steam+engines

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

Rastrick, John Urpeth

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 26 January 1780 Morpeth, England

d. 1 November 1856 Chertsey, England

[br]

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

[br]

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

Curr, John

SUBJECT AREA: Land transport, Mining and extraction technology, Railways and locomotives

[br]

b. 1756 Kyo, near Lanchester, or in Greenside, near Ryton-on-Tyne, Durham, England

d. 27 January 1823 Sheffield, England

[br]

English coal-mine manager and engineer, inventor of flanged, cast-iron plate rails.

[br]

The son of a "coal viewer", Curr was brought up in the West Durham colliery district. In 1777 he went to the Duke of Norfolk's collieries at Sheffield, where in 1880 he was appointed Superintendent. There coal was conveyed underground in baskets on sledges: Curr replaced the wicker sledges with wheeled corves, i.e. small four-wheeled wooden wagons, running on "rail-roads" with cast-iron rails and hauled from the coal-face to the shaft bottom by horses. The rails employed hitherto had usually consisted of plates of iron, the flange being on the wheels of the wagon. Curr's new design involved flanges on the rails which guided the vehicles, the wheels of which were unflanged and could run on any hard surface. He appears to have left no precise record of the date that he did this, and surviving records have been interpreted as implying various dates between 1776 and 1787. In 1787 John Buddle paid tribute to the efficiency of the rails of Curr's type, which were first used for surface transport by Joseph Butler in 1788 at his iron furnace at Wingerworth near Chesterfield: their use was then promoted widely by Benjamin Outram, and they were adopted in many other English mines. They proved serviceable until the advent of locomotives demanded different rails.

In 1788 Curr also developed a system for drawing a full corve up a mine shaft while lowering an empty one, with guides to separate them. At the surface the corves were automatically emptied by tipplers. Four years later he was awarded a patent for using double ropes for lifting heavier loads. As the weight of the rope itself became a considerable problem with the increasing depth of the shafts, Curr invented the flat hemp rope, patented in 1798, which consisted of several small round ropes stitched together and lapped upon itself in winding. It acted as a counterbalance and led to a reduction in the time and cost of hoisting: at the beginning of a run the loaded rope began to coil upon a small diameter, gradually increasing, while the unloaded rope began to coil off a large diameter, gradually decreasing.

Curr's book The Coal Viewer (1797) is the earliest-known engineering work on railway track and it also contains the most elaborate description of a Newcomen pumping engine, at the highest state of its development. He became an acknowledged expert on construction of Newcomen-type atmospheric engines, and in 1792 he established a foundry to make parts for railways and engines.

Because of the poor financial results of the Duke of Norfolk's collieries at the end of the century, Curr was dismissed in 1801 despite numerous inventions and improvements which he had introduced. After his dismissal, six more of his patents were concerned with rope-making: the one he gained in 1813 referred to the application of flat ropes to horse-gins and perpendicular drum-shafts of steam engines. Curr also introduced the use of inclined planes, where a descending train of full corves pulled up an empty one, and he was one of the pioneers employing fixed steam engines for hauling. He may have resided in France for some time before his death.

[br]

Bibliography

1788. British patent no. 1,660 (guides in mine shafts).

1789. An Account of tin Improved Method of Drawing Coals and Extracting Ores, etc., from Mines, Newcastle upon Tyne.

1797. The Coal Viewer and Engine Builder's Practical Companion; reprinted with five plates and an introduction by Charles E.Lee, 1970, London: Frank Cass, and New York: Augustus M.Kelley.

1798. British patent no. 2,270 (flat hemp ropes).

Further Reading

F.Bland, 1930–1, "John Curr, originator of iron tram roads", Transactions of the Newcomen Society 11:121–30.

R.A.Mott, 1969, Tramroads of the eighteenth century and their originator: John Curr', Transactions of the Newcomen Society 42:1–23 (includes corrections to Fred Bland's earlier paper).

Charles E.Lee, 1970, introduction to John Curr, The Coal Viewer and Engine Builder's Practical Companion, London: Frank Cass, pp. 1–4; orig. pub. 1797, Sheffield (contains the most comprehensive biographical information).

R.Galloway, 1898, Annals of Coalmining, Vol. I, London; reprinted 1971, London (provides a detailed account of Curr's technological alterations).

WK / PJGR

Dampf

m; -(e)s, Dämpfe steam; PHYS. vapo(u)r; (Rauch) smoke; (Dunst) vapo(u)r, haze; (Ausdünstung) exhalation; ( chemische) Dämpfe fumes; Dampf ablassen TECH. blow off steam; umg., fig. let off steam; aus dem Projekt etc. ist der Dampf raus umg., fig. the project etc. has run out of steam; Dampf dahinter machen oder setzen umg., fig. speed things up a bit, get things moving; jemandem Dampf machen umg., fig. give s.o. a kick in the pants, hurry s.o. up ( oder along); mit Dampf umg., fig. at full tilt

* * *

der Dampf

steam; vapour; vapor

* * *

Dạmpf [dampf]

m -(e)s, ordm;e

['dɛmpfə]

1) vapour (Brit), vapor (US); (= Wasserdampf) steam

Dampf ablassen or abblasen (lit, fig) — to let off steam

unter Dampf sein or stehen — to have (its) steam up

aus dem Schornstein quoll der Dampf in weißen Wolken — clouds of white smoke poured from the chimney

2) (inf = Wucht, Schwung) force

jdm Dampf machen (inf) — to make sb get a move on (inf)

Dampf dahintermachen or -setzen — to get a move on

mit Dampf (inf) — at full tilt

vorm Chef hat sie unheimlich Dampf — the boss really puts the wind up her (inf)

Dampf draufhaben (dated inf) — to be going at full steam

* * *

der

1) (a gas or vapour that rises from hot or boiling water or other liquid: Steam rose from the plate of soup / the wet earth in the hot sun; a cloud of steam; ( also adjective) A sauna is a type of steam bath.) steam

2) (power or energy obtained from this: The machinery is driven by steam; Diesel fuel has replaced steam on the railways; ( also adjective) steam power, steam engines.) steam

3) (the gas-like form into which a substance can be changed by heating: water vapour.) vapour

* * *

Dampf

<-[e]s, Dämpfe>

[ˈdampf, pl ˈdɛmpfə]

m

1. (Wasserdampf) steam no pl; (unter dem Siedepunkt) water vapour [or AM -or]

unter \Dampf sein [o stehen] to be under steam, to have its steam up

\Dampf draufhaben (a. fig) to be going at full steam

\Dampf ablassen (a. fig) to let off steam

2. pl (Ausdünstungen) fumes pl, vapours [or AM -ors] pl

3.

