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1 steel construction for hydraulic engineering
English-german engineering dictionary > steel construction for hydraulic engineering
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2 construction
1. строительство, постройка, возведение2. конструкция; конструктивная система; сооружение3. схема устройства4. построениеconstruction of formwork — опалубочные работы, возведение опалубки
acoustic construction — строительство с соблюдением установленных требований в отношении звукоизоляции
arched construction — арочная конструкция; здание с арочным или сводчатым перекрытием
balloon frame construction — деревянный каркас с балками, опирающимися на бобышки
beam-and-column construction — балочно-стоечная конструкция, балочно-стоечный каркас
beam-and-girder construction — балочная конструкция, балочная клетка, система перекрёстных балок
bolted construction — болтовая конструкция, конструкция с болтовыми соединениями
bridge construction fully supported on staging — бетонирование пролётного строения на сплошных подмостях
building construction — жилищное строительство, строительство жилых и общественных зданий
5. строительство из монолитного бетона6. конструкция из монолитного бетона, монолитная конструкция7. сборно-монолитная бетонная конструкция8. строительство из сборно-монолитного бетона9. конструкция из стальных холодногнутых профилей10. возведение сооружений из стальных холодногнутых профилей11. строительство в холодное время года12. строительство в районах Крайнего Севера13. комбинированная конструкцияtype of construction — тип конструкции; вид конструкции
14. сталежелезобетонная конструкцияconstruction type — тип конструкции; вид конструкции
15. сборно-монолитная железобетонная конструкция16. бетонная конструкция17. бетонные работы18. строительство из кирпича19. кирпичные конструкцииexternal construction exposed to the weather — наружная конструкция, подверженная воздействию погодных факторов
filler-joist construction — конструкция перекрытия или покрытия, состоящая из стальных балок с заполнением из керамических или бетонных блоков
20. устройство полов21. конструкция пола22. конструкция перекрытияframe construction — рамная конструкция; каркасная деревянная конструкция
23. высотная конструкция24. строительство высотных домов25. конструкция заводского изготовления26. сборное строительство с использованием элементов заводского изготовленияin-situ reinforced concrete construction — монолитная железобетонная конструкция; строительство монолитных железобетонных конструкций
large panel construction — крупнопанельное строительство; изготовление крупных железобетонных панелей
large precast concrete panel construction — строительство с применением крупных железобетонных панелей
27. строительство из лёгких конструкций28. лёгкая конструкция29. сборное строительство из объёмных блоковconstruction unit — блок; модуль; узел
30. сооружение, монтируемое из пространственных блоковmultistage construction — поэтапное строительство, строительство в несколько очередей
31. панельная конструкция32. поэтапное строительство по совмещённому графику33. строительство асфальтобетонных покрытий дорог и улиц методом последовательного наложения по графику конструктивных слоёв на участках большой протяжённостиpost-and-lintel construction — балочно-стоечная конструкция; балочно-стоечный каркас
34. сборное строительство35. сборная конструкцияsteel construction — стальная конструкция, металлоконструкция
36. сборная железобетонная панельная конструкции37. панельное строительствоpre-post-tensioned construction — сборная или сборно-монолитная железобетонная конструкция, преднапряжённые элементы которой дополнительно стягиваются напрягаемой арматурой после возведения
pretensioned construction — предварительно напряжённая железобетонная конструкция с натяжением арматуры на упоры
protected construction — конструкция, заданный предел огнестойкости всех несущих элементов которой обеспечен соответствующими мерами защиты
38. железобетонная конструкция39. строительство из железобетона40. дорожное строительство41. дорожная одежда42. рубленый дом; сруб43. строительство бревенчатых стенsegmental span-by-span construction — попролётное навесное бетонирование секциями в передвижном агрегате
44. стальная конструкцияmodular construction — модульная конструкция; модульная структура
45. возведение стальных конструкцийstressed-skin construction — пространственная стержневая конструкция с напряжённой ограждающей оболочкой
46. строительство башенных сооружений47. башенная конструкцияunbonded posttension construction — преднапряжённая конструкция без сцепления напрягаемой арматуры с бетоном
wet construction — строительство с применением «мокрых» процессов
48. деревянная конструкция49. строительство из дерева -
3 construction
