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61 automatic
автоматический аппарат; II автоматический; самодействующий; автоматизированный- automatic acceleration control unit - automatic accumulator charging - automatic action - automatic adjustment - automatic adjustment mechanism - automatic advance control - automatic air regulator - automatic alarm - automatic alarm signal transmitter - automatic alternation - automatic amplitude control - automatic arc welding - automatic arc welding machine - automatic arc-welding machine - automatic assemblage - automatic assembly - automatic assembly machine - automatic backing-up - automatic backlash control - automatic backup - automatic balance control - automatic balancer - automatic balancing - automatic bar fed turning center - automatic bar feed - automatic bias control - automatic block - automatic bonding unit - automatic brake - automatic brake adjuster - automatic brake arrangement - automatic brake controller - automatic braking - automatic braking system - automatic brazing equipment - automatic buffing machine - automatic burette - automatic butt splicer - automatic calibration - automatic cam-controlled machine - automatic cathead - automatic centering - automatic chain-bending machine - automatic change of tools - automatic change-over - automatic change-over switch - automatic check - automatic check-out recording equipment - automatic checking balance - automatic checking machine - automatic checkout equipment - automatic checkout system - automatic checkout-and-readiness equipment - automatic choke - automatic chuck - automatic chuck extractor - automatic chuck-changing system - automatic chuck jaw changing - automatic chucker - automatic circuit - automatic circuit breaker - automatic circuit recloser - automatic climate control system - automatic closing system - automatic clutch - automatic cold upsetter - automatic come-along clamp - automatic compensation option - automatic compensator - automatic consistency checking - automatic constant tension mooring winch - automatic control - automatic control actuator - automatic control channel - automatic control circuit - automatic control engineering - automatic control equipment - automatic control halting instruction - automatic control installation - automatic control loop - automatic control rod - automatic control system - automatic controller - automatic conveying - automatic coupler - automatic coupling - automatic coupling device - automatic coupling screwing unit - automatic crab winch - automatic crimper - automatic crossover - automatic cut-out torque wrench - automatic cutout - automatic cycle - automatic cycle mechanism - automatic cycle working - automatic cycling equipment - automatic data analyzer - automatic data distribution - automatic data entry - automatic data processing - automatic data processing field branch - automatic data unit - automatic datum search - automatic deicing system - automatic device - automatic diagnosis - automatic diagnostic-and-recovery system - automatic discharging device - automatic disk changer - automatic door - automatic door closer - automatic door photoelectric relay - automatic drilling control - automatic drilling rig - automatic drinking bowl - automatic drive - automatic drive detection - automatic drive engagement - automatic dump - automatic-dump truck - automatic dust ejector - automatic dust unloading valve - automatic ejection - automatic electric drive - electrical drive - automatic electrode changer - automatic elevator - automatic emergency valve - automatic end stop - automatic error correction - automatic error detection - automatic exchange of tools - automatic expansion valve - automatic fault detection - automatic fault finding - automatic fault isolation - automatic fault isolation tester - automatic fault reporting - automatic fault signalling - automatic feature - automatic feed - automatic feed drill - automatic feed-off mechanism - automatic feeder - automatic feeding mechanism - automatic feedoff - automatic fire alarm - automatic fire alarm system - automatic fire annunciator - automatic fire detector - automatic fire sprinkler - automatic fixturing system - automatic flanger - automatic float-type pump-out unit - automatic flour meter - automatic flow tank - automatic focus correction servo-system - automatic forging machine - automatic front wheel drive engagement - automatic fuel economizing device - automatic fuel-control unit - automatic fuel saving device - automatic fuel shut-off - automatic fuse - automatic gage - automatic gaging-and-compensating system - automatic gain adjustment - automatic gain control - automatic gas-cutting machine - automatic gas-welding machine - automatic gate - automatic gate closer - automatic gate opener - automatic gauging - automatic gearbox - automatic generating plant - automatic generator - automatic grab - automatic gripper change - automatic gripper control - automatic guided vehicle - automatic half-hose machine - automatic heater - automatic hill holder - automatic hinged trip spider - automatic hitch - automatic holding - automatic holding device - automatic hopper-feed machine - automatic humidity regulator - automatic identification- Auto-ID- AIS - automatic idling control - automatic ignition - automatic ignition system - automatic ignition timing - automatic input - automatic insertion - automatic interlocking - automatic internal diagnosis - automatic jaw changer - automatic jaw shift device - automatic latching - automatic level - automatic level compensation - automatic level control - automatic level control system - automatic level gauge - automatic level setup - automatic leveling control system - automatic light - automatic light control - automatic light regulation - automatic line - automatic line disconnection - automatic line switching - ALS - automatic load control - automatic load sustaining brake - automatic load-gripping device - automatic loader - automatic loading - automatic lock - automatic locking - automatic locking holder - automatic locking hub - automatic locking spindle - automatic lockout - automatic lockout feature - automatic lubrication - automatic lubricator - automatic machine cycle - automatic magazine bar feed - automatic maintenance - automatic manipulator - automatic measurement-and-compensation system - automatic measuring facilities - automatic metal forming machine - automatic mixture control - automatic mode switching - automatic moisture regulator - automatic monitoring - automatic motor control gear - automatic movements starting - automatic multicam machine - automatic noise limiter - automatic noise-reduction system - automatic oil-flow controller - automatic oiling - automatic opening circuit breaker - automatic opening cover - automatic optimization - automatic overload control - automatic overload limiter - automatic overload stop - automatic packing - automatic pallet handler - automatic pallet storage-retrieval system - automatic part gaging - automatic part-loading conveyor - automatic photodetector - automatic pipe handling system - automatic pipe stabber - automatic placement - automatic plant - automatic polishing machine - automatic positioning - automatic power control - automatic power drawbar control - automatic power rotary scraper - automatic power slips - automatic press for cold pressing of nuts - automatic press for stamping electric motor stator and rotor notches - automatic pressure control - automatic pressure regulator - automatic probe changer - automatic probe changing - automatic probing cycle - automatic punch - automatic rack stacker - automatic radiator shutter - automatic ram pile driver - automatic reading - automatic reclosing circuit breaker - automatic recovery - automatic recovery program - automatic regulation - automatic regulation of belt tension - automatic regulation of drive chain tension - automatic regulation rod - automatic regulator - automatic release - automatic releaser - automatic repeat - automatic remote control - automatic reset - automatic reset-data circuit - automatic restart - automatic return - automatic return valve - automatic rotary line - automatic router - automatic routine - automatic rpm changer - automatic safety device - automatic sample changer - automatic sampler - automatic sampling - automatic sampling device - automatic sampling equipment - automatic sand-blasting machine - automatic scales - automatic screen - automatic selective overdrive - automatic sensitivity control - automatic set point - automatic shaft-position data encoder - automatic shaker bag - automatic shank spindle - automatic shift - automatic shut-off valve - automatic shutdown - automatic side-dumping - automatic signaling - automatic signalization - automatic size control tooling - automatic sorting machine - automatic spark advance - automatic spark advance governor - automatic spark advance magneto - automatic spark timer - automatic spectrometer - automatic spectrophotometer - automatic speed compensation - automatic speed control - automatic speed selection device - automatic spider - automatic spindle gear changing - automatic sprinkler fire control system - automatic stability - automatic stability controls - automatic stabilization and control system - automatic stabilizer - automatic stacker crane - automatic start - automatic starting - automatic starting motor - automatic start-up - automatic steel - automatic steering - automatic step selection - automatic stop - automatic stop switch - automatic straightening and cutting machine - automatic strip-straightening machine - automatic submerged-arc welder - automatic submerged-arc welding - automatic sucker rod spanner - automatic suction pump - automatic surveillance - automatic switch - automatic switchable redundance - automatic switchboard - automatic swivel spindle - automatic synchronization - automatic synchronizer - automatic takeup - automatic takeup mechanism - automatic temperature recording controller - automatic temperature regulator - automatic tensioning winch - automatic test analysis system - automatic test equipment - automatic test system - automatic thrust adjustment - automatic time switch - automatic time-delay switch - automatic timed magneto - automatic timer - automatic timing - automatic timing control - automatic timing device - automatic tipper - automatic tool changing apparatus - automatic tool transport mechanism - automatic tool wear-tool broken sensing system - automatic toolsetting - automatic tongs - automatic training idler - automatic transmission - automatic transmission fluid - automatic trip - automatic troubleshooting - automatic tuning - automatic two-speed geared head - automatic update - automatic vacuum deposition system - automatic valve - automatic valve adjustment - automatic viscosity controller - automatic voltage control - automatic voltage regulator - automatic warehousing - automatic warning - automatic washer - automatic water bowl - automatic water spray fire-fighting system - automatic weight controller - automatic weighing machine - automatic weigher - automatic weld - automatic welder - automatic welding - automatic welding machine - automatic wire feed - automatic workhandling - automatic workhandling device - automatic zero adjustment - automatic zero set -
62 work
- work
- n1. работа
2. изделие
3. обработка
4. возводимый объект (строительства) ( по подрядному договору); конструкция, сооружение
5. работа, мощность
6. pl сооружение, сооружения
7. pl завод, фабрика, мастерские
work above ground — наземные работы ( в отличие от подземных и подводных); работы, производимые на поверхности земли
work below ground ( level) — подземные работы
work carried out on site — работы, выполненные на стройплощадке
work done in sections — работа, выполненная отдельными секциями [частями]
work in open excavations — работы в открытых выемках [горных выработках]
work in progress — (строительные) работы в стадии выполнения, выполняемые [производимые] (строительные) работы; объект в стадии строительства
work in water — работы, производимые в воде [под водой]
work near water — работы, производимые близ водоёмов или рек
work on schedule — работы в процессе выполнения ( по графику); работы, предусмотренные планом [графиком]
- work of deformation
- work of external forces
- work of internal forces
- above-ground works
- additional work
- agricultural works
- alteration work
- ashlar work
- auxiliary work
- avalanche baffle works
- axed work
- backfill work
- backing masonry work
- bag work
- bench work
- block work
- brewery works
- brick work
- broken-color work
- brush work
- building work
- building site works
- carcass work
- carpenter's work
- cement works
- chemical production works
- civil engineering work
- coast protection works
- cob work
- completed work
- complicated building work
- concrete work
- concrete block masonry work
- concrete masonry work
- constructional work
- construction work
- continuous shift work
- contract work
- coursed work
- crib work
- day work
- dead work
- defective work
- defence works
- deformation work
- demolition work
- development work
- diver's works
- diversion works
- donkey work
- drainage works
- earth work
- earth-moving work
- elastic work of a material
- electric work
- electricity production works
- emergency work
- enclosed construction works
- engineering works
- erection work
- erosion protection works
- excavation works
- experimental work
- external work
- extra work
- facing work
- factory work
- fascine work
- finishing work
- finish work
- floating construction works
- flood-control works
- flood-protection works
- floor work
- floor-and-wall tiling work
- floor covering work
- food industry production work
- foundation work
- funerary works
- further day's work
- gas works
- gauged work
- glazed work
- glazier's work
- half-plain work
- hammered work
- hand work
- handy work
- heat insulation work
- heavy work
- highly mechanized work
- hot work
- in-fill masonry work
- innovative construction work
- insulating work
- intake works
- internal work in the system
- ironmongery work
- joinery work
- land retention works
- landslide protection works
- loading works
- manual work
- marine works
- metallurgical processing works
- night work
- nonconforming work
- office work
- off-the-site work
- one-coat work
- open-air intake works
- open construction works
- ornamental works
- ornate work
- outlet works
- overhang work
- overhead work
- permanent works up to ground level
- petroleum extraction works
- piece work
- pitched work
- plaster work
- plumbing work
- power production works
- precast works
- production works
- promotion work
- protection works
- protective works
- public works
- random ashlar work
- refurbishment work
- refuse disposal works
- refuse incineration works
- regulation works
- reinforced concrete work
- research work
- reticulated work
- road transport works
- roof tiling work
- rubble ashlar masonry work
- sanitary works
- sea defence works
- sediment exclusion works
- sewage disposal works
- single construction works
- smillage-axed work
- solid plaster work
- steel construction works
- steel works
- steel plate work
- structural restoration work
- surface transport works
- temporary works
- textile work
- three-coat work
- tiling work
- training works
- transport works
- treatment works
- two-coat work
- underground work
- underwater work
- unloading works
- vermiculated work
- virtual work
- waste disposal works
- water works
- water treatment works
Англо-русский строительный словарь. — М.: Русский Язык. С.Н.Корчемкина, С.К.Кашкина, С.В.Курбатова. 1995.
