internal+combustion+locomotive

дизелевоз

1) Geology: diesel locomotive

2) Engineering: mine diesel locomotive

3) Mining: diesel loco, internal combustion loco, internal combustion locomotive

moteur

moteur, -trice [mɔtœʀ, tʀis]

1. masculine noun

   a. ( = appareil) engine ; (électrique) motor

• à moteur power-driven

• moteur ! (Cinema) action!

• moteur de recherche search engine

   b. ( = force) mover

• être le moteur de qch to be the driving force behind sth

2. adjective

[muscle, nerf, troubles] motor

• force motrice driving force

* * *

1.

- trice mɔtœʀ, tʀis adjectif

1) [force, principe] driving (épith)

être l'élément moteur de quelque chose — to be the driving force behind something

jouer un rôle moteur dans — to play a dynamic role in

la voiture a quatre roues motrices — the car has four-wheel drive

les roues motrices sont à l'avant — it's a front-wheel drive (car)

2) [trouble, fibre] motor (épith)

2.

nom masculin

1) lit ( électrique) motor; ( autre) engine

un véhicule à moteur — a motor vehicle

2) fig driving force

être le moteur de quelque chose — to be the driving force behind something

•

Phrasal Verbs:

- moteur de recherche

* * *

mɔtœʀ, tʀis (-trice)

1. adj

1) ANATOMIE, PHYSIOLOGIE motor

2) TECHNIQUE, AUTOMOBILES driving

à 4 roues motrices — 4-wheel drive

3) fig (rôle) dynamic

2. nm

1) [véhicule, turbine] engine, [appareil] motor

à moteur — power-driven, motor modif

moteur électrique — electric motor

un bateau à moteur — a motor boat

2) fig, [entreprise, relation] prime mover

* * *

moteur, - trice

A adj

1 ( qui entraîne) [force, principe] driving ( épith); être l'élément moteur de qch to be the driving force behind sth; jouer un rôle moteur dans to play a dynamic role in; la voiture a quatre roues motrices the car has four-wheel drive; les roues motrices sont à l'avant it's a front-wheel drive (car); les roues motrices sont ensablées the traction wheels are stuck in the sand;

2 Méd, Physiol [trouble, aphasie, fibre] motor ( épith).

B nm

1 lit ( électrique) motor; ( autre) engine; voiture avec moteur (à l')arrière/(à l')avant car with an engine at the back/in front; le moteur développe or fait 500 cv the engine is 500 hp; un moteur (de) 8 cylindres an 8-cylinder engine; un véhicule à moteur a motor vehicle; un moteur (à) 4 temps a 4-stroke engine; un moteur (de) 2 litres a 2-litre^GB engine; un moteur poussé or gonflé○ a souped-up engine; une voiture avec le moteur en marche a car with the engine running;

2 fig driving force; être le moteur de qch [personne, motif] to be the driving force behind sth.

C excl Cin action!

D motrice nf Rail (locomotive) engine.

Composés

moteur d'appoint booster; moteur asynchrone asynchronous motor; moteur atmosphérique atmospheric engine; moteur à combustion interne internal combustion engine; moteur diesel diesel engine; moteur électrique electric motor; moteur à explosion internal combustion engine; moteur hydraulique hydraulic engine; moteur à injection fuel injection engine; moteur ionique ion engine; moteur à réaction jet engine; moteur de recherche search engine; moteur rotatif rotary engine; moteur synchrone synchronous motor; moteur turbo turbo engine; moteur à vapeur steam engine.

( féminin motrice) [mɔtɶr, tris] adjectif

1. MÉCANIQUE [force] driving, motive

voiture à quatre roues motrices four-wheel drive car

2. ANATOMIE [nerf, neurone, muscle] motor (modificateur)

————————

nom masculin

1. MÉCANIQUE engine

moteur électrique (electric) motor

moteur à allumage commandé ou à explosion internal combustion engine

moteur à deux/quatre temps two-/four-stroke engine

moteur à essence/vapeur petrol/steam engine

moteur à combustion combustion engine

moteur Diesel diesel engine

moteur à injection fuel injection engine

moteur à réaction jet engine

2. [cause] mainspring, driving force

être le moteur de quelque chose to be the driving force behind something

3. CINÉMA

moteur! action!

4. INFORMATIQUE

moteur de recherche search engine

————————

motrice nom féminin

locomotive (engine)

————————

à moteur locution adjectivale

power-driven, motor (modificateur)

Seguin, Marc

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

[br]

b. 20 April 1786 Annonay, Ardèche, France

d. 24 February 1875 Annonay, Ardèche, France

[br]

French engineer, inventor of multi-tubular firetube boiler.

