was+applied+to+в+а

was applied immediately in

Математика: (this fundamental result of Lebesgue, proved in the earlier years of the century,) был немедленно приложен к (a number of contexts)

was applied immediately in a number of contexts

Общая лексика: (this fundamental result of Lebesgue, proved in the earlier years of the century,) (этот фундаментальный результат Лебега, доказанный в начале нашего столетия, был немедленно) применён в различных конт

(this fundamental result of Lebesgue, proved in the earlier years of the century,) was applied immediately in

Математика: был немедленно приложен к (a number of contexts)

(this fundamental result of Lebesgue, proved in the earlier years of the century,) was applied immediately in a number of contexts

Общая лексика: (этот фундаментальный результат Лебега, доказанный в начале нашего столетия, был немедленно) применён в различных конт

A thick layer of (...) was applied on the surface of

Математика: наносить слой (...)

in relation to which a VAT exemption was applied

Общая лексика: в отношении которого применено освобождение от НДС

A thick layer of was applied on the surface of

Математика: (...) наносить слой (...)

the same rationale was applied in the X case

Jur. des motifs semblables/analogues ont été invoqués dans l'affaire X

equation (29) was applied to set of 20 tests ...

  • уравнение (29) было применено к набору из 20 тестов...

the analysis of ... was treated by ... and applied to ...

  • анализ... проводился... и применялся к...

apply

1) прибегать к; вносить

apply a correction for вносить поправку на

2) реализовывать

A is relatively simple to apply А сравнительно легко / несложно реализовать

3) выполнять / выполняться; подходить (о соотношении, уравнении)

assumption of A does not apply допущение об А не подходит

4) производить / производиться (в знач. выполнять / выполняться; осуществлять / осуществляться)

pre-heat shall be applied in a gradual and uniform manner предварительный подогрев [ свариваемой зоны] производится плавно и равномерно

5) быть применимым / приемлемым ( об уравнении)

and two-dimensional corrections were not applied так что двумерная коррекция здесь была неприемлема

6) иметь силу; сохранять силу

These rules apply only when specified by the owner Эти правила имеют силу только в том случае, если они предписываются владельцем;

These temperature reduction criteria do not apply when Приведенные здесь критерии снижения температуры теряют силу, если;

Equation[1c] does not apply beyond approximately2*10₆ cycles При числе циклов [ напряжений] более 2Т0 уравнение [1 с] теряет силу

7) вступать в силу

in which case the requirements of Section A-5 apply и тогда вступают в силу требования раздела А-5

8) относиться по принадлежности

A is in accordance with the formula stated in each of the following piping classes, as it applies А соответствует формуле, которая приводится в каждом из следующих классов давления в трубопроводах (по принадлежности)

9) быть в норме

conditions apply состояние - в норме (имеется в виду изделия, поставки и т.д.)

10) опробовать

A was applied to В А был опробован на В

11) быть справедливым

fatigue results for A apply only to В результаты испытаний для А справедливы только для В

12) apply to обращаться (напр., за получением разрешения на производство работ)

Thomas, Sidney Gilchrist

SUBJECT AREA: Metallurgy

[br]

b. 16 April 1850 London, England

d. 1 February 1885 Paris, France

[br]

English inventor of basic steelmaking.

[br]

Thomas was educated at Dulwich College and from the age of 17, for the next twelve years, he made his living as a police-court clerk, although he studied chemistry in his spare time as an evening student at Birkbeck College, London. While there, he heard of the difficulties encountered by the Bessemer steelmaking process, which at that time was limited to using phosphorus-free iron. Any of this element present in the iron was oxidized to phosphoric acid, which would not react with the acidic lining in the converter, with the result that it would remain in the iron and render it too brittle to use. Unfortunately, phosphoric iron ores are more common than those free of this harmful element. Thomas was attracted by the view that a fortune awaited anyone who could solve this problem, and was not discouraged by the failure of several august figures in the industry, including Siemens and Lowthian Bell.

Thomas's knowledge of chemistry taught him that whereas an acidic lining allowed the phosphorus to remain in the iron, a basic lining would react with it to form part of the slag, which could then be tapped off. His experiments to find a suitable material were conducted in difficult conditions, in his spare time with meagre apparatus. Finally he found that a converter lined with dolomite, a form of limestone, would succeed, and he appealed to his cousin Percy Carlyle Gilchrist, Chemist at the Blaenavon Ironworks in Monmouthshire, for help in carrying out pilot-scale trials. In 1879 he gave up his police-court job to devote himself to the work, and in the same year they patented the Thomas- Gilchrist process. The first licence to use it was granted to Bolckow, Vaughan \& Co. of Middlesborough, and there the first steel was made in a basic Bessemer converter on 4 April 1879. The process was rapidly taken up and spread widely in Europe and beyond and was applied to other furnaces. Thomas made a fortune, but his health did not long allow him to enjoy it, for he died at the early age of 34.