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63 Bateman, John Frederick La Trobe
[br]b. 30 May 1810 Lower Wyke, near Halifax, Yorkshire, Englandd. 10 June 1889 Moor Park, Farnham, Surrey, England[br]English civil engineer whose principal works were concerned with reservoirs, water-supply schemes and pipelines.[br]Bateman's maternal grandfather was a Moravian missionary, and from the age of 7 he was educated at the Moravian schools at Fairfield and Ockbrook. At the age of 15 he was apprenticed to a "civil engineer, land surveyor and agent" in Oldham. After this apprenticeship, Bateman commenced his own practice in 1833. One of his early schemes and reports was in regard to the flooding of the river Medlock in the Manchester area. He came to the attention of William Fairbairn, the engine builder and millwright of Canal Street, Ancoats, Manchester. Fairbairn used Bateman as his site surveyor and as such he prepared much of the groundwork for the Bann reservoirs in Northern Ireland. Whilst the reports on the proposals were in the name of Fairbairn, Bateman was, in fact, appointed by the company as their engineer for the execution of the works. One scheme of Bateman's which was carried forward was the Kendal Reservoirs. The Act for these was signed in 1845 and was implemented not for the purpose of water supply but for the conservation of water to supply power to the many mills which stood on the river Kent between Kentmere and Morecambe Bay. The Kentmere Head dam is the only one of the five proposed for the scheme to survive, although not all the others were built as they would have retained only small volumes of water.Perhaps the greatest monument to the work of J.F.La Trobe Bateman is Manchester's water supply; he was consulted about this in 1844, and construction began four years later. He first built reservoirs in the Longdendale valley, which has a very complicated geological stratification. Bateman favoured earth embankment dams and gravity feed rather than pumping; the five reservoirs in the valley that impound the river Etherow were complex, cored earth dams. However, when completed they were greatly at risk from landslips and ground movement. Later dams were inserted by Bateman to prevent water loss should the older dams fail. The scheme was not completed until 1877, by which time Manchester's population had exceeded the capacity of the original scheme; Thirlmere in Cumbria was chosen by Manchester Corporation as the site of the first of the Lake District water-supply schemes. Bateman, as Consulting Engineer, designed the great stone-faced dam at the west end of the lake, the "gothic" straining well in the middle of the east shore of the lake, and the 100-mile (160 km) pipeline to Manchester. The Act for the Thirlmere reservoir was signed in 1879 and, whilst Bateman continued as Consulting Engineer, the work was supervised by G.H. Hill and was completed in 1894.Bateman was also consulted by the authorities in Glasgow, with the result that he constructed an impressive water-supply scheme derived from Loch Katrine during the years 1856–60. It was claimed that the scheme bore comparison with "the most extensive aqueducts in the world, not excluding those of ancient Rome". Bateman went on to superintend the waterworks of many cities, mainly in the north of England but also in Dublin and Belfast. In 1865 he published a pamphlet, On the Supply of Water to London from the Sources of the River Severn, based on a survey funded from his own pocket; a Royal Commission examined various schemes but favoured Bateman's.Bateman was also responsible for harbour and dock works, notably on the rivers Clyde and Shannon, and also for a number of important water-supply works on the Continent of Europe and beyond. Dams and the associated reservoirs were the principal work of J.F.La Trobe Bateman; he completed forty-three such schemes during his professional career. He also prepared many studies of water-supply schemes, and appeared as professional witness before the appropriate Parliamentary Committees.[br]Principal Honours and DistinctionsFRS 1860. President, Institution of Civil Engineers 1878, 1879.BibliographyAmong his publications History and Description of the Manchester Waterworks, (1884, London), and The Present State of Our Knowledge on the Supply of Water to Towns, (1855, London: British Association for the Advancement of Science) are notable.Further ReadingObituary, 1889, Minutes of the Proceedings of the Institution of Civil Engineers 97:392– 8.Obituary, 1889, Proceedings of the Royal Society 46:xlii-xlviii. G.M.Binnie, 1981, Early Victorian Water Engineers, London.P.N.Wilson, 1973, "Kendal reservoirs", Transactions of the Cumberland and Westmorland Antiquarian and Archaeological Society 73.KM / LRDBiographical history of technology > Bateman, John Frederick La Trobe
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64 Papin, Denis
SUBJECT AREA: Domestic appliances and interiors[br]b. 22 August 1647 Blois, Loire et Cher, Franced. 1712 London, England[br]French mathematician and physicist, inventor of the pressure-cooker.[br]Largely educated by his father, he worked for some time for Huygens at Ley den, then for a time in London where he assisted Robert Boyle with his experiments on the air pump. He supposedly invented the double-acting air pump. He travelled to Venice and worked there for a time, but was back in London in 1684 before taking up the position of Professor of Mathematics at the University of Marburg (in 1669 or 1670 he became a Doctor of Medicine at Angers), where he remained from 1687 to 1695. Then followed a period at Cassel, where he was employed by the Duke of Hesse. In this capacity he was much involved in the application of steam-power to pumping water for the Duke's garden fountains. Papin finally returned to London in 1707. He is best known for his "digester", none other than the domestic pressure-cooker. John Evelyn describes it in his diary (12 April 1682): "I went this Afternoone to a Supper, with severall of the R.Society, which was all dressed (both fish and flesh) in Monsieur Papins Digestorie; by which the hardest bones of Biefe itself, \& Mutton, were without water, or other liquor, \& with less than 8 ounces of Coales made as soft as Cheeze, produc'd an incredible quantity of Gravie…. This Philosophical Supper raised much mirth among us, \& exceedingly pleased all the Companie." The pressure-cooker depends on the increase in the boiling point of water with increase of pressure. To avoid the risk of the vessel exploding, Papin devised a weight-loaded lever-type safety valve.There are those who would claim that Papin preceded Newcomen as the true inventor of the steam engine. There is no doubt that as early as 1690 Papin had the idea of an atmospheric engine, in which a piston in a cylinder is forced upwards by expanding steam and then returned by the weight of the atmosphere upon the piston, but he lacked practical engineering skill such as was necessary to put theory into practice. The story is told of his last trip from Cassel, when returning to England. It is said that he built his own steamboat, intending to make the whole journey by this means, ending with a triumphal journey up the Thames. However, boatmen on the river Weser, thinking that the steamboat threatened their livelihood, attacked it and broke it up. Papin had to travel by more orthodox means. Papin is said to have co-operated with Thomas Savery in the development of the lat-ter's steam engine, on which he was working c. 1705.[br]Further ReadingCharles-Armand Klein, 1987, Denis Papin: Illustre savant blaisois, Chambray, France: CLD.A.P.M.Fleming and H.R.S.Brocklehurst, 1925, A History of Engineering.Sigvar Strandh, 1979, Machines, Mitchell Beazley.IMcN -
65 output
2) продукция; продукт3) добыча4) выход; вывод5) съём ( стекломассы)8) эл. выводные концы; выходные зажимы10) вчт. выходные данные, результат11) вчт. выходное устройство; устройство вывода•output on film — вывод ( набора) на фотоплёнку;output on paper — вывод ( набора) на фотобумагу;to drop irrigation output — производить урезку подачи воды на орошение;to firm up the output of power plant — обеспечивать гарантированную выработку электроэнергии ГЭС-
actual output
-
analog output
-
annual output
-
apparent output
-
available output
-
balanced output
-
binary output
-
boiler output
-
card output
-
clocked output
-
compressor output
-
continuous output
-
controlled output
-
current output
-
daily energy output
-
daily output
-
data output
-
deep-mined output
-
delayed output
-
detected output
-
differential output
-
digital output
-
direct output
-
double-ended output
-
effective output
-
energy output
-
engineering output
-
enriched output
-
floating output
-
formatted output
-
furance output
-
graphical output
-
graphic output
-
gross station output
-
heat output
-
information output
-
in-phase output
-
irrigation output
-
isolated outputs
-
kiln output
-
laser output
-
light output
-
load current output
-
mechanical output
-
melting output
-
multiple output
-
net station output
-
noise power output
-
nonreversible output
-
numerically control output
-
open collector output
-
output of spring
-
output of well
-
per face output
-
per face per day output
-
per man-hour output
-
per man-shift output
-
photovoltaic output
-
photovoltaic power system output
-
plant output
-
plotted output
-
power output
-
printed output
-
pump output
-
punched output
-
punch output
-
push-pull output
-
quadrature output
-
quantized output
-
rated output
-
rated-power output
-
reference output
-
refrigeration output
-
relay outputs
-
remote job output
-
ripple-carry output
-
short-circuit output
-
signal output
-
single-ended output
-
sound output
-
specific flame output
-
specific output
-
speech output
-
spurious output
-
station output
-
steam output
-
stripped output
-
thermal output
-
total output
-
transformer output
-
tri-state output
-
turbine output
-
unbalanced output
-
uncommitted collector output
-
useful output
-
video output
-
voice output
-
water-resources output
-
window output
-
yearly output -
66 design
1) проектирование; разработка; конструирование || проектировать; разрабатывать; конструировать2) проект; разработка; конструкция, конструктивное решение; конструктивное исполнение, конструктивное оформление3) схема; чертёж; схемное решение; план4) расчёт5) дизайн6) модель (одежды, обуви)7) рисунок•to allow for smth in design — предусматривать что-л. проектом;design of section — метал. профиль-
alternate design
-
architectural design
-
argyle design
-
asymmetrical design
-
beadless tire design
-
blast design
-
block design
-
bottom-hole design
-
bottom-up design
-
building-block design
-
center-sill design
-
center-silless design
-
character design
-
circuit design
-
civil-engineering design
-
collapse design
-
completion design
-
composite design
-
computer-aided design
-
conceptual design
-
contractor design
-
creep design
-
cut-and-try design
-
data design
-
detailed design
-
detail design
-
dimension design
-
draft design
-
elastic design
-
engineering design
-
environmental design
-
experimental design
-
exploratory design
-
external design
-
fracture-safe design
-
fracture design
-
full-size design
-
functional design
-
hydraulic design
-
in-house design
-
interactive design
-
interlocking design
-
intermediate jacquard design
-
internal design
-
lateral-force design
-
level-sensitive scan design
-
lightweight design
-
limit design
-
limit-state design
-
load-factor design
-
logical design
-
logic design
-
mask design
-
mine design
-
mirror repeat design
-
mix design
-
mode-free design
-
modular design
-
nonspiral design
-
on-line design
-
operational design
-
optimal design
-
package design
-
panel design
-
pillar design
-
pilot design
-
plastic design
-
preliminary design
-
process design
-
program design
-
proprietary design
-
proved design
-
rail-safe design
-
rear engine design
-
retrofit design
-
revised design
-
rigid design
-
roll pass design
-
schematic design
-
seismic design
-
shaft design
-
shaft lining design
-
solar power system design
-
solar system design
-
solar cell design
-
spiral form design
-
spiral design
-
sprung arch design
-
straight design
-
streamlined design
-
structural design
-
structured design
-
symmetrical design
-
thermal design
-
top-down design
-
track oscillated design
-
trail-and-error design
-
tubular design
-
type design
-
type face design
-
ultimate load design
-
unlimited design
-
water-management design
-
water-system design
-
working stress design
-
worst-case design -
67 Brunel, Isambard Kingdom
SUBJECT AREA: Civil engineering, Land transport, Mechanical, pneumatic and hydraulic engineering, Ports and shipping, Public utilities, Railways and locomotives[br]b. 9 April 1806 Portsea, Hampshire, Englandd. 15 September 1859 18 Duke Street, St James's, London, England[br]English civil and mechanical engineer.[br]The son of Marc Isambard Brunel and Sophia Kingdom, he was educated at a private boarding-school in Hove. At the age of 14 he went to the College of Caen and then to the Lycée Henri-Quatre in Paris, after which he was apprenticed to Louis Breguet. In 1822 he returned from France and started working in his father's office, while spending much of his time at the works of Maudslay, Sons \& Field.From 1825 to 1828 he worked under his father on the construction of the latter's Thames Tunnel, occupying the position of Engineer-in-Charge, exhibiting great courage and presence of mind in the emergencies which occurred not infrequently. These culminated in January 1828 in the flooding of the tunnel and work was suspended for seven years. For the next five years the young engineer made abortive attempts to find a suitable outlet for his talents, but to little avail. Eventually, in 1831, his design for a suspension bridge over the River Avon at Clifton Gorge was accepted and he was appointed Engineer. (The bridge was eventually finished five years after Brunel's death, as a memorial to him, the delay being due to inadequate financing.) He next planned and supervised improvements to the Bristol docks. In March 1833 he was appointed Engineer of the Bristol Railway, later called the Great Western Railway. He immediately started to survey the route between London and Bristol that was completed by late August that year. On 5 July 1836 he married Mary Horsley and settled into 18 Duke Street, Westminster, London, where he also had his office. Work on the Bristol Railway started in 1836. The foundation stone of the Clifton Suspension Bridge was laid the same year. Whereas George Stephenson had based his standard railway gauge as 4 ft 8½ in (1.44 m), that or a similar gauge being usual for colliery wagonways in the Newcastle area, Brunel adopted the broader gauge of 7 ft (2.13 m). The first stretch of the line, from Paddington to Maidenhead, was opened to traffic on 4 June 1838, and the whole line from London to Bristol was opened in June 1841. The continuation of the line through to Exeter was completed and opened on 1 May 1844. The normal time for the 194-mile (312 km) run from Paddington to Exeter was 5 hours, at an average speed of 38.8 mph (62.4 km/h) including stops. The Great Western line included the Box Tunnel, the longest tunnel to that date at nearly two miles (3.2 km).Brunel was the engineer of most of the railways in the West Country, in South Wales and much of Southern Ireland. As railway networks developed, the frequent break of gauge became more of a problem and on 9 July 1845 a Royal Commission was appointed to look into it. In spite of comparative tests, run between Paddington-Didcot and Darlington-York, which showed in favour of Brunel's arrangement, the enquiry ruled in favour of the narrow gauge, 274 miles (441 km) of the former having been