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1 опускной колодец
foundation cylinder строит., limpet, sunk wellРусско-английский научно-технический словарь Масловского > опускной колодец
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2 опускной колодец
1) General subject: coffer2) Engineering: American caisson, caisson coffer, cofferdam, drop shaft, sunk shaft3) Construction: Gow caisson (из телескопической наращиваемой металлической оболочки), cylinder, cylinder caisson, dredging well, drop caisson, foundation cylinder, limpet, open caisson, sunk well, timber caisson4) Hydrography: caisson5) Aluminium industry: sheet piling -
3 Zylinderpfahl
m < bau> ■ foundation cylinder -
4 опускний
vertical-sliding, center-board, dipping, sinkingопускний кіль — centre-board, sliding keel
опускний колодязь — foundation cylinder, limpet, sunk well
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5 Zylinderpfahl
Deutsch-Englisch Fachwörterbuch Architektur und Bauwesen > Zylinderpfahl
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6 Zylinderpfahl
mArchitektur & Tragwerksplanung, Infrastruktur & Entwurf foundation cylinder -
7 Yale, Linus Jr
SUBJECT AREA: Domestic appliances and interiors[br]b. 4 April 1821 Salisbury, New York, USAd. 25 December 1868 New York City, USA[br]American locksmith, inventor of the Yale pin-tumbler cylinder lock.[br]The son of a locksmith, Linus Yale Jr set out to become a portrait painter but gave this up in the 1840s to embark on the same profession as his father. He opened a shop of his own at Shelburne Falls, Massachusetts; his first products were keyoperated bank locks. The Great Exhibition of 1851 in London convinced him that any lock could be picked by someone with the necessary skill; he then turned his attention to the design of combination locks, designing the first doubledial bank lock in 1863. In 1868 he formed a partnership with John Henry Towne and his son Henry Robinson Towne to form the Yale Lock Manufacturing Company in Stamford, Connecticut, to make a patented key lock which incorporated a series of pin tumblers inside a cylinder. The principle of the pin-tumbler mechanism could be traced back to ancient Egypt; in Yale's cylinder lock, the serrations of the correct key raised the pin tumblers to the height at which the cylinder could turn, withdrawing the bolt. These cylinder locks made possible the use of smaller keys and became the foundation of the modern lock industry. Yale died soon after forming his partnership with the Townes.[br]Further ReadingJ.J.Fucini and S.Fucini, 1985, Entrepreneurs, Boston: C.K.Hall \& Co.IMcN -
8 Hornblower, Jonathan
SUBJECT AREA: Steam and internal combustion engines[br]b. 1753 Cornwall (?), Englandd. 1815 Penryn, Cornwall, England[br]English mining engineer who patented an early form of compound steam engine.[br]Jonathan came from a family with an engineering tradition: his grandfather Joseph had worked under Thomas Newcomen. Jonathan was the sixth child in a family of thirteen whose names all began with "J". In 1781 he was living at Penryn, Cornwall and described himself as a plumber, brazier and engineer. As early as 1776, when he wished to amuse himself by making a small st-eam engine, he wanted to make something new and wondered if the steam would perform more than one operation in an engine. This was the foundation for his compound engine. He worked on engines in Cornwall, and in 1778 was Engineer at the Ting Tang mine where he helped Boulton \& Watt erect one of their engines. He was granted a patent in 1781 and in that year tried a large-scale experiment by connecting together two engines at Wheal Maid. Very soon John Winwood, a partner in a firm of iron founders at Bristol, acquired a share in the patent, and in 1782 an engine was erected in a colliery at Radstock, Somerset. This was probably not very successful, but a second was erected in the same area. Hornblower claimed greater economy from his engines, but steam pressures at that time were not high enough to produce really efficient compound engines. Between 1790 and 1794 ten engines with his two-cylinder arrangement were erected in Cornwall, and this threatened Boulton \& Watt's near monopoly. At first the steam was condensed by a surface condenser in the bottom of the second, larger cylinder, but this did not prove very successful and later a water jet was used. Although Boulton \& Watt proceeded against the owners of these engines for infringement of their patent, they did not take Jonathan Hornblower to court. He tried a method of packing the piston rod by a steam gland in 1781 and his work as an engineer must have been quite successful, for he left a considerable fortune on his death.