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1 manufacturer's works
Экономика: завод-изготовитель -
2 manufacturer's works
English-russian dctionary of contemporary Economics > manufacturer's works
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3 tests at manufacturer’s works
tests at manufacturer’s works PRÜF Versuche mpl beim HerstellerEnglish-german engineering dictionary > tests at manufacturer’s works
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4 tests at the manufacturer's works
Макаров: заводские испытанияУниверсальный англо-русский словарь > tests at the manufacturer's works
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5 manufacturer's brand
марк., пат. фабричная марка, (торговая) марка [фирменный знак, бренд\] производителя (фирменное имя, которое принадлежит производителю определенного товара и всегда используется при продаже его товара, а не изменяется в зависимости от распространителя)Syn:manufacturer's mark, national brand 1), name brand, manufacturing mark, manufacturer mark, works mark, manufacture markSee:
* * *
"брэнд" производителя: фирменное имя, которое принадлежит производителю определенного товара; = name brand.* * * -
6 works mark
марк., пат. = manufacturer's brand -
7 original equipment manufacturer
1. Gen Mgta company that makes a product that works with a basic and common product, for example, a computer2. Opsa company that assembles components from other suppliers or subcontractors to produce a complete product such as a car or aircraft.Abbr. OEMThe ultimate business dictionary > original equipment manufacturer
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8 work
1. n1) работа; труд; дело2) место работы; должность, занятие3) действие, функционирование4) изделие; изделия, продукция5) заготовка; обрабатываемое изделие6) pl завод, фабрика, мастерские7) pl инженерное сооружение
- actual work
- additional work
- adjustment work
- administrative work
- agency work
- agricultural work
- aircraft works
- ancillary work
- art work
- artistic work
- assembly work
- auditing work
- auxiliary work
- building works
- casual work
- civil work
- civil engineering works
- clerical work
- commercial work
- commission work
- commissioning work
- construction works
- contract work
- contractor's works
- daily work
- day work
- day-to-day work
- decorating work
- decoration work
- defective work
- design work
- double-shift work
- efficient work
- engineering work
- engineering works
- field work
- fine work
- finishing work
- full-capacity work
- full-time work
- future work
- hand work
- heavy engineering works
- high-class work
- highly mechanized work
- highly skilled work
- hired work
- incentive work
- installation work
- integrated works
- intellectual work
- iron and steel works
- joint work
- laboratory work
- labour-intensive work
- lorry works
- low-paid work
- machine work
- maintenance work
- maker's works
- managerial work
- manual work
- manufacturer's works
- mechanical work
- metallurgical works
- mounting work
- multishift work
- night work
- nonshift work
- office work
- one-shift work
- on-site work
- outdoor work
- outstanding work
- overtime work
- packing work
- paid work
- paper work
- partial work
- part-time work
- patent work
- permanent work
- piece work
- planned work
- planning work
- practical work
- preliminary work
- preparatory work
- productive work
- reconstruction work
- regular work
- remedial work
- repair work
- rescue work
- research work
- routine work
- rush work
- rythmical work
- salvage work
- satisfactory work
- scheduled work
- scientific work
- seasonal work
- second-shift work
- serial work
- service work
- shift work
- short-time work
- smooth work
- spare-time work
- stevedore work
- stevedoring work
- subcontract work
- subcontractor's works
- subsidiary work
- survey and research work
- task work
- team work
- temporary work
- testing work
- time work
- two-shift work
- unhealthy work
- unskilled work
- wage work
- well-paid work
- work according to the book
- work at normal working hours
- work at piece rates
- work at time rates
- work by contract
- work by hire
- work by the piece
- work by the rules
- work for hire
- work in process
- work in progress
- works of art
- work of development
- work of equipment
- work of an exhibition
- work on a contract
- work on a contractual basis
- work on hand
- work on a project
- work on schedule
- work on the site
- work under way
- ex works
- out of work
- fit for work
- unfit for work
- work done
- work performed
- accept work
- accomplish work
- alter work
- assess work
- be at work
- be behind with one's work
- begin work
- bill work
- be on short time work
- be thrown out of work
- carry out work
- cease work
- close down the works
- commence work
- complete work
- control work
- coordinate work
- correct work
- do work
- employ on work
- entrust with work
- evaluate work
- execute work
- expedite work
- finalize work
- finish work
- fulfil work
- get work
- get down to work
- give out work by contract
- go ahead with work
- hold up work
- improve work
- inspect work
- insure work
- interfere with work
- interrupt work
- leave off work
- look for work
- organize work
- pay for work
- perform work
- postpone work
- proceed with work
- provide work
- put off work
- rate work
- rectify defective work
- reject work
- remedy defective work
- resume work
- retire from work
- speed up work
- start work
- step up work
- stop work