[br]

Bibliography

Further Reading

L.G.Thompson, 1940, Sidney Gilchrist Thomas, an Invention and Its Consequences, London: Faber.

T.G.Davies, 1978, Blaenavon and Sidney Gilchrist Thomas, Sheffield: Historical Metallurgy Society.

LRD

Viscose

VISCOSE

Viscose was discovered by two English chemists, Charles F. Cross and E. J. Be van, working in collaboration at Kew, near London, who found that when cellulose was treated with disulphide of carbon in the presence of caustic soda, it was converted into a golden yellow plastic compound which dissolved readily in water. A solution of the plastic was of such viscosity that it was named " viscose," a name that was destined to become world famous, seeing that round about 88 per cent of the world production of rayon is now made by the viscose process. In 1892 Cross and Bevan were granted a patent on the viscose process and it was applied to many purposes before the production of a textile thread was successfully accomplished. Fundamentally, the manufacture of viscose rayon is fairly simple. The raw material may be wood pulp, pulp from cotton linters, or a mixture of the two. The greater part of the world's viscose is made from wood pulp. Viscose rayon manufacture comprises seven distinct treatments as follows: - 1. Making and purifying the cotton or wood pulp which forms the cellulose base. 2. Caustic soda treatment of the cellulose base thereby forming alkali cellulose. 3. Treatment of alkali cellulose with carbon disulphide, forming cellulose xanthate. 4. Dissolving the cellulose xanthate in weak caustic soda to form cellulose solution or viscose. 5. Spinning viscose into yarn. 6. Bleaching, purification and finishing of the yarn. 7. Preparing the yarn for weaving and knitting.

Wallis, Sir Barnes Neville

SUBJECT AREA: Aerospace, Weapons and armour

[br]

b. 26 September 1887 Ripley, Derbyshire, England

d. 30 October 1979 Leatherhead, Surrey, England

[br]

English aeronautical designer and inventor.

[br]

Wallis was apprenticed first at Thames Engineering Works, and then, in 1908, at John Samuel White's shipyard at Cowes. In 1913, the Government, spurred on by the accelerating development of the German Zeppelins (see Zeppelin, Ferdinand von), ordered an airship from Vickers; Wallis was invited to join the design team. Thus began his long association with aeronautical design and with Vickers. This airship, and the R80 that followed it, were successfully completed, but the military lost interest in them.

In 1924 the Government initiated a programme for the construction of two airships to settle once and for all their viability for long-dis-tance air travel. The R101 was designed by a Government-sponsored team, but the R100 was designed by Wallis working for a subsidiary of Vickers. The R100 took off on 29 July 1930 for a successful round trip to Canada, but the R101 crashed on its first flight on 4 October, killing many of its distinguished passengers. The shock of this disaster brought airship development in Britain to an abrupt end and forced Wallis to direct his attention to aircraft.

In aircraft design, Wallis is known for his use of geodesic construction, which combined lightness with strength. It was applied first to the single-engined "Wellesley" and then the twin-en-gined "Wellington" bomber, which first flew in 1936. With successive modifications, it became the workhorse of RAF Bomber Command during the Second World War until the autumn of 1943, when it was replaced by four-engined machines. In other areas, it remained in service until the end of the war and, in all, no fewer than 11,461 were built.

Wallis is best known for his work on bomb design, first the bouncing bomb that was used to breach the Möhne and Eder dams in the Ruhr district of Germany in 1943, an exploit immortalized in the film Dambusters. Encouraged by this success, the authorities then allowed Wallis to realize an idea he had long urged, that of heavy, penetration bombs. In the closing stages of the war, Tallboy, of 12,000 lb (5,400 kg), and the 10-ton Grand Slam were used to devastating effect.

After the Second World War, Wallis returned to aeronautical design and was given his own department at Vickers to promote his ideas, principally on variable-geometry or swing-wing aircraft. Over the next thirteen years he battled towards the prototype stage of this revolutionary concept. That never came, however; changing conditions and requirements and increasing costs led to the abandonment of the project. Bit-terly disappointed, Wallis continued his researches into high-speed aircraft until his retirement from Vickers (by then the British Aircraft Corporation), in 1971.

[br]

Principal Honours and Distinctions

Knighted 1968. FRS 1945.

Further Reading

J.Morpurgo, 1972, Barnes Wallis: A Biography, London: Longman (a readable account, rather biased in Wallis's favour).