[br]

Seguin trained under Joseph Montgolfier, one of the inventors of the hot-air balloon, and became a pioneer of suspension bridges. In 1825 he was involved in an attempt to introduce steam navigation to the River Rhône using a tug fitted with a winding drum to wind itself upstream along a cable attached to a point on the bank, with a separate boat to transfer the cable from point to point. The attempt proved unsuccessful and was short-lived, but in 1825 Seguin had decided also to seek a government concession for a railway from Saint-Etienne to Lyons as a feeder of traffic to the river. He inspected the Stockton \& Darlington Railway and met George Stephenson; the concession was granted in 1826 to Seguin Frères \& Ed. Biot and two steam locomotives were built to their order by Robert Stephenson \& Co. The locomotives were shipped to France in the spring of 1828 for evaluation prior to construction of others there; each had two vertical cylinders, one each side between front and rear wheels, and a boiler with a single large-diameter furnace tube, with a watertube grate. Meanwhile, in 1827 Seguin, who was still attempting to produce a steamboat powerful enough to navigate the fast-flowing Rhône, had conceived the idea of increasing the heating surface of a boiler by causing the hot gases from combustion to pass through a series of tubes immersed in the water. He was soon considering application of this type of boiler to a locomotive. He applied for a patent for a multi-tubular boiler on 12 December 1827 and carried out numerous experiments with various means of producing a forced draught to overcome the perceived obstruction caused by the small tubes. By May 1829 the steam-navigation venture had collapsed, but Seguin had a locomotive under construction in the workshops of the Lyons-Sain t- Etienne Railway: he retained the cylinder layout of its Stephenson locomotives, but incorporated a boiler of his own design. The fire was beneath the barrel, surrounded by a water-jacket: a single large flue ran towards the front of the boiler, whence hot gases returned via many small tubes through the boiler barrel to a chimney above the firedoor. Draught was provided by axle-driven fans on the tender.

Seguin was not aware of the contemporary construction of Rocket, with a multi-tubular boiler, by Robert Stephenson; Rocket had its first trial run on 5 September 1829, but the precise date on which Seguin's locomotive first ran appears to be unknown, although by 20 October many experiments had been carried out upon it. Seguin's concept of a multi-tubular locomotive boiler therefore considerably antedated that of Henry Booth, and his first locomotive was completed about the same date as Rocket. It was from Rocket's boiler, however, rather than from that of Seguin's locomotive, that the conventional locomotive boiler was descended.

[br]

Bibliography

February 1828, French patent no. 3,744 (multi-tubular boiler).

1839, De l'Influence des chemins de fer et de l'art de les tracer et de les construire, Paris.

Further Reading

F.Achard and L.Seguin, 1928, "Marc Seguin and the invention of the tubular boiler", Transactions of the Newcomen Society 7 (traces the chronology of Seguin's boilers).

——1928, "British railways of 1825 as seen by Marc Seguin", Transactions of the Newcomen Society 7.

J.B.Snell, 1964, Early Railways, London: Weidenfeld \& Nicolson.

J.-M.Combe and B.Escudié, 1991, Vapeurs sur le Rhône, Lyons: Presses Universitaires de Lyon.

PJGR

spalinowy

adj

silnik spalinowy — internal combustion engine

gazy spalinowe — combustion gases

lokomotywa spalinowa — diesel locomotive

* * *

spalinowy

a.

techn. combustion; gazy spalinowe combustion gases; lokomotywa spalinowa kol. diesel engine; silnik spalinowy internal combustion engine.

Trevithick, Richard

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

[br]

b. 13 April 1771 Illogan, Cornwall, England

d. 22 April 1833 Dartford, Kent, England

[br]

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

[br]

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.

[br]

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

Webb, Francis William

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

[br]

b. 21 May 1836 Tixall, Staffordshire, England

d. 4 June 1906 Bournemouth, England

[br]

English locomotive engineer who pioneered compound locomotives in Britain and the use of steel for boilers.

[br]

Webb was a pupil at Crewe Works, London \& North Western Railway (LNWR), under F. Trevithick (son of Richard Trevithick), and was subsequently placed in charge of the works under Trevithick's successor, J.Ramsbottom. After a brief spell away from the LNWR, Webb returned in 1871 and was made Chief Mechanical Engineer, a post he held until his retirement in 1904.