1) строительство; стройка; постройка;2) конструкция; сооружение; строение; здание•- construction of diagram - construction of penetration macadam - construction of traffic facilities - adobe construction - agricultural building construction - airfield construction - air-supported construction - airtight construction - aseismic constructions - avalanche-protection construction - balanced construction of plywood - balloon frame construction - basic construction - BBS construction - beam and girder construction - bearing-wall construction - block construction - brick construction - bridge construction - building construction - cable constructions - cage construction - capital construction - carry-over construction - cast-in-place construction - cast-in-situ constructions - catenary construction - civil engineering construction - civilian construction - completion of construction - complex construction - composite construction - concrete construction - concrete-bent construction - contract construction - cost of construction - cross-wall construction - dam construction - date of completion of construction - delay in construction - delay in the construction of a project - double-skin construction - dry construction - dry-wall construction - dust-tight construction - environment-oriented home construction - fast construction - feasibility of the construction of a project - fill construction - fireproof construction - fixed period of construction - frame construction - fully-prefabricated construction - girderless construction - glued construction - high-rise construction - hipped-plate construction - hollow-wood construction - housing construction - hydraulic engineering construction - incombustible construction - incompleted construction project - individual housing construction - industrial building construction - industrialized construction - industrialized construction with apartments modules - integrated construction - laminated construction - large-panel constructions - large-sized block constructions - layer-built construction - levee construction - lift-slab construction - lightweight construction - load-carrying construction - lumber construction - lumber core construction - masonry construction - metal construction - methods of construction - mixed construction - modular construction - municipal construction - multiply construction - mushroom construction - mushroom slab construction - non-fireproof construction - ordinary construction - organization of construction - pace of construction - pan construction - panel construction - panelled construction - partially-prestressed composite construction - period of construction - plastic construction - plated construction - platform frame construction - pneumatic construction - portable unit construction - post-and-beam construction - posttensioned construction - power and water supply of the construction - power plant construction - pre-assembled member construction - precast construction - precast and cast-in-situ construction - precast concrete construction - precast panel construction - prefabricated construction - prefabricated demountable constructions - preload construction of tank - pre-posttensioned concrete construction - prestressed constructions - pretensioned concrete constructions reinforced with wires - pretensioned concrete constructions - project construction - protected metal construction - rammed earth construction - rammed loam construction - region of construction - reinforced brick construction - reinforced concrete construction - reinforced masonry construction - road construction - road-mix construction - sandwich construction - section construction - sectional construction - shell construction - simple in construction - skeleton construction - slow-burning construction - space grid constructions - stage construction - steel construction - steel-frame construction - steel-plate constructions - stone constructions - supporting construction - suspended constructions - temporary construction - thin-shell construction - thin-slab construction - thin-wall construction - total-prefabricated construction - two-dimensional construction - under construction - unit construction - urban construction - veneered construction - wall-bearing construction - water-front construction - welded construction - winter building construction - wood construction -
4 Whitworth, Sir Joseph
[br]b. 21 December 1803 Stockport, Cheshire, Englandd. 22 January 1887 Monte Carlo, Monaco[br]English mechanical engineer and pioneer of precision measurement.[br]Joseph Whitworth received his early education in a school kept by his father, but from the age of 12 he attended a school near Leeds. At 14 he joined his uncle's mill near Ambergate, Derbyshire, to learn the business of cotton spinning. In the four years he spent there he realized that he was more interested in the machinery than in managing a cotton mill. In 1821 he obtained employment as a mechanic with Crighton \& Co., Manchester. In 1825 he moved to London and worked for Henry Maudslay and later for the Holtzapffels and Joseph Clement. After these years spent gaining experience, he returned to Manchester in 1833 and set up in a small workshop under a sign "Joseph Whitworth, Tool Maker, from London".The business expanded steadily and the firm made machine tools of all types and other engineering products including steam engines. From 1834 Whitworth obtained many patents in the fields of machine tools, textile and knitting machinery and road-sweeping machines. By 1851 the company was generally regarded as the leading manufacturer of machine tools in the country. Whitworth was a pioneer of precise measurement and demonstrated the fundamental mode of producing a true plane by making surface plates in sets of three. He advocated the use of the decimal system and made use of limit gauges, and he established a standard screw thread which was adopted as the national standard. In 1853 Whitworth visited America as a member of a Royal Commission and reported on American industry. At the time of the Crimean War in 1854 he was asked to provide machinery for manufacturing rifles and this led him to design an improved rifle of his own. Although tests in 1857 showed this to be much superior to all others, it