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1 blacksmith's work
Англо-русский словарь строительных терминов > blacksmith's work
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2 blacksmith's work
работы кузнечные
Работы по изготовлению металлоизделий, выполняемые ковкой
[Терминологический словарь по строительству на 12 языках (ВНИИИС Госстроя СССР)]EN
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Англо-русский словарь нормативно-технической терминологии > blacksmith's work
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3 blacksmith's work
1) Техника: кузнечное дело2) Строительство: ручная ковка -
4 blacksmith's work
• коване• ръчни изковкиEnglish-Bulgarian polytechnical dictionary > blacksmith's work
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5 blacksmith's work
кузнечное дело; ручная ковка -
6 blacksmith
------------------------------------------------------------[English Word] blacksmith[English Plural] blacksmiths[Swahili Word] mbini[Swahili Plural] wabini[Part of Speech] noun[Class] 1/2[Derived Word] bini V------------------------------------------------------------[English Word] blacksmith[English Plural] blacksmiths[Swahili Word] mfuachuma[Swahili Plural] wafuachuma[Part of Speech] noun[Class] 1/2------------------------------------------------------------[English Word] blacksmith[English Plural] blacksmiths[Swahili Word] mhunzi[Swahili Plural] wahunzi[Part of Speech] noun[Class] 1/2------------------------------------------------------------[English Word] work of a blacksmith[Swahili Word] uhunzi[Part of Speech] noun[Class] 14[Related Words] mhunzi------------------------------------------------------------ -
7 forging work
работы кузнечные
Работы по изготовлению металлоизделий, выполняемые ковкой
[Терминологический словарь по строительству на 12 языках (ВНИИИС Госстроя СССР)]EN
DE
FR
Англо-русский словарь нормативно-технической терминологии > forging work
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8 forge work
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9 кузнечное дело
blacksmith's workБольшой англо-русский и русско-английский словарь > кузнечное дело
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10 forging
ковка
ндп. свободная ковка
Обработка металлов давлением местным приложением деформирующих нагрузок с помощью универсального подкладного инструмента или бойков
[ ГОСТ 18970-84]
[ГОСТ 3.1109-82]
ковка
Способ обработки металлов в горячем состоянии посредством пресса или с помощью многократного прерывистого воздействия давлением
[Терминологический словарь по строительству на 12 языках (ВНИИИС Госстроя СССР)]Недопустимые, нерекомендуемые
Тематики
- оборуд. для бесстружечной обработки
- технологические процессы в целом
EN
DE
FR
ковка
Процесс обработки металла до нужной формы ударами или давлением в молотах, ковочных прессах, высадочных прессах, прессах, валках и связанном с этим оборудованием. Кузнечные молоты и ковочные машины с высокоэнергетическим коэффициентом воздействия удара на заготовку, в то время как в большинстве других типов ковки используют оборудование, применяющее нагнетание давления, необходимого для деформации. Некоторые металлы могут быть откованы при комнатной температуре, но большинство из них становятся более пластичными при нагревании.
[ http://www.manual-steel.ru/eng-a.html]Тематики
EN
поковка
Изделие или заготовка, полученные технологическими методами ковки, объемной штамповки или вальцовки.
Примечания
1. Кованая поковка - поковка, полученная технологическим методом ковки.
2. Штампованная поковка - поковка, полученная технологическим методом объемной штамповки.
3. Вальцованная поковка - поковка, полученная технологическим методом вальцовки из сортового проката.
[ГОСТ 3.1109-82]
[ ГОСТ 18970-84]
поковка
Полуфабрикат, изготовляемый ковкой.
