cylinder+press

Guericke, Otto von

SUBJECT AREA: Electricity, Mechanical, pneumatic and hydraulic engineering

[br]

b. 20 November 1602 Magdeburg, Saxony, Germany

d. 11 May 1686 Hamburg, Germany

[br]

German engineer and physicist, inventor of the air pump and investigator of the properties of a vacuum.

[br]

Guericke was born into a patrician family in Magdeburg. He was educated at the University of Leipzig in 1617–20 and at the University of Helmstedt in 1620. He then spent two years studying law at Jena, and in 1622 went to Leiden to study law, mathematics, engineering and especially fortification. He spent most of his life in politics, for he was elected an alderman of Magdeburg in 1626. After the destruction of Magdeburg in 1631, he worked in Brunswick and Erfurt as an engineer for the Swedish government, and then in 1635 for the Electorate of Saxony. He was Mayor of Magdeburg for thirty years, between 1646 and 1676. He was ennobled in 1666 and retired from public office in 168land went to Hamburg. It was through his attendances at international congresses and at princely courts that he took part in the exchange of scientific ideas.

From his student days he was concerned with the definition of space and posed three questions: can empty space exist or is space always filled? How can heavenly bodies affect each other across space and how are they moved? Is space, and so also the heavenly bodies, bounded or unbounded? In c. 1647 Guericke made a suction pump for air and tried to exhaust a beer barrel, but he could not stop the leaks. He then tried a copper sphere, which imploded. He developed a series of spectacular demonstrations with his air pump. In 1654 at Rattisbon he used a vertical cylinder with a well-fitting piston connected over pulleys by a rope to fifty men, who could not stop the piston descending when the cylinder was exhausted. More famous were his copper hemispheres which, when exhausted, could not be drawn apart by two teams of eight horses. They were first demonstrated at Magdeburg in 1657 and at the court in Berlin in 1663. Through these experiments he discovered the elasticity of air and began to investigate its density at different heights. He heard of the work of Torricelli in 1653 and by 1660 had succeeded in making barometric forecasts. He published his famous work New Experiments Concerning Empty Space in 1672. Between 1660 and 1663 Guericke constructed a large ball of sulphur that could be rotated on a spindle. He found that, when he pressed his hand on it and it was rotated, it became strongly electrified; he thus unintentionally became the inventor of the first machine to generate static electricity. He attempted to reach a complete physical explanation of the world and the heavens with magnetism as a primary force and evolved an explanation for the rotation of the heavenly bodies.

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Bibliography

1672, Experimenta nova (ut vocantur) Magdeburgica de vacuo spatio (New Experiments Concerning Empty Space).

Further Reading

F.W.Hoffmann, 1874, Otto von Guericke (a full biography).

T.I.Williams (ed.), 1969, A Biographical Dictionary of Scientists, London: A. \& C.Black (contains a short account of his life).

Chambers Concise Dictionary of Scientists, 1989, Cambridge.

Dictionary of Scientific Biography, Vol. V, New York.

C.Singer (ed.), 1957, A History of Technology, Vols. III and IV, Oxford University Press (includes references to Guericke's inventions).

RLH

Reynolds, Edwin

SUBJECT AREA: Public utilities, Steam and internal combustion engines

[br]

b. 1831 Mansfield, Connecticut, USA

d. 1909 Milwaukee, Wisconsin, USA

[br]

American contributor to the development of the Corliss valve steam engine, including the "Manhattan" layout.

