field in France with his imaginative, bold use of the material. His most original structure is the Church of Notre Dame at Le Raincy on the outskirts of Paris (1922–3). The imposing exterior with its tall tower in diminishing stages is finely designed, but the interior has magnificence. It is a wide, light church, the segmented vaulted roof supported on slender columns. The whole structure is in concrete apart from the glass window panels, which extend the full height of the walls all around the church. They provide a symphony of colour culminating in deep blue behind the altar. Because of the slenderness of the columns and the richness of the glass, this church possesses a spiritual atmosphere and unimpeded sight and sound of and from the altar for everyone. It became the prototype for churches all over Europe for decades, from Moser in prewar Switzerland to Spence's postwar Coventry Cathedral.In a long working life Perret designed buildings for a wide range of purposes, adhering to his preference for ferroconcrete and adapting its use according to each building's needs. In the 1940s he was responsible for the railway station at Amiens, the Atomic Centre at Saclay and, one of his last important works, the redevelopment after wartime damage of the town centre of Le Havre. For the latter, he laid out large open squares enclosed by prefabricated units, which display a certain monotony, despite the imposing town hall and Church of St Joseph in the Place de L'Hôtel de Ville.[br]Principal Honours and DistinctionsPresident des Réunions Internationales des Architectes. American Society of the French Legion of Honour Gold Medal 1950. Elected after the Second World War to the Institut de France. First President of the International Union of Architects on its creation in 1948. RIBA Royal Gold Medal 1948.Further ReadingP.Blater, 1939, "Work of the architect A.Perret", Architektura SSSR (Moscow) 7:57 (illustrated article).1848 "Auguste Perret: a pioneer in reinforced concrete", Civil Engineers' Review, pp.296–300.Peter Collins, 1959, Concrete: The Vision of a New Architecture: A Study of Auguste Perret and his Precursors, Faber \& Faber.Marcel Zahar, 1959, D'Une Doctrine d'Architecture: Auguste Perret, Paris: Vincent Fréal.DY -
13 Monier, Joseph
[br]b. 1823 Franced. 1906 Paris, France[br]French gardener and one of the principal inventors of reinforced concrete.[br]Monier was a commercial gardener who in the course of his work was struck with the idea of inserting iron reinforcement in concrete tubs such as were used for growing orange trees. He patented this idea in 1867 and exhibited his invention the same year at the Paris Exposition. It soon occurred to him to apply the same principles to other engineering structures such as railway sleepers, pipes, floors, arches and bridges. In 1878 he took out a French patent for reinforced concrete beams and held numerous other patents for the material. Although he was not the only one to realize the benefits of combining a concrete girder or slab to resist compressive forces with iron or steel wires or rods to resist tensile stresses, "Das System Monier" was known as such by 1887 throughout Europe.[br]Further ReadingJ.W.De Courcy, 1987, "The emergence of reinforced concrete", Structural Engineer 65A: 316.IMcN -
14 Sellers, William
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 19 September 1824 Upper Darby, Pennsylvania, USAd. 24 January 1905 Philadelphia, Pennsylvania, USA[br]American mechanical engineer and inventor.[br]William Sellers was educated at a private school that had been established by his father and other relatives for their children, and at the age of 14 he was apprenticed for seven years to the machinist's trade with his uncle. At the end of his apprenticeship in 1845 he took charge of the machine shop of Fairbanks, Bancroft \& Co. in Providence, Rhode Island. In 1848 he established his own factory manufacturing machine tools and mill gearing in Philadelphia, where he was soon joined by Edward Bancroft, the firm becoming Bancroft \& Sellers. After Bancroft's death the name was changed in 1856 to William Sellers \& Co. and Sellers served as President until the end of his life. His machine tools were characterized by their robust construction and absence of decorative embellishments. In 1868 he formed the Edgemoor Iron Company, of which he was President. This company supplied the structural ironwork for the Centennial Exhibition buildings and much of the material for the Brooklyn Bridge. In 1873 he reorganized the William Butcher Steel Works, renaming it the Midvale Steel Company, and under his presidency it became a leader in the production of heavy ordnance. It was at the Midvale Steel Company that Frederick W. Taylor began, with the encouragement of Sellers, his experiments on cutting tools.In 1860 Sellers obtained the American rights of the patent for the Giffard injector for feeding steam boilers. He later invented his own improvements to the injector, which numbered among his many other patents, most of which related to machine tools. Probably Sellers's most important contribution to the engineering industry was his proposal for a system of screw threads made in 1864 and later adopted as the American national standard.Sellers was a founder member in 1880 of the American Society of Mechanical Engineers and was also a member of many other learned societies in America and other countries, including, in Britain, the Institution of Mechanical Engineers and the Iron and Steel Institute.[br]Principal Honours and DistinctionsChevalier de la Légion d'honneur 1889. President, Franklin Institute 1864–7.Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (describes Sellers's work on machine tools).Bruce Sinclair, 1969, "At the turn of a screw: William Sellers, the Franklin Institute, and a standard American thread", Technology and Culture 10:20–34 (describes his work on screw threads).RTS -
