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81 ikhtiarkan
devise, devised, devised, devising -
82 commentīcius
commentīcius (not -tītius), adj. [comminiscor], thought out, devised, fabricated, invented, new: nomina.—Feigned, pretended, ideal, imaginary: civitas Platonis: di: crimen, false.* * *commenticia, commenticium ADJinvented, devised, improvised; imaginary; fabricated/fictitious; forged, false -
83 commentus
commentus adj. [P. of comminiscor], devised, invented, feigned, fictitious: funera, O.: crimen, L.* * *commenta, commentum ADJfeigned, pretended, fabricated, devised, fictitious, invented -
84 конструировать
•The air hoists are designed (or constructed) to be easily moved and installed by one man.
•Two new pumping systems have been devised:
•This electrical equipment is engineered for a particular job.
* * *Конструировать -- to design, to devise, to engineerThe upper cover is designed to be easily removed and repaired in the field.To obviate the problem, a new instrument was devised at our laboratory.Русско-английский научно-технический словарь переводчика > конструировать
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85 Applegath, Augustus
SUBJECT AREA: Paper and printing[br]fl. 1816–58 London, England[br]English printer and manufacturer of printing machinery.[br]After Koenig and Bauer had introduced the machine printing-press and returned to Germany, it fell to Applegath and his mechanic brother-in-law Edward Cooper to effect improvements. In particular, Applegath succeeded Koenig and Bauer as machine specialist to The Times newspaper, then in the vanguard of printing technology.Applegath and Cooper first came into prominence when the Bank of England began to seek ways of reducing the number of forged banknotes. In 1816 Cooper patented a device for printing banknotes from curved stereotypes fixed to a cylinder. These were inked and printed by the rotary method. Although Applegath and Cooper were granted money to develop their invention, the Bank did not pursue it. The idea of rotary printing was interesting, but it was not followed up, possibly due to lack of demand.Applegath and Cooper were then engaged by John Walter of The Times to remedy defects in Koenig and Bauer's presses; in 1818 Cooper patented an improved method of inking the forme and Applegath also took out patents for improvements. In 1821 Applegath had enough experience of these presses to set up as a manufacturer of printing machinery in premises in Duke Street, Blackfriars, in London. Increases in the size and circulation of The Times led Walter to ask Applegath to build a faster press. In 1827 he produced a machine with the capacity of four presses, his steam-driven four-feeder press.Its flat form carrying the type passed under four impression cylinders in a row. It could make 4,200 impressions an hour and sufficed to print The Times for twenty years, until it was superseded by the rotary press devised by Hoe. By 1826, however, Applegath was in financial difficulties; he sold his Duke Street workshop to William Clowes, a book printer. In the following year he gave up being a full-time manufacturer of printing machinery and turned to silk printing. In 1830 he patented a machine for printing rolls of calico and silk from bent intaglio plates.In 1848 Applegath was persuaded by The Times to return to newspaper printing. He tackled rotary printing without the benefit of curved printing plates and roll paper feed, and he devised a large "type revolving" machine which set the pattern for newspaper printing-presses for some twenty years.[br]Further ReadingJ.Moran, 1973, Printing Presses, London: Faber \& Faber.LRD -
86 Bunsen, Robert Wilhelm
SUBJECT AREA: Chemical technology[br]b. 31 March 1811 Göttingen, Germanyd. 16 August 1899 Heidelberg, Germany[br]German chemist, pioneer of chemical spectroscopy.[br]Bunsen's father was Librarian and Professor of Linguistics at Göttingen University and Bunsen himself studied chemistry there. Obtaining his doctorate at the age of only 19, he travelled widely, meeting some of the leading chemists of the day and visiting many engineering works. On his return he held various academic posts, finally as Professor of Chemistry at Heidelberg in 1852, a post he held until his retirement in 1889.During 1837–41 Bunsen studied a series of compounds shown to contain the cacodyl (CH3)2As-group or radical. The elucidation of the structure of these compounds gave support to the radical theory in organic chemistry and earned him fame, but it also cost him the sight of an eye and other ill effects resulting from these dangerous and evil-smelling substances. With the chemist Gustav Robert Kirchhoff (1824–87), Bunsen pioneered the use of spectroscopy in chemical analysis from 1859, and with its aid he discovered the elements caesium and rubidium. He developed the Bunsen cell, a zinc-carbon primary cell, with which he isolated a number of alkali and other metals by electrodeposition from solution or electrolysis of fused chlorides.Bunsen's main work was in chemical analysis, in the course of which he devised some important laboratory equipment, such as a filter pump. The celebrated Bunsen gas burner was probably devised by his technician Peter Desdega. During 1838–44 Bunsen applied his methods of gas analysis to the study of the gases produced by blast furnaces for the production of cast iron. He demonstrated that no less than 80 per cent of the heat was lost during smelting, and that valuable gaseous by-products, such as ammonia, were also lost. Lyon Playfair in England was working along similar lines, and in 1848 the two men issued a paper, "On the gases evolved from iron furnaces", to draw attention to these drawbacks.