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101 Bte
1) Общая лексика: Заушный слуховой аппарат2) Медицина: Biphasic Truncated Exponential3) Военный термин: Between The Eyes, British Troops in Europe, battery terminal equipment, battery timing equipment, built-in test equipment4) Техника: bad tape error5) Электроника: Boltzmann Transport Equation6) Вычислительная техника: Broadband Terminal Equipment (B-ISDN)7) Деловая лексика: Business Transaction Event8) Ядерная физика: Baldwin Tate Emery -
102 bte
1) Общая лексика: Заушный слуховой аппарат2) Медицина: Biphasic Truncated Exponential3) Военный термин: Between The Eyes, British Troops in Europe, battery terminal equipment, battery timing equipment, built-in test equipment4) Техника: bad tape error5) Электроника: Boltzmann Transport Equation6) Вычислительная техника: Broadband Terminal Equipment (B-ISDN)7) Деловая лексика: Business Transaction Event8) Ядерная физика: Baldwin Tate Emery -
103 system
система; комплекс; средство; способ; метод; сеть (напр. дорог) ;aiming-navigation system (analog, digital) — прицельно-навигационная система (аналоговая, цифровая)
air observation, acquisition and fire control system — (бортовая) система воздушной разведки, засечки целей и управления огнем
air support aircraft ECM (equipment) system — (бортовая) система РЭП для самолетов авиационной поддержки
airborne (ground) target acquisition and illumination laser system — ав. бортовая лазерная система обнаружения и подсветки (наземных) целей
airborne (ground) targeting and laser designator system — ав. бортовая лазерная система обнаружения и целеуказания (наземных целей)
airborne laser illumination, ranging and tracking system — ав. бортовая система лазерной подсветки, определения дальности и сопровождения цели
artillery (nuclear) delivery system — артиллерийская система доставки (ядерного) боеприпаса (к цели)
C2 system — система оперативного управления; система руководства и управления
C3 system — система руководства, управления и связи; система оперативного управления и связи
channel and message switching (automatic) communications system — АСС с коммутацией каналов и сообщений
country-fair type rotation system (of instruction) — метод одновременного обучения [опроса] нескольких учебных групп (переходящих от одного объекта изучения к другому)
dual-capable (conventional/nuclear) weapon delivery system — система доставки (обычного или ядерного) боеприпаса к цели
electromagnetic emitters identification, location and suppression system — система обнаружения, опознавания и подавления источников электромагнитных излучений [излучающих РЭС]
field antimissile (missile) system — полевой [войсковой] ПРК
fire-on-the-move (air defense) gun system — подвижный зенитный артиллерийский комплекс для стрельбы в движении [на ходу]
fluidic (missile) control system — ркт. гидравлическая [струйная] система управления полетом
forward (area) air defense system — система ПВО передового района; ЗРК для войсковой ПВО передового района
graduated (availability) operational readiness system — Бр. система поэтапной боевой готовности (частей и соединений)
high-resolution satellite IR detection, tracking and targeting system — спутниковая система с ИК аппаратурой высокой разрешающей способности для обнаружения, сопровождения целей и наведения средств поражения
ICBM (alarm and) early warning satellite system — спутниковая система обнаружения пусков МБР и раннего предупреждения (средств ПРО)
information storage, tracking and retrieval system — система накопления, хранения и поиска информации
instantaneous grenade launcher (armored vehicle) smoke system — гранатомет (БМ) для быстрой постановки дымовой завесы
Precision Location [Locator] (and) Strike system — высокоточная система обеспечения обнаружения и поражения целей; высокоточный разведывательно-ударный комплекс
rapid deceleration (parachute) delivery system — парашютная система выброски грузов с быстрым торможением
real time, high-resolution reconnaissance satellite system — спутниковая разведывательная система с высокой разрешающей способностью аппаратуры и передачей информации в реальном масштабе времени
received signal-oriented (output) jamming signal power-adjusting ECM system — система РЭП с автоматическим регулированием уровня помех в зависимости от мощности принимаемого сигнала
sea-based nuclear (weapon) delivery system — система морского базирования доставки ядерного боеприпаса к цели
small surface-to-air ship self-defense (missile) system — ЗРК ближнего действия для самообороны корабля
Status Control, Alerting and Reporting system — система оповещения, контроля и уточнения состояния [боевой готовности] сил и средств
surface missile (weapon) system — наземный [корабельный] РК
target acquisition, rapid designation and precise aiming system — комплекс аппаратуры обнаружения цели, быстрого целеуказания и точного прицеливания
— ABM defense system— antimissile missile system— central weapon system— countersurprise military system— laser surveying system— tank weapon system— vertical launching system— weapons system -
104 Edison, Thomas Alva
SUBJECT AREA: Architecture and building, Automotive engineering, Electricity, Electronics and information technology, Metallurgy, Photography, film and optics, Public utilities, Recording, Telecommunications[br]b. 11 February 1847 Milan, Ohio, USAd. 18 October 1931 Glenmont[br]American inventor and pioneer electrical developer.[br]He was the son of Samuel Edison, who was in the timber business. His schooling was delayed due to scarlet fever until 1855, when he was 8½ years old, but he was an avid reader. By the age of 14 he had a job as a newsboy on the railway from Port Huron to Detroit, a distance of sixty-three miles (101 km). He worked a fourteen-hour day with a stopover of five hours, which he spent in the Detroit Free Library. He also sold sweets on the train and, later, fruit and vegetables, and was soon making a profit of $20 a week. He then started two stores in Port Huron and used a spare freight car as a laboratory. He added a hand-printing press to produce 400 copies weekly of The Grand Trunk Herald, most of which he compiled and edited himself. He set himself to learn telegraphy from the station agent at Mount Clements, whose son he had saved from being run over by a freight car.At the age of 16 he became a telegraphist at Port Huron. In 1863 he became railway telegraphist at the busy Stratford Junction of the Grand Trunk Railroad, arranging a clock with a notched wheel to give the hourly signal which was to prove that he was awake and at his post! He left hurriedly after failing to hold a train which was nearly involved in a head-on collision. He usually worked the night shift, allowing himself time for experiments during the day. His first invention was an arrangement of two Morse registers so that a high-speed input could be decoded at a slower speed. Moving from place to place he held many positions as a telegraphist. In Boston he invented an automatic vote recorder for Congress and patented it, but the idea was rejected. This was the first of a total of 1180 patents that he was to take out during his lifetime. After six years he resigned from the Western Union Company to devote all his time to invention, his next idea being an improved ticker-tape machine for stockbrokers. He developed a duplex telegraphy system, but this was turned down by the Western Union Company. He then moved to New York.Edison found accommodation in the battery room of Law's Gold Reporting Company, sleeping in the cellar, and there his repair of a broken transmitter marked him as someone of special talents. His superior soon resigned, and he was promoted with a salary of $300 a month. Western Union paid him $40,000 for the sole rights on future improvements on the duplex telegraph, and he moved to Ward Street, Newark, New Jersey, where he employed a gathering of specialist engineers. Within a year, he married one of his employees, Mary Stilwell, when she was only 16: a daughter, Marion, was born in 1872, and two sons, Thomas and William, in 1876 and 1879, respectively.He continued to work on the automatic telegraph, a device to send out messages faster than they could be tapped out by hand: that is, over fifty words per minute or so. An earlier machine by Alexander Bain worked at up to 400 words per minute, but was not good over long distances. Edison agreed to work on improving this feature of Bain's machine for the Automatic Telegraph Company (ATC) for $40,000. He improved it to a working speed of 500 words per minute and ran a test between Washington and New York. Hoping to sell their equipment to the Post Office in Britain, ATC sent Edison to England in 1873 to negotiate. A 500-word message was to be sent from Liverpool to London every half-hour for six hours, followed by tests on 2,200 miles (3,540 km) of cable at Greenwich. Only confused results were obtained due to induction in the cable, which lay coiled in a water tank. Edison returned to New York, where he worked on his quadruplex telegraph system, tests of which proved a success between New York and Albany in December 1874. Unfortunately, simultaneous negotiation with Western Union and ATC resulted in a lawsuit.Alexander Graham Bell was granted a patent for a telephone in March 1876 while Edison was still working on the same idea. His improvements allowed the device to operate over a distance of hundreds of miles instead of only a few miles. Tests were carried out over the 106 miles (170 km) between New York and Philadelphia. Edison applied for a patent on the carbon-button transmitter in April 1877, Western Union agreeing to pay him $6,000 a year for the seventeen-year duration of the patent. In these years he was also working on the development of the electric lamp and on a duplicating machine which would make up to 3,000 copies from a stencil. In 1876–7 he moved from Newark to Menlo Park, twenty-four miles (39 km) from New York on the Pennsylvania Railway, near Elizabeth. He had bought a house there around which he built the premises that would become his "inventions factory". It was there that he began the use of his 200- page pocket notebooks, each of which lasted him about two weeks, so prolific were his ideas. When he died he left 3,400 of them filled with notes and sketches.Late in 1877 he applied for a patent for a phonograph which was granted on 19 February 1878, and by the end of the year he had formed a company to manufacture this totally new product. At the time, Edison saw the device primarily as a business aid rather than for entertainment, rather as a dictating machine. In August 1878 he was granted a British patent. In July 1878 he tried to measure the heat from the solar corona at a solar eclipse viewed from Rawlins, Wyoming, but his "tasimeter" was too sensitive.Probably his greatest achievement was "The Subdivision of the Electric Light" or the "glow bulb". He tried many materials for the filament before settling on carbon. He gave a demonstration of electric light by lighting up Menlo Park and inviting the public. Edison was, of course, faced with the problem of inventing and producing all the ancillaries which go to make up the electrical system of generation and distribution-meters, fuses, insulation, switches, cabling—even generators had to be designed and built; everything was new. He started a number of manufacturing companies to produce the various components needed.In 1881 he built the world's largest generator, which weighed 27 tons, to light 1,200 lamps at the Paris Exhibition. It was later moved to England to be used in the world's first central power station with steam engine drive at Holborn Viaduct, London. In September 1882 he started up his Pearl Street Generating Station in New York, which led to a worldwide increase in the application of electric power, particularly for lighting. At the same time as these developments, he built a 1,300yd (1,190m) electric railway at Menlo Park.On 9 August 1884 his wife died of typhoid. Using his telegraphic skills, he proposed to 19-year-old Mina Miller in Morse code while in the company of others on a train. He married her in February 1885 before buying a new house and estate at West Orange, New Jersey, building a new laboratory not far away in the Orange Valley.Edison used direct current which was limited to around 250 volts. Alternating current was largely developed by George Westinghouse and Nicola Tesla, using transformers to step up the current to a higher voltage for long-distance transmission. The use of AC gradually overtook the Edison DC system.In autumn 1888 he patented a form of cinephotography, the kinetoscope, obtaining film-stock from George Eastman. In 1893 he set up the first film studio, which was pivoted so as to catch the sun, with a hinged roof which could be raised. In 1894 kinetoscope parlours with "peep shows" were starting up in cities all over America. Competition came from the Latham Brothers with a screen-projection machine, which Edison answered with his "Vitascope", shown in New York in 1896. This showed pictures with accompanying sound, but there was some difficulty with synchronization. Edison also experimented with captions at this early date.In 1880 he filed a patent for a magnetic ore separator, the first of nearly sixty. He bought up deposits of low-grade iron ore which had been developed in the north of New Jersey. The process was a commercial success until the discovery of iron-rich ore in Minnesota rendered it uneconomic and uncompetitive. In 1898 cement rock was discovered in New Village, west of West Orange. Edison bought the land and started cement manufacture, using kilns twice the normal length and using half as much fuel to heat them as the normal type of kiln. In 1893 he met Henry Ford, who was building his second car, at an Edison convention. This started him on the development of a battery for an electric car on which he made over 9,000 experiments. In 1903 he sold his patent for wireless telegraphy "for a song" to Guglielmo Marconi.In 1910 Edison designed a prefabricated concrete house. In December 1914 fire destroyed three-quarters of the West Orange plant, but it was at once rebuilt, and with the threat of war Edison started to set up his own plants for making all the chemicals that he had previously been buying from Europe, such as carbolic acid, phenol, benzol, aniline dyes, etc. He was appointed President of the Navy Consulting Board, for whom, he said, he made some forty-five inventions, "but they were pigeonholed, every one of them". Thus did Edison find that the Navy did not take kindly to civilian interference.In 1927 he started the Edison Botanic Research Company, founded with similar investment from Ford and Firestone with the object of finding a substitute for overseas-produced rubber. In the first year he tested no fewer than 3,327 possible plants, in the second year, over 1,400, eventually developing a variety of Golden Rod which grew to 14 ft (4.3 m) in height. However, all this effort and money was wasted, due to the discovery of synthetic rubber.In October 1929 he was present at Henry Ford's opening of his Dearborn Museum to celebrate the fiftieth anniversary of the incandescent lamp, including a replica of the Menlo Park laboratory. He was awarded the Congressional Gold Medal and was elected to the American Academy of Sciences. He died in 1931 at his home, Glenmont; throughout the USA, lights were dimmed temporarily on the day of his funeral.[br]Principal Honours and DistinctionsMember of the American Academy of Sciences. Congressional Gold Medal.Further ReadingM.Josephson, 1951, Edison, Eyre \& Spottiswode.R.W.Clark, 1977, Edison, the Man who Made the Future, Macdonald \& Jane.IMcN -
105 training
( боевая) подготовка; обучение; тренировка; наведениеship-based training (for assault landing) — десантная подготовка совместно с кораблями и плавучими средствами
— career enhancing training— common-track training— continental US training— cross-rate training— gunnery-oriented training— hand-to-hand combat training— intra-unit training— joint service training— nuclear weapon training— physical readiness training— reserve cycle training— resident school training— rifle marksmanship training— systems specific training -
106 Siemens, Sir Charles William
[br]b. 4 April 1823 Lenthe, Germanyd. 19 November 1883 London, England[br]German/British metallurgist and inventory pioneer of the regenerative principle and open-hearth steelmaking.[br]Born Carl Wilhelm, he attended craft schools in Lübeck and Magdeburg, followed by an intensive course in natural science at Göttingen as a pupil of Weber. At the age of 19 Siemens travelled to England and sold an electroplating process developed by his brother Werner Siemens to Richard Elkington, who was already established in the plating business. From 1843 to 1844 he obtained practical experience in the Magdeburg works of Count Stolburg. He settled in England in 1844 and later assumed British nationality, but maintained close contact with his brother Werner, who in 1847 had co-founded the firm Siemens \& Halske in Berlin to manufacture telegraphic equipment. William began to develop his regenerative principle of waste-heat recovery and in 1856 his brother Frederick (1826–1904) took out a British patent for heat regeneration, by which hot waste gases were passed through a honeycomb of fire-bricks. When they became hot, the gases were switched to a second mass of fire-bricks and incoming air and fuel gas were led through the hot bricks. By alternating the two gas flows, high temperatures could be reached and considerable fuel economies achieved. By 1861 the two brothers had incorporated producer gas fuel, made by gasifying low-grade coal.Heat regeneration was first applied in ironmaking by Cowper in 1857 for heating the air blast in blast furnaces. The first regenerative furnace was set up in Birmingham in 1860 for glassmaking. The first such furnace for making steel was developed in France by Pierre Martin and his father, Emile, in 1863. Siemens found British steelmakers reluctant to adopt the principle so in 1866 he rented a small works in Birmingham to develop his open-hearth steelmaking furnace, which he patented the following year. The process gradually made headway; as well as achieving high temperatures and saving fuel, it was slower than Bessemer's process, permitting greater control over the content of the steel. By 1900 the tonnage of open-hearth steel exceeded that produced by the Bessemer process.In 1872 Siemens played a major part in founding the Society of Telegraph Engineers (from which the Institution of Electrical Engineers evolved), serving as its first President. He became President for the second time in 1878. He built a cable works at Charlton, London, where the cable could be loaded directly into the holds of ships moored on the Thames. In 1873, together with William Froude, a British shipbuilder, he designed the Faraday, the first specialized vessel for Atlantic cable laying. The successful laying of a cable from Europe to the United States was completed in 1875, and a further five transatlantic cables were laid by the Faraday over the following decade.The Siemens factory in Charlton also supplied equipment for some of the earliest electric-lighting installations in London, including the British Museum in 1879 and the Savoy Theatre in 1882, the first theatre in Britain to be fully illuminated by electricity. The pioneer electric-tramway system of 1883 at Portrush, Northern Ireland, was an opportunity for the Siemens company to demonstrate its equipment.[br]Principal Honours and DistinctionsKnighted 1883. FRS 1862. Institution of Civil Engineers Telford Medal 1853. President, Institution of Mechanical Engineers 1872. President, Society of Telegraph Engineers 1872 and 1878. President, British Association 1882.Bibliography27 May 1879, British patent no. 2,110 (electricarc furnace).1889, The Scientific Works of C.William Siemens, ed. E.F.Bamber, 3 vols, London.Further ReadingW.Poles, 1888, Life of Sir William Siemens, London; repub. 1986 (compiled from material supplied by the family).S.von Weiher, 1972–3, "The Siemens brothers. Pioneers of the electrical age in Europe", Transactions of the Newcomen Society 45:1–11 (a short, authoritative biography). S.von Weihr and H.Goetler, 1983, The Siemens Company. Its Historical Role in theProgress of Electrical Engineering 1847–1980, English edn, Berlin (a scholarly account with emphasis on technology).GWBiographical history of technology > Siemens, Sir Charles William
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107 BTE
BTE, battery terminal equipment————————BTE, battery timing equipment————————BTE, British Troops in Europe————————BTE, built-in test equipmentEnglish-Russian dictionary of planing, cross-planing and slotting machines > BTE
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108 machine
станок; машина || обрабатывать на станкеto machine all over — обрабатывать ( изделие) кругом
to CNC machine — обрабатывать на станке с ЧПУ, обрабатывать на станке с ЧПУ типа CNC, обрабатывать изделие на станке с ЧПУ, обрабатывать изделие на станке с ЧПУ типа CNC
to fix a machine — налаживать станок; ремонтировать станок
to machine off — срезать; отрезать
to machine the feature — обрабатывать элемент, обрабатывать элемент изделия
to program the machine — программировать ( обработку) на станке
machine with sliding frame — станок с подвижной рамой, станок с перемещающейся рамой
- 2 m3 machinemachine with traveling table for shaping — станок с подвижным столом для раскроя по формату, станок с перемещающимся столом для раскроя по формату
- 3-axis NC machine
- 50-taper machine
- 630-mm-class machine
- 90º plate shearing machine
- 90º sheet shearing machine
- above resonance-balancing machine
- abrasion testing machine
- abrasive belt head machine
- abrasive belt-grinding machine
- abrasive cold-sawing machine
- abrasive cutting-off machine
- abrasive disk machine
- abrasive electrochemical machine
- abrasive metal-cutting machine
- abrasive wear-testing machine
- AC machine
- accounting machine
- acyclic machine
- adapting machine
- adaptive control machine
- adaptive controlled machine
- adding machine
- adjustable multiple-spindle drilling machine
- adjustable rail machine
- adjustable rail milling machine
- advanced technology machine
- air-drying machine
- airspace profiling machine
- align boring machine
- all-electric machine
- all-geared machine
- all-hydraulic machine
- all-purpose machine
- all-steel machine
- alterating impact testing machine
- alterating stress testing machine
- aluminum machine
- analog machine
- ancillary inspection machine
- angle straightening machine
- angle-bending machine
- angle-iron bending machine
- angle-iron shearing machine
- anthropomorphic machine
- arm tapping machine
- armoring machine
- articulating arm tapping machine
- artificial intelligence-driven machine
- AS/R machine
- aspheric diamond turning machine
- assembling machine
- assembly machine
- ATC machine
- ATC-equipped machine
- atomic X-ray machine
- attrition testing machine
- autochucking machine
- automatic arc welding machine
- automatic assembly machine
- automatic bar machine
- automatic buffing machine
- automatic chucking machine
- automatic chucking-and-turning machine
- automatic continuous drum milling machine
- automatic data processing machine
- automatic drill fluting machine
- automatic forging machine
- automatic gas-cutting machine
- automatic gas-welding machine
- automatic machine
- automatic metal forming machine
- automatic polishing machine
- automatic punching machine
- automatic screw machine
- automatic straightening and cutting machine
- automatic strip-straightening machine
- automatic tapping machine
- automatic toolchanger machine
- automatic toolchanging machine
- automatic turret machine
- axial fatigue machine
- axis-controlled machine
- axle turning machine
- balancing machine
- baling machine
- ball race grinding machine
- ball screw machine
- ball-grinding machine
- ball-hardness testing machine
- balling machine
- band cutoff machine
- band machine
- band metal shearing machine
- band-filing machine
- band-grinding machine
- banding machine
- band-polishing machine
- bandsaw blade grinding machine
- bandsaw machine
- bandsaw welding machine
- bandsaw-brazing machine
- bandsawing machine
- bandsaw-sharpening machine
- bar automatic turning machine
- bar feed machine
- bar feed turning machine
- bar machine
- bar-and-chucking machine
- bar-and-chucking turning machine
- bar-and-tube straightening machine
- bar-bending machine
- bar-chamfering machine
- bar-cutting machine
- bar-pointing machine
- bar-polishing machine
- barreling machine
- bar-shearing machine
- bar-skimming machine
- bar-straightening machine
- bar-tagging machine
- bar-type boring machine
- base-type milling machine
- basic machine
- batch-produced machine
- battery spot-welding machine
- beading machine
- bearing roller lapping machine
- bed-type configuration machine
- bed-type drilling machine
- bed-type machine
- bed-type milling machine
- below resonance balancing machine
- belt-driven machine
- belt-grinding machine
- belt-polishing machine
- bench-grinding machine
- bench-mounted machine
- bench-top machine
- bench-type machine
- bending and forming machine
- bending machine
- between-centers turning machine
- bevel gear hobbing machine for spiral bevel gears
- bevel gear hobbing machine for straight gears
- bevel gear lapping machine
- bevel gear making machine
- bevel gear testing machine
- bevel grinding machine
- beveling machine
- bidirectional broaching machine
- binding machine
- bipedal walking machine
- bitting machine
- blade-edging machine
- blade-grinding machine
- blanking machine
- blending machine
- blind spline broach machine
- blind spline broaching machine
- block-and-head broaching machine
- blocked machine
- blower machine
- blowing machine
- blow-ramming molding machine
- blue-print machine
- blue-printing machine
- bobbin machine
- bolt head forging machine
- bolting machine
- bolt-maker machine
- bolt-making machine
- bolt-pointing machine
- bolt-screwing machine
- bolt-threading machine
- bolt-upsetting machine
- bonded machine
- bore centerless grinding machine
- bore-sizing machine
- bore-slotting machine
- boring and milling machine
- boring machine
- boring/facing machine
- boring, drilling and milling machine
- boring, milling and drilling machine
- bottleneck machine
- box-column drilling machine
- bracket-drilling machine
- bracket-milling machine
- braiding machine
- brazing machine
- breaking machine
- bridge machine
- Bridgeport milling machine
- bridge-type milling machine
- Brinell's machine
- broach pulldown machine
- broach-and-center machine
- broach-grinding machine
- broaching tool sharpening machine
- broach-sharpening machine
- brushing machine
- buffing machine
- built-from-scratch machine
- bunching machine
- burn machine
- burning machine
- burnishing machine
- burr-cutting machine
- burring machine
- busy machine
- butt-seam welding machine
- butt-welding machine
- by-level broaching machine
- cabinet-based machine
- cable tension testing machine
- cable-making machine
- cable-stranding machine
- cam automatic screw machine
- cam machine
- cam-controlled machine
- cam-controlled screw machine
- cam-cutting machine
- cam-driven machine
- cam-driven screw machine
- cam-grinding machine
- cam-measuring machine
- cammed screw machine
- cam-milling machine
- cam-operated screw machine
- camshaft-grinding machine
- capable machine
- capacitor discharge spot-welding machine
- capacitor spot-welding machine
- capstan drive machine
- car wheel grinding machine
- carbide tool grinding machine
- carbide tool lapping machine
- carousel machine
- cast iron machine
- cast machine
- casting cleaning machine
- casting machine
- casting washing machine
- cavity sinking EDM machine
- cell machine
- center column rotary index machine
- center column rotary indexing machine
- center hole grinding machine
- center hole lapping machine
- center-drilling machine
- centerdrive machine
- centering and end facing machine
- centering and facing machine
- centering machine
- centerless bar turning machine
- centerless cylindrical grinding machine
- centerless grinding machine
- centerless lapping machine
- centerless polishing machine
- centerless turning machine
- center-type machine
- center-type turning machine
- centrifugal babbiting machine
- centrifugal casting machine
- centrifugal machine
- centrifugal sand-throwing machine
- ceramic-cutting machine
- chain broaching machine
- chain making machine
- chain shotblasting machine
- chain tension testing machine
- chain testing machine
- chain-operated broaching machine
- chamfering machine
- charge-discharge machine
- Charpy impact machine
- Charpy machine
- charting machine
- check balancing machine
- checking machine
- chip-making machine
- chip-producing machine
- chucker machine
- chucker-and-bar machine
- chucking machine
- circle cutting machine
- circuit board drilling machine
- circular cold sawing machine
- circular continuous milling machine
- circular cutoff machine
- circular dividing machine
- circular graduating machine
- circular grinding machine
- circular hot sawing machine
- circular saw blade grinding machine
- circular saw sharpening machine
- circular sawing machine
- circular seam-welding machine
- circumferential seam-welding machine
- cleaning machine
- closing machine
- CNC high-speed routing machine
- CNC machine
- CNC screw machine
- CNC Swiss-type screw machine
- CNC/CMM machine
- CNC-manual machine
- CNC-operated machine
- CNC-retrofitted machine
- CO2 laser cutting machine
- coil banding machine
- coil downending machine
- coiling machine
- coil-processing machine
- coil-strapping machine
- coil-stripping machine
- coil-winding machine
- coil-wrapping machine
- cold saw-cutting-off machine
- cold thread rolling machine
- cold upsetting machine
- cold-chamber die-casting machine
- cold-forging machine
- cold-forming machine
- cold-heading machine
- cold-sawing machine
- collecting machine
- column drilling machine
- column-and-knee-type machine
- column-and-knee-type milling machine
- combination jarring squeezing molding machine
- combined boring-and-honing machine
- combined curve-cutting and nibbling machine
