(involved in the field development)

planned number of employees (involved in the field development)

Нефть и газ: предполагаемое количество занятых (на промышленном освоении месторождения)

Field, Cyrus West

SUBJECT AREA: Telecommunications

[br]

b. 30 November 1819 Stockbridge, Massachusetts, USA

d. 12 July 1892 New York City, New York, USA

[br]

American financier and entrepreneur noted for his successful promotion of the first transatlantic telegraph cable.

[br]

At the age of 15 Field left home to seek his fortune in New York, starting work on Broadway as an errand boy for $1 per week. Returning to Massachusetts, in 1838 he became an assistant to his brother Matthew, a paper-maker, leaving to set up his own business two years later. By the age of 21 he was also a partner in a New York firm of paper wholesalers, but this firm collapsed because of large debts. Out of the wreckage he set up Cyrus W.Field \& Co., and by 1852 he had paid off all the debts. With $250,000 in the bank he therefore retired and travelled in South America. Returning to the USA, he then became involved with the construction of a telegraph line in Newfoundland by an English engineer, F.N. Osborne. Although the company collapsed, he had been fired by the dream of a transatlantic cable and in 1854 was one of the founders of the New York, Newfoundland and London Telegraph Company. He began to promote surveys and hold discussions with British telegraph pioneers and with Isambard Brunel, who was then building the Great Eastern steamship. In 1856 he helped to set up the Atlantic Telegraph Company in Britain and, as a result of his efforts and those of the British physicist and inventor Sir William Thomson (Lord Kelvin), work began in 1857 on the laying of the first transatlantic cable from Newfoundland to Ireland. After many tribulations the cable was completed on 5 August 1857, but it failed after barely a month. Following several unsuccessful attempts to repair and replace it, the cable was finally completed on 27 July 1866. Building upon his success, Field expanded his business interests. In 1877 he bought a controlling interest in and was President of the New York Elevated Railroad Company. He also helped develop the Wabash Railroad and became owner of the New York Mail and Express newspaper; however, he subsequently suffered large financial losses.

[br]

Principal Honours and Distinctions

Congressional Gold Medal.

Further Reading

A.C.Clarke, 1958, Voice Across the Sea, London: Frederick Muller (describes the development of the transatlantic telegraph).

H.M.Field, 1893, Story of the Atlantic Telegraph (also describes the transatlantic telegraph development).

L.J.Judson (ed.), 1893, Cyrus W.Field: His Life and Work (a complete biography).

KF

planned number of employees

Нефть и газ: (involved in the field development) предполагаемое количество занятых (на промышленном освоении месторождения)

Crookes, Sir William

SUBJECT AREA: Electricity

[br]

b. 17 June 1832 London, England

d. 4 April 1919 London, England

[br]

English chemist and physicist who carried out studies of electrical discharges and cathode rays in rarefied gases, leading to the development of the cathode ray tube; discoverer of the element thallium and the principle of the Crookes radiometer.

[br]

Crookes entered the Royal College of Chemistry at the age of 15, and from 1850 to 1854 held the appointment of Assistant at the college. In 1854 he became Superintendent of the Meteorological Department at the Radcliffe Observatory in Oxford. He moved to a post at the College of Science in Chester the following year. Soon after this he inherited a large fortune and set up his own private laboratory in London. There he studied the nature of electrical discharges in gases at low pressure and discovered the dark space (later named after him) that surrounds the negative electrode, or cathode. He also established that the rays produced in the process (subsequently shown by J.J.Thompson to be a stream of electrons) not only travelled in straight lines, but were also capable of producing heat and/or light upon impact with suitable anode materials. Using a variety of new methods to investigate these "cathode" rays, he applied them to the spectral analysis of compounds of selenium and, as a result, in 1861 he discovered the element thallium, finally establishing its atomic weight in 1873. Following his discovery of thallium, he became involved in two main lines of research: the properties of rarified gases, and the investigation of the elements of the "rare earths". It was also during these experiments that he discovered the principle of the Crookes radiometer, a device in which light is converted into rotational motion and which used to be found frequently in the shop windows of English opticians. Also among the fruits of this work were the Crookes tubes and the development of spectacle lenses with differential ranges of radiational absorption. In the 1870s he became interested in spiritualism and acquired a reputation for his studies of psychic phenomena, but at the turn of the century he returned to traditional scientific investigations. In 1892 he wrote about the possibility of wireless telegraphy. His work in the field of radioactivity led to the invention of the spinthariscope, an early type of detector of alpha particles. In 1900 he undertook investigations into uranium which led to the study of scintillation, an important tool in the study of radioactivity.