built against 1,901 miles (3,059 km) of the latter to that date. The Gauge Act of 1846 forbade the building of any further railways in Britain to any gauge other than 4 ft 8 1/2 in (1.44 m).The existence of long and severe gradients on the South Devon Railway led to Brunel's adoption of the atmospheric railway developed by Samuel Clegg and later by the Samuda brothers. In this a pipe of 9 in. (23 cm) or more in diameter was laid between the rails, along the top of which ran a continuous hinged flap of leather backed with iron. At intervals of about 3 miles (4.8 km) were pumping stations to exhaust the pipe. Much trouble was experienced with the flap valve and its lubrication—freezing of the leather in winter, the lubricant being sucked into the pipe or eaten by rats at other times—and the experiment was abandoned at considerable cost.Brunel is to be remembered for his two great West Country tubular bridges, the Chepstow and the Tamar Bridge at Saltash, with the latter opened in May 1859, having two main spans of 465 ft (142 m) and a central pier extending 80 ft (24 m) below high water mark and allowing 100 ft (30 m) of headroom above the same. His timber viaducts throughout Devon and Cornwall became a feature of the landscape. The line was extended ultimately to Penzance.As early as 1835 Brunel had the idea of extending the line westwards across the Atlantic from Bristol to New York by means of a steamship. In 1836 building commenced and the hull left Bristol in July 1837 for fitting out at Wapping. On 31 March 1838 the ship left again for Bristol but the boiler lagging caught fire and Brunel was injured in the subsequent confusion. On 8 April the ship set sail for New York (under steam), its rival, the 703-ton Sirius, having left four days earlier. The 1,340-ton Great Western arrived only a few hours after the Sirius. The hull was of wood, and was copper-sheathed. In 1838 Brunel planned a larger ship, some 3,000 tons, the Great Britain, which was to have an iron hull.The Great Britain was screwdriven and was launched on 19 July 1843,289 ft (88 m) long by 51 ft (15.5 m) at its widest. The ship's first voyage, from Liverpool to New York, began on 26 August 1845. In 1846 it ran aground in Dundrum Bay, County Down, and was later sold for use on the Australian run, on which it sailed no fewer than thirty-two times in twenty-three years, also serving as a troop-ship in the Crimean War. During this war, Brunel designed a 1,000-bed hospital which was shipped out to Renkioi ready for assembly and complete with shower-baths and vapour-baths with printed instructions on how to use them, beds and bedding and water closets with a supply of toilet paper! Brunel's last, largest and most extravagantly conceived ship was the Great Leviathan, eventually named The Great Eastern, which had a double-skinned iron hull, together with both paddles and screw propeller. Brunel designed the ship to carry sufficient coal for the round trip to Australia without refuelling, thus saving the need for and the cost of bunkering, as there were then few bunkering ports throughout the world. The ship's construction was started by John Scott Russell in his yard at Millwall on the Thames, but the building was completed by Brunel due to Russell's bankruptcy in 1856. The hull of the huge vessel was laid down so as to be launched sideways into the river and then to be floated on the tide. Brunel's plan for hydraulic launching gear had been turned down by the directors on the grounds of cost, an economy that proved false in the event. The sideways launch with over 4,000 tons of hydraulic power together with steam winches and floating tugs on the river took over two months, from 3 November 1857 until 13 January 1858. The ship was 680 ft (207 m) long, 83 ft (25 m) beam and 58 ft (18 m) deep; the screw was 24 ft (7.3 m) in diameter and paddles 60 ft (18.3 m) in diameter. Its displacement was 32,000 tons (32,500 tonnes).The strain of overwork and the huge responsibilities that lay on Brunel began to tell. He was diagnosed as suffering from Bright's disease, or nephritis, and spent the winter travelling in the Mediterranean and Egypt, returning to England in May 1859. On 5 September he suffered a stroke which left him partially paralysed, and he died ten days later at his Duke Street home.[br]Further ReadingL.T.C.Rolt, 1957, Isambard Kingdom Brunel, London: Longmans Green. J.Dugan, 1953, The Great Iron Ship, Hamish Hamilton.IMcNBiographical history of technology > Brunel, Isambard Kingdom
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68 Carnot, Nicolas Léonard Sadi
SUBJECT AREA: Steam and internal combustion engines[br]b. 1 June 1796 Paris, Franced. 24 August 1831 Paris, France[br]French laid the foundations for modern thermodynamics through his book Réflexions sur la puissance motrice du feu when he stated that the efficiency of an engine depended on the working substance and the temperature drop between the incoming and outgoing steam.[br]Sadi was the eldest son of Lazare Carnot, who was prominent as one of Napoleon's military and civil advisers. Sadi was born in the Palais du Petit Luxembourg and grew up during the Napoleonic wars. He was tutored by his father until in 1812, at the minimum age of 16, he entered the Ecole Polytechnique to study stress analysis, mechanics, descriptive geometry and chemistry. He organized the students to fight against the allies at Vincennes in 1814. He left the Polytechnique that October and went to the Ecole du Génie at Metz as a student second lieutenant. While there, he wrote several scientific papers, but on the Restoration in 1815 he was regarded with suspicion because of the support his father had given Napoleon. In 1816, on completion of his studies, Sadi became a second lieutenant in the Metz engineering regiment and spent his time in garrison duty, drawing up plans of fortifications. He seized the chance to escape from this dull routine in 1819 through an appointment to the army general staff corps in Paris, where he took leave of absence on half pay and began further courses of study at the Sorbonne, Collège de France, Ecole des Mines and the Conservatoire des Arts et Métiers. He was inter-ested in industrial development, political economy, tax reform and the fine arts.It was not until 1821 that he began to concentrate on the steam-engine, and he soon proposed his early form of the Carnot cycle. He sought to find a general solution to cover all types of steam-engine, and reduced their operation to three basic stages: an isothermal expansion as the steam entered the cylinder; an adiabatic expansion; and an isothermal compression in the condenser. In 1824 he published his Réflexions sur la puissance motrice du feu, which was well received at the time but quickly forgotten. In it he accepted the caloric theory of heat but pointed out the impossibility of perpetual motion. His main contribution to a correct understanding of a heat engine, however, lay in his suggestion that power can be produced only where there exists a temperature difference due "not to an actual consumption of caloric but to its transportation from a warm body to a cold body". He used the analogy of a water-wheel with the water falling around its circumference. He proposed the true Carnot cycle with the addition of a final adiabatic compression in which motive power was con sumed to heat the gas to its original incoming temperature and so closed the cycle. He realized the importance of beginning with the temperature of the fire and not the steam in the boiler. These ideas were not taken up in the study of thermodynartiics until after Sadi's death when B.P.E.Clapeyron discovered his book in 1834.In 1824 Sadi was recalled to military service as a staff captain, but he resigned in 1828 to devote his time to physics and economics. He continued his work on steam-engines and began to develop a kinetic theory of heat. In 1831 he was investigating the physical properties of gases and vapours, especially the relationship between temperature and pressure. In June 1832 he contracted scarlet fever, which was followed by "brain fever". He made a partial recovery, but that August he fell victim to a cholera epidemic to which he quickly succumbed.[br]Bibliography1824, Réflexions sur la puissance motrice du feu; pub. 1960, trans. R.H.Thurston, New York: Dover Publications; pub. 1978, trans. Robert Fox, Paris (full biographical accounts are provided in the introductions of the translated editions).Further ReadingDictionary of Scientific Biography, 1971, Vol. III, New York: C.Scribner's Sons. T.I.Williams (ed.), 1969, A Biographical Dictionary of Scientists, London: A. \& C.Black.Chambers Concise Dictionary of Scientists, 1989, Cambridge.D.S.L.Cardwell, 1971, from Watt to Clausius. The Rise of Thermodynamics in the Early Industrial Age, London: Heinemann (discusses Carnot's theories of heat).RLHBiographical history of technology > Carnot, Nicolas Léonard Sadi
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69 Monro, Philip Peter
SUBJECT AREA: Chemical technology[br]b. 27 May 1946 London, England[br]English biologist, inventor of a water-purification process by osmosis.[br]Monro's whole family background is engineering, an interest he did not share. Instead, he preferred biology, an enthusiasm aroused by reading the celebrated Science of Life by H.G. and G.P.Wells and Julian Huxley. Educated at a London comprehensive school, Monro found it necessary to attend evening classes while at school to take his advanced level science examinations. Lacking parental support, he could not pursue a degree course until he was 21 years old, and so he gained valuable practical experience as a research technician. He resumed his studies and took a zoology degree at Portsmouth Polytechnic. He then worked in a range of zoology and medical laboratories, culminating after twelve years as a Senior Experimental Officer at Southampton Medical School. In 1989 he relinquished his post to devote himself fall time to developing his inventions as Managing Director of Hampshire Advisory and Technical Services Ltd (HATS). Also in 1988 he obtained his PhD from Southampton University, in the field of embryology.Monro had meanwhile been demonstrating a talent for invention, mainly in microscopy. His most important invention, however, is of a water-purification system. The idea for it came from Michael Wilson of the Institute of Dental Surgery in London, who evolved a technique for osmotic production of sterile oral rehydration solutions, of particular use in treating infants suffering from diarrhoea in third-world countries. Monro broadened the original concept to include dried food, intravenous solutions and even dried blood. The process uses simple equipment and no external power and works as follows: a dry sugar/salts mixture is sealed in one compartment of a double bag, the common wall of which is a semipermeable membrane. Impure water is placed in the empty compartment and the water transfers across the membrane by the osmotic force of the sugar/salts. As the pores in the membrane exclude all viruses, bacteria and their toxins, a sterile solution is produced.With the help of a research fellowship granted for humanitarian reasons at King Alfred College, Winchester, the invention was developed to functional prototype stage in 1993, with worldwide patent protection. Commercial production was expected to follow, if sufficient financial backing were forthcoming. The process is not intended to replace large installations, but will revolutionize the small-scale production of sterile water in scattered third-world communities and in disaster areas where normal services have been disrupted.HATS was awarded First Prize in the small business category and was overall prize winner in the Toshiba Year of Invention, received a NatWest/BP award for technology and a Prince of Wales Award for Innovation.[br]Bibliography1993, with M.Wilson and W.A.M.Cutting, "Osmotic production of sterile oral rehydration solutions", Tropical Doctor 23:69–72.LRD -
70 channel
1) канал3) сток, сточная канава || рыть сточную канаву5) архит. каннелюра6) метал. боров7) метал. швеллер8) мн. ч. "мёртвые места" ( в конвертере)9) машиностр. проход ( для рабочей среды)11) дорожка ( магнитной ленты)12) канал, канальная область ( в полупроводниковых приборах)13) ручей ( уборочной машины)•channel with feedback — канал с обратной связью-
A channel
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active channel
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adjacent channel
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air channel
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allocated channel
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analog data transfer channel
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annular channel
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approach channel
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artificial channel
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aspirating channel
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assembly channel
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asymmetric channel
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audio channel
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average power channel
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average temperature channel
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B channel
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backward channel
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beam channel
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biological channel
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blade channel
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blocked channel
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boiling channel
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broadband channel
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broadcasting channel
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broadcast channel
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buried channel
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burst channel
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bypass channel
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byte multiplexer channel
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cable channel
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camera channel
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carrier-current channel
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carrier channel
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cascaded channel
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central fuel channel
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check channel
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chroma channel
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clock channel
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closed-circuit TV channel
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closure channel
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coin channel
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collecting channel
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color channel
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color film channel
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color telecine projection channel
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communications channel
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communication channel
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control channel
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control-rod channel
