-
1 experimental design office
EDO, experimental design officeEnglish-Russian dictionary of planing, cross-planing and slotting machines > experimental design office
-
2 experimental design office
Военный термин: опытно-конструкторское бюроУниверсальный англо-русский словарь > experimental design office
-
3 experimental design office
машиностр. опытное конструкторское бюро, ОКБEnglish-Russian scientific dictionary > experimental design office
-
4 design
1) проект
2) дизайн
3) конструировать
4) конструкторский
5) конструкция
6) оптимальный
7) оформление
8) проектирование
9) проектировать
10) решение конструктивное
11) составлять план
12) планировка
13) рисовать
14) рисунок
15) синтез
16) расчетный
17) исполнение
18) конструирование
19) проектный
20) чертеж
21) конструктивный
– associate design
– automated design
– breadboard design
– circuit design
– civil-engineering design
– computer-aided design
– conceptual design
– contractor design
– cut-and-try design
– design an experiment
– design approach
– design arrangement
– design condition
– design draught
– design elevation
– design features
– design formula
– design load
– design longevity
– design moment
– design of an experiment
– design of experiment
– design of experiments
– design office
– design optimization
– design philosophy
– design pitch
– design power
– design pressure
– design procedure
– design quantity
– design reliability
– design schedule
– design stress
– design team
– design waterline
– design work
– detail design
– develop a design
– double-buttion design
– engineering design
– experimental design
– logical design
– modular design
– physical design
– preliminary design
– process design
– refine a design
– ruggedize the design
– simple in design
– structural design
– system design
– typographic design
– unconventional design
– unit-type design
completely randomized design — полностью рандомизированный план
conception phase of IC design — проработка логической структуры ИС
experimental design office — <engin.> бюро конструкторское опытное
principle of module design — <aeron.> принцип агрегатный
special design office — <engin.> бюро конструкторское особое
-
5 experimental
1) экспериментальный
2) опытовой
3) опытовый
4) опытный
5) основанный на опыте
6) испытательный
7) испытываемый
8) пробный
9) измеренный
– experimental aircraft
– experimental car
– experimental chemistry
– experimental conditions
– experimental data
– experimental design
– experimental equipment
– experimental error
– experimental investigation
– experimental tank
– experimental technique
– experimental verification
– experimental vessel
– gravitation experimental
experimental design office — <engin.> бюро конструкторское опытное
gravitation experimental tank — гравитационный опытовый бассейн
-
6 office
1) камеральный
2) канцелярский
3) станционный
4) бюро
5) вызываемый
6) контора
7) учреждение
8) конторский
9) рабочее место
10) министерство
– branch office
– call office
– capacity of office
– central office
– common-battery office
– community office
– control office
– dean's office
– design office
– dial office
– hydrometeorological office
– information office
– office cable
– office call
– office computation
– office equipment
– office manager
– office wire
– office work
– originating office
– post office
– receiving office
– repeater office
– satellite office
– sending office
– sub-control office
– switching pad office
– switching-selector-repeater office
– tandem office
– telegraph office
– terminal office
– terminating office
– toll office
– tributary office
experimental design office — <engin.> бюро конструкторское опытное
hydrometeorological forecast office — <meteor.> бюро гидрометеорологических прогнозов
installed capacity of office — установленная емкость станции
special design office — <engin.> бюро конструкторское особое
-
7 office
-
8 EDO
1) Компьютерная техника: Enhanced Data Output, Extended Data Output2) Военный термин: Extended Defence Officer, employee development officer, engineering duty officer, experimental and development operations, experimental design office, exploratory development objective, Explosive Ordnance Disposal (обезвреживание неразорвавшихся боеприпасов, взрывоопасных предметов)3) Техника: error demodulator output4) Сокращение: Extended Duration Orbiter, effective diameter of objective5) Вычислительная техника: Enhanced Data Out, Extended Duration Orbiter (Space), Extended Data Out (ram, RAM, DRAM, IC)6) Космонавтика: extended duration orbiter programme7) Сетевые технологии: DRAM extended-data-out DRAM8) Расширение файла: Extended Data Out9) NYSE. E D O Corporation10) НАСА: Engineering Design Order -
9 Edo
1) Компьютерная техника: Enhanced Data Output, Extended Data Output2) Военный термин: Extended Defence Officer, employee development officer, engineering duty officer, experimental and development operations, experimental design office, exploratory development objective, Explosive Ordnance Disposal (обезвреживание неразорвавшихся боеприпасов, взрывоопасных предметов)3) Техника: error demodulator output4) Сокращение: Extended Duration Orbiter, effective diameter of objective5) Вычислительная техника: Enhanced Data Out, Extended Duration Orbiter (Space), Extended Data Out (ram, RAM, DRAM, IC)6) Космонавтика: extended duration orbiter programme7) Сетевые технологии: DRAM extended-data-out DRAM8) Расширение файла: Extended Data Out9) NYSE. E D O Corporation10) НАСА: Engineering Design Order -