- superintend work
- supervise work
- suspend work
- take over work
- take up work
- terminate work
- undertake work2. v1) работать2) действовать, функционировать3) обрабатывать
- work off
- work out
- work over
- work overtime
- work to rule
- work up -
9 Bullard, Edward Payson
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 18 April 1841 Uxbridge, Massachusetts, USAd. 22 December 1906 Bridgeport, Connecticut, USA[br]American mechanical engineer and machine-tool manufacturer who designed machines for boring.[br]Edward Payson Bullard served his apprenticeship at the Whitin Machine Works, Whitinsville, Massachusetts, and worked at the Colt Armory in Hartford, Connecticut, until 1863; he then entered the employ of Pratt \& Whitney, also in Hartford. He later formed a partnership with J.H.Prest and William Parsons manufacturing millwork and tools, the firm being known as Bullard \& Prest. In 1866 Bullard organized the Norwalk Iron Works Company of Norwalk, Connecticut, but afterwards withdrew and continued the business in Hartford. In 1868 the firm of Bullard \& Prest was dissolved and Bullard became Superintendent of a large machine shop in Athens, Georgia. He later organized the machine tool department of Post \& Co. at Cincinnati, and in 1872 he was made General Superintendent of the Gill Car Works at Columbus, Ohio. In 1875 he established a machinery business in Beekman Street, New York, under the name of Allis, Bullard \& Co. Mr Allis withdrew in 1877, and the Bullard Machine Company was organized.In 1880 Bullard secured entire control of the business and also became owner of the Bridgeport Machine Tool Works, Bridgeport, Connecticut. In 1883 he designed his first vertical boring and turning mill with a single head and belt feed and a 37 in. (94 cm) capacity; this was the first small boring machine designed to do the accurate work previously done on the face plate of a lathe. In 1889 Bullard gave up his New York interests and concentrated his entire attention on manufacturing at Bridgeport, the business being incorporated in 1894 as the Bullard Machine Tool Company. The company specialized in the construction of boring machines, the design being developed so that it became essentially a vertical turret lathe. After Bullard's death, his son Edward Payson Bullard II (b. 10 July 1872 Columbus, Ohio, USA; d. 26 June 1953 Fairfield, Connecticut, USA) continued as head of the company and further developed the boring machine into a vertical multi-spindle automatic lathe which he called the "Mult-au-matic" lathe. Both father and son were members of the American Society of Mechanical Engineers.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven: Yale University Press; repub. 1926, New York and 1987, Bradley, Ill.: Lindsay Publications Inc. (describes Bullard's machines).RTS -
10 Pratt, Francis Ashbury
[br]b. 15 February 1827 Woodstock, Vermont, USAd. 10 February 1902 Hartford, Connecticut, USA[br]American mechanical engineer and machine-tool manufacturer.[br]Francis A.Pratt served an apprenticeship as a machinist with Warren Aldrich, and on completing it in 1848 he entered the Gloucester Machine Works as a journeyman machinist. From 1852 to 1854 he worked at the Colt Armory in Hartford, Connecticut, where he met his future partner, Amos Whitney. He then became Superintendent of the Phoenix Iron Works, also at Hartford and run by George S.Lincoln \& Company. While there he designed the well-known "Lincoln" miller, which was first produced in 1855. This was a development of the milling machine built by Robbins \& Lawrence and designed by F.W. Howe, and incorporated a screw drive for the table instead of the rack and pinion used in the earlier machine.Whitney also moved to the Phoenix Iron Works, and in 1860 the two men started in a small way doing machine work on their own account. In 1862 they took a third partner, Monroe Stannard, and enlarged their workshop. The business continued to expand, but Pratt and Whitney remained at the Phoenix Iron Works until 1864 and in the following year they built their first new factory. The Pratt \& Whitney Company was incorporated in 1869 with a capital of $350,000, F.A.Pratt being elected President. The firm specialized in making machine tools and tools particularly for the armament industry. In the 1870s Pratt made no less than ten trips to Europe gaining orders for equipping armouries in many different countries. Pratt \& Whitney was one of the leading firms developing the system of interchangeable manufacture which led to the need to establish national standards of measurement. The Rogers-Bond Comparator, developed with the backing of Pratt \& Whitney, played an important part in the establishment of these standards, which formed the basis of the gauges of many various types made by the firm. Pratt remained President of the company until 1898, after which he served as their Consulting Engineer for a short time before retiring from professional life. He was granted a number of patents relating to machine tools. He was a founder member of the American Society of Mechanical Engineers in 1880 and was elected a vice-president in 1881. He was an alderman of the city of Hartford.[br]Principal Honours and DistinctionsVice-President, American Society of Mechanical Engineers 1881.Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, 111. (describes the origin and development of the Pratt \& Whitney Company).RTS -
11 завод I
м.
