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Lenoir, Jean Joseph Etienne

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

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b. 1822 Mussey-la-Ville, Belgium

d. 1900 Verenna Saint-Hildar, France

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Belgian (naturalized French in 1870) inventor of internal combustion engines, an electroplating process and railway telegraphy systems.

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Leaving his native village for Paris at the age of 16, Lenoir became a metal enameller. Experiments with various electroplating processes provided a useful knowledge of electricity that showed in many of his later ideas. Electric ignition, although somewhat unreliable, was a feature of the Lenoir gas engine which appeared in 1860. Resembling the steam engine of the day, Lenoir engines used a non-compression cycle of operations, in which the gas-air mixture of about atmospheric pressure was being ignited at one-third of the induction stroke. The engines were double acting. About five hundred of Lenoir's engines were built, mostly in Paris by M.Hippolyte Marinoni and by Lefébvre; the Reading Ironworks in England built about one hundred. Many useful applications of the engine are recorded, but the explosive shock that occurred on ignition, together with the unreliable ignition systems, prevented large-scale acceptance of the engine in industry. However, Lenoir's effort and achievements stimulated much discussion, and N.A. Otto is reported to have carried out his first experiments on a Lenoir engine.

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Principal Honours and Distinctions

Académie des Sciences Prix Montyon Prize 1870. Société d'Encouragement, Silver Prize of 12,000 francs. Légion d'honneur 1881 (for his work in telegraphy).

Bibliography

8 February 1860, British patent no. 335 (the first Lenoir engine).

1861, British patent no. 107 (the Lenoir engine).

Further Reading

Dugald Clerk, 1895, The Gas and Oil Engine, 6th edn, London, pp. 13–15, 30, 118, 203.

World Who's Who in Science, 1968 (for an account of Lenoir's involvement in technology).

KAB

Leonardo da Vinci

SUBJECT AREA: Aerospace, Architecture and building, Horology, Weapons and armour

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b. 15 April 1452 Vinci, near Florence, Italy,

d. 2 May 1519 St Cloux, near Amboise, France.

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Italian scientist, engineer, inventor and artist.

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Leonardo was the illegitimate son of a Florentine lawyer. His first sixteen years were spent with the lawyer's family in the rural surroundings of Vinci, which aroused in him a lifelong love of nature and an insatiable curiosity in it. He received little formal education but extended his knowledge through private reading. That gave him only a smattering of Latin, a deficiency that was to be a hindrance throughout his active life. At sixteen he was apprenticed in the studio of Andrea del Verrochio in Florence, where he received a training not only in art but in a wide variety of crafts and technical arts.

In 1482 Leonardo went to Milan, where he sought and obtained employment with Ludovico Sforza, later Duke of Milan, partly to sculpt a massive equestrian statue of Ludovico but the work never progressed beyond the full-scale model stage. He did, however, complete the painting which became known as the Virgin of the Rocks and in 1497 his greatest artistic achievement, The Last Supper, commissioned jointly by Ludovico and the friars of Santa Maria della Grazie and painted on the wall of the monastery's refectory. Leonardo was responsible for the court pageants and also devised a system of irrigation to supply water to the plains of Lombardy. In 1499 the French army entered Milan and deposed Leonardo's employer. Leonardo departed and, after a brief visit to Mantua, returned to Florence, where for a time he was employed as architect and engineer to Cesare Borgia, Duke of Romagna. Around 1504 he completed another celebrated work, the Mona Lisa.

In 1506 Leonardo began his second sojourn in Milan, this time in the service of King Louis XII of France, who appointed him "painter and engineer". In 1513 Leonardo left for Rome in the company of his pupil Francesco Melzi, but his time there was unproductive and he found himself out of touch with the younger artists active there, Michelangelo above all. In 1516 he accepted with relief an invitation from King François I of France to reside at the small château of St Cloux in the royal domain of Amboise. With the pension granted by François, Leonardo lived out his remaining years in tranquility at St Cloux.

Leonardo's career can hardly be regarded as a success or worthy of such a towering genius. For centuries he was known only for the handful of artistic works that he managed to complete and have survived more or less intact. His main activity remained hidden until the nineteenth and twentieth centuries, during which the contents of his notebooks were gradually revealed. It became evident that Leonardo was one of the greatest scientific investigators and inventors in the history of civilization. Throughout his working life he extended a searching curiosity over an extraordinarily wide range of subjects. The notes show careful investigation of questions of mechanical and civil engineering, such as power transmission by means of pulleys and also a form of chain belting. The notebooks record many devices, such as machines for grinding and polishing lenses, a lathe operated by treadle-crank, a rolling mill with conical rollers and a spinning machine with pinion and yard divider. Leonardo made an exhaustive study of the flight of birds, with a view to designing a flying machine, which obsessed him for many years.