10 edo
1) Компьютерная техника: Enhanced Data Output, Extended Data Output2) Военный термин: Extended Defence Officer, employee development officer, engineering duty officer, experimental and development operations, experimental design office, exploratory development objective, Explosive Ordnance Disposal (обезвреживание неразорвавшихся боеприпасов, взрывоопасных предметов)3) Техника: error demodulator output4) Сокращение: Extended Duration Orbiter, effective diameter of objective5) Вычислительная техника: Enhanced Data Out, Extended Duration Orbiter (Space), Extended Data Out (ram, RAM, DRAM, IC)6) Космонавтика: extended duration orbiter programme7) Сетевые технологии: DRAM extended-data-out DRAM8) Расширение файла: Extended Data Out9) NYSE. E D O Corporation10) НАСА: Engineering Design Order -
11 EDO
EDO, employee development officer————————EDO, engineering duty officer————————EDO, experimental design office————————EDO, exploratory development objective————————EDO; E & DO, experimental and development operationsEnglish-Russian dictionary of planing, cross-planing and slotting machines > EDO
-
12 Porsche, Ferdinand
[br]b. 3 September 1875 Maffersdorf, Austriad. 30 January 1952 Stuttgart, Baden-Württemberg, Germany[br]Austrian automobile engineer, designer of the Volkswagen car.[br]At the age of fifteen, Porsche built a complete electrical installation for his home. In 1894 he went to technical school in Vienna. Four years later he became Manager of the test department of the Bela Egger concern, which later became part of the Brown Boveri organization where he became the first Assistant in the calculating section. In 1899 he joined the long-established coachbuilders Jacob Lohner, and in 1902 a car of his design with mixed drive won the 1,000 kg (2,200 lb) class in the Exelberg races. In 1905 he joined the Austro-Daimler Company as Technical Director; his subsequent designs included an 85 hp mixed-drive racing car in 1907 and in 1912 an air-cooled aircraft engine which came to be known in later years as the "great-grandfather" of the Volkswagen engine. In 1916, he became Managing Director of Austro-Daimler.In 1921 he designed his first small car, which, appearing under the name of Sasch, won its class in the 1922 Targa Florio, a gruelling road-race in Italy. In 1923 Porsche left Austro-Daimler and joined the Daimler Company in Untertürk-heim, near Stuttgart, Germany. In 1929 he joined the firm of Steyr in Austria as a director and chief engineer, and in 1930 he set up his own independent design office in Stuttgart. In 1932 he visited Russia, and in the same year completed the design calculations for the Auto-Union racing car.In 1934, with his son Ferry (b. 1909), he prepared a plan for the construction of the German "people's car", a project initiated by Adolf Hitler and his Nazi regime; in June of that year he signed a contract for the design work on the Volkswagen. Racing cars of his design were also successful in 1934: the rear-engined Auto-Union won the German Grand Prix, and another Au to-Union car took the Flying Kilometre speed record at 327 km/h (203.2 mph). In 1935 Daimler-Benz started preproduction on the Volkswagen. The first trials of the cars took place in the autumn of 1936, and the following year thirty experimental cars were built by Daimler-Benz. In that year, Porsche visited the United States, where he met Henry Ford; in October an Auto-Union took the Flying Five Kilometre record at 404.3 km/h (251.2 mph). On 26 May 1938, the foundation stone of the Volkswagen factory was laid in Wolfsburg, near Braunschweig, Germany.In October 1945 Ferdinand Porsche was arrested by a unit of the United States Army and taken to Hessen; the French army removed him to Baden-Baden, then to Paris and later to Dijon. During this time he was consulted by Renault engineers regarding the design of their 4CV and designed a diesel-engined tractor. He was finally released on 5 August 1947. His last major work before his death was the approval of the design for the Cisitalia Grand Prix car.[br]Principal Honours and DistinctionsPoetting Medal 1905. Officer's Cross of Franz Josef 1916. Honorary PhD, Vienna Technical University 1916. Honorary PhD, University of Stuttgart 1924.Further ReadingK.Ludvigsen, 1983, Porsche: Excellence Was Expected: The Complete History of the Sports and Racing Cars, London: Frederick Muller.T.Shuler and G.Borgeson, 1985, "Origin and Evolution of the VW Beetle", AutomobileQuarterly (May).M.Toogood, 1991, Porsche—Germany's Legend, London: Apple Press.IMcN -
13 Smeaton, John