[br]Bibliography1904, Bunsen's collected papers were published in 3 vols, Leipzig.Further ReadingG.Lockemann, 1949, Robert Wilhelm Bunsen: Lebensbild eines deutschen Forschers, Stuttgart.T.Curtin, 1961, biog. account, in E.Farber (ed.), Great Chemists, New York, pp. 575–81. Henry E.Roscoe, 1900, "Bunsen memorial lecture, 29th March 1900", Journal of theChemical Society 77:511–54.LRD -
87 Hoe, Richard March
SUBJECT AREA: Paper and printing[br]b. 12 September 1812 New York, USAd. 7 June 1886 Florence, Italy[br]American inventor of the rotary printing press.[br]He was the son of Robert Hoe, a printer who improved the cylinder press invented by David Napier. At the age of 15 he entered his father's business, taking full control of it three years later. Newspaper publishers demanded ever-increasing speeds of output from the printing press, and Hoe was one of those who realized that the speed was limited by the reciprocating action of the flat-bed machine. In 1846 he constructed a rotary press in which a central cylinder carried the type and flat sheets of paper were fed to smaller impression cylinders ranged around it. This kind of press, with four impression cylinders, was first used to print the Philadelphia Public Ledger in 1847, and was able to print 8,000 papers per hour. Such presses reigned supreme for newspaper printing in many countries for twenty-five years: in 1857, for example, The Times had a ten-feeder machine making 20,000 impressions per hour. Even so, the quest for speed, now limited by the single-sheet feed, continued. William Bullock (1813–67) introduced continuous roll or web feed for the Philadelphia Inquirer in 1865, and the next year The Times followed suit with the web-fed Walter press. In 1871 Hoe devised a machine that combined all the advantages of the existing machines, producing a rotary, web, perfecting (printing on both sides of the paper at once) machine, first used in the office of the New York Tribune. Ten years later the Hoe Company devised a folding machine to fold the copies as they came off the press: the modern newspaper printing press had arrived. In addition to his contributions to the printing industry, Hoe was a good employer, arranging free evening classes and other welfare services for his apprentices.[br]Further ReadingR.Hoe, 1902, A Short History of the Printing Press, New York. S.D.Tucker, A History of K.Hoe \& Co. New York.LRD -
88 Pixii, Antoine Hippolyte
SUBJECT AREA: Electricity[br]b. 1808 Franced. 1835[br]French instrument maker who devised the first machine to incorporate the basic elements of a modern electric generator.[br]Mechanical devices to transform energy from a mechanical to an electrical form followed shortly after Faraday's discovery of induction. One of the earliest was Pixii's magneto generator. Pixii had been an instrument maker to Arago and Ampère for a number of years and his machine was first announced to the Academy of Sciences in Paris in September 1832. In this hand-driven generator a permanent magnet was rotated in close proximity to two coils on soft iron cores, producing an alternating current. Subsequently Pixii adapted to a larger version of his machine a "see-saw" switch or commutator devised by Ampère, in order to obtain a unidirectional current. The machine provided a current similar to that obtained with a chemical cell and was capable of decomposing water into oxygen and hydrogen. It was the prototype of many magneto-electric machines which followed.[br]Principal Honours and DistinctionsAcademy of Sciences, Paris, Gold Medal 1832.Further ReadingB.Bowers, 1982, A History of Electric Light and Power, London, pp. 70–2 (describes the development of Pixii's generator).C.Jackson, 1833, "Notice of the revolving electric magnet of Mr Pixii of Paris", American Journal of Science 24:146–7.GWBiographical history of technology > Pixii, Antoine Hippolyte
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89 Root, Elisha King
[br]b. 10 May 1808 Ludlow, Massachusetts, USAd. 31 August 1865 Hartford, Connecticut, USA[br]American mechanical engineer and inventor.