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1 kasvatusmenetelmä
• additive method• pedagogical method• additive process -
2 адитивен метод
additive methodadditive methods -
3 аддитивный метод
1) Household appliances: additive process2) Makarov: additive method -
4 аддитивный способ
Русско-английский политехнический словарь > аддитивный способ
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5 способ выгорающих добавок
Универсальный русско-английский словарь > способ выгорающих добавок
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6 Dreifarbenverfahren
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7 способ выгорающих добавок
( в производстве легковесных огнеупоров) burning additive methodРусско-английский политехнический словарь > способ выгорающих добавок
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8 opgroei-overneemmethode
• additive transfer method• plating transfer methodNederlands-Engels Technisch Woordenboek > opgroei-overneemmethode
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9 opgroeimethode
• additive transfer method• plating transfer method -
10 overneemmethode
• additive transfer method• plating transfer method -
11 Ducos du Hauron, Arthur-Louis
SUBJECT AREA: Photography, film and optics[br]b. 1837 Langon, Bordeaux, Franced. 19 August 1920 Agen, France[br]French scientist and pioneer of colour photography.[br]The son of a tax collector, Ducos du Hauron began researches into colour photography soon after the publication of Clerk Maxwell's experiment in 1861. In a communication sent in 1862 for presentation at the Académie des Sciences, but which was never read, he outlined a number of methods for photography of colours. Subsequently, in his book Les Couleurs en photographie, published in 1869, he outlined most of the principles of additive and subtractive colour photography that were later actually used. He covered additive processes, developed from Clerk Maxwell's demonstrations, and subtractive processes which could yield prints. At the time, the photographic materials available prevented the processes from being employed effectively. The design of his Chromoscope, in which transparent reflectors could be used to superimpose three additive images, was sound, however, and formed the basis of a number of later devices. He also proposed an additive system based on the use of a screen of fine red, yellow and blue lines, through which the photograph was taken and viewed. The lines blended additively when seen from a certain distance. Many years later, in 1907, Ducos du Hauron was to use this principle in an early commercial screen-plate process, Omnicolore. With his brother Alcide, he published a further work in 1878, Photographie des Couleurs, which described some more-practical subtractive processes. A few prints made at this time still survive and they are remarkably good for the period. In a French patent of 1895 he described yet another method for colour photography. His "polyfolium chromodialytique" involved a multiple-layer package of separate red-, green-and blue-sensitive materials and filters, which with a single exposure would analyse the scene in terms of the three primary colours. The individual layers would be separated for subsequent processing and printing. In a refined form, this is the principle behind modern colour films. In 1891 he patented and demonstrated the anaglyph method of stereoscopy, using superimposed red and green left and right eye images viewed through green and red filters. Ducos du Hauron's remarkable achievement was to propose theories of virtually all the basic methods of colour photography at a time when photographic materials were not adequate for the purpose of proving them correct. For his work on colour photography he was awarded the Progress Medal of the Royal Photographic Society in 1900, but despite his major contributions to colour photography he remained in poverty for much of his later life.[br]Further ReadingB.Coe, 1978, Colour Photography: The First Hundred Years, London. J.S.Friedman, 1944, History of Colour Photography, Boston. E.J.Wall, 1925, The History of Three-Colour Photography, Boston. See also Cros, Charles.BCBiographical history of technology > Ducos du Hauron, Arthur-Louis
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12 процесс
operation, making, procedure, process* * *проце́сс м.