C.J.Heap, 1987, The Papers of Sir Barnes Wallis (1887–1979) in the Science Museum Library, London: Science Museum; with a biographical introd. by L.R.Day.

LRD

Anschütz, Ottomar

SUBJECT AREA: Photography, film and optics

[br]

b. 1846 Lissa, Prussia (now Leszno, Poland) d. 1907

[br]

German photographer, chronophotographer ana inventor.

[br]

The son of a commercial photographer, Anschütz entered the business in 1868 and developed an interest in the process of instantaneous photography. The process was very difficult with the contemporary wet-plate process, but with the introduction of the much faster dry plates in the late 1870s he was able to make progress. Anschütz designed a focal plane shutter capable of operating at speeds up to 1/1000 of a second in 1883, and patented his design in 1888. it involved a vertically moving fabric roller-blind that worked at a fixed tension but had a slit the width of which could be adjusted to alter the exposure time. This design was adopted by C.P.Goerz, who from 1890 manufactures a number of cameras that incorporated it.

Anschütz's action pictures of flying birds and animals attracted the attention of the Prussian authorities, and in 1886 the Chamber of Deputies authorized financial support for him to continue his work, which had started at the Hanover Military Institute in October 1885. Inspired by the work of Eadweard Muybridge in America, Anschütz had set up rows of cameras whose focal-plane shutters were released in sequence by electromagnets, taking twenty-four pictures in about three-quarters of a second. He made a large number of studies of the actions of people, animals and birds, and at the Krupp artillery range at Meppen, near Essen, he recorded shells in flight. His pictures were reproduced, and favourably commented upon, in scientific and photographic journals.

To bring the pictures to the public, in 1887 he created the Electro-Tachyscope. The sequence negatives were printed as 90 x 120 mm transparencies and fixed around the circumference of a large steel disc. This was rotated in front of a spirally wound Geissler tube, which produced a momentary brilliant flash of light when a high voltage from an induction coil was applied to it, triggered by contacts on the steel disc. The flash duration, about 1/1000 of a second, was so short that it "froze" each picture as it passed the tube. The pictures succeeded each other at intervals of about 1/30 of a second, and the observer saw an apparently continuously lit moving picture. The Electro-Tachyscope was shown publicly in Berlin at the Kulturministerium from 19 to 21 March 1887; subsequently Siemens \& Halske manufactured 100 machines, which were shown throughout Europe and America in the early 1890s. From 1891 his pictures were available for the home in the form of the Tachyscope viewer, which used the principle of the zoetrope: sequence photographs were printed on long strips of thin card, perforated with narrow slots between the pictures. Placed around the circumference of a shallow cylinder and rotated, the pictures could be seen in life-like movement when viewed through the slots.

In November 1894 Anschütz displayed a projector using two picture discs with twelve images each, which through a form of Maltese cross movement were rotated intermittently and alternately while a rotating shutter allowed each picture to blend with the next so that no flicker occurred. The first public shows, given in Berlin, were on a screen 6×8 m (20×26 ft) in size. From 22 February 1895 they were shown regularly to audiences of 300 in a building on the Leipzigstrasse; they were the first projected motion pictures seen in Germany.

[br]

Further Reading

J.Deslandes, 1966, Histoire comparée du cinéma, Vol. I, Paris. B.Coe, 1992, Muybridge and the Chronophotographers, London.

BC

Coat

COAT (Fabric)

Very strong and coarse jute or hemp plain weave fabric, which is usually tarred and used on ships. ————————

COAT

The garment so called at present was not seen in its original shape previous to the second half of the 17th century, but the word was applied to articles of costume for both sexes both here and on the Continent as early as the 13th century. About this time the " Cote " in France was a close body-garment, over which, as its name implies, the " Surcote " was worn at pleasure, in or out of doors. Henry VIII wore long coats, demi coats, short coats, riding coats, coats with shirts, with loose sleeves and without any-Most of these coats were composed of bright coloured materials, cloth of gold and damask silver, striped with purple velvet, white satin, purple and black velvet. In the reign of Charles II was first seen what in these days would be popularly termed a coat. During the reigns of James II and William III the coat only altered in having sleeves looser, longer, and with heavy cuffs.

Carroll, Thomas

SUBJECT AREA: Agricultural and food technology

[br]

b. 1888 Melbourne, Victoria, Australia

d. 22 February 1968 Australia

[br]

Australian engineer responsible for many innovations in combine-harvester design, and in particular associated with the Massey Harris No. 20 used in the "Harvest Brigade" during the Second World War.