- combined gear hobbing and gear shaping machine
- combined machine
- combined milling-turning machine
- combined planing-and-milling machine
- combined shearing machine
- combined surface planing and thicknessing machine
- combined vertical and horizontal broaching machine
- commercial machine
- commutator machine
- complementary machines
- component cleaning machine
- component insertion machine
- composite boring-and-honing machine
- compound machine
- compound table machine
- compound universal milling machine
- compressed air driven machine
- compressed gas machine
- compression-testing machine
- compression-type machine
- computer-controlled industrial machine
- computer-controlled machine
- computerized machine
- computing machine
- condenser spot-welding machine
- cone pulley machine
- conical rotor machine
- constant cycling machine
- container erecting-and-forming machine
- container-cleaning machine
- container-washing machine
- continuous chain broaching machine
- continuous drum milling machine
- continuous motion machine
- continuous motion orienting-and-tapping machine
- continuous path NC machine
- continuous path tape controlled machine
- continuous roll-forming machine
- continuous rotary milling machine
- continuous tapping machine
- continuous wire EDM machine
- continuous wire machine
- continuous-casting machine with bending discharge
- continuous-casting machine
- continuously running machine
- contour band machine
- contour production machine
- contour squeeze molding machine
- contouring band machine
- contouring machine
- contour-milling machine
- contour-shaping machine
- controlling machine
- conventional machine
- conventional manually-operated machine
- conventionally operated machine
- converted lathe-and-milling machine
- converted machine
- convertible planing machine
- conveying machine
- cooling machine
- coordinate boring machine
- coordinate boring-and-milling machine
- coordinate drilling machine
- coordinate drilling-boring-and-milling machine
- coordinate inspection machine
- coordinate measuring machine
- coping machine
- copy control machine
- copy grinding machine
- copying machine
- copy-milling machine
- copy-piercing machine
- copy-planing machine
- core blowing machine
- core jarring machine
- core shooting machine
- core wire straightening machine
- core-making machine
- corrosion-fatigue testing machine
- corrugating machine
- countersink machine
- countersinking machine
- coupling machine
- crack detection machine
- crankpin-turning machine
- crankshaft-balancing machine
- crankshaft-grinding machine
- crankshaft-lapping machine
- crankshaft-milling machine
- crankshaft-regrinding machine
- crank-shaping machine
- crank-slotting machine
- creasing machine
- creep feed grinding machine
- creep testing machine
- crimping machine
- crocodile shearing machine
- cropping machine
- cross roll-forging machine
- cross-wire welding machine
- crosswise veneer splicing machine
- crushing machine
- cupping machine
- curling machine
- curtain coating machine
- curve-cutting machine
- curved tooth bevel gear cutting machine
- curve-milling machine
- curvilinear slotting machine
- curving machine
- custom metalcutting machine
- custom-assembled machine
- custom-build machine
- customized machine
- cutoff band machine
- cutoff machine
- cutter inspection machine
- cutter-checking machine
- cutter-grinding machine
- cutter-relieving machine
- cutting machine with coordinate drive
- cutting machine
- cutting-off machine
- cylinder-boring machine
- cylinder-grinding machine
- cylinder-honing machine
- cylindrical coordinate-measuring machine
- cylindrical external grinding machine
- cylindrical gear hobbing machine
- cylindrical gear shaping machine
- cylindrical rotor machine
- cylindrical turning machine
- cylindrical-die thread-rolling machine
- data processing machine
- database machine
- DCC coordinate measuring machine
- De Levaud casting machine
- deburring machine
- decoiling machine
- dedicated proving machine
- dedicated special machine
- deencapsulation machine
- deep drawing machine
- deep hole boring machine
- deep hole drilling machine
- deep hole drilling/boring machine
- deep rolling machine
- defective machine
- degreasing machine
- descaling machine
- deseaming machine
- desktop machine
- destination machine
- detangling machine
- detwisting machine
- development machine
- dial machine
- dial-index machine
- dial-indexing machine
- dial-type machine
- dial-type transfer machine
- diamond die polishing machine
- diamond machine
- diamond pyramid hardness machine
- diamond-boring machine
- diamond-contouring machine
- diamond-honing machine
- diamond-impregnated wire cutting machine
- diamond-turning machine
- die head chaser grinding machine
- die-and-mold grinding machine
- die-casting machine
- die-filing machine
- die-grinding machine
- die-milling machine
- die-polishing machine
- die-ripping machine
- die-shaping machine
- die-sinking and hole-contouring machine
- die-sinking machine
- die-sinking milling machine
- die-sinking spark erosion machine
- die-stamping machine
- digging machine
- digitizing and scanning machine
- digitizing machine
- digitizing/cutting machine
- digitizing-metalcutting machine
- dimensional gaging machine
- direct computer controlled machine
- direct current commutator machine
- direct stress machine
- direct stress testing machine
- direct-drive machine
- discharge machine
- disk machine
- disk sanding machine
- disk-cutting machine
- disk-grinding machine
- disk-resurfacing machine
- dividing machine
- DMM machine
- DNC-controlled machine
- DNC-like machine
- DNC-supported machine
- double duplex milling machine
- double portal cutting machine
- double wheel lapping machine
- double-cantilever cutting machine
- double-column milling machine
- double-column planing machine
- double-column slideway grinding machine
- double-disk grinding machine
- double-end facing-and-centering machine
- double-end fine boring machine
- double-end grinding machine
- double-end machine
- double-end mill-and-centering machine
- double-end milling machine
- double-ended centering and end-facing machine
- double-ended centering machine
- double-ended drilling machine
- double-ended machine
- double-ended milling machine
- double-faced mill-and-centering machine
- double-fed asynchronous machine
- double-gantry milling machine
- double-head machine
- double-housing machine
- double-housing milling machine
- double-lap lapping and polishing machine
- double-punching machine
- double-ram vertical broaching machine
- double-roll forming machine
- double-shaping machine
- double-slide vertical broaching machine
- double-strand pig machine
- dovetailing machine
- dowel-insert machine
- down machine
- downstroking machine
- drafting machine
- draw machine
- drawing machine
- dream machine
- dressing machine
- drill and tap machine
- drill fluting machine
- drill machine
- drill press machine
- drill/tap machine
- drill-grinding machine
- drillhead-changing machine
- drilling machine
- drilling, milling and boring machine
- drilling-and-boring machine
- drilling-and-counterboring machine
- drilling-and-milling machine
- drilling-and-routing machine
- drilling-and-tapping machine
- drilling-and-threading machine
- drilling-tapping machine
- drill-layout machine
- drooping-characteristic machine
- drop-testing machine
- drum-type continuous milling machine
- drum-type milling machine
- dry cutting machine
- dry-floor machine
- drying machine
- dual co-axial spindle and subspindle turning machine
- dual controlled manual/CNC machine
- dual machine
- dual planing-and-milling machine
- dual-gantry machine
- dual-head machine
- dual-pallet machine
- dual-purpose machine
- dual-ram surface-broaching machine
- dual-station machine
- ductility testing machine
- dummy machine
- dumping molding machine
- duplex machine for rail ends
- duplex machine
- duplex multiple spindle machine
- duplex vertical broaching machine
- duplex-head milling machine
- duplex-manufacturing bed-type milling machine
- duplex-type of surface broaching machine
- duplicating machine
- duplicating milling machine
- dynamic balancing machine
- eager-beaver pulldown broaching machine
- earth-moving machine
- EB welding machine
- ECM machine
- economically priced machine
- ED grinding machine
- ED wire cutting machine
- ED-copying machine
- ED-cutting-off machine
- eddy current machine
- eddy current test machine
- edge-beveling machine
- edge-chamfering machine
- edge-cutting machine
- edge-knurling machine
- edge-milling machine
- edge-planing machine
- edge-trimming machine
- edging machine
- EDM diesinking machine
- EDM machine
- EDM texturing machine
- EDM wire machine
- EDM wire-cut machine
- ED-sinking machine
- educational machine
- efficiency testing machine
- eight-axis NC machine
- electric drive machine
- electric machine
- electric molding machine
- electrical discharge die-sinking and hole-contouring machine
- electrical discharge machine
- electrical discharge outcutting machine
- electrical discharge profiling machine
- electrically-operated machine
- electric-spark cutting machine
- electrochemical grinding machine
- electrode feeding machine
- electro-discharge drilling machine
- electro-discharge grinding machine
- electrolytic grinding machine
- electrolytic machine
- electrolytic tinning machine
- electrolytically assisted cutting-off machine
- electrolytically assisted machine
- electromagnetic molding machine
- electron beam drilling machine
- electron beam machine
- electron beam welding machine
- electronic data processing machine
- electroplating machine
- electrostatic stored-energy machine
- elevating beam boring machine
- elevating head milling machine
- elevating machine
- elevating rail machine
- elevator machine
- embossing machine
- encapsulating machine
- end preparation machine
- end-finishing machine
- end-finishing-centering machine
- end-grinding machine
- ending-and-centering machine
- end-turning machine
- endurance testing machine for repeated torsion
- endurance testing machine
- end-working machine
- energy machine
- energy transforming machine
- energy-intensive machine
- engraving form duplicating machine
- engraving machine
- engraving-type form duplicating machine
- Erichsen cupping machine
- Erichsen ductility machine
- eroding machine
- erosion machine
- etch machine
- etching machine
- exhibited machine
- expanding machine
- explosive force molding machine
- extended-travel machine
- extension machine
- external angular plunge grinding machine
- external broaching machine
- external cylindrical centerless grinding machine
- external grinding machine
- external honing machine
- extracting machine
- extruding machine
- extrusion machine
- face-grinding machine
- face-milling machine
- facing machine
- facing-and-centering machine
- facsimile machine
- failed machine
- falling weight testing machine
- fastener tapping-and-orienting machine
- fatigue bending machine
- fatigue testing machine for alternating torsion
- fatigue testing machine
- fault detection machine
- fax machine
- feedback machine
- field-tested machine
- file-cutting machine
- file-testing machine
- filing machine
- filing-and-sawing machine
- filling machine
- fine boring machine
- fine countersinking machine
- fine-blanking machine
- finish boring machine
- finishing machine
- finite memory machine
- finite state machine
- first-off machine
- fir-tree broachinng machine
- fir-tree milling machine
- five-side machine
- five-sided machine
- fixed beam machine
- fixed bed milling machine
- fixed bed-type milling machine
- fixed cycle machine
- fixed machine
- fixed post machine
- fixed sequence machine
- fixed weighing machine
- fixed-column machine
- fixed-table machine
- flame-cutting machine
- flame-profiling machine
- flanging machine
- flash butt-welding machine
- flat die thread-rolling machine
- flattening machine
- flexible assembly machine
- flexible machine
- flexible shaft filing machine
- flexible transfer machine
- flexing machine
- floor charging machine
- floor horizontal boring machine
- floor machine
- floor-type horizontal boring machine
- floor-type machine
- floor-type stripper machine
- flotation machine
- Floturn machine
- flowturning machine
- FLS machine
- fluid-actuated machine
- fluid-feed machine
- flute-grinding machine
- flute-milling machine
- fluting machine
- flying cutoff machine
- FM machine
- FMS machine
- FMS-capable machine
- foil butt-seam welding machine
- folding machine
- foot-operated welding machine
- forge rolling machine
- forging machine
- form cutter milling machine
- form-duplicating machine
- form-grinding machine
- forming machine
- form-milling machine
- form-testing machine
- foundry machine
- four-ball machine
- four-pallet machine
- four-roll bending machine
- four-roll forming machine
- four-roll sheet bending machine
- four-strand continuous casting machine
- friction disk sawing machine
- front-loading turning machine
- front-operated turning machine
- full-automatic turret screw machine
- furnace hoisting machine
- furnace-threading machine
- fusion cutting-off machine
- gaging machine
- gag-straightening machine
- galvanizing machine
- gang drilling machine
- gang slitting machine
- ganghead replaceable-type machine
- gangspindle drilling machine
- gang-tooled machine
- gang-type drilling machine
- gantry cutting machine
- gantry-loaded machine
- gantry-type machine
- gantry-type milling machine
- gantry-type plano-milling machine
- gas-cutting machine
- gear cutter grinding machine
- gear fine processing machine
- gear grinding and polishing machine
- gear lapping and polishing machine
- gear machine
- gear profile grinding machine
- gear tooth chamfering machine
- gear tooth grinding machine
- gear tooth inspection machine
- gear tooth rounding machine
- gear-burnishing machine
- gear-chamfering machine
- gear-checking machine
- gear-cutting machine
- gear-deburring machine
- geared head machine
- gear-finishing machine
- gear-grinding machine
- gear-hardening machine
- gear-hobbing machine for spur gears
- gear-hobbing machine
- gear-honing machine
- gear-lapping machine
- gear-making machine
- gear-manufacturing machine
- gear-measuring machine
- gear-milling machine
- gear-polishing machine
- gear-producing machine
- gear-rolling machine
- gear-shaping machine
- gear-shaving machine
- gear-sizing machine
- gear-testing machine
- general-purpose flat surface broaching machine
- general-purpose machine
- generating machine
- gilding machine
- gimbals head rolling machine
- gold rolling machine
- grading machine
- grinder-milling machine
- grinding machine for drill bits
- grinding machine with rotating column
- grinding machine
- grinding-and-lapping machine
- grinding-and-polishing machine
- grooving machine
- G-Tech machine
- Guillotine knife grinding machine for long knives
- Guillotine knife grinding machine
- gun-boring machine
- gun-drill machine
- gun-drilling machine
- gun-rifling machine
- gun-welding machine
- hacksawing machine
- half-NC machine
- hammer impact machine
- hammering machine
- hand-driven cutting machine
- hand-fed machine
- hand-held machine
- hand-load machine
- hand-milling machine
- hand-operated molding machine
- hand-operated press-molding machine
- hand-operated squeezing machine
- hard bearing balancing machine
- hard X-ray machine
- hardening machine
- hardness-testing machine
- hardwired NC machine
- Hazellet continuous strip casting machine
- head-changer machine
- head-changing machine
- heading machine
- headstock moving-type automatic screw machine
- head-to-head machines
- heating machine
- heavy machine
- heavy-duty machine
- heavy-hogging machine
- hexapod machine
- high-accuracy machine
- high-energy-rate forging machine
- high-energy-rate machine
- high-frequency ac welding machine
- high-frequency hardening machine
- highly accurate machine
- highly productive machine
- high-performance machine
- high-precision machine
- high-production machine
- high-productivity machine
- high-specification machine
- high-speed drafting machine
- high-speed machine
- high-speed spindle machine
- high-technology machine
- high-temperature fatigue testing machine
- high-velocity ram machine
- high-volume machine
- hinged roll-over machine
- hitch-feed cut-off machine
- HNC machine
- hob back-off machine
- hob tooth profile grinding machine
- hobbing machine
- hob-grinding machine
- hob-sharpening machine
- hoisting machine
- hole milling-and-reaming machine
- hole-making machine
- hole-punching machine
- hone machine
- honing machine
- honing-and-lapping machine
- horizontal arm measuring machine
- horizontal band machine
- horizontal bar machine
- horizontal boring machine
- horizontal broaching machine
- horizontal casting machine
- horizontal continuous broaching machine
- horizontal continuous drilling machine
- horizontal forging machine
- horizontal indexing machine
- horizontal internal broaching machine
- horizontal machine
- horizontal milling machine
- horizontal plate-bending machine
- horizontal punching machine
- horizontal ram machine
- horizontal shaping machine
- horizontal slotting machine
- horizontal spindle surface grinding machine
- horizontal square T-planer type milling machine
- horizontal-type machine
- horizontal-vertical milling machine
- hose-type sandblast tank machine
- host machine
- hot plate straightening machine
- hot-box core-making machine
- hot-chamber die-casting machine
- hot-heading machine
- hot-metal sawing machine
- hsc machine
- hybrid machine
- hydraulic axis machine
- hydraulic balancing machine
- hydraulic bloom shearing machine
- hydraulic core knockout machine
- hydraulic machine
- hydraulic molding machine
- hydraulic pipe testing machine
- hydraulic riveting machine
- hydraulic shearing machine
- hydraulic squeeze machine
- hydraulically-assisted machine
- hydraulically-driven machine
- hydraulically-powered machine
- hydraulic-assisted machine
- hydraulic-driven machine
- hydraulic-electric machine
- hydraulic-powered machine
- hydro-copying machine
- hydrostatic machine
- hydrostatic-extrusion machine
- imitation machine
- impact machine
- impact pendulum-type testing machine
- impact tension machine
- impact-test machine
- impact-testing machine
- impulse-cutting machine
- impulse-forming machine
- impulsive machine
- inclined tapping machine
- indentation machine
- index machine
- index milling machine
- indexer machine
- indexing chuck machine
- indexing drum milling machine
- indexing head machine
- indexing machine
- indexing turret machine
- induction hardening machine
- induction softening machine
- industrial machine
- informational machine
- ingot stripper machine
- ingot-planing machine
- ingot-scalping machine
- ingot-slicing machine
- injection-molding machine
- in-line machine
- in-line synchronous machine
- in-line transfer machine
- innovative machine
- inspection and measuring machine
- inspection machine
- integrated turning/milling machine
- intelligent machine
- intermittently manned machine
- internal broaching machine
- internal grinding machine
- internal grooving machine
- internal keyseating machine
- internal lapping machine
- internal planetary-type grinding machine
- internal thread grinding machine
- internal-and-external broaching machine
- internal-external inspection machine
- internal-part-transfer vertical broaching machine
- inverted vertical turning machine
- involute profile measuring machine
- ion beam machine
- iron shearing machine
- jar molding machine
- jar ramming machine
- jar ramming roll-over molding machine
- jarring machine
- jig milling machine
- jig-borer-class machine
- jig-boring machine
- jig-drilling machine
- jig-grinding machine
- jigless machine
- job-dedicated machine
- joggling machine
- jointed arm drilling machine
- jolt core-making machine
- jolt molding machine
- jolt pattern-draw molding machine
- jolt roll-over pattern-draw molding machine
- jolt squeeze molding machine
- journal-milling machine
- journal-turning machine
- Kenyon machine
- key machine
- key-and-slot milling machine
- key-bitting machine
- key-cutting machine
- key-duplicating machine
- keyseating and slot milling machine
- keyseating machine
- keyseating milling machine
- keyway-cutting machine
- keyway-milling machine
- keyway-seating machine
- keyway-slotting machine
- kneading machine
- knee-and-column machine
- knee-and-column milling machine
- knee-and-column-type milling machine
- kneeless-type milling machine
- knee-type machine
- knee-type milling machine
- knife-grinding machine
- knitting machine
- knurling machine
- labeling machine
- lamination segments blanking machine
- lapping and polishing machine
- lapping machine
- large-dimensioned machine
- large-scale machine
- large-size machine
- laser beam cutting machine
- laser beam machine
- laser die-sinking machine
- laser etch machine
- laser etching machine
- laser-assisted machine
- laser-controlled machine
- laser-cutting machine
- laser-hardening machine
- laser-scribing machine
- lathe machine
- laying-out machine
- lay-out machine
- lead screw tapping machine
- lead screw testing machine
- leakage-testing machine
- lens-grinding machine
- letter and paper cup machine
- leveling machine
- lever punching machine
- lever testing machine
- leverage proportioned tracing milling machine
- lever-type Brinell machine
- lifting machine
- light machine
- light production machine
- light-duty machine
- lightly manned machine
- light-weight machine
- limited-interference machine
- linear path-controlled machine
- linear station machine
- line-boring machine
- line-controlled machine
- live spindle machine
- lock-seaming machine
- long travel machine
- long-feed cut-off machine
- longitudinal circular cold sawing machine
- longitudinal dividing machine
- longitudinal grinding machine
- longitudinal seam-welding machine
- long-lasting machine
- long-running machine
- long-stroke broaching machine
- long-stroke machine
- long-term strength testing machine
- low-pressure die-casting machine
- machine of compact construction
- machine of dieing design
- machine of the state of the art
- machining machine
- magazine bar feed machine
- magnetic cobbing machine
- magnetic force welding machine
- magnetic forming machine
- maintenance-free machine
- manual machine
- manual-CNC machine
- manual-CNC turning machine
- manually controlled machine
- manually jogged machine
- manually tended machine
- manual-toolchange machine
- manufacturing bed-type milling machine
- manufacturing machine
- manufacturing milling machine
- manufacturing-oriented machine
- manufacturing-type machine
- marking machine
- marking-off machine
- marking-out machine
- mass centering machine
- mass-production machine
- master machine
- match-plate molding machine
- material testing machine
- material-cutting machine
- MDI-controlled machine
- measurement machine
- measuring machine
- mechanical drive machine
- mechanically driven machine
- medium duty machine
- medium travel machine
- mesh-welding machine
- metal slitting machine
- metal testing machine
- metal-cutting machine
- metal-folding machine
- metal-forming machine
- metal-planing machine
- metal-removing machine
- metal-sawing machine
- metal-working machine
- metamorphic machine
- metrology machine
- microcomputer-based NC machine
- microdrilling machine
- microfinishing machine
- micromilling machine
- microscopic drilling machine
- mill/turn machine
- mill-drill-bore machine
- milling cutter grinding machine
- milling machine with table of fixed height and with vertical spindle
- milling machine with table of variable height and with horizontal spindle
- milling machine with table of variable height
- milling machine
- milling/drilling machine
- milling/turning machine
- milling-and-boring machine
- milling-and-centering machine
- minicomputer-controlled machine
- minicoordinate boring machine
- minicoordinate drilling machine
- miter saw machine
- miter-cutting machine
- mitering saw machine
- mixing machine
- mobile gantry-type machine
- mobile weighing machine
- mock-up machine
- model engineers milling machine
- modular industrial machine
- modular machine
- modular-type machine
- molding machine
- mortising machine
- motor-driven welding machine
- movable bridge machine
- movable column machine
- movable saddle machine
- moving bridge machine
- moving column/fixed table machine
- moving machine
- moving table machine
- multiaxis machine
- multidie machine
- multidisciplinary machine
- multidrilling machine
- multifunction machine
- multihead automatic arc-welding machine
- multihead changer machine
- multihead machine
- multihead milling machine
- multiloaded machine
- multioperation machine
- multioperational machine
- multipallet machine
- multiple machines
- multiple secondary-operation machine
- multiple second-operation machine
- multiple-beam flame planing machine
- multiple-blowpipe machine
- multiple-broach broaching machine
- multiple-burner machine
- multiple-diameter grinding machine
- multiple-diameter turning machine
- multiple-head broaching machine
- multiple-head drilling machine
- multiple-operation machine
- multiple-purpose machine
- multiple-roll machine
- multiple-spindle automatic machine
- multiple-spindle bar machine
- multiple-spindle machine
- multiple-spot welding machine
- multiple-station machine
- multiple-station transfer machine
- multiple-table milling machine
- multiple-torch machine
- multiple-transformer machine
- multiple-transformer spot-welding machine
- multiproduct machine
- multipurpose broaching machine
- multipurpose shearing machine
- multireduction wire-drawing machine
- multiroll bar straightening machine
- multiroller machine
- multisensor coordinate machine
- multispecimen testing machine
- multispindle automatic screw machine
- multispindle bar machine
- multispindle head machine
- multispindle head-changing machine
- multispindle screw machine
- multispot machine
- multistation indexing transfer machine
- multistation machine
- multisurface machine
- multitool turning machine
- multiunit drilling machine
- multiuniversal machine
- multiway drilling machine
- nail-making machine
- narrow belt sanding machine
- NC machine
- needle die grinding machine
- needle die polishing machine
- nibbling machine
- nibbling, milling and punching machine
- nipple-threading machine
- No.40-taper-tool machine
- No.50-taper machine
- noncantilevered machine
- nonferrous sawing machine
- non-NC machine
- nonstock machine
- nonsystem machine
- normal accuracy machine
- normal manned NC machine
- notching machine
- numbering machine
- nut-castellating machine
- nut-chamfering machine
- nut-deburring machine
- nut-facing machine
- nut-making machine
- nut-running machine
- nut-setting machine
- nut-shaping machine
- nut-tapping machine
- nut-threading machine
- OD grinding machine
- OD machine
- off-line machine
- offset milling machine
- off-site machine
- oil hydraulic machine
- oil roll machine
- oil-grooving machine
- oiling machine
- omnimil versatile machine
- one-axis machine
- one-head automatic arc-welding machine
- one-hit machine
- one-meter machine
- one-off machine
- one-operator machine
- on-line machine
- open-side milling machine
- open-side planing machine
- open-side plano-milling machine
- open-sided milling machine
- operator-independent machine
- operator-initiated machine
- operator-positionable machine
- operator-programmed machine
- opposed spindle machine
- optical jig boring machine
- optical pattern tracing machine
- optical profile grinding machine
- optical reading machine
- original equipment CNC machine
- orthodox machine
- orthogonally movable machine
- oscillating bandsaw machine
- other machines
- outfacing machine
- outmoded machine
- out-of-alignment machine
- overdesigned machine
- overhead gantry machine
- overhead grinding machine
- overhead recessing machine
- overhead traveling drilling machine
- overwrapping machine
- own-use machine
- oxyacetylene-cutting machine
- oxyfuel burn machine
- packaging machine
- pack-checking machine
- packing machine
- paddle blade-type mixing machine
- paint machine
- pallet pool machine
- pallet shuttle machine
- pallet transfer machine
- pallet-change machine
- palletized machine
- pallet-loading machine
- pallet-type transfer machine
- pantograph-engraving machine
- pantographic engraving machine
- pantograph-type milling machine
- paper-cutting machine
- parting machine
- part-transfer vertical broaching machine
- pattern draw machine
- pattern milling machine
- pattern-controlled machine
- pattern-tracing machine
- PCB machine
- PCB-drilling machine
- PC-equipped machine
- PC-governed machine
- pedal-operated welding machine
- pedal-triggered machine
- pedestal spot-welding machine
- pedestal-drilling machine
- pedestal-grinding machine
- peeling machine
- peening machine
- pendant controlled machine
- pendulum impact testing machine
- percussion-welding machine
- perforating machine
- periodic machine
- physico-chemical machine
- pick-and-place machine
- pickling machine
- piercing machine
- pig casting machine
- pillar-drilling machine
- pilot machine
- pincer spot-welding machine
- pinion-generating machine
- pin-lift molding machine
- pin-making machine
- pin-on-disk wear test machine
- pipe cut-off machine
- pipe-bending machine
- pipe-beveling machine
- pipe-beveling/cutting machine
- pipe-chamfering machine
- pipe-cropping machine
- pipe-crushing machine
- pipe-cutting machine
- pipe-expanding machine
- pipe-facing machine
- pipe-flanging machine
- pipe-flaring machine
- pipe-swabbing machine
- pipe-testing machine
- pipe-threading machine
- pipe-welding machine
- piston contouring machine
- piston ring grinding machine
- piston-turning machine
- pit planing machine
- pit-based broaching machine
- pit-type planing machine
- pivot-head machine
- placing machine
- plain grinding machine
- plain horizontal knee-type milling machine
- plain-way machine
- planer-type boring machine
- planer-type machine
- planer-type milling machine
- planer-type surface grinding machine
- planetary grinding machine
- planetary milling machine
- planetary-type thread milling machine
- planing machine
- planing-and-milling machine
- planomilling machine
- plano-type boring-and-milling machine
- plano-type surface grinding machine