Webb's initial designs included the highly successful "Precedent" or "Jumbo" class 2– 4–0, from which the example Hardwicke (now preserved by the National Railway Museum, York) achieved an average speed of 67.2 mph (108.1 km/h) between Crewe and Carlisle in 1895. His 0–6–0 "coal engines" were straightforward and cheap and were built in large numbers. In 1879 Webb, having noted the introduction of compound locomotives in France by J.T.A. Mallet, rebuilt an existing 2–2–2 locomotive as a two-cylinder compound. Then in 1882, seeking fuel economy and the suppression of coupling rods, he produced a compound locomotive to his own design, the 2–2, 2–0 Experiment, in which two outside high-pressure cylinders drove the rear driving-wheels, and a single inside large-diameter low-pressure cylinder drove the front driving-wheels. This was followed by a large number of compound locomotives: three successive classes of 2–2, 2–0s; some 2–2, 2–2s; some 4–4–0s; and some 0–8–0s for goods traffic. Although these were capable of good performance, their overall value was controversial: Webb, who was notoriously autocratic, may never have been fully informed of their defects, and after his retirement most were quickly scrapped. Webb made many other innovations during his career, one of the most important being the construction of boilers from steel rather than wrought iron.

[br]

Further Reading

C.Hamilton Ellis, 1958, Twenty Locomotive Men, Shepperton: Ian Allan, Ch. 14 (describes Webb's career).

E.L.Ahrons, 1927, The British Steam Railway Locomotive 2825–1925, London: The Locomotive Publishing Co., Chs 18 and 20 (includes a critique of Webb's compound locomotives).

See also: Bousquet, Gaston du; Gresley, Sir Herbert Nigel; Joy, David; Worsdell, Thomas William

PJGR

Hamilton, Harold Lee (Hal)

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

[br]

b. 14 June 1890 Little Shasta, California, USA

d. 3 May 1969 California, USA

[br]

American pioneer of diesel rail traction.

[br]

Orphaned as a child, Hamilton went to work for Southern Pacific Railroad in his teens, and then worked for several other companies. In his spare time he learned mathematics and physics from a retired professor. In 1911 he joined the White Motor Company, makers of road motor vehicles in Denver, Colorado, where he had gone to recuperate from malaria. He remained there until 1922, apart from an eighteenth-month break for war service.

Upon his return from war service, Hamilton found White selling petrol-engined railbuses with mechanical transmission, based on road vehicles, to railways. He noted that they were not robust enough and that the success of petrol railcars with electric transmission, built by General Electric since 1906, was limited as they were complex to drive and maintain. In 1922 Hamilton formed, and became President of, the Electro- Motive Engineering Corporation (later Electro-Motive Corporation) to design and produce petrol-electric rail cars. Needing an engine larger than those used in road vehicles, yet lighter and faster than marine engines, he approached the Win ton Engine Company to develop a suitable engine; in addition, General Electric provided electric transmission with a simplified control system. Using these components, Hamilton arranged for his petrol-electric railcars to be built by the St Louis Car Company, with the first being completed in 1924. It was the beginning of a highly successful series. Fuel costs were lower than for steam trains and initial costs were kept down by using standardized vehicles instead of designing for individual railways. Maintenance costs were minimized because Electro-Motive kept stocks of spare parts and supplied replacement units when necessary. As more powerful, 800 hp (600 kW) railcars were produced, railways tended to use them to haul trailer vehicles, although that practice reduced the fuel saving. By the end of the decade Electro-Motive needed engines more powerful still and therefore had to use cheap fuel. Diesel engines of the period, such as those that Winton had made for some years, were too heavy in relation to their power, and too slow and sluggish for rail use. Their fuel-injection system was erratic and insufficiently robust and Hamilton concluded that a separate injector was needed for each cylinder.