[br]

Carroll worked first with the Buckeye Harvester Co., then with J.J.Mitchell \& Co. In 1911 he was hired by the Argentinian distributor for Massey Harris to help in the introduction of their new horse-drawn reaper-thresher. Carroll recommended modifications to suit Argentinian conditions, and these resulted in the production of a new model. In 1917 he joined the Toronto staff of Massey Harris as a product design leader, the No. 5 reaper-thresher being the first designed under him. Many significant new developments can be attributed to Carroll: welded sections, roller chains, oil-bath gears, antifriction ball bearings and the detachable cutting table allowing easy transfer of combines between fields were all innovations of which he was the source.

In the 1930s he became Chief Engineer with responsibility for the design of a self-propelled harvester. The 20 SP was tested in Argentina only eight months after design work had begun, and it was to this machine that the name "combine harvester" was applied for the first time. Improvements to this original design produced a lighter 12 ft (3.65 m) cut machine which came off the production line in 1941. Three years later 500 of these machines were transported to the southern United States, and then gradually harvested their way northwards as the corn ripened. It has been estimated that the famous "Harvest Brigade" harvested over 1 million acres, putting 25 million bushels into store, with a saving in excess of 300,000 labour hours and half a million gallons of fuel.

Carroll retired from Massey Ferguson in 1961.

[br]

Principal Honours and Distinctions

American Society of Agricultural Engineers C.H. McCormick Gold Medal 1958.

Bibliography

1948, "Basic requirements in the design and development of the self propelled combine"

Agricultural Engineer. 29(3), 101–5.

Further Reading

G.Quick and W.Buchele, 1978, The Grain Harvesters, American Society of Agricultural Engineers (provides a detailed account of the development of the combine harvester).

K.M.Coppick, 1972, gave an account of the wartime effort, which he mistakenly called "Massey Ferguson Harvest Brigade", presented to the Canadian Society for

Agricultural Engineers, Paper 72–313.

AP

Guo Shoujing (Kuo Shou-Ching)

SUBJECT AREA: Canals, Civil engineering

[br]

b. 1231 China

d. 1316 China

[br]

Chinese mathematician, astronomer and civil engineer.

[br]

First, from 1262, he was engaged in hydraulic-engineering works for Kublai Khan. He began astronomical and calendrical investigations in 1276, and became the greatest astronomer of the Yuan dynasty. He perfected interpolation formulae (a method of finite differences) and was the founder of the study of spherical trigonometry in China; this was applied to the circles of the heavenly sphere. He planned the Ji Zhou, the summit section of the Grand Canal through the Shandong foothills, in 1283. Although the canal had to await further improvement before it could become fully effective, it was nevertheless the world's first successful entirely artificial summit canal.

Guo Shoujing was responsible for the construction of the Tong Hui He (Channel of Communicating Grace) canal with twenty lock gates in 1293, in addition to the overhaul of the entire Grand Canal. He constructed a number of devices, including 40 ft (12 m) gnomons in 1276, with which he made some of the most accurate measurements of the sun's solstitial shadows, the results of which were collected in a book that is now lost. Between 1276 and 1279 he also constructed at least one water-driven mechanical escapement clock with sophisticated jack work, and the Beijing observatory and its equipment.

[br]

Further Reading

J.Needham, Science and Civilisation in China, Cambridge: Cambridge University Press, 1959–1971, vols III, pp. 48–50, 109–10, 294, 296, 299, 349, 350; IV. 2, pp. 504–5; IV.

3, pp. 312ff., 319, 355; Heavenly Clockwork, 1960, pp. 134, 136ff., 159, 160, 163;

Clerks and Craftsmen in China and the West, 1970, pp. 2, 5, 9–10, 16, 96, 398.

LRD

Pierce, John Robinson

SUBJECT AREA: Aerospace, Electronics and information technology, Telecommunications

[br]

b. 27 March 1910 Des Moines, Iowa, USA

[br]

American scientist and communications engineer said to be the "father" of communication satellites.

[br]

From his high-school days, Pierce showed an interest in science and in science fiction, writing under the pseudonym of J.J.Coupling. After gaining Bachelor's, Master's and PhD degrees at the California Institute of Technology (CalTech) in Pasadena in 1933, 1934 and 1936, respectively, Pierce joined the Bell Telephone Laboratories in New York City in 1936. There he worked on improvements to the travelling-wave tube, in which the passage of a beam of electrons through a helical transmission line at around 7 per cent of the speed of light was made to provide amplification at 860 MHz. He also devised a new form of electrostatically focused electron-multiplier which formed the basis of a sensitive detector of radiation. However, his main contribution to electronics at this time was the invention of the Pierce electron gun—a method of producing a high-density electron beam. In the Second World War he worked with McNally and Shepherd on the development of a low-voltage reflex klystron oscillator that was applied to military radar equipment.