processоформля́ть проце́сс аппарату́рно — implement [instrument, mechanize] a processпроце́сс происхо́дит — a process occursпроце́сс протека́ет … — a process runs …реализова́ть проце́сс — implement a process; вчт., киб. instrument [mechanize] a processаддити́вный проце́сс — additive processадиабати́ческий проце́сс — adiabatic processаммиа́чно-со́довый проце́сс — Solvay processпроце́сс Ая́кс [Ая́кс-проце́сс] ( разновидность мартеновского процесса) — Ajax processбездо́менный проце́сс — direct ore-reduction processбессеме́ровский проце́сс — Bessemer processвагра́ночный проце́сс — cupola processвероя́тностный проце́сс — probabilistic processветвя́щийся проце́сс — branching processвосстанови́тельный проце́сс — reduction processпроце́сс выра́щивания криста́ллов, эпитаксиа́льный — epitaxial(-growth) processвычисли́тельный проце́сс — computational processпроце́сс гальванопокры́тия, щелочно́й — alkaline plating processдо́менный проце́сс — blast-furnace processидеа́льный проце́сс — ideal processизобари́ческий проце́сс — isobaric [constant-pressure] processизотерми́ческий проце́сс — isothermal [constant-temperature] processизохори́ческий проце́сс — isochoric [constant-volume] processизоэнтропи́ческий проце́сс — isentropic processитерацио́нный проце́сс вчт. — iterative processквазистациона́рный проце́сс — quasi-stationary processкинети́ческий проце́сс — rate processкислоро́дно-конве́ртерный проце́сс — basic oxygen [oxygen-converter] processконве́ртерный проце́сс — converter processконкури́рующие проце́ссы — competitive processesма́рковский проце́сс мат. — Markov(ian) processмарте́новский проце́сс — open-hearth processмарте́новский, ки́слый проце́сс — acid open-hearth processмарте́новский, основно́й проце́сс — basic open-hearth processмодели́руемый проце́сс — prototype processнеобрати́мый проце́сс — irreversible processнепреры́вный проце́сс — continuous processнеравнове́сный проце́сс — nonequilibrium processнестациона́рный проце́сс — non-steady processнеустанови́вшийся проце́сс — unsteady-state processобжига́тельно-восстанови́тельный проце́сс — roasting reduction processобрати́мый проце́сс — reversible processобра́тный проце́сс — inverse processокисли́тельно-восстанови́тельный проце́сс — redox processокисли́тельный проце́сс — oxidizing processпроце́сс ОЛП — OLP converter process (oxygen-lime-powder)оптима́льный проце́сс — optimal processпроце́сс перено́са — transport [transfer] processперехо́дный проце́сс — transient (process)по́сле оконча́ния перехо́дных проце́ссов … — after all transients have died out …периоди́ческий проце́сс — periodic processпроце́сс пла́вки с наво́дкой одного́ шла́ка — single-slag processпозити́вный проце́сс кфт. — positive processполитропи́ческий проце́сс — polytropic processпоследуби́льные проце́ссы — post tanningпроце́сс произво́дства — production processпроце́сс произво́дства ста́ли — steel-making processпроце́сс пряде́ния, непреры́вный — continuous spinning processравнове́сный проце́сс — equilibrium processрегули́руемый проце́сс — controlled processрегуля́рный проце́сс — regular processро́торный проце́сс ( в производстве стали) — rotor processру́дный проце́сс — pig-and-ore processпроце́сс сгора́ния — combustion (process)случа́йный проце́сс — random processстациона́рный проце́сс — stationary processстохасти́ческий проце́сс — stochastic processтехнологи́ческий проце́сс — хим. process; маш. manufacturing [production] methodвнедря́ть технологи́ческий проце́сс — bring in a new processтехнологи́ческий проце́сс ведё́тся [осуществля́ется] с центра́льного пу́льта — the process is run from a central control roomтехнологи́ческий, непреры́вный проце́сс — continuous processтехнологи́ческий, периоди́ческий проце́сс — batch processтипово́й проце́сс хим. — unit processтома́совский проце́сс — basic Bessemer processуправля́емый проце́сс — controlled processпроце́сс усредне́ния — averaging (process)установи́вшийся проце́сс — steady-state processциркуляцио́нный проце́сс хим. — a process with (a) recycleэкзотерми́ческий проце́сс — exothermic [exoergic] processзкзоэнергети́ческий проце́сс — exothermic [exoergic] processэндотерми́ческий проце́сс — endothermic [endoergic] processэргоди́ческий проце́сс мат. — ergodic process -
13 процесс
м. processпроцесс протекает … — a process runs …
после окончания переходных процессов … — after all transients have died out …
технологический процесс — process; manufacturing method
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14 Coolidge, William David
[br]b. 23 October 1873 Hudson, Massachusetts, USAd. 3 February 1975 New York, USA[br]American physicist and metallurgist who invented a method of producing ductile tungsten wire for electric lamps.[br]Coolidge obtained his BS from the Massachusetts Institute of Technology (MIT) in 1896, and his PhD (physics) from the University of Leipzig in 1899. He was appointed Assistant Professor of Physics at MIT in 1904, and in 1905 he joined the staff of the General Electric Company's research laboratory at Schenectady. In 1905 Schenectady was trying to make tungsten-filament lamps to counter the competition of the tantalum-filament lamps then being produced by their German rival Siemens. The first tungsten lamps made by Just and Hanaman in Vienna in 1904 had been too fragile for general use. Coolidge and his life-long collaborator, Colin G. Fink, succeeded in 1910 by hot-working directly dense sintered tungsten compacts into wire. This success was the result of a flash of insight by Coolidge, who first perceived that fully