1. works, factory, plant, mill;
машиностроительный ~ engineering works/plant;
чугунолитейный ~ iron-works;
маслобойный ~ creamery, butter-factory;
~ изготовитель manufacturer, factory of origin;
~ поставщик supplying factory;
~ смежник subcontractory factory;
2.: конный ~ stud-farm. -
12 Champion, Nehemiah
SUBJECT AREA: Metallurgy[br]b. 1678 probably Bristol, Englandd. 9 September 1747 probably Bristol, England[br]English merchant and brass manufacturer of Bristol.[br]Several members of Champion's Quaker family were actively engaged as merchants in Bristol during the late seventeenth and the eighteenth centuries. Port records show Nehemiah in receipt of Cornish copper ore at Bristol's Crews Hole smelting works by 1706, in association with the newly formed brassworks of the city. He later became a leading partner, managing the company some time after Abraham Darby left the Bristol works to pursue his interest at Coalbrookdale. Champion, probably in company with his father, became the largest customer for Darby's Coalbrookdale products and also acted as Agent, at least briefly, for Thomas Newcomen.A patent in 1723 related to two separate innovations introduced by the brass company.The first improved the output of brass by granulating the copper constituent and increasing its surface area. A greater proportion of zinc vapour could permeate the granules compared with the previous practice, resulting in the technique being adopted generally in the cementation process used at the time. The latter part of the same patent introduced a new type of coal-fired furnace which facilitated annealing in bulk so replacing the individual processing of pieces. The principle of batch annealing was generally adopted, although the type of furnace was later improved. A further patent, in 1739, in the name of Nehemiah, concerned overshot water-wheels possibly intended for use in conjunction with the Newcomen atmospheric pumping engine employed for recycling water by his son William.Champion's two sons, John and William, and their two sons, both named John, were all concerned with production of non-ferrous metals and responsible for patented innovations. Nehemiah, shortly before his death, is believed to have partnered William at the Warmley works to exploit his son's new patent for producing metallic zinc.[br]Bibliography1723, British patent no. 454 (granulated copper technique and coal-fired furnace). 1739, British patent no. 567 (overshot water-wheels).Further ReadingA.Raistrick, 1950, Quakers in Science and Industry, London: Bannisdale Press (for the Champion family generally).J.Day, 1973, Bristol Brass, a History of the Industry, Newton Abbot: David \& Charles (for the industrial activities of Nehemiah).JD -
13 Rowland, Thomas Fitch
SUBJECT AREA: Mining and extraction technology[br]b. 15 March 1831 New Haven, Connecticut, USAd. 13 December 1907 New York City, USA[br]American engineer and manufacturer, inventor of off-shore drilling.[br]The son of a grist miller, Rowland worked in various jobs until 1859 when he established his own business for the construction of wooden and iron steamships and for structural iron works, in Greenpoint, Long Island, New York. In 1860 he founded the Continental Works and during the American Civil War he started manufacturing gun carriages and mortar beds. He fitted out many vessels for the navy, and as a contractor for John Ericsson he built heavily armoured war vessels.He continued shipbuilding, but later diversified his business. He devoted great attention to the design of gas-works, constructing innovative storage facilities all over the United States, and he was concerned with the improvement of welding iron and steel plates and other processes in the steel industry. In the late 1860s he also began the manufacture of steam-engines and boilers for use in the new but expanding oil industry. In 1869 he took out a patent for a fixed platform for drilling for oil off-shore up to a depth of 15 m (49 ft). With this idea, just ten years after Edwin Drake's success in on-shore oil drilling in Titusville, Pennsylvania, Rowland pioneered the technology of off-shore drilling for petroleum in which the United States later became the leading nation.[br]Principal Honours and DistinctionsAmerican Society of Civil Engineers: Director 1871–3, Vice-President 1886–7, Honorary Member 1899.Further Reading"Thomas Fitch Rowland", Dictionary of American Biography.1909, "Memoir", Transactions of the American Society of Civil Engineers 62:547–9.WK -
14 McKay, Hugh Victor
SUBJECT AREA: Agricultural and food technology[br]b. c. 1866 Drummartin, Victoria, Australiad. 21 May 1926 Australia[br]Australian inventor and manufacturer of harvesting and other agricultural equipment.[br]A farmer's son, at the age of 17 McKay developed modifications to the existing stripper harvester and created a machine that would not only strip the seed from standing corn, but was able to produce a threshed, winnowed and clean sample in one operation. The prototype was produced in 1884 and worked well on the two acres of wheat that had been set aside on the family farm. By arrangement with a Melbourne plough maker, five machines were made and sold for the 1885 season. In 1886 the McKay Harvester Company was formed, with offices at Ballarat, from which the machines, built by various companies, were sold. The business expanded quickly, selling sixty machines in 1888, and eventually rising to the production of nearly 2,000 harvesters in 1905. The name "Sunshine" was given to the harvester, and the "Sun" prefix was to appear on all other implements produced by the company as it diversified its production interests. In 1902 severe drought reduced machinery sales and left 2,000 harvesters