locomotive+engineers

Inoue Masaru

SUBJECT AREA: Land transport, Railways and locomotives

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b. 1 August 1843 Hagi, Choshu, Japan

d. 2 August 1910 London, England

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Japanese "Father of Japanese Railways".

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In the early 1860s, most travel in Japan was still by foot and the Japanese were forbidden by their government to travel abroad. Inoue was one of a small group of students who left Japan illegally in 1863 for London. There he studied English, mathematics and science, and afterwards mineralogy and railways. Inoue returned to Japan in 1868, when the new Meiji Government reopened the country to the outside world after some 200 years of isolation. Part of its policy, despite opposition, was to build railways; at Inoue's suggestion, the gauge of 3 ft 6 in. (1.07 m) was adopted. Initially capital, engineers, skilled labour and materials ranging from locomotives to pencils and stationery were all imported from Britain; Edmund Morel was the first Chief Engineer. In 1871 Inoue was appointed Director of the Government Railway Bureau and he became the driving force behind railway development in Japan for more than two decades. The first line, from Tokyo to Yokohama, was opened in 1872, to be followed by others, some of them at first isolated. The number of foreigners employed, most of them British, peaked at 120 in 1877 and then rapidly declined as the Japanese learned to take over their tasks. In 1878, at Inoue's instance, construction of a line entirely by Japanese commenced for the first time, with British engineers as consultants only. It was ten years before Japanese Railways' total route was 70 miles (113 km) long; over the next ten years, this increased to 1,000 miles (1,600 km) and the system continued to grow rapidly. During 1892–3, a locomotive was built in Japan for the first time, under the guidance of Locomotive Superintendent R.F.Trevithick, grandson of the pioneer Richard Trevithick: it was a compound 2–4–2 tank engine, with many parts imported from Britain. Locomotive building in Japan then blossomed so rapidly that imports were discontinued, with rare exceptions, from 1911. Meanwhile Inoue had retired in 1893; he was on a visit to England at the time of his death.

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Principal Honours and Distinctions

Viscount 1887.

Bibliography

1909, "Japanese communications: railroads", in Count Shigenobu Okuma (ed.), Fifty Years of New Japan (English version ed. M.B.Huish), Smith, Elder, Ch. 18.

Further Reading

T.Richards and K.C.Rudd, 1991 Japanese Railways in the Meiji Period 1868–1912, Uxbridge: Brunel University (one of the few readily available accounts in English of the origins of Japanese Railways).

PJGR

Baldwin, Matthias William

SUBJECT AREA: Land transport, Railways and locomotives

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b. 10 November 1795 Elizabethtown, New Jersey, USA

d. 7 September 1866 Philadelphia, Pennsylvania, USA

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American builder of steam locomotives, founder of Baldwin Locomotive Works.

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After apprenticeship as a jeweller, Baldwin set up a machinery manufacturing business, and built stationary steam engines and, in 1832, his first locomotive, Old Ironsides, for the then-new Philadelphia, Germantown \& Norristown Railroad. Old Ironsides achieved only 1 mph (1.6 km/h) on trial, but after experimentation reached 28 mph (45 km/h). Over the next ten years Baldwin built many stationary engines and ten more locomotives, and subsequently built locomotives exclusively.

He steadily introduced detail improvements in locomotive design; standardized components by means of templates and gauges from 1838 onwards; introduced the cylinder cast integrally with half of the smokebox saddle in 1858; and in 1862 imported steel tyres, which had first been manufactured in Germany by Krupp of Essen in 1851, and began the practice in the USA of shrinking them on to locomotive wheels. At the time of Matthias Baldwin's death, the Baldwin Locomotive Works had built some 1,500 locomotives: it went on to become the largest locomotive building firm to develop from a single foundation, and by the time it built its last steam locomotive, in 1955, had produced about 75,000 in total.

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Further Reading

J.H.White Jr, 1979, A History of the American Locomotive—Its Development 1830–

1880, New York: Dover Publications Inc.

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

Dictionary of American Biography.

PJGR

Crampton, Thomas Russell

SUBJECT AREA: Land transport, Railways and locomotives, Telecommunications

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b. 6 August 1816 Broadstairs, Kent, England

d. 19 April 1888 London, England

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English engineer, pioneer of submarine electric telegraphy and inventor of the Crampton locomotive.

