to+work+on+a+railway

accident

ˈæksɪdənt сущ.
1) несчастный случай;
катастрофа;
авария to have an accident ≈ потерпеть аварию, крушение;
попасть в катастрофу to meet with an accident ≈ потерпеть аварию, крушение;
попасть в катастрофу awful, bad, dreadful, frightful, horrible, shocking accident ≈ ужасная, тяжелая авария, страшная катастрофа an accident occurs, takes place ≈ происходит несчастный случай She was involved in serious car accident last week. ≈ Она попала в серьезную автокатастрофу на прошлой неделе. automobile accident factory accident professional accident industrial accident ≈ fatal accident hit-and-run accident cerebrovascular accident cerebral accident cardiovascular accident home accident pedestrian accident hunting accident motorcar accident railway accident road accidents road traffic accidents serious accident train accident unavoidable accident
2) случай;
случайность by accident ≈ случайно, нечаянно by a lucky accident ≈ по счастливой случайности pure accident ≈ чистая случайность sheer accident ≈ чистая случайность accident measures воен. ≈ меры предупреждения случайностей We discovered it by accident. ≈ Мы обнаружили это случайно. It was by pure accident that we found the money. ≈ Мы нашли деньги по чистой случайности. It was pure accident that we met. ≈ Мы встретились по чистой случайности. The police say the killing of the young man was an accident. ≈ Полиция утверждает, что убийство молодого человека является случайностью.
3) астр.;
геол. неровность поверхности, складка
4) лог. случайное свойство ∙ accidents will happen (in the best regulated families) ≈ в семье не без урода;
скандал в благородном семействе

несчастный случай;
катастрофа;
авария;
- railway * железнодорожная катастрофа;
- fatal * несчастный случай со смертельным исходом;
- industrial * несчастный случай на производстве;
- * frequency rate (американизм) коэффициент промышленного травматизма;
- * hospital травматологическая больница;
- * insurance страхование от несчастных случаев;
- * prevention техника безопасности;
предупреждение несчастных случаев;
- * preventatives техника безопасности;
- to have an * попасть в катастрофу, дорожно-транспортное происшествие;
потерпеть аварию;
- to get back without * вернуться благополучно случай, случайность;
- pure * чистая случайность;
- * measures (военное) меры предупреждения случайностей;
- by * случайно, нечаянно;
- we met by * rather than by design мы встретились скорее случайно, чем преднамеренно;
- nothing was left to * все было предусмотрено, случайностям места не осталось (логика) случайное свойство;
побочное обстоятельство (география) складка, неровность местности, рельефа ( философское) акциденция, несущественное или неглавное качество предмета > *s will happen in the best regulated families всякое бывает;
скандал в благородном семействе

accident авария ~ катастрофа ~ астр., геол. неровность поверхности, складка ~ несчастный случай;
катастрофа;
авария;
to meet with an accident потерпеть аварию, крушение;
fatal accident несчастный случай со смертельным исходом;
industrial accident несчастный случай на производстве ~ несчастный случай ~ побочное обстоятельство ~ случай;
случайность;
by accident случайно, нечаянно;
by a lucky accident по счастливой случайности ~ случай ~ случайное свойство ~ лог. случайное свойство ~ случайность

~ at work производственная травма

~ attr.: ~ insurance страхование от несчастных случаев;
accident prevention предупреждение несчастных случаев;
техника безопасности

~ attr.: ~ insurance страхование от несчастных случаев;
accident prevention предупреждение несчастных случаев;
техника безопасности insurance: accident ~ страхование от несчастного случая accident ~ страхование от несчастных случаев

~ on way to or from work несчастный случай по пути на работу или с работы

~ attr.: ~ insurance страхование от несчастных случаев;
accident prevention предупреждение несчастных случаев;
техника безопасности prevention: accident ~ мероприятия по предупреждению несчастных случаев accident ~ техника безопасности

~ rate амер. коэффициент промышленного травматизма;
accidents will happen (in the best regulated families) = в семье не без урода;
скандал в благородном семействе

~ to conveyance несчастный случай на транспорте

~ rate амер. коэффициент промышленного травматизма;
accidents will happen (in the best regulated families) = в семье не без урода;
скандал в благородном семействе will: boys ~ be boys мальчики - всегда мальчики;
accidents will happen всегда бывают несчастные случаи

~ случай;
случайность;
by accident случайно, нечаянно;
by a lucky accident по счастливой случайности

~ случай;
случайность;
by accident случайно, нечаянно;
by a lucky accident по счастливой случайности

car ~ автомобильное происшествие

commuting ~ авария во время поездки на работу или обратно commuting ~ несчастный случай (произошедший при поездке с работы домой или из дома на работу)

employment ~ происшествие на работе

~ несчастный случай;
катастрофа;
авария;
to meet with an accident потерпеть аварию, крушение;
fatal accident несчастный случай со смертельным исходом;
industrial accident несчастный случай на производстве fatal ~ несчастный случай со смертельным исходом

~ несчастный случай;
катастрофа;
авария;
to meet with an accident потерпеть аварию, крушение;
fatal accident несчастный случай со смертельным исходом;
industrial accident несчастный случай на производстве industrial ~ несчастный случай на производстве industrial ~ производственная авария industrial ~ производственная травма

~ несчастный случай;
катастрофа;
авария;
to meet with an accident потерпеть аварию, крушение;
fatal accident несчастный случай со смертельным исходом;
industrial accident несчастный случай на производстве

mining ~ происшествие на шахте

motor ~ автомобильное происшествие

navigation ~ судоходное происшествие

nuclear ~ происшествие, связанное с атомной энергией

occupational ~ несчастный случай на производстве occupational ~ происшествие на работе

personal injury ~ несчастный случай, приведший к травме

property damage ~ авария, вызвавшая имущественный ущерб

railway ~ авария на железнодорожном транспорте railway ~ железнодорожное происшествие

single ~ единичное происшествие

traffic ~ транспортное происшествие

work ~ несчастный случай на производстве work ~ производственная травма

Clark, Edwin

SUBJECT AREA: Civil engineering

[br]

b. 7 January 1814 Marlow, Buckinghamshire, England

d. 22 October 1894 Marlow, Buckinghamshire, England

[br]

English civil engineer.

[br]

After a basic education in mathematics, latin, French and geometry, Clark was articled to a solicitor, but he left after two years because he did not like the work. He had no permanent training otherwise, and for four years he led an idle life, becoming self-taught in the subjects that interested him. He eventually became a teacher at his old school before entering Cambridge, although he returned home after two years without taking a degree. He then toured the European continent extensively, supporting himself as best he could. He returned to England in 1839 and obtained further teaching posts. With the railway boom in progress he decided to become a surveyor and did some work on a proposed line between Oxford and Brighton.

After being promised an interview with Robert Stephenson, he managed to see him in March 1846. Stephenson took a liking to Clark and asked him to investigate the strains on the Britannia Bridge tubes under various given conditions. This work so gained Stephenson's full approval that, after being entrusted with experiments and designs, Clark was appointed Resident Engineer for the Britannia Bridge across the Menai Straits. He not only completed the bridge, which was opened on 19 October 1850, but also wrote the history of its construction. After the completion of the bridge—and again without any professional experience—he was appointed Engineer-in-Chief to the Electric and International Telegraph Company. He was consulted by Captain Mark Huish of the London \& North Western Railway on a telegraphic system for the railway, and in 1853 he introduced the Block Telegraph System.

Clark was engaged on the Crystal Palace and was responsible for many railway bridges in Britain and abroad. He was Engineer and part constructor of the harbour at Callao, Peru, and also of harbour works at Colón, Panama. On canal works he was contractor for the marine canal, the Morskoy Canal, in 1875 between Kronstadt and St Petersburg. His great work on canals, however, was the concept with Edward Leader Williams of the hydraulically operated barge lift at Anderton, Cheshire, linking the Weaver Navigation to the Trent \& Mersey Canal, whose water levels have a vertical separation of 50 ft (15 m). This was opened on 26 July 1875. The structure so impressed the French engineers who were faced with a bottleneck of five locks on the Neuffossée Canal south of Saint-Omer that they commissioned Clark to design a lift there. This was completed in 1878 and survives as a historic monument. The design was also adopted for four lifts on the Canal du Centre at La Louvière in Belgium, but these were not completed until after Clark's death.

JHB

Churchward, George Jackson

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 31 January 1857 Stoke Gabriel, Devon, England

d. 19 December 1933 Swindon, Wiltshire, England

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English mechanical engineer who developed for the Great Western Railway a range of steam locomotives of the most advanced design of its time.

[br]

Churchward was articled to the Locomotive Superintendent of the South Devon Railway in 1873, and when the South Devon was absorbed by the Great Western Railway in 1876 he moved to the latter's Swindon works. There he rose by successive promotions to become Works Manager in 1896, and in 1897 Chief Assistant to William Dean, who was Locomotive Carriage and Wagon Superintendent, in which capacity Churchward was allowed extensive freedom of action. Churchward eventually succeeded Dean in 1902: his title changed to Chief Mechanical Engineer in 1916.