15 запас прочности
1) General subject: a margin of safety, margin of safety, factor of safety2) Aviation: margin, proof strength, reserve factor, safe load factor3) Naval: margin of strength4) Engineering: safety, safety margin, strength margin, ultimate factor of safety, assurance coefficient, assurance factor5) Construction: strength reserve6) Mathematics: safety factor7) Railway term: assume factor8) Oil: DS (degree of safety), FOS (factor of safety), FS (factor of safety), MS (margin of safety), degree of safety, degree of security, factor of ignorance, margin-of-safety figure, reserve power, safe-load factor, safety index9) Astronautics: material factor, structural margin10) Drilling: coefficient of safety, factor of assurance, safety coefficient11) Quality control: coefficient of resistance, degree of safety( of security)12) oil&gas: strength redundancy -
16 профильный материал
1) Naval: cold-forming shapes, hot-bending shapes2) Engineering: extrusions (полученный методом прессования), sections, shapes3) Mechanics: structural shape4) Drilling: (сортовой) shape5) Automation: section material, shapeУниверсальный русско-английский словарь > профильный материал
-
17 керамика
ceramics, ceramic, ceramic material, pottery* * *кера́мика ж.
ceramicsбытова́я кера́мика — potteryва́куумная кера́мика — vacuum ceramicsглазуро́ванная кера́мика — (плотная, высокообожжённая) enamelled stoneware; ( фаянс) enamelled earthenwareкера́мика для то́ков высо́кой частоты́ — r.f. ceramicsкера́мика для то́ков промы́шленной частоты́ — industrial frequency ceramicsжаросто́йкая кера́мика — high-temperature-ceramicsконденса́торная кера́мика — capacitor, ceramicsлита́я кера́мика — cast ceramicsогнеупо́рная кера́мика — refractoriesпьезоэлектри́ческая кера́мика — piezoelectric ceramicsрадиотехни́ческая кера́мика — radio ceramicsстрои́тельная кера́мика — structural clay productsта́льковая кера́мика — steatitic ceramicsтермосто́йкая кера́мика — heat-resistant ceramicsтехни́ческая кера́мика — engineering ceramicsэлектротехни́ческая кера́мика — electric-grade ceramics
См. также в других словарях:
Structural engineering — is a field of engineering dealing with the analysis and design of structures that support or resist loads. Structural engineering is usually considered a speciality within civil engineering, but it can also be studied in its own right. [cite… … Wikipedia
Structural engineer — Structural engineers analyze, design, plan, and research structural components and structural systems. Their work takes account mainly of technical, economic and environmental concerns, but they may also consider aesthetic and social… … Wikipedia
Structural load — Structural loads or actions are forces, deformations or accelerations applied to a structure or its components.[1][2] Loads cause stresses, deformations and displacements in structures. Assessment of their effects is carried out by the methods of … Wikipedia
Structural steel — Various structural steel shapes Structural steel is steel construction material, a profile, formed with a specific shape or cross section and certain standards of chemical composition and mechanical properties. Structural steel shape, size,… … Wikipedia
Engineering traditions in Canada — Calling of an Engineer= Haultain wrote to Rudyard Kipling, who had made reference to the work of engineers in some of his poems and writings. He asked Kipling for his assistance in developing a suitably dignified obligation and ceremony for its… … Wikipedia
Structural analysis — comprises the set of physical laws and mathematics required to study and predict the behavior of structures. The subjects of structural analysis are engineering artifacts whose integrity is judged largely based upon their ability to withstand… … Wikipedia
Engineering education — is the activity of teaching knowledge and principles related to the professional practice of engineering. It includes the initial education for becoming an engineer and any advanced education and specialization that follow. Engineering education… … Wikipedia
Engineering economics — Engineering economics, previously known as engineering economy, is a subset of economics for application to engineering projects. Engineers seek solutions to problems, and the economic viability of each potential solution is normally considered… … Wikipedia
Material Exchange Format — Filename extension .mxf Internet media type application/mxf Type code mxf Type of format Container format Container for audiovisual material, rich metadata … Wikipedia
Engineering process outsourcing — (EPO) for the AEC industry is a vertical domain for the industries of the built environment.EPO industry is playing crucial role in efficiently supporting dynamic architecture, engineering and construction industries worldwide. EPO has made major … Wikipedia
Engineering News-Record — (widely known as ENR) is a weekly magazine that provides news, analysis, data and opinion for the construction industry worldwide.It has been published since 1874.It is owned by The McGraw Hill Companies.The magazine s subscribers include… … Wikipedia