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After private education and an engineering apprenticeship, Crampton worked under Marc Brunel, Daniel Gooch and the Rennie brothers before setting up as a civil engineer in 1848. His developing ideas on locomotive design were expressed through a series of five patents taken out between 1842 and 1849, each making a multiplicity of claims. The most typical feature of the Crampton locomotive, however, was a single pair of driving wheels set to the rear of the firebox. This meant they could be of large diameter, while the centre of gravity of the locomotive remained low, for the boiler barrel, though large, had only small carrying-wheels beneath it. The cylinders were approximately midway along the boiler and were outside the frames, as was the valve gear. The result was a steady-riding locomotive which neither pitched about a central driving axle nor hunted from side to side, as did other contemporary locomotives, and its working parts were unusually accessible for maintenance. However, adhesive weight was limited and the long wheelbase tended to damage track. Locomotives of this type were soon superseded on British railways, although they lasted much longer in Germany and France. Locomotives built to the later patents incorporated a long, coupled wheelbase with drive through an intermediate crankshaft, but they mostly had only short lives. In 1851 Crampton, with associates, laid the first successful submarine electric telegraph cable. The previous year the brothers Jacob and John Brett had laid a cable, comprising a copper wire insulated with gutta-percha, beneath the English Channel from Dover to Cap Gris Nez: signals were passed but within a few hours the cable failed. Crampton joined the Bretts' company, put up half the capital needed for another attempt, and designed a much stronger cable. Four gutta-percha-insulated copper wires were twisted together, surrounded by tarred hemp and armoured by galvanized iron wires; this cable was successful.

Crampton was also active in railway civil engineering and in water and gas engineering, and c. 1882 he invented a hydraulic tunnel-boring machine intended for a Channel tunnel.

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Principal Honours and Distinctions

Vice-President, Institution of Mechanical Engineers. Officier de la Légion d'Honneur (France).

Bibliography

1842, British patent no. 9,261.

1845. British patent no. 10,854.

1846. British patent no. 11,349.

1847. British patent no. 11,760.

1849, British patent no. 12,627.

1885, British patent no. 14,021.

Further Reading

M.Sharman, 1933, The Crampton Locomotive, Swindon: M.Sharman; P.C.Dewhurst, 1956–7, "The Crampton locomotive", Parts I and II, Transactions of the Newcomen Society 30:99 (the most important recent publications on Crampton's locomotives).

C.Hamilton Ellis, 1958, Twenty Locomotive Men, Shepperton: Ian Allen. J.Kieve, 1973, The Electric Telegraph, Newton Abbot: David \& Charles, 102–4.

R.B.Matkin, 1979, "Thomas Crampton: Man of Kent", Industrial Past 6 (2).

PJGR

Bulleid, Oliver Vaughan Snell

SUBJECT AREA: Land transport, Railways and locomotives

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b. 19 September 1882 Invercargill, New Zealand

d. 25 April 1970 Malta

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New Zealand (naturalized British) locomotive engineer noted for original experimental work in the 1940s and 1950s.

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Bulleid's father died in 1889 and mother and son returned to the UK from New Zealand; Bulleid himself became a premium apprentice under H.A. Ivatt at Doncaster Works, Great Northern Railway (GNR). After working in France and for the Board of Trade, Bulleid returned to the GNR in 1912 as Personal Assistant to Chief Mechanical Engineer H.N. Gresley. After a break for war service, he returned as Assistant to Gresley on the latter's appointment as Chief Mechanical Engineer of the London \& North Eastern Railway in 1923. He was closely associated with Gresley during the late 1920s and early 1930s.

In 1937 Bulleid was appointed Chief Mechanical Engineer of the Southern Railway (SR). Concentration of resources on electrification had left the Southern short of up-to-date steam locomotives, which Bulleid proceeded to provide. His first design, the "Merchant Navy" class 4–6– 2, appeared in 1941 with chain-driven valve gear enclosed in an oil-bath, and other novel features. A powerful "austerity" 0−6−0 appeared in 1942, shorn of all inessentials to meet wartime conditions, and a mixed-traffic 4−6−2 in 1945. All were largely successful.

Under Bulleid's supervision, three large, mixed-traffic, electric locomotives were built for the Southern's 660 volt DC system and incorporated flywheel-driven generators to overcome the problem of interruptions in the live rail. Three main-line diesel-electric locomotives were completed after nationalization of the SR in 1948. All were carried on bogies, as was Bulleid's last steam locomotive design for the SR, the "Leader" class 0−6−6−0 originally intended to meet a requirement for a large, passenger tank locomotive. The first was completed after nationalization of the SR, but the project never went beyond trials. Marginally more successful was a double-deck, electric, suburban, multiple-unit train completed in 1949, with alternate high and low compartments to increase train capacity but not length. The main disadvantage was the slow entry and exit by passengers, and the type was not perpetuated, although the prototype train ran in service until 1971.

In 1951 Bulleid moved to Coras Iompair Éireann, the Irish national transport undertaking, as Chief Mechanical Engineer. There he initiated a large-scale plan for dieselization of the railway system in 1953, the first such plan in the British Isles. Simultaneously he developed, with limited success, a steam locomotive intended to burn peat briquettes: to burn peat, the only native fuel, had been a long-unfulfilled ambition of railway engineers in Ireland. Bulleid retired in 1958.

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Bibliography

Bulleid took out six patents between 1941 and 1956, covering inter alia valve gear, boilers, brake apparatus and wagon underframes.

Further Reading

H.A.V.Bulleid, 1977, Bulleid of the Southern, Shepperton: Ian Allan (a good biography written by the subject's son).