In locomotive design, Churchward adopted the flat-topped firebox invented by A.J.Belpaire of the Belgian State Railways and added a tapered barrel to improve circulation of water between the barrel and the firebox legs. He designed valves with a longer stroke and a greater lap than usual, to achieve full opening to exhaust. Passenger-train weights had been increasing rapidly, and Churchward produced his first 4–6– 0 express locomotive in 1902. However, he was still developing the details—he had a flair for selecting good engineering practices—and to aid his development work Churchward installed at Swindon in 1904 a stationary testing plant for locomotives. This was the first of its kind in Britain and was based on the work of Professor W.F.M.Goss, who had installed the first such plant at Purdue University, USA, in 1891. For comparison with his own locomotives Churchward obtained from France three 4–4–2 compound locomotives of the type developed by A. de Glehn and G. du Bousquet. He decided against compounding, but he did perpetuate many of the details of the French locomotives, notably the divided drive between the first and second pairs of driving wheels, when he introduced his four-cylinder 4–6–0 (the Star class) in 1907. He built a lone 4–6–2, the Great Bear, in 1908: the wheel arrangement enabled it to have a wide firebox, but the type was not perpetuated because Welsh coal suited narrow grates and 4–6–0 locomotives were adequate for the traffic. After Churchward retired in 1921 his successor, C.B.Collett, was to enlarge the Star class into the Castle class and then the King class, both 4–6–0s, which lasted almost as long as steam locomotives survived in service. In Church ward's time, however, the Great Western Railway was the first in Britain to adopt six-coupled locomotives on a large scale for passenger trains in place of four-coupled locomotives. The 4–6–0 classes, however, were but the most celebrated of a whole range of standard locomotives of advanced design for all types of traffic and shared between them many standardized components, particularly boilers, cylinders and valve gear.

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Further Reading

H.C.B.Rogers, 1975, G.J.Churchward. A Locomotive Biography, London: George Allen \& Unwin (a full-length account of Churchward and his locomotives, and their influence on subsequent locomotive development).

C.Hamilton Ellis, 1958, Twenty Locomotive Men, Shepperton: Ian Allan, Ch. 20 (a good brief account).

Sir William Stanier, 1955, "George Jackson Churchward", Transactions of the Newcomen

Society 30 (a unique insight into Churchward and his work, from the informed viewpoint of his former subordinate who had risen to become Chief Mechanical Engineer of the London, Midland \& Scottish Railway).

See also: Gresley, Sir Herbert Nigel; Stanier, Sir William Arthur

PJGR

Brunel, Isambard Kingdom

SUBJECT AREA: Civil engineering, Land transport, Mechanical, pneumatic and hydraulic engineering, Ports and shipping, Public utilities, Railways and locomotives

[br]

b. 9 April 1806 Portsea, Hampshire, England

d. 15 September 1859 18 Duke Street, St James's, London, England

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English civil and mechanical engineer.

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The son of Marc Isambard Brunel and Sophia Kingdom, he was educated at a private boarding-school in Hove. At the age of 14 he went to the College of Caen and then to the Lycée Henri-Quatre in Paris, after which he was apprenticed to Louis Breguet. In 1822 he returned from France and started working in his father's office, while spending much of his time at the works of Maudslay, Sons \& Field.

From 1825 to 1828 he worked under his father on the construction of the latter's Thames Tunnel, occupying the position of Engineer-in-Charge, exhibiting great courage and presence of mind in the emergencies which occurred not infrequently. These culminated in January 1828 in the flooding of the tunnel and work was suspended for seven years. For the next five years the young engineer made abortive attempts to find a suitable outlet for his talents, but to little avail. Eventually, in 1831, his design for a suspension bridge over the River Avon at Clifton Gorge was accepted and he was appointed Engineer. (The bridge was eventually finished five years after Brunel's death, as a memorial to him, the delay being due to inadequate financing.) He next planned and supervised improvements to the Bristol docks. In March 1833 he was appointed Engineer of the Bristol Railway, later called the Great Western Railway. He immediately started to survey the route between London and Bristol that was completed by late August that year. On 5 July 1836 he married Mary Horsley and settled into 18 Duke Street, Westminster, London, where he also had his office. Work on the Bristol Railway started in 1836. The foundation stone of the Clifton Suspension Bridge was laid the same year. Whereas George Stephenson had based his standard railway gauge as 4 ft 8½ in (1.44 m), that or a similar gauge being usual for colliery wagonways in the Newcastle area, Brunel adopted the broader gauge of 7 ft (2.13 m). The first stretch of the line, from Paddington to Maidenhead, was opened to traffic on 4 June 1838, and the whole line from London to Bristol was opened in June 1841. The continuation of the line through to Exeter was completed and opened on 1 May 1844. The normal time for the 194-mile (312 km) run from Paddington to Exeter was 5 hours, at an average speed of 38.8 mph (62.4 km/h) including stops. The Great Western line included the Box Tunnel, the longest tunnel to that date at nearly two miles (3.2 km).

Brunel was the engineer of most of the railways in the West Country, in South Wales and much of Southern Ireland. As railway networks developed, the frequent break of gauge became more of a problem and on 9 July 1845 a Royal Commission was appointed to look into it. In spite of comparative tests, run between Paddington-Didcot and Darlington-York, which showed in favour of Brunel's arrangement, the enquiry ruled in favour of the narrow gauge, 274 miles (441 km) of the former having been built against 1,901 miles (3,059 km) of the latter to that date. The Gauge Act of 1846 forbade the building of any further railways in Britain to any gauge other than 4 ft 8 1/2 in (1.44 m).

The existence of long and severe gradients on the South Devon Railway led to Brunel's adoption of the atmospheric railway developed by Samuel Clegg and later by the Samuda brothers. In this a pipe of 9 in. (23 cm) or more in diameter was laid between the rails, along the top of which ran a continuous hinged flap of leather backed with iron. At intervals of about 3 miles (4.8 km) were pumping stations to exhaust the pipe. Much trouble was experienced with the flap valve and its lubrication—freezing of the leather in winter, the lubricant being sucked into the pipe or eaten by rats at other times—and the experiment was abandoned at considerable cost.

Brunel is to be remembered for his two great West Country tubular bridges, the Chepstow and the Tamar Bridge at Saltash, with the latter opened in May 1859, having two main spans of 465 ft (142 m) and a central pier extending 80 ft (24 m) below high water mark and allowing 100 ft (30 m) of headroom above the same. His timber viaducts throughout Devon and Cornwall became a feature of the landscape. The line was extended ultimately to Penzance.

As early as 1835 Brunel had the idea of extending the line westwards across the Atlantic from Bristol to New York by means of a steamship. In 1836 building commenced and the hull left Bristol in July 1837 for fitting out at Wapping. On 31 March 1838 the ship left again for Bristol but the boiler lagging caught fire and Brunel was injured in the subsequent confusion. On 8 April the ship set sail for New York (under steam), its rival, the 703-ton Sirius, having left four days earlier. The 1,340-ton Great Western arrived only a few hours after the Sirius. The hull was of wood, and was copper-sheathed. In 1838 Brunel planned a larger ship, some 3,000 tons, the Great Britain, which was to have an iron hull.

The Great Britain was screwdriven and was launched on 19 July 1843,289 ft (88 m) long by 51 ft (15.5 m) at its widest. The ship's first voyage, from Liverpool to New York, began on 26 August 1845. In 1846 it ran aground in Dundrum Bay, County Down, and was later sold for use on the Australian run, on which it sailed no fewer than thirty-two times in twenty-three years, also serving as a troop-ship in the Crimean War. During this war, Brunel designed a 1,000-bed hospital which was shipped out to Renkioi ready for assembly and complete with shower-baths and vapour-baths with printed instructions on how to use them, beds and bedding and water closets with a supply of toilet paper! Brunel's last, largest and most extravagantly conceived ship was the Great Leviathan, eventually named The Great Eastern, which had a double-skinned iron hull, together with both paddles and screw propeller. Brunel designed the ship to carry sufficient coal for the round trip to Australia without refuelling, thus saving the need for and the cost of bunkering, as there were then few bunkering ports throughout the world. The ship's construction was started by John Scott Russell in his yard at Millwall on the Thames, but the building was completed by Brunel due to Russell's bankruptcy in 1856. The hull of the huge vessel was laid down so as to be launched sideways into the river and then to be floated on the tide. Brunel's plan for hydraulic launching gear had been turned down by the directors on the grounds of cost, an economy that proved false in the event. The sideways launch with over 4,000 tons of hydraulic power together with steam winches and floating tugs on the river took over two months, from 3 November 1857 until 13 January 1858. The ship was 680 ft (207 m) long, 83 ft (25 m) beam and 58 ft (18 m) deep; the screw was 24 ft (7.3 m) in diameter and paddles 60 ft (18.3 m) in diameter. Its displacement was 32,000 tons (32,500 tonnes).