In 1952 he became Director of Electronic Research at the Bell Laboratories' establishment, Murray Hill, New Jersey. Within two years he had begun work on the possibility of round-the-world relay of signals by means of communication satellites, an idea anticipated in his early science-fiction writings (and by Arthur C. Clarke in 1945), and in 1955 he published a paper in which he examined various possibilities for communications satellites, including passive and active satellites in synchronous and non-synchronous orbits. In 1960 he used the National Aeronautics and Space Administration 30 m (98 1/2 ft) diameter, aluminium-coated Echo 1 balloon satellite to reflect telephone signals back to earth. The success of this led to the launching in 1962 of the first active relay satellite (Telstar), which weighed 170 lb (77 kg) and contained solar-powered rechargeable batteries, 1,000 transistors and a travelling-wave tube capable of amplifying the signal 10,000 times. With a maximum orbital height of 3,500 miles (5,600 km), this enabled a variety of signals, including full bandwidth television, to be relayed from the USA to large receiving dishes in Europe.

From 1971 until his "retirement" in 1979, Pierce was Professor of Electrical Engineering at CalTech, after which he became Chief Technologist at the Jet Propulsion Laboratories, also in Pasadena, and Emeritus Professor of Engineering at Stanford University.

[br]

Principal Honours and Distinctions

Institute of Electrical and Electronics Engineers Morris N.Liebmann Memorial Award 1947; Edison Medal 1963; Medal of Honour 1975. Franklin Institute Stuart Ballantine Award 1960. National Medal of Science 1963. Danish Academy of Science Valdemar Poulsen Medal 1963. Marconi Award 1974. National Academy of Engineering Founders Award 1977. Japan Prize 1985. Arthur C.Clarke Award 1987. Honorary DEng Newark College of Engineering 1961. Honorary DSc Northwest University 1961, Yale 1963, Brooklyn Polytechnic Institute 1963. Editor, Proceedings of the Institute of Radio Engineers 1954–5.

Bibliography

23 October 1956, US patent no. 2,768,328 (his development of the travelling-wave tube, filed on 5 November 1946).

1947, with L.M.Field, "Travelling wave tubes", Proceedings of the Institute of Radio

Engineers 35:108 (describes the pioneering improvements to the travelling-wave tube). 1947, "Theory of the beam-type travelling wave tube", Proceedings of the Institution of

Radio Engineers 35:111. 1950, Travelling Wave Tubes.

1956, Electronic Waves and Messages. 1962, Symbols, Signals and Noise.

1981, An Introduction to Information Theory: Symbols, Signals and Noise: Dover Publications.

1990, with M.A.Knoll, Signals: Revolution in Electronic Communication: W.H.Freeman.

KF

Röntgen, Wilhelm Conrad

SUBJECT AREA: Medical technology, Photography, film and optics

[br]

b. 27 March 1845 Lennep, Prussia (now Remscheid, Germany)

d. 10 February 1923 Munich, Germany

[br]

German physicist who discovered X-rays.

[br]

Expelled from school and so unable to attend university, Röntgen studied engineering at Zurich Polytechnic. After graduation he obtained a post as assistant to the distinguished German physicist Kundt and eventually secured an appointment at the University of Würzburg in Bavaria. He was successively Professor of Physics at the universities of Strasbourg (1876), Giessen (1879), Würzburg (1888) and Munich (1900–20), but he died in abject poverty. At various times he studied piezo-electricity; heat absorption by and the specific heat of gases; heat conduction in crystals; elasticity; and the capillary action of fluids. In 1895, whilst experimenting with the Crookes tube, a partially evacuated tube invented some seven years earlier, he observed that when a high voltage was applied across the tube, a nearby piece of barium platinocyanide produced light. He theorized that when the so-called cathode rays produced by the tube (electrons, as we now know) struck the glass wall, some unknown radiation occurred that was able to penetrate light materials and affect photographic plates. These he called X-rays (they also became known as Röntgen rays), but he believed (erroneously) that they bore no relation to light rays. For this important discovery he was awarded the Nobel Prize for Physics, but, sadly, he died in abject poverty during the hyperinflation of the 1920s.

[br]

Principal Honours and Distinctions

First Nobel Prize for Physics 1901.

Bibliography

1895, "A new kind of radiation", Meeting of the Würzburg Physical-Medical Society (December) (reported Röntgen's discovery of X-rays).

Further Reading

O.Glasser, 1945, Dr. W.C.Röntgen (biography).

KF