C.Fryer, 1990, Experiments with Steam, Wellingborough: Patrick Stephens (provides details of the austerity 0–6–0, the "Leader" locomotive and the peat-burning locomotive: see Chs 19, 20 and 21 respectively).

PJGR

Bury, Edward

SUBJECT AREA: Land transport, Railways and locomotives

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b. 22 October 1794 Salford, Lancashire, England

d. 25 November 1858 Scarborough, Yorkshire, England

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English steam locomotive designer and builder.

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Bury was the earliest engineer to build locomotives distinctively different from those developed by Robert Stephenson yet successful in mainline passenger service. A Liverpool sawmill owner, he set up as a locomotive manufacturer while the Liverpool \& Manchester Railway was under construction and, after experiments, completed the four-wheeled locomotive Liverpool in 1831. It included features that were to be typical of his designs: a firebox in the form of a vertical cylinder with a dome-shaped top and the front flattened to receive the tubes, and inside frames built up from wrought-iron bars. In 1838 Bury was appointed to supply and maintain the locomotives for the London \& Birmingham Railway (L \& BR), then under construction by Robert Stephenson, on the grounds that the latter should not also provide its locomotives. For several years the L \& BR used Bury locomotives exclusively, and they were also used on several other early main lines. Following export to the USA, their bar frames became an enduring feature of locomotive design in that country. Bury claimed, with justification, that his locomotives were economical in maintenance and fuel: the shape of the firebox promoted rapid circulation of water. His locomotives were well built, but some of their features precluded enlargement of the design to produce more powerful locomotives and within a few years they were outclassed.

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Principal Honours and Distinctions

FRS 1844.

Bibliography

1840, "On the locomotive engines of the London and Birmingham Railway", Transactions of the Institution of Civil Engineers 3 (4) (provides details of his locomotives and the thinking behind them).

Further Reading

C.F.Dendy Marshall, 1953, A History of'Railway Locomotives Down to the End of the Year 1831, London: The Locomotive Publishing Co. (describes Bury's early work).

P.J.G.Ransom, 1990, The Victorian Railway and How It Evolved, London: Heinemann, pp. 167–8 and 174–6.

PJGR

Forrester, George

SUBJECT AREA: Land transport, Railways and locomotives

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b. 1780/1 Scotland

d. after 1841

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Scottish locomotive builder and technical innovator.

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George Forrester \& Co. built locomotives at the Vauxhall Foundry, Liverpool, between 1834 and c.1847. The first locomotives built by them, in 1834, were three for the Dublin \& Kingstown Railway and one for the Liverpool \& Manchester Railway; they were the first locomotives to have outside horizontal cylinders and the first to have four fixed eccentrics to operate the valves, in place of two loose eccentrics. Two locomotives built by Forrester in 1835 for the Dublin \& Kingstown Railway were the first tank locomotives to run regularly on a public railway, and two more supplied in 1836 to the London \& Greenwich Railway were the first such locomotives in England. Little appears to be known about Forrester himself. In the 1841 census his profession is shown as "civil engineer, residence 1 Lord Nelson Street". Directories for Liverpool, contemporary with Forrester \& Co.'s locomotive building period, describe the firm variously as engineers, iron founders and boilermakers, located at (successively) 234,224 and 40 Vauxhall Road. Works Manager until 1840 was Alexander Allan, who subsequently used the experience he had gained with Forrester in the design of his "Crewe Type" outside-cylinder locomotive, which became widely used.

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Further Reading

E.L.Ahrons, 1927, The British Steam Railway Locomotive 1825–1925, The Locomotive Publishing Co., pp. 29, 43, 50 and 83.

J.Lowe, 1975, British Steam Locomotive Builders, Cambridge: Goose \& Son.

R.H.G.Thomas, 1986, London's First Railway: The London \& Greenwich, B.T.Batsford, p. 176.

PJGR

Johnson, Samuel Waite

SUBJECT AREA: Land transport, Railways and locomotives

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b. 14 October 1831 Bramley, Leeds, England

d. 14 January 1912 Nottingham, England

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English locomotive engineer, designer of Midland Railway's successful compound locomotives.

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After an apprenticeship with E.B.Wilson, Leeds, Johnson worked successively for the Great Northern, Manchester Sheffield \& Lincolnshire, Edinburgh \& Glasgow and Great Eastern Railways before being appointed Locomotive Superintendent of the Midland Railway in 1873. There he remained for the rest of his working life, becoming notable for well-designed, well-finished locomotives. Of these, the most famous were his 4–2–2 express locomotives, introduced in 1887. The use of a single pair of driving-wheels was made possible at this late date by application of steam sanding gear (invented in 1886 by F. Holt) to enable them to haul heavy trains without slipping. In 1901, almost at the end of his career, he produced the first Midland compound 4–4–0, with a single internal high-pressure cylinder and two external low-pressure ones. The system had been devised by W.M.Smith, working on the North Eastern Railway under Wilson Worsdell. These locomotives were successful enough to be developed and built in quantity by Johnson's successors and were adopted as a standard locomotive by the London Midland \& Scottish Railway after the grouping of 1923.