The strain of overwork and the huge responsibilities that lay on Brunel began to tell. He was diagnosed as suffering from Bright's disease, or nephritis, and spent the winter travelling in the Mediterranean and Egypt, returning to England in May 1859. On 5 September he suffered a stroke which left him partially paralysed, and he died ten days later at his Duke Street home.

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Further Reading

L.T.C.Rolt, 1957, Isambard Kingdom Brunel, London: Longmans Green. J.Dugan, 1953, The Great Iron Ship, Hamish Hamilton.

IMcN

Gooch, Sir Daniel

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

[br]

b. 24 August 1816 Bedlington, Northumberland, England

d. 15 October 1889 Clewer Park, Berkshire, England

[br]

English engineer, first locomotive superintendent of the Great Western Railway and pioneer of transatlantic electric telegraphy.

[br]

Gooch gained experience as a pupil with several successive engineering firms, including Vulcan Foundry and Robert Stephenson \& Co. In 1837 he was engaged by I.K. Brunel, who was then building the Great Western Railway (GWR) to the broad gauge of 7 ft 1/4 in. (2.14 m), to take charge of the railway's locomotive department. He was just 21 years old. The initial locomotive stock comprised several locomotives built to such extreme specifications laid down by Brunel that they were virtually unworkable, and two 2–2–2 locomotives, North Star and Morning Star, which had been built by Robert Stephenson \& Co. but left on the builder's hands. These latter were reliable and were perpetuated. An enlarged version, the "Fire Fly" class, was designed by Gooch and built in quantity: Gooch was an early proponent of standardization. His highly successful 4–2–2 Iron Duke of 1847 became the prototype of GWR express locomotives for the next forty-five years, until the railway's last broad-gauge sections were narrowed. Meanwhile Gooch had been largely responsible for establishing Swindon Works, opened in 1843. In 1862 he designed 2–4–0 condensing tank locomotives to work the first urban underground railway, the Metropolitan Railway in London. Gooch retired in 1864 but was then instrumental in arranging for Brunel's immense steamship Great Eastern to be used to lay the first transatlantic electric telegraph cable: he was on board when the cable was successfully laid in 1866. He had been elected Member of Parliament for Cricklade (which constituency included Swindon) in 1865, and the same year he had accepted an invitation to become Chairman of the Great Western Railway Company, which was in financial difficulties; he rescued it from near bankruptcy and remained Chairman until shortly before his death. The greatest engineering work undertaken during his chairmanship was the boring of the Severn Tunnel.

[br]

Principal Honours and Distinctions

Knighted 1866 (on completion of transatlantic telegraph).

Bibliography

1972, Sir Daniel Gooch, Memoirs and Diary, ed. R.B.Wilson, with introd. and notes, Newton Abbot: David \& Charles.

Further Reading

A.Platt, 1987, The Life and Times of Daniel Gooch, Gloucester: Alan Sutton (puts Gooch's career into context).

C.Hamilton Ellis, 1958, Twenty Locomotive Men, Ian Allan (contains a good short biography).

J.Kieve, 1973, The Electric Telegraph, Newton Abbot: David \& Charles, pp. 112–5.

PJGR

station

[ˈsteɪʃən]

station место, пост; battle station боевой пост; he took up a convenient station он занял удобную позицию station станция, пункт; life-boat station спасательная станция; broadcasting station радиостанция bus station автобусная станция called station вчт. вызываемая станция central station ж.-д. узловая станция coast-guard station морской пограничный пост combined heat and power station (CHP) теплоэлектростанция combined station вчт. комбинированная станция comfort station амер. общественная уборная commercial broadcasting station коммерческая радиотрансляционная станция commercial broadcasting station коммерческая телевизионная станция commercial radio station коммерческая радиостанция container freight station (CFS) пункт обработки грузовых контейнеров data station вчт. пункт сбора и обработки данных data station вчт. станция сети передачи данных display station вчт. дисплейный терминал duty station дежурный пост duty station место службы ex railway station франко-железнодорожная станция forwarding station пересылочная станция goods station товарная пристань goods station товарная станция goods station товарный склад station место, пост; battle station боевой пост; he took up a convenient station он занял удобную позицию station станция, пункт; life-boat station спасательная станция; broadcasting station радиостанция main station центральный вокзал master station вчт. ведущая станция master station вчт. главная станция operator station вчт. станция оператора police station полицейский участок polling station избирательный пункт, участок power station электростанция radio station радиостанция railway station железнодорожная станция railway station железнодорожный вокзал reading station вчт. блок считывания remote station далекая станция service station станция обслуживания (автомобилей) station воен. размещать; to station a guard выставить караул station attr. станционный station ставить на (определенное) место; помещать; to station oneself расположиться television station телевизионная станция terminal station абонентский пункт terminal station конечная станция terminal station тупиковая станция terminal station узловая станция terminal: terminal заключительный, конечный; terminal station конечная станция they returned to their several stations они вернулись на свои места work station вчт. автоматизированное рабочее место work station вчт. рабочая станция work: station attr. рабочий; work station (или position) рабочее место (у конвейера); work horse рабочая лошадь

Froude, William

SUBJECT AREA: Ports and shipping

[br]

b. 1810 Dartington, Devon, England

d. 4 May 1879 Simonstown, South Africa

[br]

English naval architect; pioneer of experimental ship-model research.

[br]

Froude was educated at a preparatory school at Buckfastleigh, and then at Westminster School, London, before entering Oriel College, Oxford, to read mathematics and classics. Between 1836 and 1838 he served as a pupil civil engineer, and then he joined the staff of Isambard Kingdom Brunel on various railway engineering projects in southern England, including the South Devon Atmospheric Railway. He retired from professional work in 1846 and lived with his invalid father at Dartington Parsonage. The next twenty years, while apparently unproductive, were important to Froude as he concentrated his mind on difficult mathematical and scientific problems. Froude married in 1839 and had five children, one of whom, Robert Edmund Froude (1846–1924), was to succeed him in later years in his research work for the Admiralty. Following the death of his father, Froude moved to Paignton, and there commenced his studies on the resistance of solid bodies moving through fluids. Initially these were with hulls towed through a house roof storage tank by wires taken over a pulley and attached to falling weights, but the work became more sophisticated and was conducted on ponds and the open water of a creek near Dartmouth. Froude published work on the rolling of ships in the second volume of the Transactions of the then new Institution of Naval Architects and through this became acquainted with Sir Edward Reed. This led in 1870 to the Admiralty's offer of £2,000 towards the cost of an experimental tank for ship models at Torquay. The tank was completed in 1872 and tests were carried out on the model of HMS Greyhound following full-scale towing trials which had commenced on the actual ship the previous year. From this Froude enunciated his Law of Comparisons, which defines the rules concerning the relationship of the power required to move geometrically similar floating bodies across fluids. It enabled naval architects to predict, from a study of a much less expensive and smaller model, the resistance to motion and the power required to move a full-size ship. The work in the tank led Froude to design a model-cutting machine, dynamometers and machinery for the accurate ruling of graph paper. Froude's work, and later that of his son, was prodigious and covered many fields of ship design, including powering, propulsion, rolling, steering and stability. In only six years he had stamped his academic authority on the new science of hydrodynamics, served on many national committees and corresponded with fellow researchers throughout the world. His health suffered and he sailed for South Africa to recuperate, but he contracted dysentery and died at Simonstown. He will be remembered for all time as one of the greatest "fathers" of naval architecture.

[br]

Principal Honours and Distinctions

FRS. Honorary LLD Glasgow University.

Bibliography

1955, The Papers of William Froude, London: Institution of Naval Architects (the Institution also published a memoir by Sir Westcott Abell and an evaluation of his work by Dr R.W.L. Gawn of the Royal Corps of Naval Constructors; this volume reprints all Froude's papers from the Institution of Naval Architects and other sources as diverse as the British Association, the Royal Society of Edinburgh and the Institution of Civil Engineers.

Further Reading

A.T.Crichton, 1990, "William and Robert Edmund Froude and the evolution of the ship model experimental tank", Transactions of the Newcomen Society 61:33–49.

FMW

Lartigue, Charles François Marie-Thérèse

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 1834 Toulouse, France d. 1907

[br]

French engineer and businessman, inventor of the Lartigue monorail.

[br]

Lartigue worked as a civil engineer in Algeria and while there invented a simple monorail for industrial or agricultural use. It comprised a single rail carried on trestles; vehicles comprised a single wheel with two tubs suspended either side, like panniers. These were pushed or pulled by hand or, occasionally, hauled by mule. Such lines were used in Algerian esparto-grass plantations.