- plasma arc machine
- plasma-cutting machine
- plastics extrusion machine
- plate-bending machine
- plate-cutting machine
- plate-edge beveling machine
- plate-edge planing machine
- plate-fabricating machine
- plate-flanging machine
- plate-flattening machine
- plate-leveling machine
- platen TL machine
- platen-tooled machine
- plate-punching machine
- plate-shearing machine
- plate-straightening machine
- plate-working machine
- platform weighing machine
- plating machine
- plier spot-welding machine
- plugboard/capstan machine
- plugboard-control machine
- plugboard-controlled machine
- plug-ramming machine
- plunge-grinding machine
- plunger core machine
- plunger-type pickling machine
- pneumatic hand machine
- pneumatic machine
- pneumatic molding machine
- pointing machine
- pointing rolling machine
- point-to-point NC machine
- polishing machine
- polygonal turning machine
- polyvalent machine
- portable facing machine
- portable machine
- portable milling machine
- portable valve grinding machine
- portal cutting machine
- portal machine
- portal-frame machine
- portal-type machine
- portal-type plano-milling machine with variable height cross rail
- position control machine
- positive-displacement hydraulic machine
- positive-displacement pneumatic machine
- pot-broach vertical broaching machine
- pot-broaching machine
- powder metal compacting machine
- power machine
- power-driven machine
- power-operated molding machine
- precision boring machine
- precision-controlled machine
- precision-drawing machine
- preparatory NC machine
- preset machine
- presetting machine
- press-molding machine
- press-type machine
- pressure die-casting machine
- press-welding machine
- primary turning machine
- printing machine
- prior art machine
- prior art-type machine
- prismatic coordinate inspection machine
- prismatic machine
- prismatic-type indexing machine
- process machines
- processing machine
- process-specialized machine
- production machine
- product-oriented machine
- profile measurement machine
- profile-cutting machine
- profile-grinding machine
- profile-iron bending machine
- profile-milling machine
- profiler machine
- profiling machine
- profiling milling machine
- program sequence controlled machine
- programmable machine
- programmable-controlled machine
- progressive broach machine
- projection form grinding machine
- projection welding machine
- prototype machine
- proving machine
- pull test machine
- pull-broaching machine
- pull-down broaching machine
- pulling-in machine
- pull-type broaching machine
- pull-type machine
- pull-up broaching machine
- punch machine
- punching and shearing machine
- punching machine
- purpose-built machine
- purpose-designed machine
- push-broaching machine
- push-cut shaping machine
- push-down broaching machine
- push-pull fatigue-testing machine
- push-up broaching machine
- qualifying machine
- quenching machine
- rack milling machine
- rack-and-pinion machine
- rack-and-pinion-operated machine
- radial arm-drilling machine
- radial arm-sawing machine
- radial articulated-arm cutting machine
- radial drilling machine
- radial-and-pillar drilling machine
- radiusing machine
- rail end milling machine
- rail-bending machine
- rail-cambering machine
- rail-drilling machine
- rail-straightening machine
- railway axle grinding machine
- ram impact machine
- ram milling machine
- ram-boring machine
- ram-head milling machine
- ramming molding machine
- ram-type boring and horizontal milling machine
- ram-type EDM machine
- ram-type milling machine
- ram-type tooling machine
- ratio cutting machine
- raw component measuring machine
- reading machine
- reaming machine
- reaming-and-facing machine
- recessing machine
- reciprocating cutoff machine
- reciprocating grinding machine
- reciprocating machine
- reciprocating-die machine
- reciprocating-table surface grinding machine
- recognizing machine
- recoiling machine
- rectifier-type welding machine
- redesigned machine
- reference machine
- refrigerating machine
- regrinding machine
- reinforcing bar bending machine
- reinforcing rod cropping machine
- relieving machine
- remote-control machine
- remote-controlled machine
- renewed machine
- repetitive milling machine
- replaceable gang head machine
- replacement machine
- reproducing pattern milling machine
- research-oriented machine
- resistance welding machine
- resonance-balancing machine
- resonant vibration machine
- resurfacing machine
- retapping machine
- reverse torsion fatigue testing machine
- reverse torsion machine
- rewinding machine
- rifling machine
- rigid production machine
- rigid-bed milling machine
- rigid-capable machine
- rise and fall tank machine
- rising blade machine
- rising table broaching machine
- rivet machine
- riveting machine
- robot machine
- robot-assisted machine
- robot-controlled machine
- robot-fed machine
- robotic machine
- robotically-fed machine
- robot-loaded machine
- robot-operated machine
- rock-crushing machine
- rocker-arm spot-welding machine
- rocker-type pickling machine
- Rockwell hardness machine
- Rockwell hardness-testing machine
- roll machine
- roll sheet bending machine
- roll-bending machine
- roll-end milling machine
- roller finishing machine
- roller profiling machine
- roller section-machinestraightening machine
- roller shape-machinestraightening machine
- roller spot-and-seam welding machine
- roller straightening machine
- roller-stretcher machine
- roll-fluting machine
- roll-forging machine
- roll-forming machine
- roll-grinding machine
- rolling dividing machine
- rolling machine
- rolling-and-bending machine
- rolling-on machine
- rolling-quench machine
- roll-over molding machine
- roll-over pattern-draw machine
- roll-seam welding machine
- roll-straightening machine
- roll-threading machine
- roll-turning machine
- rotary assembly machine
- rotary broaching machine
- rotary compression-type machine
- rotary continuous drum-type milling machine
- rotary continuous milling machine
- rotary dial machine
- rotary dial-index machine
- rotary disk filing machine
- rotary drum broaching machine
- rotary drum fixture milling machine
- rotary flame planing machine
- rotary head machine
- rotary indexing drum machine
- rotary indexing machine
- rotary indexing pallet machine
- rotary indexing table machine
- rotary knife cutting machine
- rotary machine
- rotary milling machine with horizontal workholder
- rotary pallet machine
- rotary planetary machine
- rotary planetary-die machine
- rotary stamping machine
- rotary surface grinding machine
- rotary table machine
- rotary tooled machine
- rotary transfer machine
- rotary welding machine
- rotary-drive machine
- rotary-driven machine
- rotary-table broaching machine
- rotary-table index machine
- rotary-table indexing machine
- rotary-table milling machine
- rotary-table surface grinding machine
- rotary-table transfer machine
- rotary-type milling machine
- rotating machine
- rotating-beam fatigue machine
- rotating-beam fatigue testing machine
- rotation machine
- rotor milling machine
- rotor slot milling machine
- rough boring machine
- rough facing machine
- rough grinding machine
- rough milling machine
- rough turning machine
- roughing machine
- round column drilling machine
- rounding machine
- roundness measuring machine
- routing milling machine
- RP machine
- rundown machine
- running balance indicating machine
- S/R machine
- saddle-type machine
- sample preparation machine
- sampling machine
- sandblast cleaning machine
- sandblast machine with stationary nozzle
- sandblast machine
- sandblast sprocket-table machine
- sand-throwing machine
- saw machine
- saw-brazing machine
- saw-cutting machine
- saw-grinding machine
- sawing machine
- saw-setting machine
- saw-sharpening machine
- saw-toothing machine
- scalping machine
- scissors-type horizontal band machine
- scissors-type horizontal machine
- scrap shearing machine
- scraping machine
- scratchbrush machine
- screening machine
- screw machine
- screw thread grinding machine
- screw thread milling machine
- screw thread rolling machine
- screw thread whirling machine
- screw-cutting machine
- screw-driving machine
- screw-head slotting machine
- screwing machine
- screw-nicking machine
- screw-shaving machine
- scribing machine
- scrubbing machine
- scrubbing-and-drying machine
- sculpturing machine
- seam-welding machine
- secondary machine
- second-operation machine
- section bending machine
- section shearing machine
- section-iron bending machine
- section-iron shearing machine
- section-straightening machine
- section-stretching machine
- segmented transfer machine
- self-controlling machine
- self-correcting machine
- semiautomatic arc welding machine
- semiautomatic gas-cutting machine
- semiautomatic grinding machine
- semiautomatic machine
- semiautomatic welding machine
- semiproduction machine
- sensitive drilling machine
- sensitive tapping machine
- separately excited machine
- sequence-controlled machine
- sequential transfer machines
- series-produced machines
- servo indexer machine
- servo slide machine
- sets-of-parts operated machine
- shaft machine
- shape-cutting machine
- shaper machine
- shape-straightening machine
- shaping machine
- sharpening machine
- shaving cutter grinding machine
- shear machine
- shearing machine
- shear-speed machine
- sheet and plate bending machine
- sheet bending machine
- sheet metal bending machine
- sheet metal cutting machine
- sheet metal folding machine
- sheet metal leveling machine
- sheet metal shearing machine
- sheet metal stamping machine
- sheet metal working machine
- sheet straightening and polishing machine
- sheet working machine
- sheet-leveling machine
- sheet-straightening machine
- shell core blowing machine
- shell molding machine
- ship propeller milling machine
- shock-and-vibration machine
- shockless jolting machine
- shopfloor machine
- shopworn machine
- show machine
- shredding machine for wood wool production
- shredding machine
- side hole drilling machine
- side-milling machine
- side-planing machine
- sieving machine
- simple-to-operate automatic machine
- simple-to-operate machine
- simplex milling machine
- simplex multiple-spindle machine
- simulation machine
- simultaneous 5-axis machine
- single wheel lapping machine
- single-address machine
- single-axis machine
- single-blade sawing machine
- single-end boring machine
- single-end centering and end-facing machine
- single-end machine
- single-end tenoning machine
- single-ended boring machine
- single-ended machine
- single-function machine
- single-gantry machine
- single-head machine
- single-hitb machine
- single-operation transfer machine
- single-piece machine
- single-point cutting-off machine
- single-position metal forming machine
- single-purpose machine
- single-shift machine
- single-shifted machine
- single-slide bed-type machine
- single-spindle machine
- single-station machine
- single-task machine
- single-upright machine
- singlex machine
- sinking machine
- six-axis NC machine
- sizing machine
- skin-milling machine
- skiving machine
- slabbing machine
- slab-milling machine
- slant-carriage machine
- slant-slide machine
- slave machine
- slicing machine
- slideway-grinding machine
- sliding bush machine
- sliding head machine
- sliding head milling machine
- sliding head/fixed spindle machine
- sliding headstock bar machine
- sliding headstock machine
- slinger molding machine
- slitting machine
- slot and keyway milling machine
- slot-drilling machine
- slot-milling machine
- slotting machine
- small capacity machine
- small-chuck machine
- small-envelope machine
- small-footprint machine
- small-parts machine
- smooth planing machine
- snagging grinding machine
- soft bearing balancing machine
- software-controlled machine
- software-oriented machine
- soldering machine
- solid bed-type milling machine
- sorting machine
- spar milling machine
- spark erosion machine
- spark machine
- special design machine
- special unit machine
- special way-type machine
- specialist machine
- specialized machine
- special-purpose machine
- specialty machine
- speed reduction machine
- spherical grinding machine
- spindle turning machine
- spinning machine
- spiral drive planing machine
- spline cold rolling machine
- spline shaft grinding machine
- spline shaft hobbing machine
- spline-broaching machine
- spline-grinding machine
- spline-hobbing machine
- spline-milling machine
- splining machine
- spring end grinding machine
- spring forming machine
- spring manufacturing machine
- spring testing machine
- spring-coiling machine
- spring-making machine
- spring-winding machine
- spur-and-helical grinding machine
- square milling machine
- squeeze core-making machine
- squeeze molding machine
- squeezing machine
- squirrel cage balancing machine
- SR machine
- stack-routing machine
- stamping machine
- standalone machine
- standard configuration machine
- standard design machine
- standard machine
- standard-unit-type machine
- static balancing machine
- station-type machine
- storage retrieval machine
- straight line milling machine
- straightening machine
- strength testing machine
- stress-relieving machine
- stress-rupture testing machine
- stretch straightening machine
- strip leveling machine
- stud thread rolling machine
- studding machine
- subspindle turning machine
- subspindle-equipped turning machine
- subspindle-type machine
- super-accurate machine
- supercharged laser cutting machine
- superfinishing machine for centerless plunge-cut
- superfinishing machine for centerless throughfeed
- superfinishing machine
- surface and profile grinding machine
- surface-broaching machine
- surface-grinding machine with long table
- surface-grinding machine with two columns
- surface-grinding machine
- surface-milling machine
- surface-treatment machine
- swage machine
- swaging machine
- swing frame grinding machine
- Swiss bar machine
- Swiss screw machine
- Swiss sliding headstock machine
- Swiss-style sliding-headstock machine
- Swiss-style sliding-headstock-type machine
- Swiss-type cam automatic screw machine
- Swiss-type machine
- Swiss-type movable headstock automatic screw machine
- Swiss-type stationary headstock automatic screw machine
- swivel head milling machine
- swivel head slotting machine
- synchronous transfer machine
- synchronous-feed machine
- system machine
- system-ready machine
- systems-compatible machine
- tabletop machine
- table-type machine
- table-uo broaching machine
- tabulating machine
- tailored machine
- tandem table machine
- tap flute milling machine
- tap fluting machine
- tap-drill machine
- tape finishing machine
- tape machine
- tape preparation machine
- tape-controlled machine
- tape-handling machine
- taper strip milling machine
- tap-grinding machine
- tapping machine
- tap-sharpening machine
- targeted machine
- teaching machine
- TEM machine
- template-controlled machine
- tenoning machine
- tensile strength testing machine
- tensile testing machine
- tension testing machine
- test machine
- test sieving machine
- testing machine
- texturing machine
- thermal cutting machine
- thermal deburrting machine
- thermally symmetric machine
- thermally symmetrical machine
- thermoelectric machine
- thread chaser grinding machine
- thread-cutting machine
- threaded wheel grinding machine
- thread-generating machine
- thread-grinding machine
- threading machine
- thread-milling machine
- thread-producing machine
- thread-rolling machine with roller and segmented die
- thread-rolling machine
- thread-tapping machine
- thread-turning machine
- thread-whirling machine
- three-axis checking machine
- three-axis digital read-out inspection machine
- three-axis NC machine
- three-axis-controlled machine
- three-dimensional forming machine
- three-dimensional NC machine
- three-dimensional profiling machine
- three-roll bending machine
- three-roll forming machine
- three-roll sheet bending machine
- three-shift machine
- three-shifted machine
- three-way machine
- tiering machine
- tilt frame machine
- tilting body slotting machine
- tilting column machine
- tilting spindle grinding machine
- tilting spindle machine
- time-tested machine
- TL machine
- TNC-milling machine
- tool and diemaker's milling machine
- tool changer machine
- tool presetting and inspection machine
- tool presetting machine
- tool-and-cutter grinding machine
- tool-grinding machine
- toolroom machine
- toolroom-milling machine
- tool-setting machine
- tooth generating machine
- tooth rounding-and-chamfering machine
- top-of-the-line machine
- torsion testing machine
- totally automated machine
- totally enclosed machine
- touch-trigger machine
- T-planer type machine
- tracer controlled machine
- tracer milling machine
- tracer-controlled electrical discharge profiling machine
- tracer-controlled milling machine
- tracer-guided machine
- tracer-guided milling machine
- tracing machine
- transfer-line-ready machine
- transfer-segmented machine
- transfer-type machine
- transport machine
- transverse planing machine
- traveling bar-type boring machine
- traveling bridge-type plano-milling machine
- traveling column machine
- traveling column-type machine
- traveling gantry machine
- traveling head shaping machine
- traveling portal milling machine
- traveling table machine
- traveling table-type machine
- traveling wire electrical discharge machine
- traveling-head boring machine
- traveling-head surface grinding machine
- traverse grinding machine
- traversing head shaping machine
- trimming machine
- trip dog-controlled machine
- triplex milling machine
- trunnion machine
- trunnion-style machine
- trunnion-type machine
- T-slot milling machine
- tube cutoff machine
- tube grinding-and-polishing machine
- tube-bending machine
- tube-boring machine
- tube-chamfering machine
- tube-drawing machine
- tube-enlarging machine
- tube-forming machine
- tube-sawing machine
- tube-straightening machine
- tube-welding machine
- tumbling machine
- turbine shot-blasting machine
- turbine slot milling machine
- turn/mill machine
- turn, bore and cut-off machine
- turn-broaching machine
- turning machine
- turning, milling and boring machine
- turning-and-boring machine
- turn-mill machine
- turn-peeling machine
- turret hole punching machine
- turret machine
- turret press machine
- turret ram milling machine
- turret screw machine
- turret-chucking machine
- turret-drilling machine
- turret-milling machine
- turret-punching machine
- turret-type drilling machine
- twin pallet machine
- twin screw knee-type machine
- twin six-station turret machine
- twin-head machine
- twin-head shaping machine
- twin-opposed spindle turning machine
- twin-overarm milling machine
- twin-spindle machine
- twin-turret machine
- twist drill flute grinding machine
- twist drill fluting machine
- twist drill grinding machine
- twist drill milling machine
- twist drill point grinding machine
- twist test machine
- two-address machine
- two-axis NC machine
- two-axis-controlled machine
- two-dimensional engraving machine
- two-plane balancing machine
- two-roll sheet bending machine
- two-shift machine
- two-shifted machine
- two-tool machine
- two-way broaching machine
- two-way drilling machine
- two-way machine
- tybe-reducing machine
- typical machine
- ultra precision machine
- ultra-high precision machine
- ultra-high speed machine
- ultrasonic cleaning and degreasing machine
- ultrasonic cleaning machine
- ultrasonic copy-piercing machine
- ultrasonic drilling machine
- ultrasonic hole-contouring machine
- undedicated machine
- underdesigned machine
- underutilized machine
- unit construction machine
- unit-built machine
- unit-changeable machine
- unit-type machine
- universal boring machine
- universal cutter and tool grinding machine
- universal head milling machine
- universal horizontal milling machine
- universal knee-type milling machine
- universal milling machine
- universal rotaty table grinding machine
- universal table grinding machine
- universal testing machine
- universal tool and die milling machine
- universal tool milling and boring machine
- universal toolroom milling machine
- universal-spindle machine
- unmanned machine
- unmanned measuring machine
- unmanned turning machine
- upgradable machine
- uprated machine
- upright boring machine
- upright drilling machine
- upright drilling-and-boring machine
- upsetting machine
- used machine
- user-friendly machine
- utrasonic lapping machine
- valve seat lapping machine
- valve seat milling machine
- vehicle-mounted machine
- vending machine
- veneer slicing machine
- versatile machine
- vertical arm measuring machine
- vertical band machine
- vertical band-saw machine
- vertical band-sawing machine
- vertical bed machine
- vertical boring machine
- vertical broaching machine
- vertical chucking machine
- vertical double-ram broaching machine
- vertical double-slide broaching machine
- vertical drilling machine
- vertical machine
- vertical milling machine
- vertical planing machine
- vertical plano-milling machine
- vertical pull-up broaching machine
- vertical push-broaching machine
- vertical ram machine
- vertical slotting machine
- vertical spindle surface-grinding machine
- vertical turning machine
- vertical turning-and-boring machine
- vertical/horizontal machine
- vertically oriented drilling machine
- vertical-type machine
- vibration fatigue testing machine
- vibration machine
- vibratory finishing machine
- vibrofinishing machine
- Vickers hardness machine
- Vickers pyramid hardness machine
- vision-controlled machine
- volume production machine
- walking machine
- wall machine
- washing drying machine
- washing machine
- watch-case making machine
- watch-gear hobbing machine
- watch-gear making machine
- water jet cutting machine
- water-jet machine
- way-type machine
- way-type unit head machine
- weathering machine
- weighing machine
- welding machine
- well-developed machine
- wet-cutting machine
- wet-grinding machine
- wheel turning machine
- whirling machine
- wide belt sending machine
- wire bonding machine
- wire brush deburring machine
- wire coiling and winding machine
- wire cutting-off machine
- wire drawing machine
- wire EDM machine
- wire erosion machine
- wire netting and weaving machine
- wire-cut EDM machine
- wire-cut electrical discharge machine
- wire-cut machine
- wire-cutting machine
- wire-cutting spark erosion machine
- wire-eroding machine
- wire-forming machine
- wire-making machine
- wire-polishing machine
- wire-straightening machine
- woodsawing machine
- woodworking machine
- workpiece moving-type machine
- worm grinding machine
- worm milling machine
- wrist-pin boring machine
- xerox machine
- X-ray machineEnglish-Russian dictionary of mechanical engineering and automation > machine
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109 Fox, Sir Charles
[br]b. 11 March 1810 Derby, Englandd. 14 June 1874 Blackheath, London, England[br]English railway engineer, builder of Crystal Palace, London.[br]Fox was a pupil of John Ericsson, helped to build the locomotive Novelty, and drove it at the Rainhill Trials in 1829. He became a driver on the Liverpool \& Manchester Railway and then a pupil of Robert Stephenson, who appointed him an assistant engineer for construction of the southern part of the London \& Birmingham Railway, opened in 1837. He was probably responsible for the design of the early bow-string girder bridge which carried the railway over the Regent's Canal. He also invented turnouts with switch blades, i.e. "points". With Robert Stephenson he designed the light iron train sheds at Euston Station, a type of roof that was subsequently much used elsewhere. He then became a partner in Fox, Henderson \& Co., railway contractors and manufacturers of railway equipment and bridges. The firm built the Crystal Palace in London for the Great Exhibition of 1851: Fox did much of the detail design work personally and was subsequently knighted. It also built many station roofs, including that at Paddington. From 1857 Fox was in practice in London as a consulting engineer in partnership with his sons, Charles Douglas Fox and Francis Fox. Sir Charles Fox became an advocate of light and narrow-gauge railways, although he was opposed to break-of-gauge unless it was unavoidable. He was joint Engineer for the Indian Tramway Company, building the first narrow-gauge (3 ft 6 in. or 107 cm) railway in India, opened in 1865, and his firm was Consulting Engineer for the first railways in Queensland, Australia, built to the same gauge at the same period on recommendation of Government Engineer A.C.Fitzgibbon.[br]Principal Honours and DistinctionsKnighted 1851.Further ReadingObituary, 1875, Minutes of Proceedings of the Institution of Civil Engineers 39:264.F.Fox, 1904, River, Road, and Rail, John Murray, Ch. 1 (personal reminiscences by his son).L.T.C.Rolt, 1970, Victorian Engineering, London: Allen Lane.PJGR -
110 Lartigue, Charles François Marie-Thérèse
[br]b. 1834 Toulouse, France d. 1907[br]French engineer and businessman, inventor of the Lartigue monorail.[br]Lartigue worked as a civil engineer in Algeria and while there invented a simple monorail for industrial or agricultural use. It comprised a single rail carried on trestles; vehicles comprised a single wheel with two tubs suspended either side, like panniers. These were pushed or pulled by hand or, occasionally, hauled by mule. Such lines were used in Algerian esparto-grass plantations.In 1882 he patented a monorail system based on this arrangement, with important improvements: traction was to be mechanical; vehicles were to have two or four wheels and to be able to be coupled together; and the trestles were to have, on each side, a light guide rail upon which horizontal rollers beneath the vehicles would bear. Early in 1883 the Lartigue Railway Construction Company was formed in London and two experimental prototype monorails were subsequently demonstrated in public. One, at the Paris Agricultural Exhibition, had an electric locomotive that was built in two parts, one either side of the rail to maintain balance, hauling small wagons. The other prototype, in London, had a small, steam locomotive with two vertical boilers and was designed by Anatole Mallet. By now Lartigue had become associated with F.B. Behr. Behr was Managing Director of the construction company and of the Listowel \& Ballybunion Railway Company, which obtained an Act of Parliament in 1886 to built a Lartigue monorail railway in the South West of Ireland between those two places. Its further development and successful operation are described in the article on Behr in this volume.A much less successful attempt to establish a Lartigue monorail railway took place in France, in the départment of Loire. In 1888 the council of the département agreed to a proposal put forward by Lartigue for a 10 1/2 mile (17 km) long monorail between the towns of Feurs and Panissières: the agreement was reached on the casting vote of the Chairman, a contact of Lartigue. A concession was granted to successive companies with which Lartigue was closely involved, but construction of the line was attended by muddle, delay and perhaps fraud, although it was completed sufficiently for trial trains to operate. The locomotive had two horizontal boilers, one either side of the track. But the inspectors of the department found deficiencies in the completeness and probable safety of the railway; when they did eventually agree to opening on a limited scale, the company claimed to have insufficient funds to do so unless monies owed by the department were paid. In the end the concession was forfeited and the line dismantled. More successful was an electrically operated Lartigue mineral line built at mines in the eastern Pyrenees.It appears to have reused equipment from the electric demonstration line, with modifications, and included gradients as steep as 1 in 12. There was no generating station: descending trains generated the electricity to power ascending ones. This line is said to have operated for at least two years.[br]Bibliography1882, French patent no. 149,301 (monorail system). 1882, British patent no. 2,764 (monorail system).Further ReadingD.G.Tucker, 1984, "F.B.Behr's development of the Lartigue monorail", Transactions of the Newcomen Society 55 (describes Lartigue and his work).P.H.Chauffort and J.-L.Largier, 1981, "Le monorail de Feurs à Panissières", Chemin defer régionaux et urbains (magazine of the Fédération des Amis des Chemins de FerSecondaires) 164 (in French; describes Lartigue and his work).PJGRBiographical history of technology > Lartigue, Charles François Marie-Thérèse
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111 Lawrence, Richard Smith
SUBJECT AREA: Weapons and armour[br]b. 22 November 1817 Chester, Vermont, USAd. 10 March 1892 Hartford, Connecticut, USA[br]American gunsmith and inventor.[br]Richard S.Lawrence received only an elementary education and as a young man worked on local farms and later in a woodworking shop. His work there included making carpenters' and joiners' tools and he spent some of his spare time in a local gunsmith's shop. After a brief period of service in the Army, he obtained employment in 1838 with N.Kendall \& Co. of Windsor, Vermont, making guns at the Windsor prison. Within six months he was put in charge of the work, continuing in this position until 1842 when the gun-making ceased; he remained at the prison for a time in charge of the carriage shop. In 1843 he opened a gun shop in Windsor in partnership with Kendall, and the next year S.E. Robbins, a businessman, helped them obtain a contract from the Federal Government for 10,000 rifles. A new company, Robbins, Kendall \& Lawrence, was formed and a factory was built at Windsor. Three years later Kendall's share of the business was purchased by his partners and the firm became Robbins \& Lawrence. Lawrence supervised the design and production and, to improve methods of manufacture, developed new machine tools with the aid of F.W. Howe. In 1850 Lawrence introduced the lubrication of bullets, which practice ensured the success of the breech-loading rifle. Also in 1850, the company undertook to manufacture railway cars, but this involved them in a considerable financial loss. The company took to the Great Exhibition of 1851 in London, England, a set of rifles built on the interchangeable system. The interest this created resulted in a visit of some members of the British Royal Small Arms Commission to America and subsequently an order for 150 machine tools, jigs and fixtures from Robbins \& Lawrence, to be installed at the small-arms factory at Enfield. In 1852 the company contracted to manufacture Sharps rifles and carbines at a new factory to be built at Hartford, Connecticut. Lawrence moved to Hartford in 1853 to superintend the building and equipment of the plant. Shortly afterwards, however, a promised order for a large number of rifles failed to materialize and, following its earlier financial difficulties, Robbins \& Lawrence was forced into bankruptcy. The Hartford plant was acquired by the Sharps Rifle Company in 1856 and Lawrence remained there as Superintendent until 1872. From then he was for many years Superintendent of Streets in the city of Hartford and he also served on the Water Board, the Board of Aldermen and as Chairman of the Fire Board.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; repub. 1926, New York; and 1987, Bradley, Ill. (provides biographical information and includes in an Appendix (pp. 281–94) autobiographical notes written by Richard S.Lawrence in 1890).Merritt Roe Smith, 1974, "The American Precision Museum", Technology and Culture 15 (3): 413–37 (for information on Robbins \& Lawrence and products).RTSBiographical history of technology > Lawrence, Richard Smith