▶ \Dampf aufsetzen, \Dampf dahinter machen SCHWEIZ to get a move on

▶ \Dampf in den Fäusten haben to pack quite a punch

▶ jdm \Dampf machen (fam) to make sb get a move on fam

▶ \Dampf hinter etw akk machen SCHWEIZ to hurry on with sth

* * *

der; Dampf[e]s, Dämpfe steam no pl., no indef. art.; (Physik) [water] vapour as tech. term, no pl., no indef. art.

Dampf dahinter/hinter etwas (Akk.) machen — (ugs.) (sich beeilen) get a move on/get a move on with something; (andere zur Eile treiben) get things pl./something moving

* * *

Dampf m; -(e)s, Dämpfe steam; PHYS vapo(u)r; (Rauch) smoke; (Dunst) vapo(u)r, haze; (Ausdünstung) exhalation;

(chemische) Dämpfe fumes;

Dampf ablassen TECH blow off steam; umg, fig let off steam;

aus dem Projekt etc

ist der Dampf raus umg, fig the project etc has run out of steam;

Dampf dahinter machen oder

setzen umg, fig speed things up a bit, get things moving;

jemandem Dampf machen umg, fig give sb a kick in the pants, hurry sb up ( oder along);

mit Dampf umg, fig at full tilt

* * *

der; Dampf[e]s, Dämpfe steam no pl., no indef. art.; (Physik) [water] vapour as tech. term, no pl., no indef. art.

Dampf dahinter/hinter etwas (Akk.) machen — (ugs.) (sich beeilen) get a move on/get a move on with something; (andere zur Eile treiben) get things pl./something moving

* * *

¨–e m.

steam n.

vapor (US) n.

vapour (UK) n.

Baldwin, Matthias William

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 10 November 1795 Elizabethtown, New Jersey, USA

d. 7 September 1866 Philadelphia, Pennsylvania, USA

[br]

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

[br]

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.

[br]

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

Hackworth, Timothy

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 22 December 1786 Wylam, Northumberland, England

d. 7 July 1850 Shildon, Co. Durham, England

[br]

English engineer, pioneer in construction and operation of steam locomotives.

[br]

Hackworth trained under his father, who was Foreman Blacksmith at Wylam colliery, and succeeded him upon his death in 1807. Between 1812 and 1816 he helped to build and maintain the Wylam locomotives under William Hedley. He then moved to Walbottle colliery, but during 1824 he took temporary charge of Robert Stephenson \& Co.'s works while George Stephenson was surveying the Liverpool \& Manchester Railway and Robert Stephenson was away in South America. In May 1825 Hackworth was appointed to the Stockton \& Darlington Railway (S \& DR) "to have superintendence of the permanent (i.e. stationary) and locomotive engines". He established the workshops at Shildon, and when the railway opened in September he became in effect the first locomotive superintendent of a railway company. From experience of operating Robert Stephenson \& Co.'s locomotives he was able to make many detail improvements, notably spring safety valves. In 1827 he designed and built the locomotive Royal George, with six wheels coupled and inverted vertical cylinders driving the rear pair. From the pistons, drive was direct by way of piston rods and connecting rods to crankpins on the wheels, the first instance of the use of this layout on a locomotive. Royal George was the most powerful and satisfactory locomotive on the S \& DR to date and was the forerunner of Hackworth's type of heavy-goods locomotive, which was built until the mid-1840s.

For the Rainhill Trials in 1829 Hackworth built and entered the locomotive Sans Pareil, which was subsequently used on the Bol ton \& Leigh Railway and is now in the Science Museum, London. A working replica was built for the 150th anniversary of the Liverpool \& Manchester Railway in 1980. In 1833 a further agreement with the S \& DR enabled Hackworth, while remaining in charge of their locomotives, to set up a locomotive and engineering works on his own account. Its products eventually included locomotives for the London, Brighton \& South Coast and York, Newcastle \& Berwick Railways, as well as some of the earliest locomotives exported to Russia and Canada. Hackworth's son, John Wesley Hackworth, was also an engineer and invented the radial valve gear for steam engines that bears his name.

[br]

Further Reading

R.Young, 1975, Timothy Hackworth and the Locomotive, Shildon: Shildon "Stockton \& Darlington Railway" Silver Jubilee Committee; orig. pub. 1923, London (tends to emphasize Hackworth's achievements at the expense of other contemporary engineers).

L.T.C.Rolt, 1960, George and Robert Stephenson, London: Longmans (describes much of Hackworth's work and is more objective).

E.L.Ahrons, 1927, The British Steam Railway Locomotive 1825–1925, London: The Locomotive Publishing Co.

PJGR

Nasmyth, James Hall

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 19 August 1808 Edinburgh, Scotland

d. 7 May 1890 London, England

[br]

Scottish mechanical engineer and inventor of the steam-hammer.