Leonardo recorded his observations and conclusions, together with many ingenious inventions, on thousands of pages of manuscript notes, sketches and drawings. There are occasional indications that he had in mind the publication of portions of the notes in a coherent form, but he never diverted his energy into putting them in order; instead, he went on making notes. As a result, Leonardo's impact on the development of science and technology was virtually nil. Even if his notebooks had been copied and circulated, there were daunting impediments to their understanding. Leonardo was left-handed and wrote in mirror-writing: that is, in reverse from right to left. He also used his own abbreviations and no punctuation.

At his death Leonardo bequeathed his entire output of notes to his friend and companion Francesco Melzi, who kept them safe until his own death in 1570. Melzi left the collection in turn to his son Orazio, whose lack of interest in the arts and sciences resulted in a sad period of dispersal which endangered their survival, but in 1636 the bulk of them, in thirteen volumes, were assembled and donated to the Ambrosian Library in Milan. These include a large volume of notes and drawings compiled from the various portions of the notebooks and is now known as the Codex Atlanticus. There they stayed, forgotten and ignored, until 1796, when Napoleon's marauding army overran Italy and art and literary works, including the thirteen volumes of Leonardo's notebooks, were pillaged and taken to Paris. After the war in 1815, the French government agreed to return them but only the Codex Atlanticus found its way back to Milan; the rest remained in Paris. The appendix to one notebook, dealing with the flight of birds, was later regarded as of sufficient importance to stand on its own. Four small collections reached Britain at various times during the seventeenth and eighteenth centuries; of these, the volume in the Royal Collection at Windsor Castle is notable for its magnificent series of anatomical drawings. Other collections include the Codex Leicester and Codex Arundel in the British Museum in London, and the Madrid Codices in Spain.

Towards the end of the nineteenth century, Leonardo's true stature as scientist, engineer and inventor began to emerge, particularly with the publication of transcriptions and translations of his notebooks. The volumes in Paris appeared in 1881–97 and the Codex Atlanticus was published in Milan between 1894 and 1904.

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Principal Honours and Distinctions

"Premier peintre, architecte et mécanicien du Roi" to King François I of France, 1516.

Further Reading

E.MacCurdy, 1939, The Notebooks of Leonardo da Vinci, 2 vols, London; 2nd edn, 1956, London (the most extensive selection of the notes, with an English translation).

G.Vasari (trans. G.Bull), 1965, Lives of the Artists, London: Penguin, pp. 255–271.

C.Gibbs-Smith, 1978, The Inventions of Leonardo da Vinci, Oxford: Phaidon. L.H.Heydenreich, Dibner and L. Reti, 1981, Leonardo the Inventor, London: Hutchinson.

I.B.Hart, 1961, The World of Leonardo da Vinci, London: Macdonald.

LRD / IMcN

Maxim, Sir Hiram Stevens

SUBJECT AREA: Aerospace, Weapons and armour

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b. 5 February 1840 Brockway's Mills, Maine, USA

d. 24 November 1916 Streatham, London, England

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American (naturalized British) inventor; designer of the first fully automatic machine gun and of an experimental steam-powered aircraft.

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Maxim was born the son of a pioneer farmer who later became a wood turner. Young Maxim was first apprenticed to a carriage maker and then embarked on a succession of jobs before joining his uncle in his engineering firm in Massachusetts in 1864. As a young man he gained a reputation as a boxer, but it was his uncle who first identified and encouraged Hiram's latent talent for invention.

It was not, however, until 1878, when Maxim joined the first electric-light company to be established in the USA, as its Chief Engineer, that he began to make a name for himself. He developed an improved light filament and his electric pressure regulator not only won a prize at the first International Electrical Exhibition, held in Paris in 1881, but also resulted in his being made a Chevalier de la Légion d'honneur. While in Europe he was advised that weapons development was a more lucrative field than electricity; consequently, he moved to England and established a small laboratory at Hatton Garden, London. He began by investigating improvements to the Gatling gun in order to produce a weapon with a faster rate of fire and which was more accurate. In 1883, by adapting a Winchester carbine, he successfully produced a semi-automatic weapon, which used the recoil to cock the gun automatically after firing. The following year he took this concept a stage further and produced a fully automatic belt-fed weapon. The recoil drove barrel and breechblock to the vent. The barrel then halted, while the breechblock, now unlocked from the former, continued rearwards, extracting the spent case and recocking the firing mechanism. The return spring, which it had been compressing, then drove the breechblock forward again, chambering the next round, which had been fed from the belt, as it did so. Keeping the trigger pressed enabled the gun to continue firing until the belt was expended. The Maxim gun, as it became known, was adopted by almost every army within the decade, and was to remain in service for nearly fifty years. Maxim himself joined forces with the large British armaments firm of Vickers, and the Vickers machine gun, which served the British Army during two world wars, was merely a refined version of the Maxim gun.