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112 Yarrow, Sir Alfred Fernandez
SUBJECT AREA: Ports and shipping[br]b. 13 January 1842 London, Englandd. 24 January 1932 London, England[br]English shipbuilder, naval architect, engineer and philanthropist.[br]At the conclusion of his schooling in the South of England, Yarrow became an indentured apprentice to the Thames engine-builder Ravenhill. During this five-year period various incidents and meetings sharpened his interest in scientific matters and he showed the skills that in later years were to be so beneficial to shipbuilding. For two years he acted as London representative for Ravenhill before joining up with a Mr Hedley to form a shipyard on the Isle of Dogs. The company lasted from 1868 until 1875 and in that period produced 350 small launches and other craft. This massive output enabled Yarrow to gain confidence in many aspects of ship design. Within two years of setting out on his own he built his first ship for the Royal Navy: a torpedo boat, then at the cutting edge of technology.In the early 1890s the company was building watertube boilers and producing destroyers with speeds in excess of 27 knots (50 km/h); it built the Russian destroyer Sokol, did pioneering work with aluminium and with high-tensile steels and worked on shipboard equipment to nullify vibrational effects. With the closure of most of the Thames shipyards and the run-down in skilled labour, Yarrow decided that the shipyard must move to some other part of the United Kingdom. After careful deliberation a green field site to the west of Glasgow was chosen, and in 1908 their first Clyde-built destroyer was launched. The company expanded, more building berths were arranged, boiler construction was developed and over the years they became recognized as specialists in smaller highspeed craft and in "knock down" ships for other parts of the world.Yarrow retired in 1913, but at the commencement of the First World War he returned to help the yard produce, in four years, twenty-nine destroyers with speeds of up to 40 knots (74 km/h). At the end of hostilities he gave of his time and money to many charities, including those for ex-servicemen. He left a remarkable industrial organization which remains to this day the most prolific builder of surface craft for the Royal Navy.[br]Principal Honours and DistinctionsCreated Baronet 1916. FRS 1922. Vice-President, Institution of Naval Architects 1896.Further ReadingLady Yarrow, 1924, Alfred Yarrow, His Life and Work, London: Edward Arnold. A.Borthwick, 1965, Yarrow and Company Limited, The First Hundred Years 1865–1965, Glasgow.B.Baxter, 1986, "Alfred Fernandez Yarrow", Dictionary of Scottish Business Biography, Vol. I, pp. 245–7, Slaven \& Checkland and Aberdeen University Press.FMWBiographical history of technology > Yarrow, Sir Alfred Fernandez
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113 area
1) площадь; пространство3) поверхность4) (производственный) участок; помещение; площадка5) рабочая ячейка ( склада)•equal in area — равновеликий;area of base — площадь основания, площадь подошвы фундаментаarea of bearing — 1. площадь опоры 2. строит. площадка опиранияarea of contact — площадь поверхности контактаarea of diagram — площадь эпюры; площадь графикаarea of fracture — 1. поверхность излома 2. площадь поперечного сечения в месте разрушенияarea of occurrence — возд. район происшествияarea of water section — гидр. площадь живого сечения потокаarea of well influence — зона влияния колодца или скважины-
absorption area
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active area
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actual contact area
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actuating area
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actuation probability area
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addressable area
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adjustment control area
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advisory area
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air intake hazard area
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aircraft parking area
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airflow separation area
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airport construction area
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airport prohibited area
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airport service area
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air-route area
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alighting area
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alloy storage area
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annulus area
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antenna effective area
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antenna area
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antinode area
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aperture area
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approach area
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ash-disposal area
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auditory area
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backwater area
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bare area
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base area
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bearing surface area
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binding area
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blade area
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blade-exit area
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blind area
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blind drainage area
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boarding area
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bolted area
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bonding area
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bond area
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bore area
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bubble-melt surface area
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buffer area
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building area
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built-up area
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burning area
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catalyst surface area
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catchment area
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caved area
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central equipment area
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centralized telecine area
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centralized traffic area
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centralized video tape area
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charge-makeup area
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charging area
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chip area
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choke-tube area
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circling approach area
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clean processing area
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clearance area
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climb-out area
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clinch area
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coal area
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coherence area
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cold area
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commanded area
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common area
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compression area
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concrete area
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cone effect area
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congested area
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connector area
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conservation area
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constant area
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contact area
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contact spot area
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contaminated area
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contamination control area
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contiguous area
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contour area of contact
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control area
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controlled access area
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cooling area
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corrosion area
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coverage area
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crimp area
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critical area
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cross-sectional area
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cross-section area
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cutting area
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cylinder annular area
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dangerous area
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data-rich area
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data-sparse area
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data-void area
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decontamination area
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demixing area
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design wing area
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developed area
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developed blade area
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development area
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die attach area
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diked area
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direct transit area
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discharge area
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display area
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disposal area
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dot area
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downstream area
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drainage area
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drainless area
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dry area
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dynamic area
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echoing area
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echo area
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effective area
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effective braking area
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effective cross-sectional area
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effective cross-section area
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effective screening area
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effects area
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electrical contact area
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electroded area
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elemental area
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enclosed working area
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end safety area
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engineering area
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environmentally fragile area
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exchange area
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exclusion area
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exhaust area
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expanded blade area
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expanded area
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exposure area
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face area
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fan blast area
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felling area
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fenced-off area
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fetch area
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fill area
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film-editing area
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filter effective area
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filter open area
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filtering area
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finished-products storage area
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fixed area
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flame area
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flooded area
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flood-free area
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flooding area
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floor area
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flow area
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focus area
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forbidden area
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free-surface area
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fringe area
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functional area
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furnace area
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fusing area
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fusion area
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gases shear area
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gasket surface area
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gassy area
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gathering area
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gob area
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graticule area
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gray-scale picture area
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gross cross-sectional area
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gross cross-section area
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gross irrigable area
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ground contact area
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gutter area
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hard-core area
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hard-to-reach area
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hearth area
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heat dissipation area
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heat-affected area
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heating area
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heat-transfer area
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high-activity area
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high-beat area
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high-radiation area
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holding area
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hot area
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housing area
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illuminated area
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image area
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impact area
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impression area
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inactive area
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ingot-stripping area
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input area
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instantaneous area of flame front
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instruction area
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intended landing area
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interfacial area
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interference area
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interlocking area
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inundated area
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junction area
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knuckle area
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land area
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landing area
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lateral area
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lift irrigation area
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lift-off area
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link overlapped area
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living area
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living floor area
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load-and-unload area
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load-carrying area
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loading area
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loadout area
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localized areas of wear
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low-radiation area
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makeup area
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maneuvering area
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man-impacted area
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manned area
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manual setting-up area
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melting area
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mesa area
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metropolitan area
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mining area
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mirror area
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mold conditioning area
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mold opening area
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moment area
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movement area
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mush area
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natural area
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net cross-sectional area
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net cross-section area
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neutron migration area
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nominal contact area
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noncontact area
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nonimage area
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nonmoving area
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nonoccupied area
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nonprinting area
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nonstorage area
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nonutilizable area
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normally occupied area
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nose area
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nuclear area
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numbering area
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obstructed landing area
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open area
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open flow area
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outgassed area
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output area
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overrun safety area
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pallet area
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patch area
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pattern area
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payable area
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percent shear area
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personnel and utility area
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phosphor area
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photolithographic area
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picture area
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poor-reception area
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port area
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presentation area
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pressing area
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prewarming area
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primary area
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primary service area
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printing area
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production area
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production control area
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programmed operating area
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prohibited area
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projectedblade area
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projected area
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propeller disk area
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protected area
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quality-control area
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quality area
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quench area
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quiet area
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radar area
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radiation-control area
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real area of contact
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recording area
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record area
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refining area
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regeneration area
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reinforcing steel area
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rerecording area
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reservoir surface area
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reservoir area
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residential area
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resident area
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residential floor area
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restricted area
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retarder area
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rig deck area
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risk area
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robot area
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roof contact area
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rubbing path area
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rudder area
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run-up area
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rural area
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safe operating area
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safety area
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sail area
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save area
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scanned area
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scrap-consuming area
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scrap-disposal area
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scrap-grading area
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scratch area
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screen area
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sealing area
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seal area
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search area
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secondary area
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sectional area
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section area
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seeking area
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segregated area
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service area
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serviceable area
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setting-up area
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shaded area
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shadow area
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shareable area
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shoe pad transition area
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shooting area
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sintering area
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site area
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skip area
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slag-line area
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slot area
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slowing-down area of neutron
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snow-covered area
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solid area
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sound area
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sound-track area
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special work permit area
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specific floor area
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specific surface area
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spliced area
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spoil area
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stack area
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stockline area
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stool conditioning area
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storage area
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stripped area
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subsidence area
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superheated area
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surface area
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switching area
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takeoff area
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takeoff flight path area
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tape area
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taphole area
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target area
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technical-equipment area
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technical area
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telecine area
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tension area
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terminal area
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terminal control area
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test area
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throat area
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tongs area of pipe
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tool service area
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tool-presetting area