While the theoretical basis of his work has not stood the test of time, his material discoveries, observations and investigations of new facts formed a basis on which others such as J.J. Thomson were to develop subatomic theory. His later involvement in the investigation of spiritualism led to much criticism, but could be justified on the basis of a belief in the duty to investigate all phenomena.

[br]

Principal Honours and Distinctions

Knighted 1897. Order of Merit 1910. FRS 1863. President, Royal Society 1913–15. Honorary LLD Birmingham. Honorary DSc Oxon, Cambridge, Sheffield, Durham, Ireland and Cape of Good Hope.

Bibliography

1874, On Attraction and Repulsion Resulting from Radiation.

1874, "Researches in the phenomenon of spiritualism", Society of Metaphysics; reprinted in facsimile, 1986.

For many years he was also Proprietor and Editor of Chemical News.

Further Reading

E.E.Fournier D'Albe, 1923, Life of Sir William Crookes. Who Was Who II, 1916–28, London: A. \& C. Black. T.I.Williams, 1969, A Biographical Dictionary of Scientists. See also Braun, Karl Ferdinand.

KF / MG

Forrester, Jay Wright

SUBJECT AREA: Electronics and information technology

[br]

b. 14 July 1918 Anselmo, Nebraska, USA

[br]

American electrical engineer and management expert who invented the magnetic-core random access memory used in most early digital computers.

[br]

Born on a cattle ranch, Forrester obtained a BSc in electrical engineering at the University of Nebraska in 1939 and his MSc at the Massachusetts Institute of Technology (MIT) in Cambridge, Massachusetts, where he remained to teach and carry out research. Becoming interested in computing, he established the Digital Computer Laboratory at MIT in 1945 and became involved in the construction of Whirlwind I, an early general-purpose computer completed in March 1951 and used for flight-simulation by the US Army Air Force. Finding the linear memories then available for storing data a major limiting factor in the speed at which computers were able to operate, he developed a three-dimensional store based on the binary switching of the state of small magnetic cores that could be addressed and switched by a matrix of wires carrying pulses of current. The machine used parallel synchronous fixed-point computing, with fifteen binary digits and a plus sign, i.e. 16 bits in all, and contained 5,000 vacuum tubes, eleven semiconductors and a 2 MHz clock for the arithmetic logic unit. It occupied a two-storey building and consumed 150kW of electricity. From his experience with the development and use of computers, he came to realize their great potential for the simulation and modelling of real situations and hence for the solution of a variety of management problems, using data communications and the technique now known as interactive graphics. His later career was therefore in this field, first at the MIT Lincoln Laboratory in Lexington, Massachusetts (1951) and subsequently (from 1956) as Professor at the Sloan School of Management at the Massachusetts Institute of Technology.

[br]

Principal Honours and Distinctions

National Academy of Engineering 1967. George Washington University Inventor of the Year 1968. Danish Academy of Science Valdemar Poulsen Gold Medal 1969. Systems, Man and Cybernetics Society Award for Outstanding Accomplishments 1972. Computer Society Pioneer Award 1972. Institution of Electrical Engineers Medal of Honour 1972. National Inventors Hall of Fame 1979. Magnetics Society Information Storage Award 1988. Honorary DEng Nebraska 1954, Newark College of Engineering 1971, Notre Dame University 1974. Honorary DSc Boston 1969, Union College 1973. Honorary DPolSci Mannheim University, Germany. Honorary DHumLett, State University of New York 1988.

Bibliography

1951, "Data storage in three dimensions using magnetic cores", Journal of Applied Physics 20: 44 (his first description of the core store).

Publications on management include: 1961, Industrial Dynamics, Cambridge, Mass.: MIT Press; 1968, Principles of Systems, 1971, Urban Dynamics, 1980, with A.A.Legasto \& J.M.Lyneis, System Dynamics, North Holland. 1975, Collected Papers, Cambridge, Mass.: MIT.

Further Reading

K.C.Redmond \& T.M.Smith, Project Whirlwind, the History of a Pioneer Computer (provides details of the Whirlwind computer).

H.H.Goldstine, 1993, The Computer from Pascal to von Neumann, Princeton University Press (for more general background to the development of computers).

Serrell et al., 1962, "Evolution of computing machines", Proceedings of the Institute of

Radio Engineers 1,047.

M.R.Williams, 1975, History of Computing Technology, London: Prentice-Hall.

See also: Burks, Arthur Walter; Goldstine, Herman H.; Wilkes, Maurice Vincent; Williams, Sir Frederic Calland

KF

Henry, James J.

SUBJECT AREA: Ports and shipping

[br]

b. 22 June 1913 Ancon, Panama Canal Zone

d. 1986 USA

[br]

American naval architect, innovator in specialist cargo-ship design.