[br]

James Nasmyth was the youngest son of Alexander Nasmyth (1758–1840), the portrait and landscape painter. According to his autobiography he was named James Hall after his father's friend, the geologist Sir James Hall (1761–1832), but he seems never to have used his second name in official documents. He received an elementary education at Edinburgh High School, but left at the age of 12. He attended evening classes at the Edinburgh School of Arts for the instruction of Mechanics between 1821 and 1825, and gained experience as a mechanic at an early age in his father's workshop. He shared these early experiences with his brother George, who was only a year or so older, and in the 1820s the brothers built several model steam engines and a steam-carriage capable of carrying eight passengers on the public roads. In 1829 Nasmyth obtained a position in London as personal assistant to Henry Maudslay, and after Maudslay's death in February 1831 he remained with Maudslay's partner, Joshua Field, for a short time. He then returned to Edinburgh, where he and his brother George started in a small way as general engineers. In 1834 they moved to a small workshop in Manchester, and in 1836, with the aid of financial backing from some Manchester businessmen, they established on a site at Patricroft, a few miles from the city, the works which became known as the Bridgewater Foundry. They were soon joined by a third partner, Holbrook Gaskell (1813–1909), who looked after the administration of the business, the firm then being known as Nasmyths Gaskell \& Co. They specialized in making machine tools, and Nasmyth invented many improvements so that they soon became one of the leading manufacturers in this field. They also made steam locomotives for the rapidly developing railways. James Nasmyth's best-known invention was the steam-hammer, which dates from 1839 but was not patented until 1842. The self-acting control gear was probably the work of Robert Wilson and ensured the commercial success of the invention. George Nasmyth resigned from the partnership in 1843 and in 1850 Gaskell also resigned, after which the firm continued as James Nasmyth \& Co. James Nasmyth himself retired at the end of 1856 and went to live at Penshurst, Kent, in a house which he named "Hammerfield" where he devoted his time mainly to his hobby of astronomy. Robert Wilson returned to become Managing Partner of the firm, which later became Nasmyth, Wilson \& Co. and retained that style until its closure in 1940. Nasmyth's claim to be the sole inventor of the steam-hammer has been disputed, but his patent of 1842 was not challenged and the fourteen-year monopoly ensured the prosperity of the business so that he was able to retire at the age of 48. At his death in 1890 he left an estate valued at £243,805.

[br]

Bibliography

1874, with J.Carpenter, The Moon Considered as a Planet, a World, and a Satellite, London.

1883, Autobiography, ed. Samuel Smiles, London.

Further Reading

R.Wailes, 1963, "James Nasmyth—Artist's Son", Engineering Heritage, vol. I, London, 106–11 (a short account).

J.A.Cantrell, 1984, James Nasmyth and the Bridgewater Foundry: A Study of Entrepreneurship in the Early Engineering Industry, Manchester (a full-length critical study).

——1984–5, "James Nasmyth and the steam hammer", Transactions of the Newcomen Society 56:133–8.

RTS

Mallet, Jules Théodore Anatole

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 1837 Geneva, Switzerland

d. November 1919 Nice, France

[br]

Swiss engineer, inventor of the compound steam locomotive and the Mallet articulated locomotive.

[br]

Mallet's family moved to Normandy while he was still a child. After working as a civil engineer, in 1867 he turned to machinery, particularly to compound steam engines. He designed the first true compound steam locomotives, which were built for the Bayonne- Biarritz Railway in 1876. They were 0–4–2 tank locomotives with one high-pressure and one low-pressure cylinder. A starting valve controlled by the driver admitted high-pressure steam to the low-pressure cylinder while the high-pressure cylinder exhausted to the atmosphere. At that time it was thought impracticable in a narrow-gauge locomotive to have more than three coupled axles in rigid frames. Mallet patented his system of articulation in 1884 and the first locomotives were built to that design in 1888: they were 0–4–4–0 tanks with two sets of frames. The two rear pairs of wheels carried the rear set of frames and were driven by two high-pressure cylinders; the two front pairs, which were driven by the high-pressure cylinders, carried a separate set of frames that was allowed sideplay, with a centre of rotation between the low-pressure cylinders. In contrast to the patent locomotive of Robert Fairlie, no flexible connections were required to carry steam at boiler pressure. The first Mallet articulated locomotives were small, built to 60 cm (23.6 in.) gauge: the first standard-gauge Mallets were built in 1890, for the St Gotthard Railway, and it was only after the type was adopted by American railways in 1904 that large Mallet locomotives were built, with sizes increasing rapidly to culminate in some of the largest steam locomotives ever produced. In the late 1880s Mallet also designed monorail locomotives, which were built for the system developed by C.F.M.-T. Lartigue.

[br]

Bibliography

1884, French patent no. 162,876 (articulated locomotive).

Further Reading

J.T.van Riemsdijk, 1970, "The compound locomotive, Part I", Transactions of the Newcomen Society 43 (describes Mallet's work on compounding).

L.Wiener, 1930, Articulated Locomotives, London: Constable (describes his articulated locomotives).

For the Mallet family, see Historisch-Biographisches Lexikon der Schweiz.

See also: Bousquet, Gaston du; Vauclain, Samuel Matthews; Webb, Francis William

PJGR

Stevens, John

SUBJECT AREA: Land transport, Ports and shipping, Railways and locomotives

[br]

b. 1749 New York, New York, USA

d. 6 March 1838 Hoboken, New Jersey, USA

[br]

American pioneer of steamboats and railways.

[br]

Stevens, a wealthy landowner with an estate at Hoboken on the Hudson River, had his attention drawn to the steamboat of John Fitch in 1786, and thenceforth devoted much of his time and fortune to developing steamboats and mechanical transport. He also had political influence and it was at his instance that Congress in 1790 passed an Act establishing the first patent laws in the USA. The following year Stevens was one of the first recipients of a US patent. This referred to multi-tubular boilers, of both watertube and firetube types, and antedated by many years the work of both Henry Booth and Marc Seguin on the latter.