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total area
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total irrigation area
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total tuyere area
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transient area
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turnaround area
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tuyere area
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type area
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unattacked area
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undershoot area
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ungaged area
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uniform area
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unobstructed landing area
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upstream area
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urban area
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usable area
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user area
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valve fillet area
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valve seating face area
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video tape recording area
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video tape area
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viewing area
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vision control area
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vulnerable area
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waste area
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waste-metal area
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waste-storage area
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water catchment area
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waterplane area
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water-surface area
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wear track area
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weld metal area
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well drainage area
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wellhead area
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wetted area
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wildlife area
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window area
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worked-out area
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working area
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yard area
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yoke area -
114 receiver
[rɪ'siːvə(r)]1) (telephone) ricevitore m., cornetta f.2) rad. telev. (equipment) apparecchio m. ricevente, ricevitore m.3) BE econ. dir. (anche Official Receiver) amministratore m. giudiziario, curatore m. fallimentare4) BE dir. ricettatore m.5) AE (in baseball)(wide) receiver — ricevitore, catcher
* * *1) (the part of a telephone which is held to one's ear.) ricevitore, cornetta2) (an apparatus for receiving radio or television signals.) ricevitore3) (a person who receives stolen goods.) ricettatore4) (a person who is appointed to take control of the business of someone who has gone bankrupt.) liquidatore5) (a stereo amplifier with a built-in radio.) apparecchio ricevente* * *receiver /rɪˈsi:və(r)/n.1 (telef.) ricevitore; cornetta: to pick up the receiver, alzare la cornetta; to put down the receiver, posare la cornetta3 (leg.. in GB; = receiver in bankruptcy, official receiver) curatore fallimentare (cfr. trustee, def. 2)6 (leg., USA) amministratore giudiziale ( nell'amministrazione controllata); ( anche) liquidatore ( di un'azienda)7 (chim.) recipiente di raccolta; serbatoio8 ( sport: tennis, pallavolo, ecc.) giocatore alla ricezione; chi risponde a un servizio; ( sport) the receiver of a pass, il giocatore che riceve la palla10 (ling.) ricevente; destinatario11 (fin.) tesoriere* * *[rɪ'siːvə(r)]1) (telephone) ricevitore m., cornetta f.2) rad. telev. (equipment) apparecchio m. ricevente, ricevitore m.3) BE econ. dir. (anche Official Receiver) amministratore m. giudiziario, curatore m. fallimentare4) BE dir. ricettatore m.5) AE (in baseball)(wide) receiver — ricevitore, catcher
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115 Barnack, Oskar
SUBJECT AREA: Photography, film and optics[br]b. 1879 Berlin, Germanyd. January 1936 Wetzlar, Germany[br]German camera designer who conceived the first Leica camera and many subsequent models.[br]Oskar Barnack was an optical engineer, introspective and in poor health, when in 1910 he was invited through the good offices of his friend the mechanical engineer Emil Mechau, who worked for Ernst Leitz, to join the company at Wetzlar to work on research into microscope design. He was engaged after a week's trial, and on 2 January 1911 he was put in charge of microscope research. He was an enthusiastic photographer, but excursions with his large and heavy plate camera equipment taxed his strength. In 1912, Mechau was working on a revolutionary film projector design and needed film to test it. Barnack suggested that it was not necessary to buy an expensive commercial machine— why not make one? Leitz agreed, and Barnack constructed a 35 mm movie camera, which he used to cover events in and around Wetzlar.The exposure problems he encountered with the variable sensitivity of the cine film led him to consider the design of a still camera in which short lengths of film could be tested before shooting—a kind of exposure-meter camera. Dissatisfied with the poor picture quality of his first model, which took the standard cine frame of 18×24 mm, he built a new model in which the frame size was doubled to 36×24 mm. It used a simple focal-plane shutter adjustable to 1/500 of a second, and a Zeiss Milar lens of 42 mm focal length. This is what is now known as the UR-Leica. Using his new camera, 1/250 of the weight of his plate equipment, Barnack made many photographs around Wetzlar, giving postcard-sized prints of good quality.Ernst Leitz Junior was lent the camera for his trip in June 1914 to America, where he was urged to put it into production. Visiting George Eastman in Rochester, Leitz passed on Barnack's requests for film of finer grain and better quality. The First World War put an end to the chances of developing the design at that time. As Germany emerged from the postwar chaos, Leitz Junior, then in charge of the firm, took Barnack off microscope work to design prototypes for a commercial model. Leitz's Chief Optician, Max Berek, designed a new lens, the f3.5 Elmax, for the new camera. They settled on the name Leica, and the first production models went on show at the Leipzig Spring Fair in 1925. By the end of the year, 1,000 cameras had been shipped, despite costing about two months' good wages.The Leica camera established 35 mm still photography as a practical proposition, and film manufacturers began to create the special fine-grain films that Barnack had longed for. He continued to improve the design, and a succession of new Leica models appeared with new features, such as interchangeable lenses, coupled range-finders, 250 exposures. By the time of his sudden death in 1936, Barnack's life's work had forever transformed the nature of photography.[br]Further ReadingJ.Borgé and G.Borgé, 1977, Prestige de la, photographie.BC -
116 Davis, Robert Henry
SUBJECT AREA: Ports and shipping[br]b. 6 June 1870 London, Englandd. 29 March 1965 Epsom, Surrey, England[br]English inventor of breathing, diving and escape apparatus.[br]Davis was the son of a detective with the City of London police. At the age of 11 he entered the employment of Siebe, Gorman \& Co., manufacturers of diving and other safety equipment since 1819, at their Lambeth works. By good fortune, his neat handwriting attracted the notice of Mr Gorman and he was transferred to work in the office. He studied hard after working hours and rose steadily in the firm. In his twenties he was promoted to Assistant Manager, then General Manager, Managing Director and finally Governing Director. He retired in 1960, having been made Life President the previous year, and continued to attend the office regularly until May 1964.Davis's entire career was devoted to research and development in the firm's special field. In 1906 he perfected the first practicable oxygen-breathing apparatus for use in mine rescue; it was widely adopted and with modifications was still in use in the 1990s. With Professor Leonard Hill he designed a deep-sea diving-bell incorporating a decompression chamber. He also invented an oxygen-breathing apparatus and heated apparel for airmen flying at high altitudes.Immediately after the first German gas attacks on the Western Front in April 1915, Davis devised a respirator, known as the stocking skene or veil mask. He quickly organized the mass manufacture of this device, roping in members of his family and placing the work in the homes of Lambeth: within 48 hours the first consignment was being sent off to France.He was a member of the Admiralty Deep Sea Diving Committee, which in 1933 completed tables for the safe ascent of divers with oxygen from a depth of 300 ft (91 m). They were compiled by Davis in conjunction with Professors J.B.S.Haldane and Leonard Hill and Captain G.C.Damant, the Royal Navy's leading diving expert. With revisions these tables have been used by the Navy ever since. Davis's best-known invention was first used in 1929: the Davis Submarine Escape Apparatus. It became standard equipment on submarines until it was replaced by the Built-in Breathing System, which the firm began manufacturing in 1951.The firm's works were bombed during the Second World War and were re-established at Chessington, Surrey. The extensive research facilities there were placed at the disposal of the Royal Navy and the Admiralty Experimental Diving Unit. Davis worked with Haldane and Hill on problems of the underwater physiology of working divers. A number of inventions issued from Chessington, such as the human torpedo, midget submarine and human minesweeper. In the early 1950s the firm helped to pioneer the use of underwater television to investigate the sinking of the submarine Affray and the crashed Comet jet airliners.[br]Principal Honours and DistinctionsKnighted 1932.BibliographyDavis was the author of several manuals on diving including Deep Sea Diving and Submarine Operations and Breathing in Irrespirable Atmospheres. He also wrote Resuscitation: A Brief Personal History of Siebe, Gorman \& Co. 1819–1957.Further ReadingObituary, 1965, The Times, 31 March, p. 16.LRD -
117 remote maintenance
дистанционное техническое обслуживание
Техническое обслуживание объекта, проводимое под управлением персонала без его непосредственного присутствия.
[ОСТ 45.152-99 ]Параллельные тексты EN-RU из ABB Review. Перевод компании Интент
Service from afarДистанционный сервисABB’s Remote Service concept is revolutionizing the robotics industryРазработанная АББ концепция дистанционного обслуживания Remote Service революционизирует робототехникуABB robots are found in industrial applications everywhere – lifting, packing, grinding and welding, to name a few. Robust and tireless, they work around the clock and are critical to a company’s productivity. Thus, keeping these robots in top shape is essential – any failure can lead to serious output consequences. But what happens when a robot malfunctions?Роботы АББ используются во всех отраслях промышленности для перемещения грузов, упаковки, шлифовки, сварки – всего и не перечислить. Надежные и неутомимые работники, способные трудиться день и ночь, они представляют большую ценность для владельца. Поэтому очень важно поддерживать их в надлежащей состоянии, ведь любой отказ может иметь серьезные последствия. Но что делать, если робот все-таки сломался?ABB’s new Remote Service concept holds the answer: This approach enables a malfunctioning robot to alarm for help itself. An ABB service engineer then receives whole diagnostic information via wireless technology, analyzes the data on a Web site and responds with support in just minutes. This unique service is paying off for customers and ABB alike, and in the process is revolutionizing service thinking.Ответом на этот вопрос стала новая концепция Remote Service от АББ, согласно которой неисправный робот сам просит о помощи. C помощью беспроводной технологии специалист сервисной службы АББ получает всю необходимую диагностическую информацию, анализирует данные на web-сайте и через считанные минуты выдает рекомендации по устранению отказа. Эта уникальная возможность одинаково ценна как для заказчиков, так и для самой компании АББ. В перспективе она способна в корне изменить весь подход к организации технического обслуживания.Every minute of production downtime can have financially disastrous consequences for a company. Traditional reactive service is no longer sufficient since on-site service engineer visits also demand great amounts of time and money. Thus, companies not only require faster help from the service organization when needed but they also want to avoid disturbances in production.Каждая минута простоя производства может привести к губительным финансовым последствиям. Традиционная организация сервиса, предусматривающая ликвидацию возникающих неисправностей, становится все менее эффективной, поскольку вызов сервисного инженера на место эксплуатации робота сопряжен с большими затратами времени и денег. Предприятия требуют от сервисной организации не только более быстрого оказания помощи, но и предотвращения возможных сбоев производства.In 2006, ABB developed a new approach to better meet customer’s expectations: Using the latest technologies to reach the robots at customer sites around the world, ABB could support them remotely in just minutes, thereby reducing the need for site visits. Thus the new Remote Service concept was quickly brought to fruition and was launched in mid-2007. Statistics show that by using the system the majority of production stoppages can be avoided.В 2006 г. компания АББ разработала новый подход к удовлетворению ожиданий своих заказчиков. Использование современных технологий позволяет специалистам АББ получать информацию от роботов из любой точки мира и в считанные минуты оказывать помощь дистанционно, в результате чего сокращается количество выездов на место установки. Запущенная в середине 2007 г. концепция Remote Service быстро себя оправдала. Статистика показывает, что её применение позволило предотвратить большое число остановок производства.Reactive maintenance The hardware that makes ABB Remote Service possible consists of a communication unit, which has a function similar to that of an airplane’s so-called black box 1. This “service box” is connected to the robot’s control system and can read and transmit diagnostic information. The unit not only reads critical diagnostic information that enables immediate support in the event of a failure, but also makes it possible to monitor and analyze the robot’s condition, thereby proactively detecting the need for maintenance.Устранение возникающих неисправностей Аппаратное устройство, с помощью которого реализуется концепция Remote Service, представляет собой коммуникационный блок, работающий аналогично черному ящику самолета (рис. 1). Этот блок считывает диагностические данные из контроллера робота и передает их по каналу GSM. Считывается не только информация, необходимая для оказания немедленной помощи в случае отказа, но и сведения, позволяющие контролировать и анализировать состояние робота для прогнозирования неисправностей и планирования технического обслуживания.If the robot breaks down, the service box immediately stores the status of the robot, its historical data (as log files), and diagnostic parameters such as temperature and power supply. Equipped with a built-in modem and using the GSM network, the box transmits the data to a central server for analysis and presentation on a dedicated Web site. Alerts are automatically sent to the nearest of ABB’s 1,200 robot service engineers who then accesses the detailed data and error log to analyze the problem.При поломке робота сервисный блок немедленно сохраняет данные о его состоянии, сведения из рабочего журнала, а также значения диагностических параметров (температура и характеристики питания). Эти данные передаются встроенным GSM-модемом на центральный сервер для анализа и представления на соответствующем web-сайте. Аварийные сообщения автоматически пересылаются ближайшему к месту аварии одному из 1200 сервисных инженеров-робототехников АББ, который получает доступ к детальной информации и журналу аварий для анализа возникшей проблемы.A remotely based ABB engineer can then quickly identify the exact fault, offering rapid customer support. For problems that cannot be solved remotely, the service engineer can arrange for quick delivery of spare parts and visit the site to repair the robot. Even if the engineer must make a site visit, service is faster, more efficient and performed to a higher standard than otherwise possible.Специалист АББ может дистанционно идентифицировать отказ и оказать быструю помощь заказчику. Если неисправность не может быть устранена дистанционно, сервисный инженер организовывает доставку запасных частей и выезд ремонтной бригады. Даже если необходимо разрешение проблемы на месте, предшествующая дистанционная диагностика позволяет минимизировать объем работ и сократить время простоя.Remote Service enables engineers to “talk” to robots remotely and to utilize tools that enable smart, fast and automatic analysis. The system is based on a machine-to-machine (M2M) concept, which works automatically, requiring human input only for analysis and personalized customer recommendations. ABB was recognized for this innovative solution at the M2M United Conference in Chicago in 2008 Factbox.Remote Service позволяет инженерам «разговаривать» с роботами на расстоянии и предоставляет в их распоряжение интеллектуальные средства быстрого автоматизированного анализа. Система основана на основе технологии автоматической связи машины с машиной (M2M), где участие человека сводится к анализу данных и выдаче рекомендаций клиенту. В 2008 г. это инновационное решение от АББ получило приз на конференции M2M United Conference в Чикаго (см. вставку).Proactive maintenanceRemote Service also allows ABB engineers to monitor and detect potential problems in the robot system and opens up new possibilities for proactive maintenance.Прогнозирование неисправностейRemote Service позволяет инженерам АББ дистанционно контролировать состояние роботов и прогнозировать возможные неисправности, что открывает новые возможности по организации профилактического обслуживания.The service box regularly takes condition measurements. By monitoring key parameters over time, Remote Service can identify potential failures and when necessary notify both the end customer and the appropriate ABB engineer. The management and storage of full system backups is a very powerful service to help recover from critical situations caused, for example, by operator errors.Сервисный блок регулярно выполняет диагностические измерения. Непрерывно контролируя ключевые параметры, Remote Service может распознать потенциальные опасности и, при необходимости, оповещать владельца оборудования и соответствующего специалиста АББ. Резервирование данных для возможного отката является мощным средством, обеспечивающим восстановление системы в критических ситуациях, например, после ошибки оператора.The first Remote Service installation took place in the automotive industry in the United States and quickly proved its value. The motherboard in a robot cabinet overheated and the rise in temperature triggered an alarm via Remote Service. Because of the alarm, engineers were able to replace a faulty fan, preventing a costly production shutdown.Первая система Remote Service была установлена на автозаводе в США и очень скоро была оценена по достоинству. Она обнаружила перегрев материнской платы в шкафу управления роботом и передала сигнал о превышении допустимой температуры, благодаря чему инженеры смогли заменить неисправный вентилятор и предотвратить дорогостоящую остановку производства.MyRobot: 24-hour remote access
Having regular access to a robot’s condition data is also essential to achieving lean production. At any time, from any location, customers can verify their robots’ status and access maintenance information and performance reports simply by logging in to ABB’s MyRobot Web site. The service enables customers to easily compare performances, identify bottlenecks or developing issues, and initiate the mostСайт MyRobot: круглосуточный дистанционный доступДля того чтобы обеспечить бесперебойное производство, необходимо иметь регулярный доступ к информации о состоянии робота. Зайдя на соответствующую страницу сайта MyRobot компании АББ, заказчики получат все необходимые данные, включая сведения о техническом обслуживании и отчеты о производительности своего робота. Эта услуга позволяет легко сравнивать данные о производительности, обнаруживать возможные проблемы, а также оптимизировать планирование технического обслуживания и модернизации. С помощью MyRobot можно значительно увеличить выпуск продукции и уменьшить количество выбросов.Award-winning solutionIn June 2008, the innovative Remote Service solution won the Gold Value Chain award at the M2M United Conference in Chicago. The value chain award honors successful corporate adopters of M2M (machine–to-machine) technology and highlights the process of combining multiple technologies to deliver high-quality services to customers. ABB won in the categoryof Smart Services.Приз за удачное решениеВ июне 2008 г. инновационное решение Remote Service получило награду Gold Value Chain (Золотая цепь) на конференции M2M United Conference в Чикаго. «Золотая цепь» присуждается за успешное масштабное внедрение технологии M2M (машина – машина), а также за достижения в объединении различных технологий для предоставления высококачественных услуг заказчикам. АББ одержала победу в номинации «Интеллектуальный сервис».Case study: Tetley Tetley GB Ltd is the world’s second-largest manufacturer and distributor of tea. The company’s manufacturing and distribution business is spread across 40 countries and sells over 60 branded tea bags. Tetley’s UK tea production facility in Eaglescliffe, County Durham is the sole producer of Tetley tea bags 2.Пример применения: Tetley Компания TetleyGB Ltd является вторым по величине мировым производителем и поставщиком чая. Производственные и торговые филиалы компании имеются в 40 странах, а продукция распространяется под 60 торговыми марками. Чаеразвесочная фабрика в Иглсклифф, графство Дарем, Великобритания – единственный производитель чая Tetley в пакетиках (рис. 2).ABB offers a flexible choice of service agreements for both new and existing robot installations, which can help extend the mean time between failures, shorten the time to repair and lower the cost of automated production.Предлагаемые АББ контракты на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и общую стоимость автоматизированного производства.Robots in the plant’s production line were tripping alarms and delaying the whole production cycle. The spurious alarms resulted in much unnecessary downtime that was spent resetting the robots in the hope that another breakdown could be avoided. Each time an alarm was tripped, several hours of production time was lost. “It was for this reason that we were keen to try out ABB’s Remote Service agreement,” said Colin Trevor, plant maintenance manager.Установленные в технологической линии роботы выдавали аварийные сигналы, задерживающие выполнение производственного цикла. Ложные срабатывания вынуждали перезапускать роботов в надежде предотвратить возможные отказы, в результате чего после каждого аварийного сигнала производство останавливалось на несколько часов. «Именно поэтому мы решили попробовать заключить с АББ контракт на дистанционное техническое обслуживание», – сказал Колин Тревор, начальник технической службы фабрики.To prevent future disruptions caused by unplanned downtime, Tetley signed an ABB Response Package service agreement, which included installing a service box and system infrastructure into the robot control systems. Using the Remote Service solution, ABB remotely monitors and collects data on the “wear and tear” and productivity of the robotic cells; this data is then shared with the customer and contributes to smooth-running production cycles.Для предотвращения ущерба в результате незапланированных простоев Tetley заключила с АББ контракт на комплексное обслуживание Response Package, согласно которому системы управления роботами были дооборудованы сервисными блоками с необходимой инфраструктурой. С помощью Remote Service компания АББ дистанционно собирает данные о наработке, износе и производительности роботизированных модулей. Эти данные предоставляются заказчику для оптимизации загрузки производственного оборудования.Higher production uptimeSince the implementation of Remote Service, Tetley has enjoyed greatly reduced robot downtime, with no further disruptions caused by unforeseen problems. “The Remote Service package has dramatically changed the plant,” said Trevor. “We no longer have breakdown issues throughout the shift, helping us to achieve much longer periods of robot uptime. As we have learned, world-class manufacturing facilities need world-class support packages. Remote monitoring of our robots helps us to maintain machine uptime, prevent costly downtime and ensures my employees can be put to more valuable use.”Увеличение полезного времениС момента внедрения Remote Service компания Tetley была приятно удивлена резким сокращением простоя роботов и отсутствием незапланированных остановок производства. «Пакет Remote Service резко изменил ситуацию на предприятии», – сказал Тревор. «Мы избавились от простоев роботов и смогли резко увеличить их эксплуатационную готовность. Мы поняли, что для производственного оборудования мирового класса необходим сервисный пакет мирового класса. Дистанционный контроль роботов помогает нам поддерживать их в рабочем состоянии, предотвращать дорогостоящие простои и задействовать наш персонал для выполнения более важных задач».Service accessRemote Service is available worldwide, connecting more than 500 robots. Companies that have up to 30 robots are often good candidates for the Remote Service offering, as they usually have neither the engineers nor the requisite skills to deal with robotics faults themselves. Larger companies are also enthusiastic about Remote Service, as the proactive services will improve the lifetime of their equipment and increase overall production uptime.Доступность сервисаСеть Remote Service охватывает более 700 роботов по всему миру. Потенциальными заказчиками Remote Service являются компании, имеющие до 30 роботов, но не имеющие инженеров и техников, способных самостоятельно устранять их неисправности. Интерес к Remote Service проявляют и более крупные компании, поскольку они заинтересованы в увеличении срока службы и эксплуатационной готовности производственного оборудования.In today’s competitive environment, business profitability often relies on demanding production schedules that do not always leave time for exhaustive or repeated equipment health checks. ABB’s Remote Service agreements are designed to monitor its customers’ robots to identify when problems are likely to occur and ensure that help is dispatched before the problem can escalate. In over 60 percent of ABB’s service calls, its robots can be brought back online remotely, without further intervention.В условиях современной конкуренции окупаемость бизнеса часто зависит от соблюдения жестких графиков производства, не оставляющих времени для полномасштабных или периодических проверок исправности оборудования. Контракт Remote Service предусматривает мониторинг состояния роботов заказчика для прогнозирования возможных неисправностей и принятие мер по их предотвращению. В более чем 60 % случаев для устранения неисправности достаточно дистанционной консультации в сервисной службе АББ, дальнейшего вмешательства не требуется.ABB offers a flexible choice of service agreements for both new and existing robot installations, which helps extend the mean time between failures, shorten the time to repair and lower the total cost of ownership. With four new packages available – Support, Response, Maintenance and Warranty, each backed up by ABB’s Remote Service technology – businesses can minimize the impact of unplanned downtime and achieve improved production-line efficiency.Компания АББ предлагает гибкий выбор контрактов на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, которые позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и эксплуатационные расходы. Четыре новых пакета на основе технологии Remote Service – Support, Response, Maintenance и Warranty – позволяют минимизировать внеплановые простои и значительно повысить эффективность производства.The benefits of Remote Sevice are clear: improved availability, fewer service visits, lower maintenance costs and maximized total cost of ownership. This unique service sets ABB apart from its competitors and is the beginning of a revolution in service thinking. It provides ABB with a great opportunity to improve customer access to its expertise and develop more advanced services worldwide.Преимущества дистанционного технического обслуживания очевидны: повышенная надежность, уменьшение выездов ремонтных бригад, уменьшение затрат на обслуживание и общих эксплуатационных расходов. Эта уникальная услуга дает компании АББ преимущества над конкурентами и демонстрирует революционный подход к организации сервиса. Благодаря ей компания АББ расширяет доступ заказчиков к опыту своих специалистов и получает возможность более эффективного оказания технической помощи по всему миру.Тематики
- тех. обсл. и ремонт средств электросвязи
Обобщающие термины
EN
Англо-русский словарь нормативно-технической терминологии > remote maintenance
118 remote sevice
дистанционное техническое обслуживание
Техническое обслуживание объекта, проводимое под управлением персонала без его непосредственного присутствия.