In 1882 he patented a monorail system based on this arrangement, with important improvements: traction was to be mechanical; vehicles were to have two or four wheels and to be able to be coupled together; and the trestles were to have, on each side, a light guide rail upon which horizontal rollers beneath the vehicles would bear. Early in 1883 the Lartigue Railway Construction Company was formed in London and two experimental prototype monorails were subsequently demonstrated in public. One, at the Paris Agricultural Exhibition, had an electric locomotive that was built in two parts, one either side of the rail to maintain balance, hauling small wagons. The other prototype, in London, had a small, steam locomotive with two vertical boilers and was designed by Anatole Mallet. By now Lartigue had become associated with F.B. Behr. Behr was Managing Director of the construction company and of the Listowel \& Ballybunion Railway Company, which obtained an Act of Parliament in 1886 to built a Lartigue monorail railway in the South West of Ireland between those two places. Its further development and successful operation are described in the article on Behr in this volume.

A much less successful attempt to establish a Lartigue monorail railway took place in France, in the départment of Loire. In 1888 the council of the département agreed to a proposal put forward by Lartigue for a 10 1/2 mile (17 km) long monorail between the towns of Feurs and Panissières: the agreement was reached on the casting vote of the Chairman, a contact of Lartigue. A concession was granted to successive companies with which Lartigue was closely involved, but construction of the line was attended by muddle, delay and perhaps fraud, although it was completed sufficiently for trial trains to operate. The locomotive had two horizontal boilers, one either side of the track. But the inspectors of the department found deficiencies in the completeness and probable safety of the railway; when they did eventually agree to opening on a limited scale, the company claimed to have insufficient funds to do so unless monies owed by the department were paid. In the end the concession was forfeited and the line dismantled. More successful was an electrically operated Lartigue mineral line built at mines in the eastern Pyrenees.

It appears to have reused equipment from the electric demonstration line, with modifications, and included gradients as steep as 1 in 12. There was no generating station: descending trains generated the electricity to power ascending ones. This line is said to have operated for at least two years.

[br]

Bibliography

1882, French patent no. 149,301 (monorail system). 1882, British patent no. 2,764 (monorail system).

Further Reading

D.G.Tucker, 1984, "F.B.Behr's development of the Lartigue monorail", Transactions of the Newcomen Society 55 (describes Lartigue and his work).

P.H.Chauffort and J.-L.Largier, 1981, "Le monorail de Feurs à Panissières", Chemin defer régionaux et urbains (magazine of the Fédération des Amis des Chemins de Fer

Secondaires) 164 (in French; describes Lartigue and his work).

See also: Brennan, Louis; Palmer, Henry Robinson

PJGR

Spooner, Charles Easton

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 1818 Maentwrog, Merioneth (now Gwynedd), Wales

d. 18 November 1889 Portmadoc (now Porthmadog), Wales

[br]

English engineer, pioneer of narrow-gauge steam railways.

[br]

At the age of 16 Charles Spooner helped his father, James, to build the Festiniog Railway, a horse-and-gravity tramroad; they maintained an even gradient and kept costs down by following a sinuous course along Welsh mountainsides and using a very narrow gauge. This was probably originally 2 ft 1 in. (63.5 cm) from rail centre to rail centre; with the introduction of heavier, and therefore wider, rails the gauge between them was reduced and was eventually standardized at 1 ft 11 1/2 in (60 cm). After James Spooner's death in 1856 Charles Spooner became Manager and Engineer of the Festiniog Railway and sought to introduce steam locomotives. Widening the gauge was impracticable, but there was no precedent for operating a public railway of such narrow gauge by steam. Much of the design work for locomotives for the Festiniog Railway was the responsibility of C.M.Holland, and many possible types were considered: eventually, in 1863, two very small 0–4–0 tank locomotives, with tenders for coal, were built by George England.

These locomotives were successful, after initial problems had been overcome, and a passenger train service was introduced in 1865 with equal success. The potential for economical operation offered by such a railway attracted widespread attention, the more so because it had been effectively illegal to build new passenger railways in Britain to other than standard gauge since the Gauge of Railways Act of 1846.

Spooner progressively improved the track, alignment, signalling and rolling stock of the Festiniog Railway and developed it from a tramroad to a miniaturized main line. Increasing traffic led to the introduction in 1869 of the 0–4–4–0 double-Fairlie locomotive Little Wonder, built to the patent of Robert Fairlie. This proved more powerful than two 0–4–0s and impressive demonstrations were given to engineers from many parts of the world, leading to the widespread adoption of narrow-gauge railways. Spooner himself favoured a gauge of 2 ft 6 in. (76 cm) or 2 ft 9 in. (84 cm). Comparison of the economy of narrow gauges with the inconvenience of a break of gauge at junctions with wider gauges did, however, become a continuing controversy, which limited the adoption of narrow gauges in Britain.

Bogie coaches had long been used in North America but were introduced to Britain by Spooner in 1872, when he had two such coaches built for the Festiniog Railway. Both of these and one of its original locomotives, though much rebuilt, remain in service.

Spooner, despite some serious illnesses, remained Manager of the Festiniog Railway until his death.

[br]

Bibliography

1869, jointly with G.A.Huddart, British patent no. 1,487 (improved fishplates). 1869, British patent no. 2,896 (rail-bending machinery).

1871, Narrow Gauge Railways, E. \& F.N.Spon (includes his description of the Festiniog Railway, reports of locomotive trials and his proposals for narrow-gauge railways).

Further Reading

J.I.C.Boyd, 1975, The Festiniog Railway, Blandford: Oakwood Press; C.E.Lee, 1945, Narrow-Gauge Railways in North Wales, The Railway Publishing Co. (both give good descriptions of Spooner and the Festiniog Railway).

C.Hamilton Ellis, 1965, Railway Carriages in the British Isles, London: George Allen \& Unwin, pp. 181–3. Pihl, Carl Abraham.

PJGR

model

'modl
1. noun

1) (a copy or representation of something usually on a much smaller scale: a model of the Taj Mahal; (also adjective) a model aeroplane.) modelo, maqueta

2) (a particular type or design of something, eg a car, that is manufactured in large numbers: Our car is a 1999 model.) modelo

3) (a person who wears clothes etc so that possible buyers can see them being worn: He has a job as a male fashion model.) modelo, maniquí

4) (a person who is painted, sculpted, photographed etc by an artist, photographer etc: I work as an artist's model.) modelo

5) (something that can be used to copy from.) modelo, patrón

6) (a person or thing which is an excellent example: She is a model of politeness; (also adjective) model behaviour.) modelo

2. verb

1) (to wear (clothes etc) to show them to possible buyers: They model (underwear) for a living.) modelar

2) (to work or pose as a model for an artist, photographer etc: She models at the local art school.) hacer de modelo, posar

3) (to make models (of things or people): to model (the heads of famous people) in clay.) modelar

4) (to form (something) into a (particular) shape: She modelled the clay into the shape of a penguin; She models herself on her older sister.) modelar

•

- modelling

model¹ adj en miniatura / a escala

a model railway un ferrocarril en miniatura

model² n

1. modelo / maqueta

a model of the Tower of London una maqueta de la Torre de Londres

2. modelo

she's a very famous model es una modelo muy famosa

model

tr['mɒdəl]

noun

1 (small representation) modelo, maqueta

■ he made a model of the Eiffel Tower hizo una maqueta de la Torre Eiffel

2 (design) modelo, patrón nombre masculino

3 (type of car etc) modelo

■ the latest model el último modelo

4 (perfect example) modelo, pauta

■ I'll use yours as a model utilizaré el tuyo como modelo

■ based on the American model of democracy basado en el modelo democrático americano

■ a role model un modelo de comportamiento

5 (fashion model) modelo nombre masulino o femenino, maniquí nombre masulino o femenino; (artist's model) modelo nombre masulino o femenino

adjective

1 (miniature) en miniatura, a escala; (toy) de juguete

■ model aeroplane aeromodelo

2 (exemplary) ejemplar; (ideal) modelo

■ model student estudiante ejemplar

■ model husband marido modelo

■ a model prison una cárcel modelo

transitive verb (pt & pp modelled (|us| modeled), ger modelling (|us| modeling))

1 modelar

2 presentar, vestir, modelar

intransitive verb

1 modelar

2 trabajar de modelo

\

SMALLIDIOMATIC EXPRESSION/SMALL

to model oneself on somebody seguir el ejemplo de alguien| modeling))

1 modelar

2 presentar, vestir, modelar

intransitive verb

1 modelar

2 trabajar de modelo

\

SMALLIDIOMATIC EXPRESSION/SMALL

to model oneself upon somebody seguir el ejemplo de alguien

model ['mɑdəl] v, - eled or - elled ; - eling or - elling vt

shape: modelar

model vi

: trabajar de modelo

model adj

1) exemplary: modelo, ejemplar

a model student: un estudiante modelo

2) miniature: en miniatura

model n

1) pattern: modelo m

2) miniature: modelo m, miniatura f

3) example: modelo m, ejemplo m

4) mannequin: modelo mf

5) design: modelo m

the '97 model: el modelo '97

model

adj.

• modelo, -a adj.

n.

• boceto s.m.

• dechado s.m.

• ejemplar s.m.

• espejo s.m.

• horma s.f.

• maqueta s.f.