In 1930 Electro-Motive Corporation and Winton were acquired by General Motors in pursuance of their aim to develop a diesel engine suitable for rail traction, with the use of unit fuel injectors; Hamilton retained his position as President. At this time, industrial depression had combined with road and air competition to undermine railway-passenger business, and Ralph Budd, President of the Chicago, Burlington \& Quincy Railroad, thought that traffic could be recovered by way of high-speed, luxury motor trains; hence the Pioneer Zephyr was built for the Burlington. This comprised a 600 hp (450 kW), lightweight, two-stroke, diesel engine developed by General Motors (model 201 A), with electric transmission, that powered a streamlined train of three articulated coaches. This train demonstrated its powers on 26 May 1934 by running non-stop from Denver to Chicago, a distance of 1,015 miles (1,635 km), in 13 hours and 6 minutes, when the fastest steam schedule was 26 hours. Hamilton and Budd were among those on board the train, and it ushered in an era of high-speed diesel trains in the USA. By then Hamilton, with General Motors backing, was planning to use the lightweight engine to power diesel-electric locomotives. Their layout was derived not from steam locomotives, but from the standard American boxcar. The power plant was mounted within the body and powered the bogies, and driver's cabs were at each end. Two 900 hp (670 kW) engines were mounted in a single car to become an 1,800 hp (l,340 kW) locomotive, which could be operated in multiple by a single driver to form a 3,600 hp (2,680 kW) locomotive. To keep costs down, standard locomotives could be mass-produced rather than needing individual designs for each railway, as with steam locomotives. Two units of this type were completed in 1935 and sent on trial throughout much of the USA. They were able to match steam locomotive performance, with considerable economies: fuel costs alone were halved and there was much less wear on the track. In the same year, Electro-Motive began manufacturing diesel-electrie locomotives at La Grange, Illinois, with design modifications: the driver was placed high up above a projecting nose, which improved visibility and provided protection in the event of collision on unguarded level crossings; six-wheeled bogies were introduced, to reduce axle loading and improve stability. The first production passenger locomotives emerged from La Grange in 1937, and by early 1939 seventy units were in service. Meanwhile, improved engines had been developed and were being made at La Grange, and late in 1939 a prototype, four-unit, 5,400 hp (4,000 kW) diesel-electric locomotive for freight trains was produced and sent out on test from coast to coast; production versions appeared late in 1940. After an interval from 1941 to 1943, when Electro-Motive produced diesel engines for military and naval use, locomotive production resumed in quantity in 1944, and within a few years diesel power replaced steam on most railways in the USA.

Hal Hamilton remained President of Electro-Motive Corporation until 1942, when it became a division of General Motors, of which he became Vice-President.

[br]

Further Reading

P.M.Reck, 1948, On Time: The History of the Electro-Motive Division of General Motors Corporation, La Grange, Ill.: General Motors (describes Hamilton's career).

PJGR

Joy, David

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

[br]

b. 3 March 1825 Leeds, England

d. 14 March 1903 Hampstead, London, England

[br]

English mechanical engineer, designer of the locomotive Jenny Lind and of Joy's valve gear for steam engines.

[br]

By the mid-1840s Joy was Chief Draughtsman at E.B.Wilson's locomotive works at Leeds. During that period, attempts by engineers to design ever larger and more powerful locomotives were producing ungainly types, such as the long-boiler and the Cramp ton, which were to prove blind alleys in locomotive development. Joy rediscovered the proper route with his Jenny Lind 2–2–2, built in 1847. His locomotive had minimal overhang, with the firebox between the driving and trailing axles; the driving axle supported inside frames which stopped short at the firebox, allowing the latter to be wide, while leading and trailing wheels were held by outside plate frames which had a degree of elasticity. The boiler was low-pitched, the steam pressure high at 120 psi (8.4 kg/cm²). The result was a powerful locomotive which rode well and immediately became popular, a forerunner of many later designs. Joy subsequently had a varied career with successive railways and engineering firms. In the late 1850s he invented steam reversing gear for large, marine steam engines, a hydraulic organ blower and a pneumatic hammer. In 1879 he invented his radial valve gear for steam engines, which was adopted by F.W. Webb for the London \& North Western Railway's locomotives and was also much used in marine steam engines.

[br]

Bibliography

1879, British patent no. 929 (valve gear).

Further Reading

Obituary, 1903, Engineering (20 March).

Obituary, 1903, The Engineer (20 March).

PJGR

Walschaert, Egide

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 20 January 1820 Mechlin, Belgium

d. 18 February 1901 Saint-Lilies, Brussels, Belgium

[br]

Belgian inventor of Walschaerrt valve gear for steam engines.

[br]

Walschaert was appointed Foreman of the Brussels Midi workshops of the Belgian State Railways in 1844, when they were opened, and remained in this position until 1885. He invented his valve gear the year he took up his appointment and was allowed to fit it to a 2–2–2 locomotive in 1848, the results being excellent. It was soon adopted in Belgium and to a lesser extent in France, but although it offered accessibility, light weight and mechanical efficiency, railways elsewhere were remarkably slow to take it up. It was first used in the British Isles in 1878, on a 0–4–4 tank locomotive built to the patent of Robert Fairlie, but was not used again there until 1890. By contrast, Fairlie had already used Walchaert's valve gear in 1873, on locomotives for New Zealand, and when New Zealand Railways started to build their own locomotives in 1889 they perpetuated it. The valve gear was only introduced to the USA following a visit by an executive of the Baldwin Locomotive Works to New Zealand ten years later. Subsequently it came to be used almost everywhere there were steam locomotives. Walschaert himself invented other improvements for steam engines, but none with lasting effect.