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convergent-divergent channel
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cooling channel
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core channel
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data transfer channel
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data channel
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dedicated channel
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dial-up channel
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die channel
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digital communication channel
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digital channel
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direct access channel
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discharge channel
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discrete channel
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display channel
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diversion channel
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diversity channel
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divertor channel
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Doppler-shifted channel
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downstream channel
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drain channel
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drainage channel
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duplex channel
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engine main oil channel
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engineering channel
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entrance channel
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equalizer bar channel
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exhaust channel
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experimental channel
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expulsion smoke channel
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fading channel
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fast-safety channel
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feedback channel
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fiber optic communication channel
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fiber optic channel
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film channel
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fire channel
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fish bypass channel
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fixed-tuned channel
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flood relief channel
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flow channel
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flowing channel
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flux-measuring channel
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forward channel
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frequency channel
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fuel channel
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fuel return channel
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Gaussian channel
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guard channel
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gun barrel channel
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half-duplex channel
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head channel
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headrace channel
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high Reynolds number channel
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highest-grade channel
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hot channel
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I channel
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idle channel
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image channel
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induced channel
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induction smoke channel
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information channel
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inlet channel
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input channel
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input-output channel
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instrument channel
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intake channel
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integrated channel
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intercepting channel
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interference channel
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intermediate-frequency channel
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internally finned channel
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inversion channel
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ionospheric channel
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jammed channel
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L stereo channel
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leased channel
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left audio channel
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line-of-sight channel
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long-distance channel
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lubrication channel
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luminance channel
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main channel
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main drainage channel
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main ship channel
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measuring channel
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memory channel
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memoryless channel
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molding channel
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monophonic channel
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motion channel
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multipath channel
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multiplexer channel
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multiplex channel
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multiuser channel
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narrow-band channel
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navigable channel
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near infrared channel
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noiseless channel
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noisy channel
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nonsynchronized channel
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n-type channel
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ocean color channel
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oil channel
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one-way channel
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optical channel
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output channel
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overflow channel
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picture channel
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pilot channel
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pitch channel
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plasma channel
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power mismatch channel
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power range channel
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power-level channel
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primary channel
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primary-color channel
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process channel
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p-type channel
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Q channel
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quantum channel
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R stereo channel
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radio channel
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radioactivity measurement channel
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radio-frequency channel
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read channel
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recording channel
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recording-duplicating channel
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reference channel
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relay channel
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replay channel
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return channel
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right audio channel
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roll channel
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rolled steel channel
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roll-formed channel
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roof-support channel
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running channel
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safety channel
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scatter channel
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scavenge channel
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sea channel
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secondary channel
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selector channel
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service channel
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short channel
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shutdown channel
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side channel
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signaling channel
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simplex channel
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simulated fuel channel
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simultaneous channels
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skew-back channel
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sloping loop channel
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sluiceway channel
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sodium-filled channel
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sodium channel
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sole channel
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sound channel
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sow channel
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spark channel
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speech channel
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sprocket channel
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stationary channel
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stereophonic channel
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stereo channel
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supervisory channel
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supply channel
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surface channel
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switched channel
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symmetrical channel
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symmetric channel
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synchronizing channel
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tailrace channel
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taxi channel
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telecine projection channel
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telecine channel
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telecommunications channel
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telecommunication channel
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telegraph channel
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telemetering channel
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telemeter channel
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television channel
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through channel
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time-derived channels
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time-varying channel
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timing channel
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top channel
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training channel
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transmission channel
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two-way channel
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uncharged fuel channel
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vane channel
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vertical channel
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video-frequency vision channel
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video vision channel
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video-frequency channel
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video channel
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voice-band voice-grade channel
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voice voice-grade channel
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voice-band channel
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voice channel
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wasteway channel
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water channel
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whip channel
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wide-band channel
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wind channel
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wireless channel
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wire-tap channel
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write channel
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Y channel
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yaw channel -
71 plant
1) предприятие; завод; фабрика2) основные производственные средства (включая земельный участок)3) установка; агрегат; оборудование4) растение5) сажать; сеять6) внедрять7) основывать -
72 Bacon, Francis Thomas
