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1 compressed fibre
Машиностроение: сжатое волокно -
2 compressed fibre
English-Russian dictionary of machine parts > compressed fibre
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3 compressed fibre
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4 fibre
1) волокно2) фибра3) оптическое ( волокно)4) лыко, мочало•- acrylic fibre - artificial fibre - asbestos fibre - bast fibres - brittle fibre - brush fibre - cane fibre - ceramic fibre - compressed fibre - cordage fibres - extreme fibre - fire-retardant fibre - glass fibre - guiding fibre - heat-insulating fibre - longitudinal fibre - lower fibre - mean fibre - median fibre - natural fibre - optical glass fibre - pliant fibre - reinforcing fibre - top fibre - transverse fibre - upper fibres - vulcanized fibre - wood fibre - woody fibre -
5 compressed fiberboard
Dictionary of Engineering, architecture and construction > compressed fiberboard
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6 compressed asbestos fibre sheets
Общая лексика: паронит (по ГОСТ 481-80; http://www.vniiki.ru/details_v_gost.asp?id=1960)Универсальный англо-русский словарь > compressed asbestos fibre sheets
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7 CAF (compressed asbestos fibre) gasket
Техника: паронитовая прокладкаУниверсальный англо-русский словарь > CAF (compressed asbestos fibre) gasket
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8 fiber
= fibre* * *волокно; фибра- acetate fiberfiber stressed beyond the proportional limit — волокно, напряжённое свыше предела пропорциональности
- acrylic fiber
- alkali-resistant glass fiber
- artificial fiber
- asbestos fiber
- bottom fiber
- cane fiber
- carbon fiber
- compressed fiber
- corrugated steel fibers
- crimped steel fibers
- extreme fiber
- glass fiber
- high modulus polymer fiber
- man-made fiber
- mineral fiber
- natural fiber
- natural mineral fiber
- neutral fiber
- outer fiber
- outermost fiber
- short chopped fibers
- silica fiber
- sisal fibers
- synthetic fiber
- tensile fiber
- top fiber -
9 concrete
1) бетон, бетонная смесь || бетонировать2) бетонный; бетонированный3) конкретный, определённый; реальный4) затвердевать, застывать• -
10 Flax Retting
Ret, Aerated - A type of ret where compressed air is forced into the bottom of the tank to maintain the retting liquor at or near the neutral point as regards acidity. Ret, Aerobic - A type of bacterial ret where the predominant bacteria are aerobic, i.e., work only in the presence of oxygen. Ret, Anaerobic - Any type of bacterial retting where the predominant bacteria are anaerobic, i.e., work in the absence of oxygen. This is the usual condition. Ret, Belgian - A term applied to a tank ret where warm water is sprayed into the bottom of the tank at intervals. Ret, Channel - A ret in which crates of flax are regularly introduced at one end of a water channel and removed at the other end. Ret, Chemical - The straw is subjected to chemical solutions to induce loosening of the fibre from the wood. Ret, Dam - Water retting by immersing the crop or de-seeded straw in dams cut in the earth and filled with water at natural temperature. Ret, Dew - The straw is spread on the ground in the open, in a thin layer and retting is effected by the action of fungi in the presence of rain, dew and sunlight. Ret, Double - The straw is subjected to two independent rets with intermediate drying. Ret, Duplex - A form of tank retting in which one tankful of straw undergoing the second half of its ret is in circulation with another tankful undergoing the first half of its ret. Ret, Interrupted - Essentially a two-stage warm water tank ret, the retting liquor being replaced by fresh water when the ret is about one-half to two-thirds complete. Ret, Pond - Water retting by immersing the crop or de-seeded straw in natural ponds. Ret, River - The straw is immersed in rivers, but usually after being packed in crates. Ret, Rossi - A type of aerated or aerobic retting in which a pure culture of bacteria is introduced. Ret, Tank- - The straw is packed into concrete or other tanks and the temperature of the water and its renewal during the ret is controlled. Ret, Water - The total immersion of the straw in water to induce retting by bacterial action. Retting - The subjection of crop or deseeded straw to chemical or biological treatment to make the fibre strands more easily separable from the woody part of the stem. -