[br]

After graduating in 1935 from the Webb Institute of Naval Architecture, New York, Henry served in different government agencies until 1938 when he joined the fast expanding US Maritime Commission. He assisted in the design and construction of troop-carrying vessels, Cl cargo ships, and he supervised the construction of two wartime attack transports. At the end of hostilities, he set up as a consultant naval architect and by 1951 had incorporated the business as J.J.Henry \& Company Inc. The opportunities that consultancy gave him were grasped eagerly; he became involved in the conversion of war-built tonnage to peaceful purposes (such as T2 tankers to ore carriers), the development of the new technologies of the carriage of liquefied gases at cryogenic temperatures and low pressures and, possibly the greatest step forward of all, the development of containerization. Containerization and the closely related field of barge transportation were to provide considerable business during the 1960s and the 1970s. The company designed the wonderful 33-knot container ships for Sea-Land and the auspicious Sea-bee barge carriers for the Lykes Brothers of New Orleans. James Henry's professional achievements were recognized internationally when he was elected President of the (United States) Society of Naval Architects and Marine Engineers in 1969. By then he had served on many boards and committees and was especially honoured to be Chairman of the Board of Trustees of his graduating college, the Webb Institute of Naval Architecture of New York.

FMW

Bramah, Joseph

SUBJECT AREA: Civil engineering, Domestic appliances and interiors, Land transport, Mechanical, pneumatic and hydraulic engineering, Public utilities

[br]

b. 2 April 1749 Stainborough, Yorkshire, England

d. 9 December 1814 Pimlico, London, England

[br]

English inventor of the second patented water-closet, the beer-engine, the Bramah lock and, most important, the hydraulic press.

[br]

Bramah was the son of a tenant farmer and was educated at the village school before being apprenticed to a local carpenter, Thomas Allot. He walked to London c.1773 and found work with a Mr Allen that included the repair of some of the comparatively rare water-closets of the period. He invented and patented one of his own, which was followed by a water cock in 1783. His next invention, a greatly improved lock, involved the devising of a number of special machine tools, for it was one of the first devices involving interchangeable components in its manufacture. In this he had the help of Henry Maudslay, then a young and unknown engineer, who became Bramah's foreman before setting up business on his own. In 1784 he moved his premises from Denmark Street, St Giles, to 124 Piccadilly, which was later used as a showroom when he set up a factory in Pimlico. He invented an engine for putting out fires in 1785 and 1793, in effect a reciprocating rotary-vane pump. He undertook the refurbishment and modernization of Norwich waterworks c.1793, but fell out with Robert Mylne, who was acting as Consultant to the Norwich Corporation and had produced a remarkably vague specification. This was Bramah's only venture into the field of civil engineering.

In 1797 he acted as an expert witness for Hornblower \& Maberley in the patent infringement case brought against them by Boulton and Watt. Having been cut short by the judge, he published his proposed evidence in "Letter to the Rt Hon. Sir James Eyre, Lord Chief Justice of the Common Pleas…etc". In 1795 he was granted his most important patent, based on Pascal's Hydrostatic Paradox, for the hydraulic press which also incorporated the concept of hydraulics for the transmission of both power and motion and was the foundation of the whole subsequent hydraulic industry. There is no truth in the oft-repeated assertion originating from Samuel Smiles's Industrial Biography (1863) that the hydraulic press could not be made to work until Henry Maudslay invented the self-sealing neck leather. Bramah used a single-acting upstroking ram, sealed only at its base with a U-leather. There was no need for a neck leather.

He also used the concept of the weight-loaded, in this case as a public-house beer-engine. He devised machinery for carbonating soda water. The first banknote-numbering machine was of his design and was bought by the Bank of England. His development of a machine to cut twelve nibs from one goose quill started a patent specification which ended with the invention of the fountain pen, patented in 1809. His coach brakes were an innovation that was followed bv a form of hydropneumatic carriage suspension that was somewhat in advance of its time, as was his patent of 1812. This foresaw the introduction of hydraulic power mains in major cities and included the telescopic ram and the air-loaded accumulator.

In all Joseph Bramah was granted eighteen patents. On 22 March 1813 he demonstrated a hydraulic machine for pulling up trees by the roots in Hyde Park before a large crowd headed by the Duke of York. Using the same machine in Alice Holt Forest in Hampshire to fell timber for ships for the Navy, he caught a chill and died soon after at his home in Pimlico.

[br]

Bibliography

1778, British patent no. 1177 (water-closet). 1784, British patent no. 1430 (Bramah Lock). 1795, British patent no. 2045 (hydraulic press). 1809, British patent no. 3260 (fountain pen). 1812, British patent no. 3611.

Further Reading

I.McNeil, 1968, Joseph Bramah, a Century of Invention.

S.Smiles, 1863, Industrial Biography.

H.W.Dickinson, 1942, "Joseph Bramah and his inventions", Transactions of the Newcomen Society 22:169–86.