recrystallized tungsten wire was always brittle and that only partially work-hardened wire retained a measure of ductility. This grasped, a process was developed which induced ductility into the wire by hot-working at temperatures below those required for full recrystallization, so that an elongated fibrous grain structure was progressively developed. Sintered tungsten ingots were swaged to bar at temperatures around 1,500°C and at the end of the process ductile tungsten filament wire was drawn through diamond dies around 550°C. This process allowed General Electric to dominate the world lamp market. Tungsten lamps consumed only one-third the energy of carbon lamps, and for the first time the cost of electric lighting was reduced to that of gas. Between 1911 and 1914, manufacturing licences for the General Electric patents had been granted for most of the developed work. The validity of the General Electric monopoly was bitterly contested, though in all the litigation that followed, Coolidge's fibering principle was upheld. Commercial arrangements between General Electric and European producers such as Siemens led to the name "Osram" being commonly applied to any lamp with a drawn tungsten filament. In 1910 Coolidge patented the use of thoria as a particular additive that greatly improved the high-temperature strength of tungsten filaments. From this development sprang the technique of "dispersion strengthening", still being widely used in the development of high-temperature alloys in the 1990s. In 1913 Coolidge introduced the first controllable hot-cathode X-ray tube, which had a tungsten target and operated in vacuo rather than in a gaseous atmosphere. With this equipment, medical radiography could for the first time be safely practised on a routine basis. During the First World War, Coolidge developed portable X-ray units for use in field hospitals, and between the First and Second World Wars he introduced between 1 and 2 million X-ray machines for cancer treatment and for industrial radiography. He became Director of the Schenectady laboratory in 1932, and from 1940 until 1944 he was Vice-President and Director of Research. After retirement he was retained as an X-ray consultant, and in this capacity he attended the Bikini atom bomb trials in 1946. Throughout the Second World War he was a member of the National Defence Research Committee.[br]Bibliography1965, "The development of ductile tungsten", Sorby Centennial Symposium on the History of Metallurgy, AIME Metallurgy Society Conference, Vol. 27, ed. Cyril Stanley Smith, Gordon and Breach, pp. 443–9.Further ReadingD.J.Jones and A.Prince, 1985, "Tungsten and high density alloys", Journal of the Historical Metallurgy Society 19(1):72–84.ASDBiographical history of technology > Coolidge, William David
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15 Godowsky, Leopold Jr
SUBJECT AREA: Photography, film and optics[br]b. 27 May 1900 Chicago, Illinois, USA d. 1983[br]American musician and photographic experimenter whose researches, with those of his colleague Mannes, led to the introduction of the first commercial tripack colour film, Kodachrome.[br]Both from distinguished musical families, Godowsky and Leopold Damrosch Mannes met at Riverdale School in New York in 1916, and shared an interest in photography. They began experiments in methods of additive colour photography, gaining a patent for a three-colour projector. Godowsky went to the University of California to study chemistry, physics and mathematics, while working as a professional violinist; Mannes, a pianist, went to Harvard to study music and physics. They kept in touch, and after graduating they joined up in New York, working as musicians and experimenting in colour photography in their spare time.Initially working in kitchens and bathrooms, they succeeded in creating a two-layer colour photographic plate, with emulsions separately sensitized to parts of the spectrum, and patented the process. This achievement was all the greater since they were unable to make the emulsions themselves and had to resort to buying commercial photographic plates so that they could scrape off the emulsions, remelt them and coat their experimental materials. In 1922 their work came to the attention of C.E.K. Mees, the leading photographic scientist and Director of the Eastman Kodak Research Laboratory in Rochester, New York. Mees arranged for plates to be coated to their specifications. With a grant from Kuhn, Loeb \& Co. they were able to rent laboratory space. Learning of Rudolf Fischer's early work on dye couplers, they worked to develop a new process incorporating them. Mees saw that their work, however promising, would not develop in an amateur laboratory, and in 1930 he invited them to join the Kodak Research Laboratory, where they arrived on 15 June 1931. Their new colleagues worked on ways of coating multi-layer film, while Mannes and Godowsky worked out a method of separately processing the individual layers in the exposed film. The result was Kodachrome film, the first of the modern integral tripack films, launched on 15 April 1935.They remained with Eastman Kodak until December 1939; their work contributed to the later appearance of Ektachrome colour-reversal film and the Kodacolor and Eastman Color negative-positive colour processes. Mannes became the Director of his father's Music Academy in New York, remaining as such until his death in 1964. Godowsky returned to Westport, Connecticut, and continued to study mathematics at Columbia University. He carried out photographic research un his private laboratory up until the time of his death in 1983.[br]Further ReadingC.E.K.Mees, 1961, From Dry Plates to Ektachrome Film, New York.BC -