[br]

Edwin Reynolds grew up at a time when formal engineering education in America was almost unavailable, but through his genius and his experience working under such masters as G.H. Corliss and William Wright, he developed into one of the best mechanical engineers in the country. When he was Plant Superintendent for the Corliss Steam Engine Company, he built the giant Corliss valve steam engine displayed at the 1876 Centennial Exhibition. In July 1877 he left the Corliss Steam Engine Company to join Edward Allis at his Reliance Works, although he was offered a lower salary. In 1861 Allis had moved his business to the Menomonee Valley, where he had the largest foundry in the area. Immediately on his arrival with Allis, Reynolds began desig-ning and building the "Reliance-Corliss" engine, which becamea symbol of simplicity, economy and reliability. By early 1878 the new engine was so successful that the firm had a six-month backlog of orders. In 1888 he built the first triple-expansion waterworks-pumping engine in the United States for the city of Milwaukee, and in the same year he patented a new design of blowing engine for blast furnaces. He followed this in March 1892 with the first steam engine sets coupled directly to electric generators when Allis-Chalmers contracted to build two Corliss cross-compound engines for the Narragansett Light Company of Providence, Rhode Island. In 1893, one of the impressive attractions at the World's Columbian Exposition in Chicago was the 3,000 hp (2,200 kW) quadruple-expansion Reynolds-Corliss engine designed by Reynolds, who continued to make significant improvements and gained worldwide recognition of his outstanding achievements in engine building.

Reynolds was asked to go to New York in 1898 for consultation about some high-horsepower engines for the Manhattan transport system. There, 225 railway locomotives were to be replaced by electric trains, which would be supplied from one generating station producing 60,000 hp (45,000 kW). Reynolds sketched out his ideas for 10,000 hp (7,500 kW) engines while on the train. Because space was limited, he suggested a four-cylinder design with two horizontal-high-pressure cylinders and two vertical, low-pressure ones. One cylinder of each type was placed on each side of the flywheel generator, which with cranks at 135° gave an exceptionally smooth-running compact engine known as the "Manhattan". A further nine similar engines that were superheated and generated three-phase current were supplied in 1902 to the New York Interborough Rapid Transit Company. These were the largest reciprocating steam engines built for use on land, and a few smaller ones with a similar layout were installed in British textile mills.

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Further Reading

Concise Dictionary of American Biography, 1964, New York: C.Scribner's Sons (contains a brief biography).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (provides a brief account of the Manhattan engines) Part of the information for this biography is derived from a typescript in the Smithsonian Institution, Washington, DC: T.H.Fehring, "Technological contributions of Milwaukee's Menomonee Valley industries".

RLH

Wasborough, Matthew

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 1753 Bristol, England

d. 21 October 1781 Bristol, England

[br]

English patentee of an application of the flywheel to create a rotative steam engine.

[br]

A single-cylinder atmospheric steam engine had a power stroke only when the piston descended the cylinder: a means had to be found of returning the piston to its starting position. For rotative engines, this was partially solved by the patent of Matthew Wasborough in 1779. His father was a partner in a Bristol brass-founding and clockmaking business in Narrow Wine Street where he was joined by his son. Wasborough proposed to use some form of ratchet gear to effect the rotary motion and added a flywheel, the first time one was used in a steam engine, "in order to render the motion more regular and uniform". He installed one engine to drive the lathes in the Bristol works and another at James Pickard's flour mill at Snow Hill, Birmingham, where Pickard applied his recently patented crank to it. It was this Wasborough-Pickard engine which posed a threat to Boulton \& Watt trying to develop a rotative engine, for Wasborough built several engines for cornmills in Bristol, woollen mills in Gloucestershire and a block factory at Southampton before his early death. Matthew Boulton was told that Wasborough was "so intent upon the study of engines as to bring a fever on his brain and he dyed in consequence thereof…. How dangerous it is for a man to wade out of his depth" (Jenkins 1936:106).

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Bibliography

1779, British patent no. 1,213 (rotative engine with flywheel).

Further Reading

J.Tann, 1978–9, "Makers of improved Newcomen engines in the late 18th century, and R.A.Buchanan", 1978–9, "Steam and the engineering community in the eighteenth century", Transactions of the Newcomen Society 50 ("Thomas Newcomen. A commemorative symposium") (both papers discuss Wasborough's engines).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (examines his patent).