[br]After an elementary education, Elisha K.Root was apprenticed as a machinist and worked in that occupation at Ware and Chicopee Falls, Massachusetts. In 1832 he went to Collinsville, Connecticut, to join the Collins Company, manufacturers of axes. He started as a lathe hand but soon became Foreman and, in 1845, Superintendent. While with the company, he devised and patented special-purpose machinery for forming axes which transformed the establishment from a primitive workshop to a modern factory.In 1849 Root was offered positions by four different manufacturers and accepted the post of Superintendent of the armoury then being planned at Hartford, Connecticut, by Samuel Colt for the manufacture of his revolver pistol, which he had invented in 1835. Initial acceptance of the revolver was slow, but by the mid1840s Colt had received sufficient orders to justify the establishment of a new factory and Root was engaged to design and install the machinery. The principle of interchangeable manufacture was adopted, and Root devised special machines for boring, rifling, making cartridges, etc., and a system of jigs, fixtures, tools and gauges. One of these special machines was a drop hammer that he invented and patented in 1853 and which established the art of die-forging on a modern basis. He was also associated with F.A. Pratt in the design of the "Lincoln" milling machine in 1855.When Colt died in 1862, Root became President of the company and continued in that capacity until his own death. It was said that he was one of the ablest and most highly paid mechanics from New England and that he was largely responsible for the success of both the Collins and the Colt companies.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (describes Root's work at the Colt Armory).Paul Uselding, 1974, "Elisha K.Root, Forging, and the “American System”", "Elisha K.Root, forging, and the “American System”", Technology and Culture 15:543–68 (provides further biographical details, his work with the Collins Company and a list of his patents).RTS -
90 Soemmerring, Samuel Thomas von
SUBJECT AREA: Telecommunications[br]b. 28 January 1755 Torun, Poland (later Thorn, Prussia)d. 2 March 1830 Frankfurt, Germany[br]German physician who devised an early form of electric telegraph.[br]Soemmerring appears to have been a distinguished anatomist and physiologist who in 1805 became a member of the Munich Academy of Sciences. Whilst experimenting with electric currents in acid solutions in 1809, he observed the bubbles of gases produced by the dissociation process. Using this effect at the receiver, he devised a telegraph consisting of twenty-six parallel wires (one for each letter of the alphabet) and was able to transmit messages over a distance of 2 miles (3 km), but the idea was not commercially viable. In 1812, with the help of Schilling, he experimented with soluble indiarubber as a possible cable insulator.[br]Principal Honours and DistinctionsKnight of the Order of St Anne of Russia 1818. Hon. Member of St Petersburg Imperial Academy of Sciences 1819. FRS 1827.BibliographySoemmerring's "electrolytic" telegraph was described in a paper read before the Munich Academy of Sciences on 29 August 1809.Further ReadingJ.J.Fahie, 1884, A History of Electric Telegraphy to the Year 1837, London: E\&F Spon. E.Hawkes, 1927, Pioneers of Wireless, London: Methuen.See also: Morse, Samuel Finley BreezeKFBiographical history of technology > Soemmerring, Samuel Thomas von
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91 Talbot, William Henry Fox
SUBJECT AREA: Photography, film and optics[br]b. 11 February 1800 Melbury, Englandd. 17 September 1877 Lacock, Wiltshire, England[br]English scientist, inventor of negative—positive photography and practicable photo engraving.[br]Educated at Harrow, where he first showed an interest in science, and at Cambridge, Talbot was an outstanding scholar and a formidable mathematician. He published over fifty scientific papers and took out twelve English patents. His interests outside the field of science were also wide and included Assyriology, etymology and the classics. He was briefly a Member of Parliament, but did not pursue a parliamentary career.Talbot's invention of photography arose out of his frustrating attempts to produce acceptable pencil sketches using popular artist's aids, the camera discura and camera lucida. From his experiments with the former he conceived the idea of placing on the screen a paper coated with silver salts so that the image would be captured chemically. During the spring of 1834 he made outline images of subjects such as leaves and flowers by placing them on sheets of sensitized paper and exposing them to sunlight. No camera was involved and the first images produced using an optical system were made with a solar microscope. It was only when he had devised a more sensitive paper that Talbot was able to make camera pictures; the earliest surviving camera negative dates from August 1835. From the beginning, Talbot noticed that the lights and shades of his images were reversed. During 1834 or 1835 he discovered that by placing this reversed image on another sheet of sensitized paper and again exposing it to sunlight, a picture was produced with lights and shades in the correct disposition. Talbot had discovered the basis of modern photography, the photographic negative, from which could be produced an unlimited number of positives. He did little further work until the announcement of Daguerre's process in 1839 prompted him to publish an account of his negative-positive process. Aware that his photogenic drawing process had many imperfections, Talbot plunged into further experiments and in September 1840, using a mixture incorporating a solution of gallic acid, discovered an invisible latent image that could be made visible by development. This improved calotype process dramatically shortened