[br]

Further Reading

P.Ransome-Wallis (ed.), 1959, The Concise Encyclopaedia, of World Railway Locomotives, London: Hutchinson (includes both a brief biography of Walschaert (p.

502) and a technical description of his valve gear (p. 298)).

E.L.Ahrons, 1927, The British Steam Railway Locomotive 1825–1925, London: The Locomotive Publishing Co., pp. 224 and 289 (describes the introduction of the valve gear to Britain).

J.B.Snell, 1964, Early Railways, London: Weidenfeld \& Nicolson, 103.

PJGR

Caprotti, Arturo

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

[br]

b. 22 March 1881 Cremona, Italy

d. 9 February 1938 Milan, Italy

[br]

Italian engineer, inventor of Caprotti poppet valve gear for steam locomotives.

[br]

Caprotti graduated as a mechanical engineer at Turin Royal Polytechnic College and spent some years in the motor car industry. After researching the application of poppet valves to railway locomotives, he invented his rotary cam valve gear for poppet valves in 1915. Compared with usual slide and piston valves and valve gears, it offered independent timing of inlet and exhaust valves and a saving in weight. Valve gear to Caprotti's design was first fitted in 1920 to a 2−6−0 locomotive of the Italian State Railways, and was subsequently widely used there and elsewhere. Caprotti valve gear was first applied in Britain in 1926 to a Claughton class 4−6−0 of the London, Midland \& Scottish Railway, resulting in substantial fuel savings compared with a similar locomotive fitted with Walschaert's valve gear and piston valves. Others of the class were then fitted similarly. Caprotti valve gear never came into general use in Britain and its final application was in 1954 to British Railways class 8 4−6−2 no. 71000; this was intended as the prototype of a class of standard locomotives for express trains, but the class was never built, because diesel and electric locomotives took their place. Some components survived scrapping, and a reconstruction of the locomotive is in working order.

[br]

Further Reading

John Marshall, 1978, A Biographical Dictionary of Railway Engineers, Newton Abbot: David \& Charles.

P.Ransome-Wallis (ed.), 1959, The Concise Encyclopaedia of World Railway Locomotives, London: Hutchinson (contains a note about Caprotti (p. 497) and a description of the valve gear (p. 301).

PJGR

McCoy, Elijah

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 1843 Colchester, Ontario, Canada

d. 1929 Detroit, Michigan (?), USA

[br]

African-American inventor of steam-engine lubricators.

[br]

McCoy was born into a community of escaped African-American slaves. As a youth he went to Scotland and served an apprenticeship in Edinburgh in mechanical engineering. He returned to North America and ended up in Ypsilanti, Michigan, seeking employment at the headquarters of the Michigan Central Railroad Company. In spite of his training, the only job McCoy could obtain was that of locomotive fireman. Still, that enabled him to study at close quarters the problem of lubricating adequately the moving parts of a steam locomotive. Inefficient lubrication led to overheating, delays and even damage. In 1872 McCoy patented the first of his lubricating devices, applicable particularly to stationary engines. He assigned his patent rights to W. and S.C.Hamlin of Ypsilanti, from which he derived enough financial resources to develop his invention. A year later he patented an improved hydrostatic lubricator, which could be used for both stationary and locomotive engines, and went on to make further improvements. McCoy's lubricators were widely taken up by other railroads and his employers promoted him from the footplate to the task of giving instruction in the use of his lubricating equipment. Many others had been attempting to achieve the same result and many rival products were on the market, but none was superior to McCoy's, which came to be known as "the Real McCoy", a term that has since acquired a wider application than to engine lubricators. McCoy moved to Detroit, Michigan, as a patent consultant in the railroad business. Altogether, he took out over fifty patents for various inventions, so that he became one of the most prolific of nineteenth-century black inventors, whose activities had been so greatly stimulated by the freedoms they acquired after the American Civil War. His more valuable patents were assigned to investors, who formed the Elijah McCoy Manufacturing Company. McCoy himself, however, was not a major shareholder, so he seems not to have derived the benefit that was due to him.

[br]

Further Reading

P.P.James, 1989, The Real McCoy: African-American Invention and Innovation 1619– 1930, Washington: Smithsonian Institution, pp. 73–5.

LRD

Schmidt, Wilhelm

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

[br]

b. 18 February 1858 Wegeleben, Saxony, Germany

d. 16 February 1924 Bethel, Westphalia, Germany

[br]

German engineer, inventor of an effective means of superheating steam in locomotive boilers.