R.Jenkins (ed.), 1936, Collected Papers, 106 (for Matthew Boulton's letter of 30 October 1781).

RLH

Watt, James

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 19 January 1735 Greenock, Renfrewshire, Scotland

d. 19 August 1819 Handsworth Heath, Birmingham, England

[br]

Scottish engineer and inventor of the separate condenser for the steam engine.

[br]

The sixth child of James Watt, merchant and general contractor, and Agnes Muirhead, Watt was a weak and sickly child; he was one of only two to survive childhood out of a total of eight, yet, like his father, he was to live to an age of over 80. He was educated at local schools, including Greenock Grammar School where he was an uninspired pupil. At the age of 17 he was sent to live with relatives in Glasgow and then in 1755 to London to become an apprentice to a mathematical instrument maker, John Morgan of Finch Lane, Cornhill. Less than a year later he returned to Greenock and then to Glasgow, where he was appointed mathematical instrument maker to the University and was permitted in 1757 to set up a workshop within the University grounds. In this position he came to know many of the University professors and staff, and it was thus that he became involved in work on the steam engine when in 1764 he was asked to put in working order a defective Newcomen engine model. It did not take Watt long to perceive that the great inefficiency of the Newcomen engine was due to the repeated heating and cooling of the cylinder. His idea was to drive the steam out of the cylinder and to condense it in a separate vessel. The story is told of Watt's flash of inspiration as he was walking across Glasgow Green one Sunday afternoon; the idea formed perfectly in his mind and he became anxious to get back to his workshop to construct the necessary apparatus, but this was the Sabbath and work had to wait until the morrow, so Watt forced himself to wait until the Monday morning.

Watt designed a condensing engine and was lent money for its development by Joseph Black, the Glasgow University professor who had established the concept of latent heat. In 1768 Watt went into partnership with John Roebuck, who required the steam engine for the drainage of a coal-mine that he was opening up at Bo'ness, West Lothian. In 1769, Watt took out his patent for "A New Invented Method of Lessening the Consumption of Steam and Fuel in Fire Engines". When Roebuck went bankrupt in 1772, Matthew Boulton, proprietor of the Soho Engineering Works near Birmingham, bought Roebuck's share in Watt's patent. Watt had met Boulton four years earlier at the Soho works, where power was obtained at that time by means of a water-wheel and a steam engine to pump the water back up again above the wheel. Watt moved to Birmingham in 1774, and after the patent had been extended by Parliament in 1775 he and Boulton embarked on a highly profitable partnership. While Boulton endeavoured to keep the business supplied with capital, Watt continued to refine his engine, making several improvements over the years; he was also involved frequently in legal proceedings over infringements of his patent.

In 1794 Watt and Boulton founded the new company of Boulton \& Watt, with a view to their retirement; Watt's son James and Boulton's son Matthew assumed management of the company. Watt retired in 1800, but continued to spend much of his time in the workshop he had set up in the garret of his Heathfield home; principal amongst his work after retirement was the invention of a pantograph sculpturing machine.

James Watt was hard-working, ingenious and essentially practical, but it is doubtful that he would have succeeded as he did without the business sense of his partner, Matthew Boulton. Watt coined the term "horsepower" for quantifying the output of engines, and the SI unit of power, the watt, is named in his honour.

[br]

Principal Honours and Distinctions

FRS 1785. Honorary LLD, University of Glasgow 1806. Foreign Associate, Académie des Sciences, Paris 1814.

Further Reading

H.W.Dickinson and R Jenkins, 1927, James Watt and the Steam Engine, Oxford: Clarendon Press.

L.T.C.Rolt, 1962, James Watt, London: B.T. Batsford.

R.Wailes, 1963, James Watt, Instrument Maker (The Great Masters: Engineering Heritage, Vol. 1), London: Institution of Mechanical Engineers.