SUBJECT AREA: Civil engineering, Mechanical, pneumatic and hydraulic engineering, Steam and internal combustion engines[br]b. 8 June 1724 Austhorpe, near Leeds, Yorkshire, Englandd. 28 October 1792 Austhorpe, near Leeds, Yorkshire, England[br]English mechanical and civil engineer.[br]As a boy, Smeaton showed mechanical ability, making for himself a number of tools and models. This practical skill was backed by a sound education, probably at Leeds Grammar School. At the age of 16 he entered his father's office; he seemed set to follow his father's profession in the law. In 1742 he went to London to continue his legal studies, but he preferred instead, with his father's reluctant permission, to set up as a scientific instrument maker and dealer and opened a shop of his own in 1748. About this time he began attending meetings of the Royal Society and presented several papers on instruments and mechanical subjects, being elected a Fellow in 1753. His interests were turning towards engineering but were informed by scientific principles grounded in careful and accurate observation.In 1755 the second Eddystone lighthouse, on a reef some 14 miles (23 km) off the English coast at Plymouth, was destroyed by fire. The President of the Royal Society was consulted as to a suitable engineer to undertake the task of constructing a new one, and he unhesitatingly suggested Smeaton. Work began in 1756 and was completed in three years to produce the first great wave-swept stone lighthouse. It was constructed of Portland stone blocks, shaped and pegged both together and to the base rock, and bonded by hydraulic cement, scientifically developed by Smeaton. It withstood the storms of the English Channel for over a century, but by 1876 erosion of the rock had weakened the structure and a replacement had to be built. The upper portion of Smeaton's lighthouse was re-erected on a suitable base on Plymouth Hoe, leaving the original base portion on the reef as a memorial to the engineer.The Eddystone lighthouse made Smeaton's reputation and from then on he was constantly in demand as a consultant in all kinds of engineering projects. He carried out a number himself, notably the 38 mile (61 km) long Forth and Clyde canal with thirty-nine locks, begun in 1768 but for financial reasons not completed until 1790. In 1774 he took charge of the Ramsgate Harbour works.On the mechanical side, Smeaton undertook a systematic study of water-and windmills, to determine the design and construction to achieve the greatest power output. This work issued forth as the paper "An experimental enquiry concerning the natural powers of water and wind to turn mills" and exerted a considerable influence on mill design during the early part of the Industrial Revolution. Between 1753 and 1790 Smeaton constructed no fewer than forty-four mills.Meanwhile, in 1756 he had returned to Austhorpe, which continued to be his home base for the rest of his life. In 1767, as a result of the disappointing performance of an engine he had been involved with at New River Head, Islington, London, Smeaton began his important study of the steam-engine. Smeaton was the first to apply scientific principles to the steam-engine and achieved the most notable improvements in its efficiency since its invention by Newcomen, until its radical overhaul by James Watt. To compare the performance of engines quantitatively, he introduced the concept of "duty", i.e. the weight of water that could be raised 1 ft (30 cm) while burning one bushel (84 lb or 38 kg) of coal. The first engine to embody his improvements was erected at Long Benton colliery in Northumberland in 1772, with a duty of 9.45 million pounds, compared to the best figure obtained previously of 7.44 million pounds. One source of heat loss he attributed to inaccurate boring of the cylinder, which he was able to improve through his close association with Carron Ironworks near Falkirk, Scotland.[br]Principal Honours and DistinctionsFRS 1753.Bibliography1759, "An experimental enquiry concerning the natural powers of water and wind to turn mills", Philosophical Transactions of the Royal Society.Towards the end of his life, Smeaton intended to write accounts of his many works but only completed A Narrative of the Eddystone Lighthouse, 1791, London.Further ReadingS.Smiles, 1874, Lives of the Engineers: Smeaton and Rennie, London. A.W.Skempton, (ed.), 1981, John Smeaton FRS, London: Thomas Telford. L.T.C.Rolt and J.S.Allen, 1977, The Steam Engine of Thomas Newcomen, 2nd edn, Hartington: Moorland Publishing, esp. pp. 108–18 (gives a good description of his work on the steam-engine).LRD -
14 Gresley, Sir Herbert Nigel