was not adopted by the War Office. Whitworth's experiments with small arms led on to the construction of big guns and projectiles. To improve the quality of the steel used for these guns, he subjected the molten metal to pressure during its solidification, this fluid-compressed steel being then known as "Whitworth steel".In 1868 Whitworth established thirty annual scholarships for engineering students. After his death his executors permanently endowed the Whitworth Scholarships and distributed his estate of nearly half a million pounds to various educational and charitable institutions. Whitworth was elected an Associate of the Institution of Civil Engineers in 1841 and a Member in 1848 and served on its Council for many years. He was elected a Member of the Institution of Mechanical Engineers in 1847, the year of its foundation.[br]Principal Honours and DistinctionsBaronet 1869. FRS 1857. President, Institution of Mechanical Engineers 1856, 1857 and 1866. Hon. LLD Trinity College, Dublin, 1863. Hon. DCL Oxford University 1868. Member of the Smeatonian Society of Civil Engineers 1864. Légion d'honneur 1868. Society of Arts Albert Medal 1868.Bibliography1858, Miscellaneous Papers on Mechanical Subjects, London; 1873, Miscellaneous Papers on Practical Subjects: Guns and Steel, London (both are collections of his papers to technical societies).1854, with G.Wallis, The Industry of the United States in Machinery, Manufactures, andUseful and Ornamental Arts, London.Further ReadingF.C.Lea, 1946, A Pioneer of Mechanical Engineering: Sir Joseph Whitworth, London (a short biographical account).A.E.Musson, 1963, "Joseph Whitworth: toolmaker and manufacturer", Engineering Heritage, Vol. 1, London, 124–9 (a short biography).D.J.Jeremy (ed.), 1984–6, Dictionary of Business Biography, Vol. 5, London, 797–802 (a short biography).W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (describes Whitworth's machine tools).RTS -
5 Sellers, William
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 19 September 1824 Upper Darby, Pennsylvania, USAd. 24 January 1905 Philadelphia, Pennsylvania, USA[br]American mechanical engineer and inventor.[br]William Sellers was educated at a private school that had been established by his father and other relatives for their children, and at the age of 14 he was apprenticed for seven years to the machinist's trade with his uncle. At the end of his apprenticeship in 1845 he took charge of the machine shop of Fairbanks, Bancroft \& Co. in Providence, Rhode Island. In 1848 he established his own factory manufacturing machine tools and mill gearing in Philadelphia, where he was soon joined by Edward Bancroft, the firm becoming Bancroft \& Sellers. After Bancroft's death the name was changed in 1856 to William Sellers \& Co. and Sellers served as President until the end of his life. His machine tools were characterized by their robust construction and absence of decorative embellishments. In 1868 he formed the Edgemoor Iron Company, of which he was President. This company supplied the structural ironwork for the Centennial Exhibition buildings and much of the material for the Brooklyn Bridge. In 1873 he reorganized the William Butcher Steel Works, renaming it the Midvale Steel Company, and under his presidency it became a leader in the production of heavy ordnance. It was at the Midvale Steel Company that Frederick W. Taylor began, with the encouragement of Sellers, his experiments on cutting tools.In 1860 Sellers obtained the American rights of the patent for the Giffard injector for feeding steam boilers. He later invented his own improvements to the injector, which numbered among his many other patents, most of which related to machine tools. Probably Sellers's most important contribution to the engineering industry was his proposal for a system of screw threads made in 1864 and later adopted as the American national standard.Sellers was a founder member in 1880 of the American Society of Mechanical Engineers and was also a member of many other learned societies in America and other countries, including, in Britain, the Institution of Mechanical Engineers and the Iron and Steel Institute.[br]Principal Honours and DistinctionsChevalier de la Légion d'honneur 1889. President, Franklin Institute 1864–7.Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (describes Sellers's work on machine tools).Bruce Sinclair, 1969, "At the turn of a screw: William Sellers, the Franklin Institute, and a standard American thread", Technology and Culture 10:20–34 (describes his work on screw threads).RTS -
6 Ramsden, Jesse
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 6 October 1735 (?) Halifax, Yorkshire, Englandd. 5 November 1800 Brighton, Sussex, England[br]English instrument-maker who developed machines for accurately measuring angular and linear scales.