processing+world

Danone

   Danone is the world's leading dairy company, and is known in the USAas Dannon. Its principal sectors of activity are today fresh milk products (yoghurts, desserts), baby food and mineral water. It distributes some of France's best known mineral waters, notably Volvic and Evian, and is the no. 2 worldwide in bottled mineral water. Danone became France's leading food-processing group in 1973, on the merger of Gervais-Danone and BSN. It is aCAC 40 company.

производство производств·о

1) (процесс) production, output; (изготовление) manufacture, making, make

демонополизировать производство — to demonopolize production

интенсифицировать производство — to intensify production

наращивать производство — to build up the production (of)

наращивать мощности по производству (чего-л.) — to build up / to enlarge the capacties

наращивать темпы производства — to step up the rate of production

постепенно снимать с производства — to phase out

поступать в производство — to go into production

расширять производство — to expand production

сдерживать / сокращать производство — to curb / to curtail / to cut down production

форсировать производство — to step up production, to go ahead with production

производство снизилось — production has fallen / dropped

производство сократилось на 10 процентов — production declined by 10 per cent

военное производство — war / military production

вредное производство — dangerous trade / industry

высокоорганизованное производство — highly organized production

годовое производство — annual production

крупносерийное производство — large-scale manufacture / serial production

массовое производство — large-scale / high volume / quantity production, production in bulk

материальное производство — material production

мелкое производство — small-scale production

мировое производство — world output / production

незавершённое производство — goods in process

общественное производство — social production

опытное производство — pilot production

отечественное производство — domestic / home-produced production

товары отечественного производства — home-made / home-produced goods

плановое производство — planned production

поточное производство — flow / line production

промышленное производство — industrial production

промышленное производство военного времени — war-time production

свёртывание промышленного производства — cutback in industrial production

рентабельное производство — profitable enterprise

сельскохозяйственное производство — agricultural / farm production / output

товарное сельскохозяйственное производство — commercial agriculture

объём сельскохозяйственного производства — agricultural output

собственного производства — of one's own making

совместное производство — coproduction

современное производство — present-day production

убыточное производство — unprofitable / wasteful production

энергоёмкие производства — energyintensive industrial facilities; power consuming industries

эффективное производство — efficient production

анархия производства — anarchy of production

децентрализация производства — decentralization of production

диспропорции в производстве — imbalances in production

интенсификация производства — the intensifying / intensification of production

колебания уровня производства — swing in production

масштаб производства — scale of production

наращивание темпов производства — steady rise in the rate of production; stepping up the rate of production

непрерывный рост производства — continual increase in output

неритмичность производства — jerky production

обновление производства — renovation of production

общий уровень производства — overall production

объём производства — overall / total production

годовой объём производства — annual output

общий объём производства — overall / total output

реальный объём производства — real output

свёртывание объёма производства — curtailment of / cutback in production

сокращение / ограничение (объёма) производства — production cutback

организация производства — organization of production

улучшать организацию производства — to improve organization of production

орудие производства — instrument of production

отходы производства — waste materials, industrial wastes

использовать отходы производства — to utilize waste materials / industrial wastes

падение производства — drop in production

перерыв в производстве — disruption of production

планирование производства — production schedules

предельная мощность производства — peak output

производство вооружений и предметов военно-технического снабжения — munitions production

производство на душу населения — per capita / per head production

производство на коммерческой основе — commercial work

производство, обеспечивающее работу военной промышленности — defence-supporting production

производство оружия — arms manufacture

производство основного продукта (важнейшего технологического оборудования) — basic production

производство потребительских товаров — consumer goods production, output of consumer goods

производство продукции военного / оборонного назначения — defence production

производство продукции невоенного / гражданского назначения — civilian production

производство химического оружия — production of chemical weapons

прекратить производство химического оружия — to cease production of chemical weapons

производство ядерных материалов — processing of nuclear material

производство ядерного оружия — manufacture / production of nuclear weapons

запретить производство ядерного оружия — to ban the production of atomic nuclear weapons

расширение / рост производства — expansion of production

регулирование производства — adjustment of production

секреты производства — know-how

снятие с производства — phasedown

сокращение производства — curtailnent of production, cutback in production

способ производства — mode of production

господствующий способ производства — prevailing mode of production

производство средств производства — manufacture of the means of production

структура производства — structure of production

перестройка структуры производства — the reshaping of the structure of production