IMcN

Lister, Joseph, Baron Lister

SUBJECT AREA: Medical technology

[br]

b. 5 April 1827 Upton, Essex, England

d. 10 February 1912 Walmer, Kent, England

[br]

English surgeon, founder of the antiseptic and aseptic principles of surgical practice.

[br]

Of Quaker stock, his father also being a Fellow of the Royal Society, he studied medicine at University College, London. He qualified, and became a Fellow of the Royal College of Surgeons, in 1852. Wishing to pursue a surgical career, he moved to Edinburgh to study surgery under William Syme, whose daughter he married in 1852, the same year he was appointed Assistant Surgeon to the Edinburgh Royal Infirmary.

Until his appointment as Regius Professor of Surgery at Glasgow University and Glasgow Royal Infirmary in 1861, he was engaged in a wide variety of investigations into the nature of inflammation and the effects of irritants on wounds. Following his move to Glasgow, he became particularly involved in the major problems arising out of the vast increase in the number of surgical procedures brought about by the recent introduction of general anaesthesia. By 1865 his continuing study of wound inflammation and the microbial studies of Pasteur had led him to institute in the operating theatre a regime of surgical antisepsis involving the use of a carbolic acid spray coupled with the sterilization of instruments, the site of operation and the hands of the operator. Increasingly it was appreciated that the air was the least important origin of infection, and by 1887 the antiseptic approach had been superseded by the aseptic.

In 1869 he succeeded Syme in the Chair at Edinburgh and his methods were widely accepted abroad. In 1877 he moved to the Chair of Surgery at King's College Hospital, London, in the hope of encouraging acceptance of his work in the metropolis. As well as developing a variety of new surgical procedures, he was engaged for many years in the development of surgical ligatures, which had always been a potent stimulant of infection. His choice of catgut as a sterilizable, absorbable material paved the way for major developments in this field. The Lister Institute of Preventive Medicine was named in his honour in 1903.

[br]

Principal Honours and Distinctions

Created Baronet 1883. Baron 1897. Order of Merit 1902. President, Royal Society 1895– 1900.

Bibliography

1870, "On the effects of the antiseptic system of treatment upon the salubrity of a surgical hospital", Lancet.

1859, Philosophical Transactions of the Royal Society.

1863, Croonian Lecture.

1881, 1900, Transactions of the International Medical Congress.

Further Reading

R.J.Godlee, 1924, Lord Lister.

1927, Lister Centenary Handbook, London: Wellcome Historical Medical Museum. H.C.Cameron, 1948, Joseph Lister, the Friend of Man.

MG

Talbot, William Henry Fox

SUBJECT AREA: Photography, film and optics

[br]

b. 11 February 1800 Melbury, England

d. 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 Distinctions

FRS March 1831. Royal Society Rumford Medal 1842. Grand Médaille d'Honneur, L'Exposition Universelle, Paris, 1855. Honorary Doctorate of Laws, Edinburgh University, 1863.

Bibliography

1839, "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 Reading

H.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).

JW

activity

n

1) часто pl активность, деятельность; действия, операции ( в определенной области)

2) хозяйственная деятельность, производственная деятельность

3) pl показатели ( в экономических исследованиях)

•

to abandon political activities altogether — полностью отказываться от политической деятельности

to accuse smb of subversive activities — обвинять кого-л. в подрывной деятельности

to ban all political activities — запрещать любую политическую деятельность

to bar smb from political activities — запрещать кому-л. заниматься политической деятельностью

to be engaged in an activities — заниматься какой-л. деятельностью

to be involved in an activities — участвовать в какой-л. деятельности

to boost a country's economic activity — стимулировать экономическую деятельность страны

to break off an activities — прекращать какую-л. деятельность

to carry out activities — осуществлять какую-л. деятельность

to check smb's hostile activities — пресекать чьи-л. враждебные действия

to coordinate smb's activities — координировать чью-л. деятельность / чьи-л. действия

to combine smb's activities — объединять чьи-л. действия

to conceal one's activities — скрывать свою деятельность

to conduct an activities — заниматься какой-л. деятельностью

to cover up smb's war time activities — прикрывать чью-л. деятельность во время войны

to curb illegal activities — пресекать незаконную деятельность

to cut down on one's spying activities — сокращать свою разведывательную деятельность

to dampen activity — снижать активность

to display activity — проявлять активность

to disrupt activities — мешать деятельности

to eliminate hostile activities — пресекать враждебные проявления

to engage in an activities — заниматься какой-л. деятельностью

to enhance social activity of the young people — повышать социальную активность молодежи

to examine activities — изучать / исследовать деятельность

to expand activities — расширять рамки деятельности

to expel smb for activities incompatible with his diplomatic status — выдворять кого-л. за деятельность, несовместимую с его дипломатическим статусом

to facilitate operational activities — способствовать / помогать оперативной деятельности

to finance new activities — финансировать новые виды деятельности

to focus activities on / upon smth — сосредоточить деятельность на чем-л.