[ ГОСТ 25501-82]Тематики
- заготовки и полуфабрикаты в металлургии
- оборуд. для бесстружечной обработки
- технологические процессы в целом
EN
DE
поковка)
(напр. ротора турбины
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
работы кузнечные
Работы по изготовлению металлоизделий, выполняемые ковкой
[Терминологический словарь по строительству на 12 языках (ВНИИИС Госстроя СССР)]EN
DE
FR
105. Поковка
D. Schmiedestück
E. Forging
Источник: ГОСТ 3.1109-82: Единая система технологической документации. Термины и определения основных понятий оригинал документа
Англо-русский словарь нормативно-технической терминологии > forging
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11 smith
[smiƟ]1) (a blacksmith.) grovsmed2) (a person whose job is to work with a particular metal, or make a particular type of article: a goldsmith; a silversmith; a gunsmith.) smed; -smed•- smithy* * *[smiƟ]1) (a blacksmith.) grovsmed2) (a person whose job is to work with a particular metal, or make a particular type of article: a goldsmith; a silversmith; a gunsmith.) smed; -smed•- smithy -
12 smith
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13 smithery
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14 Clement (Clemmet), Joseph
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]bapt. 13 June 1779 Great Asby, Westmoreland, Englandd. 28 February 1844 London, England[br]English machine tool builder and inventor.[br]Although known as Clement in his professional life, his baptism at Asby and his death were registered under the name of Joseph Clemmet. He worked as a slater until the age of 23, but his interest in mechanics led him to spend much of his spare time in the local blacksmith's shop. By studying books on mechanics borrowed from his cousin, a watchmaker, he taught himself and with the aid of the village blacksmith made his own lathe. By 1805 he was able to give up the slating trade and find employment as a mechanic in a small factory at Kirkby Stephen. From there he moved to Carlisle for two years, and then to Glasgow where, while working as a turner, he took lessons in drawing; he had a natural talent and soon became an expert draughtsman. From about 1809 he was employed by Leys, Mason \& Co. of Aberdeen designing and making power looms. For this work he built a screw-cutting lathe and continued his self-education. At the end of 1813, having saved about £100, he made his way to London, where he soon found employment as a mechanic and draughtsman. Within a few months he was engaged by Joseph Bramah, and after a trial period a formal agreement dated 1 April 1814 was made by which Clement was to be Chief Draughtsman and Superintendent of Bramah's Pimlico works for five years. However, Bramah died in December 1814 and after his sons took over the business it was agreed that Clement should leave before the expiry of the five-year period. He soon found employment as Chief Draughtsman with Henry Maudslay \& Co. By 1817 Clement had saved about £500, which enabled him to establish his own business at Prospect Place, Newington Butts, as a mechanical draughtsman and manufacturer of high-class machinery. For this purpose he built lathes for his own use and invented various improvements in their detailed design. In 1827 he designed and built a facing lathe which incorporated an ingenious system of infinitely variable belt gearing. He had also built his own planing machine by 1820 and another, much larger one in 1825. In 1828 Clement began making fluted taps and dies and standardized the screw threads, thus anticipating on a small scale the national standards later established by Sir Joseph Whitworth. Because of his reputation for first-class workmanship, Clement was in the 1820s engaged by Charles Babbage to carry out the construction of his first Difference Engine.[br]Principal Honours and DistinctionsSociety of Arts Gold Medal 1818 (for straightline mechanism), 1827 (for facing lathe); Silver Medal 1828 (for lathe-driving device).BibliographyExamples of Clement's draughtsmanship can be found in the Transactions of the Society of Arts 33 (1817), 36 (1818), 43 (1925), 46 (1828) and 48 (1829).Further ReadingS.Smiles, 1863, Industrial Biography, London, reprinted 1967, Newton Abbot (virtually the only source of biographical information on Clement).L.T.C.Rolt, 1965, Tools for the Job, London (repub. 1986); W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (both contain descriptions of his machine tools).RTSBiographical history of technology > Clement (Clemmet), Joseph