• marco s.m.

• modelo s.m.

• molde s.m.

• muestra s.f.

• padrón s.m.

• pauta s.f.

• plantilla s.f.

v.

• modelar v.

I 'mɑːdḷ, 'mɒdḷ

noun

1) ( reproduction) maqueta f, modelo m

a scale model — un modelo a escala

2) (paragon, example) modelo m

a model of efficiency — un modelo de eficiencia

3) ( design) modelo m

the most popular model in our range — el modelo más popular de nuestra serie

4) ( person) modelo mf

a male model — un modelo

II
1.

BrE - ll- transitive verb

1) \<\<clay/shape\>\> modelar

2) ( base)

their education system was modeled on that of France — su sistema educativo se inspiró en el francés

to model oneself on somebody — tomar a alguien como modelo

3) \<\<garment\>\>

she models sportswear — es modelo de ropa sport

2.

vi

1) ( make shapes) modelar

2) ( pose) ( Clothing) trabajar de modelo; ( Art) posar; ( Phot) ser* modelo

III

adjective (before n, no comp)

1) ( miniature) <railway/village> en miniatura, a escala

model aeroplane — aeromodelo m

2) ( ideal) <citizen/husband/pupil> modelo adj inv, ejemplar; < answer> tipo adj inv

a model prison — una cárcel modelo

['mɒdl]

1. N

1) (=small-scale representation) modelo m a escala, maqueta f

2) (=example) modelo m

to hold sth/sb up as a model — presentar algo/a algn como modelo (a seguir)

a tribunal is to be set up on the model of Nuremberg — se constituirá un tribunal según el modelo de or a la manera del de Nuremberg

3) (=paragon) modelo m

he is a model of good behaviour/patience — es un modelo de buen comportamiento/paciencia

4) (=person) (Art) modelo mf ; (Fashion) modelo mf, maniquí mf

5) (Comm) (=design) modelo m

2. ADJ

1) (=miniature) [railway, village] en miniatura, a escala

model aeroplane — aeromodelo m

2) (=prototype) [home] piloto

3) (=perfect) modelo inv

a model husband/wife — un marido/una esposa modelo

3. VT

1)

to model sth on sth: their new socialist state is modelled on that of China — su nuevo estado socialista toma como modelo el de China

the gardens are modelled on those at Versailles — los jardines están inspirados en los de Versalles

to model o.s. on sb — tomar a algn como modelo

children usually model themselves on their parents — los niños normalmente toman como modelo a sus padres

he models himself on James Dean — imita a James Dean, su modelo a imitar es James Dean

2) (Art) modelar

3) (Fashion)

Jane is modelling a design by Valentino — Jane luce un modelo de Valentino

her daughter models children's clothes — su hija es modelo de ropa de niños

4. VI

1) (Art) (=make models) modelar

2) (Phot, Art) posar; (Fashion) ser modelo, trabajar de modelo

* * *

I ['mɑːdḷ, 'mɒdḷ]

noun

1) ( reproduction) maqueta f, modelo m

a scale model — un modelo a escala

2) (paragon, example) modelo m

a model of efficiency — un modelo de eficiencia

3) ( design) modelo m

the most popular model in our range — el modelo más popular de nuestra serie

4) ( person) modelo mf

a male model — un modelo

II
1.

BrE - ll- transitive verb

1) \<\<clay/shape\>\> modelar

2) ( base)

their education system was modeled on that of France — su sistema educativo se inspiró en el francés

to model oneself on somebody — tomar a alguien como modelo

3) \<\<garment\>\>

she models sportswear — es modelo de ropa sport

2.

vi

1) ( make shapes) modelar

2) ( pose) ( Clothing) trabajar de modelo; ( Art) posar; ( Phot) ser* modelo

III

adjective (before n, no comp)

1) ( miniature) <railway/village> en miniatura, a escala

model aeroplane — aeromodelo m

2) ( ideal) <citizen/husband/pupil> modelo adj inv, ejemplar; < answer> tipo adj inv

a model prison — una cárcel modelo

Behr, Fritz Bernhard

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 9 October 1842 Berlin, Germany

d. 25 February 1927

[br]

German (naturalized British in 1876) engineer, promoter of the Lartigue monorail system.

[br]

Behr trained as an engineer in Britain and had several railway engineering appointments before becoming associated with C.F.M.-T. Lartigue in promoting the Lartigue monorail system in the British Isles. In Lartigue's system, a single rail was supported on trestles; vehicles ran on the rail, their bodies suspended pannier-fashion, stabilized by horizontal rollers running against light guide rails fixed to the sides of the trestles. Behr became Managing Director of the Listowel \& Ballybunion Railway Company, which in 1888 opened its Lartigue system line between those two places in the south-west of Ireland. Three locomotives designed by J.T.A. Mallet were built for the line by Hunslet Engine Company, each with two horizontal boilers, one either side of the track. Coaches and wagons likewise were in two parts. Technically the railway was successful, but lack of traffic caused the company to go bankrupt in 1897: the railway continued to operate until 1924.

Meanwhile Behr had been thinking in terms far more ambitious than a country branch line. Railway speeds of 150mph (240km/h) or more then lay far in the future: engineers were uncertain whether normal railway vehicles would even be stable at such speeds. Behr was convinced that a high-speed electric vehicle on a substantial Lartigue monorail track would be stable. In 1897 he demonstrated such a vehicle on a 3mile (4.8km) test track at the Brussels International Exhibition. By keeping the weight of the motors low, he was able to place the seats above rail level. Although the generating station provided by the Exhibition authorities never operated at full power, speeds over 75mph (120 km/h) were achieved.

Behr then promoted the Manchester-Liverpool Express Railway, on which monorail trains of this type running at speeds up to 110mph (177km/h) were to link the two cities in twenty minutes. Despite strong opposition from established railway companies, an Act of Parliament authorizing it was made in 1901. The Act also contained provision for the Board of Trade to require experiments to prove the system's safety. In practice this meant that seven miles of line, and a complete generating station to enable trains to travel at full speed, must be built before it was known whether the Board would give its approval for the railway or not. Such a condition was too severe for the scheme to attract investors and it remained stillborn.

[br]

Further Reading

H.Fayle, 1946, The Narrow Gauge Railways of Ireland, Greenlake Publications, Part 2, ch. 2 (describes the Listowel \& Ballybunion Railway and Behr's work there).

D.G.Tucker, 1984, "F.B.Behr's development of the Lartigue monorail", Transactions of

the Newcomen Society 55 (covers mainly the high speed lines).

See also: Brennan, Louis

PJGR

Edison, Thomas Alva

SUBJECT AREA: Architecture and building, Automotive engineering, Electricity, Electronics and information technology, Metallurgy, Photography, film and optics, Public utilities, Recording, Telecommunications

[br]

b. 11 February 1847 Milan, Ohio, USA

d. 18 October 1931 Glenmont

[br]

American inventor and pioneer electrical developer.

[br]

He was the son of Samuel Edison, who was in the timber business. His schooling was delayed due to scarlet fever until 1855, when he was 8½ years old, but he was an avid reader. By the age of 14 he had a job as a newsboy on the railway from Port Huron to Detroit, a distance of sixty-three miles (101 km). He worked a fourteen-hour day with a stopover of five hours, which he spent in the Detroit Free Library. He also sold sweets on the train and, later, fruit and vegetables, and was soon making a profit of $20 a week. He then started two stores in Port Huron and used a spare freight car as a laboratory. He added a hand-printing press to produce 400 copies weekly of The Grand Trunk Herald, most of which he compiled and edited himself. He set himself to learn telegraphy from the station agent at Mount Clements, whose son he had saved from being run over by a freight car.

At the age of 16 he became a telegraphist at Port Huron. In 1863 he became railway telegraphist at the busy Stratford Junction of the Grand Trunk Railroad, arranging a clock with a notched wheel to give the hourly signal which was to prove that he was awake and at his post! He left hurriedly after failing to hold a train which was nearly involved in a head-on collision. He usually worked the night shift, allowing himself time for experiments during the day. His first invention was an arrangement of two Morse registers so that a high-speed input could be decoded at a slower speed. Moving from place to place he held many positions as a telegraphist. In Boston he invented an automatic vote recorder for Congress and patented it, but the idea was rejected. This was the first of a total of 1180 patents that he was to take out during his lifetime. After six years he resigned from the Western Union Company to devote all his time to invention, his next idea being an improved ticker-tape machine for stockbrokers. He developed a duplex telegraphy system, but this was turned down by the Western Union Company. He then moved to New York.

Edison found accommodation in the battery room of Law's Gold Reporting Company, sleeping in the cellar, and there his repair of a broken transmitter marked him as someone of special talents. His superior soon resigned, and he was promoted with a salary of $300 a month. Western Union paid him $40,000 for the sole rights on future improvements on the duplex telegraph, and he moved to Ward Street, Newark, New Jersey, where he employed a gathering of specialist engineers. Within a year, he married one of his employees, Mary Stilwell, when she was only 16: a daughter, Marion, was born in 1872, and two sons, Thomas and William, in 1876 and 1879, respectively.

