erected equipment

erected equipment

Экономика: установленное оборудование

erected equipment

установленное оборудование

equipment

n

оборудование; снаряжение; оснащение

- advanced equipment
- agricultural equipment
- accessory equipment
- ancillary equipment
- assembly line equipment
- audiovisual equipment
- automated equipment
- automatic equipment
- auxiliary equipment
- basic equipment
- business equipment
- capital equipment
- capitalized equipment
- cargo-handling equipment
- carrier equipment
- cine equipment
- clerical equipment
- commercial equipment
- competitive equipment
- complete equipment
- complex equipment
- construction equipment
- contract equipment
- damaged equipment
- data transmission equipment
- delivered equipment
- defective equipment
- durable equipment
- efficient equipment
- electric equipment
- electrical equipment
- electronic equipment
- electronic payment equipment
- emergency equipment
- erected equipment
- erecting equipment
- exhibition equipment
- factory equipment
- farm equipment
- fast-wearing equipment
- fire-fighting equipment
- first-rate equipment
- food-packaging equipment
- handling equipment
- heavy equipment
- heavy-duty equipment
- high-fi equipment
- hi-fi equipment
- high-precision equipment
- high quality equipment
- high-technology equipment
- hoisting and conveying equipment
- home equipment
- idle equipment
- imported equipment
- incomplete equipment
- industrial equipment
- installed equipment
- labour-displacing equipment
- labour-saving equipment
- lifting equipment
- loading equipment
- loading-unloading equipment
- main equipment
- maintenance equipment
- manufacturing equipment
- materials-handling equipment
- mechanical equipment
- metallurgical equipment
- miscellaneous equipment
- missing equipment
- modern equipment
- modified equipment
- morally obsolete equipment
- mounted equipment
- nondurable equipment
- nonstandard equipment
- nuclear equipment
- obsolete equipment
- office equipment
- operating equipment
- operative equipment
- optional equipment
- ordered equipment
- outdated equipment
- overhaul equipment
- oversized equipment
- packing equipment
- patent equipment
- peripheral equipment
- permanent equipment
- plant equipment
- port equipment
- portable equipment
- power-generating equipment
- process equipment
- process control equipment
- producers' durable equipment
- production equipment
- productive equipment
- purchased equipment
- rapidly-wearing equipment
- repair equipment
- rental equipment
- replaceable equipment
- revenue equipment
- ro-ro equipment
- quick-wearing equipment
- safety equipment
- second-hand equipment
- secondary equipment
- semi-automatic equipment
- service equipment
- serial equipment
- shop equipment
- short-lived equipment
- short-shipped equipment
- sophisticated equipment
- specialized equipment
- special-purpose equipment
- stand equipment
- standard equipment
- standby equipment
- storage equipment
- technical equipment
- technological equipment
- third generation equipment
- transport equipment
- transportation equipment
- unique equipment
- unserviceable equipment
- up-to-date equipment
- used equipment
- weighing equipment
- working equipment
- worn-out equipment
- equipment of high quality
- equipment of home manufacture
- equipment of new generations
- equipment of serial production
- equipment on display
- assemble equipment
- buy equipment
- check equipment
- deal in equipment
- deliver equipment
- design equipment
- dismantle equipment
- erect equipment
- improve equipment
- install equipment
- lease equipment
- manufacture equipment
- market equipment
- modify equipment
- mount equipment
- obtain equipment
- pack equipment
- procure equipment
- produce equipment
- purchase equipment
- put equipment into operation
- reject defective equipment
- rent equipment
- repair equipment
- retain equipment
- secure equipment
- sell equipment
- service equipment
- ship equipment
- supply equipment
- upgrade equipment
- use equipment
- utilize equipment

установленное оборудование

1) Military: installed equipment

2) Engineering: mounted equipment

3) Economy: equipment in place, erected equipment

4) Telecommunications: equipment in position

5) Astronautics: fixed equipment

6) Makarov: inventory

Barber, John

SUBJECT AREA: Aerospace, Steam and internal combustion engines

[br]

baptized 22 October 1734 Greasley, Nottinghamshire, England

d. 6 November 1801 Attleborough, Nuneaton, England

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English inventor of the gas turbine and jet propulsion.

