boiler master

главный регулятор котла

1. boiler master

 

главный регулятор котла
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]

Тематики

• энергетика в целом

EN

• boiler master

шаблон

1) General subject: cam, centre, cliche, face mould, former, gage, gauge, jig, model, mould, pattern, routine, sample, shape, stencil, stencil plate, stereotype, template

2) Computers: layout constant

3) Geology: gauge board

4) Aviation: flat pattern

5) Medicine: mold

6) Colloquial: rubber stamp

7) Military: ( master) form

8) Engineering: bobbin (для обмотки), copy, face-mould, form, formed plate, gauge group, guide block, master form, master plate, master workpiece, matrix, picture, profile, profile form, profile gage, sampler, stencil mask (для трафаретной печати), sweep, template gage, templet, templet gage

9) Chemistry: caliber

10) Construction: basket (для фиксации положения штырей в швах бетонных дорожных покрытий), guiding rule, leveling board (для разравнивания бетонной или растворной смеси), mould board, pitch board, pregauger, reference gauge, scantling gauge, screed, screed board (для разравнивания бетонной или растворной смеси), smoothing board, strike board, strikle, mould-board, tram

11) Railway term: copperspun rotor, copying bar, moulding board

12) Australian slang: number

13) Architecture: clichu, stencil-plate

14) Mining: mule (дорожный), templex

15) Road works: mule

16) Forestry: center, molding block, molding board, sticking board, torsel

17) Metallurgy: strickle, striker, sweep (для формовки без модели)

18) Abbreviation: temp

19) Textile: drawing, outline frame, printing block (для ручной набивки), setting gauge

20) Physics: profile board

21) Electronics: mask

22) Information technology: boiler, boiler plate, boilerplate (в системах подготовки текстов), custom pattern, mold (АЛГОЛ 68), placeholder, template (Используется при описании ресурсов типа "панель диалога"), wildcard, wildcard character

23) Oil: drift mandrel, dummy (насосной установки), gage, matrice material, drift (дефектоскопия трубы, прогоняется внутри трубы)

24) Dentistry: putty index

25) Astronautics: master gage (для сверления отверстий), master plate (для сверления отверстий), template (для сверления отверстий)

26) Cartography: guide

27) Geophysics: recording patch

28) Mechanic engineering: face cam

29) Silicates: mold block, temple

30) Mechanics: control template, copy machining template, copy template, guiding template, master template, profile template

31) Sowing: preparation attachment

32) Advertising: formula

33) Drilling: rabbit

34) Sakhalin energy glossary: drift / rabbit (для проверки диаметра обсадной трубы перед спуском), gauge (gage)

35) Polymers: shaping plate

36) Programming: framework (напр. структурный), template (Параметризованный тип. Шаблон позволяет сгенерировать нужный тип - в зависимости от значения аргумента)

37) Automation: control templet, copy machining templet, copy templet, copying templet, form gage, formed, guiding templet, master, master templet, master-former, modelwork, profile templet, tracing master

38) Quality control: profile gauge

39) Plastics: calibre, stencil (для раскраски и печати)

40) Sakhalin R: gauge (gage)

41) Cables: template (templet)

42) Makarov: former (напр. буквы для изготовления пуансона), prototype, replica, transparency

43) Tengiz: ( track) gage

44) Karachaganak: gage ring, gauge ring

45) Cement: screeding board (для разравнивания бетонной смеси)

46) Dental implantology: stent, surgical drive, surgical guide, surgical implant index, surgical stent, surgical template

Trevithick, Richard

SUBJECT AREA: Land transport, Railways and locomotives, Steam and internal combustion engines

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b. 13 April 1771 Illogan, Cornwall, England

d. 22 April 1833 Dartford, Kent, England

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English engineer, pioneer of non-condensing steam-engines; designed and built the first locomotives.