He continued to work on the automatic telegraph, a device to send out messages faster than they could be tapped out by hand: that is, over fifty words per minute or so. An earlier machine by Alexander Bain worked at up to 400 words per minute, but was not good over long distances. Edison agreed to work on improving this feature of Bain's machine for the Automatic Telegraph Company (ATC) for $40,000. He improved it to a working speed of 500 words per minute and ran a test between Washington and New York. Hoping to sell their equipment to the Post Office in Britain, ATC sent Edison to England in 1873 to negotiate. A 500-word message was to be sent from Liverpool to London every half-hour for six hours, followed by tests on 2,200 miles (3,540 km) of cable at Greenwich. Only confused results were obtained due to induction in the cable, which lay coiled in a water tank. Edison returned to New York, where he worked on his quadruplex telegraph system, tests of which proved a success between New York and Albany in December 1874. Unfortunately, simultaneous negotiation with Western Union and ATC resulted in a lawsuit.

Alexander Graham Bell was granted a patent for a telephone in March 1876 while Edison was still working on the same idea. His improvements allowed the device to operate over a distance of hundreds of miles instead of only a few miles. Tests were carried out over the 106 miles (170 km) between New York and Philadelphia. Edison applied for a patent on the carbon-button transmitter in April 1877, Western Union agreeing to pay him $6,000 a year for the seventeen-year duration of the patent. In these years he was also working on the development of the electric lamp and on a duplicating machine which would make up to 3,000 copies from a stencil. In 1876–7 he moved from Newark to Menlo Park, twenty-four miles (39 km) from New York on the Pennsylvania Railway, near Elizabeth. He had bought a house there around which he built the premises that would become his "inventions factory". It was there that he began the use of his 200- page pocket notebooks, each of which lasted him about two weeks, so prolific were his ideas. When he died he left 3,400 of them filled with notes and sketches.

Late in 1877 he applied for a patent for a phonograph which was granted on 19 February 1878, and by the end of the year he had formed a company to manufacture this totally new product. At the time, Edison saw the device primarily as a business aid rather than for entertainment, rather as a dictating machine. In August 1878 he was granted a British patent. In July 1878 he tried to measure the heat from the solar corona at a solar eclipse viewed from Rawlins, Wyoming, but his "tasimeter" was too sensitive.

Probably his greatest achievement was "The Subdivision of the Electric Light" or the "glow bulb". He tried many materials for the filament before settling on carbon. He gave a demonstration of electric light by lighting up Menlo Park and inviting the public. Edison was, of course, faced with the problem of inventing and producing all the ancillaries which go to make up the electrical system of generation and distribution-meters, fuses, insulation, switches, cabling—even generators had to be designed and built; everything was new. He started a number of manufacturing companies to produce the various components needed.

In 1881 he built the world's largest generator, which weighed 27 tons, to light 1,200 lamps at the Paris Exhibition. It was later moved to England to be used in the world's first central power station with steam engine drive at Holborn Viaduct, London. In September 1882 he started up his Pearl Street Generating Station in New York, which led to a worldwide increase in the application of electric power, particularly for lighting. At the same time as these developments, he built a 1,300yd (1,190m) electric railway at Menlo Park.

On 9 August 1884 his wife died of typhoid. Using his telegraphic skills, he proposed to 19-year-old Mina Miller in Morse code while in the company of others on a train. He married her in February 1885 before buying a new house and estate at West Orange, New Jersey, building a new laboratory not far away in the Orange Valley.

Edison used direct current which was limited to around 250 volts. Alternating current was largely developed by George Westinghouse and Nicola Tesla, using transformers to step up the current to a higher voltage for long-distance transmission. The use of AC gradually overtook the Edison DC system.

In autumn 1888 he patented a form of cinephotography, the kinetoscope, obtaining film-stock from George Eastman. In 1893 he set up the first film studio, which was pivoted so as to catch the sun, with a hinged roof which could be raised. In 1894 kinetoscope parlours with "peep shows" were starting up in cities all over America. Competition came from the Latham Brothers with a screen-projection machine, which Edison answered with his "Vitascope", shown in New York in 1896. This showed pictures with accompanying sound, but there was some difficulty with synchronization. Edison also experimented with captions at this early date.

In 1880 he filed a patent for a magnetic ore separator, the first of nearly sixty. He bought up deposits of low-grade iron ore which had been developed in the north of New Jersey. The process was a commercial success until the discovery of iron-rich ore in Minnesota rendered it uneconomic and uncompetitive. In 1898 cement rock was discovered in New Village, west of West Orange. Edison bought the land and started cement manufacture, using kilns twice the normal length and using half as much fuel to heat them as the normal type of kiln. In 1893 he met Henry Ford, who was building his second car, at an Edison convention. This started him on the development of a battery for an electric car on which he made over 9,000 experiments. In 1903 he sold his patent for wireless telegraphy "for a song" to Guglielmo Marconi.

In 1910 Edison designed a prefabricated concrete house. In December 1914 fire destroyed three-quarters of the West Orange plant, but it was at once rebuilt, and with the threat of war Edison started to set up his own plants for making all the chemicals that he had previously been buying from Europe, such as carbolic acid, phenol, benzol, aniline dyes, etc. He was appointed President of the Navy Consulting Board, for whom, he said, he made some forty-five inventions, "but they were pigeonholed, every one of them". Thus did Edison find that the Navy did not take kindly to civilian interference.

In 1927 he started the Edison Botanic Research Company, founded with similar investment from Ford and Firestone with the object of finding a substitute for overseas-produced rubber. In the first year he tested no fewer than 3,327 possible plants, in the second year, over 1,400, eventually developing a variety of Golden Rod which grew to 14 ft (4.3 m) in height. However, all this effort and money was wasted, due to the discovery of synthetic rubber.

In October 1929 he was present at Henry Ford's opening of his Dearborn Museum to celebrate the fiftieth anniversary of the incandescent lamp, including a replica of the Menlo Park laboratory. He was awarded the Congressional Gold Medal and was elected to the American Academy of Sciences. He died in 1931 at his home, Glenmont; throughout the USA, lights were dimmed temporarily on the day of his funeral.

[br]

Principal Honours and Distinctions

Member of the American Academy of Sciences. Congressional Gold Medal.

Further Reading

M.Josephson, 1951, Edison, Eyre \& Spottiswode.

R.W.Clark, 1977, Edison, the Man who Made the Future, Macdonald \& Jane.

IMcN

Preece, Sir William Henry

SUBJECT AREA: Electronics and information technology, Public utilities, Telecommunications

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b. 15 February 1834 Bryn Helen, Gwynedd, Wales

d. 6 November 1913 Penrhos, Gwynedd, Wales

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Welsh electrical engineer who greatly furthered the development and use of wireless telegraphy and the telephone in Britain, dominating British Post Office engineering during the last two decades of the nineteenth century.

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After education at King's College, London, in 1852 Preece entered the office of Edwin Clark with the intention of becoming a civil engineer, but graduate studies at the Royal Institution under Faraday fired his enthusiasm for things electrical. His earliest work, as connected with telegraphy and in particular its application for securing the safe working of railways; in 1853 he obtained an appointment with the Electric and National Telegraph Company. In 1856 he became Superintendent of that company's southern district, but four years later he moved to telegraph work with the London and South West Railway. From 1858 to 1862 he was also Engineer to the Channel Islands Telegraph Company. When the various telegraph companies in Britain were transferred to the State in 1870, Preece became a Divisional Engineer in the General Post Office (GPO). Promotion followed in 1877, when he was appointed Chief Electrician to the Post Office. One of the first specimens of Bell's telephone was brought to England by Preece and exhibited at the British Association meeting in 1877. From 1892 to 1899 he served as Engineer-in-Chief to the Post Office. During this time he made a number of important contributions to telegraphy, including the use of water as part of telegraph circuits across the Solent (1882) and the Bristol Channel (1888). He also discovered the existence of inductive effects between parallel wires, and with Fleming showed that a current (thermionic) flowed between the hot filament and a cold conductor in an incandescent lamp.

Preece was distinguished by his administrative ability, some scientific insight, considerable engineering intuition and immense energy. He held erroneous views about telephone transmission and, not accepting the work of Oliver Heaviside, made many errors when planning trunk circuits. Prior to the successful use of Hertzian waves for wireless communication Preece carried out experiments, often on a large scale, in attempts at wireless communication by inductive methods. These became of historic interest only when the work of Maxwell and Hertz was developed by Guglielmo Marconi. It is to Preece that credit should be given for encouraging Marconi in 1896 and collaborating with him in his early experimental work on radio telegraphy.

While still employed by the Post Office, Preece contributed to the development of numerous early public electricity schemes, acting as Consultant and often supervising their construction. At Worcester he was responsible for Britain's largest nineteenth-century public hydro-electric station. He received a knighthood on his retirement in 1899, after which he continued his consulting practice in association with his two sons and Major Philip Cardew. Preece contributed some 136 papers and printed lectures to scientific journals, ninety-nine during the period 1877 to 1894.