Maxim's interests continued to occupy several fields of technology, including flight. In 1891 he took out a patent for a steam-powered aeroplane fitted with a pendulous gyroscopic stabilizer which would maintain the pitch of the aeroplane at any desired inclination (basically, a simple autopilot). Maxim decided to test the relationship between power, thrust and lift before moving on to stability and control. He designed a lightweight steam-engine which developed 180 hp (135 kW) and drove a propeller measuring 17 ft 10 in. (5.44 m) in diameter. He fitted two of these engines into his huge flying machine testrig, which needed a wing span of 104 ft (31.7 m) to generate enough lift to overcome a total weight of 4 tons. The machine was not designed for free flight, but ran on one set of rails with a second set to prevent it rising more than about 2 ft (61 cm). At Baldwyn's Park in Kent on 31 July 1894 the huge machine, carrying Maxim and his crew, reached a speed of 42 mph (67.6 km/h) and lifted off its rails. Unfortunately, one of the restraining axles broke and the machine was extensively damaged. Although it was subsequently repaired and further trials carried out, these experiments were very expensive. Maxim eventually abandoned the flying machine and did not develop his idea for a stabilizer, turning instead to other projects. At the age of almost 70 he returned to the problems of flight and designed a biplane with a petrol engine: it was built in 1910 but never left the ground.

In all, Maxim registered 122 US and 149 British patents on objects ranging from mousetraps to automatic spindles. Included among them was a 1901 patent for a foot-operated suction cleaner. In 1900 he became a British subject and he was knighted the following year. He remained a larger-than-life figure, both physically and in character, until the end of his life.

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Principal Honours and Distinctions

Chevalier de la Légion d'Honneur 1881. Knighted 1901.

Bibliography

1908, Natural and Artificial Flight, London. 1915, My Life, London: Methuen (autobiography).

Further Reading

Obituary, 1916, Engineer (1 December).

Obituary, 1916, Engineering (1 December).

P.F.Mottelay, 1920, The Life and Work of Sir Hiram Maxim, London and New York: John Lane.

Dictionary of National Biography, 1912–1921, 1927, Oxford: Oxford University Press.

See also: Pilcher, Percy Sinclair

CM / JDS

Monro, Philip Peter

SUBJECT AREA: Chemical technology

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b. 27 May 1946 London, England

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English biologist, inventor of a water-purification process by osmosis.

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Monro's whole family background is engineering, an interest he did not share. Instead, he preferred biology, an enthusiasm aroused by reading the celebrated Science of Life by H.G. and G.P.Wells and Julian Huxley. Educated at a London comprehensive school, Monro found it necessary to attend evening classes while at school to take his advanced level science examinations. Lacking parental support, he could not pursue a degree course until he was 21 years old, and so he gained valuable practical experience as a research technician. He resumed his studies and took a zoology degree at Portsmouth Polytechnic. He then worked in a range of zoology and medical laboratories, culminating after twelve years as a Senior Experimental Officer at Southampton Medical School. In 1989 he relinquished his post to devote himself fall time to developing his inventions as Managing Director of Hampshire Advisory and Technical Services Ltd (HATS). Also in 1988 he obtained his PhD from Southampton University, in the field of embryology.

Monro had meanwhile been demonstrating a talent for invention, mainly in microscopy. His most important invention, however, is of a water-purification system. The idea for it came from Michael Wilson of the Institute of Dental Surgery in London, who evolved a technique for osmotic production of sterile oral rehydration solutions, of particular use in treating infants suffering from diarrhoea in third-world countries. Monro broadened the original concept to include dried food, intravenous solutions and even dried blood. The process uses simple equipment and no external power and works as follows: a dry sugar/salts mixture is sealed in one compartment of a double bag, the common wall of which is a semipermeable membrane. Impure water is placed in the empty compartment and the water transfers across the membrane by the osmotic force of the sugar/salts. As the pores in the membrane exclude all viruses, bacteria and their toxins, a sterile solution is produced.

With the help of a research fellowship granted for humanitarian reasons at King Alfred College, Winchester, the invention was developed to functional prototype stage in 1993, with worldwide patent protection. Commercial production was expected to follow, if sufficient financial backing were forthcoming. The process is not intended to replace large installations, but will revolutionize the small-scale production of sterile water in scattered third-world communities and in disaster areas where normal services have been disrupted.

HATS was awarded First Prize in the small business category and was overall prize winner in the Toshiba Year of Invention, received a NatWest/BP award for technology and a Prince of Wales Award for Innovation.