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Principal Honours and Distinctions

President, Institution of Mechanical Engineers 1898.

Further Reading

C.Hamilton Ellis, 1958, Twenty Locomotive Men, Ian Allan, Ch. 11 (describes Johnson's career).

E.L.Ahrons, 1927, The British Steam Railway Locomotive 1825–1925, The Locomotive Publishing Co. (describes Johnson's locomotives).

PJGR

Allen, Horatio

SUBJECT AREA: Land transport, Railways and locomotives

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b. 10 May 1802 Schenectady, New York, USA

d. 1 January 1890 South Orange, New Jersey, USA

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American engineer, pioneer of steam locomotives.

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Allen was the Resident Engineer for construction of the Delaware \& Hudson Canal and in 1828 was instructed by J.B. Jervis to visit England to purchase locomotives for the canal's rail extension. He drove the locomotive Stourbridge Lion, built by J.U. Rastrick, on its first trial on 9 August 1829, but weak track prevented its regular use.

Allen was present at the Rainhill Trials on the Liverpool \& Manchester Railway in October 1829. So was E.L.Miller, one of the promoters of the South Carolina Canal \& Rail Road Company, to which Allen was appointed Chief Engineer that autumn. Allen was influential in introducing locomotives to this railway, and the West Point Foundry built a locomotive for it to his design; it was the first locomotive built in the USA for sale. This locomotive, which bore some resemblance to Novelty, built for Rainhill by John Braithwaite and John Ericsson, was named Best Friend of Charleston. On Christmas Day 1830 it hauled the first scheduled steam train to run in America, carrying 141 passengers.

In 1832 the West Point Foundry built four double-ended, articulated 2–2–0+0–2–2 locomotives to Horatio Allen's design for the South Carolina railroad. From each end of a central firebox extended two boiler barrels side by side with common smokeboxes and chimneys; wheels were mounted on swivelling sub-frames, one at each end, beneath these boilers. Allen's principal object was to produce a powerful locomotive with a light axle loading.

Allen subsequently became a partner in Stillman, Allen \& Co. of New York, builders of marine engines, and in 1843 was President of the Erie Railroad.

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Further Reading

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

Dictionary of American Biography.

R.E.Carlson, 1969, The Liverpool \& Manchester Railway Project 1821–1831, Newton Abbot: David \& Charles.

J.F.Stover, 1961, American Railroads, Chicago: University of Chicago Press.

J.H.White Jr, 1994, "Old debts and new visions", in Common Roots—Separate Branches, London: Science Museum, 79–82.

PJGR

Joy, David

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

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b. 3 March 1825 Leeds, England

d. 14 March 1903 Hampstead, London, England

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

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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.

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Bibliography

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

Further Reading

Obituary, 1903, Engineering (20 March).

Obituary, 1903, The Engineer (20 March).

PJGR

Stanier, Sir William Arthur

SUBJECT AREA: Land transport, Railways and locomotives

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b. 27 May 1876 Swindon, England

d. 27 September 1965 London, England

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English Chief Mechanical Engineer of the London Midland \& Scottish Railway, the locomotive stock of which he modernized most effectively.

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Stanier's career started when he was Office Boy at the Great Western Railway's Swindon works. He was taken on as a pupil in 1892 and steady promotion elevated him to Works Manager in 1920, under Chief Mechanical Engineer George Churchward. In 1923 he became Principal Assistant to Churchward's successor, C.B.Collett. In 1932, at the age of 56 and after some forty years' service with the Great Western Railway (GWR), W.A.Stanier was appointed Chief Mechanical Engineer of the London Midland \& Scottish Railway (LMS). This, the largest British railway, had been formed by the amalgamation in 1923 of several long-established railways, including the London \& North Western and the Midland, that had strong and disparate traditions in locomotive design. A coherent and comprehensive policy had still to emerge; Stanier did, however, inherit a policy of reducing the number of types of locomotives, in the interest of economy, by the withdrawal and replacement of small classes, which had originated with constituent companies.

Initially as replacements, Stanier brought in to the LMS a series of highly successful standard locomotives; this practice may be considered a development of that of G.J.Churchward on the GWR. Notably, these new locomotives included: the class 5, mixed-traffic 4–6–0; the 8F heavy-freight 2–8–0; and the "Duchess" 4–6–2 for express passenger trains. Stanier also built, in 1935, a steam-turbine-driven 4–6–2, which became the only steam-turbine locomotive in Britain to have an extended career in regular service, although the economies it provided were insufficient for more of the type to be built. From 1932–3 onwards, and initially as part of a programme to economize on shunting costs by producing a single-manned locomotive, the LMS started to develop diesel shunting locomotives. Stanier delegated much of the responsibility for these to C.E.Fairburn. From 1939 diesel-electric shunting locomotives were being built in quantity for the LMS: this was the first instance of adoption of diesel power on a large scale by a British main-line railway. In a remarkably short time, Stanier transformed LMS locomotive stock, formerly the most backward of the principal British railways, to the point at which it was second to none. He was seconded to the Government as Scientific Advisor to the Ministry of Production in 1942, and retired two years later.