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Principal Honours and Distinctions

CB 1894. Knighted (KCB) 1899. FRS 1881. President, Society of Telegraph Engineers, 1880. President, Institution of Electrical Engineers 1880, 1893. President, Institution of Civil Engineers 1898–9. Chairman, Royal Society of Arts 1901–2.

Bibliography

Preece produced numerous papers on telegraphy and telephony that were presented as Royal Institution Lectures (see Royal Institution Library of Science, 1974) or as British Association reports.

1862–3, "Railway telegraphs and the application of electricity to the signaling and working of trains", Proceedings of the ICE 22:167–93.

Eleven editions of Telegraphy (with J.Sivewright), London, 1870, were published by 1895.

1883, "Molecular radiation in incandescent lamps", Proceedings of the Physical Society 5: 283.

1885. "Molecular shadows in incandescent lamps". Proceedings of the Physical Society 7: 178.

1886. "Electric induction between wires and wires", British Association Report. 1889, with J.Maier, The Telephone.

1894, "Electric signalling without wires", RSA Journal.

1898, "Aetheric telegraphy", Proceedings of the Institution of Electrical Engineers.

Further Reading

J.J.Fahie, 1899, History of Wireless Telegraphy 1838–1899, Edinburgh: Blackwood. E.Hawkes, 1927, Pioneers of Wireless, London: Methuen.

E.C.Baker, 1976, Sir William Preece, F.R.S. Victorian Engineer Extraordinary, London (a detailed biography with an appended list of his patents, principal lectures and publications).

D.G.Tucker, 1981–2, "Sir William Preece (1834–1913)", Transactions of the Newcomen Society 53:119–36 (a critical review with a summary of his consultancies).

GW / KF

Riggenbach, Niklaus

SUBJECT AREA: Land transport, Railways and locomotives

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b. 21 May 1817 Gebweiler, Alsace

d. 25 July 1899 Olten, Switzerland

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Swiss locomotive engineer and pioneer of mountain rack railways.

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Riggenbach came from a Basle family and was educated in Basle, Lyons and Paris, where he was so impressed by the new railway to Saint-Germain that he decided to devote himself to work in that field. He worked for Kessler's locomotive works in Karlsruhe, which built the first locomotives for the Zurich-Baden Railway. This was the first railway in Switzerland and when it was opened in 1847 Riggenbach drove the first train. He subsequently became Locomotive Superintendent of the Swiss Central Railway, and the problems of operating a steeply graded line solely by adhesion led him to develop a rack railway which incorporated a ladder rack similar to that of Sylvester Marsh. However, it was only after the Swiss Consul in Washington had reported enthusiastically on the Mount Washington Cog Railway that Riggenbach and associates were able to get a concession for their first line, which was laid up the Rigi mountain and was opened in 1871. That same year Riggenbach opened a quarry railway operated for the first time by a mixture of rack and adhesion. From this start, rack railways were built widely in Switzerland and to a lesser extent in many other parts of the world. His Rigi railway continues to operate.

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Bibliography

Riggenbach patented his rack railway in 1863.

Further Reading

Riggenbach's type of counter-pressure brakes is described in Transactions of the Newcomen Society 55:13.

M.Dietschy, 1971, "Le Chemin de fer du Rigi à 100 ans", Chemins defer régionaux et

urbains 106.

O.J.Morris, 1951, The Snow don Mountain Railway, Ian Allan.

See also: Abt, Roman

PJGR

Wöhler, August

SUBJECT AREA: Metallurgy

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b. 22 June 1819 Soltau, Germany

d. 21 June 1914 Hannover, Germany

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German railway engineer who first established the fatigue fracture of metals.

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Wöhler, the son of a schoolteacher, was born at Soltau on the Luneburg Heath and received his early education at his father's school, where his mathematical abilities soon became apparent. He completed his studies at the Technical High School, Hannover.

In 1840 he obtained a position at the Borsig Engineering Works in Berlin and acquired there much valuable experience in railway technology. He trained as an engine driver in Belgium and in 1843 was appointed as an engineer to the first Hannoverian Railway, then being constructed between Hannover and Lehrte. In 1847 he became Chief Superintendent of rolling stock on the Lower Silesian-Brandenhurg Railway, where his technical abilities influenced the Prussian Minister of Commerce to appoint him to a commission set up to investigate the reasons for the unusually high incidence of axle failures then being encountered on the railways. This was in 1852, and by 1854, when the Brandenburg line had been nationalized, Wöhler had already embarked on the long, systematic programme of mechanical testing which eventually provided him with a clear insight into the process of what is now referred to as "fatigue failure". He concentrated initially on the behaviour of machined iron and steel specimens subjected to fluctuating direct, bending and torsional stresses that were imposed by testing machines of his own design.

Although Wöhler was not the first investigator in this area, he was the first to recognize the state of "fatigue" induced in metals by the repeated application of cycles of stress at levels well below those that would cause immediate failure. His method of plotting the fatigue stress amplitude "S" against the number of stress cycles necessary to cause failure "N" yielded the well-known S-N curve which described very precisely the susceptibility to fatigue failure of the material concerned. Engineers were thus provided with an invaluable testing technique that is still widely used in the 1990s.

Between 1851 and 1898 Wöhler published forty-two papers in German technical journals, although the importance of his work was not initially fully appreciated in other countries. A display of some of his fracture fatigue specimens at the Paris Exposition in 1867, however, stimulated a short review of his work in Engineering in London. Four years later, in 1871, Engineering published a series of nine articles which described Wöhler's findings in considerable detail and brought them to the attention of engineers. Wöhler became a member of the newly created management board of the Imperial German Railways in 1874, an appointment that he retained until 1889. He is also remembered for his derivation in 1855 of a formula for calculating the deflections under load of lattice girders, plate girders, and other continuous beams resting on more than two supports. This "Three Moments" theorem appeared two years before Clapeyron independently advanced the same expression. Wöhler's other major contribution to bridge design was to use rollers at one end to allow for thermal expansion and contraction.

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Bibliography

1855, "Theorie rechteckiger eiserner Brückenbalken", Zeitschrift für Bauwesen 5:122–66. 1870, "Über die Festigkeitversuche mit Eisen und Stahl", Zeitschrift für Bauwesen 20:73– 106.

Wöhler's experiments on the fatigue of metals were reported in Engineering (1867) 2:160; (1871) 11:199–200, 222, 243–4, 261, 299–300, 326–7, 349–50, 397, 439–41.

Further Reading

R.Blaum, 1918, "August Wöhler", Beiträge zur Geschichte der Technik und Industrie 8:35–55.

——1925, "August Wöhler", Deutsches biographisches Jahrbuch, Vol. I, Stuttgart, pp. 103–7.

K.Pearson, 1890, "On Wöhler's experiments on alternating stress", Messeng. Math.

20:21–37.

J.Gilchrist, 1900, "On Wöhler's Laws", Engineer 90:203–4.

ASD

Greathead, James Henry

SUBJECT AREA: Civil engineering, Mining and extraction technology

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b. 6 August 1844 Grahamstown, Cape Colony (now South Africa)

d. 21 October 1896 Streatham, London, England

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British civil engineer, inventor of the Greathead tunnelling shield.

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Greathead came to England in 1859 to complete his education. In 1864 he began a three-year pupillage with the civil engineer Peter W. Barlow, after which he was engaged as an assistant engineer on the extension of the Midland Railway from Bedford to London. In 1869 he was entrusted with the construction of the Tower Subway under the River Thames; this was carried out using a cylindrical wrought-iron shield which was forced forward by six large screws as material was excavated in front of it. This work was completed the same year. In 1870 he set himself up as a consulting engineer, and from 1873 he was Resident Engineer on the Hammersmith and Richmond extensions of the Metropolitan District Railway. He assisted in the preparation of several other railway projects including the Regent's Canal Railway in 1880, the Dagenham Dock and the Metropolitan Outer Circle Railways in 1881, a new line from London to Eastbourne and a number of Irish light railways. He worked on a bill for the City and South London Railway, which was built between 1886 and 1890; here compressed air was used to prevent the inrush of water, a method for tunnelling which was generally adopted from then on. He invented apparatus for the application of water to excavate in front of the shield as well as for injecting cement-grout behind the lining of the tunnel.

He was joint engineer with Sir Douglas Fox for the construction of the Liverpool Overhead Railway, and held the same post with W.R.Galbraith on the Waterloo and City Railway; he was also associated with Sir John Fowler and Sir Benjamin Baker in the construction of the Central London Railway. He died, aged 52, before the completion of some of these projects.

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Further Reading

Obituary, 1896, Proceedings of the Institution of Mechanical Engineers.

O.Green, 1987, The London Underground: An Illustrated History', London: Ian Allan (in association with the London Transport Museum).