unsold. McKay was forced to look to export markets to dispose of his surplus machines. By 1914 a total of 10,000 machines were being exported annually. During the First World War McKay was appointed to the Business Board of the Defence Department. Increases in the scale of production resulted in the company moving to Melbourne, where it was close to the port of entry of raw materials and was able to export the finished article more readily. In 1909 McKay produced one of the first gas-engined harvesters, but its cost prevented it from being more than an experimental prototype. By this time McKay was the largest agricultural machinery manufacturer in the Southern hemisphere, producing a wide range of implements, including binders. In 1916 McKay hired Headlie Taylor, who had developed a machine capable of harvesting fallen crops. The jointly developed machine was a major success, coming as it did in what would otherwise have been a disastrous Australian harvest. Further developments included the "Sun Auto-header" in 1923, the first of the harvesting machines to adopt the "T" configuration to be seen on modern harvesters. The Australian market was expanding fast and a keen rivalry developed between McKay and Massey Harris. Confronted by the tariff regulations with which the Australian Government had protected its indigenous machinery industry since 1906, Massey Harris sold all its Australian assets to the H.V. McKay company in 1930. Twenty-three years later Massey Ferguson acquired the old Sunshine works and was still operating from there in the 1990s.Despite a long-running history of wage disputes with his workforce, McKay established a retiring fund as well as a self-help fund for distressed cases. Before his death he created a charitable trust and requested that some funds should be made available for the "aerial experiments" which were to lead to the establishment of the Flying Doctor Service.[br]Principal Honours and DistinctionsCBE.Further ReadingGraeme Quick and Wesley Buchele, 1978, The Grain Harvesters, American Society of Agricultural Engineers (devotes a chapter to the unique development of harvesting machinery which took place in Australia).AP -
15 Roebuck, John
SUBJECT AREA: Chemical technology[br]b. 1718 Sheffield, Englandd. 17 July 1794[br]English chemist and manufacturer, inventor of the lead-chamber process for sulphuric acid.[br]The son of a prosperous Sheffield manufacturer, Roebuck forsook the family business to pursue studies in medicine at Edinburgh University. There he met Dr Joseph Black (1727–99), celebrated Professor of Chemistry, who aroused in Roebuck a lasting interest in chemistry. Roebuck continued his studies at Leyden, where he took his medical degree in 1742. He set up in practice in Birmingham, but in his spare time he continued chemical experiments that might help local industries.Among his early achievements was his new method of refining gold and silver. Success led to the setting up of a large laboratory and a reputation as a chemical consultant. It was at this time that Roebuck devised an improved way of making sulphuric acid. This vital substance was then made by burning sulphur and nitre (potassium nitrate) over water in a glass globe. The scale of the process was limited by the fragility of the glass. Roebuck substituted "lead chambers", or vessels consisting of sheets of lead, a metal both cheap and resistant to acids, set in wooden frames. After the first plant was set up in 1746, productivity rose and the price of sulphuric acid fell sharply. Success encouraged Roebuck to establish a second, larger plant at Prestonpans, near Edinburgh. He preferred to rely on secrecy rather than patents to preserve his monopoly, but a departing employee took the secret with him and the process spread rapidly in England and on the European continent. It remained the standard process until it was superseded by the contact process towards the end of the nineteenth century. Roebuck next turned his attention to ironmaking and finally selected a site on the Carron river, near Falkirk in Scotland, where the raw materials and water power and transport lay close at hand. The Carron ironworks began producing iron in 1760 and became one of the great names in the history of ironmaking. Roebuck was an early proponent of the smelting of iron with coke, pioneered by Abraham Darby at Coalbrookdale. To supply the stronger blast required, Roebuck consulted John Smeaton, who c. 1760 installed the first blowing cylinders of any size.All had so far gone well for Roebuck, but he now leased coal-mines and salt-works from the Duke of Hamilton's lands at Borrowstonness in Linlithgow. The coal workings were plagued with flooding which the existing Newcomen engines were unable to overcome. Through his friendship with Joseph Black, patron of James Watt, Roebuck persuaded Watt to join him to apply his improved steam-engine to the flooded mine. He took over Black's loan to Watt of £1,200, helped him to obtain the first steam-engine patent of 1769 and took a two-thirds interest in the project. However, the new engine was not yet equal to the task and the debts mounted. To satisfy his creditors, Roebuck had to dispose of his capital in his various ventures. One creditor was Matthew Boulton, who accepted Roebuck's two-thirds share in Watt's steam-engine, rather than claim payment from his depleted estate, thus initiating a famous partnership. Roebuck was retained to manage Borrowstonness and allowed an annuity for his continued support until his death in 1794.[br]Further ReadingMemoir of John Roebuck in J.Roy. Soc. Edin., vol. 4 (1798), pp. 65–87.S.Gregory, 1987, "John Roebuck, 18th century entrepreneur", Chem. Engr. 443:28–31.LRD -
16 предприятие
ср.