[br]b. 19 June 1876 Edinburgh, Scotlandd. 5 April 1941 Hertford, England[br]English mechanical engineer, designer of the A4-class 4–6–2 locomotive holding the world speed record for steam traction.[br]Gresley was the son of the Rector of Netherseale, Derbyshire; he was educated at Marlborough and by the age of 13 was skilled at making sketches of locomotives. In 1893 he became a pupil of F.W. Webb at Crewe works, London \& North Western Railway, and in 1898 he moved to Horwich works, Lancashire \& Yorkshire Railway, to gain drawing-office experience under J.A.F.Aspinall, subsequently becoming Foreman of the locomotive running sheds at Blackpool. In 1900 he transferred to the carriage and wagon department, and in 1904 he had risen to become its Assistant Superintendent. In 1905 he moved to the Great Northern Railway, becoming Superintendent of its carriage and wagon department at Doncaster under H.A. Ivatt. In 1906 he designed and produced a bogie luggage van with steel underframe, teak body, elliptical roof, bowed ends and buckeye couplings: this became the prototype for East Coast main-line coaches built over the next thirty-five years. In 1911 Gresley succeeded Ivatt as Locomotive, Carriage \& Wagon Superintendent. His first locomotive was a mixed-traffic 2–6–0, his next a 2–8–0 for freight. From 1915 he worked on the design of a 4–6–2 locomotive for express passenger traffic: as with Ivatt's 4 4 2s, the trailing axle would allow the wide firebox needed for Yorkshire coal. He also devised a means by which two sets of valve gear could operate the valves on a three-cylinder locomotive and applied it for the first time on a 2–8–0 built in 1918. The system was complex, but a later simplified form was used on all subsequent Gresley three-cylinder locomotives, including his first 4–6–2 which appeared in 1922. In 1921, Gresley introduced the first British restaurant car with electric cooking facilities.With the grouping of 1923, the Great Northern Railway was absorbed into the London \& North Eastern Railway and Gresley was appointed Chief Mechanical Engineer. More 4–6– 2s were built, the first British class of such wheel arrangement. Modifications to their valve gear, along lines developed by G.J. Churchward, reduced their coal consumption sufficiently to enable them to run non-stop between London and Edinburgh. So that enginemen might change over en route, some of the locomotives were equipped with corridor tenders from 1928. The design was steadily improved in detail, and by comparison an experimental 4–6–4 with a watertube boiler that Gresley produced in 1929 showed no overall benefit. A successful high-powered 2–8–2 was built in 1934, following the introduction of third-class sleeping cars, to haul 500-ton passenger trains between Edinburgh and Aberdeen.In 1932 the need to meet increasing road competition had resulted in the end of a long-standing agreement between East Coast and West Coast railways, that train journeys between London and Edinburgh by either route should be scheduled to take 8 1/4 hours. Seeking to accelerate train services, Gresley studied high-speed, diesel-electric railcars in Germany and petrol-electric railcars in France. He considered them for the London \& North Eastern Railway, but a test run by a train hauled by one of his 4–6–2s in 1934, which reached 108 mph (174 km/h), suggested that a steam train could better the railcar proposals while its accommodation would be more comfortable. To celebrate the Silver Jubilee of King George V, a high-speed, streamlined train between London and Newcastle upon Tyne was proposed, the first such train in Britain. An improved 4–6–2, the A4 class, was designed with modifications to ensure free running and an ample reserve of power up hill. Its streamlined outline included a wedge-shaped front which reduced wind resistance and helped to lift the exhaust dear of the cab windows at speed. The first locomotive of the class, named Silver Link, ran at an average speed of 100 mph (161 km/h) for 43 miles (69 km), with a maximum speed of 112 1/2 mph (181 km/h), on a seven-coach test train on 27 September 1935: the locomotive went into service hauling the Silver Jubilee express single-handed (since others of the class had still to be completed) for the first three weeks, a round trip of 536 miles (863 km) daily, much of it at 90 mph (145 km/h), without any mechanical troubles at all. Coaches for the Silver Jubilee had teak-framed, steel-panelled bodies on all-steel, welded underframes; windows were double glazed; and there was a pressure ventilation/heating system. Comparable trains were introduced between London Kings Cross and Edinburgh in 1937 and to Leeds in 1938.Gresley did not hesitate to incorporate outstanding features from elsewhere into his locomotive designs and was well aware of the work of André Chapelon in France. Four A4s built in 1938 were equipped with Kylchap twin blast-pipes and double chimneys to improve performance still further. The first of these to be completed, no. 4468, Mallard, on 3 July 1938 ran a test train at over 120 mph (193 km/h) for 2 miles (3.2 km) and momentarily achieved 126 mph (203 km/h), the world speed record for steam traction. J.Duddington was the driver and T.Bray the fireman. The use of high-speed trains came to an end with the Second World War. The A4s were then demonstrated to be powerful as well as fast: one was noted hauling a 730-ton, 22-coach train at an average speed exceeding 75 mph (120 km/h) over 30 miles (48 km). The war also halted electrification of the Manchester-Sheffield line, on the 1,500 volt DC overhead system; however, anticipating eventual resumption, Gresley had a prototype main-line Bo-Bo electric locomotive built in 1941. Sadly, Gresley died from a heart attack while still in office.[br]Principal Honours and DistinctionsKnighted 1936. President, Institution of Locomotive Engineers 1927 and 1934. President, Institution of Mechanical Engineers 1936.Further ReadingF.A.S.Brown, 1961, Nigel Gresley, Locomotive Engineer, Ian Allan (full-length biography).John Bellwood and David Jenkinson, Gresley and Stanier. A Centenary Tribute (a good comparative account).See also: Bulleid, Oliver Vaughan SnellPJGRBiographical history of technology > Gresley, Sir Herbert Nigel