P.P.Holman, 1990, The Amazing Electric Tube: A History of the City and South London

Railway, London: London Transport Museum.

IMcN

Aspinall, Sir John Audley Frederick

SUBJECT AREA: Electricity, Land transport, Railways and locomotives

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b. 25 August 1851 Liverpool, England

d. 19 January 1937 Woking, England

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English mechanical engineer, pioneer of the automatic vacuum brake for railway trains and of railway electrification.

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Aspinall's father was a QC, Recorder of Liverpool, and Aspinall himself became a pupil at Crewe Works of the London \& North Western Railway, eventually under F.W. Webb. In 1875 he was appointed Manager of the works at Inchicore, Great Southern \& Western Railway, Ireland. While he was there, some of the trains were equipped, on trial, with continuous brakes of the non-automatic vacuum type. Aspinall modified these to make them automatic, i.e. if the train divided, brakes throughout both parts would be applied automatically. Aspinall vacuum brakes were subsequently adopted by the important Great Northern, Lancashire \& Yorkshire, and London \& North Western Railways.

In 1883, aged only 32, Aspinall was appointed Locomotive Superintendent of the Great Southern \& Western Railway, but in 1886 he moved in the same capacity to the Lancashire \& Yorkshire Railway, where his first task was to fit out the new works at Horwich. The first locomotive was completed there in 1889, to his design. In 1899 he introduced a 4–4–2, the largest express locomotive in Britain at the time, some of which were fitted with smokebox superheaters to Aspinall's design.

Unusually for an engineer, in 1892 Aspinall was appointed General Manager of the Lancashire \& Yorkshire Railway. He electrified the Liverpool-Southport line in 1904 at 600 volts DC with a third rail; this was an early example of main-line electrification, for it extended beyond the Liverpool suburban area. He also experimented with 3,500 volt DC overhead electrification of the Bury-Holcombe Brook branch in 1913, but converted this to 1,200 volts DC third rail to conform with the Manchester-Bury line when this was electrified in 1915. In 1918 he was made a director of the Lancashire \& Yorkshire Railway.

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Principal Honours and Distinctions

Knighted 1917. President, Institution of Mechanical Engineers 1909. President, Institution of Civil Engineers 1918.

Further Reading

H.A.V.Bulleid, 1967, The Aspinall Era, Shepperton: Ian Allan (provides a good account of Aspinall and his life's work).

C.Hamilton Ellis, 1958, Twenty Locomotive Men, Shepperton: Ian Allan, Ch. 19 (a good brief account).

See also: Gresley, Sir Herbert Nigel; Schmidt, Wilhelm; Westinghouse, George

PJGR

Booth, Henry

SUBJECT AREA: Land transport, Railways and locomotives

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b. 4 April 1789 Liverpool, England

d. 28 March 1869 Liverpool, England

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English railway administrator and inventor.

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Booth followed his father as a Liverpool corn merchant but had great mechanical aptitude. In 1824 he joined the committee for the proposed Liverpool \& Manchester Railway (L \& MR) and after the company obtained its Act of Parliament in 1826 he was appointed Treasurer.

In 1829 the L \& MR announced a prize competition, the Rainhill Trials, for an improved steam locomotive: Booth, realizing that the power of a locomotive depended largely upon its capacity to raise steam, had the idea that this could be maximized by passing burning gases from the fire through the boiler in many small tubes to increase the heating surface, rather than in one large one, as was then the practice. He was apparently unaware of work on this type of boiler even then being done by Marc Seguin, and the 1791 American patent by John Stevens. Booth discussed his idea with George Stephenson, and a boiler of this type was incorporated into the locomotive Rocket, which was built by Robert Stephenson and entered in the Trials by Booth and the two Stephensons in partnership. The boiler enabled Rocket to do all that was required in the trials, and far more: it became the prototype for all subsequent conventional locomotive boilers.

After the L \& MR opened in 1830, Booth as Treasurer became in effect the general superintendent and was later General Manager. He invented screw couplings for use with sprung buffers. When the L \& MR was absorbed by the Grand Junction Railway in 1845 he became Secretary of the latter, and when, later the same year, that in turn amalgamated with the London \& Birmingham Railway (L \& BR) to form the London \& North Western Railway (L \& NWR), he became joint Secretary with Richard Creed from the L \& BR.

Earlier, completion in 1838 of the railway from London to Liverpool had brought problems with regard to local times. Towns then kept their own time according to their longitude: Birmingham time, for instance, was 7¼ minutes later than London time. This caused difficulties in railway operation, so Booth prepared a petition to Parliament on behalf of the L \& MR that London time should be used throughout the country, and in 1847 the L \& NWR, with other principal railways and the Post Office, adopted Greenwich time. It was only in 1880, however, that the arrangement was made law by Act of Parliament.

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Bibliography

1835. British patent no. 6,814 (grease lubricants for axleboxes). 1836. British patent no. 6,989 (screw couplings).

Booth also wrote several pamphlets on railways, uniformity of time, and political matters.

Further Reading

H.Booth, 1980, Henry Booth, Ilfracombe: Arthur H.Stockwell (a good full-length biography, the author being the great-great-nephew of his subject; with bibliography).

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

PJGR

Davidson, Robert

SUBJECT AREA: Electricity, Land transport, Railways and locomotives

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b. 18 April 1804 Aberdeen, Scotland

d. 16 November 1894 Aberdeen, Scotland

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Scottish chemist, pioneer of electric power and builder of the first electric railway locomotives.

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Davidson, son of an Aberdeen merchant, attended Marischal College, Aberdeen, between 1819 and 1822: his studies included mathematics, mechanics and chemistry. He subsequently joined his father's grocery business, which from time to time received enquiries for yeast: to meet these, Davidson began to manufacture yeast for sale and from that start built up a successful chemical manufacturing business with the emphasis on yeast and dyes. About 1837 he started to experiment first with electric batteries and then with motors. He invented a form of electromagnetic engine in which soft iron bars arranged on the periphery of a wooden cylinder, parallel to its axis, around which the cylinder could rotate, were attracted by fixed electromagnets. These were energized in turn by current controlled by a simple commutaring device. Electric current was produced by his batteries. His activities were brought to the attention of Michael Faraday and to the scientific world in general by a letter from Professor Forbes of King's College, Aberdeen. Davidson declined to patent his inventions, believing that all should be able freely to draw advantage from them, and in order to afford an opportunity for all interested parties to inspect them an exhibition was held at 36 Union Street, Aberdeen, in October 1840 to demonstrate his "apparatus actuated by electro-magnetic power". It included: a model locomotive carriage, large enough to carry two people, that ran on a railway; a turning lathe with tools for visitors to use; and a small printing machine. In the spring of 1842 he put on a similar exhibition in Edinburgh, this time including a sawmill. Davidson sought support from railway companies for further experiments and the construction of an electromagnetic locomotive; the Edinburgh exhibition successfully attracted the attention of the proprietors of the Edinburgh 585\& Glasgow Railway (E \& GR), whose line had been opened in February 1842. Davidson built a full-size locomotive incorporating his principle, apparently at the expense of the railway company. The locomotive weighed 7 tons: each of its two axles carried a cylinder upon which were fastened three iron bars, and four electromagnets were arranged in pairs on each side of the cylinders. The motors he used were reluctance motors, the power source being zinc-iron batteries. It was named Galvani and was demonstrated on the E \& GR that autumn, when it achieved a speed of 4 mph (6.4 km/h) while hauling a load of 6 tons over a distance of 1 1/2 miles (2.4 km); it was the first electric locomotive. Nevertheless, further support from the railway company was not forthcoming, although to some railway workers the locomotive seems to have appeared promising enough: they destroyed it in Luddite reaction. Davidson staged a further exhibition in London in 1843 without result and then, the cost of battery chemicals being high, ceased further experiments of this type. He survived long enough to see the electric railway become truly practicable in the 1880s.

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Bibliography

1840, letter, Mechanics Magazine, 33:53–5 (comparing his machine with that of William Hannis Taylor (2 November 1839, British patent no. 8,255)).

Further Reading

1891, Electrical World, 17:454.

J.H.R.Body, 1935, "A note on electro-magnetic engines", Transactions of the Newcomen Society 14:104 (describes Davidson's locomotive).

F.J.G.Haut, 1956, "The early history of the electric locomotive", Transactions of the Newcomen Society 27 (describes Davidson's locomotive).

A.F.Anderson, 1974, "Unusual electric machines", Electronics \& Power 14 (November) (biographical information).

—1975, "Robert Davidson. Father of the electric locomotive", Proceedings of the Meeting on the History of Electrical Engineering Institution of Electrical Engineers, 8/1–8/17 (the most comprehensive account of Davidson's work).

A.C.Davidson, 1976, "Ingenious Aberdonian", Scots Magazine (January) (details of his life).

PJGR / GW

Hackworth, Timothy

SUBJECT AREA: Land transport, Railways and locomotives

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b. 22 December 1786 Wylam, Northumberland, England

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

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

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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.

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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