IMcN

печатная машина планетарного типа

1) Engineering: common impression cylinder printing press

2) Polygraphy: satellite printing press

3) Makarov: around press

самопресс

1) Textile: cylinder mangle, rotary press, rotary steam press

2) Oil: mouldenpress

rodillo

m.

1 rolling pin.

2 roller.

3 (paint) roller.

4 clod crusher.

* * *

rodillo

► nombre masculino

1 roller

2 COCINA rolling pin

* * *

noun m.

roller

* * *

SM (Culin) rolling pin; (Tip) ink roller; [de máquina de escribir] cylinder, roller; [para pintura, césped] roller; (=exprimidor) mangle; (Agr) roller

rodillo de pintura — paint roller

rodillo de vapor — steamroller

rodillo pastelero — rolling pin

* * *

masculino ( de cocina) rolling pin; ( para pintar) paint roller; ( de máquina de escribir) roller, platen; ( de tinta) ink roller; ( de lavadora) mangle, wringer

* * *

= paint roller.

Ex. It was the portrait of a woman standing against a wall with a paint roller.

----

* material del rodillo = roller stock.

* prensa tipográfica de rodillos = rolling press.

* rodillo de amasar = rolling pin.

* rodillo del tintero = fountain roller.

* rodillo entintador = roller, inking roller.

* rodillo en vitela = wove dandy.

* rodillo filigranador = dandy roll, dandy.

* rodillo para pintar = paint roller.

* * *

masculino ( de cocina) rolling pin; ( para pintar) paint roller; ( de máquina de escribir) roller, platen; ( de tinta) ink roller; ( de lavadora) mangle, wringer

* * *

= paint roller.

Ex: It was the portrait of a woman standing against a wall with a paint roller.

* material del rodillo = roller stock.

* prensa tipográfica de rodillos = rolling press.

* rodillo de amasar = rolling pin.

* rodillo del tintero = fountain roller.

* rodillo entintador = roller, inking roller.

* rodillo en vitela = wove dandy.

* rodillo filigranador = dandy roll, dandy.

* rodillo para pintar = paint roller.

* * *

rodillo

masculine

1 (de cocina) rolling pin

2 (para pintar) paint roller; (de una máquina de escribir) roller, platen; (de tinta) ink roller

3 (de una lavadora) mangle, wringer

4 (para calles) road roller; (para el césped) roller

Compuestos:

● rodillo de arrastre

drag roller

● rodillo de avance

feed roller

● rodillo de leva

cam follower

● rodillo inerte

dead roller

● rodillo tensor or de tensión

belt idler

* * *

rodillo sustantivo masculino ( de cocina) rolling pin;
( para pintar) paint roller;
( de máquina de escribir) roller, platen
rodillo sustantivo masculino roller
rodillo de cocina, rolling pin
' rodillo' also found in these entries:
English:
dough
- paint-roller
- roller
- rolling pin
- mangle

* * *

rodillo nm

1. [para amasar] rolling pin

2. [para pintar] (paint) roller

3. [para asfaltar] road roller;

Fam

el gobierno utilizó el rodillo parlamentario para aprobar la ley the government steamrollered the bill through parliament

4. [pieza cilíndrica] [en máquina de escribir, imprenta] roller

* * *

rodillo

m

1 para amasar rolling pin

2 TÉC roller

* * *

rodillo nm

1) : roller

2) : rolling pin

зеркало

с.

1) ( отражающее стекло) mirror; looking glass уст.

ручно́е зе́ркало — hand mirror

зе́ркало за́днего обзо́ра / ви́да авто — rear-view mirror

зе́ркало цили́ндра тех. — cylinder face

2) мед. speculum (pl -la)

3) ( гладкая поверхность воды) (water) surface

зе́ркало водохрани́лища — reservoir surface

4) (отражение явлений, процессов) mirror

в зе́ркале пре́ссы — as mirrored by the press, in the mirror of the press

криво́е зе́ркало — distorting mirror

Stumpf, Johann

SUBJECT AREA: Steam and internal combustion engines

[br]

fl. c. 1900 Germany

[br]

German inventor of a successful design of uniflow steam engine.