to halt all military activities against smb — прекращать все военные действия против кого-л.

to initiate trading activities — начинать торговую деятельность

to intensify activities — усиливать / повышать активность

to limit smb's activities — ограничивать чью-л. деятельность / чьи-л. действия

to make a contribution to smb's activities — вносить вклад в чью-л. деятельность

to make up for the decline of economic activities — компенсировать спад экономической деятельности

to monitor smb's activities — следить за чьей-л. деятельностью

to mount intensive sabotage activity — развертывать активную диверсионную деятельность

to paralyze smb's activities — парализовать чью-л. деятельность

to participate in an activities — участвовать в какой-л. деятельности

to permit normal market activities — разрешать нормальную рыночную деятельность

to put a stop to smb's criminal activities — пресекать чью-л. преступную деятельность, положить конец чьим-л. преступным действиям

to refrain from political activities — воздерживаться от политической деятельности

to repress activities — подавлять деятельность

to restrain / to restrict smb's activities — ограничивать чью-л. деятельность

to resume one's activities — возобновлять свою деятельность

to review the activities — делать обзор деятельности

to set off a flurry of intense negotiation activity — давать толчок лихорадочной переговорной деятельности

to show activity — проявлять активность

to step up one's activities — повышать свою активность; активизировать / усиливать свою деятельность

to stimulate activity — стимулировать активность

to stir to activity — активизировать

to streamline the activities — рационализировать деятельность

to supervise and guide the activities — осуществлять контроль и руководство за деятельностью

to surpass the activities — подавлять деятельность

to take part in an activity — принимать участие в какой-л. деятельности

to terminate an activities — прекращать какую-л. деятельность

to uncover enemy's activities — разоблачать вражескую деятельность

to undertake activities — осуществлять деятельность, предпринимать действия

to widen the range of activities — расширять масштаб / поле деятельности

to withdraw from activities — прекращать деятельность

- abolition of military activities

- activity in the market
- activity incompatible with one's diplomatic status
- activity inconsistent with one's diplomatic status
- activity on the international scene
- activities against smb / smth
- advisory activity
- aggregate activities
- aggressive activity
- ancillary activities
- anti-democratic activities
- anti-government activities
- anti-militarist activities
- anti-national activities
- anti-popular activities
- anti-state activities
- area of activity
- backstage activities
- back-stairs activities
- banned activities
- basic activities
- behind-the-scenes activities
- black market activities
- business activity
- civil activity
- clandestine activities
- commercial activities
- competitive activity
- conspiratorial activity
- constant activity
- continuing activity
- continuous activity
- coordination of activities
- counterespionage activities
- covert activities
- criminal activities
- cultural activities
- current activities
- curtailing of military activities
- day-to-day activity
- decline in business activity
- defense activity
- defense industry activity
- defense-generated economic activity
- detraction and pollution of nature through the activities of man
- development activities
- diplomatic activity
- domestic activity
- dominant activity
- duplication of activities
- economic activity
- environmental activity
- escalation of terrorist activities
- espionage activities
- exposure of unlawful activities
- extension of IRA activity to Europe
- factional activities
- family planning activities
- field activities

- field of activity

- financial activities

- flurry of diplomatic activities
- follow-up activity
- forecasting activity
- foreign economic activities
- foreign policy activities
- fruitful activity
- full activity
- generalization of the activities
- global activities
- government activities
- government research activities
- growing activity
- guerilla activity
- heightened activity
- high priority activities
- hostile activities
- human rights activity
- humanitarian activities
- ideological activities
- illegal activities
- illicit activity
- industrial activity
- ineffective activities
- information activities
- intellectual activities
- intelligence activities
- intensification of activity
- intensive activity
- interconnected activities
- international activities
- investment activities
- involvement in espionage activities for a country
- know-how activity
- labor activities
- legislative activity
- leisure activity
- leisure-time activity
- level of activities
- long-term activity
- manifestation of activities
- mass communication activities
- military activities
- multifaceted activity
- nationalist activities
- nonmarket activities
- nonprofit activities
- nuclear related activities
- operational activities
- opposition activity
- organizational activities
- parliamentary activities
- peaceful activities
- permitted activities
- political activity
- practical activity
- primary activity
- priority activities
- pro-American activities
- production activity
- productive activity
- professional activity
- profit-making activity
- profit-seeking activity
- program activities
- prohibited activities
- project activities
- promotional activities
- propaganda activities
- provocative activities
- public activities
- public relations activities
- R & D activities
- range of activity
- rebel activities
- recurring activities
- regular government activities
- relaxation of political activities
- renewed activity
- research activities
- research and development activities
- Resistance activities
- revival of activities
- revolutionary activities
- sabotage activities
- scientific activities
- scope of activities
- seat of activities
- secessionist activities
- secondary activities
- service activities
- set of activities
- social and political activity
- space activities
- spate of terrorist activity
- special activities
- speculative activities