[br]Bibliography1781, British patent no. 1,298 (compound steam engine).Further ReadingR.Jenkins, 1979–80, "Jonathan Hornblower and the compound engine", Transactions of the Newcomen Society 11.J.Tann, 1979–80, "Mr Hornblower and his crew, steam engine pirates in the late 18th century", Transactions of the Newcomen Society 51.J.Farey, 1827, A Treatise on the Steam Engine, Historical, Practical and Descriptive, reprinted 1971, Newton Abbot: David \& Charles (an almost contemporary account of the compound engine).D.S.L.Cardwell, 1971, From Watt to Clausius. The Rise of Thermo dynamics in the Early Industrial Age, London: Heinemann.H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press.R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press.RLH -
9 Card Clothing
The name used for the clothing of a carding machine, and it consists of a foundation material in which wires are fastened. These wires do the work of carding the cotton. The foundation is secured to the revolving cylinder and is usually made of cotton and woollen cloth and rubber. This cloth is very compactly woven in three layers firmly cemented together, with rubber face to give elasticity to the wires. The wire teeth are inserted in pairs - The coupling bar of each pair is known as the " crown," the carding end of each tooth is termed the " point." Each tooth is bent near the middle, and the bend is the " knee " (see Filleting) -
10 돌망태
n. gabion, stone-filled cylinder used as a foundation for dams and dikes -
11 блок
(бетонный, песчаника, известняка) brick, assemblage, assembly unit, bank, sheave block, block, box электрон.; вчт., cluster, construction unit, element, organ, structural member, modular unit, module, solid monolith, pack, package, pulley, sheave, slab сил., stack, station, unit* * *блок м.1. ( механизм в форме колеса с жёлобом по окружности) block, pulley2. ( узел машины) unit3. стр. blockавари́йный блок яд. физ. — safety blockавтоно́мный блок вчт. — off-line unitблок аккумуля́торных пласти́н одно́й поля́рности — positive or negative plate groupарифмети́ческий блок вчт. — arithmetic unitбето́нный блок — concrete blockблок вво́да-вы́вода вчт. — input-output unitблок веретена́ текст. — wharve, pulleyвертлю́жный блок — swivel blockвоспринима́ющий блок — sensing unitблок воспроизведе́ния вчт. — reproducing unitблок вы́борки (числа́) вчт. — selection unitблок вы́дачи да́нных — read-out unitблок выделе́ния (сигна́ла) оши́бки — error detectorблок выпускно́го отве́рстия метал. — tap-hole blockвысокочасто́тный блок (передатчика, приёмника) — radio-frequency [r.f., RF] unit, radio-frequency [r.f., RF] sectionвычисли́тельный блок — computing unitблок генера́тор — трансформа́тор — generator-transformer unitблок генера́тор — усили́тель — oscillator-amplifier unitги́псовый блок — gypsum blockги́псовый, перегоро́дочный блок — plaster slabглухо́й блок — dummy blockглухо́й, торцо́вый блок — girder end blockблок горе́лок — burner assemblyблок грузовы́х та́лей — cargo-hoist blockблок да́нных вчт. — data unit, data blockдополня́ть блок да́нных до тре́буемой длины́ (напр. двоичными нулями) — pad a data block with (e. g., binary zeroes)блок да́тчиков — data-transmitter unitблок дви́гателя — engine blockдвойно́й блок — double (sheaved) blockдвушки́вный блок — double (sheaved) blockдиато́мовый блок геол. — diatomaceous blockдифференциа́льный блок — differential blockблок для заполне́ния перекры́тия — filler blockблок дози́рующих кла́панов прок. — metering blockдо́ковый блок — dock blockзадаю́щий блок вчт. — set (up) unitблок заде́ржки1. см. блок запаздывания2. вчт. delay unitзакладно́й блок стр. — blockoutблок замедли́теля ( реактора) — moderator blockблок запа́здывания (для моделирования транспортного запаздывания в системах автоматического управления) — time-delay simulator, time-delay unitзапасно́й блок — spare unitблок за́писей вчт. — record blockкомпонова́ть блок из за́писей — pack a block with recordsразбива́ть блок за́писей на сегме́нты — split a (record) block into segmentsзащи́тный блок стр. — shielding blockзвуково́й блок — sound unit, sound headзвуково́й, магни́тный блок — magnetic sound headблок зу́бчатых колё́с — gear clusterблок