[ОСТ 45.152-99 ]Параллельные тексты EN-RU из ABB Review. Перевод компании Интент
Service from afarДистанционный сервисABB’s Remote Service concept is revolutionizing the robotics industryРазработанная АББ концепция дистанционного обслуживания Remote Service революционизирует робототехникуABB robots are found in industrial applications everywhere – lifting, packing, grinding and welding, to name a few. Robust and tireless, they work around the clock and are critical to a company’s productivity. Thus, keeping these robots in top shape is essential – any failure can lead to serious output consequences. But what happens when a robot malfunctions?Роботы АББ используются во всех отраслях промышленности для перемещения грузов, упаковки, шлифовки, сварки – всего и не перечислить. Надежные и неутомимые работники, способные трудиться день и ночь, они представляют большую ценность для владельца. Поэтому очень важно поддерживать их в надлежащей состоянии, ведь любой отказ может иметь серьезные последствия. Но что делать, если робот все-таки сломался?ABB’s new Remote Service concept holds the answer: This approach enables a malfunctioning robot to alarm for help itself. An ABB service engineer then receives whole diagnostic information via wireless technology, analyzes the data on a Web site and responds with support in just minutes. This unique service is paying off for customers and ABB alike, and in the process is revolutionizing service thinking.Ответом на этот вопрос стала новая концепция Remote Service от АББ, согласно которой неисправный робот сам просит о помощи. C помощью беспроводной технологии специалист сервисной службы АББ получает всю необходимую диагностическую информацию, анализирует данные на web-сайте и через считанные минуты выдает рекомендации по устранению отказа. Эта уникальная возможность одинаково ценна как для заказчиков, так и для самой компании АББ. В перспективе она способна в корне изменить весь подход к организации технического обслуживания.Every minute of production downtime can have financially disastrous consequences for a company. Traditional reactive service is no longer sufficient since on-site service engineer visits also demand great amounts of time and money. Thus, companies not only require faster help from the service organization when needed but they also want to avoid disturbances in production.Каждая минута простоя производства может привести к губительным финансовым последствиям. Традиционная организация сервиса, предусматривающая ликвидацию возникающих неисправностей, становится все менее эффективной, поскольку вызов сервисного инженера на место эксплуатации робота сопряжен с большими затратами времени и денег. Предприятия требуют от сервисной организации не только более быстрого оказания помощи, но и предотвращения возможных сбоев производства.In 2006, ABB developed a new approach to better meet customer’s expectations: Using the latest technologies to reach the robots at customer sites around the world, ABB could support them remotely in just minutes, thereby reducing the need for site visits. Thus the new Remote Service concept was quickly brought to fruition and was launched in mid-2007. Statistics show that by using the system the majority of production stoppages can be avoided.В 2006 г. компания АББ разработала новый подход к удовлетворению ожиданий своих заказчиков. Использование современных технологий позволяет специалистам АББ получать информацию от роботов из любой точки мира и в считанные минуты оказывать помощь дистанционно, в результате чего сокращается количество выездов на место установки. Запущенная в середине 2007 г. концепция Remote Service быстро себя оправдала. Статистика показывает, что её применение позволило предотвратить большое число остановок производства.Reactive maintenance The hardware that makes ABB Remote Service possible consists of a communication unit, which has a function similar to that of an airplane’s so-called black box 1. This “service box” is connected to the robot’s control system and can read and transmit diagnostic information. The unit not only reads critical diagnostic information that enables immediate support in the event of a failure, but also makes it possible to monitor and analyze the robot’s condition, thereby proactively detecting the need for maintenance.Устранение возникающих неисправностей Аппаратное устройство, с помощью которого реализуется концепция Remote Service, представляет собой коммуникационный блок, работающий аналогично черному ящику самолета (рис. 1). Этот блок считывает диагностические данные из контроллера робота и передает их по каналу GSM. Считывается не только информация, необходимая для оказания немедленной помощи в случае отказа, но и сведения, позволяющие контролировать и анализировать состояние робота для прогнозирования неисправностей и планирования технического обслуживания.If the robot breaks down, the service box immediately stores the status of the robot, its historical data (as log files), and diagnostic parameters such as temperature and power supply. Equipped with a built-in modem and using the GSM network, the box transmits the data to a central server for analysis and presentation on a dedicated Web site. Alerts are automatically sent to the nearest of ABB’s 1,200 robot service engineers who then accesses the detailed data and error log to analyze the problem.При поломке робота сервисный блок немедленно сохраняет данные о его состоянии, сведения из рабочего журнала, а также значения диагностических параметров (температура и характеристики питания). Эти данные передаются встроенным GSM-модемом на центральный сервер для анализа и представления на соответствующем web-сайте. Аварийные сообщения автоматически пересылаются ближайшему к месту аварии одному из 1200 сервисных инженеров-робототехников АББ, который получает доступ к детальной информации и журналу аварий для анализа возникшей проблемы.A remotely based ABB engineer can then quickly identify the exact fault, offering rapid customer support. For problems that cannot be solved remotely, the service engineer can arrange for quick delivery of spare parts and visit the site to repair the robot. Even if the engineer must make a site visit, service is faster, more efficient and performed to a higher standard than otherwise possible.Специалист АББ может дистанционно идентифицировать отказ и оказать быструю помощь заказчику. Если неисправность не может быть устранена дистанционно, сервисный инженер организовывает доставку запасных частей и выезд ремонтной бригады. Даже если необходимо разрешение проблемы на месте, предшествующая дистанционная диагностика позволяет минимизировать объем работ и сократить время простоя.Remote Service enables engineers to “talk” to robots remotely and to utilize tools that enable smart, fast and automatic analysis. The system is based on a machine-to-machine (M2M) concept, which works automatically, requiring human input only for analysis and personalized customer recommendations. ABB was recognized for this innovative solution at the M2M United Conference in Chicago in 2008 Factbox.Remote Service позволяет инженерам «разговаривать» с роботами на расстоянии и предоставляет в их распоряжение интеллектуальные средства быстрого автоматизированного анализа. Система основана на основе технологии автоматической связи машины с машиной (M2M), где участие человека сводится к анализу данных и выдаче рекомендаций клиенту. В 2008 г. это инновационное решение от АББ получило приз на конференции M2M United Conference в Чикаго (см. вставку).Proactive maintenanceRemote Service also allows ABB engineers to monitor and detect potential problems in the robot system and opens up new possibilities for proactive maintenance.Прогнозирование неисправностейRemote Service позволяет инженерам АББ дистанционно контролировать состояние роботов и прогнозировать возможные неисправности, что открывает новые возможности по организации профилактического обслуживания.The service box regularly takes condition measurements. By monitoring key parameters over time, Remote Service can identify potential failures and when necessary notify both the end customer and the appropriate ABB engineer. The management and storage of full system backups is a very powerful service to help recover from critical situations caused, for example, by operator errors.Сервисный блок регулярно выполняет диагностические измерения. Непрерывно контролируя ключевые параметры, Remote Service может распознать потенциальные опасности и, при необходимости, оповещать владельца оборудования и соответствующего специалиста АББ. Резервирование данных для возможного отката является мощным средством, обеспечивающим восстановление системы в критических ситуациях, например, после ошибки оператора.The first Remote Service installation took place in the automotive industry in the United States and quickly proved its value. The motherboard in a robot cabinet overheated and the rise in temperature triggered an alarm via Remote Service. Because of the alarm, engineers were able to replace a faulty fan, preventing a costly production shutdown.Первая система Remote Service была установлена на автозаводе в США и очень скоро была оценена по достоинству. Она обнаружила перегрев материнской платы в шкафу управления роботом и передала сигнал о превышении допустимой температуры, благодаря чему инженеры смогли заменить неисправный вентилятор и предотвратить дорогостоящую остановку производства.MyRobot: 24-hour remote access
Having regular access to a robot’s condition data is also essential to achieving lean production. At any time, from any location, customers can verify their robots’ status and access maintenance information and performance reports simply by logging in to ABB’s MyRobot Web site. The service enables customers to easily compare performances, identify bottlenecks or developing issues, and initiate the mostСайт MyRobot: круглосуточный дистанционный доступДля того чтобы обеспечить бесперебойное производство, необходимо иметь регулярный доступ к информации о состоянии робота. Зайдя на соответствующую страницу сайта MyRobot компании АББ, заказчики получат все необходимые данные, включая сведения о техническом обслуживании и отчеты о производительности своего робота. Эта услуга позволяет легко сравнивать данные о производительности, обнаруживать возможные проблемы, а также оптимизировать планирование технического обслуживания и модернизации. С помощью MyRobot можно значительно увеличить выпуск продукции и уменьшить количество выбросов.Award-winning solutionIn June 2008, the innovative Remote Service solution won the Gold Value Chain award at the M2M United Conference in Chicago. The value chain award honors successful corporate adopters of M2M (machine–to-machine) technology and highlights the process of combining multiple technologies to deliver high-quality services to customers. ABB won in the categoryof Smart Services.Приз за удачное решениеВ июне 2008 г. инновационное решение Remote Service получило награду Gold Value Chain (Золотая цепь) на конференции M2M United Conference в Чикаго. «Золотая цепь» присуждается за успешное масштабное внедрение технологии M2M (машина – машина), а также за достижения в объединении различных технологий для предоставления высококачественных услуг заказчикам. АББ одержала победу в номинации «Интеллектуальный сервис».Case study: Tetley Tetley GB Ltd is the world’s second-largest manufacturer and distributor of tea. The company’s manufacturing and distribution business is spread across 40 countries and sells over 60 branded tea bags. Tetley’s UK tea production facility in Eaglescliffe, County Durham is the sole producer of Tetley tea bags 2.Пример применения: Tetley Компания TetleyGB Ltd является вторым по величине мировым производителем и поставщиком чая. Производственные и торговые филиалы компании имеются в 40 странах, а продукция распространяется под 60 торговыми марками. Чаеразвесочная фабрика в Иглсклифф, графство Дарем, Великобритания – единственный производитель чая Tetley в пакетиках (рис. 2).ABB offers a flexible choice of service agreements for both new and existing robot installations, which can help extend the mean time between failures, shorten the time to repair and lower the cost of automated production.Предлагаемые АББ контракты на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и общую стоимость автоматизированного производства.Robots in the plant’s production line were tripping alarms and delaying the whole production cycle. The spurious alarms resulted in much unnecessary downtime that was spent resetting the robots in the hope that another breakdown could be avoided. Each time an alarm was tripped, several hours of production time was lost. “It was for this reason that we were keen to try out ABB’s Remote Service agreement,” said Colin Trevor, plant maintenance manager.Установленные в технологической линии роботы выдавали аварийные сигналы, задерживающие выполнение производственного цикла. Ложные срабатывания вынуждали перезапускать роботов в надежде предотвратить возможные отказы, в результате чего после каждого аварийного сигнала производство останавливалось на несколько часов. «Именно поэтому мы решили попробовать заключить с АББ контракт на дистанционное техническое обслуживание», – сказал Колин Тревор, начальник технической службы фабрики.To prevent future disruptions caused by unplanned downtime, Tetley signed an ABB Response Package service agreement, which included installing a service box and system infrastructure into the robot control systems. Using the Remote Service solution, ABB remotely monitors and collects data on the “wear and tear” and productivity of the robotic cells; this data is then shared with the customer and contributes to smooth-running production cycles.Для предотвращения ущерба в результате незапланированных простоев Tetley заключила с АББ контракт на комплексное обслуживание Response Package, согласно которому системы управления роботами были дооборудованы сервисными блоками с необходимой инфраструктурой. С помощью Remote Service компания АББ дистанционно собирает данные о наработке, износе и производительности роботизированных модулей. Эти данные предоставляются заказчику для оптимизации загрузки производственного оборудования.Higher production uptimeSince the implementation of Remote Service, Tetley has enjoyed greatly reduced robot downtime, with no further disruptions caused by unforeseen problems. “The Remote Service package has dramatically changed the plant,” said Trevor. “We no longer have breakdown issues throughout the shift, helping us to achieve much longer periods of robot uptime. As we have learned, world-class manufacturing facilities need world-class support packages. Remote monitoring of our robots helps us to maintain machine uptime, prevent costly downtime and ensures my employees can be put to more valuable use.”Увеличение полезного времениС момента внедрения Remote Service компания Tetley была приятно удивлена резким сокращением простоя роботов и отсутствием незапланированных остановок производства. «Пакет Remote Service резко изменил ситуацию на предприятии», – сказал Тревор. «Мы избавились от простоев роботов и смогли резко увеличить их эксплуатационную готовность. Мы поняли, что для производственного оборудования мирового класса необходим сервисный пакет мирового класса. Дистанционный контроль роботов помогает нам поддерживать их в рабочем состоянии, предотвращать дорогостоящие простои и задействовать наш персонал для выполнения более важных задач».Service accessRemote Service is available worldwide, connecting more than 500 robots. Companies that have up to 30 robots are often good candidates for the Remote Service offering, as they usually have neither the engineers nor the requisite skills to deal with robotics faults themselves. Larger companies are also enthusiastic about Remote Service, as the proactive services will improve the lifetime of their equipment and increase overall production uptime.Доступность сервисаСеть Remote Service охватывает более 700 роботов по всему миру. Потенциальными заказчиками Remote Service являются компании, имеющие до 30 роботов, но не имеющие инженеров и техников, способных самостоятельно устранять их неисправности. Интерес к Remote Service проявляют и более крупные компании, поскольку они заинтересованы в увеличении срока службы и эксплуатационной готовности производственного оборудования.In today’s competitive environment, business profitability often relies on demanding production schedules that do not always leave time for exhaustive or repeated equipment health checks. ABB’s Remote Service agreements are designed to monitor its customers’ robots to identify when problems are likely to occur and ensure that help is dispatched before the problem can escalate. In over 60 percent of ABB’s service calls, its robots can be brought back online remotely, without further intervention.В условиях современной конкуренции окупаемость бизнеса часто зависит от соблюдения жестких графиков производства, не оставляющих времени для полномасштабных или периодических проверок исправности оборудования. Контракт Remote Service предусматривает мониторинг состояния роботов заказчика для прогнозирования возможных неисправностей и принятие мер по их предотвращению. В более чем 60 % случаев для устранения неисправности достаточно дистанционной консультации в сервисной службе АББ, дальнейшего вмешательства не требуется.ABB offers a flexible choice of service agreements for both new and existing robot installations, which helps extend the mean time between failures, shorten the time to repair and lower the total cost of ownership. With four new packages available – Support, Response, Maintenance and Warranty, each backed up by ABB’s Remote Service technology – businesses can minimize the impact of unplanned downtime and achieve improved production-line efficiency.Компания АББ предлагает гибкий выбор контрактов на выполнение технического обслуживания как уже имеющихся, так и вновь устанавливаемых роботов, которые позволяют значительно увеличить среднюю наработку на отказ, сократить время ремонта и эксплуатационные расходы. Четыре новых пакета на основе технологии Remote Service – Support, Response, Maintenance и Warranty – позволяют минимизировать внеплановые простои и значительно повысить эффективность производства.The benefits of Remote Sevice are clear: improved availability, fewer service visits, lower maintenance costs and maximized total cost of ownership. This unique service sets ABB apart from its competitors and is the beginning of a revolution in service thinking. It provides ABB with a great opportunity to improve customer access to its expertise and develop more advanced services worldwide.Преимущества дистанционного технического обслуживания очевидны: повышенная надежность, уменьшение выездов ремонтных бригад, уменьшение затрат на обслуживание и общих эксплуатационных расходов. Эта уникальная услуга дает компании АББ преимущества над конкурентами и демонстрирует революционный подход к организации сервиса. Благодаря ей компания АББ расширяет доступ заказчиков к опыту своих специалистов и получает возможность более эффективного оказания технической помощи по всему миру.Тематики
- тех. обсл. и ремонт средств электросвязи
Обобщающие термины
EN
Англо-русский словарь нормативно-технической терминологии > remote sevice
119 SEAC
1) Военный термин: Special Equipment Aramid Composite, submarine exercise area coordinator2) Ветеринария: Spongiform Encephalopathy Advisory Committee3) Сокращение: South-East Asia Command, Submarine Exercise Area Controller, seacoast5) Вычислительная техника: Name of first computer to use transistors, built by ( National Bureau of) Standards Eastern Automatic Calculator (Also see SWAC), Standards Eastern Automatic Computer6) Образование: Special Education Advisory Committee120 Historical Portugal
Before Romans described western Iberia or Hispania as "Lusitania," ancient Iberians inhabited the land. Phoenician and Greek trading settlements grew up in the Tagus estuary area and nearby coasts. Beginning around 202 BCE, Romans invaded what is today southern Portugal. With Rome's defeat of Carthage, Romans proceeded to conquer and rule the western region north of the Tagus, which they named Roman "Lusitania." In the fourth century CE, as Rome's rule weakened, the area experienced yet another invasion—Germanic tribes, principally the Suevi, who eventually were Christianized. During the sixth century CE, the Suevi kingdom was superseded by yet another Germanic tribe—the Christian Visigoths.A major turning point in Portugal's history came in 711, as Muslim armies from North Africa, consisting of both Arab and Berber elements, invaded the Iberian Peninsula from across the Straits of Gibraltar. They entered what is now Portugal in 714, and proceeded to conquer most of the country except for the far north. For the next half a millennium, Islam and Muslim presence in Portugal left a significant mark upon the politics, government, language, and culture of the country.Islam, Reconquest, and Portugal Created, 714-1140The long frontier struggle between Muslim invaders and Christian communities in the north of the Iberian peninsula was called the Reconquista (Reconquest). It was during this struggle that the first dynasty of Portuguese kings (Burgundian) emerged and the independent monarchy of Portugal was established. Christian forces moved south from what is now the extreme north of Portugal and gradually defeated Muslim forces, besieging and capturing towns under Muslim sway. In the ninth century, as Christian forces slowly made their way southward, Christian elements were dominant only in the area between Minho province and the Douro River; this region became known as "territorium Portu-calense."In the 11th century, the advance of the Reconquest quickened as local Christian armies were reinforced by crusading knights from what is now France and England. Christian forces took Montemor (1034), at the Mondego River; Lamego (1058); Viseu (1058); and Coimbra (1064). In 1095, the king of Castile and Léon granted the country of "Portu-cale," what became northern Portugal, to a Burgundian count who had emigrated from France. This was the foundation of Portugal. In 1139, a descendant of this count, Afonso Henriques, proclaimed himself "King of Portugal." He was Portugal's first monarch, the "Founder," and the first of the Burgundian dynasty, which ruled until 1385.The emergence of Portugal in the 12th century as a separate monarchy in Iberia occurred before the Christian Reconquest of the peninsula. In the 1140s, the pope in Rome recognized Afonso Henriques as king of Portugal. In 1147, after a long, bloody siege, Muslim-occupied Lisbon fell to Afonso Henriques's army. Lisbon was the greatest prize of the 500-year war. Assisting this effort were English crusaders on their way to the Holy Land; the first bishop of Lisbon was an Englishman. When the Portuguese captured Faro and Silves in the Algarve province in 1248-50, the Reconquest of the extreme western portion of the Iberian peninsula was complete—significantly, more than two centuries before the Spanish crown completed the Reconquest of the eastern portion by capturing Granada in 1492.Consolidation and Independence of Burgundian Portugal, 1140-1385Two main themes of Portugal's early existence as a monarchy are the consolidation of control over the realm and the defeat of a Castil-ian threat from the east to its independence. At the end of this period came the birth of a new royal dynasty (Aviz), which prepared to carry the Christian Reconquest beyond continental Portugal across the straits of Gibraltar to North Africa. There was a variety of motives behind these developments. Portugal's independent existence was imperiled by threats from neighboring Iberian kingdoms to the north and east. Politics were dominated not only by efforts against the Muslims inPortugal (until 1250) and in nearby southern Spain (until 1492), but also by internecine warfare among the kingdoms of Castile, Léon, Aragon, and Portugal. A final comeback of Muslim forces was defeated at the battle of Salado (1340) by allied Castilian and Portuguese forces. In the emerging Kingdom of Portugal, the monarch gradually gained power over and neutralized the nobility and the Church.The historic and commonplace Portuguese saying "From Spain, neither a good wind nor a good marriage" was literally played out in diplomacy and war in the late 14th-century struggles for mastery in the peninsula. Larger, more populous Castile was pitted against smaller Portugal. Castile's Juan I intended to force a union between Castile and Portugal during this era of confusion and conflict. In late 1383, Portugal's King Fernando, the last king of the Burgundian dynasty, suddenly died prematurely at age 38, and the Master of Aviz, Portugal's most powerful nobleman, took up the cause of independence and resistance against Castile's invasion. The Master of Aviz, who became King João I of Portugal, was able to obtain foreign assistance. With the aid of English archers, Joao's armies defeated the Castilians in the crucial battle of Aljubarrota, on 14 August 1385, a victory that assured the independence of the Portuguese monarchy from its Castilian nemesis for several centuries.Aviz Dynasty and Portugal's First Overseas Empire, 1385-1580The results of the victory at Aljubarrota, much celebrated in Portugal's art and monuments, and the rise of the Aviz dynasty also helped to establish a new merchant class in Lisbon and Oporto, Portugal's second city. This group supported King João I's program of carrying the Reconquest to North Africa, since it was interested in expanding Portugal's foreign commerce and tapping into Muslim trade routes and resources in Africa. With the Reconquest against the Muslims completed in Portugal and the threat from Castile thwarted for the moment, the Aviz dynasty launched an era of overseas conquest, exploration, and trade. These efforts dominated Portugal's 15th and 16th centuries.The overseas empire and age of Discoveries began with Portugal's bold conquest in 1415 of the Moroccan city of Ceuta. One royal member of the 1415 expedition was young, 21-year-old Prince Henry, later known in history as "Prince Henry the Navigator." His part in the capture of Ceuta won Henry his knighthood and began Portugal's "Marvelous Century," during which the small kingdom was counted as a European and world power of consequence. Henry was the son of King João I and his English queen, Philippa of Lancaster, but he did not inherit the throne. Instead, he spent most of his life and his fortune, and that of the wealthy military Order of Christ, on various imperial ventures and on voyages of exploration