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15 Davenport, Thomas
SUBJECT AREA: Electricity[br]b. 9 July 1802 Williamstown, Vermont, USAd. 6 July 1851 Salisbury, Vermont, USA[br]American craftsman and inventor who constructed the first rotating electrical machines in the United States.[br]When he was 14 years old Davenport was apprenticed to a blacksmith for seven years. At the close of his apprenticeship in 1823 he opened a blacksmith's shop in Brandon, Vermont. He began experimenting with electromagnets after observing one in use at the Penfield Iron Works at Crown Point, New York, in 1831. He saw the device as a possible source of power and by July 1834 had constructed his first electric motor. Having totally abandoned his regular business, Davenport built and exhibited a number of miniature machines; he utilized an electric motor to propel a model car around a circular track in 1836, and this became the first recorded instance of an electric railway. An application for a patent and a model were destroyed in a fire at the United States Patent Office in December 1836, but a second application was made and Davenport received a patent the following year for Improvements in Propelling Machinery by Magnetism and Electromagnetism. A British patent was also obtained. A workshop and laboratory were established in New York, but Davenport had little financial backing for his experiments. He built a total of over one hundred motors but was defeated by the inability to obtain an inexpensive source of power. Using an electric motor of his own design to operate a printing press in 1840, he undertook the publication of a journal, The Electromagnet and Mechanics' Intelligencer. This was the first American periodical on electricity, but it was discontinued after a few issues. In failing health he retired to Vermont where in the last year of his life he continued experiments in electromagnetism.[br]Bibliography1837, US patent no. 132, "Improvements in Propelling Machinery by Magnetism and Electromagnetism".6 June 1837 British patent no. 7,386.Further ReadingF.L.Pope, 1891, "Inventors of the electric motor with special reference to the work of Thomas Davenport", Electrical Engineer, 11:1–5, 33–9, 65–71, 93–8, 125–30 (the most comprehensive account).Annals of Electricity (1838) 2:257–64 (provides a description of Davenport's motor).W.J.King, 1962, The Development of Electrical Technology in the 19th Century, Washington, DC: Smithsonian Institution, Paper 28, pp. 263–4 (a short account).GW -
16 Murray, Matthew
SUBJECT AREA: Land transport, Mechanical, pneumatic and hydraulic engineering, Railways and locomotives, Steam and internal combustion engines[br]b. 1765 near Newcastle upon Tyne, Englandd. 20 February 1826 Holbeck, Leeds, England[br]English mechanical engineer and steam engine, locomotive and machine-tool pioneer.[br]Matthew Murray was apprenticed at the age of 14 to a blacksmith who probably also did millwrighting work. He then worked as a journeyman mechanic at Stockton-on-Tees, where he had experience with machinery for a flax mill at Darlington. Trade in the Stockton area became slack in 1788 and Murray sought work in Leeds, where he was employed by John Marshall, who owned a flax mill at Adel, located about 5 miles (8 km) from Leeds. He soon became Marshall's chief mechanic, and when in 1790 a new mill was built in the Holbeck district of Leeds by Marshall and his partner Benyon, Murray was responsible for the installation of the machinery. At about this time he took out two patents relating to improvements in textile machinery.In 1795 he left Marshall's employment and, in partnership with David Wood (1761– 1820), established a general engineering and millwrighting business at Mill Green, Holbeck. In the following year the firm moved to a larger site at Water Lane, Holbeck, and additional capital was provided by two new partners, James Fenton (1754–1834) and William Lister (1796–1811). Lister was a sleeping partner and the firm was known as Fenton, Murray \& Wood and was organized so that Fenton kept the accounts, Wood was the administrator and took charge of the workshops, while Murray provided the technical expertise. The factory was extended in 1802 by the construction of a fitting shop of circular form, after which the establishment became known as the "Round Foundry".In addition to textile machinery, the firm soon began the manufacture of machine tools and steam-engines. In this field it became a serious rival to