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Bibliography

1993, with M.Wilson and W.A.M.Cutting, "Osmotic production of sterile oral rehydration solutions", Tropical Doctor 23:69–72.

LRD

Mudge, Thomas

SUBJECT AREA: Horology

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b. 1715 Exeter, England

d. 14 November 1794 Walworth, England

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English clock-and watchmaker who invented the lever escapement that was ultimately used in all mechanical watches.

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Thomas Mudge was the son of a clergyman and schoolmaster who, recognizing his son's mechanical aptitude, apprenticed him to the eminent London clock-and watchmaker George Graham. Mudge became free of the Clockmakers' Company in 1738 and set up on his own account after Graham's death in 1751. Around 1755 he formed a partnership with William Dutton, another apprentice of Graham. The firm produced conventional clocks and watches of excellent quality, but Mudge had also established a reputation for making highly innovative individual pieces. The most significant of these was the watch with a detached-lever escapement that he completed in 1770, although the idea had occurred to him as early as 1754. This watch was purchased by George III for Queen Charlotte and is still in the Royal Collection. Shortly afterwards Mudge moved to Plymouth, to devote his time to the perfection of the marine chronometer, leaving the London business in the hands of Dutton. The chronometers he produced were comparable in performance to those of John Harrison, but like them they were too complicated and expensive to be produced in quantity.

Mudge's patron, Count Bruhl, recognized the potential of the detached-lever escapement, but Mudge was too involved with his marine chronometers to make a watch for him. He did, however, provide Bruhl with a large-scale model of his escapement, from which the Swiss expatriate Josiah Emery was able to make a watch in 1782. Over the next decade Emery made a limited number of similar watches for wealthy clients, and it was the performance of these watches that demonstrated the worth of the escapement. The detached-lever escapement took some time to be adopted universally, but this was facilitated in the nineteenth century by the development of a cheaper form, the pin lever.

By the end of the century the detached-lever escapement was used in one form or another in practically all mechanical watches and portable clocks. If a watch is to be a good timekeeper the balance must be free to swing with as little interference as possible from the escapement. In this respect the cylinder escapement is an improvement on the verge, although it still exerts a frictional force on the balance. The lever escapement is a further improvement because it detaches itself from the balance after delivering the impulse which keeps it oscillating.

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Principal Honours and Distinctions

Clockmaker to George III 1776.

Further Reading

T.Mudge, Jr, 1799, A Description with Plates of the Time-Keeper Invented by the Late Mr. Thomas Mudge, London (contains a tract written by his father and the text of his letters to Count Bruhl).

C.Clutton and G.Daniels, 1986, Watches, 4th edn, London (provides further biographical information and a good account of the history of the lever watch).

R.Good, 1978, Britten's Watch \& Clock Maker's Handbook Dictionary and Guide, 16th edn, London, pp. 190–200 (provides a good technical description of Mudge's lever escapement and its later development).

DV

Niepce, Joseph Nicéphore

SUBJECT AREA: Photography, film and optics

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b. 1765 France

d. 5 July 1833 Chalon, France

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French inventor who was the first to produce permanent photographic images with the aid of a camera.

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Coming from a prosperous family, Niepce was educated in a Catholic seminary and destined for the priesthood. The French Revolution intervened and Niepce became an officer in an infantry regiment. An attack of typhoid fever in Italy ended his military career, and he returned to France and was married. Returning to his paternal home in Chalon in 1801, he joined with his brother Claude to construct an ingenious engine called the pyréolophore, which they patented in 1807. The French Government also encouraged the brothers in their attempts to produce large quantities of indigo-blue dye from wood, a venture that was ultimately unsuccessful.

Nicéphore began to experiment with lithography, which led him to take an interest in the properties of light-sensitive materials. He pursued this interest after Claude moved to Paris in 1816 and is reported to have made negative images in a camera obscura using paper soaked in silver chloride. Niepce went on to experiment with bitumen of judea, a substance that hardened on exposure to light. In 1822, using bitumen of judea on glass, he produced a heliograph from an engraving. The first images from nature may have been made as early as 1824, but the world's earliest surviving photographic image was made in 1826. A view of the courtyard of Niepce's home in Chalon was captured on a pewter plate coated with bitumen of judea; an exposure of several hours was required, the softer parts of the bitumen being dissolved away by a solvent to reveal the image.

In 1827 he took examples of his work to London where he met Francis Bauer, Secretary of the Royal Society. Nothing came of this meeting, but on returning to France Niepce continued his work and in 1829 entered into a formal partnership with L.J.M. Daguerre with a view to developing their mutual interest in capturing images formed by the camera obscura. However, the partnership made only limited progress and was terminated by Niepce's death in 1833. It was another six years before the announcement of the first practicable photographic processes was made.