exposure times and allowed Talbot to take portraits. In 1841 he patented the process, an exercise that was later to cause controversy, and between 1844 and 1846 produced The Pencil of Nature, the world's first commercial photographically illustrated book.Concerned that some of his photographs were prone to fading, Talbot later began experiments to combine photography with printing and engraving. Using bichromated gelatine, he devised the first practicable method of photo engraving, which was patented as Photoglyphic engraving in October 1852. He later went on to use screens of gauze, muslin and finely powdered gum to break up the image into lines and dots, thus anticipating modern photomechanical processes.Talbot was described by contemporaries as the "Father of Photography" primarily in recognition of his discovery of the negative-positive process, but he also produced the first photomicrographs, took the first high-speed photographs with the aid of a spark from a Leyden jar, and is credited with proposing infra-red photography. He was a shy man and his misguided attempts to enforce his calotype patent made him many enemies. It was perhaps for this reason that he never received the formal recognition from the British nation that his family felt he deserved.[br]Principal Honours and DistinctionsFRS March 1831. Royal Society Rumford Medal 1842. Grand Médaille d'Honneur, L'Exposition Universelle, Paris, 1855. Honorary Doctorate of Laws, Edinburgh University, 1863.Bibliography1839, "Some account of the art of photographic drawing", Royal Society Proceedings 4:120–1; Phil. Mag., XIV, 1839, pp. 19–21.8 February 1841, British patent no. 8842 (calotype process).1844–6, The Pencil of Nature, 6 parts, London (Talbot'a account of his invention can be found in the introduction; there is a facsimile edn, with an intro. by Beamont Newhall, New York, 1968.Further ReadingH.J.P.Arnold, 1977, William Henry Fox Talbot, London.D.B.Thomas, 1964, The First Negatives, London (a lucid concise account of Talbot's photograph work).J.Ward and S.Stevenson, 1986, Printed Light, Edinburgh (an essay on Talbot's invention and its reception).H.Gernsheim and A.Gernsheim, 1977, The History of Photography, London (a wider picture of Talbot, based primarily on secondary sources).JWBiographical history of technology > Talbot, William Henry Fox
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92 в соответствии с
. в зависимости от; изменяться в соответствии с кривой; классификация по; находиться в соответствии с; согласно; соответствие•In line with this assumption, we have devised a model of...
•To modify the beach profile in response to changing wave conditions...
•Evaporators for marine use are classed as horizontal or vertical by (or according to, or depending on) the position of their tubes.
•The test report is performed in accord( ance) (or conformity, or compliance) with the specifications.
•In keeping with the limitation of only four orbitals, the formation of double or triple bonds between atoms of these elements reduces the coordination number of the central atom.
•The machine is designed and built to higher standards of accuracy.
•The sketch can be interpreted in terms of either system.
•The console pressure can be regulated to match the individual gauge range.
•In the reactors designed around this approach the energy-carrying neutrons released by thermonuclear reactions will be absorbed in a lithium blanket.
•These techniques must be selected in relation to the properties of the substances being separated.
* * *В соответствии с (нормами)The specimens were tested at a frequency of approximately 130 Hz, following ASTM E466 [...].В соответствии с -- in accordance with, in agreement with, in keeping with, in line with, in compliance with, consistent with; as required by, to match, following, according to; in step with (синхронно); per (в инструкциях); to conform to (о требованиях стандарта и т. п.), pursuant to (в письмах)Fatigue life results of the bearings tested were statistically analyzed in accordance with the methods of [...].In agreement with this, it was found that the low ф machine went into a part-span stall.Also, in keeping with practice, the inter-plate spacing was made equal to the plate length.The section on low-pressure heating boilers now had testing and marking requirements in line with those of the power boiler section.(Tf -- Ts) is kept fixed by increasing Ts with time as required by the surface temperature, Ts.Normally, this value of radial clearance is established to match the bearing size.According to a previous investigation of dressing [...], fracture can occur within the grain.The Sh number increases in step with the wake turbulence.Install housing and grease per figure and table.They are metered by orifice plate assemblies built to conform to BS 1042.Pursuant to your request, I am confirming our consent to the publication of the book in two volumes.Floating roof tanks generally do not require protection when installed in compliance with Section...Русско-английский научно-технический словарь переводчика > в соответствии с
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93 вводить
•The medicine is administered to the patients (or into the organism).