техническое обновление производства — technical modernization of production

товары отечественного производства — home-made / -produced goods

трудоёмкость производства — ratio of labour to put

увеличение темпов производства — step-up / increase in the rate of production

управление производством — administration of production

цикличная организация производства — cyclic organization of production

эффективность производства — production efficiency

повышать эффективность производства — to raise production efficiency

2) (отрасль промышленности) industry

3) (завод, фабрика) factory, plant; works

4) юр.; письменное производство по делу records of evidence

судебное производство — procedure, proceedings

начать судебное производство — to take / to institute legal proceedings (against)

прекратить судебное производство — to drop legal proceedings (against)

гражданское судебное производство — civil procedure, proceedings in civil causes

уголовное судебное производство — criminal procedure

суммарное / упрощённое производство — summary jurisdiction / proceedings

в порядке суммарного производства — on summary jurisdiction / proceeding

производство, совершаемое административными властями — proceedings instituted by administrative authorities

система

1. sensor-based system

система отображения данных — data-display system

система отсчета курса — heading reference system

система охлаждения туманом — coolant mist system

система очистки воды — water-purification system

система первого контура — primary cooling system

2. arrangements

проведение ревизии; карточная система — audit arrangements

объемная система пожаротушения — smothering arrangement

трехвалковая система — three-high mill arrangement

красочная система — inking arrangement area

осушительная система — bilge arrangement

3. framework

система показателей учета — accounting framework

система понятий — conceptual framework

возможность системы — system framework

4. frame

система отсчета — frame

система координат — frame

система координат мира — world frame

стропильная система крыши — frame of roof

подвижная система — relative frame of reference

5. set

система факторов — factor set

инициализация системы — all reset

перезапуск системы — system reset

система предпочтений — set of preferences

счетчик системы регулировки — set counter

6. installation

система подогрева груза — cargo heating installation

система обнаружения дыма — smoke-detecting installation

система пожаротушения — fire-extinguishing installation

система местного радиовещания — loudspeaker installation

7. arrangement

карточная система — audit arrangements

8. pattern

система вихрей — vortex pattern

система заводнения — flood pattern

система поведения вихрей — vortex pattern

система скачков уплотнения — shock pattern

система установления цен — pricing pattern

9. scheme

система аксиом — axiom scheme

система цветов — color scheme

система льгот — incentives scheme

премиальная система — bonus scheme

система гарантий — assurance scheme

10. systems

система океанских станций — ocean station system

система подачи полиокса — polyox ejection system

система подсчета результатов — system of scoring

система пополосной вёрстки — page makeup system

система поставок со склада — depot supply system

11. system

система координат звена — link coordinate system

система минимакс — optional replenishment system

система обеспечения плавучести — buoyancy system

система приема топлива — fuel-oil filling system

система программирования вне станка — olp system

12. formation

бытовая информационная система — House Information System

система контроля информации — information checking system

изменение системы обучения — the reformation of education

система преобразования информации — information processing

система информации об опасности — hazard information system

13. method

система разработки — mining method

столбовая система разработки — barrier method

веерная система разработки — fan-mining method

система эксплуатации — the method of operation

система разработки с закладкой — filling method

Terylene

TERYLENE

Synthetic textile fibre produced from a polyester derived essentially from terepthalic acid and ethylene glycol, it is the result of research work initiated by Calico Printers' Association, and carried out in their laboratories by Mr. J. R. Whinfield, assisted by Dr. J. T. Dickson and others. The qualities of polyester, and its potential value for fibre making, were recognised by the C.P.A., and patents covering the inventions were taken out by them. The subsequent research work on the chemical polymer and its conversion into a textile fibre was entrusted to Imperial Chemical Industries, who acquired an exclusive licence covering the whole world outside the U.S.A. From a given sample of the parent polymer it is possible to produce multi-filament yams of widely different characteristics by varying the physical and mechanical operations of the spinning and processing. Thus, for example, it is possible to obtain from the same polymer a yarn of low extensibility, but with outstandingly high strength (8 grams per denier or higher), or one of increased extensibility, but with lower strength. Notable property of " Terylene " is high resistance to light and heat and high initial elastic modulus.