[br]

Schmidt was educated at Dresden Technical High School and worked as an assistant to a locksmith. He experimented with steam engines worked at extremely high pressures and developed ideas for using superheated steam. Two early types of locomotive superheater that he designed were tried out in Prussia in the late 1890s, but his firetube type, which was eventually successful, was first used in Belgium in 1901. Within ten years of its introduction, superheating using Schmidt-type superheaters was standard practice on large locomotives worldwide.

In the superheater, steam from the boiler is passed through tubular elements within the firetubes before passing to the cylinders. This raises the steam's temperature without increasing its pressure: advantages of doing so include increasing the volume of steam produced and reducing condensation in the cylinders, with consequent economies of fuel and water. Schmidt superheaters were first used in Britain in 1906 by George Hughes, Locomotive Superintendent of the Lancashire \& Yorkshire Railway, on two goods locomotives, and then by D.Earle Marsh on the London Brighton \& South Coast Railway; hefitted them to 4–4–2 express tank locomotives in 1908. These were conspicuously successful in comparative trials with equivalent non-superheated locomotives from the London \& North Western Railway.

[br]

Further Reading

J.Marshall, 1978, A Biographical Dictionary of Railway Engineers, Newton Abbot: David \& Charles.

P.Ransome-Wallis (ed.), 1959, The Concise Encyclopaedia of World Railway Locomotives, London: Hutchinson, p. 501 (with references to superheaters, pp. 286, 392–4).

C.Hamilton Ellis, 1959, British Railway History, Vol. II: 1877–1947, George Allen \& Unwin, pp. 268–71 (for the introduction of superheating to Britain).

PJGR

Adamson, Daniel

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy, Steam and internal combustion engines

[br]

b. 1818 Shildon, Co. Durham, England

d. January 1890 Didsbury, Manchester, England

[br]

English mechanical engineer, pioneer in the use of steel for boilers, which enabled higher pressures to be introduced; pioneer in the use of triple-and quadruple-expansion mill engines.

[br]

Adamson was apprenticed between 1835 and 1841 to Timothy Hackworth, then Locomotive Superintendent on the Stockton \& Darlington Railway. After this he was appointed Draughtsman, then Superintendent Engineer, at that railway's locomotive works until in 1847 he became Manager of Shildon Works. In 1850 he resigned and moved to act as General Manager of Heaton Foundry, Stockport. In the following year he commenced business on his own at Newton Moor Iron Works near Manchester, where he built up his business as an iron-founder and boilermaker. By 1872 this works had become too small and he moved to a 4 acre (1.6 hectare) site at Hyde Junction, Dukinfield. There he employed 600 men making steel boilers, heavy machinery including mill engines fitted with the American Wheelock valve gear, hydraulic plant and general millwrighting. His success was based on his early recognition of the importance of using high-pressure steam and steel instead of wrought iron. In 1852 he patented his type of flanged seam for the firetubes of Lancashire boilers, which prevented these tubes cracking through expansion. In 1862 he patented the fabrication of boilers by drilling rivet holes instead of punching them and also by drilling the holes through two plates held together in their assembly positions. He had started to use steel for some boilers he made for railway locomotives in 1857, and in 1860, only four years after Bessemer's patent, he built six mill engine boilers from steel for Platt Bros, Oldham. He solved the problems of using this new material, and by his death had made c.2,800 steel boilers with pressures up to 250 psi (17.6 kg/cm²).

He was a pioneer in the general introduction of steel and in 1863–4 was a partner in establishing the Yorkshire Iron and Steel Works at Penistone. This was the first works to depend entirely upon Bessemer steel for engineering purposes and was later sold at a large profit to Charles Cammell \& Co., Sheffield. When he started this works, he also patented improvements both to the Bessemer converters and to the engines which provided their blast. In 1870 he helped to turn Lincolnshire into an important ironmaking area by erecting the North Lincolnshire Ironworks. He was also a shareholder in ironworks in South Wales and Cumberland.

He contributed to the development of the stationary steam engine, for as early as 1855 he built one to run with a pressure of 150 psi (10.5 kg/cm) that worked quite satisfactorily. He reheated the steam between the cylinders of compound engines and then in 1861–2 patented a triple-expansion engine, followed in 1873 by a quadruple-expansion one to further economize steam. In 1858 he developed improved machinery for testing tensile strength and compressive resistance of materials, and in the same year patents for hydraulic lifting jacks and riveting machines were obtained.