•Gadolinium is incorporated in plastic scintillators.
•The tracer is injected into a vein.
•The probe can easily be inserted into the body.
•The gas could be introduced into the system.
•The fuel is injected into the chamber.
•All materials affect a magnetic field in(to) which they are inserted.
•A group of volunteers received injections of the labelled morphine.
•The tracer is infused intravenously.
* * *Вводить -- to introduce, to incorporate (внедрять, предусматривать); to devise (для облегчения расчёта и т. п.); to insert (вставлять); to administer (лекарство), to inject (путем инъекции); to coin (о термине)Thus, it is convenient to introduce a pressure ratio parameter defined as p.A "preload" element is devised that contracts a prescribed amount.—вводить поправку наРусско-английский научно-технический словарь переводчика > вводить
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94 веками
•Down the centuries many different systems of measurement have been devised and abandoned.
Русско-английский научно-технический словарь переводчика > веками
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95 весьма перспективный в области
•A method of considerable promise for the production of "superheavy" elements has been devised.
Русско-английский научно-технический словарь переводчика > весьма перспективный в области
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96 в соответствии с
. в зависимости от; изменяться в соответствии с кривой; классификация по; находиться в соответствии с; согласно; соответствие•In line with this assumption, we have devised a model of...
•To modify the beach profile in response to changing wave conditions...
•Evaporators for marine use are classed as horizontal or vertical by (or according to, or depending on) the position of their tubes.
•The test report is performed in accord( ance) (or conformity, or compliance) with the specifications.
•In keeping with the limitation of only four orbitals, the formation of double or triple bonds between atoms of these elements reduces the coordination number of the central atom.
•The machine is designed and built to higher standards of accuracy.
•The sketch can be interpreted in terms of either system.
•The console pressure can be regulated to match the individual gauge range.
•In the reactors designed around this approach the energy-carrying neutrons released by thermonuclear reactions will be absorbed in a lithium blanket.
•These techniques must be selected in relation to the properties of the substances being separated.
Русско-английский научно-технический словарь переводчика > в соответствии с
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97 веками
•Down the centuries many different systems of measurement have been devised and abandoned.
Русско-английский научно-технический словарь переводчика > веками
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98 весьма перспективный в области
•A method of considerable promise for the production of "superheavy" elements has been devised.
Русско-английский научно-технический словарь переводчика > весьма перспективный в области
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99 до сих пор
•Atomic hydrogen remains a gas at the lowest temperature we have yet investigated.
•So far it has been assumed that the field applied to the gas is uniform.
•The designs discussed thus (or so) far provide examples of...
•To this point the assumption has been made that...
•The discussion up till (or to) now (or up to the present) has been based upon...
•This can be done more rapidly and accurately than has hitherto been possible.
•Up to this point it has been possible to work entirely with the concept of...
•The applications heretofore have tended towards special purpose machines.
•The other investigations mentioned up until this point can be arranged without sending the patient to hospital.
Русско-английский научно-технический словарь переводчика > до сих пор
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100 изящный метод
•For this purpose an elegant method has been devised.
Русско-английский научно-технический словарь переводчика > изящный метод
См. также в других словарях:
devised — index controlled (automatic), tactical Burton s Legal Thesaurus. William C. Burton. 2006 … Law dictionary
Devised — Devise De*vise , v. t. [imp. & p. p. {Devised}; p. pr. & vb. n. {Devising}.] [OF. deviser to distribute, regulate, direct, relate, F., to chat, fr. L. divisus divided, distributed, p. p. of dividere. See {Divide}, and cf. {Device}.] 1. To form in … The Collaborative International Dictionary of English
devised — un·devised; … English syllables
Devised theatre — (also called collaborative creation, particularly in the United States [1]) is a form of theatre where the script originates not from a writer or writers, but from collaborative, usually improvisatory, work by a group of people (usually, but not… … Wikipedia
devised by will — index testamentary Burton s Legal Thesaurus. William C. Burton. 2006 … Law dictionary
devised — de·vise || dɪ vaɪz v. plan, invent; bequeath property through a will … English contemporary dictionary
devised — … Useful english dictionary
Self-devised — Self de*vised , a. Devised by one s self. [1913 Webster] … The Collaborative International Dictionary of English
well-devised — index politic, premeditated Burton s Legal Thesaurus. William C. Burton. 2006 … Law dictionary
A system could not well have been devised more studiously hostile to human happiness than marriage. — См. Брак холодит душу … Большой толково-фразеологический словарь Михельсона (оригинальная орфография)
self-devised — adj. * * * … Universalium