A steamboat built in 1798 by John Stevens, Nicholas J.Roosevelt and Stevens's brother-in-law, Robert R.Livingston, in association was unsuccessful, nor was Stevens satisfied with a boat built in 1802 in which a simple rotary steam-en-gine was mounted on the same shaft as a screw propeller. However, although others had experimented earlier with screw propellers, when John Stevens had the Little Juliana built in 1804 he produced the first practical screw steamboat. Steam at 50 psi (3.5 kg/cm²) pressure was supplied by a watertube boiler to a single-cylinder engine which drove two contra-rotating shafts, upon each of which was mounted a screw propeller. This little boat, less than 25 ft (7.6 m) long, was taken backwards and forwards across the Hudson River by two of Stevens's sons, one of whom, R.L. Stevens, was to help his father with many subsequent experiments. The boat, however, was ahead of its time, and steamships were to be driven by paddle wheels until the late 1830s.

In 1807 John Stevens declined an invitation to join with Robert Fulton and Robert R.Living-ston in their development work, which culminated in successful operation of the PS Clermont that summer; in 1808, however, he launched his own paddle steamer, the Phoenix. But Fulton and Livingston had obtained an effective monopoly of steamer operation on the Hudson and, unable to reach agreement with them, Stevens sent Phoenix to Philadelphia to operate on the Delaware River. The intervening voyage over 150 miles (240 km) of open sea made Phoenix the first ocean-going steamer.

From about 1810 John Stevens turned his attention to the possibilities of railways. He was at first considered a visionary, but in 1815, at his instance, the New Jersey Assembly created a company to build a railway between the Delaware and Raritan Rivers. It was the first railway charter granted in the USA, although the line it authorized remained unbuilt. To demonstrate the feasibility of the steam locomotive, Stevens built an experimental locomotive in 1825, at the age of 76. With flangeless wheels, guide rollers and rack-and-pinion drive, it ran on a circular track at his Hoboken home; it was the first steam locomotive to be built in America.

[br]

Bibliography

1812, Documents Tending to Prove the Superior Advantages of Rail-ways and Steam-carriages over Canal Navigation.

He took out patents relating to steam-engines in the USA in 1791, 1803, and 1810, and in England, through his son John Cox Stevens, in 1805.

Further Reading

H.P.Spratt, 1958, The Birth of the Steamboat, Charles Griffin (provides technical details of Stevens's boats).

J.T.Flexner, 1978, Steamboats Come True, Boston: Little, Brown (describes his work in relation to that of other steamboat pioneers).

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

Transactions of the Newcomen Society (1927) 7: 114 (discusses tubular boilers).

J.R.Day and B.G.Wilson, 1957, Unusual Railways, F.Muller (discusses Stevens's locomotive).

See also: Allen, Horatio; Cooper, Peter

PJGR

Field, Joshua

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

[br]

b. 1786 Hackney, London, England

d. 11 August 1863 Balham Hill, Surrey, England

[br]

English mechanical engineer, co-founder of the Institution of Civil Engineers.

[br]

Joshua Field was educated at a boarding school in Essex until the age of 16, when he obtained employment at the Royal Dockyards at Portsmouth under the Chief Mechanical Superintendent, Simon Goodrich (1773–1847), and later in the drawing office at the Admiralty in Whitehall. At this time, machinery for the manufacture of ships' blocks was being made for the Admiralty by Henry Maudslay, who was in need of a competent draughtsman, and Goodrich recommended Joshua Field. This was the beginning of Field's long association with Maudslay; he later became a partner in the firm which was for many years known as Maudslay, Sons \& Field. They undertook a variety of mechanical engineering work but were renowned for marine steam engines, with Field being responsible for much of the design work in the early years. Joshua Field was the eldest of the eight young men who in 1818 founded the Institution of Civil Engineers; he was the first Chairman of the Institution and later became a vice-president. He was the only one of the founders to be elected President and was the first mechanical engineer to hold that office. James Nasmyth in his autobiography relates that Joshua Field kept a methodical account of his technical discussions in a series of note books which were later indexed. Some of these diaries have survived, and extracts from the notes he made on a tour of the industrial areas of the Midlands and the North West in 1821 have been published.

[br]

Principal Honours and Distinctions

FRS 1836. President, Institution of Civil Engineers 1848–9. Member, Smeatonian Society of Civil Engineers 1835; President 1848.

Bibliography

1925–6, "Joshua Field's diary of a tour in 1821 through the Midlands", introd. and notes J.W.Hall, Transactions of the Newcomen Society 6:1–41.

1932–3, "Joshua Field's diary of a tour in 1821 through the provinces", introd. and notes E.C. Smith, Transactions of the Newcomen Society 13:15–50.

RTS

Kennedy, John

SUBJECT AREA: Textiles

[br]

b. 4 July 1769 Knocknalling, Kirkcudbrightshire, Scotland

d. 30 October 1855 Ardwick Hall, Manchester, England

[br]

Scottish cotton spinner and textile machine maker.

[br]

Kennedy was the third son of his father, Robert, and went to the village school in Dalry. On his father's death, he was sent at the age of 14 to Chowbent, Lancashire, where he was apprenticed to William Cannan, a maker of textile machines such as carding frames, Hargreaves's jennies and Arkwright's waterframes. On completion of his apprenticeship in 1791, he moved to Manchester and entered into partnership with Benjamin and William Sandford and James M'Connel, textile machine makers and mule spinners. In 1795 this partnership was terminated and one was made with James M'Connel to form the firm M'Connel \& Kennedy, cotton spinners.

Kennedy introduced improvements for spinning fine yarns and the firm of M'Connel \& Kennedy became famous for the quality of these products, which were in great demand. He made the spindles turn faster during the second part of the mule carriage's outward draw, and from 1793 onwards he experimented with driving mules by steam engines. Like William Kelly at New Lanark, he succeeded in making the spinning sequences power-operated by 1800, although the spinner had to take over the winding on. This made the mule into a factory machine, but it still required skilled operators. He was also involved with Henry Houldsworth, Junior, in the improvement of the roving frame. In 1803 Kennedy joined the Manchester Literary \& Philosophical Society, to which he presented several papers, including one in 1830 on "A memoir of Samuel Crompton". He retired from the spinning business in 1826, but continued his technical and mechanical pursuits. He was consulted about whether the Liverpool \& Manchester Railway should have moving or stationary steam engines and was an umpire at the Rainhill Trials in 1829.