down the African coast and into the Atlantic. While mythology has surrounded Henry's controversial role in the Discoveries, and this role has been exaggerated, there is no doubt that he played a vital part in the initiation of Portugal's first overseas empire and in encouraging exploration. He was naturally curious, had a sense of mission for Portugal, and was a strong leader. He also had wealth to expend; at least a third of the African voyages of the time were under his sponsorship. If Prince Henry himself knew little science, significant scientific advances in navigation were made in his day.What were Portugal's motives for this new imperial effort? The well-worn historical cliche of "God, Glory, and Gold" can only partly explain the motivation of a small kingdom with few natural resources and barely 1 million people, which was greatly outnumbered by the other powers it confronted. Among Portuguese objectives were the desire to exploit known North African trade routes and resources (gold, wheat, leather, weaponry, and other goods that were scarce in Iberia); the need to outflank the Muslim world in the Mediterranean by sailing around Africa, attacking Muslims en route; and the wish to ally with Christian kingdoms beyond Africa. This enterprise also involved a strategy of breaking the Venetian spice monopoly by trading directly with the East by means of discovering and exploiting a sea route around Africa to Asia. Besides the commercial motives, Portugal nurtured a strong crusading sense of Christian mission, and various classes in the kingdom saw an opportunity for fame and gain.By the time of Prince Henry's death in 1460, Portugal had gained control of the Atlantic archipelagos of the Azores and Madeiras, begun to colonize the Cape Verde Islands, failed to conquer the Canary Islands from Castile, captured various cities on Morocco's coast, and explored as far as Senegal, West Africa, down the African coast. By 1488, Bar-tolomeu Dias had rounded the Cape of Good Hope in South Africa and thereby discovered the way to the Indian Ocean.Portugal's largely coastal African empire and later its fragile Asian empire brought unexpected wealth but were purchased at a high price. Costs included wars of conquest and defense against rival powers, manning the far-flung navel and trade fleets and scattered castle-fortresses, and staffing its small but fierce armies, all of which entailed a loss of skills and population to maintain a scattered empire. Always short of capital, the monarchy became indebted to bankers. There were many defeats beginning in the 16th century at the hands of the larger imperial European monarchies (Spain, France, England, and Holland) and many attacks on Portugal and its strung-out empire. Typically, there was also the conflict that arose when a tenuously held world empire that rarely if ever paid its way demanded finance and manpower Portugal itself lacked.The first 80 years of the glorious imperial era, the golden age of Portugal's imperial power and world influence, was an African phase. During 1415-88, Portuguese navigators and explorers in small ships, some of them caravelas (caravels), explored the treacherous, disease-ridden coasts of Africa from Morocco to South Africa beyond the Cape of Good Hope. By the 1470s, the Portuguese had reached the Gulf of Guinea and, in the early 1480s, what is now Angola. Bartolomeu Dias's extraordinary voyage of 1487-88 to South Africa's coast and the edge of the Indian Ocean convinced Portugal that the best route to Asia's spices and Christians lay south, around the tip of southern Africa. Between 1488 and 1495, there was a hiatus caused in part by domestic conflict in Portugal, discussion of resources available for further conquests beyond Africa in Asia, and serious questions as to Portugal's capacity to reach beyond Africa. In 1495, King Manuel and his council decided to strike for Asia, whatever the consequences. In 1497-99, Vasco da Gama, under royal orders, made the epic two-year voyage that discovered the sea route to western India (Asia), outflanked Islam and Venice, and began Portugal's Asian empire. Within 50 years, Portugal had discovered and begun the exploitation of its largest colony, Brazil, and set up forts and trading posts from the Middle East (Aden and Ormuz), India (Calicut, Goa, etc.), Malacca, and Indonesia to Macau in China.By the 1550s, parts of its largely coastal, maritime trading post empire from Morocco to the Moluccas were under siege from various hostile forces, including Muslims, Christians, and Hindi. Although Moroccan forces expelled the Portuguese from the major coastal cities by 1550, the rival European monarchies of Castile (Spain), England, France, and later Holland began to seize portions of her undermanned, outgunned maritime empire.In 1580, Phillip II of Spain, whose mother was a Portuguese princess and who had a strong claim to the Portuguese throne, invaded Portugal, claimed the throne, and assumed control over the realm and, by extension, its African, Asian, and American empires. Phillip II filled the power vacuum that appeared in Portugal following the loss of most of Portugal's army and its young, headstrong King Sebastião in a disastrous war in Morocco. Sebastiao's death in battle (1578) and the lack of a natural heir to succeed him, as well as the weak leadership of the cardinal who briefly assumed control in Lisbon, led to a crisis that Spain's strong monarch exploited. As a result, Portugal lost its independence to Spain for a period of 60 years.Portugal under Spanish Rule, 1580-1640Despite the disastrous nature of Portugal's experience under Spanish rule, "The Babylonian Captivity" gave birth to modern Portuguese nationalism, its second overseas empire, and its modern alliance system with England. Although Spain allowed Portugal's weakened empire some autonomy, Spanish rule in Portugal became increasingly burdensome and unacceptable. Spain's ambitious imperial efforts in Europe and overseas had an impact on the Portuguese as Spain made greater and greater demands on its smaller neighbor for manpower and money. Portugal's culture underwent a controversial Castilianization, while its empire became hostage to Spain's fortunes. New rival powers England, France, and Holland attacked and took parts of Spain's empire and at the same time attacked Portugal's empire, as well as the mother country.Portugal's empire bore the consequences of being attacked by Spain's bitter enemies in what was a form of world war. Portuguese losses were heavy. By 1640, Portugal had lost most of its Moroccan cities as well as Ceylon, the Moluccas, and sections of India. With this, Portugal's Asian empire was gravely weakened. Only Goa, Damão, Diu, Bombay, Timor, and Macau remained and, in Brazil, Dutch forces occupied the northeast.On 1 December 1640, long commemorated as a national holiday, Portuguese rebels led by the duke of Braganza overthrew Spanish domination and took advantage of Spanish weakness following a more serious rebellion in Catalonia. Portugal regained independence from Spain, but at a price: dependence on foreign assistance to maintain its independence in the form of the renewal of the alliance with England.Restoration and Second Empire, 1640-1822Foreign affairs and empire dominated the restoration era and aftermath, and Portugal again briefly enjoyed greater European power and prestige. The Anglo-Portuguese Alliance was renewed and strengthened in treaties of 1642, 1654, and 1661, and Portugal's independence from Spain was underwritten by English pledges and armed assistance. In a Luso-Spanish treaty of 1668, Spain recognized Portugal's independence. Portugal's alliance with England was a marriage of convenience and necessity between two monarchies with important religious, cultural, and social differences. In return for legal, diplomatic, and trade privileges, as well as the use during war and peace of Portugal's great Lisbon harbor and colonial ports for England's navy, England pledged to protect Portugal and its scattered empire from any attack. The previously cited 17th-century alliance treaties were renewed later in the Treaty of Windsor, signed in London in 1899. On at least 10 different occasions after 1640, and during the next two centuries, England was central in helping prevent or repel foreign invasions of its ally, Portugal.Portugal's second empire (1640-1822) was largely Brazil-oriented. Portuguese colonization, exploitation of wealth, and emigration focused on Portuguese America, and imperial revenues came chiefly from Brazil. Between 1670 and 1740, Portugal's royalty and nobility grew wealthier on funds derived from Brazilian gold, diamonds, sugar, tobacco, and other crops, an enterprise supported by the Atlantic slave trade and the supply of African slave labor from West Africa and Angola. Visitors today can see where much of that wealth was invested: Portugal's rich legacy of monumental architecture. Meanwhile, the African slave trade took a toll in Angola and West Africa.In continental Portugal, absolutist monarchy dominated politics and government, and there was a struggle for position and power between the monarchy and other institutions, such as the Church and nobility. King José I's chief minister, usually known in history as the marquis of Pombal (ruled 1750-77), sharply suppressed the nobility and theChurch (including the Inquisition, now a weak institution) and expelled the Jesuits. Pombal also made an effort to reduce economic dependence on England, Portugal's oldest ally. But his successes did not last much beyond his disputed time in office.Beginning in the late 18th century, the European-wide impact of the French Revolution and the rise of Napoleon placed Portugal in a vulnerable position. With the monarchy ineffectively led by an insane queen (Maria I) and her indecisive regent son (João VI), Portugal again became the focus of foreign ambition and aggression. With England unable to provide decisive assistance in time, France—with Spain's consent—invaded Portugal in 1807. As Napoleon's army under General Junot entered Lisbon meeting no resistance, Portugal's royal family fled on a British fleet to Brazil, where it remained in exile until 1821. In the meantime, Portugal's overseas empire was again under threat. There was a power vacuum as the monarch was absent, foreign armies were present, and new political notions of liberalism and constitutional monarchy were exciting various groups of citizens.Again England came to the rescue, this time in the form of the armies of the duke of Wellington. Three successive French invasions of Portugal were defeated and expelled, and Wellington succeeded in carrying the war against Napoleon across the Portuguese frontier into Spain. The presence of the English army, the new French-born liberal ideas, and the political vacuum combined to create revolutionary conditions. The French invasions and the peninsular wars, where Portuguese armed forces played a key role, marked the beginning of a new era in politics.Liberalism and Constitutional Monarchy, 1822-1910During 1807-22, foreign invasions, war, and civil strife over conflicting political ideas gravely damaged Portugal's commerce, economy, and novice industry. The next terrible blow was the loss of Brazil in 1822, the jewel in the imperial crown. Portugal's very independence seemed to be at risk. In vain, Portugal sought to resist Brazilian independence by force, but in 1825 it formally acknowledged Brazilian independence by treaty.Portugal's slow recovery from the destructive French invasions and the "war of independence" was complicated by civil strife over the form of constitutional monarchy that best suited Portugal. After struggles over these issues between 1820 and 1834, Portugal settled somewhat uncertainly into a moderate constitutional monarchy whose constitution (Charter of 1826) lent it strong political powers to exert a moderating influence between the executive and legislative branches of the government. It also featured a new upper middle class based on land ownership and commerce; a Catholic Church that, although still important, lived with reduced privileges and property; a largely African (third) empire to which Lisbon and Oporto devoted increasing spiritual and material resources, starting with the liberal imperial plans of 1836 and 1851, and continuing with the work of institutions like the Lisbon Society of Geography (established 1875); and a mass of rural peasants whose bonds to the land weakened after 1850 and who began to immigrate in increasing numbers to Brazil and North America.Chronic military intervention in national politics began in 19th-century Portugal. Such intervention, usually commencing with coups or pronunciamentos (military revolts), was a shortcut to the spoils of political office and could reflect popular discontent as well as the power of personalities. An early example of this was the 1817 golpe (coup) attempt of General Gomes Freire against British military rule in Portugal before the return of King João VI from Brazil. Except for a more stable period from 1851 to 1880, military intervention in politics, or the threat thereof, became a feature of the constitutional monarchy's political life, and it continued into the First Republic and the subsequent Estado Novo.Beginning with the Regeneration period (1851-80), Portugal experienced greater political stability and economic progress. Military intervention in politics virtually ceased; industrialization and construction of railroads, roads, and bridges proceeded; two political parties (Regenerators and Historicals) worked out a system of rotation in power; and leading intellectuals sparked a cultural revival in several fields. In 19th-century literature, there was a new golden age led by such figures as Alexandre Herculano (historian), Eça de Queirós (novelist), Almeida Garrett (playwright and essayist), Antero de Quental (poet), and Joaquim Oliveira Martins (historian and social scientist). In its third overseas empire, Portugal attempted to replace the slave trade and slavery with legitimate economic activities; to reform the administration; and to expand Portuguese holdings beyond coastal footholds deep into the African hinterlands in West, West Central, and East Africa. After 1841, to some extent, and especially after 1870, colonial affairs, combined with intense nationalism, pressures for economic profit in Africa, sentiment for national revival, and the drift of European affairs would make or break Lisbon governments.Beginning with the political crisis that arose out of the "English Ultimatum" affair of January 1890, the monarchy became discredtted and identified with the poorly functioning government, political parties splintered, and republicanism found more supporters. Portugal participated in the "Scramble for Africa," expanding its African holdings, but failed to annex territory connecting Angola and Mozambique. A growing foreign debt and state bankruptcy as of the early 1890s damaged the constitutional monarchy's reputation, despite the efforts of King Carlos in diplomacy, the renewal of the alliance in the Windsor Treaty of 1899, and the successful if bloody colonial wars in the empire (1880-97). Republicanism proclaimed that Portugal's weak economy and poor society were due to two historic institutions: the monarchy and the Catholic Church. A republic, its stalwarts claimed, would bring greater individual liberty; efficient, if more decentralized government; and a stronger colonial program while stripping the Church of its role in both society and education.As the monarchy lost support and republicans became more aggressive, violence increased in politics. King Carlos I and his heir Luís were murdered in Lisbon by anarchist-republicans on 1 February 1908. Following a military and civil insurrection and fighting between monarchist and republican forces, on 5 October 1910, King Manuel II fled Portugal and a republic was proclaimed.First Parliamentary Republic, 1910-26Portugal's first attempt at republican government was the most unstable, turbulent parliamentary republic in the history of 20th-century Western Europe. During a little under 16 years of the republic, there were 45 governments, a number of legislatures that did not complete normal terms, military coups, and only one president who completed his four-year term in office. Portuguese society was poorly prepared for this political experiment. Among the deadly legacies of the monarchy were a huge public debt; a largely rural, apolitical, and illiterate peasant population; conflict over the causes of the country's misfortunes; and lack of experience with a pluralist, democratic system.The republic had some talented leadership but lacked popular, institutional, and economic support. The 1911 republican constitution established only a limited democracy, as only a small portion of the adult male citizenry was eligible to vote. In a country where the majority was Catholic, the republic passed harshly anticlerical laws, and its institutions and supporters persecuted both the Church and its adherents. During its brief disjointed life, the First Republic drafted important reform plans in economic, social, and educational affairs; actively promoted development in the empire; and pursued a liberal, generous foreign policy. Following British requests for Portugal's assistance in World War I, Portugal entered the war on the Allied side in March 1916 and sent armies to Flanders and Portuguese Africa. Portugal's intervention in that conflict, however, was too costly in many respects, and the ultimate failure of the republic in part may be ascribed to Portugal's World War I activities.Unfortunately for the republic, its time coincided with new threats to Portugal's African possessions: World War I, social and political demands from various classes that could not be reconciled, excessive military intervention in politics, and, in particular, the worst economic and financial crisis Portugal had experienced since the 16th and 17th centuries. After the original Portuguese Republican Party (PRP, also known as the "Democrats") splintered into three warring groups in 1912, no true multiparty system emerged. The Democrats, except for only one or two elections, held an iron monopoly of electoral power, and political corruption became a major issue. As extreme right-wing dictatorships elsewhere in Europe began to take power in Italy (1922), neighboring Spain (1923), and Greece (1925), what scant popular support remained for the republic collapsed. Backed by a right-wing coalition of landowners from Alentejo, clergy, Coimbra University faculty and students, Catholic organizations, and big business, career military officers led by General Gomes da Costa executed a coup on 28 May 1926, turned out the last republican government, and established a military government.The Estado Novo (New State), 1926-74During the military phase (1926-32) of the Estado Novo, professional military officers, largely from the army, governed and administered Portugal and held key cabinet posts, but soon discovered that the military possessed no magic formula that could readily solve the problems inherited from the First Republic. Especially during the years 1926-31, the military dictatorship, even with its political repression of republican activities and institutions (military censorship of the press, political police action, and closure of the republic's rowdy parliament), was characterized by similar weaknesses: personalism and factionalism; military coups and political instability, including civil strife and loss of life; state debt and bankruptcy; and a weak economy. "Barracks parliamentarism" was not an acceptable alternative even to the "Nightmare Republic."Led by General Óscar Carmona, who had replaced and sent into exile General Gomes da Costa, the military dictatorship turned to a civilian expert in finance and economics to break the budget impasse and bring coherence to the disorganized system. Appointed minister of finance on 27 April 1928, the Coimbra University Law School professor of economics Antônio de Oliveira Salazar (1889-1970) first reformed finance, helped balance the budget, and then turned to other concerns as he garnered extraordinary governing powers. In 1930, he was appointed interim head of another key ministry (Colonies) and within a few years had become, in effect, a civilian dictator who, with the military hierarchy's support, provided the government with coherence, a program, and a set of policies.For nearly 40 years after he was appointed the first civilian prime minister in 1932, Salazar's personality dominated the government. Unlike extreme right-wing dictators elsewhere in Europe, Salazar was directly appointed by the army but was never endorsed by a popular political party, street militia, or voter base. The scholarly, reclusive former Coimbra University professor built up what became known after 1932 as the Estado Novo ("New State"), which at the time of its overthrow by another military coup in 1974, was the longest surviving authoritarian regime in Western Europe. The system of Salazar and the largely academic and technocratic ruling group he gathered in his cabinets was based on the central bureaucracy of the state, which was supported by the president of the republic—always a senior career military officer, General Óscar Carmona (1928-51), General Craveiro Lopes (1951-58), and Admiral Américo Tómaz (1958-74)—and the complicity of various institutions. These included a rubber-stamp legislature called the National Assembly (1935-74) and a political police known under various names: PVDE (1932-45), PIDE (1945-69),and DGS (1969-74). Other defenders of the Estado Novo security were paramilitary organizations such as the National Republican Guard (GNR); the Portuguese Legion (PL); and the Portuguese Youth [Movement]. In addition to censorship of the media, theater, and books, there was political repression and a deliberate policy of depoliticization. All political parties except for the approved movement of regime loyalists, the União Nacional or (National Union), were banned.The most vigorous and more popular period of the New State was 1932-44, when the basic structures were established. Never monolithic or entirely the work of one person (Salazar), the New State was constructed with the assistance of several dozen top associates who were mainly academics from law schools, some technocrats with specialized skills, and a handful of trusted career military officers. The 1933 Constitution declared Portugal to be a "unitary, corporative Republic," and pressures to restore the monarchy were resisted. Although some of the regime's followers were fascists and pseudofascists, many more were conservative Catholics, integralists, nationalists, and monarchists of different varieties, and even some reactionary republicans. If the New State was authoritarian, it was not totalitarian and, unlike fascism in Benito Mussolini's Italy or Adolf Hitler's Germany, it usually employed the minimum of violence necessary to defeat what remained a largely fractious, incoherent opposition.With the tumultuous Second Republic and the subsequent civil war in nearby Spain, the regime felt threatened and reinforced its defenses. During what Salazar rightly perceived as a time of foreign policy crisis for Portugal (1936-45), he assumed control of the Ministry of Foreign Affairs. From there, he pursued four basic foreign policy objectives: supporting the Nationalist rebels of General Francisco Franco in the Spanish Civil War (1936-39) and concluding defense treaties with a triumphant Franco; ensuring that General Franco in an exhausted Spain did not enter World War II on the Axis side; maintaining Portuguese neutrality in World War II with a post-1942 tilt toward the Allies, including granting Britain and the United States use of bases in the Azores Islands; and preserving and protecting Portugal's Atlantic Islands and its extensive, if poor, overseas empire in Africa and Asia.During the middle years of the New State (1944-58), many key Salazar associates in government either died or resigned, and there was greater social unrest in the form of unprecedented strikes and clandestine Communist activities, intensified opposition, and new threatening international pressures on Portugal's overseas empire. During the earlier phase of the Cold War (1947-60), Portugal became a steadfast, if weak, member of the US-dominated North Atlantic Treaty Organization alliance and, in 1955, with American support, Portugal joined the United Nations (UN). Colonial affairs remained a central concern of the regime. As of 1939, Portugal was the third largest colonial power in the world and possessed territories in tropical Africa (Angola, Mozambique, Guinea-Bissau, and São Tomé and Príncipe Islands) and the remnants of its 16th-century empire in Asia (Goa, Damão, Diu, East Timor, and Macau). Beginning in the early 1950s, following the independence of India in 1947, Portugal resisted Indian pressures to decolonize Portuguese India and used police forces to discourage internal opposition in its Asian and African colonies.The later years of the New State (1958-68) witnessed the aging of the increasingly isolated but feared Salazar and new threats both at home and overseas. Although the regime easily overcame the brief oppositionist threat from rival presidential candidate General Humberto Delgado in the spring of 1958, new developments in the African and Asian empires imperiled the authoritarian system. In February 1961, oppositionists hijacked the Portuguese ocean liner Santa Maria and, in following weeks, African insurgents in northern Angola, although they failed to expel the Portuguese, gained worldwide media attention, discredited the New State, and began the 13-year colonial war. After thwarting a dissident military coup against his continued leadership, Salazar and his ruling group mobilized military repression in Angola and attempted to develop the African colonies at a faster pace in order to ensure Portuguese control. Meanwhile, the other European colonial powers (Britain, France, Belgium, and Spain) rapidly granted political independence to their African territories.At the time of Salazar's removal from power in September 1968, following a stroke, Portugal's efforts to maintain control over its colonies appeared to be successful. President Americo Tomás appointed Dr. Marcello Caetano as Salazar's successor as prime minister. While maintaining the New State's basic structures, and continuing the regime's essential colonial policy, Caetano attempted wider reforms in colonial administration and some devolution of power from Lisbon, as well as