имита́ции гистере́зиса — hysteresis unitблок имита́ции зо́ны нечувстви́тельности — dead zone unitблок и́мпульсного генера́тора — pulser boxблок индика́ции — display unitблок информа́ции — information blockисполни́тельный блок — actuating [final-control] unit, actuator; вчт. executive unitка́бельный, многокана́льный блок — multiple-duct conduitка́бельный, моноли́тный блок — monolithic conduitка́бельный, однокана́льный блок — single-duct conduit, one-duct bankкни́жный блок — inner bookблок компенса́ции череду́ющимися возмуще́ниями киб. — posicast compensating sectionконденса́торный блок — gang capacitorконтро́льный блок ( монитор) тлв. — monitor unitблок котё́л — турби́на — single-boiler single-turbine combinationкоте́льный, заводско́й блок — shop-assembled boiler moduleкоте́льный, монта́жный блок — field-assembled boiler moduleлепно́й потоло́чный блок — stucco ceiling blockлито́й блок — slip-cast blockлонг-та́кельный блок — long-tackle blockблок магни́тных голо́вок — head stackблок манипуля́тора — keying unitмногошки́вный блок — multiple (sheaved) blockмно́жительно-дели́тельный блок — multiplier-divider (unit)мо́дульный блок — modular unitблок мозаи́чной структу́ры — mosaic blockблок на грузово́й стреле́ — head blockнакопи́тельный блок ( в запоминающем устройстве) — stackблок намо́точных бараба́нов прок. — winding frameнаправля́ющий блок — lead(ing) blockблок настро́йки1. радио tuner2. автмт. adjusting [setting] unitблок настро́йки анте́нны — aerial [antenna] tuning unitблок настро́йки сопла́ ракет. — nozzle-trim unitнатяжно́й блок — tension blockнеавтоно́мный блок вчт. — on-line unitневосстана́вливаемый блок — “throw-away” unitблок незави́симой переме́нной — independent variable unitнеподви́жный блок стр. — fixed [standing] blockблок обрабо́тки да́нных — processing unitобъё́мный блок стр. — (concrete) box unitобъё́мный, кварти́рный блок — factory-assembled box-formed dwelling unitогнеупо́рный шамо́тный блок — refractory fireclay blockоднопусто́тный блок стр. — unicell blockодношки́вный блок — single(-sheaved) blockоперацио́нный блок — operational unitосновно́й блок ( в системе параллельного резервирования или дублирования) — nonredundant unitотводно́й блок — angle blockоткрыва́ющийся блок стр. — snatch blockблок отрабо́тки магни́тных вариа́ций — magnetic variation unitблок оце́нки — estimation [evaluation] unitблок па́мяти — memory [storage] unitблок па́мяти, бу́ферный — buffer unitблок переключа́телей — gang switchблок пече́й метал. — benchпечно́й блок метал. — furnace blockблок пита́ния1. power [supply] unit2. хим. feeding blockблок плаву́чести мор. — foam buoyancyподви́жный блок — running blockподъё́мный блок ( в отличие от приводного) — load [lifting] blockблок полиспа́ста — tackle blockблок полиспа́ста, ни́жний — hoisting block (of a purchase tackle)блок постоя́нных коэффицие́нтов — scalerбло́ки постоя́нных програ́мм — firmwareприводно́й блок — hauling [operating] blockприё́мно-усили́тельный блок — receiver-amplifier unitблок проби́вки перфока́рт — card punching unitблок прогно́за киб. — prediction unitблок произво́дных автмт. — derivative blockпросто́й блок — single purchaseблок радиотелеметри́ческой за́писи, ка́дровый — histogram recorderблок развё́ртки (осциллоскопа радиолокационного индикатора, электроннолучевой трубки) — брит. time-base circuit, time-base unit; амер. sweep circuit, sweep unitблок, распределя́ющий нагру́зку — distributing blockрегистри́рующий блок — recording unitблок регулиро́вки — adjustment unitрегули́рующий блок — regulating unitрезе́рвный блок — standby unit; ( в системе резервирования) redundant [duplicate] unit, redundant [duplicate] componentреле́йный блок — relay unitру́дный блок — ore blockсво́довый магнези́то-хроми́товый блок — magnesite-chrome roof blockблок свя́зи — coupling unit, couplerблок свя́зи с кана́лом ( в системе передачи данных) — line adapterблок сдви́га — shift unitсдво́енный блок — twin pulley blockселе́кторный блок — strobe unitблок селе́кции и́мпульсов — pulse gating unitсельси́нный блок — synchro unitблок се́точного управле́ния — grid control unitблок синхрониза́ции — synchronizer, timer, timing unitскре́перный блок горн. — scraper blockскулово́й блок мор. — bilge blockсло́жный, кана́тный блок — rope tackleсло́жный, цепно́й блок — chain tackle, chain purchaseслуча́йный блок ( в системах управления) — randomized blockсме́нный блок — plug-in [pluggable] unitсмолодоломи́товый блок — tar-dolomite blockблок согласова́ния