Burks, Arthur Walter

SUBJECT AREA: Electronics and information technology

[br]

b. 13 October 1915 Duluth, Minnesota, USA

[br]

American engineer involved in the development of the ENIAC and Whirlwind computers.

[br]

After obtaining his AB degree from De Pere University, Wisconsin (1937), and his AM and PhD from the University of Michigan (1938 and 1941, respectively), Burks carried out research at the Moore School of Engineering, University of Pennsylvania, during the Second World War, and at the same time taught philosophy in another department. There, with Herman Goldstine, he was involved in the construction of ENIAC (the Electronic Numerical Integrator and Computer).

In 1946 he took a post as Assistant Professor of Engineering at Michigan University, and subsequently became Associate Professor (1948) and Full Professor (1954). Between 1946 and 1948 he was also associated with the computer activities of John von Neumann at the Institute of Advanced Studies, Princeton, and was involved in the development of the Whirlwind I computer (the first stored-program computer) by Jay Forrester at the Massachusetts Institute of Technology. From 1948 until 1954 he was a consultant for the Burroughs Corporation and also contributed to the Oak Ridge computer ORACLE. He was Chairman of the Michigan University Department of Communications Science in 1967–71 and at various times was Visiting Professor at Harvard University and the universities of Illinois and Stanford. In 1975 he became Editor of the Journal of Computer and System Sciences.

[br]

Bibliography

1946. "Super electronic computing machine", Electronics Industry 62.

1947. "Electronic computing circuits of the ENIAC", Proceedings of the Institute of Radio Engineers 35:756.

1980, "From ENIAC to the stored program computer. Two revolutions in computing", in N.Metropolis, J.Hewlett \& G.-C.Rota (eds), A History of Computing in the 20th Century, London: Academic Press.

Further Reading

J.W.Corlada, 1987, Historical Dictionary of Data Processing (provides further details of Burk's career).

KF

Goldstine, Herman H.

SUBJECT AREA: Electronics and information technology

[br]

b. 13 September 1913 USA

[br]

American mathematician largely responsible for the development of ENIAC, an early electronic computer.

[br]

Goldstine studied mathematics at the University of Chicago, Illinois, gaining his PhD in 1936. After teaching mathematics there, he moved to a similar position at the University of Michigan in 1939, becoming an assistant professor. After the USA entered the Second World War, in 1942 he joined the army as a lieutenant in the Ballistic Missile Research Laboratory at the Aberdeen Proving Ground in Maryland. He was then assigned to the Moore School of Engineering at the University of Pennsylvania, where he was involved with Arthur Burks in building the valve-based Electronic Numerical Integrator and Computer (ENIAC) to compute ballistic tables. The machine was completed in 1946, but prior to this Goldstine had met John von Neumann of the Institute for Advanced Studies (IAS) at Princeton, New Jersey, and active collaboration between them had already begun. After the war he joined von Neumann as Assistant Director of the Computer Project at the Institute of Advanced Studies, Princeton, becoming its Director in 1954. There he developed the idea of computer-flow diagrams and, with von Neumann, built the first computer to use a magnetic drum for data storage. In 1958 he joined IBM as Director of the Mathematical Sciences Department, becoming Director of Development at the IBM Data Processing Headquarters in 1965. Two years later he became a Research Consultant, and in 1969 he became an IBM Research Fellow.

[br]

Principal Honours and Distinctions

Goldstine's many awards include three honorary degrees for his contributions to the development of computers.

Bibliography

1946, with A.Goldstine, "The Electronic Numerical Integrator and Computer (ENIAC)", Mathematical Tables and Other Aids to Computation 2:97 (describes the work on ENIAC).

1946, with A.W.Burks and J.von Neumann, "Preliminary discussions of the logical design of an electronic computing instrument", Princeton Institute for Advanced Studies.

1972, The Computer from Pascal to von Neumann, Princeton University Press.

1977, "A brief history of the computer", Proceedings of the American Physical Society 121:339.