11 CNAF
1) Машиностроение: compressed non-asbestos fibre, сжатое безасбестовое волокно (материал для прокладок)2) НАСДАК: Commercial National Financial Corporation -
12 CAF gasket
Техника: (compressed asbestos fibre) паронитовая прокладка -
13 slab
1) плита; панель; плита дорожного покрытия; панель перекрытия3) горбыль•- anchor slab - apron slab - armoured concrete slab - back slab - balcony slab - beam slab - bending slab - building slab - cement slab - cladding slab - composite slab - concrete slab - concrete pavement slab - continuous slab - continuous foundation slab - cored slab - cork slab - corner slab - cornice slab - crest slab - cross slab - curb slab - deck slab of dam - face slab - facing slab - fibre reinforced gypsum slab - filler-concrete slab - fixed-edge slab - floating slab - floor slab - floor slab of a bridge - grade slab - ground slab - gunited slab - heat insulating slab - laminated slab - large slab - lift slab - load-bearing wall slabs - marble wall slab - mineral wool slab - multilayer slab - one-way slab - pavement slab - paving slab - peat slab - pillar wall slab - plaster slab - plinth slab - precast slab - prefabricated slabs - ready-made slab - reinforced-concrete slab - ribbed slab - road slab - roadway slab - rolled slab - roof slab - sandwich slab - sheet slab - shell slab - short span slab - side slab - single-layer slab - sluice slab - sound insulating slab - sound isolation slab - spillway slab - stiffened slab - T-beam floor slab - test slab - thickened edge slab - thin slab - three-layer slab - toe slab - truss slab - two-way slab - uniform road slab - uniform thickness slab - upstream-deck slab - ventilation slab - wall slab - wall heating slab - window slab - wind-protective slab - wood-based slab - woodfibre slab - woodwool slabslab with stiffened edges — плита с укреплёнными краями; плита с жёстко заделанными краями
* * *1. плита ( элемент конструкции)2. горбыль ( пиломатериал)slab over basement — надподвальная плита, плита подвального перекрытия
slab rested on loose fill material — плита ( пола), опирающаяся на насыпной грунт
slab shotcreted over expanded metal — бетонная плита, выполненная методом торкретирования поверх просечно-вытяжного настила; торкрет-бетонная плита, армированная просечно-вытяжным настилом
slab simply supported on four sides — прямоугольная плита, свободно [шарнирно] опёртая по четырём сторонам
- approach slabslab spanning in two directions — плита, работающая в двух направлениях
- apron slab
- balcony slab
- basement slab
- beam slab
- beam and girder slab
- brick-lined concrete slab
- bridge deck slab
- compressed straw slab
- concrete slab
- concrete slab on grade
- continuous slab
- deck slab
- edge supported slab
- equalizing slab
- fixed-edge slab
- flat slab
- floating slab
- floor slab
- foundation slab
- ground slab
- heat-insulating slab
- hollow core slab
- hollow-tile floor slab
- infinite slab
- in-situ concrete slab
- leftward skew slab
- lift slab
- marked out facing slab
- monolithic slab and foundation slab
- mud slab
- paving slab
- plaster slab
- post-tensioned slab
- post-tension slab
- restrained slab
- ribbed slab above basement
- roof slab
- sandwich slab
- semi-infinite slab
- short span slab
- simply supported slab
- skew slab
- solid slab
- spillway slab
- structural slab
- terrazzo facing slab
- terrazzo slab
- two-way slab
- two-way ribbed flat slab
- two-way ribbed slab
- unstiffened edge slab
- upstanding beam slab
- upstand beam slab
- upstream-deck slab
- waffle slab
- wood-fiber slab -
14 Slag Wool
This is an interesting byproduct from the blast furnace. It is not a textile fibre, although it is used as packing material. The process of manufacture consists in subjecting a small stream of molten slag to a strong blast of steam or compressed air. This has the effect of breaking if up into minute spherules, and each small bead particle as it is blown away carries behind it extremely delicate filaments resembling fine glass that are often 2 feet to 3 feet in length, but readily break up into smaller lengths, and in bulk look like a mass of cotton of a dirty slate colour. Slag wool has the property of great lightness combined with that of being absolutely fireproof; it is also a very good non-conductor of heat and sound. -