анте́нны — aerial-matching [antenna-matching] unit, aerial [antenna] couplerблок сопровожде́ния рлк. — tracking unitблок сравне́ния — comparator (unit)станда́ртный блок — standard unitстекля́нный блок — glass blockстеново́й блок — building blockстеново́й, керами́ческий пустоте́лый блок — clay building tileстеново́й, пустоте́лый блок — hollow building blockстрои́тельный блок — building blockприменя́ть строи́тельные бло́ки под облицо́вку [обкла́дку] — use building blocks for backing up a facing materialстыково́й блок — joint blockсъё́мный блок вчт. — plug-in [pluggable] unitсырцо́вый блок — adobe blockблок телеметри́ческой аппарату́ры — telemetry unitблок трансля́ции — translator unitблок уко́сины, направля́ющий — jib sheaveблок умноже́ния — multiplier (unit)блок управле́ния — control unit, control blockура́новый блок ( ядерного реактора) — slugблок ускори́телей ракет. — boost clusterблок у шпо́ра грузово́й стрелы́ — heel blockблок фазиро́вки анте́нны — aerial [antenna] phasing unitблок фокусиро́вки — focusing blockблок формирова́ния и́мпульсов — pulse shaping [generating] unitблок формирова́ния пусково́го и́мпульса — trigger-pulse generatorблок фототриангуля́ции — (aerial) triangulation block, aeropolygonблок фунда́мента — concrete foundation blockфункциона́льный блок вчт. — functional block, functional unitблок футеро́вки метал. — lining blockхрони́рующий блок радио — clock unitцепно́й блок — chain sheaveблок цепны́х та́лей — chain-hoist blockблок цикло́нов — cyclone batteryцилиндри́ческий, а́нкерный блок — cylindrical blockблок цили́ндров — cylinder blockцифрово́й блок — digital unitблок часто́тной развя́зки — diplexerблок шестерё́н — gear clusterшлакобето́нный блок — slag-concrete [cinder] blockшнурово́й блок ( ручного телефонного коммутатора) — cord pulley weightблок штукату́рки, мая́чный — spacer block -
12 отсутствовать
Отсутствовать - to be absent, to be lacking; to be not available (в распоряжении кого-либо); to be out of stock (на складе); not to exist, to be nonexistent (не существовать вообще)Unfortunately, the elastic foundation has an irregular boundary and is absent in some zones.The occurrence of such fluctuations is indicated by a large number of statistical studies, but iron-clad proof is still lacking.Measures for improving the fatigue strength of steels are not currently available.These constraints do not exist when the cylinder is situated in a purely liquid environment.Since the masses were centrally located, higher order, shaft critical speeds were nonexistent.Spherical data are, virtually nonexistent because of the difficulty of providing enough energy to the sphere to cause film boiling.Русско-английский научно-технический словарь переводчика > отсутствовать
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13 блок питания
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14 Baldwin, Matthias William
[br]b. 10 November 1795 Elizabethtown, New Jersey, USAd. 7 September 1866 Philadelphia, Pennsylvania, USA[br]American builder of steam locomotives, founder of Baldwin Locomotive Works.[br]After apprenticeship as a jeweller, Baldwin set up a machinery manufacturing business, and built stationary steam engines and, in 1832, his first locomotive, Old Ironsides, for the then-new Philadelphia, Germantown \& Norristown Railroad. Old Ironsides achieved only 1 mph (1.6 km/h) on trial, but after experimentation reached 28 mph (45 km/h). Over the next ten years Baldwin built many stationary engines and ten more locomotives, and subsequently built locomotives exclusively.He steadily introduced detail improvements in locomotive design; standardized components by means of templates and gauges from 1838 onwards; introduced the cylinder cast integrally with half of the smokebox saddle in 1858; and in 1862 imported steel tyres, which had first been manufactured in Germany by Krupp of Essen in 1851, and began the practice in the USA of shrinking them on to locomotive wheels. At the time of Matthias Baldwin's death, the Baldwin Locomotive Works had built some 1,500 locomotives: it went on to become the largest locomotive building firm to develop from a single foundation, and by the time it built its last steam locomotive, in 1955, had produced about 75,000 in total.[br]Further ReadingJ.H.White Jr, 1979, A History of the American Locomotive—Its Development 1830–1880, New York: Dover Publications Inc.J.Marshall, 1978, A Biographical Dictionary of Railway Engineers, Newton Abbot: David \& Charles.Dictionary of American Biography.PJGRBiographical history of technology > Baldwin, Matthias William