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Principal Honours and Distinctions

Knighted 1943. FRS 1944. President, Institution of Mechanical Engineers 1941.

Bibliography

1955, "George Jackson Churchward", Transactions of the Newcomen Society 30 (Stanier provides a unique view of the life and work of his former chief).

Further Reading

O.S.Nock, 1964, Sir William Stanier, An Engineering Biography, Shepperton: Ian Allan (a full-length biography).

John Bellwood and David Jenkinson, 1976, Oresley and Stanier. A Centenary Tribute, London: HMSO (a comparative account).

C.Hamilton Ellis, 1970, London Midland \& Scottish, Shepperton: Ian Allan.

PJGR

Abt, Roman

SUBJECT AREA: Land transport, Railways and locomotives

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b. 17 July 1850 Bünzen, Switzerland

d. 1 May 1933 Lucerne, Switzerland

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Swiss locomotive engineer, inventor of the Abt rack rail system.

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Abt trained under N. Riggenbach and worked for his short-lived International Company for Mountain Railways during the 1870s, and subsequently invented the Abt rack system as an improvement on Riggenbach's ladder rack, in which the rungs gave trouble by working loose. Abt's rack system, in what became its usual form, comprises two machined racks side by side with their teeth staggered so that a tooth in one rack is opposite a recess in the other, and at least one tooth is always engaged with a locomotive's driving pinions. This system was first used in 1884 on the mixed rack-and-adhesion Harz Railway in Germany, and then largely superseded Riggenbach's system for new rack railways built worldwide to an eventual total of seventy-two, including the Snowdon Mountain Railway in the UK that was built in the 1890s. In many cases Abt himself designed locomotives and rolling stock, and supervised their construction.

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Bibliography

1877–8, Abstract in Minutes of Proceedings of the Institution of Civil Engineers, Vol. 52 (part II) (abstract of a paper given by Abt in which he described eight Riggenbach system railways then operating; his own system was patented in 1882).

Further Reading

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

O.J.Morris, 1951, Snowdon Mountain Railway, Ian Allan.

PJGR

Roberts, Richard

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Textiles

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b. 22 April 1789 Carreghova, Llanymynech, Montgomeryshire, Wales

d. 11 March 1864 London, England

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Welsh mechanical engineer and inventor.

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Richard Roberts was the son of a shoemaker and tollkeeper and received only an elementary education at the village school. At the age of 10 his interest in mechanics was stimulated when he was allowed by the Curate, the Revd Griffith Howell, to use his lathe and other tools. As a young man Roberts acquired a considerable local reputation for his mechanical skills, but these were exercised only in his spare time. For many years he worked in the local limestone quarries, until at the age of 20 he obtained employment as a pattern-maker in Staffordshire. In the next few years he worked as a mechanic in Liverpool, Manchester and Salford before moving in 1814 to London, where he obtained employment with Henry Maudslay. In 1816 he set up on his own account in Manchester. He soon established a reputation there for gear-cutting and other general engineering work, especially for the textile industry, and by 1821 he was employing about twelve men. He built machine tools mainly for his own use, including, in 1817, one of the first planing machines.

One of his first inventions was a gas meter, but his first patent was obtained in 1822 for improvements in looms. His most important contribution to textile technology was his invention of the self-acting spinning mule, patented in 1825. The normal fourteen-year term of this patent was extended in 1839 by a further seven years. Between 1826 and 1828 Roberts paid several visits to Alsace, France, arranging cottonspinning machinery for a new factory at Mulhouse. By 1826 he had become a partner in the firm of Sharp Brothers, the company then becoming Sharp, Roberts \& Co. The firm continued to build textile machinery, and in the 1830s it built locomotive engines for the newly created railways and made one experimental steam-carriage for use on roads. The partnership was dissolved in 1843, the Sharps establishing a new works to continue locomotive building while Roberts retained the existing factory, known as the Globe Works, where he soon after took as partners R.G.Dobinson and Benjamin Fothergill (1802–79). This partnership was dissolved c. 1851, and Roberts continued in business on his own for a few years before moving to London as a consulting engineer.

During the 1840s and 1850s Roberts produced many new inventions in a variety of fields, including machine tools, clocks and watches, textile machinery, pumps and ships. One of these was a machine controlled by a punched-card system similar to the Jacquard loom for punching rivet holes in plates. This was used in the construction of the Conway and Menai Straits tubular bridges. Roberts was granted twenty-six patents, many of which, before the Patent Law Amendment Act of 1852, covered more than one invention; there were still other inventions he did not patent. He made his contribution to the discussion which led up to the 1852 Act by publishing, in 1830 and 1833, pamphlets suggesting reform of the Patent Law.