Further Reading

M.Campbell-Kelly \& M.R.Williams (eds), 1985, The Moore School Lectures (1946), Charles Babbage Institute Report Series for the History of Computing, Vol 9. M.R.Williams, 1985, History of Computing Technology, London: Prentice-Hall.

KF

Kilby, Jack St Clair

SUBJECT AREA: Electronics and information technology

[br]

b. 8 November 1923 Jefferson City, Missouri, USA

[br]

American engineer who filed the first patents for micro-electronic (integrated) circuits.

[br]

Kilby spent most of his childhood in Great Bend, Kansas, where he often accompanied his father, an electrical power engineer, on his maintenance rounds. Working in the blizzard of 1937, his father borrowed a "ham" radio, and this fired Jack to study for his amateur licence (W9GTY) and to construct his own equipment while still a student at Great Bend High School. In 1941 he entered the University of Illinois, but four months later, after the attack on Pearl Harbor, he was enlisted in the US Army and found himself working in a radio repair workshop in India. When the war ended he returned to his studies, obtaining his BSEE from Illinois in 1947 and his MSEE from the University of Wisconsin. He then joined Centralab, a small electronics firm in Milwaukee owned by Globe-Union. There he filed twelve patents, including some for reduced titanate capacitors and for Steatite-packing of transistors, and developed a transistorized hearing-aid. During this period he also attended a course on transistors at Bell Laboratories. In May 1958, concerned to gain experience in the field of number processing, he joined Texas Instruments in Dallas. Shortly afterwards, while working alone during the factory vacation, he conceived the idea of making monolithic, or integrated, circuits by diffusing impurities into a silicon substrate to create P-N junctions. Within less than a month he had produced a complete oscillator on a chip to prove that the technology was feasible, and the following year at the 1ERE Show he demonstrated a germanium integrated-circuit flip-flop. Initially he was granted a patent for the idea, but eventually, after protracted litigation, priority was awarded to Robert Noyce of Fairchild. In 1965 he was commissioned by Patrick Haggerty, the Chief Executive of Texas Instruments, to make a pocket calculator based on integrated circuits, and on 14 April 1971 the world's first such device, the Pocketronic, was launched onto the market. Costing $150 (and weighing some 2½ lb or 1.1 kg), it was an instant success and in 1972 some 5 million calculators were sold worldwide. He left Texas Instruments in November 1970 to become an independent consultant and inventor, working on, amongst other things, methods of deriving electricity from sunlight.

[br]

Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1966. Institute of Electrical and Electronics Engineers David Sarnoff Award 1966; Cledo Brunetti Award (jointly with Noyce) 1978; Medal of Honour 1986. National Academy of Engineering 1967. National Science Medal 1969. National Inventors Hall of Fame 1982. Honorary DEng Miami 1982, Rochester 1986. Honorary DSc Wisconsin 1988. Distinguished Professor, Texas A \& M University.

Bibliography

6 February 1959, US patent no. 3,138,743 (the first integrated circuit (IC); initially granted June 1964).

US patent no. 3,819,921 (the Pocketronic calculator).

Further Reading

T.R.Reid, 1984, Microchip. The Story of a Revolution and the Men Who Made It, London: Pan Books (for the background to the development of the integrated circuit). H.Queisser, 1988, Conquest of the Microchip, Cambridge, Mass.: Harvard University Press.

KF

Lumière, Auguste

SUBJECT AREA: Photography, film and optics

[br]

b. 19 October 1862 Besançon, France

d. 10 April 1954 Lyon, France

[br]

French scientist and inventor.

[br]

Auguste and his brother Louis Lumière (b. 5 October 1864 Besançon, France; d. 6 June 1948 Bandol, France) developed the photographic plate-making business founded by their father, Charles Antoine Lumière, at Lyons, extending production to roll-film manufacture in 1887. In the summer of 1894 their father brought to the factory a piece of Edison kinetoscope film, and said that they should produce films for the French owners of the new moving-picture machine. To do this, of course, a camera was needed; Louis was chiefly responsible for the design, which used an intermittent claw for driving the film, inspired by a sewing-machine mechanism. The machine was patented on 13 February 1895, and it was shown on 22 March 1895 at the Société d'Encouragement pour l'In-dustrie Nationale in Paris, with a projected film showing workers leaving the Lyons factory. Further demonstrations followed at the Sorbonne, and in Lyons during the Congrès des Sociétés de Photographie in June 1895. The Lumières filmed the delegates returning from an excursion, and showed the film to the Congrès the next day. To bring the Cinématographe, as it was called, to the public, the basement of the Grand Café in the Boulevard des Capuchines in Paris was rented, and on Saturday 28 December 1895 the first regular presentations of projected pictures to a paying public took place. The half-hour shows were an immediate success, and in a few months Lumière Cinématographes were seen throughout the world.