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He was the son of Francis Barber, coalmaster of Greasley, and Elizabeth Fletcher. In his will of 1765. his uncle, John Fletcher, left the bulk of his property, including collieries and Stainsby House, Horsley Woodhouse, Derbyshire, to John Barber. Another uncle, Robert, bequeathed him property in the next village, Smalley. It is clear that at this time John Barber was a man of considerable means. On a tablet erected by John in 1767, he acknowledges his debt to his uncle John in the words "in remembrance of the man who trained him up from a youth". At this time John Barber was living at Stainsby House and had already been granted his first patent, in 1766. The contents of this patent, which included a reversible water turbine, and his subsequent patents, suggest that he was very familiar with mining equipment, including the Newcomen engine. It comes as rather a surprise that c.1784 he became bankrupt and had to leave Stainsby House, evidently moving to Attleborough. In a strange twist, a descendent of Mr Sitwell, the new owner, bought the prototype Akroyd Stuart oil engine from the Doncaster Show in 1891.

The second and fifth (final) patents, in 1773 and 1792, were concerned with smelting and the third, in 1776, featured a boiler-mounted impulse steam turbine. The fourth and most important patent, in 1791, describes and engine that could be applied to the "grinding of corn, flints, etc.", "rolling, slitting, forging or battering iron and other metals", "turning of mills for spinning", "turning up coals and other minerals from mines", and "stamping of ores, raising water". Further, and importantly, the directing of the fluid stream into smelting furnaces or at the stern of ships to propel them is mentioned. The engine described comprised two retorts for heating coal or oil to produce an inflammable gas, one to operate while the other was cleansed and recharged. The resultant gas, together with the right amount of air, passed to a beam-operated pump and a water-cooled combustion chamber, and then to a water-cooled nozzle to an impulse gas turbine, which drove the pumps and provided the output. A clear description of the thermodynamic sequence known as the Joule Cycle (Brayton in the USA) is thus given. Further, the method of gas production predates Murdoch's lighting of the Soho foundry by gas.

It seems unlikely that John Barber was able to get his engine to work; indeed, it was well over a hundred years before a continuous combustion chamber was achieved. However, the details of the specification, for example the use of cooling water jackets and injection, suggest that considerable experimentation had taken place.

To be active in the taking out of patents over a period of 26 years is remarkable; that the best came after bankruptcy is more so. There is nothing to suggest that the cost of his experiments was the cause of his financial troubles.

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Further Reading

A.K.Bruce, 1944, "John Barber and the gas turbine", Engineer 29 December: 506–8; 8 March (1946):216, 217.

C.Lyle Cummins, 1976, Internal Fire, Carnot Press.

JB

Junghans, Siegfried

SUBJECT AREA: Metallurgy

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b. 1887

d. 1954

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German pioneer of the continuous casting of metals.

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Junghans was of the family that owned Gebrüder Junghans, one of the largest firms in the German watch-and clockmaking industry. From 1906 to 1918 he served in the German Army, after which he took a course in metallurgy and analytical chemistry at the Technical High School in Stuttgart. Junghans was then given control of the brassworks owned by his family. He wanted to make castings simply and cheaply, but he found that he lacked the normal foundry equipment. By 1927, formulating his ideas on continuous casting, he had conceived a way of overcoming this deficiency and began experiments. By the time the firm was taken over by Wieland-Werke AG in 1931, Junghans had achieved positive results. A test plant was erected in 1932, and commercial production of continuously cast metal followed the year after. Wieland told Junghans that a brassfounder who had come up through the trade would never have hit on the idea: it took an outsider like Junghans to do it. He was made Technical Director of Wielands but left in 1935 to work privately on the development of continuous casting for all metals. He was able to license the process for non-ferrous metals during 1936–9 in Germany and other countries, but the Second World War interrupted his work; however, the German government supported him and a production plant was built. In 1948 he was able to resume work on the continuous casting of steel, which he had been considering since 1936. He pushed on in spite of financial difficulties and produced the first steel by this process at Schorndorf in March 1949. From 1950 he made agreements with four firms to work towards the pilot plant stage, and this was achieved in 1954 at Mannesmann's Huckingen works. The aim of continuous casting is to bypass the conventional processes of casting molten steel into ingots, reheating the ingots and shaping them by rolling them in a large mill. Essentially, in continuous casting, molten steel is drawn through the bottom of a ladle and down through a water-cooled copper mould. The unique feature of Junghans's process was the vertically reciprocating mould, which prevented the molten metal sticking as it passed through. A continuous length of steel is taken off and cooled until it is completely solidified into the required shape. The idea of continuous casting can be traced back to Bessemer, and although others tried to apply it later, they did not have any success. It was Junghans who, more than anybody, made the process a reality.