Boulton \& Watt, who privately acknowledged Murray's superior craftsmanship, particularly in foundry work, and resorted to some industrial espionage to discover details of his techniques. Murray obtained patents for improvements in steam engines in 1799, 1801 and 1802. These included automatic regulation of draught, a mechanical stoker and his short-D slide valve. The patent of 1801 was successfully opposed by Boulton \& Watt. An important contribution of Murray to the development of the steam engine was the use of a bedplate so that the engine became a compact, self-contained unit instead of separate components built into an en-gine-house.Murray was one of the first, if not the very first, to build machine tools for sale. However, this was not the case with the planing machine, which he is said to have invented to produce flat surfaces for his slide valves. Rather than being patented, this machine was kept secret, although it was apparently in use before 1814.In 1812 Murray was engaged by John Blenkinsop (1783–1831) to build locomotives for his rack railway from Middleton Colliery to Leeds (about 3 1/2 miles or 5.6 km). Murray was responsible for their design and they were fitted with two double-acting cylinders and cranks at right angles, an important step in the development of the steam locomotive. About six of these locomotives were built for the Middleton and other colliery railways and some were in use for over twenty years. Murray also supplied engines for many early steamboats. In addition, he built some hydraulic machinery and in 1814 patented a hydraulic press for baling cloth.Murray's son-in-law, Richard Jackson, later became a partner in the firm, which was then styled Fenton, Murray \& Jackson. The firm went out of business in 1843.[br]Principal Honours and DistinctionsSociety of Arts Gold Medal 1809 (for machine for hackling flax).Further ReadingL.T.C.Rolt, 1962, Great Engineers, London (contains a good short biography).E.Kilburn Scott (ed.), 1928, Matthew Murray, Pioneer Engineer, Leeds (a collection of essays and source material).C.F.Dendy Marshall, 1953, A History of Railway Locomotives Down to the End of theYear 1831, London.L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (provides information on Murray's machine-tool work).Some of Murray's correspondence with Simon Goodrich of the Admiralty has been published in Transactions of the Newcomen Society 3 (1922–3); 6(1925–6); 18(1937– 8); and 32 (1959–60).RTS -
17 Napier, Robert
SUBJECT AREA: Ports and shipping[br]b. 18 June 1791 Dumbarton, Scotlandd. 23 June 1876 Shandon, Dunbartonshire, Scotland[br]Scottish shipbuilder one of the greatest shipbuilders of all time, known as the "father" of Clyde shipbuilding.[br]Educated at Dumbarton Grammar School, Robert Napier had been destined for the Church but persuaded his father to let him serve an apprenticeship as a blacksmith under him. For a while he worked in Edinburgh, but then in 1815 he commenced business in Glasgow, the city that he served for the rest of his life. Initially his workshop was in Camlachie, but it was moved in 1836 to a riverside factory site at Lancefield in the heart of the City and again in 1841 to the Old Shipyard in the Burgh of Govan (then independent of the City of Glasgow). The business expanded through his preparedness to build steam machinery, beginning in 1823 with the engines for the paddle steamer Leven, still to be seen a few hundred metres from Napier's grave in Dumbarton. His name assured owners of quality, and business expanded after two key orders: one in 1836 for the Honourable East India Company; and the second two years later for the Royal Navy, hitherto the preserve of the Royal Dockyards and of the shipbuilders of south-east England. Napier's shipyard and engine shops, then known as Robert Napier and Sons, were to be awarded sixty Admiralty contracts in his lifetime, with a profound influence on ship and engine procurement for the Navy and on foreign governments, which for the first time placed substantial work in the United Kingdom.Having had problems with hull subcontractors and also with the installation of machinery in wooden hulls, in 1843 Napier ventured into shipbuilding with the paddle steamer Vanguard, which was built of iron. The following year the Royal Navy took delivery of the iron-hulled Jackall, enabling Napier to secure the contract for the Black Prince, Britain's second ironclad and sister ship to HMS Warrior now preserved at Portsmouth. With so much work in iron