He was a founding member of the Iron and Steel Institute and became its President in 1888 when it visited Manchester. The previous year he had been President of the Institution of Civil Engineers when he was presented with the Bessemer Gold Medal. He was a constant contributor at the meetings of these associations as well as those of the Institution of Mechanical Engineers. He did not live to see the opening of one of his final achievements, the Manchester Ship Canal. He was the one man who, by his indomitable energy and skill at public speaking, roused the enthusiasm of the people in Manchester for this project and he made it a really practical proposition in the face of strong opposition.

[br]

Principal Honours and Distinctions

President, Institution of Civil Engineers 1887.

President, Iron and Steel Institute 1888. Institution of Civil Engineers Bessemer Gold Medal 1887.

Further Reading

Obituary, Engineer 69:56.

Obituary, Engineering 49:66–8.

Obituary, Proceedings of the Institution of Civil Engineers 100:374–8.

H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (provides an illustration of Adamson's flanged seam for boilers).

R.L.Hills, 1989, Power from Steam. A History of the Stationary Steam Engine, Cambridge University Press (covers the development of the triple-expansion engine).

RLH

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, England

d. 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 Distinctions

Society of Arts Gold Medal 1809 (for machine for hackling flax).

Further Reading

L.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 the

Year 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

Beau de Rochas, Alphonse Eugène

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 1815 France

d. 1893 France

[br]

French railway engineer, patentee of a four-stroke cycle engine.

[br]

Renowned more for his ideas on technical matters than his practical deeds, Beau de Rochas was a prolific thinker. Within a few years he proposed a rail tunnel beneath the English Channel, a submarine telegraph, a new kind of drive for canal boats, the use of steel for high-pressure boilers and a method of improving the adhesion of locomotive wheels travelling the Alps.

The most notable of Beau de Rochas's ideas occurred in 1862 when he was employed as Ingenieur Attaché to the Central de Chemins. With remarkable foresight, he expressed the theoretical considerations for the cycle of operations for the now widely used four-stroke cycle engine. A French patent of 1862 lapsed with a failure to pay the annuity and thus the proposals for a new motive power lapsed into obscurity. Resurrected some twenty years later, the Beau de Rochas tract figures prominently in patent litigation cases. In 1885, a German court upheld a submission by a German patent lawyer that Otto's four-stroke engine of 1876 infringed the Beau de Rochas patent. It remains a mystery why Beau de Rochas never emerged at any time to defend his claims. In France he is regarded as the inventor of the four-stroke cycle engine.

[br]

Principal Honours and Distinctions

Société d'Encouragement pour l'Industrie Nationale, prize of 3000 francs, 1891.

Bibliography

1885, The Engineer 60:441 (an English translation of the Beau de Rochas tract).

Further Reading

1938, Bulletin de la Société d'Encouragement pour l'Industrie Nationale 137:209–39. 1962, Document pour l'histoire des techniques Cahier no. 2: pp. 3–42.

B.Donkin, 1900, The Gas, Oil and Air Engine, London: p. 467.

See also: Langen, Eugen

KAB

Giffard, Baptiste Henry Jacques (Henri)

SUBJECT AREA: Aerospace, Steam and internal combustion engines

[br]

b. 8 February 1825 Paris, France

d. 14 April 1882 Paris, France

[br]

French pioneer of airships and balloons, inventor of an injector for steam-boiler feedwater.

[br]

Giffard entered the works of the Western Railway of France at the age of 16 but became absorbed by the problem of steam-powered aerial navigation. He proposed a steam-powered helicopter in 1847, but he then turned his attention to an airship. He designed a lightweight coke-burning, single-cylinder steam engine and boiler which produced just over 3 hp (2.2 kW) and mounted it below a cigar-shaped gas bag 44 m (144 ft) in length. A triangular rudder was fitted at the rear to control the direction of flight. On 24 September 1852 Giffard took off from Paris and, at a steady 8 km/h (5 mph), he travelled 28 km (17 miles) to Trappes. This can be claimed to be the first steerable lighter-than-air craft, but with a top speed of only 8 km/h (5 mph) even a modest headwind would have reduced the forward speed to nil (or even negative). Giffard built a second airship, which crashed in 1855, slightly injuring Giffard and his companion; a third airship was planned with a very large gas bag in order to lift the inherently heavy steam engine and boiler, but this was never built. His airships were inflated by coal gas and refusal by the gas company to provide further supplies brought these promising experiments to a premature end.