- sphere of activity

- spying activity

- statistical data processing activities
- subsequent activity
- subversive activities
- subversive and terrorist activities
- supporting activity
- tactical activities
- take-over activity
- technical assistance activities
- terrorist activities
- time-limited activity
- trading activities
- treatment of economic activity
- undercover activities
- underground activities
- underhand activities
- uninterrupted activity
- union activities
- verification activities
- vigorous activity
- volume of activity
- wartime activities
- work activities
- world business activities

Creativity

   1) All Human Complex Problem Solving Is Creativity

   Put in this bald way, these aims sound utopian. How utopian they areor rather, how imminent their realization-depends on how broadly or narrowly we interpret the term "creative." If we are willing to regard all human complex problem solving as creative, then-as we will point out-successful programs for problem solving mechanisms that simulate human problem solvers already exist, and a number of their general characteristics are known. If we reserve the term "creative" for activities like discovery of the special theory of relativity or the composition of Beethoven's Seventh Symphony, then no example of a creative mechanism exists at the present time. (Simon, 1979, pp. 144-145)

   2) Artificial Intelligence Models of Creative Association

   Among the questions that can now be given preliminary answers in computational terms are the following: how can ideas from very different sources be spontaneously thought of together? how can two ideas be merged to produce a new structure, which shows the influence of both ancestor ideas without being a mere "cut-and-paste" combination? how can the mind be "primed," so that one will more easily notice serendipitous ideas? why may someone notice-and remember-something fairly uninteresting, if it occurs in an interesting context? how can a brief phrase conjure up an entire melody from memory? and how can we accept two ideas as similar ("love" and "prove" as rhyming, for instance) in respect of a feature not identical in both? The features of connectionist AI models that suggest answers to these questions are their powers of pattern completion, graceful degradation, sensitization, multiple constraint satisfaction, and "best-fit" equilibration.... Here, the important point is that the unconscious, "insightful," associative aspects of creativity can be explained-in outline, at least-by AI methods. (Boden, 1996, p. 273)

   3) Creative Innovation and Social Independence

   There thus appears to be an underlying similarity in the process involved in creative innovation and social independence, with common traits and postures required for expression of both behaviors. The difference is one of product-literary, musical, artistic, theoretical products on the one hand, opinions on the other-rather than one of process. In both instances the individual must believe that his perceptions are meaningful and valid and be willing to rely upon his own interpretations. He must trust himself sufficiently that even when persons express opinions counter to his own he can proceed on the basis of his own perceptions and convictions. (Coopersmith, 1967, p. 58)

   4) Ego Strength and Emotional Stability among Creative Geniuses

   he average level of ego strength and emotional stability is noticeably higher among creative geniuses than among the general population, though it is possibly lower than among men of comparable intelligence and education who go into administrative and similar positions. High anxiety and excitability appear common (e.g. Priestley, Darwin, Kepler) but full-blown neurosis is quite rare. (Cattell & Butcher, 1970, p. 315)

   5) Its Mundane Character

   he insight that is supposed to be required for such work as discovery turns out to be synonymous with the familiar process of recognition; and other terms commonly used in the discussion of creative work-such terms as "judgment," "creativity," or even "genius"-appear to be wholly dispensable or to be definable, as insight is, in terms of mundane and well-understood concepts. (Simon, 1989, p. 376)

   6) Mozart's Musical Ideas Came to Him in Polished Form

   From the sketch material still in existence, from the condition of the fragments, and from the autographs themselves we can draw definite conclusions about Mozart's creative process. To invent musical ideas he did not need any stimulation; they came to his mind "ready-made" and in polished form. In contrast to Beethoven, who made numerous attempts at shaping his musical ideas until he found the definitive formulation of a theme, Mozart's first inspiration has the stamp of finality. Any Mozart theme has completeness and unity; as a phenomenon it is a Gestalt. (Herzmann, 1964, p. 28)

   7) Scientific Theories and Works of Art Alike Originate in Fantasy

   Great artists enlarge the limits of one's perception. Looking at the world through the eyes of Rembrandt or Tolstoy makes one able to perceive aspects of truth about the world which one could not have achieved without their aid. Freud believed that science was adaptive because it facilitated mastery of the external world; but was it not the case that many scientific theories, like works of art, also originated in phantasy? Certainly, reading accounts of scientific discovery by men of the calibre of Einstein compelled me to conclude that phantasy was not merely escapist, but a way of reaching new insights concerning the nature of reality. Scientific hypotheses require proof; works of art do not. Both are concerned with creating order, with making sense out of the world and our experience of it. (Storr, 1993, p. xii)