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15 Perkins, Jacob
[br]b. 9 July 1766 Newburyport, Massachusetts, USAd. 30 July 1849 London, England[br]American inventor of a nail-making machine and a method of printing banknotes, investigator of the use of steam at very high pressures.[br]Perkins's occupation was that of a gold-and silversmith; while he does not seem to have followed this after 1800, however, it gave him the skills in working metals which he would continue to employ in his inventions. He had been working in America for four years before he patented his nail-making machine in 1796. At the time there was a great shortage of nails because only hand-forged ones were available. By 1800, other people had followed his example and produced automatic nail-making machines, but in 1811 Perkins' improved machines were introduced to England by J.C. Dyer. Eventually Perkins had twenty-one American patents for a range of inventions in his name.In 1799 Perkins invented a system of engraving steel plates for printing banknotes, which became the foundation of modern siderographic work. It discouraged forging and was adopted by many banking houses, including the Federal Government when the Second United States Bank was inaugurated in 1816. This led Perkins to move to Philadelphia. In the intervening years, Perkins had improved his nail-making machine, invented a machine for graining morocco leather in 1809, a fire-engine in 1812, a letter-lock for bank vaults and improved methods of rolling out spoons in 1813, and improved armament and equipment for naval ships from 1812 to 1815.It was in Philadelphia that Perkins became interested in the steam engine, when he met Oliver Evans, who had pioneered the use of high-pressure steam. He became a member of the American Philosophical Society and conducted experiments on the compressibility of water before a committee of that society. Perkins claimed to have liquified air during his experiments in 1822 and, if so, was the real discoverer of the liquification of gases. In 1819 he came to England to demonstrate his forgery-proof system of printing banknotes, but the Bank of England was the only one which did not adopt his system.While in London, Perkins began to experiment with the highest steam pressures used up to that time and in 1822 took out his first of nineteen British patents. This was followed by another in 1823 for a 10 hp (7.5 kW) engine with only 2 in. (51 mm) bore, 12 in. (305 mm) stroke but a pressure of 500 psi (35 kg/cm2), for which he claimed exceptional economy. After 1826, Perkins abandoned his drum boiler for iron tubes and steam pressures of 1,500 psi (105 kg/cm2), but the materials would not withstand such pressures or temperatures for long. It was in that same year that he patented a form of uniflow cylinder that was later taken up by L.J. Todd. One of his engines ran for five days, continuously pumping water at St Katherine's docks, but Perkins could not raise more finance to continue his experiments.In 1823 one his high-pressure hot-water systems was installed to heat the Duke of Wellington's house at Stratfield Saye and it acquired a considerable vogue, being used by Sir John Soane, among others. In 1834 Perkins patented a compression ice-making apparatus, but it did not succeed commercially because ice was imported more cheaply from Norway as ballast for sailing ships. Perkins was often dubbed "the American inventor" because his inquisitive personality allied to his inventive ingenuity enabled him to solve so many mechanical challenges.[br]Further ReadingHistorical Society of Pennsylvania, 1943, biography which appeared previously as a shortened version in the Transactions of the Newcomen Society 24.D.Bathe and G.Bathe, 1943–5, "The contribution of Jacob Perkins to science and engineering", Transactions of the Newcomen Society 24.D.S.L.Cardwell, 1971, From Watt to Clausius. The Rise of Thermodynamics in the Early Industrial Age, London: Heinemann (includes comments on the importance of Perkins's steam engine).A.F.Dufton, 1940–1, "Early application of engineering to warming of buildings", Transactions of the Newcomen Society 21 (includes a note on Perkins's application of a high-pressure hot-water heating system).RLH
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