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Bibliography

1973. Joseph Nicéphore Niepce lettres 1816–7, Pavillon de Photographie du Parc Naturel, Régional de Brotonne.

1974, Joseph Nicéphore Niepce correspondences 1825–1829, Pavillon de Photographie du Parc Naturel, Régional de Brotonne.

Further Reading

J.M.Eder, 1945, History of Photography, trans. E. Epstean, New York (provides a full account of Niepce's life and work).

H.Gernsheim and A.Gernsheim, 1969, The History of Photography, rev. edn, London (provides a full account of Niepce's life and work).

JW

Parry, George

SUBJECT AREA: Metallurgy

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fl. 1800–1850 Wales

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Welsh ironmaker and inventor of the bell and hopper for blastfurnaces.

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Until the mid-nineteenth century, blast furnaces were open at the top to facilitate loading of the iron ore, fuel and flux (the charge). However, that arrangement allowed the hot gases produced in the furnace to escape, whereas they could have been used to heat boilers or the incoming air blast. Attempts had been made to capture the fugitive gases, but they had all failed until George Parry devised his bell and hopper equipment for dosing the throat or top of the furnace. He fixed an inverted cone or hopper inside the throat and arranged inside it a cast-iron bell that could be raised or lowered. When in the raised position, it was in contact with the underside of the hopper, thus sealing the furnace. The hot gases could then be led off through a large pipe to do useful work. The charge was dropped onto the bell, and when enough had accumulated there the bell was lowered, allowing the charge to fall into the furnace. The gas escaped only for the brief period that the bell was lowered. The advantages of this arrangement were soon realized by other ironmasters and it was quite rapidly, and then generally, adopted. The device was still in use in the 1990s, with modifications.

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Bibliography

1858, "On the principal causes of derangements in blast furnaces", Proceedings of the South Wales Institute of Engineers 1:26–39 (describes his improvements to the blast furnace), 28 ff. (relates to the improvements in the charging arrangements).

Further Reading

W.K.V.Gale, 1969, Iron and Steel, London: Longmans, p. 52.

LRD

Paxton, Sir Joseph

SUBJECT AREA: Architecture and building, Civil engineering

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b. 3 August 1801 Milton Bryant, Bedfordshire, England

d. 8 June 1865 Sydenham, London, England

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English designer of the Crystal Palace, the first large-scale prefabricated ferrovitreous structure.

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The son of a farmer, he had worked in gardens since boyhood and at the age of 21 was employed as Undergardener at the Horticultural Society Gardens in Chiswick, from where he went on to become Head Gardener for the Duke of Devonshire at Chatsworth. It was there that he developed his methods of glasshouse construction, culminating in the Great Conservatory of 1836–40, an immense structure some 277 ft (84.4 m) long, 123 ft (37.5 m) wide and 67 ft (20.4 m) high. Its framework was of iron and its roof of glass, with wood to contain the glass panels; it is now demolished. Paxton went on to landscape garden design, fountain and waterway engineering, the laying out of the model village of Edensor, and to play a part in railway and country house projects.

The structure that made Paxton a household name was erected in Hyde Park, London, to house the Great Exhibition of 1851 and was aptly dubbed, by Punch, the Crystal Palace. The idea of holding an international exhibition for industry had been mooted in 1849 and was backed by Prince Albert and Henry Cole. The money for this was to be raised by public subscription and 245 designs were entered into a competition held in 1850; however, most of the concepts, received from many notable architects and engineers, were very costly and unsuitable, and none were accepted. That same year, Paxton published his scheme in the Illustrated London News and it was approved after it received over-whelming public support.

Paxton's Crystal Palace, designed and erected in association with the engineers Fox and Henderson, was a prefabricated glasshouse of vast dimensions: it was 1,848 ft (563.3 m) long, 408 ft (124.4 m) wide and over 100 ft (30.5 m) high. It contained 3,300 iron columns, 2,150 girders. 24 miles (39 km) of guttering, 600,000 ft3 (17,000 m³) of timber and 900,000 ft2 (84,000 m) of sheet glass made by Chance Bros, of Birmingham. One of the chief reasons why it was accepted by the Royal Commission Committee was that it fulfilled the competition proviso that it should be capable of being erected quickly and subsequently dismantled and re-erected elsewhere. The Crystal Palace was to be erected at a cost of £79,800, much less than the other designs. Building began on 30 July 1850, with a labour force of some 2,000, and was completed on 31 March 1851. It was a landmark in construction at the time, for its size, speed of construction and its non-eclectic design, and, most of all, as the first great prefabricated building: parts were standardized and made in quantity, and were assembled on site. The exhibition was opened by Queen Victoria on 1 May 1851 and had received six million visitors when it closed on 11 October. The building was dismantled in 1852 and reassembled, with variations in design, at Sydenham in south London, where it remained until its spectacular conflagration in 1936.