   8) Self- Esteem and Creative Expression

   The importance of self-esteem for creative expression appears to be almost beyond disproof. Without a high regard for himself the individual who is working in the frontiers of his field cannot trust himself to discriminate between the trivial and the significant. Without trust in his own powers the person seeking improved solutions or alternative theories has no basis for distinguishing the significant and profound innovation from the one that is merely different.... An essential component of the creative process, whether it be analysis, synthesis, or the development of a new perspective or more comprehensive theory, is the conviction that one's judgment in interpreting the events is to be trusted. (Coopersmith, 1967, p. 59)

   9) Stages in Creative Problem- Solving

   In the daily stream of thought these four different stages [preparation; incubation; illumination or inspiration; and verification] constantly overlap each other as we explore different problems. An economist reading a Blue Book, a physiologist watching an experiment, or a business man going through his morning's letters, may at the same time be "incubating" on a problem which he proposed to himself a few days ago, be accumulating knowledge in "preparation" for a second problem, and be "verifying" his conclusions to a third problem. Even in exploring the same problem, the mind may be unconsciously incubating on one aspect of it, while it is consciously employed in preparing for or verifying another aspect. (Wallas, 1926, p. 81)

    10) The Bisociative Pattern of the Creative Synthesis

   he basic, bisociative pattern of the creative synthesis [is] the sudden interlocking of two previously unrelated skills, or matrices of thought. (Koestler, 1964, p. 121)

    11) The Earliest Stages in the Creative Process Involve a Commerce with Disorder

   Even to the creator himself, the earliest effort may seem to involve a commerce with disorder. For the creative order, which is an extension of life, is not an elaboration of the established, but a movement beyond the established, or at least a reorganization of it and often of elements not included in it. The first need is therefore to transcend the old order. Before any new order can be defined, the absolute power of the established, the hold upon us of what we know and are, must be broken. New life comes always from outside our world, as we commonly conceive that world. This is the reason why, in order to invent, one must yield to the indeterminate within him, or, more precisely, to certain illdefined impulses which seem to be of the very texture of the ungoverned fullness which John Livingston Lowes calls "the surging chaos of the unexpressed." (Ghiselin, 1985, p. 4)

    12) The Inner Life of the Creative Process

   New life comes always from outside our world, as we commonly conceive our world. This is the reason why, in order to invent, one must yield to the indeterminate within him, or, more precisely, to certain illdefined impulses which seem to be of the very texture of the ungoverned fullness which John Livingston Lowes calls "the surging chaos of the unexpressed." Chaos and disorder are perhaps the wrong terms for that indeterminate fullness and activity of the inner life. For it is organic, dynamic, full of tension and tendency. What is absent from it, except in the decisive act of creation, is determination, fixity, and commitment to one resolution or another of the whole complex of its tensions. (Ghiselin, 1952, p. 13)

    13) The Problem of What Impels the Creative Person

   [P]sychoanalysts have principally been concerned with the content of creative products, and with explaining content in terms of the artist's infantile past. They have paid less attention to examining why the artist chooses his particular activity to express, abreact or sublimate his emotions. In short, they have not made much distinction between art and neurosis; and, since the former is one of the blessings of mankind, whereas the latter is one of the curses, it seems a pity that they should not be better differentiated....

   Psychoanalysis, being fundamentally concerned with drive and motive, might have been expected to throw more light upon what impels the creative person that in fact it has. (Storr, 1993, pp. xvii, 3)

    14) Theories of Creative Thinking

   A number of theoretical approaches were considered. Associative theory, as developed by Mednick (1962), gained some empirical support from the apparent validity of the Remote Associates Test, which was constructed on the basis of the theory.... Koestler's (1964) bisociative theory allows more complexity to mental organization than Mednick's associative theory, and postulates "associative contexts" or "frames of reference." He proposed that normal, non-creative, thought proceeds within particular contexts or frames and that the creative act involves linking together previously unconnected frames.... Simonton (1988) has developed associative notions further and explored the mathematical consequences of chance permutation of ideas....