15 Swan, Sir Joseph Wilson
[br]b. 31 October 1828 Sunderland, Englandd. 27 May 1914 Warlingham, Surrey, England[br]English chemist, inventor in Britain of the incandescent electric lamp and of photographic processes.[br]At the age of 14 Swan was apprenticed to a Sunderland firm of druggists, later joining John Mawson who had opened a pharmacy in Newcastle. While in Sunderland Swan attended lectures at the Athenaeum, at one of which W.E. Staite exhibited electric-arc and incandescent lighting. The impression made on Swan prompted him to conduct experiments that led to his demonstration of a practical working lamp in 1879. As early as 1848 he was experimenting with carbon as a lamp filament, and by 1869 he had mounted a strip of carbon in a vessel exhausted of air as completely as was then possible; however, because of residual air, the filament quickly failed.Discouraged by the cost of current from primary batteries and the difficulty of achieving a good vacuum, Swan began to devote much of his attention to photography. With Mawson's support the pharmacy was expanded to include a photographic business. Swan's interest in making permanent photographic records led him to patent the carbon process in 1864 and he discovered how to make a sensitive dry plate in place of the inconvenient wet collodian process hitherto in use. He followed this success with the invention of bromide paper, the subject of a British patent in 1879.Swan resumed his interest in electric lighting. Sprengel's invention of the mercury pump in 1865 provided Swan with the means of obtaining the high vacuum he needed to produce a satisfactory lamp. Swan adopted a technique which was to become an essential feature in vacuum physics: continuing to heat the filament during the exhaustion process allowed the removal of absorbed gases. The inventions of Gramme, Siemens and Brush provided the source of electrical power at reasonable cost needed to make the incandescent lamp of practical service. Swan exhibited his lamp at a meeting in December 1878 of the Newcastle Chemical Society and again the following year before an audience of 700 at the Newcastle Literary and Philosophical Society. Swan's failure to patent his invention immediately was a tactical error as in November 1879 Edison was granted a British patent for his original lamp, which, however, did not go into production. Parchmentized thread was used in Swan's first commercial lamps, a material soon superseded by the regenerated cellulose filament that he developed. The cellulose filament was made by extruding a solution of nitro-cellulose in acetic acid through a die under pressure into a coagulating fluid, and was used until the ultimate obsolescence of the carbon-filament lamp. Regenerated cellulose became the first synthetic fibre, the further development and exploitation of which he left to others, the patent rights for the process being sold to Courtaulds.Swan also devised a modification of Planté's secondary battery in which the active material was compressed into a cellular lead plate. This has remained the central principle of all improvements in secondary cells, greatly increasing the storage capacity for a given weight.[br]Principal Honours and DistinctionsKnighted 1904. FRS 1894. President, Institution of Electrical Engineers 1898. First President, Faraday Society 1904. Royal Society Hughes Medal 1904. Chevalier de la Légion d'Honneur 1881.Bibliography2 January 1880, British patent no. 18 (incandescent electric lamp).24 May 1881, British patent no. 2,272 (improved plates for the Planté cell).1898, "The rise and progress of the electrochemical industries", Journal of the Institution of Electrical Engineers 27:8–33 (Swan's Presidential Address to the Institution of Electrical Engineers).Further ReadingM.E.Swan and K.R.Swan, 1968, Sir Joseph Wilson Swan F.R.S., Newcastle upon Tyne (a detailed account).R.C.Chirnside, 1979, "Sir Joseph Swan and the invention of the electric lamp", IEEElectronics and Power 25:96–100 (a short, authoritative biography).GWBiographical history of technology > Swan, Sir Joseph Wilson
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