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Principal Honours and Distinctions

Knighted 1851. MP for Coventry 1854–65. Fellow Linnaean Society 1853; Horticultural Society 1826. Order of St Vladimir, Russia, 1844.

Further Reading

P.Beaver, 1986, The Crystal Palace: A Portrait of Victorian Enterprise, Phillimore. George F.Chadwick, 1961, Works of Sir Joseph Paxton 1803–1865, Architectural Press.

DY

Pierce, John Robinson

SUBJECT AREA: Aerospace, Electronics and information technology, Telecommunications

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b. 27 March 1910 Des Moines, Iowa, USA

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American scientist and communications engineer said to be the "father" of communication satellites.

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From his high-school days, Pierce showed an interest in science and in science fiction, writing under the pseudonym of J.J.Coupling. After gaining Bachelor's, Master's and PhD degrees at the California Institute of Technology (CalTech) in Pasadena in 1933, 1934 and 1936, respectively, Pierce joined the Bell Telephone Laboratories in New York City in 1936. There he worked on improvements to the travelling-wave tube, in which the passage of a beam of electrons through a helical transmission line at around 7 per cent of the speed of light was made to provide amplification at 860 MHz. He also devised a new form of electrostatically focused electron-multiplier which formed the basis of a sensitive detector of radiation. However, his main contribution to electronics at this time was the invention of the Pierce electron gun—a method of producing a high-density electron beam. In the Second World War he worked with McNally and Shepherd on the development of a low-voltage reflex klystron oscillator that was applied to military radar equipment.

In 1952 he became Director of Electronic Research at the Bell Laboratories' establishment, Murray Hill, New Jersey. Within two years he had begun work on the possibility of round-the-world relay of signals by means of communication satellites, an idea anticipated in his early science-fiction writings (and by Arthur C. Clarke in 1945), and in 1955 he published a paper in which he examined various possibilities for communications satellites, including passive and active satellites in synchronous and non-synchronous orbits. In 1960 he used the National Aeronautics and Space Administration 30 m (98 1/2 ft) diameter, aluminium-coated Echo 1 balloon satellite to reflect telephone signals back to earth. The success of this led to the launching in 1962 of the first active relay satellite (Telstar), which weighed 170 lb (77 kg) and contained solar-powered rechargeable batteries, 1,000 transistors and a travelling-wave tube capable of amplifying the signal 10,000 times. With a maximum orbital height of 3,500 miles (5,600 km), this enabled a variety of signals, including full bandwidth television, to be relayed from the USA to large receiving dishes in Europe.

From 1971 until his "retirement" in 1979, Pierce was Professor of Electrical Engineering at CalTech, after which he became Chief Technologist at the Jet Propulsion Laboratories, also in Pasadena, and Emeritus Professor of Engineering at Stanford University.

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Principal Honours and Distinctions

Institute of Electrical and Electronics Engineers Morris N.Liebmann Memorial Award 1947; Edison Medal 1963; Medal of Honour 1975. Franklin Institute Stuart Ballantine Award 1960. National Medal of Science 1963. Danish Academy of Science Valdemar Poulsen Medal 1963. Marconi Award 1974. National Academy of Engineering Founders Award 1977. Japan Prize 1985. Arthur C.Clarke Award 1987. Honorary DEng Newark College of Engineering 1961. Honorary DSc Northwest University 1961, Yale 1963, Brooklyn Polytechnic Institute 1963. Editor, Proceedings of the Institute of Radio Engineers 1954–5.

Bibliography

23 October 1956, US patent no. 2,768,328 (his development of the travelling-wave tube, filed on 5 November 1946).

1947, with L.M.Field, "Travelling wave tubes", Proceedings of the Institute of Radio

Engineers 35:108 (describes the pioneering improvements to the travelling-wave tube). 1947, "Theory of the beam-type travelling wave tube", Proceedings of the Institution of

Radio Engineers 35:111. 1950, Travelling Wave Tubes.

1956, Electronic Waves and Messages. 1962, Symbols, Signals and Noise.

1981, An Introduction to Information Theory: Symbols, Signals and Noise: Dover Publications.

1990, with M.A.Knoll, Signals: Revolution in Electronic Communication: W.H.Freeman.

KF

Pretsch, Paul

SUBJECT AREA: Paper and printing, Photography, film and optics

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b. 1808 Vienna, Austria

d. 1873 Vienna, Austria

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Austrian printer and inventor of photogalvanography, one of the earliest commercial photomechanical printing processes.