1) undertaking, enterprise;
business рискованное предприятие ≈ egg-dance, gamble, adventure безнадежное предприятие ≈ fruitless task, forlorn hope выгодное предприятие ≈ gravy train
2) plant, works, factory, enterprise, concern, development дочернее предприятие ≈ branch establishment, daughter enterprise частное предприятие ≈ privately owned enterprise горное предприятие ≈ adventure коммерческое предприятие ≈ business закрыть предприятие ≈ to close out предприятие угольной промышленности ≈ colliery головное предприятие ≈ parent enterprise государственное предприятие ≈ public enterprise, national enterprise предприятие черной металлургии ≈ ironworks предприятие обрабатывающей промышленности ≈ manufacturer перерабатывающее предприятие ≈ reprocessor единоличное предприятие ≈ one-man business производственное предприятие ≈ manufacturing firmпредприяти|е - с.
1. (предпринятое дело) undertaking;
(рискованное) venture;
2. (промышленное) enterprise;
(завод тж.) factory, works;
акционерное ~ incorporated enterprise;
внешнеторговое ~ foreign trade company;
высокорентабельное ~ highly profitable enterprise;
государственное ~ governmental/state-owned enterprise;
действующее ~ operating enterprise;
деловое ~ business enterprise;
дочернее ~ subsidiary enterprise;
единоличное ~ ownership;
зависимое ~ subsidiary enterprise;
коммерческое ~ commercial undertaking;
конкурирующее ~ competitor enterprise;
кооперативное ~ cooperative enterprise;
малое ~ small enterprise;
оптовое ~ wholesaler;
промышленное ~ industrial undertaking;
совместное ~ joint venture;
торговое ~ trading company;
эксплуатационное ~ operating agency;
частное ~ private enterprise;
~я партнёров partners, production facilities;
~ с участием иностранного капитала joint venture with the participation of foreign capital;
мощность ~я enterprise capacity;
основать ~ launch an enterprise, establish a business;
руководить ~ем conduct a business.Большой англо-русский и русско-английский словарь > предприятие
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17 test
- test
- nиспытание; проверка; тест; опыт; проба; анализ; исследование; эксперимент || испытывать; проверять; исследовать
test by immersion in boiling water — проба [испытание] кипячением в воде
- test of time
- AASHO density test
- Abbot compaction test
- Abrams' test
- abrasion test
- absorption test
- accelerated test
- accelerated test for compressive strength
- accelerated strength test
- acceptance test
- accredited tests
- acid test
- aggregate crushing test
- aggregate impact test
- air test
- air content test
- air entrainment test
- air filter blackness test
- air leakage test
- air permeability test
- air permeability fineness test
- alternating bending test
- anchorage shear test
- aptitude test
- Atterberg test
- attrition test
- autoclave test
- baling-out permeability test
- ball test
- ball hardness test
- barium sulphate test
- beam test
- bearing test
- bending test
- bending tensile test
- bit wear test
- blackness air filter test
- Blain test
- block shear test
- blow flexure test
- boiling test
- bond test
- bootstrap test
- borehole shear test
- breaking test
- Brinell hardness test
- California bearing ratio test
- cement tests
- Charpy test
- Charpy V-notch impact test
- checking test
- check test
- COLE volume change test
- colorimetric test
- color test
- compacting factor test
- compaction test
- complience test
- compression test