more freedom of expression in Lisbon. Still, a great deal of the budget was devoted to supporting the wars against the insurgencies in Africa. Meanwhile in Asia, Portuguese India had fallen when the Indian army invaded in December 1961. The loss of Goa was a psychological blow to the leadership of the New State, and of the Asian empire only East Timor and Macau remained.The Caetano years (1968-74) were but a hiatus between the waning Salazar era and a new regime. There was greater political freedom and rapid economic growth (5-6 percent annually to late 1973), but Caetano's government was unable to reform the old system thoroughly and refused to consider new methods either at home or in the empire. In the end, regime change came from junior officers of the professional military who organized the Armed Forces Movement (MFA) against the Caetano government. It was this group of several hundred officers, mainly in the army and navy, which engineered a largely bloodless coup in Lisbon on 25 April 1974. Their unexpected action brought down the 48-year-old New State and made possible the eventual establishment and consolidation of democratic governance in Portugal, as well as a reorientation of the country away from the Atlantic toward Europe.Revolution of Carnations, 1974-76Following successful military operations of the Armed Forces Movement against the Caetano government, Portugal experienced what became known as the "Revolution of Carnations." It so happened that during the rainy week of the military golpe, Lisbon flower shops were featuring carnations, and the revolutionaries and their supporters adopted the red carnation as the common symbol of the event, as well as of the new freedom from dictatorship. The MFA, whose leaders at first were mostly little-known majors and captains, proclaimed a three-fold program of change for the new Portugal: democracy; decolonization of the overseas empire, after ending the colonial wars; and developing a backward economy in the spirit of opportunity and equality. During the first 24 months after the coup, there was civil strife, some anarchy, and a power struggle. With the passing of the Estado Novo, public euphoria burst forth as the new provisional military government proclaimed the freedoms of speech, press, and assembly, and abolished censorship, the political police, the Portuguese Legion, Portuguese Youth, and other New State organizations, including the National Union. Scores of political parties were born and joined the senior political party, the Portuguese Community Party (PCP), and the Socialist Party (PS), founded shortly before the coup.Portugal's Revolution of Carnations went through several phases. There was an attempt to take control by radical leftists, including the PCP and its allies. This was thwarted by moderate officers in the army, as well as by the efforts of two political parties: the PS and the Social Democrats (PPD, later PSD). The first phase was from April to September 1974. Provisional president General Antonio Spínola, whose 1974 book Portugal and the Future had helped prepare public opinion for the coup, met irresistible leftist pressures. After Spinola's efforts to avoid rapid decolonization of the African empire failed, he resigned in September 1974. During the second phase, from September 1974 to March 1975, radical military officers gained control, but a coup attempt by General Spínola and his supporters in Lisbon in March 1975 failed and Spínola fled to Spain.In the third phase of the Revolution, March-November 1975, a strong leftist reaction followed. Farm workers occupied and "nationalized" 1.1 million hectares of farmland in the Alentejo province, and radical military officers in the provisional government ordered the nationalization of Portuguese banks (foreign banks were exempted), utilities, and major industries, or about 60 percent of the economic system. There were power struggles among various political parties — a total of 50 emerged—and in the streets there was civil strife among labor, military, and law enforcement groups. A constituent assembly, elected on 25 April 1975, in Portugal's first free elections since 1926, drafted a democratic constitution. The Council of the Revolution (CR), briefly a revolutionary military watchdog committee, was entrenched as part of the government under the constitution, until a later revision. During the chaotic year of 1975, about 30 persons were killed in political frays while unstable provisional governments came and went. On 25 November 1975, moderate military forces led by Colonel Ramalho Eanes, who later was twice elected president of the republic (1976 and 1981), defeated radical, leftist military groups' revolutionary conspiracies.In the meantime, Portugal's scattered overseas empire experienced a precipitous and unprepared decolonization. One by one, the former colonies were granted and accepted independence—Guinea-Bissau (September 1974), Cape Verde Islands (July 1975), and Mozambique (July 1975). Portugal offered to turn over Macau to the People's Republic of China, but the offer was refused then and later negotiations led to the establishment of a formal decolonization or hand-over date of 1999. But in two former colonies, the process of decolonization had tragic results.In Angola, decolonization negotiations were greatly complicated by the fact that there were three rival nationalist movements in a struggle for power. The January 1975 Alvor Agreement signed by Portugal and these three parties was not effectively implemented. A bloody civil war broke out in Angola in the spring of 1975 and, when Portuguese armed forces withdrew and declared that Angola was independent on 11 November 1975, the bloodshed only increased. Meanwhile, most of the white Portuguese settlers from Angola and Mozambique fled during the course of 1975. Together with African refugees, more than 600,000 of these retornados ("returned ones") went by ship and air to Portugal and thousands more to Namibia, South Africa, Brazil, Canada, and the United States.The second major decolonization disaster was in Portugal's colony of East Timor in the Indonesian archipelago. Portugal's capacity to supervise and control a peaceful transition to independence in this isolated, neglected colony was limited by the strength of giant Indonesia, distance from Lisbon, and Portugal's revolutionary disorder and inability to defend Timor. In early December 1975, before Portugal granted formal independence and as one party, FRETILIN, unilaterally declared East Timor's independence, Indonesia's armed forces invaded, conquered, and annexed East Timor. Indonesian occupation encountered East Timorese resistance, and a heavy loss of life followed. The East Timor question remained a contentious international issue in the UN, as well as in Lisbon and Jakarta, for more than 20 years following Indonesia's invasion and annexation of the former colony of Portugal. Major changes occurred, beginning in 1998, after Indonesia underwent a political revolution and allowed a referendum in East Timor to decide that territory's political future in August 1999. Most East Timorese chose independence, but Indonesian forces resisted that verdict untilUN intervention in September 1999. Following UN rule for several years, East Timor attained full independence on 20 May 2002.Consolidation of Democracy, 1976-2000After several free elections and record voter turnouts between 25 April 1975 and June 1976, civil war was averted and Portugal's second democratic republic began to stabilize. The MFA was dissolved, the military were returned to the barracks, and increasingly elected civilians took over the government of the country. The 1976 Constitution was revised several times beginning in 1982 and 1989, in order to reempha-size the principle of free enterprise in the economy while much of the large, nationalized sector was privatized. In June 1976, General Ram-alho Eanes was elected the first constitutional president of the republic (five-year term), and he appointed socialist leader Dr. Mário Soares as prime minister of the first constitutional government.From 1976 to 1985, Portugal's new system featured a weak economy and finances, labor unrest, and administrative and political instability. The difficult consolidation of democratic governance was eased in part by the strong currency and gold reserves inherited from the Estado Novo, but Lisbon seemed unable to cope with high unemployment, new debt, the complex impact of the refugees from Africa, world recession, and the agitation of political parties. Four major parties emerged from the maelstrom of 1974-75, except for the Communist Party, all newly founded. They were, from left to right, the Communists (PCP); the Socialists (PS), who managed to dominate governments and the legislature but not win a majority in the Assembly of the Republic; the Social Democrats (PSD); and the Christian Democrats (CDS). During this period, the annual growth rate was low (l-2 percent), and the nationalized sector of the economy stagnated.Enhanced economic growth, greater political stability, and more effective central government as of 1985, and especially 1987, were due to several developments. In 1977, Portugal applied for membership in the European Economic Community (EEC), now the European Union (EU) since 1993. In January 1986, with Spain, Portugal was granted membership, and economic and financial progress in the intervening years has been significantly influenced by the comparatively large investment, loans, technology, advice, and other assistance from the EEC. Low unemployment, high annual growth rates (5 percent), and moderate inflation have also been induced by the new political and administrative stability in Lisbon. Led by Prime Minister Cavaco Silva, an economist who was trained abroad, the PSD's strong organization, management, and electoral support since 1985 have assisted in encouraging economic recovery and development. In 1985, the PSD turned the PS out of office and won the general election, although they did not have an absolute majority of assembly seats. In 1986, Mário Soares was elected president of the republic, the first civilian to hold that office since the First Republic. In the elections of 1987 and 1991, however, the PSD was returned to power with clear majorities of over 50 percent of the vote.Although the PSD received 50.4 percent of the vote in the 1991 parliamentary elections and held a 42-seat majority in the Assembly of the Republic, the party began to lose public support following media revelations regarding corruption and complaints about Prime Minister Cavaco Silva's perceived arrogant leadership style. President Mário Soares voiced criticism of the PSD's seemingly untouchable majority and described a "tyranny of the majority." Economic growth slowed down. In the parliamentary elections of 1995 and the presidential election of 1996, the PSD's dominance ended for the time being. Prime Minister Antônio Guterres came to office when the PS won the October 1995 elections, and in the subsequent presidential contest, in January 1996, socialist Jorge Sampaio, the former mayor of Lisbon, was elected president of the republic, thus defeating Cavaco Silva's bid. Young and popular, Guterres moved the PS toward the center of the political spectrum. Under Guterres, the PS won the October 1999 parliamentary elections. The PS defeated the PSD but did not manage to win a clear, working majority of seats, and this made the PS dependent upon alliances with smaller parties, including the PCP.In the local elections in December 2001, the PSD's criticism of PS's heavy public spending allowed the PSD to take control of the key cities of Lisbon, Oporto, and Coimbra. Guterres resigned, and parliamentary elections were brought forward from 2004 to March 2002. The PSD won a narrow victory with 40 percent of the votes, and Jose Durão Barroso became prime minister. Having failed to win a majority of the seats in parliament forced the PSD to govern in coalition with the right-wing Popular Party (PP) led by Paulo Portas. Durão Barroso set about reducing government spending by cutting the budgets of local authorities, freezing civil service hiring, and reviving the economy by accelerating privatization of state-owned enterprises. These measures provoked a 24-hour strike by public-sector workers. Durão Barroso reacted with vows to press ahead with budget-cutting measures and imposed a wage freeze on all employees earning more than €1,000, which affected more than one-half of Portugal's work force.In June 2004, Durão Barroso was invited by Romano Prodi to succeed him as president of the European Commission. Durão Barroso accepted and resigned the prime ministership in July. Pedro Santana Lopes, the leader of the PSD, became prime minister. Already unpopular at the time of Durão Barroso's resignation, the PSD-led government became increasingly unpopular under Santana Lopes. A month-long delay in the start of the school year and confusion over his plan to cut taxes and raise public-sector salaries, eroded confidence even more. By November, Santana Lopes's government was so unpopular that President Jorge Sampaio was obliged to dissolve parliament and hold new elections, two years ahead of schedule.Parliamentary elections were held on 20 February 2005. The PS, which had promised the electorate disciplined and transparent governance, educational reform, the alleviation of poverty, and a boost in employment, won 45 percent of the vote and the majority of the seats in parliament. The leader of the PS, José Sôcrates became prime minister on 12 March 2005. In the regularly scheduled presidential elections held on 6 January 2006, the former leader of the PSD and prime minister, Aníbal Cavaco Silva, won a narrow victory and became president on 9 March 2006. With a mass protest, public teachers' strike, and street demonstrations in March 2008, Portugal's media, educational, and social systems experienced more severe pressures. With the spreading global recession beginning in September 2008, Portugal's economic and financial systems became more troubled.Owing to its geographic location on the southwestern most edge of continental Europe, Portugal has been historically in but not of Europe. Almost from the beginning of its existence in the 12th century as an independent monarchy, Portugal turned its back on Europe and oriented itself toward the Atlantic Ocean. After carving out a Christian kingdom on the western portion of the Iberian peninsula, Portuguese kings gradually built and maintained a vast seaborne global empire that became central to the way Portugal understood its individuality as a nation-state. While the creation of this empire allows Portugal to claim an unusual number of "firsts" or distinctions in world and Western history, it also retarded Portugal's economic, social, and political development. It can be reasonably argued that the Revolution of 25 April 1974 was the most decisive event in Portugal's long history because it finally ended Portugal's oceanic mission and view of itself as an imperial power. After the 1974 Revolution, Portugal turned away from its global mission and vigorously reoriented itself toward Europe. Contemporary Portugal is now both in and of Europe.The turn toward Europe began immediately after 25 April 1974. Portugal granted independence to its African colonies in 1975. It was admitted to the European Council and took the first steps toward accession to the European Economic Community (EEC) in 1976. On 28 March 1977, the Portuguese government officially applied for EEC membership. Because of Portugal's economic and social backwardness, which would require vast sums of EEC money to overcome, negotiations for membership were long and difficult. Finally, a treaty of accession was signed on 12 June 1985. Portugal officially joined the EEC (the European Union [EU] since 1993) on 1 January 1986. Since becoming a full-fledged member of the EU, Portugal has been steadily overcoming the economic and social underdevelopment caused by its imperial past and is becoming more like the rest of Europe.Membership in the EU has speeded up the structural transformation of Portugal's economy, which actually began during the Estado Novo. Investments made by the Estado Novo in Portugal's economy began to shift employment out of the agricultural sector, which, in 1950, accounted for 50 percent of Portugal's economically active population. Today, only 10 percent of the economically active population is employed in the agricultural sector (the highest among EU member states); 30 percent in the industrial sector (also the highest among EU member states); and 60 percent in the service sector (the lowest among EU member states). The economically active population numbers about 5,000,000 employed, 56 percent of whom are women. Women workers are the majority of the workforce in the agricultural and service sectors (the highest among the EU member states). The expansion of the service sector has been primarily in health care and education. Portugal has had the lowest unemployment rates among EU member states, with the overall rate never being more than 10 percent of the active population. Since joining the EU, the number of employers increased from 2.6 percent to 5.8 percent of the active population; self-employed from 16 to 19 percent; and employees from 65 to 70 percent. Twenty-six percent of the employers are women. Unemployment tends to hit younger workers in industry and transportation, women employed in domestic service, workers on short-term contracts, and poorly educated workers. Salaried workers earn only 63 percent of the EU average, and hourly workers only one-third to one-half of that earned by their EU counterparts. Despite having had the second highest growth of gross national product (GNP) per inhabitant (after Ireland) among EU member states, the above data suggest that while much has been accomplished in terms of modernizing the Portuguese economy, much remains to be done to bring Portugal's economy up to the level of the "average" EU member state.Membership in the EU has also speeded up changes in Portuguese society. Over the last 30 years, coastalization and urbanization have intensified. Fully 50 percent of Portuguese live in the coastal urban conurbations of Lisbon, Oporto, Braga, Aveiro, Coimbra, Viseu, Évora, and Faro. The Portuguese population is one of the oldest among EU member states (17.3 percent are 65 years of age or older) thanks to a considerable increase in life expectancy at birth (77.87 years for the total population, 74.6 years for men, 81.36 years for women) and one of the lowest birthrates (10.59 births/1,000) in Europe. Family size averages 2.8 persons per household, with the strict nuclear family (one or two generations) in which both parents work being typical. Common law marriages, cohabitating couples, and single-parent households are more and more common. The divorce rate has also increased. "Youth Culture" has developed. The young have their own meeting places, leisure-time activities, and nightlife (bars, clubs, and discos).All Portuguese citizens, whether they have contributed or not, have a right to an old-age pension, invalidity benefits, widowed persons' pension, as well as payments for disabilities, children, unemployment, and large families. There is a national minimum wage (€385 per month), which is low by EU standards. The rapid aging of Portugal's population has changed the ratio of contributors to pensioners to 1.7, the lowest in the EU. This has created deficits in Portugal's social security fund.The adult literacy rate is about 92 percent. Illiteracy is still found among the elderly. Although universal compulsory education up to grade 9 was achieved in 1980, only 21.2 percent of the population aged 25-64 had undergone secondary education, compared to an EU average of 65.7 percent. Portugal's higher education system currently consists of 14 state universities and 14 private universities, 15 state polytechnic institutions, one Catholic university, and one military academy. All in all, Portugal spends a greater percentage of its state budget on education than most EU member states. Despite this high level of expenditure, the troubled Portuguese education system does not perform well. Early leaving and repetition rates are among the highest among EU member states.After the Revolution of 25 April 1974, Portugal created a National Health Service, which today consists of 221 hospitals and 512 medical centers employing 33,751 doctors and 41,799 nurses. Like its education system, Portugal's medical system is inefficient. There are long waiting lists for appointments with specialists and for surgical procedures.Structural changes in Portugal's economy and society mean that social life in Portugal is not too different from that in other EU member states. A mass consumption society has been created. Televisions, telephones, refrigerators, cars, music equipment, mobile phones, and personal computers are commonplace. Sixty percent of Portuguese households possess at least one automobile, and 65 percent of Portuguese own their own home. Portuguese citizens are more aware of their legal rights than ever before. This has resulted in a trebling of the number of legal proceeding since 1960 and an eight-fold increase in the number of lawyers. In general, Portuguese society has become more permissive and secular; the Catholic Church and the armed forces are much less influential than in the past. Portugal's population is also much more culturally, religiously, and ethnically diverse, a consequence of the coming to Portugal of hundreds of thousands of immigrants, mainly from former African colonies.Portuguese are becoming more cosmopolitan and sophisticated through the impact of world media, the Internet, and the World Wide Web. A prime case in point came in the summer and early fall of 1999, with the extraordinary events in East Timor and the massive Portuguese popular responses. An internationally monitored referendum in East Timor, Portugal's former colony in the Indonesian archipelago and under Indonesian occupation from late 1975 to summer 1999, resulted in a vote of 78.5 percent for rejecting integration with Indonesia and for independence. When Indonesian prointegration gangs, aided by the Indonesian military, responded to the referendum with widespread brutality and threatened to reverse the verdict of the referendum, there was a spontaneous popular outpouring of protest in the cities and towns of Portugal. An avalanche of Portuguese e-mail fell on leaders and groups in the UN and in certain countries around the world as Portugal's diplomats, perhaps to compensate for the weak initial response to Indonesian armed aggression in 1975, called for the protection of East Timor as an independent state and for UN intervention to thwart Indonesian action. Using global communications networks, the Portuguese were able to mobilize UN and world public opinion against Indonesian actions and aided the eventual independence of East Timor on 20 May 2002.From the Revolution of 25 April 1974 until the 1990s, Portugal had a large number of political parties, one of the largest Communist parties in western Europe, frequent elections, and endemic cabinet instability. Since the 1990s, the number of political parties has been dramatically reduced and cabinet stability increased. Gradually, the Portuguese electorate has concentrated around two larger parties, the right-of-center Social Democrats (PSD) and the left-of-center Socialist (PS). In the 1980s, these two parties together garnered 65 percent of the vote and 70 percent of the seats in parliament. In 2005, these percentages had risen to 74 percent and 85 percent, respectively. In effect, Portugal is currently a two-party dominant system in which the two largest parties — PS and PSD—alternate in and out of power, not unlike the rotation of the two main political parties (the Regenerators and the Historicals) during the last decades (1850s to 1880s) of the liberal constitutional monarchy. As Portugal's democracy has consolidated, turnout rates for the eligible electorate have declined. In the 1970s, turnout was 85 percent. In Portugal's most recent parliamentary election (2005), turnout had fallen to 65 percent of the eligible electorate.Portugal has benefited greatly from membership in the EU, and whatever doubts remain about the price paid for membership, no Portuguese government in the near future can afford to sever this connection. The vast majority of Portuguese citizens see membership in the EU as a "good thing" and strongly believe that Portugal has benefited from membership. Only the Communist Party opposed membership because it reduces national sovereignty, serves the interests of capitalists not workers, and suffers from a democratic deficit. Despite the high level of support for the EU, Portuguese voters are increasingly not voting in elections for the European Parliament, however. Turnout for European Parliament elections fell from 40 percent of the eligible electorate in the 1999 elections to 38 percent in the 2004 elections.In sum, Portugal's turn toward Europe has done much to overcome its backwardness. However, despite the economic, social, and political progress made since 1986, Portugal has a long way to go before it can claim to be on a par with the level found even in Spain, much less the rest of western Europe. As Portugal struggles to move from underde-velopment, especially in the rural areas away from the coast, it must keep in mind the perils of too rapid modern development, which could damage two of its most precious assets: its scenery and environment. The growth and future prosperity of the economy will depend on the degree to which the government and the private sector will remain stewards of clean air, soil, water, and other finite resources on which the tourism industry depends and on which Portugal's world image as a unique place to visit rests. Currently, Portugal is investing heavily in renewable energy from solar, wind, and wave power in order to account for about 50 percent of its electricity needs by 2010. Portugal opened the world's largest solar power plant and the world's first commercial wave power farm in 2006.An American documentary film on Portugal produced in the 1970s described this little country as having "a Past in Search of a Future." In the years after the Revolution of 25 April 1974, it could be said that Portugal is now living in "a Present in Search of a Future." Increasingly, that future lies in Europe as an active and productive member of the EU.СтраницыСм. также в других словарях:
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