[br]

Further Reading

Dictionary of National Biography.

W.Fairbairn, obituary, Manchester Memoirs, Manchester Literary and Philosophical Society.

C.H.Lee, 1972, A Cotton Enterprise 1795–1840. A History of M'Connel \& Kennedy, Fine

Cotton Spinners, Manchester (an account of Kennedy's spinning business). R.L.Hills, 1970, Power in the Industrial Revolution, Manchester (provides details of Kennedy's inventions on the mule).

RLH

Thomson, James

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 16 February 1822 Belfast, Ireland (now Northern Ireland)

d. 8 May 1892 Glasgow, Scotland

[br]

Irish civil engineer noted for his work in hydraulics and for his design of the "Vortex" turbine.

[br]

James Thomson was a pupil in several civil-engineering offices, but the nature of the work was beyond his physical capacity and from 1843 onwards he devoted himself to theoretical studies. Hhe first concentrated on the problems associated with the expansion of liquids when they reach their freezing point: water is one such example. He continued this work with his younger brother, Lord Kelvin (see Thomson, Sir William).

After experimentation with a "feathered" paddle wheel as a young man, he turned his attention to water power. In 1850 he made his first patent application, "Hydraulic machinery and steam engines": this patent became his "Vortex" turbine design. He settled in Belfast, the home of the MacAdam-Fourneyron turbine, in 1851, and as a civil engineer became the Resident Engineer to the Belfast Water Commissioners in 1853. In 1857 he was appointed Professor of Civil Engineering and Surveying at Queen's College, Belfast.

Whilst it is understood that he made his first turbine models in Belfast, he came to an arrangement with the Williamson Brothers of Kendal to make his turbine. In 1856 Williamsons produced their first turbine to Thomson's design and drawings. This was the Vortex Williamson Number 1, which produced 5 hp (3.7 kW) under a fall of 31 ft (9.4 m) on a 9 in. (23 cm) diameter supply. The rotor of this turbine ran in a horizontal plane. For several years the Williamson catalogue described their Vortex turbine as "designed by Professor James Thomson".

Thomson continued with his study of hydraulics and water flow both at Queen's College, Belfast, and, later, at Glasgow University, where he became Professor in 1873, succeeding Macquorn Rankine, another famous engineer. At Glasgow, James Thomson studied the flow in rivers and the effects of erosion on river beds. He was also an authority on geological formations such as the development of the basalt structure of the Giant's Causeway, north of Belfast.

James Thomson was an extremely active engineer and a very profound teacher of civil engineering. His form of water turbine had a long life before being displaced by the turbines designed in the twentieth century.

[br]

Bibliography

1850, British patent no. 13,156 "Hydraulic machinery and steam engines".

Further Reading

Gilkes, 1956, One Hundred Years of Water Power, Kendal.

KM

Wilkinson, John

SUBJECT AREA: Weapons and armour

[br]

b. 1728 Clifton, Cumberland, England

d. 14 July 1808 Bradley, Staffordshire, England

[br]

English ironmaster, inventor of a cannon-boring machine.

[br]

Wilkinson's father Isaac was a farmer turned ironmaster. Soon after 1750, the family acquired Bersham furnace, near Wrexham. This was later in the hands of John and his brother William. By 1763, John had risen to take sole charge of Broseley furnace near Coalbrookdale, Shropshire, and in 1770 he set up a third furnace at Bradley, Staffordshire. By this time he had become one of the country's leading ironmasters, known for the wide range of ware made of cast iron, doubtless the reason for his nickname "Ironmad Wilkinson". He made a cast-iron boat which, to the surprise of many, floated. For his own eventual use, he also made a cast-iron coffin, but did not make sufficient allowance for increasing girth with age! Wilkinson's most notable invention was his cannon-boring machine, patented in 1774. The gun barrel was held rigidly while the cutter head moved forward on a rod inside a hollow boring bar. The machine was easily adapted to bore the cylinders for Boulton \& Watt's steam engines and he became a regular supplier, as only he could bore them with the required accuracy. On the other hand, their second engine was supplied to Wilkinson to power a blowing engine to provide air blast for his Broseley furnace: this was the first use of a Boulton \& Watt engine for a purpose other than pumping. By 1780 he had three further steam engines at work. Wilkinson installed the first Boulton \& Watt engine in France at the Paris waterworks, for which he supplied the iron pipes. Another patent was obtained in 1794 for the invention of the cupola or furnace for melting metal for small castings, although it is now thought that the real inventor was his brother William. Apart from domestic and engineering ironware, Wilkinson was supplier of arms to the American and, illicitly, to the French.

[br]

Further Reading

H.W.Dickinson, 1914, John Wilkinson, Iron-master.

LRD

Bell, Henry

SUBJECT AREA: Ports and shipping

[br]

b. 1767 Torphichen Mill, near Linlithgow, Scotland

d. 1830 Helensburgh, Scotland

[br]

Scottish projector of the first steamboat service in Europe.

[br]

The son of Patrick Bell, a millwright, Henry had two sisters and an elder brother and was educated at the village school. When he was 9 years old Henry was sent to lodge in Falkirk with an uncle and aunt of his mother's so that he could attend the school there. At the age of 12 he left school and agreed to become a mason with a relative. In 1783, after only three years, he was bound apprentice to his Uncle Henry, a millwright at Jay Mill. He stayed there for a further three years and then, in 1786, joined the firm of Shaw \& Hart, shipbuilders of Borrowstoneness. These were to be the builders of William Symington's hull for the Charlotte Dundas. He also spent twelve months with Mr James Inglis, an engineer of Bellshill, Lanarkshire, and then went to London to gain experience, working for the famous John Rennie for some eighteen months. By 1790 he was back in Glasgow, and a year later he took a partner, James Paterson, into his new business of builder and contractor, based in the Trongate. He later referred to himself as "architect", and his partnership with Paterson lasted seven years. He is said to have invented a discharging machine for calico printing, as well as a steam dredger for clearing the River Clyde.