- cone penetration test
- consistency test
- consolidated quick test
- consolidation test
- constant head permeability test
- constant rate of penetration test
- constant rate of uplift test
- constant volume test
- control test
- core test
- creep test
- C.R.P. test
- crushing test
- cube strength test
- cube test
- cylinder test
- dehydration test
- diametral compression test
- diamond pyramid hardness test
- dioctylphthalate test
- direct shear test
- dispersion test
- dissipation test
- DOP test
- Dorry test
- drain test
- drained triaxial test
- driving test
- drop-weight test
- durability test
- dust spot test
- Dutch sounding test
- dynamic penetration test
- expandable sleeve concrete test
- exposure tests
- fast field tests
- fatigue test
- field tests
- field density test
- field loading test
- field percolation test
- field vane test
- flexure test
- flow-table test
- flow test
- four-point bending test
- fracture test
- freeze-thaw test
- freeze-thaw durability test
- freezing test
- gravimetric air filter test
- hardening test of concrete
- hardness test
- Herbert cloudburst test
- hollow cylinder test
- hydraulic drain test
- hydraulic flat-jack test
- hydraulic pressure test
- hydraulic test
- hydrostatic test
- impact test
- impact crushing value test
- indentation test
- ink test
- in-place test
- in-place slump test
- in-situ test
- in-situ soil tests
- insulation test
- integrity test
- Izod impact test
- Izod test
- jolt test
- Kelly ball test
- Knoop hardness test
- laboratory test
- leakage test
- life test
- line-load test
- load test of structures
- loading test
- long-term test
- long-time creep test
- maintained load test
- manufacturer test
- methylene blue test
- model test
- needle test
- notch bending test
- notched bar test
- nuclear density test
- operational test
- organic test
- organic test for fine aggregate
- orifice tube test
- penetration test
- percussion test
- performance test
- photoelastic test
- pile load test
- pile pulling test
- pile redriving test
- plate-bearing test
- pneumatic test
- point-load test
- preliminary test
- pressure test
- pressure meter test
- proof test
- proof load test
- pumping test
- punching shear test
- pycnometer test
- Q-test
- quick test
- R-test
- Ro test
- radial percolation test
- Raymond standard test
- reception test
- reference test
- reliability test
- repeated load test
- resonant-column test
- reverse bend test
- rock bolts convergence test
- Rockwell hardness test
- Rockwell superficial hardness test
- S-test
- saponification test
- scratch test
- shearing test
- shear test
- shock bending test
- short-term test
- single point test
- site test for cement content of mortars
- slow test
- slump test
- smoke test
- soap test
- splitting tensile test
- standard-density test
- standard penetration test
- static penetration test
- strength test
- stress-relaxation test
- stress-rupture test
- tensile test
- tightness test
- time-of-set test
- torsion test
- triaxial compression test
- triaxial test
- two-point test
- type test
- ultrasonic test
- undrained test
- vacuum test
- vane test
- vibrated mortar cube test
- vibrating crushing test
- Vicat needle test
- water test
- water loading test
- water retention test
- wind loading test
- wind-tunnel test
- works beam test
- works cube test
- yield test
Англо-русский строительный словарь. — М.: Русский Язык. С.Н.Корчемкина, С.К.Кашкина, С.В.Курбатова. 1995.