16 Riley, James
SUBJECT AREA: Metallurgy[br]b. 1840 Halifax, Englandd. 15 July 1910 Harrogate, England[br]English steelmaker who promoted the manufacture of low-carbon bulk steel by the open-hearth process for tin plate and shipbuilding; pioneer of nickel steels.[br]After working as a millwright in Halifax, Riley found employment at the Ormesby Ironworks in Middlesbrough until, in 1869, he became manager of the Askam Ironworks in Cumberland. Three years later, in 1872, he was appointed Blast-furnace Manager at the pioneering Siemens Steel Company's works at Landore, near Swansea in South Wales. Using Spanish ore, he produced the manganese-rich iron (spiegeleisen) required as an additive to make satisfactory steel. Riley was promoted in 1874 to be General Manager at Landore, and he worked with William Siemens to develop the use of the latter's regenerative furnace for the production of open-hearth steel. He persuaded Welsh makers of tin plate to use sheets rolled from lowcarbon (mild) steel instead of from charcoal iron and, partly by publishing some test results, he was instrumental in influencing the Admiralty to build two naval vessels of mild steel, the Mercury and the Iris.In 1878 Riley moved north on his appointment as General Manager of the Steel Company of Scotland, a firm closely associated with Charles Tennant that was formed in 1872 to make steel by the Siemens process. Already by 1878, fourteen Siemens melting furnaces had been erected, and in that year 42,000 long tons of ingots were produced at the company's Hallside (Newton) Works, situated 8 km (5 miles) south-east of Glasgow. Under Riley's leadership, steelmaking in open-hearth furnaces was initiated at a second plant situated at Blochairn. Plates and sections for all aspects of shipbuilding, including boilers, formed the main products; the company also supplied the greater part of the steel for the Forth (Railway) Bridge. Riley was associated with technical modifications which improved the performance of steelmaking furnaces using Siemens's principles. He built a gasfired cupola for melting pig-iron, and constructed the first British "universal" plate mill using three-high rolls (Lauth mill).At the request of French interests, Riley investigated the properties of steels containing various proportions of nickel; the report that he read before the Iron and Steel Institute in 1889 successfully brought to the notice of potential users the greatly enhanced strength that nickel could impart and its ability to yield alloys possessing substantially lower corrodibility.The Steel Company of Scotland paid dividends in the years to 1890, but then came a lean period. In 1895, at the age of 54, Riley moved once more to another employer, becoming General Manager of the Glasgow Iron and Steel Company, which had just laid out a new steelmaking plant at Wishaw, 25 km (15 miles) south-east of Glasgow, where it already had blast furnaces. Still the technical innovator, in 1900 Riley presented an account of his experiences in introducing molten blast-furnace metal as feed for the open-hearth steel furnaces. In the early 1890s it was largely through Riley's efforts that a West of Scotland Board of Conciliation and Arbitration for the Manufactured Steel Trade came into being; he was its first Chairman and then its President.In 1899 James Riley resigned from his Scottish employment to move back to his native Yorkshire, where he became his own master by acquiring the small Richmond Ironworks situated at Stockton-on-Tees. Although Riley's 1900 account to the Iron and Steel Institute was the last of the many of which he was author, he continued to contribute to the discussion of papers written by others.[br]Principal Honours and DistinctionsPresident, West of Scotland Iron and Steel Institute 1893–5. Vice-President, Iron and Steel Institute, 1893–1910. Iron and Steel Institute (London) Bessemer Gold Medal 1887.Bibliography1876, "On steel for shipbuilding as supplied to the Royal Navy", Transactions of the Institute of Naval Architects 17:135–55.1884, "On recent improvements in the method of manufacture of open-hearth steel", Journal of the Iron and Steel Institute 2:43–52 plus plates 27–31.1887, "Some investigations as to the effects of different methods of treatment of mild steel in the manufacture of plates", Journal of the Iron and Steel Institute 1:121–30 (plus sheets II and III and plates XI and XII).27 February 1888, "Improvements in basichearth steel making furnaces", British patent no. 2,896.27 February 1888, "Improvements in regenerative furnaces for steel-making and analogous operations", British patent no. 2,899.1889, "Alloys of nickel and steel", Journal of the Iron and Steel Institute 1:45–55.Further ReadingA.Slaven, 1986, "James Riley", in Dictionary of Scottish Business Biography 1860–1960, Volume 1: The Staple Industries (ed. A.Slaven and S. Checkland), Aberdeen: Aberdeen University Press, 136–8."Men you know", The Bailie (Glasgow) 23 January 1884, series no. 588 (a brief biography, with portrait).J.C.Carr and W.Taplin, 1962, History of the British Steel Industry, Harvard University Press (contains an excellent summary of salient events).JKA
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