SUBJECT AREA: Aerospace[br]b. 21 December 1904 Billericay, Englandd. 24 May 1992 Little Shelford, Cambridge, England[br]English mechanical engineer, a pioneer in the modern phase of fuel-cell development.[br]After receiving his education at Eton and Trinity College, Cambridge, Bacon served with C.A. Parsons at Newcastle upon Tyne from 1925 to 1940. From 1946 to 1956 he carried out research on Hydrox fuel cells at Cambridge University and was a consultant on fuel-cell design to a number of organizations throughout the rest of his life.Sir William Grove was the first to observe that when oxygen and hydrogen were supplied to platinum electrodes immersed in sulphuric acid a current was produced in an external circuit, but he did not envisage this as a practical source of electrical energy. In the 1930s Bacon started work to develop a hydrogen-oxygen fuel cell that operated at moderate temperatures and pressures using an alkaline electrolyte. In 1940 he was appointed to a post at King's College, London, and there, with the support of the Admiralty, he started full-time experimental work on fuel cells. His brief was to produce a power source for the propulsion of submarines. The following year he was posted as a temporary experimental officer to the Anti-Submarine Experimental Establishment at Fairlie, Ayrshire, and he remained there until the end of the Second World War.In 1946 he joined the Department of Chemical Engineering at Cambridge, receiving a small amount of money from the Electrical Research Association. Backing came six years later from the National Research and Development Corporation (NRDC), the development of the fuel cell being transferred to Marshalls of Cambridge, where Bacon was appointed Consultant.By 1959, after almost twenty years of individual effort, he was able to demonstrate a 6 kW (8 hp) power unit capable of driving a small truck. Bacon appreciated that when substantial power was required over long periods the hydrogen-oxygen fuel cell associated with high-pressure gas storage would be more compact than conventional secondary batteries.The development of the fuel-cell system pioneered by Bacon was stimulated by a particular need for a compact, lightweight source of power in the United States space programme. Electro-chemical generators using hydrogen-oxygen cells were chosen to provide the main supplies on the Apollo spacecraft for landing on the surface of the moon in 1969. An added advantage of the cells was that they simultaneously provided water. NRDC was largely responsible for the forma-tion of Energy Conversion Ltd, a company that was set up to exploit Bacon's patents and to manufacture fuel cells, and which was supported by British Ropes Ltd, British Petroleum and Guest, Keen \& Nettlefold Ltd at Basingstoke. Bacon was their full-time consultant. In 1971 Energy Conversion's operation was moved to the UK Atomic Energy Research Establishment at Harwell, as Fuel Cells Ltd. Bacon remained with them until he retired in 1973.[br]Principal Honours and DistinctionsOBE 1967. FRS 1972. Royal Society S.G. Brown Medal 1965. Royal Aeronautical Society British Silver Medal 1969.Bibliography27 February 1952, British patent no. 667,298 (hydrogen-oxygen fuel cell). 1963, contribution in W.Mitchell (ed.), Fuel Cells, New York, pp. 130–92.1965, contribution in B.S.Baker (ed.), Hydrocarbon Fuel Cell Technology, New York, pp. 1–7.Further ReadingObituary, 1992, Daily Telegraph (8 June).A.McDougal, 1976, Fuel Cells, London (makes an acknowledgement of Bacon's contribution to the design and application of fuel cells).D.P.Gregory, 1972, Fuel Cells, London (a concise introduction to fuel-cell technology).GW -
73 development
1) разработка; проектирование; опытно-конструкторские работы, ОКР; проектно-конструкторские работы; конструирование2) развитие, совершенствование, доводка, отладка3) горн. вскрытие; подготовка ( месторождения)4) нефт. разработка ( месторождения)5) застройка; строительство8) матем. разложение ( в ряд)9) развёртывание ( проекции)10) проявление ( плёнки); обработка ( фотоматериалов)•to be under development — находиться в состоянии разработки;to bring into development — вводить в разработкуdevelopment of brittleness — развитие хрупкости, охрупчиваниеdevelopment of environment — улучшение( качества) окружающей средыdevelopment of photoresist — проявление фоторезиста-
advanced development
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aerosol development
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automatic development
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bench development
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black-and-white development
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bottom-up development
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brush development
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cascade development
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chemical development
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cluster-well development
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coarse grain development
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color development
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Correx development
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crack development
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crestal field development
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custom development
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daylight development
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deformation development
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drum development
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dry process development
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dry development
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electrographic development
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electrolytic development
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engine development
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engineering development
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experimental development
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exploratory development
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face line development
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factorial development
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field development
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fine-grained development
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fine-grain development
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hardware development
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heat development
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high-head power development
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high-head development
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hydraulic power development
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incremental program development
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infectious development
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integrated development
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integrated river-basin development
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latent image development
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liquid development
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low-head power development
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low-head development
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machine development
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main development
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marginal field development
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mine development
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negative development
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ocean development
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oil pool development
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on-the-scene film development
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operational development
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organizational development
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outstep field development
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parachute development
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photographic development
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physical development
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planned development
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positive development
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post-fixation development
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powder cloud development
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puddle development
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pumped-storage development
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rack-and-tank development
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raise development
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recreational development
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reversal development
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ribbon development
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river-basin development
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roadway development
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silver development
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simultaneous field development
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single bath development
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single-well development
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software development
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sporadic development
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spray development
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superadditivity development
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thermal development
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three-bath development
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top-down development
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two-bath development
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waterflood oil pool development
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water-resources development
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wet process development
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wet development -
74 structure
1) сооружение; конструкция2) конструкция; устройство; схема3) структура; строение4) система6) форма; вид7) эл. опора•- accordion stitch structure -
acicular structure
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active substrate structure
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air-inflated structure
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air structure
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aligned structure
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alignment structure
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all-metal structure
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angle structure
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antiavalanche structure
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appurtenant structure
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Aran structure
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arborescent structure
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aromatic structure
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array structure
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as-hardened structure
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atlas structure
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atomic structure
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austenitic structure
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automatically erectable structure
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avalanche injection structure
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backbone structure
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backward-wave structure
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balanced atlas structure
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balloon structure
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band structure
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barrier injection structure
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base-coupled structure
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basic structure
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bearing structure
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bearing-wall structure
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benzene-like structure
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bipolar diffused structure
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bipolar junction structure
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bird's eye backing jacquard structure
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blackberry stitch structure
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blister structure
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block structure
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block-graft structure
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body structure
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boundary structure
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bourrelet structure
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box-like space structure
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braced structure
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branched structure
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bubble stitch structure
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building structure
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bulk structure
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buried structure
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buried-collector structure
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buried-gate structure
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buried-oxide MOS structure
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bus-organized structure
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bus structure
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cable stitch structure
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cable-stayed structure
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camera structure
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catenary suspension structure
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cellular structure
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chain structure
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chain-packed structure
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charge injection structure
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charge transfer structure
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charge-coupled structure
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check structure
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chemical structure
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cholesteric structure
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circus-support structure
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closed structure
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close-grained structure
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close-packed structure
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clustered structure
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coagulation structure