The Baths Hotel was opened in Helensburgh in 1808, with the hotel-keeper, who was also the first provost of the town, being none other than Henry Bell. It has been suggested that Bell was also the builder of the hotel and this seems very likely. Bell installed a steam engine for pumping sea water out of the Clyde and into the baths, and at first ran a coach service to bring customers from Glasgow three days a week. The driver was his brother Tom. The coach was replaced by the Comet steamboat in 1812.

While Henry was busy with his provost's duties and making arrangements for the building of his steamboat, his wife Margaret, née Young, whom he married in March 1794, occupied herself with the management of the Baths Hotel. Bell did not himself manufacture, but supervised the work of experts: John and Charles Wood of Port Glasgow, builders of the 43ft 6 in. (13.25 m)-long hull of the Comet; David Napier of Howard Street Foundry for the boiler and other castings; and John Robertson of Dempster Street, who had previously supplied a small engine for pumping water to the baths at the hotel in Helensburgh, for the 3 hp engine. The first trials of the finished ship were held on 24 July 1812, when she was launched from Wood's yard. A regular service was advertised in the Glasgow Chronicle on 5 August and was the first in Europe, preceded only by that of Robert Fulton in the USA. The Comet continued to run until 1820, when it was wrecked.

Bell received little reward for his promotion of steam navigation, merely small pensions from the Clyde trustees and others. He was buried at the parish church of Rhu.

[br]

Further Reading

Edward Morris, 1844, Life of Henry Bell.

Henry Bell, 1813, Applying Steam Engines to Vessels.

IMcN

Bouton, Georges Thadé

SUBJECT AREA: Automotive engineering

[br]

b. 22 November 1847 Paris, France

d. November 1938

[br]

French pioneer in automobile manufacture.

[br]

Bouton was the son of a painter and learned mechanics at Honfleur and Paris. In 1870 he was fighting in Les Mobiles de Calvados, and in 1881, having finished his training, he joined his brother-in-law, Trepardoux, to open a workshop in rue de la Chapelle for the construction of steam engines for scientific toys. The comte de Dion discovered the workshop and became associated with it in 1882. They also built steam-boilers for automobiles. In 1883 they built their first quadricycle, and in 1887 their first steam tricycle. These were followed in 1892 and 1893 by a car and a steam tractor. After the appearance of the petrol engine they put in hand a star-shaped four-cylinder engine of this type, but it was not until 1895 and 1898 that the first de Dion-Bouton single-cylinder tricycle and their petrol bicycle, respectively, came out. From 1899 the manufacture of de Dion-Bouton was concentrated on the voiturette. Georges Bouton was responsible for the manufacture of all these machines and took part in the first motor races.

[br]

Further Reading

1933, Dictionnaire de biographie française.

IMcN

Ford, Henry

SUBJECT AREA: Automotive engineering, Land transport

[br]

b. 30 July 1863 Dearborn, Michigan, USA

d. 7 April 1947 Dearborn, Michigan, USA

[br]

American pioneer motor-car maker and developer of mass-production methods.

[br]

He was the son of an Irish immigrant farmer, William Ford, and the oldest son to survive of Mary Litogot; his mother died in 1876 with the birth of her sixth child. He went to the village school, and at the age of 16 he was apprenticed to Flower brothers' machine shop and then at the Drydock \& Engineering Works in Detroit. In 1882 he left to return to the family farm and spent some time working with a 1 1/2 hp steam engine doing odd jobs for the farming community at $3 per day. He was then employed as a demonstrator for Westinghouse steam engines. He met Clara Jane Bryant at New Year 1885 and they were married on 11 April 1888. Their only child, Edsel Bryant Ford, was born on 6 November 1893.

At that time Henry worked on steam engine repairs for the Edison Illuminating Company, where he became Chief Engineer. He became one of a group working to develop a "horseless carriage" in 1896 and in June completed his first vehicle, a "quadri cycle" with a two-cylinder engine. It was built in a brick shed, which had to be partially demolished to get the carriage out.

Ford became involved in motor racing, at which he was more successful than he was in starting a car-manufacturing company. Several early ventures failed, until the Ford Motor Company of 1903. By October 1908 they had started with production of the Model T. The first, of which over 15 million were built up to the end of its production in May 1927, came out with bought-out steel stampings and a planetary gearbox, and had a one-piece four-cylinder block with a bolt-on head. This was one of the most successful models built by Ford or any other motor manufacturer in the life of the motor car.

Interchangeability of components was an important element in Ford's philosophy. Ford was a pioneer in the use of vanadium steel for engine components. He adopted the principles of Frederick Taylor, the pioneer of time-and-motion study, and installed the world's first moving assembly line for the production of magnetos, started in 1913. He installed blast furnaces at the factory to make his own steel, and he also promoted research and the cultivation of the soya bean, from which a plastic was derived.

In October 1913 he introduced the "Five Dollar Day", almost doubling the normal rate of pay. This was a profit-sharing scheme for his employees and contained an element of a reward for good behaviour. About this time he initiated work on an agricultural tractor, the "Fordson" made by a separate company, the directors of which were Henry and his son Edsel.