-
15 Biles, Sir John Harvard
SUBJECT AREA: Ports and shipping[br]b. 1854 Portsmouth, Englandd. 27 October 1933 Scotland (?)[br]English naval architect, academic and successful consultant in the years when British shipbuilding was at its peak.[br]At the conclusion of his apprenticeship at the Royal Dockyard, Portsmouth, Biles entered the Royal School of Naval Architecture, South Kensington, London; as it was absorbed by the Royal Naval College, he graduated from Greenwich to the Naval Construction Branch, first at Pembroke and later at the Admiralty. From the outset of his professional career it was apparent that he had the intellectual qualities that would enable him to oversee the greatest changes in ship design of all time. He was one of the earliest proponents of the revolutionary work of the hydrodynamicist William Froude.In 1880 Biles turned to the merchant sector, taking the post of Naval Architect to J. \& G. Thomson (later John Brown \& Co.). Using Froude's Law of Comparisons he was able to design the record-breaking City of Paris of 1887, the ship that started the fabled succession of fast and safe Clyde bank-built North Atlantic liners. For a short spell, before returning to Scotland, Biles worked in Southampton. In 1891 Biles accepted the Chair of Naval Architecture at the University of Glasgow. Working from the campus at Gilmorehill, he was to make the University (the oldest school of engineering in the English-speaking world) renowned in naval architecture. His workload was legendary, but despite this he was admired as an excellent lecturer with cheerful ways which inspired devotion to the Department and the University. During the thirty years of his incumbency of the Chair, he served on most of the important government and international shipping committees, including those that recommended the design of HMS Dreadnought, the ordering of the Cunarders Lusitania and Mauretania and the lifesaving improvements following the Titanic disaster. An enquiry into the strength of destroyer hulls followed the loss of HMS Cobra and Viper, and he published the report on advanced experimental work carried out on HMS Wolf by his undergraduates.In 1906 he became Consultant Naval Architect to the India Office, having already set up his own consultancy organization, which exists today as Sir J.H.Biles and Partners. His writing was prolific, with over twenty-five papers to professional institutions, sundry articles and a two-volume textbook.[br]Principal Honours and DistinctionsKnighted 1913. Knight Commander of the Indian Empire 1922. Master of the Worshipful Company of Shipwrights 1904.Bibliography1905, "The strength of ships with special reference to experiments and calculations made upon HMS Wolf", Transactions of the Institution of Naval Architects.1911, The Design and Construction of Ships, London: Griffin.Further ReadingC.A.Oakley, 1973, History of a Facuity, Glasgow University.FMWBiographical history of technology > Biles, Sir John Harvard
-
16 work
1) работа; труд; действие; функционирование2) обработка3) обрабатываемая заготовка; обрабатываемая деталь; обрабатываемое изделие4) механизм5) конструкция6) мн. ч. завод; фабрика; мастерские; технические сооружения; строительные работы7) мн. ч. работающие части механизма, подвижные органы механизма8) работать; обрабатывать9) действовать, двигаться, поворачиваться ( о подвижных частях механизмов)10) коробиться•work performed with materials in a smaller quantity — работа, выполненная с недостаточным использованием материалов
work performed without the necessary diligence — работа, выполненная небрежно
work which is not in accordance with specifications — работа, не соответствующая техническим требованиям
work which is not in accordance with the requirements of the engineer — работа, не отвечающая требованиям инженера
to work down — 1) осаживать ( вниз); оседать 2) обрабатывать на меньший размер
to work in — вделывать, вмонтировать
to work into — углубляться во что-либо, уходить внутрь
to work off — 1) соскакивать, соскальзывать ( во время работы) 2) снимать (напр. стружку)
to work on — действовать на что-либо, оказывать влияние на что-либо
to work out — 1) разрабатывать (план, проект) 2) вырабатывать (что-либо) из чего-либо (напр. вытачивать, выстрагивать, выфрезеровывать) 3) выскакивать, выпадать во время работы
to work over — обрабатывать вторично, перерабатывать, подвергать переработке
to work upon — действовать на что-либо, оказывать влияние на что-либо