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The son of a goldsmith, Pretsch learned the printing trade in Vienna, where he worked until 1831. He then took up a series of posts in Germany, Belgium and Holland before returning to Vienna, where in 1842 he joined the Imperial State Printing Office. The office was equipped with a photographic studio, and Pretsch was encouraged to explore applications of photography to printing and the graphic arts. In 1851 he was sent to London to take responsibility for the Austrian printing exhibits of the Great Exhibition. This event proved to be a significant international show case for photography and Pretsch saw a great number of recent innovations and made many useful contacts. On returning to Vienna, he began to develop a process for producing printing plates from photographs. Using Talbot's discovery that bichromated gelatine swells in water after exposure to light, he electrotyped the relief image obtained. In 1854 Pretsch resigned from his post in Vienna and travelled back to London, where he patented his process, calling it photogalvanography. He went on to form a business, the Photo-Galvano-Graphic Company, to print and market his pictures.

The Photographic Manager of the company was the celebrated photographer Roger Fenton, recently returned from his exploits on the battlefields of the Crimea. In 1856 the company issued a large serial work, Photographic Art Treasures, illustrated with Pretsch's pictures, which created considerable interest. The venture did not prove a commercial success, however, and although further plates were made and issued, Fenton found other interests to pursue and Pretsch was left to try to apply some of his ideas to lithography. This too had no successful outcome, and in 1863 Pretsch returned to Vienna. He was reappointed to a post at the Imperial State Printing Office, but his health failed and he made no further progress with his processes.

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Bibliography

9 November 1854, British patent no. 2,373. 11 August 1855, British patent no. 1,824.

Further Reading

J.M.Eder, 1945, History of Photography, trans. E. Epstean, New York.

H.Gernsheim and A.Gernsheim, 1969, The History of Photography, rev. edn, London. H.J.P.Arnold, 1977, William Henry Fox Talbot, London (an account of the relationship with Talbot's process).

JW

Renard, Charles

SUBJECT AREA: Aerospace

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b. 23 November 1847 Damblain, Vosges, France

d. 13 April 1905 Chalais-Meudon, France

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French pioneer of military aeronautics who, with A.C.Krebs, built an airship powered by an electric motor.

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Charles Renard was a French army officer with an interest in aviation. In 1873 he constructed an unusual unmanned glider with ten wings and an automatic stabilizing device to control rolling. This operated by means of a pendulum device linked to moving control surfaces. The model was launched from a tower near Arras, but unfortunately it spiralled into the ground. The control surfaces could not cope with the basic instability of the design, but as an idea for automatic flight control it was ahead of its time.

Following a Commission report on the military use of balloons, carrier pigeons and an optical telegraph, an aeronautical establishment was set up in 1877 at Chalais-Meudon, near Paris, under the direction of Charles Renard, who was assisted by his brother Paul. The following year Renard and a colleague, Arthur Krebs, began to plan an airship. They received financial help from Léon Gambetta, a prominent politician who had escaped from Paris by balloon in 1870 during the siege by the Prussians. Renard and Krebs studied earlier airship designs: they used the outside shape of Paul Haenlein's gas-engined airship of 1872 and included Meusnier's internal air-filled ballonnets. The gas-engine had not been a success so they decided on an electric motor. Renard developed lightweight pile batteries while Krebs designed a motor, although this was later replaced by a more powerful Gramme motor of 6.5 kW (9 hp). La France was constructed at Chalais-Meudon and, after a two-month wait for calm conditions, the airship finally ascended on 9 August 1884. The motor was switched on and the flight began. Renard and Krebs found their airship handled well and after twenty-three minutes they landed back at their base. La, France made several successful flights, but its speed of only 24 km/h (15 mph) meant that flights could be made only in calm weather. Parts of La, France, including the electric motor, are preserved in the Musée de l'Air in Paris.

Renard remained in charge of the establishment at Chalais-Meudon until his death. Among other things, he developed the "Train Renard", a train of articulated road vehicles for military and civil use, of which a number were built between 1903 and 1911. Towards the end of his life Renard became interested in helicopters, and in 1904 he built a large twin-rotor model which, however, failed to take off.

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Bibliography

1886, Le Ballon dirigeable La France, Paris (a description of the airship).

Further Reading

Descriptions of Renard and Kreb's airship are given in most books on the history of lighter-than-air flight, e.g.

L.T.C.Rolt, 1966, The Aeronauts, London; pub. in paperback 1985.

C.Bailleux, c. 1988, Association pour l'Histoire de l'Electricité en France, (a detailed account of the conception and operations of La France).

1977, Centenaire de la recherche aéronautique à Chalais-Meudon, Paris (an official memoir on the work of Chalais-Meudon with a chapter on Renard).