Napier instigated studies into metallurgy, and the published work of David Kirkaldy bears witness to his open-handedness in assisting the industry. This service to industry was even more apparent in 1866 when the company laid out the Skelmorlie Measured Mile on the Firth of Clyde for ship testing, a mile still in use by ships of all nations.The greatest legacy of Robert Napier was his training of young engineers, shipbuilders and naval architects. Almost every major Scottish shipyard, and some English too, was influenced by him and many of his early foremen left to set up rival establishments along the banks of the River Clyde. His close association with Samuel Cunard led to the setting up of the company now known as the Cunard Line. Napier designed and engined the first four ships, subcontracting the hulls of this historic quartet to other shipbuilders on the river. While he contributed only 2 per cent to the equity of the shipping line, they came back to him for many more vessels, including the magnificent paddle ship Persia, of 1855.It is an old tradition on the Clyde that the smokestacks of ships are made by the enginebuilders. The Cunard Line still uses red funnels with black bands, Napier's trademark, in honour of the engineer who set them going.[br]Principal Honours and DistinctionsKnight Commander of the Dannebrog (Denmark). President, Institution of Mechanical Engineers 1864. Honorary Member of the Glasgow Society of Engineers 1869.Further ReadingJames Napier, 1904, The Life of Robert Napier, Edinburgh, Blackwood.J.M.Halliday, 1980–1, "Robert Napier. The father of Clyde shipbuilding", Transactions of the Institution of Engineers and Shipbuilders in Scotland 124.Fred M.Walker, 1984, Song of the Clyde. A History of Clyde Shipbuilding, Cambridge: PSL.FMW -
18 Newcomen, Thomas
SUBJECT AREA: Steam and internal combustion engines[br]b. January or February 1663 Dartmouth, Devon, Englandd. 5 August 1729 London, England[br]English inventor and builder of the world's first successful stationary steam-engine.[br]Newcomen was probably born at a house on the quay at Dartmouth, Devon, England, the son of Elias Newcomen and Sarah Trenhale. Nothing is known of his education, and there is only dubious evidence of his apprenticeship to an ironmonger in Exeter. He returned to Dartmouth and established himself there as an "ironmonger". The term "ironmonger" at that time meant more than a dealer in ironmongery: a skilled craftsman working in iron, nearer to today's "blacksmith". In this venture he had a partner, John Calley or Caley, who was a plumber and glazier. Besides running his business in Dartmouth, it is evident that Newcomen spent a good deal of time travelling round the mines of Devon and Cornwall in search of business.Eighteenth-century writers and others found it impossible to believe that a provincial ironmonger could have invented the steam-engine, the concept of which had occupied the best scientific brains in Europe, and postulated a connection between Newcomen and Savery or Papin, but scholars in recent years have failed to find any evidence of this. Certainly Savery was in Dartmouth at the same time as Newcomen but there is nothing to indicate that they met, although it is possible. The most recent biographer of Thomas Newcomen is of the opinion that he was aware of Savery and his work, that the two men had met by 1705 and that, although Newcomen could have taken out his own patent, he could not have operated his own engines without infringing Savery's patent. In the event, they came to an agreement by which Newcomen was enabled to sell his engines under Savery's patent.The first recorded Newcomen engine is dated 1712, although this may have been preceded by a good number of test engines built at Dartmouth, possibly following a number of models. Over one hundred engines were built to Newcomen's design during his lifetime, with the first engine being installed at the Griff Colliery near Dudley Castle in Staffordshire.On the death of Thomas Savery, on 15 May 1715, a new company, the Proprietors of the Engine Patent, was formed to carry on the business. The Company was represented by Edward Elliot, "who attended the Sword Blade Coffee House in Birchin Lane, London, between 3 and 5 o'clock to receive enquiries and to act as a contact for the committee". Newcomen was, of course, a member of the Proprietors.A staunch Baptist, Newcomen married Hannah Waymouth, who bore him two sons and a daughter. He died, it is said of a fever, in London on 5 August 1729 and was buried at Bunhill Fields.[br]Further ReadingL.T.C.Rolt and J.S.Allen, 1977, The Steam Engine of Thomas Newcomen, Hartington: Moorland Publishing Company (the definitive account of his life and work).IMcN -