- work executed - work in process - work of acceleration - work of deformation - work of ideal cycle - work of resistance - work on arbour - works under way - access to works - actual progress of works - amendment of the date of completion of works - amount of the executed works - applied work - asphalt work - assessment of works - auxiliary work - bank work - bargain work - beat-cob work - betterment work - black and white work - bluff work - bonus work - bosh brick work - branch work - branched work - bright work - carpenter's work - cast steel work - cessation of works - chased work - check of works - checking of works - chequer work - chequered work - cindering work - civil works - civil and erection works - clay work - clearing work - commencement of works - completed works - completion of works - concrete work - diversion work - condensing works - construction works - consumed work - continuous execution of works - contract works - cost of works - cost of uncovering works - covered-up works - date of commencement of works - date of completion of works - day-to-day work - day wage work - dead work - defective works - delay in completion of works - delayed completion of works - demolition works - description of works - design and survey works - desilting works - diaper work of bricklaying - drainage work - dredge work - dressing works - drove work - earth works - effective work - embossed work - emergency works - engineering works - erecting works - erection works - examination of works - excavation works - execution of works - expected period of works - extension of the time for completion of works - external work - face work - fascine work - field works - finely finished work - finishing work - fitter's works - flat trellis work - float work - forming work - forthcoming works - frosted rustic work - gauge work - gauged work - geologic works - geological works - grading works - gunite work - heading work - health work - hot work - hydro-meteorologic works - hydro-meteorological works - inadequate progress of works - incomplete lattice work - indicated work - inlaid work - inspection of works - installation work - intake works - irrigation works - jack works - jobbing work - joggle work - ladder work - line work - link work - locksmith's work - machine work - main works - maintenance work - management of works - maritime works - metal work - milling work - motion work - multiple lattice work - nature of works - neat work - negative work - night work - no-load work - odd works - on the site works - order of execution of works - outlet work - outstanding works - overhead works - panel work - partially completed works - part of works - paternoster work - period of works - period of execution of works - permanent works - pilot-scale work - plane frame work - planer work - pneumatic work - port work - portion of works - pottery work - precision work - preliminary works - preparatory works - pressure cementing work - programme of works - progress of works - proper execution of works - prospecting works - public works - pump works - quantity of works - rag work - R and D work - random work - range work - reclamation work - recoverable-strain work - recuperated work - reflected work - reliability of works - relief work - remedial works - repair work - repairing work - required work - research work - resumption of works - retaining works - reticulated work - right of access to works - river training works - rustic work - safety of works - schedule of works - scope of work - shaper work - sheet metal work - shift work - smith and founder work - spillway works - starting work - step-by-step check of works - step-by-step checking of works - stick and rag work - stoppage of works - subcontract works - submarine work - substituted works - sufficiency of works - supervision for works - supervision for of works - survey work - survey and research works - suspension of works - taking over of works - task work - temporary work - test work - test-hole work - three-coat work - through-carved work - time for completion of works - timely completion of works - tool work - topiary work - topographic works - topographical works - track work - treatment works - trellis work - trench work - trestle work - turning work - uncompleted works - uncovering of works - upon completion of works - variations in works - variations of works - volume of works - wiring work - X-ray workto complete works (in the time stipulated in the contract) — завершать работы (в срок, оговорённый в контракте)
* * *1. работа2. изделие3. обработка4. возводимый объект (строительства) ( по подрядному договору); конструкция, сооружение5. работа, мощность6. pl сооружение, сооружения7. pl завод, фабрика, мастерскиеwork 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 of deformationwork on schedule — работы в процессе выполнения ( по графику); работы, предусмотренные планом [графиком]
- 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 -
17 Bailey, Sir Donald Coleman