In the early 1820s Roberts helped to establish the Manchester Mechanics' Institute, and in 1823 he was elected a member of the Literary and Philosophical Society of Manchester. He frequently contributed to their proceedings and in 1861 he was made an Honorary Member. He was elected a Member of the Institution of Civil Engineers in 1838. From 1838 to 1843 he served as a councillor of the then-new Municipal Borough of Manchester. In his final years, without the assistance of business partners, Roberts suffered financial difficulties, and at the time of his death a fund for his aid was being raised.

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Principal Honours and Distinctions

Member, Institution of Civil Engineers 1838.

Further Reading

There is no full-length biography of Richard Roberts but the best account is H.W.Dickinson, 1945–7, "Richard Roberts, his life and inventions", Transactions of the Newcomen Society 25:123–37.

W.H.Chaloner, 1968–9, "New light on Richard Roberts, textile engineer (1789–1864)", Transactions of the Newcomen Society 41:27–44.

RTS

Krauss, Georg

SUBJECT AREA: Land transport, Railways and locomotives

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b. 25 December 1826 Augsburg, Germany

d. 5 November 1906 Munich, Germany

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German locomotive engineer, founder of the locomotive builders Krauss \& Co.

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Krauss entered the Maffei locomotive works, Munich, as a fitter and subsequently worked successively for the Bavarian State Railways and the Swiss North Eastern Railway, which he left in 1866 to found Locomotivfabrik Krauss in Munich. The firm became one of the most important locomotive builders in Germany. A second factory was established in Munich in 1872 and a third at Linz, Austria, in 1880: by the time of Krauss's death, these factories had built more than 5,500 locomotives. The second Munich factory was predominantly for small locomotives, and to increase the sales of these Krauss promoted the construction of many local railways in south Germany and Austria. The firm survived to amalgamate with Maffei and take the name Krauss-Maffei AG in 1940.

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Further Reading

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

Biographical note, 1985–6, Transactions of the Newcomen Society 57:46.

PJGR

Rastrick, John Urpeth

SUBJECT AREA: Land transport, Railways and locomotives

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b. 26 January 1780 Morpeth, England

d. 1 November 1856 Chertsey, England

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English engineer whose career spanned the formative years of steam railways, from constructing some of the earliest locomotives to building great trunk lines.

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John Urpeth Rastrick, son of an engineer, was initially articled to his father and then moved to Ketley Ironworks, Shropshire, c. 1801. In 1808 he entered into a partnership with John Hazledine at Bridgnorth, Shropshire: Hazledine and Rastrick built many steam engines to the designs of Richard Trevithick, including the demonstration locomotive Catch-Me-Who-Can. The firm also built iron bridges, notably the bridge over the River Wye at Chepstow in 1815–16.

Between 1822 and 1826 the Stratford \& Moreton Railway was built under Rastrick's direction. Malleable iron rails were laid, in one of the first instances of their use. They were supplied by James Foster of Stourbridge, with whom Rastrick went into partnership after the death of Hazledine. In 1825 Rastrick was one of a team of engineers sent by the committee of the proposed Liverpool \& Manchester Railway (L \& MR) to carry out trials of locomotives built by George Stephenson on the Killingworth Waggonway. Early in 1829 the directors of the L \& MR, which was by then under construction, sent Rastrick and James Walker to inspect railways in North East England and report on the relative merits of steam locomotives and fixed engines with cable haulage. They reported, rather hesitantly, in favour of the latter, particularly the reciprocal system of Benjamin Thompson. In consequence the Rainhill Trials, at which Rastrick was one of the judges, were held that October. In 1829 Rastrick constructed the Shutt End colliery railway in Worcestershire, for which Foster and Rastrick built the locomotive Agenoria; this survives in the National Railway Museum. Three similar locomotives were built to the order of Horatio Allen for export to the USA.

From then until he retired in 1847 Rastrick found ample employment surveying railways, appearing as a witness before Parliamentary committees, and supervising construction. Principally, he surveyed the southern part of the Grand Junction Railway, which was built for the most part by Joseph Locke, and the line from Manchester to Crewe which was eventually built as the Manchester \& Birmingham Railway. The London \& Brighton Railway (Croydon to Brighton) was his great achievement: built under Rastrick's supervision between 1836 and 1840, it included three long tunnels and the magnificent Ouse Viaduct. In 1845 he was Engineer to the Gravesend \& Rochester Railway, the track of which was laid through the Thames \& Medway Canal's Strood Tunnel, partly on the towpath and partly on a continuous staging over the water.

[br]

Principal Honours and Distinctions

FRS 1837.

Bibliography

1829, with Walker, Report…on the Comparative Merits of Locomotive and Fixed Engines, Liverpool.

Further Reading

C.F.Dendy Marshall, 1953, A History of Railway Locomotives Down to the End of the Year 1831, The Locomotive Publishing Co.

R.E.Carlson, 1969, The Liverpool \& Manchester Railway Project 1821–1831, Newton Abbot: David \& Charles.

C.Hadfield and J.Norris, 1962, Waterways to Stratford, Newton Abbot: David \& Charles (covers Stratford and Moreton Railway).