As a draughtsman Giffard had the opportunity to travel on locomotives and he observed the inadequacies of the feed pumps then used to supply boiler feedwater. To overcome these problems he invented the injector with its series of three cones: in the first cone (convergent), steam at or below boiler pressure becomes a high-velocity jet; in the second (also convergent), it combines with feedwater to condense and impart high velocity to it; and in the third (divergent), that velocity is converted into pressure sufficient to overcome the pressure of steam in the boiler. The injector, patented by Giffard, was quickly adopted by railways everywhere, and the royalties provided him with funds to finance further experiments in aviation. These took the form of tethered hydrogen-inflated balloons of successively larger size. At the Paris Exposition of 1878 one of these balloons carried fifty-two passengers on each tethered "flight". The height of the balloon was controlled by a cable attached to a huge steam-powered winch, and by the end of the fair 1,033 ascents had been made and 35,000 passengers had seen Paris from the air. This, and similar balloons, greatly widened the public's interest in aeronautics. Sadly, after becoming blind, Giffard committed suicide; however, he died a rich man and bequeathed large sums of money to the State for humanitarian an scientific purposes.

[br]

Principal Honours and Distinctions

Croix de la Légion d'honneur 1863.

Bibliography

1860, Notice théorique et pratique sur l'injecteur automoteur.

1870, Description du premier aérostat à vapeur.

Further Reading

Dictionnaire de biographie française.

Gaston Tissandier, 1872, Les Ballons dirigeables, Paris.

—1878, Le Grand ballon captif à vapeur de M. Henri Giffard, Paris.

W.de Fonvielle, 1882, Les Ballons dirigeables à vapeur de H.Giffard, Paris. Giffard is covered in most books on balloons or airships, e.g.: Basil Clarke, 1961, The History of Airships, London. L.T.C.Rolt, 1966, The Aeronauts, London.

Ian McNeill (ed.), 1990, An Encyclopaedia of the History of Technology, London: Routledge, pp. 575 and 614.

J.T.Hodgson and C.S.Lake, 1954, Locomotive Management, Tothill Press, p. 100.

PJGR / JDS

Gurney, Sir Goldsworthy

SUBJECT AREA: Automotive engineering, Land transport, Mining and extraction technology, Steam and internal combustion engines

[br]

b. 14 February 1793 Treator, near Padstow, Cornwall, England

d. 28 February 1875 Reeds, near Bude, Cornwall, England

[br]

English pioneer of steam road transport.

[br]

Educated at Truro Grammar School, he then studied under Dr Avery at Wadebridge to become a doctor of medicine. He settled as a surgeon in Wadebridge, spending his leisure time in building an organ and in the study of chemistry and mechanical science. He married Elizabeth Symons in 1814, and in 1820 moved with his wife to London. He delivered a course of lectures at the Surrey Institution on the elements of chemical science, attended by, amongst others, the young Michael Faraday. While there, Gurney made his first invention, the oxyhydrogen blowpipe. For this he received the Gold Medal of the Society of Arts. He experimented with lime and magnesia for the production of an illuminant for lighthouses with some success. He invented a musical instrument of glasses played like a piano.

In 1823 he started experiments related to steam and locomotion which necessitated taking a partner in to his medical practice, from which he resigned shortly after. His objective was to produce a steam-driven vehicle to run on common roads. His invention of the steam-jet of blast greatly improved the performance of the steam engine. In 1827 he took his steam carriage to Cyfarthfa at the request of Mr Crawshaw, and while there applied his steam-jet to the blast furnaces, greatly improving their performance in the manufacture of iron. Much of the success of George Stephenson's steam engine, the Rocket was due to Gurney's steam blast.

In July 1829 Gurney made a historic trip with his road locomotive. This was from London to Bath and back, which was accomplished at a speed of 18 mph (29 km/h) and was made at the instigation of the Quartermaster-General of the Army. So successful was the carriage that Sir Charles Dance started to run a regular service with it between Gloucester and Cheltenham. This ran for three months without accident, until Parliament introduced prohibitive taxation on all self-propelled vehicles. A House of Commons committee proposed that these should be abolished as inhibiting progress, but this was not done. Sir Goldsworthy petitioned Parliament on the harm being done to him, but nothing was done and the coming of the railways put the matter beyond consideration. He devoted his time to finding other uses for the steam-jet: it was used for extinguishing fires in coal-mines, some of which had been burning for many years; he developed a stove for the production of gas from oil and other fatty substances, intended for lighthouses; he was responsible for the heating and the lighting of both the old and the new Houses of Parliament. His evidence after a colliery explosion resulted in an Act of Parliament requiring all mines to have two shafts. He was knighted in 1863, the same year that he suffered a stroke which incapacitated him. He retired to his house at Reeds, near Bude, where he was looked after by his daughter, Anna.

[br]

Principal Honours and Distinctions

Knighted 1863. Society of Arts Gold Medal.

IMcN