SUBJECT AREA: Civil engineering[br]b. 15 September 1901 Rotherham, Yorkshire, Englandd. 5 May 1985 Bournemouth, Dorset, England[br]English engineer, designer of the Bailey bridge.[br]Bailey was educated at the Leys School, Cambridge, before going to Sheffield University where he studied for a degree in engineering. He joined the Civil Service in 1928 and was posted to the staff of the Experimental Bridging Establishment of the Ministry of Supply at Christchurch, Hampshire. There he continued his boyhood hobby of making model bridges of wood and string. He evolved a design for a prefabricated metal bridge assembled from welded panels linked by pinned joints; this became known as the Bailey bridge. Its design was accepted by the War Office in 1941 and from then on it was used throughout the subsequent conflict of the Second World War. It was a great improvement on its predecessor, the Inglis bridge, designed by a Cambridge University professor of engineering, Charles Inglis, with tubular members that were 10 or 12 ft (3.66 m) long; this bridge was notoriously difficult to construct, particularly in adverse weather conditions, whereas the Bailey bridge's panels and joints were far more manageable and easy to assemble. The simple and standardized component parts of the Bailey bridge made it highly adaptable: it could be strengthened by increasing the number of truss girders, and wide rivers could be crossed by a series of Bailey bridges connected by pontoons. Field Marshal Montgomery is recorded as saying that without the Bailey bridge we should not have won the war'.[br]Principal Honours and DistinctionsKnighted 1946.Further ReadingObituary, 1985, The Guardian 6 May.IMcNBiographical history of technology > Bailey, Sir Donald Coleman
-
18 Kirkaldy, David
[br]b. 4 April 1820 Mayfield, Dundee, Scotlandd. 25 January 1897 London, England[br]Scottish engineer and pioneer in materials testing.[br]The son of a merchant of Dundee, Kirkaldy was educated there, then at Merchiston Castle School, Edinburgh, and at Edinburgh University. For a while he worked in his father's office, but with a preference for engineering, in 1843 he commenced an apprenticeship at the Glasgow works of Robert Napier. After four years in the shops he was transferred to the drawing office and in a very few years rose to become Chief. Here Kirkaldy demonstrated a remarkable talent both for the meticulous recording of observations and data and for technical drawing. His work also had an aesthetic appeal and four of his drawings of Napier steamships were shown at the Paris Exhibition of 1855, earning both Napier and Kirkaldy a medal. His "as fitted" set of drawings of the Cunard Liner Persia, which had been built in 1855, is now in the possession of the National Maritime Museum at Greenwich, London; it is regarded as one of the finest examples of its kind in the world, and has even been exhibited at the Royal Academy in London.With the impending order for the Royal Naval Ironclad Black Prince (sister ship to HMS Warrior, now preserved at Portsmouth) and for some high-pressure marine boilers and engines, there was need for a close scientific analysis of the physical properties of iron and steel. Kirkaldy, now designated Chief Draughtsman and Calculator, was placed in charge of this work, which included comparisons of puddled steel and wrought iron, using a simple lever-arm testing machine. The tests lasted some three years and resulted in Kirkaldy's most important publication, Experiments on Wrought Iron and Steel (1862, London), which gained him wide recognition for his careful and thorough work. Napier's did not encourage him to continue testing; but realizing the growing importance of materials testing, Kirkaldy resigned from the shipyard in 1861. For the next two and a half years Kirkaldy worked on the design of a massive testing machine that was manufactured in Leeds and installed in premises in London, at The Grove, Southwark.The works was open for trade in January 1866 and engineers soon began to bring him specimens for testing on the great machine: Joseph Cubitt (son of William Cubitt) brought him samples of the materials for the new Blackfriars Bridge, which was then under construction. Soon The Grove became too cramped and Kirkaldy moved to 99 Southwark Street, reopening in January 1874. In the years that followed, Kirkaldy gained a worldwide reputation for rigorous and meticulous testing and recording of results, coupled with the highest integrity. He numbered the most distinguished engineers of the time among his clients.After Kirkaldy's death, his son William George, whom he had taken into partnership, carried on the business. When the son died in 1914, his widow took charge until her death in 1938, when the grandson David became proprietor. He sold out to Treharne \& Davies, chemical consultants, in 1965, but the works finally closed in 1974. The future of the premises and the testing machine at first seemed threatened, but that has now been secured and the machine is once more in working order. Over almost one hundred years of trading in South London, the company was involved in many famous enquiries, including the analysis of the iron from the ill-fated Tay Bridge (see Bouch, Sir Thomas).[br]Principal Honours and DistinctionsInstitution of Engineers and Shipbuilders in Scotland Gold Medal 1864.Bibliography1862, Results of an Experimental Inquiry into the Tensile Strength and Other Properties of Wrought Iron and Steel (originally presented as a paper to the 1860–1 session of the Scottish Shipbuilders' Association).Further ReadingD.P.Smith, 1981, "David Kirkaldy (1820–97) and engineering materials testing", Transactions of the Newcomen Society 52:49–65 (a clear and well-documented account).LRD / FMW -