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18 test
1) испытание; опыт; проба; проверка2) критерий; мерило, пробный камень3) испытательный, контрольный, пробный4) испытывать; делать опыты; подвергать испытанию5) брать пробы•test for soundness — испытание ( цемента) на равномерность изменения объёма
- abruption test - absorption test - accelerated corrosion test - accelerated wear test - acceptance test - acid test - adhesion test - adverse field test - ageing test - air test - air-content test - air-pressure test - alkalimetric test - alternate stress test - alternating bending test - alternating impact test - alternating torsion fatigue test - altitude test - angular test - appearance test - approval test - arbitration test - Atterberg test - autoclave test - axial test - back-and-forth bending test - bacteriological test - ball test - ball hardness test - ball rebound test - beam test - beam rotating fatigue test - beam-strength test - bearing test of soil - bench test - bending test - bending and unbending test - bloating test - blow test - blow-bending test - blowpipe test - bounce test - breakdown test - breaking test - Brinell hardness test - brittleness test - buckling test - burning test - bursting test - calibration test - calorimeter test - cannon test - carbon residue test - Charpy test - check test - chemical test of drain - cleavage test - closure test - coating test - cold test - cold bending test - colorimetric test for organic impurities - commercial test - commissioning tests - compaction test - comparative test - comprehensive test - compression test - compression-compression test - consistency test of concrete - continuous test - continuity of test - corrosion test - corrosive wear test - crack test - crash test - creep test - cross-bending test - crushing test - cupping test - cyclic test - damp test - decantation test - deep test - deflection test - deformation test - degradation rate test - density test - destruction test - destructive test - Deval abrasion test - doubling test - drain test - drill test - drop test - dummy test - duplicate test - dynamic breaking test - elongation test - endurance test - end-use test - evaluation test - extraction test on Portland cement - factory test - failure test - fatigue test - field tests - field in-place test - file test - fire hose reel test - fire resistance test - flange test - flattening test - flexion test - flexure test - float test - flow test - folding test - fracture test - free-bend test - freezing test - freezing and thawing test - fuel test - full-scale test - green test - grinding test - guarantee test - hardness test - hot bend test - hot twist test - immersion test - impact test - impact bend test - indentation test - ink test - intermittent test - internal pressure test - Izod impact test - knock test - Knoop microhardness test - laboratory test - leak test - leakage test - life test - limiting pressure test - load test on pile - load test - loading test - long run tests - minimum flow rate test - model test - moment test - mortar bar test - non-destructive test - notch bar test - notch bending test - on-the-road test - organic impurities test - pat test - pendulum test - penetration test - percentage test - performance test - physical endurance test - pile test - pile loading test - pneumatic test - preliminary test - pressure test - prototype test - pull-out bond test - pumping test - puncture test - qualification test - quality test - rattler test - reduced section tension test - reduction-in-alkalinity test - reduction-in-expansion test - reheat test - relaxation test - remolding test - repair test - repetition test - resistance to corrosion test - resistance to impact test - reversed bend test - ride test - rig test - road tests - rod test - running test - running-in test - salt spray tests - scale test - scratch test - sedimentation test - service test - settleability test - severe test - shear test - shear test of soil - shock test - shop test - Shore's scleroscope hardness test - short-circuit test - size test - sizing test - skid test - slump test - smell test - smoke test - soap test - sodium solution test - soil test - soundness test - spray angle test - spring closure test - squeeze test - stain test - static test - strength test - strip-off adhesion test - subgrade test - subzero test - sugar test of cement - taking over tests - tear test - tee-bend test - tensile test - tension test - throw range test - time-of-setting test - torsion test - transverse test - twisting test - ultrasonic test - unit-weight test - vane test - Vicat needle test - warpage test - warranty test - water test - water absorption test - water retention test - wear test - weather exposure test - weldability test - X-ray testto test the instrument — проверять прибор, эталонировать прибор
* * *испытание; проверка; тест; опыт; проба; анализ; исследование; эксперимент || испытывать; проверять; исследовать- test of timetest by immersion in boiling water — проба [испытание] кипячением в воде
- AASHO density test
- Abbot compaction test
- Abrams' test
- abrasion test
- absorption test
- accelerated test
- accelerated test for compressive strength
- accelerated strength test
- acceptance test
- accredited tests
- acid test
- aggregate crushing test
- aggregate impact test
- air test
- air content test
- air entrainment test
- air filter blackness test
- air leakage test
- air permeability test
- air permeability fineness test
- alternating bending test
- anchorage shear test
- aptitude test
- Atterberg test
- attrition test
- autoclave test
- baling-out permeability test
- ball test
- ball hardness test
- barium sulphate test
- beam test
- bearing test
- bending test
- bending tensile test
- bit wear test
- blackness air filter test
- Blain test
- block shear test
- blow flexure test
- boiling test
- bond test
- bootstrap test
- borehole shear test
- breaking test
- Brinell hardness test
- California bearing ratio test
- cement tests
- Charpy test
- Charpy V-notch impact test
- checking test
- check test