The other principal area of achievement by the Lumière brothers was colour photography. They took up Lippman's method of interference colour photography, developing special grainless emulsions, and early in 1893 demonstrated their results by lighting them with an arc lamp and projecting them on to a screen. In 1895 they patented a method of subtractive colour photography involving printing the colour separations on bichromated gelatine glue sheets, which were then dyed and assembled in register, on paper for prints or bound between glass for transparencies. Their most successful colour process was based upon the colour-mosaic principle. In 1904 they described a process in which microscopic grains of potato starch, dyed red, green and blue, were scattered on a freshly varnished glass plate. When dried the mosaic was coated with varnish and then with a panchromatic emulsion. The plate was exposed with the mosaic towards the lens, and after reversal processing a colour transparency was produced. The process was launched commercially in 1907 under the name Autochrome; it was the first fully practical single-plate colour process to reach the public, remaining on the market until the 1930s, when it was followed by a film version using the same principle.

Auguste and Louis received the Progress Medal of the Royal Photographic Society in 1909 for their work in colour photography. Auguste was also much involved in biological science and, having founded the Clinique Auguste Lumière, spent many of his later years working in the physiological laboratory.

[br]

Further Reading

Guy Borgé, 1980, Prestige de la photographie, Nos. 8, 9 and 10, Paris. Brian Coe, 1978, Colour Photography: The First Hundred Years, London ——1981, The History of Movie Photography, London.

Jacques Deslandes, 1966, Histoire comparée du cinéma, Vol. I, Paris. Gert Koshofer, 1981, Farbfotografie, Vol. I, Munich.

BC

Owens, Michael Joseph

SUBJECT AREA: Agricultural and food technology, Domestic appliances and interiors

[br]

b. 1 January 1859 Mason County, Virginia, USA

d. 27 December 1923 Toledo, Ohio, USA

[br]

American inventor of the automatic glass bottle making machine.

[br]

To assist the finances of a coal miner's family, Owens entered a glassworks at Wheeling, Virginia, at the tender age of 10, stoking coal into the "glory hole" or furnace where glass was resoftened at various stages of the hand-forming process. By the age of 15 he had become a glassblower.

In 1888 Owens moved to the glassworks of Edward Drummond Libbey at Toledo, Ohio, where within three months he was appointed Superintendent and, not long after, a branch manager. In 1893 Owens supervised the company's famous exhibit at the World's Columbian Exposition at Chicago. He had by then begun experiments that were to lead to the first automatic bottle-blowing machine. He first used a piston pump to suck molten glass into a mould, and then transferred the gathered glass over another mould into which the bottle was blown by reversing the pump. The first patents were taken out in 1895, followed by others incorporating improvements and culminating in the patent of 8 November 1904 for an essentially perfected machine. Eventually it was capable of producing four bottles a second, thus effecting a revolution in bottle making. Owens, with Libbey and others, set up the Owens Bottle Machine Company in 1903, which Owens himself managed from 1915 to 1919, becoming Vice-President from 1915 until his death. A plant was also established in Manchester in 1905.

Besides this, Owens and Libbey first assisted Irving W.Colburn with his experiments on the continuous drawing of flat sheet glass and then in 1912 bought the patents, forming the Owens-Libbey Sheet Glass Company. In all, Owens was granted forty-five US patents, mainly relating to the manufacture and processing of glass. Owens's undoubted inventive genius was hampered by a lack of scientific knowledge, which he made good by judicious consultation.

[br]

Further Reading

1923, Michael J.Owens (privately printed) (a series of memorial articles reprinted from various sources).

G.S.Duncan, 1960, Bibliography of Glass, Sheffield: Society of Glass Manufacturers (cites references to Owens's papers and patents).