In 1915 he chartered the Oscar II, a "peace ship", and with fifty-five delegates sailed for Europe a week before Christmas, docking at Oslo. Their objective was to appeal to all European Heads of State to stop the war. He had hoped to persuade manufacturers to replace armaments with tractors in their production programmes. In the event, Ford took to his bed in the hotel with a chill, stayed there for five days and then sailed for New York and home. He did, however, continue to finance the peace activists who remained in Europe. Back in America, he stood for election to the US Senate but was defeated. He was probably the father of John Dahlinger, illegitimate son of Evangeline Dahlinger, a stenographer employed by the firm and on whom he lavished gifts of cars, clothes and properties. He became the owner of a weekly newspaper, the Dearborn Independent, which became the medium for the expression of many of his more unorthodox ideas. He was involved in a lawsuit with the Chicago Tribune in 1919, during which he was cross-examined on his knowledge of American history: he is reputed to have said "History is bunk". What he actually said was, "History is bunk as it is taught in schools", a very different comment. The lawyers who thus made a fool of him would have been surprised if they could have foreseen the force and energy that their actions were to release. For years Ford employed a team of specialists to scour America and Europe for furniture, artefacts and relics of all kinds, illustrating various aspects of history. Starting with the Wayside Inn from South Sudbury, Massachusetts, buildings were bought, dismantled and moved, to be reconstructed in Greenfield Village, near Dearborn. The courthouse where Abraham Lincoln had practised law and the Ohio bicycle shop where the Wright brothers built their first primitive aeroplane were added to the farmhouse where the proprietor, Henry Ford, had been born. Replicas were made of Independence Hall, Congress Hall and the old City Hall in Philadelphia, and even a reconstruction of Edison's Menlo Park laboratory was installed. The Henry Ford museum was officially opened on 21 October 1929, on the fiftieth anniversary of Edison's invention of the incandescent bulb, but it continued to be a primary preoccupation of the great American car maker until his death.

Henry Ford was also responsible for a number of aeronautical developments at the Ford Airport at Dearborn. He introduced the first use of radio to guide a commercial aircraft, the first regular airmail service in the United States. He also manufactured the country's first all-metal multi-engined plane, the Ford Tri-Motor.

Edsel became President of the Ford Motor Company on his father's resignation from that position on 30 December 1918. Following the end of production in May 1927 of the Model T, the replacement Model A was not in production for another six months. During this period Henry Ford, though officially retired from the presidency of the company, repeatedly interfered and countermanded the orders of his son, ostensibly the man in charge. Edsel, who died of stomach cancer at his home at Grosse Point, Detroit, on 26 May 1943, was the father of Henry Ford II. Henry Ford died at his home, "Fair Lane", four years after his son's death.

[br]

Bibliography

1922, with S.Crowther, My Life and Work, London: Heinemann.

Further Reading

R.Lacey, 1986, Ford, the Men and the Machine, London: Heinemann. W.C.Richards, 1948, The Last Billionaire, Henry Ford, New York: Charles Scribner.

IMcN

Murdock (Murdoch), William

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Public utilities

[br]

b. 21 August 1754 Cumnock, Ayrshire, Scotland

d. 15 November 1839 Handsworth, Birmingham, England

[br]

Scottish engineer and inventor, pioneer in coal-gas production.

[br]

He was the third child and the eldest of three boys born to John Murdoch and Anna Bruce. His father, a millwright and joiner, spelled his name Murdock on moving to England. He was educated for some years at Old Cumnock Parish School and in 1777, with his father, he built a "wooden horse", supposed to have been a form of cycle. In 1777 he set out for the Soho manufactory of Boulton \& Watt, where he quickly found employment, Boulton supposedly being impressed by the lad's hat. This was oval and made of wood, and young William had turned it himself on a lathe of his own manufacture. Murdock quickly became Boulton \& Watt's representative in Cornwall, where there was a flourishing demand for steam-engines. He lived at Redruth during this period.

It is said that a number of the inventions generally ascribed to James Watt are in fact as much due to Murdock as to Watt. Examples are the piston and slide valve and the sun-and-planet gearing. A number of other inventions are attributed to Murdock alone: typical of these is the oscillating cylinder engine which obviated the need for an overhead beam.

In about 1784 he planned a steam-driven road carriage of which he made a working model. He also planned a high-pressure non-condensing engine. The model carriage was demonstrated before Murdock's friends and travelled at a speed of 6–8 mph (10–13 km/h). Boulton and Watt were both antagonistic to their employees' developing independent inventions, and when in 1786 Murdock set out with his model for the Patent Office, having received no reply to a letter he had sent to Watt, Boulton intercepted him on the open road near Exeter and dissuaded him from going any further.

In 1785 he married Mary Painter, daughter of a mine captain. She bore him four children, two of whom died in infancy, those surviving eventually joining their father at the Soho Works. Murdock was a great believer in pneumatic power: he had a pneumatic bell-push at Sycamore House, his home near Soho. The pattern-makers lathe at the Soho Works worked for thirty-five years from an air motor. He also conceived the idea of a vacuum piston engine to exhaust a pipe, later developed by the London Pneumatic Despatch Company's railway and the forerunner of the atmospheric railway.

Another field in which Murdock was a pioneer was the gas industry. In 1791, in Redruth, he was experimenting with different feedstocks in his home-cum-office in Cross Street: of wood, peat and coal, he preferred the last. He designed and built in the backyard of his house a prototype generator, washer, storage and distribution plant, and publicized the efficiency of coal gas as an illuminant by using it to light his own home. In 1794 or 1795 he informed Boulton and Watt of his experimental work and of its success, suggesting that a patent should be applied for. James Watt Junior was now in the firm and was against patenting the idea since they had had so much trouble with previous patents and had been involved in so much litigation. He refused Murdock's request and for a short time Murdock left the firm to go home to his father's mill. Boulton \& Watt soon recognized the loss of a valuable servant and, in a short time, he was again employed at Soho, now as Engineer and Superintendent at the increased salary of £300 per year plus a 1 per cent commission. From this income, he left £14,000 when he died in 1839.

In 1798 the workshops of Boulton and Watt were permanently lit by gas, starting with the foundry building. The 180 ft (55 m) façade of the Soho works was illuminated by gas for the Peace of Paris in June 1814. By 1804, Murdock had brought his apparatus to a point where Boulton \& Watt were able to canvas for orders. Murdock continued with the company after the death of James Watt in 1819, but retired in 1830 and continued to live at Sycamore House, Handsworth, near Birmingham.

[br]

Principal Honours and Distinctions

Royal Society Rumford Gold Medal 1808.