- COLE volume change test
- colorimetric test
- color test
- compacting factor test
- compaction test
- complience test
- compression test
- cone penetration test
- consistency test
- consolidated quick test
- consolidation test
- constant head permeability test
- constant rate of penetration test
- constant rate of uplift test
- constant volume test
- control test
- core test
- creep test
- C.R.P. test
- crushing test
- cube strength test
- cube test
- cylinder test
- dehydration test
- diametral compression test
- diamond pyramid hardness test
- dioctylphthalate test
- direct shear test
- dispersion test
- dissipation test
- DOP test
- Dorry test
- drain test
- drained triaxial test
- driving test
- drop-weight test
- durability test
- dust spot test
- Dutch sounding test
- dynamic penetration test
- expandable sleeve concrete test
- exposure tests
- fast field tests
- fatigue test
- field tests
- field density test
- field loading test
- field percolation test
- field vane test
- flexure test
- flow-table test
- flow test
- four-point bending test
- fracture test
- freeze-thaw test
- freeze-thaw durability test
- freezing test
- gravimetric air filter test
- hardening test of concrete
- hardness test
- Herbert cloudburst test
- hollow cylinder test
- hydraulic drain test
- hydraulic flat-jack test
- hydraulic pressure test
- hydraulic test
- hydrostatic test
- impact test
- impact crushing value test
- indentation test
- ink test
- in-place test
- in-place slump test
- in-situ test
- in-situ soil tests
- insulation test
- integrity test
- Izod impact test
- Izod test
- jolt test
- Kelly ball test
- Knoop hardness test
- laboratory test
- leakage test
- life test
- line-load test
- load test of structures
- loading test
- long-term test
- long-time creep test
- maintained load test
- manufacturer test
- methylene blue test
- model test
- needle test
- notch bending test
- notched bar test
- nuclear density test
- operational test
- organic test
- organic test for fine aggregate
- orifice tube test
- penetration test
- percussion test
- performance test
- photoelastic test
- pile load test
- pile pulling test
- pile redriving test
- plate-bearing test
- pneumatic test
- point-load test
- preliminary test
- pressure test
- pressure meter test
- proof test
- proof load test
- pumping test
- punching shear test
- pycnometer test
- Q-test
- quick test
- R-test
- Ro test
- radial percolation test
- Raymond standard test
- reception test
- reference test
- reliability test
- repeated load test
- resonant-column test
- reverse bend test
- rock bolts convergence test
- Rockwell hardness test
- Rockwell superficial hardness test
- S-test
- saponification test
- scratch test
- shearing test
- shear test
- shock bending test
- short-term test
- single point test
- site test for cement content of mortars
- slow test
- slump test
- smoke test
- soap test
- splitting tensile test
- standard-density test
- standard penetration test
- static penetration test
- strength test
- stress-relaxation test
- stress-rupture test
- tensile test
- tightness test
- time-of-set test
- torsion test
- triaxial compression test
- triaxial test
- two-point test
- type test
- ultrasonic test
- undrained test
- vacuum test
- vane test
- vibrated mortar cube test
- vibrating crushing test
- Vicat needle test
- water test
- water loading test
- water retention test
- wind loading test
- wind-tunnel test
- works beam test
- works cube test
- yield test -
19 Borsig, Johann Carl Friedrich August
[br]b. 25 June 1804 Breslau, Germany (now Wroclaw, Poland)d. 7 July 1854 Berlin, Germany[br]German pioneer manufacturer of locomotives and rails.[br]Borsig established a small works at Berlin in 1837 that ten years later had expanded sufficiently to employ 1,200 people. In that year it produced sixty-seven locomotives. Borsig copied the long-boiler type then popular in Britain and which had been exported to Germany by British manufacturers: it became the standard goods engine in Germany for many years, and the name Borsig became one of the famous names of locomotive building. In 1847 Borsig established an iron-works near Berlin that from 1851 started to produce good-quality rails; German railways previously had to import these from Britain.[br]Further ReadingJ.Marshall, 1978, A Biographical Dictionary of Railway Engineers, Newton Abbot: David \& Charles.PJGRBiographical history of technology > Borsig, Johann Carl Friedrich August
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20 Dockwra, William
SUBJECT AREA: Metallurgy[br]d. 1716[br]English merchant; manufacturer of copper, brass, wire and pins.[br]William Dockwra established a penny postal system in London in 1683. He was appointed Comptroller of the Penny Post in 1697, but following enquiries into his activities he was dismissed on charges of maladministration. In the early 1690s he was heading a partnership with premises at Esher, formerly the brassworks of Jacob Momma. Brass was made there and both brass and copper sheet was manufactured by water-powered rolling mills, at a time when such techniques were new to England. Wire was drawn and used for pinmaking on the premises, making this the first comprehensive works of its kind. Dockwra was involved in a further partnership based at Redbrook on the Wye in Gloucestershire, where copper was smelted by John Coster using new coal-fired reverberatory furnaces. It was from there that the Esher works received its copper for brassmaking and other manufacturing processes. Following his dismissal as Comptroller of the Penny Post, Dockwra's fortunes declined. By the early years of the eighteenth century he had withdrawn from his involvement in manufacturing, no longer being included in either of his former partnerships, although their work continued.[br]Further ReadingJ.Day, 1973, Bristol Brass: A History of the Industry (puts Dockwra's manufacturing activities in context).J.Houghton, 1697, Husbandry and Trade Improv'd (a contemporary account of Dockwra's industrial activities).JD
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