19 Murray, John Mackay
SUBJECT AREA: Ports and shipping[br]b. 25 June 1902 Glasgow, Scotlandd. 5 August 1966 Maplehurst, Sussex, England[br]Scottish naval architect who added to the understanding of the structural strength of ships.[br]Murray was educated in Glasgow at Allan Glen's School and then at the University, from which he graduated in naval architecture in 1922. He served an apprenticeship simultaneously with Barclay Curle \& Co., rising to the rank of Assistant Shipyard Manager before leaving in 1927 to join Lloyd's Register of Shipping. After an initial year in Newcastle, he joined the head office in London, which was to be base for the remainder of his working life. Starting with plan approval, he worked his way to experimental work on ship structures and was ultimately given the massive task of revising Lloyd's Rules and placing them on a scientific basis. During the Second World War he acted as liaison officer between Lloyd's and the Admiralty. Throughout his career he presented no fewer than twenty-two papers on ship design, and of these nearly half dealt with hull longitudinal strength. This work won him considerable acclaim and several awards and was of fundamental importance to the shipping industry. The Royal Institution of Naval Architects honoured Murray in 1960 by inviting him to present one of the only two papers read at their centenary meeting: "Merchant ships 1860–1960". At Lloyd's Register he rose to Chief Ship Surveyor, and at the time of his death was Honorary Vice-President of the Royal Institution of Naval Architects.[br]Principal Honours and DistinctionsMBE 1946. Honorary Vice-President, Royal Institution of Naval Architects. Royal Institution of Naval Architects Froude Gold Medal. Institute of Marine Engineers Silver Medal. Premium of the Institution of Engineers and Shipbuilders in Scotland.FMW
См. также в других словарях:
Design–build — Design build (or design/build, and abbreviated D–B or D/B accordingly) is a project delivery system used in the construction industry. It is a method to deliver a project in which the design and construction services are contracted by a single… … Wikipedia
design — {{Roman}}I.{{/Roman}} noun 1 making drawings of how sth should be made ADJECTIVE ▪ graphic ▪ computer aided ▪ a specialist in computer aided design ▪ architectural, industrial … Collocations dictionary
Office of Naval Research — ONR logo The Office of Naval Research (ONR), headquartered in Arlington, Virginia (Ballston), is the office within the United States Department of the Navy that coordinates, executes, and promotes the science and technology programs of the U.S.… … Wikipedia
Office of Nuclear Energy — Current Assistant Secretary for Nuclear Energy, Dr. Peter B. Lyons The Office of Nuclear Energy promotes nuclear power as a resource capable of meeting the Nation s energy, environmental and national security needs by resolving technical and… … Wikipedia
Intelligent design — This article is about intelligent design as promulgated by the Discovery Institute. For other uses, see Intelligent design (disambiguation). For the philosophical argument from design , see Teleological argument … Wikipedia
University of Illinois Experimental Dairy Farm Historic District — Infobox nrhp name = University of Illinois Experimental Dairy Farm Historic District nrhp type = hd caption = A view of the University of Illinois Experimental Dairy Farm Historic District location = Urbana, Champaign County, Illinois, USA… … Wikipedia
Nuclear weapon design — The first nuclear weapons, though large, cumbersome and inefficient, provided the basic design building blocks of all future weapons. Here the Gadget device is prepared for the first nuclear test: Trinity. Nuclear weapon designs are physical,… … Wikipedia
Manchester Small-Scale Experimental Machine — Replica of the Small Scale Experimental Machine (SSEM) at the Museum of Science and Industry in Castlefield, Manchester … Wikipedia
Top-down and bottom-up design — Top down and bottom up are strategies of information processing and knowledge ordering, mostly involving software, but also other humanistic and scientific theories (see systemics). In practice, they can be seen as a style of thinking and… … Wikipedia
Crime prevention through environmental design — Criminology and penology Theories Causes and correlates of crime Anomie Differential association theory Deviance … Wikipedia
Intelligent Design — (engl. „intelligenter Entwurf“, „intelligente Gestaltung“; abgekürzt ID) ist die Auffassung, dass sich bestimmte Eigenschaften des Universums und des Lebens auf der Erde am besten durch einen intelligenten Urheber erklären lassen und nicht durch… … Deutsch Wikipedia