   Like Koestler, Gruber (1980; Gruber and Davis, 1988) has based his analysis on case studies. He has focused especially on Darwin's development of the theory of evolution. Using piagetian notions, such as assimilation and accommodation, Gruber shows how Darwin's system of ideas changed very slowly over a period of many years. "Moments of insight," in Gruber's analysis, were the culminations of slow long-term processes.... Finally, the information-processing approach, as represented by Simon (1966) and Langley et al. (1987), was considered.... [Simon] points out the importance of good problem representations, both to ensure search is in an appropriate problem space and to aid in developing heuristic evaluations of possible research directions.... The work of Langley et al. (1987) demonstrates how such search processes, realized in computer programs, can indeed discover many basic laws of science from tables of raw data.... Boden (1990a, 1994) has stressed the importance of restructuring the problem space in creative work to develop new genres and paradigms in the arts and sciences. (Gilhooly, 1996, pp. 243-244; emphasis in original)

arc-proof low voltage switchgear and controlgear assembly

1. НКУ с защитой от воздействия электрической дуги

 

НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]

EN

arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.

There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.

Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.

arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]

Параллельные тексты EN-RU

If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.

Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.

The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.

Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.

This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.

Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.

These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.

As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.

This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.

[ABB]

Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.

Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.

Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.

Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.

Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.

При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.

Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.

Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.

Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.

[Перевод Интент]

Тематики

• НКУ (шкафы, пульты,...)

Синонимы

• комплектное устройство с защитой от электрической дуги
• низковольтное комплектное устройство с защитой от электрической дуги
• НКУ распределения и управления с защитой от электрической дуги

EN

• arc-proof low voltage switchgear and controlgear assembly
• arc-proof switchboard
• arc-proof switchgear
• arc-resistant switchgear
• internal arc-proof switchgear and controlgear assemblу

arc-proof switchboard

1. НКУ с защитой от воздействия электрической дуги

 

НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]

EN

arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.

There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.

Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.

arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]

Параллельные тексты EN-RU

If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.

Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.

The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.

Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.

This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.

Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.

These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.

As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.

This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.

[ABB]

Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.

Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.

Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.

Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.

Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.

При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.

Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.

Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.

Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.

[Перевод Интент]

Тематики

• НКУ (шкафы, пульты,...)

Синонимы

• комплектное устройство с защитой от электрической дуги
• низковольтное комплектное устройство с защитой от электрической дуги
• НКУ распределения и управления с защитой от электрической дуги

EN

• arc-proof low voltage switchgear and controlgear assembly
• arc-proof switchboard
• arc-proof switchgear
• arc-resistant switchgear
• internal arc-proof switchgear and controlgear assemblу

arc-proof switchgear

1. НКУ с защитой от воздействия электрической дуги

 

НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]

EN

arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.

There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.

Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.

arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]

Параллельные тексты EN-RU

If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.

Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.

The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.

Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.

This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.

Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.

These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.

As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.

This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.

[ABB]

Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.

Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.

Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.

Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.

Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.

При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.

Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.

Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.

Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.

[Перевод Интент]

Тематики

• НКУ (шкафы, пульты,...)

Синонимы

• комплектное устройство с защитой от электрической дуги
• низковольтное комплектное устройство с защитой от электрической дуги
• НКУ распределения и управления с защитой от электрической дуги

EN

• arc-proof low voltage switchgear and controlgear assembly
• arc-proof switchboard
• arc-proof switchgear
• arc-resistant switchgear
• internal arc-proof switchgear and controlgear assemblу

arc-resistant switchgear

1. НКУ с защитой от воздействия электрической дуги

 

НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]

EN

arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.

There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.

Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.

arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]

Параллельные тексты EN-RU

If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.

Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.

The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.

Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.

This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.

Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.

These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.

As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.

This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.

[ABB]

Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.

Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.

Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.

Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.

Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.

При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.

Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.

Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.

Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.

[Перевод Интент]

Тематики

• НКУ (шкафы, пульты,...)

Синонимы

• комплектное устройство с защитой от электрической дуги
• низковольтное комплектное устройство с защитой от электрической дуги
• НКУ распределения и управления с защитой от электрической дуги

EN

• arc-proof low voltage switchgear and controlgear assembly
• arc-proof switchboard
• arc-proof switchgear
• arc-resistant switchgear
• internal arc-proof switchgear and controlgear assemblу

internal arc-proof switchgear and controlgear assemblу

1. НКУ с защитой от воздействия электрической дуги

 

НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]

EN

arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.

There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.

Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.

arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]

Параллельные тексты EN-RU

If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.

Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.

The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.

Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.

This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.

Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.

These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.

As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.

This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.

[ABB]

Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.

Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.

Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.

Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.

Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.

При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.

Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.

Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.

Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.

[Перевод Интент]

Тематики

• НКУ (шкафы, пульты,...)

Синонимы

• комплектное устройство с защитой от электрической дуги
• низковольтное комплектное устройство с защитой от электрической дуги
• НКУ распределения и управления с защитой от электрической дуги

EN

• arc-proof low voltage switchgear and controlgear assembly
• arc-proof switchboard
• arc-proof switchgear
• arc-resistant switchgear
• internal arc-proof switchgear and controlgear assemblу