See also: Stephenson, Robert

PJGR

Sprague, Frank Julian

SUBJECT AREA: Architecture and building, Electricity, Land transport, Railways and locomotives

[br]

b. 25 July 1857 Milford, Connecticut, USA

d. 25 October 1934 New York, USA

[br]

American electrical engineer and inventor, a leading innovator in electric propulsion systems for urban transport.

[br]

Graduating from the United States Naval Academy, Annapolis, in 1878, Sprague served at sea and with various shore establishments. In 1883 he resigned from the Navy and obtained employment with the Edison Company; but being convinced that the use of electricity for motive power was as important as that for illumination, in 1884 he founded the Sprague Electric Railway and Motor Company. Sprague began to develop reliable and efficient motors in large sizes, marketing 15 hp (11 kW) examples by 1885. He devised the method of collecting current by using a wooden, spring-loaded rod to press a roller against the underside of an overhead wire. The installation by Sprague in 1888 of a street tramway on a large scale in Richmond, Virginia, was to become the prototype of the universally adopted trolley system with overhead conductor and the beginning of commercial electric traction. Following the success of the Richmond tramway the company equipped sixty-seven other railways before its merger with Edison General Electric in 1890. The Sprague traction motor supported on the axle of electric streetcars and flexibly mounted to the bogie set a pattern that was widely adopted for many years.

Encouraged by successful experiments with multiple-sheave electric elevators, the Sprague Elevator Company was formed and installed the first set of high-speed passenger cars in 1893–4. These effectively displaced hydraulic elevators in larger buildings. From experience with control systems for these, he developed his system of multiple-unit control for electric trains, which other engineers had considered impracticable. In Sprague's system, a master controller situated in the driver's cab operated electrically at a distance the contactors and reversers which controlled the motors distributed down the train. After years of experiment, Sprague's multiple-unit control was put into use for the first time in 1898 by the Chicago South Side Elevated Railway: within fifteen years multiple-unit operation was used worldwide.

[br]

Principal Honours and Distinctions

President, American Institute of Electrical Engineers 1892–3. Franklin Institute Elliot Cresson Medal 1904, Franklin Medal 1921. American Institute of Electrical Engineers Edison Medal 1910.

Bibliography

1888, "The solution of municipal rapid transit", Trans. AIEE 5:352–98. See "The multiple unit system for electric railways", Cassiers Magazine, (1899) London, repub. 1960, 439–460.

1934, "Digging in “The Mines of the Motor”", Electrical Engineering 53, New York: 695–706 (a short autobiography).

Further Reading

Lionel Calisch, 1913, Electric Traction, London: The Locomotive Publishing Co., Ch. 6 (for a near-contemporary view of Sprague's multiple-unit control).

D.C.Jackson, 1934, "Frank Julian Sprague", Scientific Monthly 57:431–41.

H.C.Passer, 1952, "Frank Julian Sprague: father of electric traction", in Men of Business, ed. W. Miller, Cambridge, Mass., pp. 212–37 (a reliable account).

——1953, The Electrical Manufacturers: 1875–1900, Cambridge, Mass. P.Ransome-Wallis (ed.), 1959, The Concise Encyclopaedia of World Railway

Locomotives, London: Hutchinson, p. 143..

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

GW / 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

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

engineer

engineer [‚endʒɪ'nɪə(r)]

1 noun

(a) (for roads, machines, bridges) ingénieur m, femme f ingénieur; (mechanic, repairer) dépanneur(euse) m,f;

∎ civil engineer ingénieur m civil;

∎ marine engineer ingénieur m du génie maritime;

∎ mechanical engineer ingénieur m mécanicien;

∎ mining engineer ingénieur m des mines;

∎ consulting engineer ingénieur m conseil;

∎ production engineer ingénieur m (chargé) de la production;

∎ Telecommunications telephone engineer technicien(enne) m,f des télécommunications ou du téléphone

(b) Nautical ingénieur m, mécanicien m;

∎ chief engineer chef m mécanicien;

∎ second engineer officier m mécanicien en second

(c) Aviation

∎ flight engineer (on military aircraft) mécanicien m navigant; (on civil aircraft) mécanicien m de bord;

∎ aircraft engineer mécanicien m de piste

(d) Military soldat m du génie, sapeur m;

∎ the engineers le génie, l'arme f du génie;

∎ British the Royal Engineers, American the Corps of Engineers ≃ le Génie

(e) American Railways (driver → of locomotive) conducteur(trice) m,f, mécanicien(enne) m,f

(f) figurative pejorative (instigator → of plan, plot) âme f, instigateur(trice) m,f;

∎ her ex-husband was the engineer of her downfall son ex-mari a été l'instigateur de sa ruine

2 transitive verb

(a) (road, bridge, car) concevoir;

∎ the bridge has been superbly engineered le pont est un superbe travail d'ingénierie

(b) figurative pejorative (bring about → coup, downfall, defeat) machiner; (→ event, situation) manigancer;

∎ she engineered his escape elle a organisé son évasion;

∎ he had carefully engineered the seating arrangements il avait disposé les convives avec soin

(c) (work → goal, victory) amener

►► engineer officer ingénieur m mécanicien

Locke, Joseph

SUBJECT AREA: Civil engineering, Land transport, Railways and locomotives

[br]

b. 9 August 1805 Attercliffe, Yorkshire, England

d. 18 September 1860 Moffat, Scotland

[br]

English civil engineer who built many important early main-line railways.