[br]

In 1869 Stumpf was commissioned by the Pope Manufacturing Company of Hertford, Connecticut, to set up two triple-expansion, vertical, Corliss pumping engines. He tried to simplify this complicated system and started research with the internal combustion engine and the steam turbine particularly as his models. The construction of steam turbines in several stages where the steam passed through in a unidirectional flow was being pursued at that time, and Stumpf wondered whether it would be possible to raise the efficiency of a reciprocating steam engine to the same thermal level as the turbine by the use of the uniflow principle.

Stumpf began to investigate these principles without studying the work of earlier pioneers like L.J. Todd, which he later thought would have led him astray. It was not until 1908, when he was Professor at the Institute of Technology in Berlin- Charlottenburg, that he patented his successful "una-flow" steam engine. In that year he took out six British patents for improvements in details on his original one Stumpf fully realized the thermal advantages of compressing the residual steam and was able to evolve systems of coping with excessive compression when starting. He also placed steam-jackets around the ends of the cylinder. Stumpf's first engine was built in 1908 by the Erste B runner Maschinenfabrik-Gesellschaft, and licences were taken out by many other manufacturers, including those in Britain and the USA. His engine was developed into the most economical type of reciprocating steam engine.

[br]

Bibliography

1912, The Una-Flow Steam Engine, Munich: R. Oldenbourg (his own account of the una-flow engine).

Further Reading

H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press; R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (both discuss Stumpf's engine).

H.J.Braun, "The National Association of German-American Technologists and technology transfer between Germany and the United States, 1844–1930", History of Technology 8 (provides details of Stumpf's earlier work).

RLH

пресса

1) media

2) press

гидравлический цилиндр привода пресса — ram drive cylinder

в соответствии с формой

•

The plates are curved to fit the plate cylinder of a rotary press.

в соответствии с формой

•

The plates are curved to fit the plate cylinder of a rotary press.

главный цилиндр (гидравлического) пресса

Metallurgy: main press cylinder

корректурный станок с механическим приводом

Polygraphy: power-operated cylinder proof press

нажимной валик

1) Engineering: press roller, presser, presser roller (механизма оттяжки полотна на трикотажной машине), pressing cylinder, pressure roller

2) Polygraphy: backup roller, (печатный) lithographic roller (для получения оттиска с литографской формы), stressing roller

3) Automation: top roll

печатная машина с одним общим печатным цилиндром

Engineering: common impression cylinder printing press

рулонная плоскопечатная машина для двусторонней печати газет

Polygraphy: roll-fed flatbed cylinder perfecting newspaper press

типографская плоскопечатная машина

Makarov: cylinder letterpress printing press

цилиндрический пресс

Textile: cylinder mangle, rotary press

валик

bead сварка, bowl, ( перед индентором) bulge, ( обычно резной) chaplet, string cornice, ( пишущей машины) cylinder, facia архит., fascia, fillet, fusarole, nose, pass, reed, roll, roller, round, spindle, ( базы колонны) torus, ( вдоль дороги) windrow

* * *

ва́лик м.