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Trevithick's father was a tin-mine manager, and Trevithick himself, after limited formal education, developed his immense engineering talent among local mining machinery and steam-engines and found employment as a mining engineer. Tall, strong and high-spirited, he was the eternal optimist.

About 1797 it occurred to him that the separate condenser patent of James Watt could be avoided by employing "strong steam", that is steam at pressures substantially greater than atmospheric, to drive steam-engines: after use, steam could be exhausted to the atmosphere and the condenser eliminated. His first winding engine on this principle came into use in 1799, and subsequently such engines were widely used. To produce high-pressure steam, a stronger boiler was needed than the boilers then in use, in which the pressure vessel was mounted upon masonry above the fire: Trevithick designed the cylindrical boiler, with furnace tube within, from which the Cornish and later the Lancashire boilers evolved.

Simultaneously he realized that high-pressure steam enabled a compact steam-engine/boiler unit to be built: typically, the Trevithick engine comprised a cylindrical boiler with return firetube, and a cylinder recessed into the boiler. No beam intervened between connecting rod and crank. A master patent was taken out.

Such an engine was well suited to driving vehicles. Trevithick built his first steam-carriage in 1801, but after a few days' use it overturned on a rough Cornish road and was damaged beyond repair by fire. Nevertheless, it had been the first self-propelled vehicle successfully to carry passengers. His second steam-carriage was driven about the streets of London in 1803, even more successfully; however, it aroused no commercial interest. Meanwhile the Coalbrookdale Company had started to build a locomotive incorporating a Trevithick engine for its tramroads, though little is known of the outcome; however, Samuel Homfray's ironworks at Penydarren, South Wales, was already building engines to Trevithick's design, and in 1804 Trevithick built one there as a locomotive for the Penydarren Tramroad. In this, and in the London steam-carriage, exhaust steam was turned up the chimney to draw the fire. On 21 February the locomotive hauled five wagons with 10 tons of iron and seventy men for 9 miles (14 km): it was the first successful railway locomotive.

Again, there was no commercial interest, although Trevithick now had nearly fifty stationary engines completed or being built to his design under licence. He experimented with one to power a barge on the Severn and used one to power a dredger on the Thames. He became Engineer to a project to drive a tunnel beneath the Thames at Rotherhithe and was only narrowly defeated, by quicksands. Trevithick then set up, in 1808, a circular tramroad track in London and upon it demonstrated to the admission-fee-paying public the locomotive Catch me who can, built to his design by John Hazledine and J.U. Rastrick.

In 1809, by which date Trevithick had sold all his interest in the steam-engine patent, he and Robert Dickinson, in partnership, obtained a patent for iron tanks to hold liquid cargo in ships, replacing the wooden casks then used, and started to manufacture them. In 1810, however, he was taken seriously ill with typhus for six months and had to return to Cornwall, and early in 1811 the partners were bankrupt; Trevithick was discharged from bankruptcy only in 1814.

In the meantime he continued as a steam engineer and produced a single-acting steam engine in which the cut-off could be varied to work the engine expansively by way of a three-way cock actuated by a cam. Then, in 1813, Trevithick was approached by a representative of a company set up to drain the rich but flooded silver-mines at Cerro de Pasco, Peru, at an altitude of 14,000 ft (4,300 m). Low-pressure steam engines, dependent largely upon atmospheric pressure, would not work at such an altitude, but Trevithick's high-pressure engines would. Nine engines and much other mining plant were built by Hazledine and Rastrick and despatched to Peru in 1814, and Trevithick himself followed two years later. However, the war of independence was taking place in Peru, then a Spanish colony, and no sooner had Trevithick, after immense difficulties, put everything in order at the mines then rebels arrived and broke up the machinery, for they saw the mines as a source of supply for the Spanish forces. It was only after innumerable further adventures, during which he encountered and was assisted financially by Robert Stephenson, that Trevithick eventually arrived home in Cornwall in 1827, penniless.