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coast-protecting structure
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collector-coupled structure
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columnar structure
-
complementary MOS structure
-
compliance structure
-
condensation structure
-
continuous structure
-
control structure
-
controlled eutectic structure
-
core support structure
-
course structure
-
crest structure
-
cross plating structure
-
cross-armless structure
-
cross-linked structure
-
cross-miss structure
-
cross-rope suspension structure
-
cross-tuck structure
-
crystalline structure
-
crystal structure
-
cubic structure
-
cutting structure
-
daisy-chain structure
-
dangerous structure
-
data structure
-
dead-end structure
-
debris retaining structure
-
deep structure
-
delay-line structure
-
dendrite structure
-
determinate structure
-
diffused-gate structure
-
disordered structure
-
docking module launch support structure
-
domain structure
-
dotted structure
-
double epitaxial structure
-
double-avalanche structure
-
double-diffused MOS structure
-
double-implanted structure
-
double-polysilicon structure
-
double-poly structure
-
drawing file structure
-
drilling bit bearing structure
-
drill bit bearing structure
-
drop structure
-
dropped stitch structure
-
duplex structure
-
earth structure
-
earthquake-proof structure
-
earth-retaining structure
-
eightlock structure
-
embroidery plating structure
-
emitter-coupled structure
-
energy-band structure
-
engineering structure
-
epitaxial structure
-
evermonte structure
-
exterior structure
-
eyelet structure
-
fabric structure
-
fabricated structure
-
fail-safe structure
-
fancy stitch structure
-
faulted structure
-
fendering structure
-
fibrous structure
-
field structure
-
field-interleaved structure
-
file structure
-
filiform molecule structure
-
filler structure
-
film guiding structure
-
film handling structure
-
film structure
-
fine structure
-
fine-grain structure
-
fire-tree structure
-
fish protection structure
-
flaky structure
-
flexible structure
-
float plated fishnet structure
-
float plated structure
-
float stitch structure
-
floated-in structure
-
floating dock structure
-
floating gate MOS structure
-
floating gate structure
-
flood-regulating structure
-
floor structure
-
flow-measuring structure
-
folded-plate structure
-
frame structure
-
framed structure
-
frame-like structure
-
French pique structure
-
fringe structure
-
full cardigan rib structure
-
full cardigan structure
-
full tricot structure
-
full-jacquard structure
-
functional structure
-
gate-operation structure
-
gel structure
-
geological structure
-
glass structure
-
glass-like structure
-
grade separation structure
-
graded structure
-
graphoepitaxial structure
-
gravity-dependent structure
-
gravity structure
-
grid structure
-
groundwater intake structure
-
guard-ring structure
-
guide structure
-
hairpin structure
-
half-cardigan structure
-
half-transfer stitch structure
-
herringbone twill structure
-
heteroepitaxial structure
-
heterogeneous structure
-
heterojunction structure
-
H-frame structure
-
hierarchical sensory-control structure
-
hierarchical structure
-
highly refined structure
-
high-performance MOS structure
-
homogeneous structure
-
honeycomb structure
-
horizontal striped backing jacquard structure
-
hydraulic structure
-
hydrodynamic dissipative structure
-
hyperfine structure
-
hyperstatic structure
-
image structure
-
indeterminate structure
-
industrial structure
-
inflatable structure
-
ingot structure
-
inlay lap stitch structure
-
in-line structure
-
instruction structure
-
insulated gate structure
-
insulated substrate structure
-
intake structure
-
interdigital structure
-
interior structure
-
interlock stitch structure
-
ionic gating structures
-
ion gating structures
-
ion-implanted structure
-
ion-selective field-effect structure
-
isle structure
-
jacquard structure
-
jersey structure
-
jointless structure
-
jumbo structure
-
junction field-effect structure
-
junction-isolated structure
-
knitted structure
-
knock-off lap stitch structure
-
lace stitch structure
-
ladder structure
-
ladderproof structure
-
lamellar structure
-
laminated structure
-
lateral structure
-
lattice structure
-
layer-like structure
-
light-trapping structure
-
line structure
-
linear structure
-
line-interleaved structure
-
line-locked structure
-
line-quincunx structure
-
linked structure
-
links-links structure
-
liquid-like structure
-
list structure
-
locknit structure
-
logical structure
-
logic structure
-
looped plush structure
-
looped tuck structure
-
loosely packed structure
-
macromolecular structure
-
magnetic structure
-
mammoth structure
-
manipulator erectable structure
-
manually erectable structure
-
marine structure
-
marquisette structure
-
mat structure
-
mesa strip structure
-
mesa structure
-
mesh structure
-
metal-insulator-semiconductor structure
-
metallized semiconductor gate structure
-
metal-nitride-oxide-semiconductor structure
-
metal-nitride-semiconductor structure
-
metal-oxide-metal structure
-
metal-oxide-semiconductor structure
-
microgel structure
-
micromesh structure
-
Milano rib structure
-
mock rib structure
-
mode structure
-
modular structure
-
mosaic structure
-
moss stitch structure
-
multicollector structure
-
multiemitter structure
-
multilayer structure
-
multilevel structure
-
multi-microprocessor structure
-
multispan structure
-
multituck structure
-
n-channel structure
-
nematic structure
-
net structure
-
netting structure
-
network structure
-
nipple stitch structure
-
n-MOS structure
-
nonbearing structure
-
n-p-n structure
-
nuclear structure
-
ocean structure
-
ocean thermal structure
-
offshore marine structure
-
offshore structure
-
open stitch structure
-
open structure
-
open-neck structure
-
open-pile braced structure
-
orbiting structure
-
ordered structure
-
orthogonal structure
-
orthorhombic structure
-
ottoman structure
-
overaged structure
-
pattern purl stitch structure
-
patterned structure
-
p-channel structure
-
pelerine structure
-
periodic structure
-
permanent structure
-
photovoltaic equipped parking and shade structure
-
p-i-n structure
-
pin tuck structure
-
planar structure
-
p-MOS structure
-
p-n-p structure
-
polycrystalline structure
-
polycrystal structure
-
ponte di Roma structure
-
popcorn stitch structure
-
portal structure
-
power system structure
-
pressurized structure
-
prestressed structure
-
primary structure
-
protecting structure
-
purification structure
-
purl structure
-
quarternary structure
-
queenscord structure
-
quenched-and-tempered structure
-
rack stitch structure
-
racked full-cardigan structure
-
racked half-cardigan structure
-
racked rib structure
-
random structure
-
reactor top structure
-
redundant structure
-
reflecting structure
-
regular crystal structure
-
regular structure
-
reticular structure
-
reverse locknit structure
-
reversed mesa structure
-
reversible jacquard structure
-
reversible racked rib structure
-
rhombic structure
-
rhombohedral structure
-
rib structure
-
rib transfer stitch structure
-
rib-jacquard structure
-
rigid structure
-
ring structure
-
ring-like structure
-
ripple stitch structure
-
rod-like structure
-
rotorcraft flight structure
-
rugged structure
-
run-resist structure
-
sandwich structure
-
satin stripe structure
-
Schottky-gate structure
-
screwdown structure
-
seam structure
-
secondary structure
-
segregation-free structure
-
selected backing jacquara structure
-
self-aligned gate structure
-
self-floating structure
-
self-registered gate structure
-
semiconductor structure
-
semiconductor-metal-semiconductor structure
-
separation structure
-
shaft structure
-
sharkskin structure
-
shell stitch structure
-
shell structure
-
shutter structure
-
silicon-on-insulator structure
-
silicon-on-sapphire structure
-
simple structure
-
single Lacoste structure
-
single-crystal structure
-
single-layer structure
-
single-level structure
-
single-pique structure
-
sinker mesh structure
-
skeleton structure
-
skin-core structure
-
slaty structure
-
slowing structure
-
sluiceway structure
-
smectic structure
-
soil structure
-
solar animal structure
-
solid-state structure
-
solid structure
-
space structure
-
spiral cloud structure
-
stable structure
-
stacked structure
-
star-type structure
-
star structure
-
statically determinate structure
-
statically indeterminate structure
-
stockinette structure
-
streaky structure
-
stressed-skin structure
-
stress-relieved structure
-
subgrain structure
-
submerged structure
-
submicrometer structure
-
substatic structure
-
subsurface ingot structure
-
superlattice structure
-
supporting structure
-
surface structure
-
suspension structure
-
Swiss pique structure
-
tailrace structure
-
tangent structure
-
tank supporting structure
-
temporary structure
-
terry stitch structure
-
tertiary structure
-
test structure
-
tetragonal structure
-
texipique structure
-
thin-slab structure
-
three-dimensional structure
-
tidal regulating structure
-
tied-in floats structure
-
torsion box structure
-
tower-base structure
-
track structure
-
training structure
-
transferred sinker stitch structure
-
trashrack structure
-
tree-type structure
-
tree structure
-
triclinic structure
-
trigonal structure
-
tuck purl structure
-
tuck rib honeycomb structure
-
tuck ripple structure
-
tuck-interlock structure
-
tunnel access structure
-
turnout structure
-
twill backing jacquard structure
-
twin structure
-
twist nematic structure
-
two-needle overlap stitch structure
-
underground structure
-
underlying structure
-
unipolar structure
-
unstable structure
-
variable-gap structure
-
vesicular structure
-
V-groove MOS structure
-
void structure
-
warp knit meshes structure
-
water conveyance structure
-
water-diverting structure
-
waterflow retarding structure
-
waterfront structure
-
water-retaining structure
-
waterside structure
-
weft insertion structure
-
welt structure
-
woody structure
-
wrap embroidery structure
-
wrought structure -
75 Villard de Honnecourt
[br]b. c. 1200 Honnecourt-sur-Escaut, near Cambrai, Franced. mid-13th century (?) France[br]French architect-engineer.[br]Villard was one of the thirteenth-century architect-engineers who were responsible for the design and construction of the great Gothic cathedrals and other churches of the time. Their responsibilities covered all aspects of the work, including (in the spirit of the Roman architect Vitruvius) the invention and construction of mechanical devices. In their time, these men were highly esteemed and richly rewarded, although few of the inscriptions paying tribute to their achievements have survived. Villard stands out among them because a substantial part of his sketchbook has survived, in the form of thirty-three parchment sheets of drawings and notes, now kept in the Bibliothèque Nationale in Paris. Villard's professional career lasted roughly from 1225 to 1250. As a boy, he went to work on the building of the Cistercian monastery at Vaucelles, not far from Honnecourt, and afterwards he was apprenticed to the masons' lodge at Cambrai Cathedral, where he began copying the drawings and layouts on the tracing-house floor. All his drawings are, therefore, of the plans, elevations and sections of cathedrals. These buildings have long since been destroyed, but his drawings, perhaps among his earliest, bear witness to their architecture. He travelled widely in France and recorded features of the great works at Reims, Laon and Chartres. These include the complex system of passageways built into the fabric of a great cathedral; Villard comments that one of their purposes was "to allow circulation in case of fire".Villard was invited to Hungary and reached there c. 1235. He may have been responsible for the edifice dedicated to St Elizabeth of Hungary, canonized in 1235, at Kassa (now Košice, Slovakia). Villard probably returned to France c. 1240, at least before the Tartar invasion of Hungary in 1241.His sketchbook, which dates to c. 1235, stands as a memorial to Villard's skill as a draughtsman, a student of perspective and a mechanical engineer. He took his sketchbook with him on his travels, and used ideas from it in his work abroad. It contains architectural designs, geometrical constructions for use in building, surveying exercises and drawings for various kinds of mechanical devices, for civil or military use. He was transmitting details from the highly developed French Gothic masons to the relatively underdeveloped eastern countries. The notebooks were annotated for the use of pupils and other master masons, and the notes on geometry were obviously intended for pupils. The prize examples are the pages in the book, clearly Villard's own work, related to mechanical devices. Whilst he, like many others of the period and after, played with designs for perpetual-motion machines, he concentrated on useful devices. These included the first Western representation of a perpetualmotion machine, which at least displays a concern to derive a source of energy: this was a water-powered sawmill, with automatic feed of the timber into the mill. This has been described as the first industrial automatic power-machine to involve two motions, for it not only converts the rotary motion of the water-wheel to the reciprocating motion of the saw, but incorporates a means of keeping the log pressed against the saw. His other designs included water-wheels, watermills, the Archimedean screw and other curious devices.[br]BibliographyOf several facsimile reprints with notes there are Album de Villard de Honnecourt, 1858, ed. J.B.Lassus, Paris (repr. 1968, Paris: Laget), and The Sketchbook of Villard de Honnecourt, 1959, ed. T.Bowie, Bloomington: Indiana University Press.Further ReadingJ.Gimpel, 1977, "Villard de Honnecourt: architect and engineer", The Medieval Machine, London: Victor Gollancz, ch. 6, pp. 114–46.——1988, The Medieval Machine, the Industrial Revolution of the Middle Ages, London.R.Pernord, J.Gimpel and R.Delatouche, 1986, Le Moyen age pour quoi fayre, Paris.KM / LRD -
76 installation
- электроустановка
- установка (процесс)
- установка (оборудования)
- установка (напр., оборудования)
- установка
- система чистого помещения
- расположение
- пуск в действие
- оборудование
- инсталляция
- внедрение (в практику)
- ввод в эксплуатацию
- введение в должность
ввод в эксплуатацию
Событие, фиксирующее готовность изделия к использованию по назначению, документально оформленное в установленном порядке.
Примечание - Для специальных видов техники к вводу в эксплуатацию дополнительно относят подготовительные работы, контроль, приемку и закрепление изделия за эксплуатирующим подразделением
[ ГОСТ 25866-83 Эксплуатация техники. Термины и определения.]FR
Параллельные тексты EN-RU
No more pulleys nor belts to adjust during start up and service
[Lennox]Не нужно регулировать положение шкивов и натяжение ремней при вводе в эксплуатацию и во время технического обслуживания.
[Перевод Интент]
START-UP
Once the equipment has been placed in its definitive location, Schneider Electric CPCS factory-trained service personnel will energize and check the functionality of the equipment in all modes of operation and conduct various tests to obtain internal power supply voltage readings, temperature, pressure and other critical checks.
CPCS - Critical Power & Cooling Services
[Schneider Electric]
Putting into operation vs. Commissioning
Hello!
What is the difference in the use of terms "commissioning" and "putting into operation"?
Are they absolutely interchangeable or there are certain tints in their meaning, which limit their applicatoin in this or that context?
=======================================I am an engineer who works in the field, commissioning equipment.