[br]Jesse Ramsden was the son of an innkeeper but received a good general education: after attending the free school at Halifax, he was sent at the age of 12 to his uncle for further study, particularly in mathematics. At the age of 16 he was apprenticed to a cloth-worker in Halifax and on completion of the apprenticeship in 1755 he moved to London to work as a clerk in a cloth warehouse. In 1758 he became an apprentice in the workshop of a London mathematical instrument-maker named Burton. He quickly gained the skill, particularly in engraving, and by 1762 he was able to set up on his own account. He married in 1765 or 1766 the youngest daughter of the optician John Dollond FRS (1706– 61) and received a share of Dollond's patent for making achromatic lenses.Ramsden's experience and reputation increased rapidly and he was generally regarded as the leading instrument-maker of his time. He opened a shop in the Haymarket and transferred to Piccadilly in 1775. His staff increased to about sixty workers and apprentices, and by 1789 he had constructed nearly 1,000 sextants as well as theodolites, micrometers, balances, barometers, quadrants and other instruments.One of Ramsden's most important contributions to precision measurement was his development of machines for obtaining accurate division of angular and linear scales. For this work he received a premium from the Commissioners of the Board of Longitude, who published his descriptions of the machines. For the trigonometrical survey of Great Britain, initiated by General William Roy FRS (1726–90) and continued by the Board of Ordnance, Ramsden supplied a 3 ft (91 cm) theodolite and steel measuring chains, and was also engaged to check the glass tubes used to measure the fundamental base line.[br]Principal Honours and DistinctionsFRS 1786; Royal Society Copley Medal 1795. Member, Imperial Academy of St Petersburg 1794. Member, Smeatonian Society of Civil Engineers 1793.Bibliography1774, Description of a New Universal Equatorial Instrument, London; repub. 1791. 1777, Description of an Engine for Dividing Mathematical Instruments, London. 1779, Description of an Engine for Dividing Straight Lines on MathematicalInstruments, London.1779, "Description of two new micrometers", Philosophical Transactions of the Royal Society 69:419–31.1782, "A new construction of eyeglasses for such telescopes as may be applied to mathematical instruments", Philosophical Transactions of the Royal Society 73:94–99.Further ReadingR.S.Woodbury, 1961, History of the Lathe to 1850, Cleveland, Ohio; W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (both provide a brief description of Ramsden's dividing machines).RTS -
7 design
1) конструкция; проект; план2) проектирование, конструирование3) расчёт; определение размеров4) конструктивный вариант, конструктивное решение5) художественное моделирование, художественное оформление6) проектировать; конструировать•- design of concrete mix - design of detailed planning - design of mixture - design of reinforced concrete frame building - alternate design - approved design - architectural design - aseismic design - balanced design - barrier-free design - bridge design - building design - cantilever design - civil-engineering design - codes of structural design - computer-aided design - concrete design - contract design - contractor design - curvature design - custom design - detailed contract design - detailed design stage - draft design - engineering design - environmental design - experimental design - fail-safe design - full-size design - further-edge design of cross section - housing development design - human settlement design - hydraulic design - individual design - industrial design - intelligent design - interactive design - landscape design - lateral-force design - limit design - mix design - mock-up method of design - modular design - multistage design work - pavement design - pilot design - plastic design - point design - preliminary design - probabalistic design - project design - prototype design - regional planning design - research design - seismic design - single-stage design work - sprung arch design - standard design - standardized design - step-by-step design - structural design - structural steel design - thermal design - town planning design - traffic island design - two-stage design work - type design - typical design - ultimate load design - urban design* * *1. конструкция2. план, замысел; проект, проектное решение3. чертёж, эскиз4. проектирование; расчёт5. дизайн || проектировать; рассчитыватьdesign on empirical basis — эмпирический расчёт, расчёт на эмпирической основе
- design of stiffened compression flangesdesign to limit state theory — расчёт, основанный на гипотезе предельных состояний; расчёт по предельным состояниям
- design of structural members
- design of structural steel
- design of structures
- design of welds
- allowable stress design
- alternate design
- architectural design
- basic design
- beam design
- building design
- city design
- civic design
- composite design
- computer-aided design
- concrete mix design for pumping
- construction joint design
- cost-efficient design
- critical-load design
- elastic design
- environmental design
- experimental design
- final design
- form design
- frame design
- frost capacity design
- fully rigid basis design
- geometric highway design
- hydraulic design
- industrial design
- integrated environmental design
- landscape design
- lateral-force design
- limit design
- limit-load design
- limit-state design
- load factor design
- maximum load design
- methods design
- mix design
- mix design with fly ash
- modified structural design
- modular design
- one-off design
- original design
- outline design
- pavement design
- plastic design
- plastic limit design
- post and lintel design
- probabilistic design
- schematic design
- seismic design
- semirigid design
- shearing design
- shear design
- site design
- stable design
- standard design
- steel design
- structural design
- structural timber design
- tender design
- town-building design
- trial design
- tubular design
- ultimate load design
- ultimate-strength design
- unified design
- work design
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