He petitioned Parliament for a grant in recognition of his improvements to steam-engines and boilers, without success. He was as inventive as ever though: he proposed a hydraulic power transmission system; he was consulted over steam engines for land drainage in Holland; and he suggested a 1,000 ft (305 m) high tower of gilded cast iron to commemorate the Reform Act of 1832. While working on steam propulsion of ships in 1833, he caught pneumonia, from which he died.

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Bibliography

Trevithick took out fourteen patents, solely or in partnership, of which the most important are: 1802, Construction of Steam Engines, British patent no. 2,599. 1808, Stowing Ships' Cargoes, British patent no. 3,172.

Further Reading

H.W.Dickinson and A.Titley, 1934, Richard Trevithick. The Engineer and the Man, Cambridge; F.Trevithick, 1872, Life of Richard Trevithick, London (these two are the principal biographies).

E.A.Forward, 1952, "Links in the history of the locomotive", The Engineer (22 February), 226 (considers the case for the Coalbrookdale locomotive of 1802).

See also: Blenkinsop, John

PJGR

Fairlie, Robert Francis

SUBJECT AREA: Land transport, Railways and locomotives

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b. March 1831 Scotland

d. 31 July 1885 Clapham, London, England

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British engineer, designer of the double-bogie locomotive, advocate of narrow-gauge railways.

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Fairlie worked on railways in Ireland and India, and established himself as a consulting engineer in London by the early 1860s. In 1864 he patented his design of locomotive: it was to be carried on two bogies and had a double boiler, the barrels extending in each direction from a central firebox. From smokeboxes at the outer ends, return tubes led to a single central chimney. At that time in British practice, locomotives of ever-increasing size were being carried on longer and longer rigid wheelbases, but often only one or two of their three or four pairs of wheels were powered. Bogies were little used and then only for carrying-wheels rather than driving-wheels: since their pivots were given no sideplay, they were of little value. Fairlie's design offered a powerful locomotive with a wheelbase which though long would be flexible; it would ride well and have all wheels driven and available for adhesion.

The first five double Fairlie locomotives were built by James Cross \& Co. of St Helens during 1865–7. None was particularly successful: the single central chimney of the original design had been replaced by two chimneys, one at each end of the locomotive, but the single central firebox was retained, so that exhaust up one chimney tended to draw cold air down the other. In 1870 the next double Fairlie, Little Wonder, was built for the Festiniog Railway, on which C.E. Spooner was pioneering steam trains of very narrow gauge. The order had gone to George England, but the locomotive was completed by his successor in business, the Fairlie Engine \& Steam Carriage Company, in which Fairlie and George England's son were the principal partners. Little Wonder was given two inner fireboxes separated by a water space and proved outstandingly successful. The spectacle of this locomotive hauling immensely long trains up grade, through the Festiniog Railway's sinuous curves, was demonstrated before engineers from many parts of the world and had lasting effect. Fairlie himself became a great protagonist of narrow-gauge railways and influenced their construction in many countries.

Towards the end of the 1860s, Fairlie was designing steam carriages or, as they would now be called, railcars, but only one was built before the death of George England Jr precipitated closure of the works in 1870. Fairlie's business became a design agency and his patent locomotives were built in large numbers under licence by many noted locomotive builders, for narrow, standard and broad gauges. Few operated in Britain, but many did in other lands; they were particularly successful in Mexico and Russia.

Many Fairlie locomotives were fitted with the radial valve gear invented by Egide Walschaert; Fairlie's role in the universal adoption of this valve gear was instrumental, for he introduced it to Britain in 1877 and fitted it to locomotives for New Zealand, whence it eventually spread worldwide. Earlier, in 1869, the Great Southern \& Western Railway of Ireland had built in its works the first "single Fairlie", a 0–4–4 tank engine carried on two bogies but with only one of them powered. This type, too, became popular during the last part of the nineteenth century. In the USA it was built in quantity by William Mason of Mason Machine Works, Taunton, Massachusetts, in preference to the double-ended type.