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Further Reading

K.Sperth and A.Bungeroth, 1953, "The Junghans method of continuous casting of steel", Metal Treatment and Drop Forging, Mayn.

J.Jewkes et al., 1969, The Sources of Invention, 2nd edn, London: Macmillan, pp. 287 ff.

LRD

Yeoman, Thomas

SUBJECT AREA: Civil engineering

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b. c. 1700 probably near Northampton, England

d. 24 January 1781 London, England

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English surveyor and civil engineer.

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Very little is known of his early life, but he was clearly a skilful and gifted engineer who had received comprehensive practical training, for in 1743 he erected the machinery in the world's first water-powered cotton mill at Northampton on the river Nene. In 1748 he invented a weighing machine for use by turnpike trusts for weighing wagons. Until 1757 he remained in Northampton, mainly surveying enclosures and turnpike roads and making agricultural machinery. He also gained a national reputation for building and installing very successful ventilating equipment (invented by Dr Stephen Hales) in hospitals, prisons and ships, including some ventilators of Yeoman's own design in the Houses of Parliament.

Meanwhile he developed an interest in river improvements, and in 1744 he made his first survey of the River Nene between Thrapston and Northampton; he repeated the survey in 1753 and subsequently gave evidence in parliamentary proceedings in 1756. The following year he was in Gloucestershire surveying the line of the Stroudwater Canal, an operation that he repeated in 1776. Also in 1757, he was appointed Surveyor to the River Ivel Navigation in Bedfordshire. In 1761 he was back on the Nene. During 1762–5 he carried out surveys for the Chelmer \& Blackwater Navigation, although the work was not undertaken for another thirty years. In 1765 he reported on land-drainage improvements for the Kentish Sour. It was at this time that he became associated with John Smeaton in a major survey in 1766 of the river Lea for the Lee Navigation Trustees, having already made some surveys with Joseph Nickalls near Waltham Abbey in 1762. Yeoman modified some of Smeaton's proposals and on 1 July 1767 was officially appointed Surveyor to the Lee Navigation Trustees, a post he retained until 1771. He also advised on the work to create the Stort Navigation, and at the official opening on 24 October 1769 he made a formal speech announcing: "Now is Bishops Stortford open to all the ports of the world." Among his other works were: advice on Ferriby Sluice on the River Ancholme (1766); reports on the Forth \& Clyde Canal, the North Level and Wisbech outfall on the Nene, the Coventry Canal, and estimates for the Leeds and Selby Canal (1768–71); estimates for the extension of the Medway Navigation from Tonbridge to Edenbridge (1771); and between 1767 and 1777 he was consulted, with other engineers, by the City of London on problems regarding the Thames.

He joined the Northampton Philosophical Society shortly after its formation in 1743 and was President several times before he moved to London. In 1760 he became a member of the Society for the Encouragement of Arts, Manufactures and Commerce, and in 1763 he was chosen as joint Chairman of the Committee on Mechanics—a position he held until 1778. He was elected a Fellow of the Royal Society on 12 January 1764. On the formation of the Smeatonian Society of Civil Engineers, the forerunner of the present Institution of Civil Engineers, he was elected first President in 1771, remaining as such until his illness in 1780.

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Principal Honours and Distinctions

FRS 1764. President, Smeatonian Society of Civil Engineers 1771–80; Treasurer 1771–7.

JHB