Commissioning is the process where everything associated with the equipment is fully checked, all items are simulated or caused to happen, all possible events are tested, all methods of failure are accounted for. In other words, the complete design of the equipment is tested. Then, and only then, equipment is run and shown to be according to the design.
This is commissioning.
You could put equipment into operation without fully checking all systems. You can just run equipment and hope that all safety systems work according to plan.
That is the difference. No manufacturer or reputable engineering firm would simply put equipment into operation.
[ http://www.usingenglish.com/forum/threads/136100-Putting-into-operation-vs-Commissioning]Тематики
- система техн. обслуж. и ремонта техники
EN
внедрение
1. Процесс планомерного перевода объекта (предприятия или организации, системы управления, отдельного процесса или его элемента) из существующего состояния в новое, предусмотренное проектом.
2. Распространение нововведений, достижение практического использования прогрессивных идей, изобретений, результатов научных исследований.
[ http://www.lexikon.ru/dict/buh/index.html]Тематики
EN
инсталляция
1. Установка программного изделия на ПЭВМ.
2. Одно из ограничений на программное изделие при продаже его фирмой.
[Домарев В.В. Безопасность информационных технологий. Системный подход.]Тематики
EN
оборудование
оборудование
Совокупность связанных между собой частей или устройств, из которых по крайней мере одно движется, а также элементы привода, управления и энергетические узлы, которые предназначены для определенного применения, в частности для обработки, производства, перемещения или упаковки материала. К термину «оборудование» относят также машину и совокупность машин, которые так устроены и управляемы, что они функционируют как единое целое для достижения одной и той же цели.
[ГОСТ ЕН 1070-2003]
-
[IEV number 151-11-25 ]
оборудование
Оснащение, материалы, приспособления, устройства, механизмы, приборы, инструменты и другие принадлежности, используемые в качестве частей электрической установки или в соединении с ней.
[ ГОСТ Р МЭК 60204-1-2007]EN
equipment
single apparatus or set of devices or apparatuses, or the set of main devices of an installation, or all devices necessary to perform a specific task
NOTE – Examples of equipment are a power transformer, the equipment of a substation, measuring equipment.
[IEV number 151-11-25 ]
equipment
material, fittings, devices, components, appliances, fixtures, apparatus, and the like used as part of, or in connection with, the electrical equipment of machines
[IEC 60204-1-2006]FR
équipement, m
matériel, m
appareil unique ou ensemble de dispositifs ou appareils, ou ensemble des dispositifs principaux d'une installation, ou ensemble des dispositifs nécessaires à l'accomplissement d'une tâche particulière
NOTE – Des exemples d’équipement ou de matériel sont un transformateur de puissance, l’équipement d’une sous-station, un équipement de mesure.
[IEV number 151-11-25]Тематики
EN
- accessories
- apparatus
- appliance
- assets
- environment
- equipment
- facility
- fitment
- fixing
- gear
- H/W
- hardware
- hardware environment
- HW
- installation
- instrument
- instrumentation
- layout
- machinery
- outfit
- paraphernalia
- plant
- plant stock
- product
- provisions
- rig
- rigging
- set-up
- stock-in-trade
- tackle
- technical equipment
- technique
DE
FR
- machine
- matériel, m
- équipement, m
пуск в действие
монтаж
запуск
ввод в действие
—
[Л.Г.Суменко. Англо-русский словарь по информационным технологиям. М.: ГП ЦНИИС, 2003.]Тематики
Синонимы
EN
расположение
—
[Я.Н.Лугинский, М.С.Фези-Жилинская, Ю.С.Кабиров. Англо-русский словарь по электротехнике и электроэнергетике, Москва]Тематики
- электротехника, основные понятия
EN
установка
Условное наименование объекта в энергетических сооружениях, на который выпускается схема, например, главные цепи.
[ГОСТ 2.701-84]
установка
Условное наименование комплекса взаимосвязанного оборудования и (или) устройств.
[РД 01.120.00-КТН-228-06]
установка
Комплекс машин и оборудования, собранных в один или несколько агрегатов, предназначаемый для выполнения связанных технологической последовательностью работ
[Терминологический словарь по строительству на 12 языках (ВНИИИС Госстроя СССР)]EN
DE
FR
установка (напр., оборудования)
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
установка (оборудования)
Проведение необходимых монтажных и других подготовительных работ, предшествующих введению оборудования в эксплуатацию.
[Л.М. Невдяев. Телекоммуникационные технологии. Англо-русский толковый словарь-справочник. Под редакцией Ю.М. Горностаева. Москва, 2002]Тематики
- электросвязь, основные понятия
EN
установка (процесс)
сборка
монтаж
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
Синонимы
EN
электроустановка
Любое сочетание взаимосвязанного электрического оборудования в пределах данного пространства или помещения.
[Макаров Е.Ф. Справочник по электрическим сетям 0,4-35 кВ и 110-1150 кВ]
электроустановка
Совокупность машин, аппаратов, линий и вспомогательного оборудования (вместе с сооружениями и помещениями, в которых они установлены), предназначенных для производства, преобразования, трансформации, передачи, распределения электрической энергии и преобразования ее в другие виды энергии
[ПУЭ]
электроустановка
Энергоустановка, предназначенная для производства или преобразования, передачи, распределения или потребления электрической энергии.
[ ГОСТ 19431-84]
электроустановка
Совокупность взаимосвязанного электрического оборудования, имеющего согласованные характеристики и предназначенного для определенной цели.
[ ГОСТ Р МЭК 60050-826-2009]
установка
-
[IEV number 151-11-26]EN
electrical installation
assembly of associated electric equipment having co-ordinated characteristics to fulfil specific purposes
[IEV number 826-10-01]
installation
one apparatus or a set of devices and/or apparatuses associated in a given location to fulfil specified purposes, including all means for their satisfactory operation
[IEV number 151-11-26]FR
installation électrique, f
ensemble de matériels électriques associés ayant des caractéristiques coordonnées en vue d'une application donnée
[IEV number 826-10-01]
installation, f
appareil unique ou ensemble de dispositifs ou d'appareils associés en vue d’une application déterminée et situés en un emplacement donné, y compris les moyens nécessaires à leur fonctionnement correct
[IEV number 151-11-26]Параллельные тексты EN-RU
In water installations, harmonics are mainly generated by Variable Speed Drives, Ozone generators and UV lamps, which should all be carefully managed.
Применение в электроустановках систем водоснабжения приводов с регулируемой частотой вращения, генераторов озона и УФ-ламп приводит к загрязнению электросети гармоническими составляющими, которые нужно тщательно отфильтровывать.
[Перевод Интент]11.1 Стандарт распространяется на проектирование, монтаж и проверку электроустановок следующих объектов:
a) жилых зданий;
b) торговых предприятий;
c) общественных зданий;
d) производственных зданий;
e) сельскохозяйственных и садоводческих строений;
f) сборных зданий;
g) жилых автофургонов, стоянок для них и аналогичных участков;
h) строительных площадок, выставок, ярмарок и других временных сооружений;
i) пристаней для малых судов, используемых на досуге;
j) наружного освещения и установок аналогичного назначения (кроме перечисления е) в подразделе 11.3);
k) медицинских учреждений;
i) подвижных или транспортируемых средств;
m) фотоэлектрических систем;
n) низковольтных генераторных установок.
Примечание - Под терминами «здание», «предприятие», «строение», «сооружение», «учреждение» понимают также земельные участки и все, что на них находится.
... электроустановки потребителя, расположенные вне зданий
[ ГОСТ Р 50571. 1- 2009 ( МЭК 60364-1: 2005)]
По условиям электробезопасности электроустановки классифицируются следующим образом:
- электроустановки напряжением до 1 кВ с заземленной нейтралью
- электроустановки напряжением до 1 кВ с изолированной нейтралью
- электроустановки напряжением выше 1 кВ в сетях с эффективно заземленной нейтралью (с большими токами замыкания на землю)
- электроустановки напряжением выше 1 кВ в сетях с изолированной нейтралью (с малыми токами замыкания на землю).
Тематики
Близкие понятия
- электроустановка здания
- электроустановка квартиры
- электроустановка объекта
- электроустановка потребителя
- электроустановка промышленного предприятия
- электроустановки жилых и общественных зданий
Действия
- включение электроустановки
- заземление электроустановки
- зануление электроустановки
- защита электроустановки от перенапряжений
- монтаж электроустановки
- обслуживание электроустановки
- организация эксплуатации электроустановки
- присоединение электроустановки к электрической сети
- проектирование электроустановки
- сертификация электроустановки
- создание электроустановки
- техническое освидетельствование текущего состояния электроустановки
- устройство электроустановки
- эксплуатация электроустановки
Синонимы
EN
DE
- elektrische Anlage, f
FR
- installation électrique, f
3.1.3 система чистого помещения (installation): Чистое помещение или одна или несколько чистых зон со всеми относящимися к ним структурами, системами подготовки воздуха, обслуживания и утилизации [ИСО 14644-1 (пункт 2.1.3)].
Источник: ГОСТ Р ИСО 14644-3-2007: Чистые помещения и связанные с ними контролируемые среды. Часть 3. Методы испытаний оригинал документа
2.82 система чистого помещения (installation): Чистое помещение (2.33) или одна или несколько чистых зон (2.34) со всеми относящимися к ним структурами, системами подготовки воздуха, обслуживания и утилизации.
[ИСО 14644-1:1999, статья 2.1.3], [ИСО 14644-3:2005, статья 3.1.3]
Источник: ГОСТ Р ИСО 14644-6-2010: Чистые помещения и связанные с ними контролируемые среды. Часть 6. Термины оригинал документа
3.6.18 установка (installation): Первоначальный процесс, обеспечивающий ресурсу возможность осуществлять требуемую деятельность.