Further Reading

S.Smiles, 1861, Lives of the Engineers, Vol. IV: Boulton and Watt, London: John Murray.

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

J.A.McCash, 1966, "William Murdoch. Faithful servant" in E.G.Semler (ed.), The Great Masters. Engineering Heritage, Vol. II, London: Institution of Mechanical Engineers/Heinemann.

IMcN

Cayley, Sir George

SUBJECT AREA: Aerospace

[br]

b. 27 December 1773 Scarborough, England

d. 15 December 1857 Brompton Hall, Yorkshire, England

[br]

English pioneer who laid down the basic principles of the aeroplane in 1799 and built a manned glider in 1853.

[br]

Cayley was born into a well-to-do Yorkshire family living at Brompton Hall. He was encouraged to study mathematics, navigation and mechanics, particularly by his mother. In 1792 he succeeded to the baronetcy and took over the daunting task of revitalizing the run-down family estate.

The first aeronautical device made by Cayley was a copy of the toy helicopter invented by the Frenchmen Launoy and Bienvenu in 1784. Cayley's version, made in 1796, convinced him that a machine could "rise in the air by mechanical means", as he later wrote. He studied the aerodynamics of flight and broke away from the unsuccessful ornithopters of his predecessors. In 1799 he scratched two sketches on a silver disc: one side of the disc showed the aerodynamic force on a wing resolved into lift and drag, and on the other side he illustrated his idea for a fixed-wing aeroplane; this disc is preserved in the Science Museum in London. In 1804 he tested a small wing on the end of a whirling arm to measure its lifting power. This led to the world's first model glider, which consisted of a simple kite (the wing) mounted on a pole with an adjustable cruciform tail. A full-size glider followed in 1809 and this flew successfully unmanned. By 1809 Cayley had also investigated the lifting properties of cambered wings and produced a low-drag aerofoil section. His aim was to produce a powered aeroplane, but no suitable engines were available. Steam-engines were too heavy, but he experimented with a gunpowder motor and invented the hot-air engine in 1807. He published details of some of his aeronautical researches in 1809–10 and in 1816 he wrote a paper on airships. Then for a period of some twenty-five years he was so busy with other activities that he largely neglected his aeronautical researches. It was not until 1843, at the age of 70, that he really had time to pursue his quest for flight. The Mechanics' Magazine of 8 April 1843 published drawings of "Sir George Cayley's Aerial Carriage", which consisted of a helicopter design with four circular lifting rotors—which could be adjusted to become wings—and two pusher propellers. In 1849 he built a full-size triplane glider which lifted a boy off the ground for a brief hop. Then in 1852 he proposed a monoplane glider which could be launched from a balloon. Late in 1853 Cayley built his "new flyer", another monoplane glider, which carried his coachman as a reluctant passenger across a dale at Brompton, Cayley became involved in public affairs and was MP for Scarborough in 1832. He also took a leading part in local scientific activities and was co-founder of the British Association for the Advancement of Science in 1831 and of the Regent Street Polytechnic Institution in 1838.

[br]

Bibliography

Cayley wrote a number of articles and papers, the most significant being "On aerial navigation", Nicholson's Journal of Natural Philosophy (November 1809—March 1810) (published in three numbers); and two further papers with the same title in Philosophical Magazine (1816 and 1817) (both describe semi-rigid airships).

Further Reading

L.Pritchard, 1961, Sir George Cayley, London (the standard work on the life of Cayley).

C.H.Gibbs-Smith, 1962, Sir George Cayley's Aeronautics 1796–1855, London (covers his aeronautical achievements in more detail).

—1974, "Sir George Cayley, father of aerial navigation (1773–1857)", Aeronautical Journal (Royal Aeronautical Society) (April) (an updating paper).

JDS

kinu

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[Swahili Word] kinu

[Swahili Plural] vinu

[English Word] mortar

[English Plural] mortars

[Part of Speech] noun

[Class] 7/8

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[Swahili Word] kinu

[Swahili Plural] vinu

[English Word] press

[English Plural] presses

[Part of Speech] noun

[Class] 7/8

------------------------------------------------------------

[Swahili Word] kinu

[Swahili Plural] vinu

[English Word] mill

[English Plural] mills

[Part of Speech] noun

[Class] 7/8

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[Swahili Word] kinu cha kushindikia mafuta

[Swahili Plural] vinu vya kushindikia mafuta

[English Word] oil press

[English Plural] oil presses

[Part of Speech] noun

[Class] 7/8

[Related Words] -shindikia, mafuta

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[Swahili Word] kinu

[Swahili Plural] vinu

[English Word] machine

[English Plural] machines

[Part of Speech] noun

[Class] 7/8

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[Swahili Word] kinu cha kuchambulia pamba

[Swahili Plural] vinu vya kuchambulia pamba

[English Word] cotton gin

[English Plural] cotton gins

[Part of Speech] noun

[Class] 7/8

[Related Words] -chambulia, pamba

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[Swahili Word] kinu cha moshi

[Swahili Plural] vinu vya moshi

[English Word] steam engine

[English Plural] steam engines

[Part of Speech] noun

[Class] 7/8

[Related Words] moshi

[Terminology] railway

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[Swahili Word] kinu cha taa

[Swahili Plural] vinu vya taa

[English Word] power plant

[English Plural] power plants

[Part of Speech] noun

[Class] 7/8

[Related Words] taa

[Terminology] electricity

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[Swahili Word] kinu cha stimu

[Swahili Plural] vinu vya stimu

[English Word] power plant

[English Plural] power plants

[Part of Speech] noun

[Class] 7/8

[Related Words] stimu

[Terminology] electricity

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[Swahili Word] kinu

[Swahili Plural] vinu

[English Word] hub (of a wheel or bicycle)

[English Plural] hubs

[Part of Speech] noun

[Class] 7/8

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безкондензаторна парна машина

non-condensing steam engine

non-condensing steam engines