19 Richard of Wallingford, Abbot
SUBJECT AREA: Horology[br]b. 1291/2 Wallingford, Englandd. 23 May 1336 St Albans, Hertfordshire, England[br]English cleric, mathematician and astronomer who produced the earliest mechanical clock of which there is detailed knowledge.[br]Richard, the son of a blacksmith, was adopted by the Prior of Wallingford when his father died and educated at Oxford. He then joined the monastery at St Albans and was ordained as a priest in 1317. After a further period at Oxford studying mathematics and astronomy he returned to St Albans as Abbot in 1327. Shortly after he had been elected Abbot he started work on a very elaborate astronomical clock. The escapement and the striking mechanism of this clock were unusual. The former was a variation on the verge escapement, and the hour striking (up to twenty-four) was controlled by a series of pins laid out in a helical pattern on a drum. However, timekeeping was of secondary importance as the main purpose of the clock was to show the motion of the Sun, Moon and planets (the details of the planet mechanism are lost) and to demonstrate eclipses. This was achieved in a very precise manner by a series of ingenious mechanisms, such as the elliptical wheel that was used to derive the variable motion of the sun.Richard died of leprosy, which he had contracted during a visit to obtain papal confirmation of his appointment, and the clock was completed after his death. The last recorded reference to it was made by John Leyland, shortly before the dissolution of the monasteries. It is now known only from incomplete manuscript copies of Richard's treatise. A modern reconstruction has been made based upon J.D.North's interpretation of the manuscript.[br]BibliographyFor the drafts of Richard's Treatise on the Clock, with translation and commentary, see J.D.North, 1976, Richard of Wallingford, 3 vols, Oxford.Further ReadingSee J.D.North's definitive work above: for biographical information see Vol. 2, pp. 1–16. Most of the shorter accounts appeared before the publication of North's treatise and are therefore of more limited use.G.White, 1978, "Evolution of the epicyclic gear—part 2", Chartered Mechanical Engineer (April): 85–8 (an account of Richard's use of epicyclic gearing).DVBiographical history of technology > Richard of Wallingford, Abbot
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20 Wilkinson, David
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 5 January 1771 Smithfield (now Slatersville), Rhode Island, USAd. 3 February 1852 Caledonia Springs, Ontario, Canada[br]American mechanical engineer and inventor of a screw-cutting lathe.[br]David Wilkinson was the third son of Oziel Wilkinson (1744–1815), a blacksmith who c.1783 established at Pawtucket, Rhode Island, a plant for making farm tools and domestic utensils. This enterprise he steadily expanded with the aid of his sons, until by 1800 it was regarded as the leading iron and machinery manufacturing business in New England. At the age of 13, David Wilkinson entered his father's workshops. Their products included iron screws, and the problem of cutting the threads was one that engaged his attention. After working on it for some years he devised a screw-cutting lathe, for which he obtained a patent in 1798. In about 1800 David and his brother Daniel established their own factory at Pawtucket, known as David Wilkinson \& Co., where they specialized in the manufacture of textile machinery. Later they began to make cast cannon and installed a special boring machine for machining them. The firm prospered until 1829, when a financial crisis caused its collapse. David Wilkinson set up a new business in Cohoes, New York, but this was not a success and from 1836 he travelled around finding work chiefly in canal and bridge construction in New Jersey, Ohio and Canada. In 1848 he petitioned Congress for some reward for his invention of the screw-cutting lathe of 1798; he was awarded $10,000.[br]Further ReadingJ.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (provides a short account of David Wilkinson and his work).R.S.Woodbury, 1961, History of the Lathe to 1850, Cleveland, Ohio (includes a description of Wilkinson's screw-cutting lathe).RTS
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