Источник: ГОСТ Р ИСО 15531-1-2008: Промышленные автоматизированные системы и интеграция. Данные по управлению промышленным производством. Часть 1. Общий обзор оригинал документа
Англо-русский словарь нормативно-технической терминологии > installation
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77 service
1) служба2) работа; функционирование3) эксплуатация4) обслуживание, сервис || обслуживать5) техническое обслуживание и (текущий) ремонт || проводить техническое обслуживание и (текущий) ремонт6) мн. ч. строит. коммуникации7) система энергоснабжения; энергоснабжение8) эл. подводка, абонентский ввод9) ж.-д., возд. сообщение; перевозки•to begin service — начинать эксплуатацию;to be in service — находиться в эксплуатации;to be ready for service — быть готовым к эксплуатации;to enter [to go into\] service — вводить в эксплуатацию;to lay services — прокладывать коммуникации;to map services — давать разбивку коммуникаций;to operate passenger service — эксплуатировать пассажирские поезда;to phase in the night service — вводить в эксплуатацию ночной поезд;to prepare for service — приводить в рабочее состояние; делать годным к эксплуатации;to provide service — обслуживать; ж.-д. обеспечивать сообщение;to put into service — вводить в эксплуатацию;-
absent-subscriber service
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aerodrome alerting service
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aerodrome control service
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aerodrome service
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aeronautical fixed service
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aeronautical information service
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aeronautical mobile service
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air service
-
air traffic service
-
air transport service
-
airport safety service
-
airport traffic service
-
alerting service
-
all-cargo service
-
antihail service
-
approach control service
-
around-the-clock service
-
braking service
-
broadcasting service
-
building service
-
bulk-commodity service
-
citizen's radio service
-
classification yard service
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coastal radio service
-
communication service
-
computer service
-
continuous service
-
delivery service
-
directory inquiry service
-
disrupt service
-
domestic service
-
electric train service
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emergency radio service
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emergency service
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engineering services
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environmental service
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facsimile service
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field service
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fire fighting service
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flight information service
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flight service
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flood-forecasting service
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flood-warning service
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freight service
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hail-suppression service
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heavy-unit train service
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high-pressure service
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high-utilization service
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house service
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information service
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intercity air service
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intermittent-duty service
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intermittent service
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international communication service
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interurban service
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irrigation management service
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irrigation service
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lighting service
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line service
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locomotive-hauled service
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logging services
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long-haul service
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mail service
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marine meteorological service
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mobile breakdown service
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mobile phone service
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multistop service
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network service
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on-orbit service
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passenger train service
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personal-radio service
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pooled service
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power service
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powerplant services
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predelivery service
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production services
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radar service
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radio monitoring service
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radiocommunication service
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radionavigation service
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radiopaging service
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rail defect detection service
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railway service
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rebuild service
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remote service
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rescue and recovery service
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rescue service
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revenue producing service
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revenue service
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reversing service
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running service
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sanitation service
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scheduled air service
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search and rescue service
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short-haul service
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short-time service
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shunting service
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shuttle service
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single service
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standby service
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station service
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stop-and-go service
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suburban service
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supervisory service
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telemetric service
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telephoto service
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television service
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temporary power service
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terminal information service
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through air service
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through railway service
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time-signal service
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traffic advisory service
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train service
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transfer service
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trial passenger service
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turnaround service
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value-added services
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videoconference service
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videophone service
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warning service
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water service
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waterway operating service
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weather service
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wire-line services
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yard service -
78 time
1) время || измерять [определять\] время; отмечать время; хронометрировать2) период [интервал\] времени4) срок; длительность, продолжительность5) темп; такт6) хронировать; синхронизировать; осуществлять привязку по времени7) регулировать взаимное положение фаз периодических процессов•time on — время включения; продолжительность пребывания во включенном состоянии;time to failure — наработка на отказ;time to repair — 1. наработка до ремонта 2. время ремонта-
absolute time
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acceleration time
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acceptance time
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access time
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acquisition time
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action time
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active repair time
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actual airborne time
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actual time
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actuation time
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addition time
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add time
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addressing time
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administrative time
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advance time
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ageing time
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aging time
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air cutting time
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air time
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alignment time
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annealing time
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apparent time
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arcing time
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arc time
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arrestment time
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arrival time
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assembly time
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astronomical time
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atomic time
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attack time
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attenuation time
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average time
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averaging time
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backup time
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baking time
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base transit time
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basin lag time
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batch-free time
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block-to-block time
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blowing time
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braking time
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break contact release time
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bridging time
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bubble penetration time
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bubble waiting time
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build up time
-
burning time
-
burn-off time
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burst time
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caging time
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calendar time
-
capture time
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carbonizing time
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carrier transit time
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cell production time
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chambering time
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changeover time
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characteristic time
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charge time
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check-in time
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chill time
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chock-to-chock time
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civil time
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clear time
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clearing time
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clipping time
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closing time
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compilation time
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computer time
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conditioning time
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contact time
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continuous recording time
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continuous time
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conversion time
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cooking time
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cool time
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critical time
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cumulative cutting time
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cumulative operating time
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cure time
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current impulse time
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current time
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current-rise time
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cutoff time
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cutting time
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cutting-in time
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cycle time
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damping time
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data-hold time
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daylight saving time
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dead time
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debatable time
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debugging time
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debug time
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decay time
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deceleration time
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definite minimum inverse operating time
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definite operating time
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deionization time
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delay time
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departure time
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detention time
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development time
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discharge time
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disconnection time
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discrete time
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divide time
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door-to-door time
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down time
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drift-transit time
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drift time
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drive time
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dropout time
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dust-free time
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dwelling time
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dwell time
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early finish time
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early start time
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effective time
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elapsed time
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emptying time
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engine ground test time
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engine operating time
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engine run-in time
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engineering time
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entry time
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ephemeris time
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erase time
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error-free running time
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estimated elapsed time
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estimated time of checkpoint
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execution time
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exposure time
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extinction time
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fall time
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fast time
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fault clearing time
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fault time
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fetch time
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firing time
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first copy-out time
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flash-off time
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flight block time
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flight dual instruction time
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flight duty time
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flight time
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flooding time
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floor-to-floor time
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flotation time
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flushing time
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flyover time
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forepumping time
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forge time
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freezing time
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fuel-doubling time
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fueling time
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fuel-residence time
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full operating time
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fusing time
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gate-controlled delay time
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gate-controlled rise time
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gate-controlled turn-on time
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gate-controlled-turn-off time
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gating time
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generation time
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Greenwich mean time
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gross-coking time
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ground operating time
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group delay time
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guard time
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gyro erection time
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handling time
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heat time
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high-water time
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holding time
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hold time
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hold-off time
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idle running time
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idle time
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ignition time
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impulse front time
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impulse tail time
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incidental time
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ineffective time
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initial setting time
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in-pile time
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installation time
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instruction time
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instrument flight time
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interaction time
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interarrival time
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interpulse time
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interrupting time
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intrinsic time
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ionization time
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keeping time
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lag time of flow
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lag time
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landing gear extension time
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latency time
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lead time
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leading-edge time
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life time
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local time
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lockage time
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locking time
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low-water time
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machine time
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maintenance time
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make contact operating time
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make contact release time
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make time
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make-break time
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manipulation time
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Markov's time
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Markov time
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maximum permissible short-circuit clearing time
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mean time between failures
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mean time between power failures
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melting time
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mill delay time
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mill pacing time
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mixing time
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modal transit time
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monolayer time
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moving time
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multiplication time
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near-real time
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Newtonian time
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no-load running time
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nonreal time
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normally-closed contact release time
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nuclear time
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nucleation time
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object time
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observation time
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off time
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off-stream time
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on time
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on-stream time
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opening time
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operating time
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operator's time
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optimized contact time
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orbit phasing time
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outage time
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output voltage setup time
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overall cycle time
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paralysis time
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partial operating time
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particle residence time
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peak-load time
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periodic time
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pickup time
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plasma time
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playing time
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poison override time
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predetermined time
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preroll time
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preset time
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press down time
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pressure resistance time
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prestrike time
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production pitch time
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productive time
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program fetch time
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program testing time
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propagation delay time
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propagation time
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proper time
-
pulling-out time
-
pull-out time
-
pull-in time
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pull-up time
-
pulse fall time
-
pulse rise time
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pulse time
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ramp time
-
reaction time
-
read time
-
readiness time
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reading readout time
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reading time
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real time
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recession time
-
reclosing dead time
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reclosing time
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recovery time
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reference time
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release time
-
remaining life time
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repair time
-
reset time
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residence time
-
response time
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restoration time
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retention time
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retrace time
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retrieval time
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reverberation time
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reversal time
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rewind time
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rig time
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rig total operating time
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rig-down time
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rig-up time
-
rise time
-
rolling time
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roughing time
-
round-trip time
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route-setting time
-
run time
-
run-down time
-
running time
-
running-down time
-
running-in time
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run-up time
-
scheduled departure time
-
screen time
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search time
-
seed-free time
-
seek time
-
selection time
-
self-extinction time
-
service time
-
serviceable time
-
servicing time
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set time
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setting time
-
settling time
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setup time
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shelf time
-
shipping time
-
ship time
-
shot time
-
sidereal time
-
signal modulation time
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signal transit time
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simulated time
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sludging time
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snubbing time
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soaking time
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solar time
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sowing time
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specified time
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spending time
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spray-on time
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stabilization time
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standard time
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standing time
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starting time
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start time
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station time
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stay-down time
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stock-descent time
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stop time
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stopping time
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storage time
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subtraction time
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subtract time
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succession time
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summer time
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sweep time
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switchgear operating time
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switching time
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switchover time
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tack-free time
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takedown time
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tap-to-tap time
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task time
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thermal death time
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throughput time
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time of arrival
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time of coincidence
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time of delivery
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time of fall
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time of flight
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time of persistence
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time of swing
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tool-in-cut time
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track time
-
traffic release time
-
trailing-edge time
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trailing time
-
transfer time
-
transient time
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transit time
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transition time
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translating time
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transmission time
-
traveling time
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travel time
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trigger time
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trip time
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troubleshooting time
-
true time
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turnaround time
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turn-off time
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turn-on time
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turnover time
-
turnround time
-
unit time
-
universal time
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up time
-
useful time
-
vehicle-off-the-road time
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viewing time
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waiting time
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wait time
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waiting-on-cement time
-
warm-up time
-
wavefront time
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wavetail time
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write time
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Zebra time
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zero time
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zonal time
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Zulu time -
79 industrial
1) промышленный
2) индустриальный
3) производственный
4) фабрично-заводский
5) заводской
– industrial architecture
– industrial automation
– industrial boiler
– industrial catalysis
– industrial computations
– industrial condensate
– industrial control
– industrial diamond
– industrial drive
– industrial economics
– industrial emissions
– industrial engine
– industrial engineering
– industrial hazard
– industrial lighting
– industrial load
– industrial lubricant
– industrial luminaire
– industrial network
– industrial noise
– industrial oil
– industrial oxygen
– industrial pipe-line
– industrial poison
– industrial pollution
– industrial safety
– industrial sanitation
– industrial scrap
– industrial structure
– industrial television
– industrial thermometer
– industrial waste
– industrial water
industrial gamma ray source — <engin.> гамма-установка промышленная
industrial power association — <engin.> объединение производственное энергетическое
powered industrial car — <industr.> автокар, автотележка
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80 system
1) система2) устройствоАнгло-русский словарь по полиграфии и издательскому делу > system
См. также в других словарях:
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