LRD

центр

адрес входного центра коммутации

entry switching center address

адрес передающего центра

transmitting center address

Всемирный центр зональных прогнозов

World area forecast center

вспомогательный центр поиска

rescue subcenter

(пропавших воздушных судов) держать шарик в центре

keep the ball centered

диспетчерский центр

control center

диспетчерский центр управления верхним районом

upper area control center

диспетчерский центр управления воздушным движением

air traffic control center

диспетчерский центр управления потоком воздушного движения

flow control center

коммутационный центр метеорологических донесений

weather message switching center

координационный центр по спасанию

rescue coordination center

метеорологический центр

meteorological center

неустойчивость центра давления

center-of-pressure instability

океанический районный диспетчерский центр

oceanic area control center

разворот с креном к центру разворота

inside turn

разворот с креном от центра разворота

outside turn

районный диспетчерский центр управления движением на авиатрассе

area control center

региональный диспетчерский центр

regional control center

траектория движения центра тяжести

center-of-gravity path

центр аэродинамического давления

center of air pressure

центр давления

1. center of pressure

2. pressure center центр жесткости

elastic center

центр зональных прогнозов

area forecast center

центр информации для верхнего района

upper information center

центр летной подготовки

1. aircrew training center

2. flying training center центр масс

center of mass

центр низкого давления

center of depression

центр обеспечения воздушной связи

air communication center

центр обработки донесений

message center

центр обработки радиолокационной информации

radar processing center

центр передачи радиолокационной информации

radar information center

центр подъемной силы

center lift

центр поиска и спасания

search and rescue center

центр полетной информации

flight information center

центр приложения силы

center of force

центр прогнозов

forecast center

центр радиолокационного управления заходом на посадку

radar approach control

центр сбора информации

collecting center

центр тяжести

1. center of gravity

2. center-of-gravity

Turing Machine

    The Claim That Man Can Be Understood as a Turing Machine

   [W]hen Minsky or Turing claims that man can be understood as a Turing machine, they must mean that a digital computer can reproduce a human behavior... by processing data representing facts about the world using log ical operations that can be reduced to matching, classifying and Boolean operations. (Dreyfus, 1972, p. 192)

измеритель механических напряжений

1. stressometer system

 

измеритель механических напряжений
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[Интент]

Параллельные тексты EN-RU из ABB Review. Перевод компании Интент

High precision in Venice

From the 13th century, Venice traded in copper and bronze, which was used to manufacture coins and building details. Today, ILNOR SpA, a family-owned business established in 1961, continues the tradition of processing metals for use in various industries. The high-quality brass, bronze and copper strips it produces are used for products in the automotive, electric and electronic industries. However, the taste for aesthetical and high-quality products is centuries old in Venice, and ILNOR continues to uphold this tradition by constantly investing in technology that improves the quality of its products 1. The choice of the Stressometer 7.0 FSA from ABB was natural. Stressometer systems provide the advanced automated control system needed to produce the high-quality flat strip demanded by producers, and is evidence of ABB’s dedication to detail and perfection, something that is well recognized and appreciated in this part of the old world.

Высокая точность в Венеции

С XIII века  Венеция торгует медью и бронзой, из которых изготавливаются монеты и элементы зданий. Сегодня ILNOR SpA, семейное предприятие, основанное в 1961 году, продолжает традиции обработки металлов, которые применяются в различных отраслях промышленности. Выпускаемые им высококачественные латунные, бронзовые и медные листы используются предприятиями автомобильной, электрической и электронной промышленности. Вкус к эстетически выдержанным и высококачественным изделиям складывался в Венеции в течение многих столетий, и ILNOR продолжает эти традиции, постоянно вкладывая средства в технологии, повышающие качество изделий (рис. 1). Поэтому совершенно естественным выглядит выбор измерителя механических напряжений Stressometer 7.0 FSA компании АББ. Данные измерители механических напряжений позволяют создавать усовершенствованные системы автоматического контроля, необходимые для производства высококачественных листовых материалов, и красноречиво демонстрируют стремление компании АББ к точности и совершенству, что высоко ценится в этой части Старого Света.

EN

• stressometer system