Double Fairlies may still be seen in operation on the Festiniog Railway; some of Fairlie's ideas were far ahead of their time, and modern diesel and electric locomotives are of the powered-bogie, double-ended type.

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Bibliography

1864, British patent no. 1,210 (Fairlie's master patent).

1864, Locomotive Engines, What They Are and What They Ought to Be, London; reprinted 1969, Portmadoc: Festiniog Railway Co. (promoting his ideas for locomotives).

1865, British patent no. 3,185 (single Fairlie).

1867. British patent no. 3,221 (combined locomotive/carriage).

1868. "Railways and their Management", Journal of the Society of Arts: 328. 1871. "On the Gauge for Railways of the Future", abstract in Report of the Fortieth

Meeting of the British Association in 1870: 215. 1872. British patent no. 2,387 (taper boiler).

1872, Railways or No Railways. "Narrow Gauge, Economy with Efficiency; or Broad Gauge, Costliness with Extravagance", London: Effingham Wilson; repr. 1990s Canton, Ohio: Railhead Publications (promoting the cause for narrow-gauge railways).

Further Reading

Fairlie and his patent locomotives are well described in: P.C.Dewhurst, 1962, "The Fairlie locomotive", Part 1, Transactions of the Newcomen Society 34; 1966, Part 2, Transactions 39.

R.A.S.Abbott, 1970, The Fairlie Locomotive, Newton Abbot: David \& Charles.

PJGR

Pattinson, Hugh Lee

SUBJECT AREA: Metallurgy

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b. 25 December 1796 Alston, Cumberland, England

d. 11 November 1858 Scot's House, Gateshead, England

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English inventor of a silver-extraction process.

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Born into a Quaker family, he was educated at private schools; his studies included electricity and chemistry, with a bias towards metallurgy. Around 1821 Pattinson became Clerk and Assistant to Anthony Clapham, a soap-boiler of Newcastle upon Tyne. In 1825 he secured appointment as Assay Master to the lords of the manor of Alston. There he was able to pursue the subject of special interest to him, and in January 1829 he devised a method of separating silver from lead ore; however, he was prevented from developing it because of a lack of funds.

Two years later he was appointed Manager of Wentworth Beaumont's lead-works. There he was able to continue his researches, which culminated in the patent of 1833 enshrining the invention by which he is best known: a new process for extracting silver from lead by skimming crystals of pure lead with a perforated ladle from the surface of the molten silver-bearing lead, contained in a succession of cast-iron pots. The molten metal was stirred as it cooled until one pot provided a metal containing 300 oz. of silver to the ton (8,370 g to the tonne). Until that time, it was unprofitable to extract silver from lead ores containing less than 8 oz. per ton (223 g per tonne), but the Pattinson process reduced that to 2–3 oz. (56–84 g per tonne), and it therefore won wide acceptance. Pattinson resigned his post and went into partnership to establish a chemical works near Gateshead. He was able to devise two further processes of importance, one an improved method of obtaining white lead and the other a new process for manufacturing magnesia alba, or basic carbonate of magnesium. Both processes were patented in 1841.

Pattinson retired in 1858 and devoted himself to the study of astronomy, aided by a 7½ in. (19 cm) equatorial telescope that he had erected at his home at Scot's House.

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Principal Honours and Distinctions

Vice-President, British Association Chemical Section 1838. Fellow of the Geological Society, Royal Astronomical Society and Royal Society 1852.

Bibliography

Pattinson wrote eight scientific papers, mainly on mining, listed in Royal Society Catalogue of Scientific Papers, most of which appeared in the Philosophical

Magazine.

Further Reading

J.Percy, Metallurgy (volume on lead): 121–44 (fully describes Pattinson's desilvering process).

Lonsdale, 1873, Worthies of Cumberland, pp. 273–320 (contains details of his life). T.K.Derry and T.I.Williams, 1960, A Short History ofTechnology, Oxford: Oxford University Press.

LRD