1. roller

2. ( сварной шов) bead

направля́ть ва́лик — deposit [run] a bead

формирова́ть ва́лик — form a bead

боково́й ва́лик архит. — lateral ridge

бры́згальный ва́лик текст. — sprinkling roller

вальцма́ссный ва́лик полигр. — composition roller

ворсова́льный ва́лик текст. — raising roller

во́рсовый ва́лик полигр. — nap [friezed] roller

выра́внивающий ва́лик — aligning roller

гла́дкий ва́лик — smooth roller

грузово́й ва́лик текст. — pressing roller, press roll, pressure beam

ва́лик для раска́та кра́ски, ручно́й полигр. — brayer

жело́бчатый ва́лик — grooved [fluted] roller

загру́зочный ва́лик текст. — immersion roll

зака́точный ва́лик рез. — winding-up roll

иго́льчатый ва́лик текст. — spiked [porcupine] roller

клеево́й ва́лик цел.-бум. — glueing roller

кра́сочный ва́лик полигр. — inking roller

кру́глый ва́лик архит. — round fillet, boltel

лентоведу́щий ва́лик полигр. — carrier roller

ва́лик магнитофо́на, прижимно́й — pinch roller

мери́льный ва́лик текст. — measuring roller

мота́льный ва́лик пласт. — winding-up roller

мя́льный ва́лик текст. — breaking roller

нажимно́й ва́лик — pressure roller

нака́тный ва́лик полигр. — form roller

нака́точный ва́лик маш. — knurling roller

напла́вленный ва́лик — deposited [weld] bead

направля́ющий ва́лик — guide-roller

ва́лик ножево́й ва́лик текст. — knife roller

обезрепе́ивающий ва́лик текст. — burring roller

обрези́ненный ва́лик — rubber roller

опо́рный ва́лик — bearing [supporting] roller

опускно́й ва́лик текст. — drop roller

отбо́йный ва́лик текст. — burr beater

отжига́ющий ва́лик — annealing weld

отжи́мный ва́лик — squeeze roll(er)

очё́сывающий ва́лик пласт. — stripping roller

печа́тающий ва́лик (пишущей машины, буквопечатающего телеграфа и т. п.) — platen

печа́тный ва́лик полигр. — impression [printing] roller

пита́ющий ва́лик — feed roller

пла́вающий ва́лик полигр. — dancer [floating] roller

плющи́льный ва́лик текст. — calender roll

подпо́рный ва́лик — supporting roller

полукру́глый ва́лик архит. — half-round fillet

приё́мный ва́лик — receiving [take-up] roll(er)

прика́тный ва́лик полигр. — squeegee roller

прома́зочный ва́лик — smearing roller

противоворсова́льный ва́лик — counterpile roller

рабо́чий ва́лик текст. — worker

размо́точный ва́лик пласт. — winding-out roller

разра́внивающий ва́лик текст. — evener roller

раскатно́й ва́лик полигр. — distributing roller

раска́точный ва́лик (напр. кабеля) — pay-out [take-off] roller

распределя́ющий ва́лик ( краскотёрочной машины) — distributing roller

реми́зный ва́лик текст. — heald roller

рифлё́ный ва́лик — ribbed [corrugated] roll

сбива́ющий ва́лик текст. — stripping roller

ска́тывающий ва́лик текст. — lap roller

ва́лик с колко́вой гарниту́рой текст. — spiked [porcupine] roller

сма́чивающий ва́лик — dampening roller, dampener

со́рный ва́лик текст. — dirt roller

ва́лик со сквозны́м проплавле́нием, корнево́й — penetration [root] bead

сто́порный ва́лик — stop [locking, retaining] roller

съё́мный ва́лик текст. — discharging roller, doffing roll

това́рный ва́лик текст. — combing [batching] roll, cloth beam

увлажня́ющий ва́лик — dampening roller, dampener

углово́й ва́лик архит. — corner fillet

у́зкий ва́лик — string(er) bead

ва́лик усиле́ния — reinforcing bead

уши́ренный ва́лик — spread(ing) bead

факти́совый ва́лик полигр. — factice [vulcanized oil] roller

фальцева́льный ва́лик — folding roller

ва́лик фо́рмы архит. — moulding fillet

холсто́вый ва́лик текст. — lap roll(er)

четвертно́й ва́лик архит. — quarter-round fillet

чисти́тельный ва́лик текст. — stripper

шири́льный ва́лик текст. — full-width roller

шири́тельный ва́лик рез. — expanding roller

щё́точный ва́лик — brush roller

* * *

beading fillet