[br]

Joseph Locke was the son of a colliery viewer who had known George Stephenson in Northumberland before moving to Yorkshire: Locke himself became a pupil of Stephenson in 1823. He worked with Robert Stephenson at Robert Stephenson \& Co.'s locomotive works and surveyed railways, including the Leeds \& Selby and the Canterbury \& Whitstable, for George Stephenson.

When George Stephenson was appointed Chief Engineer for construction of the Liverpool \& Manchester Railway in 1826, the first resident engineer whom he appointed to work under him was Locke, who took a prominent part in promoting traction by locomotives rather than by fixed engines with cable haulage. The pupil eventually excelled the master and in 1835 Locke was appointed in place of Stephenson as Chief Engineer for construction of the Grand Junction Railway. He introduced double-headed rails carried in chairs on wooden sleepers, the prototype of the bullhead track that became standard on British railways for more than a century. By preparing the most detailed specifications, Locke was able to estimate the cost of the railway much more accurately than was usual at that time, and it was built at a cost close to the estimate; this made his name. He became Engineer to the London \& Southampton Railway and completed the Sheffield, Ashton-under-Lyme \& Manchester Railway, including the 3-mile (3.8 km) Woodhead Tunnel, which had been started by Charles Vignoles. He was subsequently responsible for many British main lines, including those of the companies that extended the West Coast Route northwards from Preston to Scotland. He was also Engineer to important early main lines in France, notably that from Paris to Rouen and its extension to Le Havre, and in Spain and Holland. In 1847 Locke was elected MP for Honiton.

Locke appreciated early in his career that steam locomotives able to operate over gradients steeper than at first thought practicable would be developed. Overall his monument is not great individual works of engineering, such as the famous bridges of his close contemporaries Robert Stephenson and I.K. Brunel, but a series of lines built economically but soundly through rugged country without such works; for example, the line over Shap, Cumbria.

[br]

Principal Honours and Distinctions

Officier de la Légion d'honneur, France. FRS. President, Institution of Civil Engineers 1858–9.

Further Reading

Obituary, 1861, Minutes of Proceedings of the Institution of Civil Engineers 20. L.T.C.Rolt, 1962, Great Engineers, London: G. Bell \& Sons, ch. 6.

Industrial Heritage, 1991, Vol. 9(2):9.

See also: Brassey, Thomas

PJGR

Ericsson, John

SUBJECT AREA: Ports and shipping, Railways and locomotives

[br]

b. 31 July 1803 Farnebo, Sweden

d. 8 March 1899 New York, USA

[br]

Swedish (naturalized American 1848) engineer and inventor.

[br]

The son of a mine owner and inspector, Ericsson's first education was private and haphazard. War with Russia disrupted the mines and the father secured a position on the Gotha Canal, then under construction. He enrolled John, then aged 13, and another son as cadets in a corps of military engineers engaged on the canal. There John was given a sound education and training in the physical sciences and engineering. At the age of 17 he decided to enlist in the Army, and on receiving a commission he was drafted to cartographic survey duties. After some years he decided that a career outside the Army offered him the best opportunities, and in 1826 he moved to London to pursue a career of mechanical invention.

Ericsson first developed a heat (external combustion) engine, which proved unsuccessful. Three years later he designed and constructed the steam locomotive Novelty, which he entered in the Rainhill locomotive trials on the new Liverpool \& Manchester Railway. The engine began by performing promisingly, but it later broke down and failed to complete the test runs. Later he devised a self-regulating lead (1835) and then, more important and successful, he invented the screw propeller, patented in 1835 and installed in his first screw-propelled ship of 1839. This work was carried out independently of Sir Francis Pettit Smith, who contemporaneously developed a four-bladed propeller that was adopted by the British Admiralty. Ericsson saw that with screw propulsion the engine could be below the waterline, a distinct advantage in warships. He crossed the Atlantic to interest the American government in his ideas and became a naturalized citizen in 1848. He pioneered the gun turret for mounting heavy guns on board ship. Ericsson came into his own during the American Civil War, with the construction of the epoch-making warship Monitor, a screw-propelled ironclad with gun turret. This vessel demonstrated its powers in a signal victory at Hampton Roads on 9 March 1862.

Ericsson continued to design warships and torpedoes, pointing out to President Lincoln that success in war would now depend on technological rather than numerical superiority. Meanwhile he continued to pursue his interest in heat engines, and from 1870 to 1888 he spent much of his time and resources in pursuing research into alternative energy sources, such as solar power, gravitation and tidal forces.

[br]

Further Reading

W.C.Church, 1891, Life of John Ericsson, 2 vols, London.

LRD