JDS

Roebuck, John

SUBJECT AREA: Chemical technology

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b. 1718 Sheffield, England

d. 17 July 1794

[br]

English chemist and manufacturer, inventor of the lead-chamber process for sulphuric acid.

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The son of a prosperous Sheffield manufacturer, Roebuck forsook the family business to pursue studies in medicine at Edinburgh University. There he met Dr Joseph Black (1727–99), celebrated Professor of Chemistry, who aroused in Roebuck a lasting interest in chemistry. Roebuck continued his studies at Leyden, where he took his medical degree in 1742. He set up in practice in Birmingham, but in his spare time he continued chemical experiments that might help local industries.

Among his early achievements was his new method of refining gold and silver. Success led to the setting up of a large laboratory and a reputation as a chemical consultant. It was at this time that Roebuck devised an improved way of making sulphuric acid. This vital substance was then made by burning sulphur and nitre (potassium nitrate) over water in a glass globe. The scale of the process was limited by the fragility of the glass. Roebuck substituted "lead chambers", or vessels consisting of sheets of lead, a metal both cheap and resistant to acids, set in wooden frames. After the first plant was set up in 1746, productivity rose and the price of sulphuric acid fell sharply. Success encouraged Roebuck to establish a second, larger plant at Prestonpans, near Edinburgh. He preferred to rely on secrecy rather than patents to preserve his monopoly, but a departing employee took the secret with him and the process spread rapidly in England and on the European continent. It remained the standard process until it was superseded by the contact process towards the end of the nineteenth century. Roebuck next turned his attention to ironmaking and finally selected a site on the Carron river, near Falkirk in Scotland, where the raw materials and water power and transport lay close at hand. The Carron ironworks began producing iron in 1760 and became one of the great names in the history of ironmaking. Roebuck was an early proponent of the smelting of iron with coke, pioneered by Abraham Darby at Coalbrookdale. To supply the stronger blast required, Roebuck consulted John Smeaton, who c. 1760 installed the first blowing cylinders of any size.

All had so far gone well for Roebuck, but he now leased coal-mines and salt-works from the Duke of Hamilton's lands at Borrowstonness in Linlithgow. The coal workings were plagued with flooding which the existing Newcomen engines were unable to overcome. Through his friendship with Joseph Black, patron of James Watt, Roebuck persuaded Watt to join him to apply his improved steam-engine to the flooded mine. He took over Black's loan to Watt of £1,200, helped him to obtain the first steam-engine patent of 1769 and took a two-thirds interest in the project. However, the new engine was not yet equal to the task and the debts mounted. To satisfy his creditors, Roebuck had to dispose of his capital in his various ventures. One creditor was Matthew Boulton, who accepted Roebuck's two-thirds share in Watt's steam-engine, rather than claim payment from his depleted estate, thus initiating a famous partnership. Roebuck was retained to manage Borrowstonness and allowed an annuity for his continued support until his death in 1794.

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Further Reading

Memoir of John Roebuck in J.Roy. Soc. Edin., vol. 4 (1798), pp. 65–87.

S.Gregory, 1987, "John Roebuck, 18th century entrepreneur", Chem. Engr. 443:28–31.

LRD

Ross, Andrew

SUBJECT AREA: Photography, film and optics

[br]

b. 1798 London, England d. 1859

[br]

English optical-instrument maker, founder of a photographic-lens making dynasty.

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Apprenticed to the optical-instrument maker Gilbert at the age of 14, Ross rose to become Manager of the factory before leaving to found his own business in 1830. He soon earned a reputation for fine craftsmanship and was the first optician in England to produce achromatic microscope objectives. He had an early involvement with photography, perhaps before the public announcements in 1839, for he supplied lenses and instruments to Talbot. On hearing of Petzval's portrait lens, he made a highaperture portrait lens to his own design for the first professional calotypist, Henry Collan. It was unsuccessful, however, and Ross did little more photographic work of note, although his son Thomas and his son-in-law and one-time apprentice, John Henry Dallmeyer, made significant contributions to English photographic optics. Both Thomas and Dallmeyer were left large sums of money on Andrew's death, and independently they established successful businesses; they were to become the two most important suppliers of photographic lenses in England.

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Further Reading

Rudolf Kingslake, 1989, A History of the Photographic Lens, Boston (a brief biography of Ross).

J.M.Eder, 1945, History of Photography, trans. E.Epstean, New York.

H.J.P.Arnold, 1977, William Henry Fox Talbot, London.

JW

Ruggles, Stephen

SUBJECT AREA: Paper and printing

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fl. 1820s-1850s Boston, Massachusetts, USA

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American maker of the first successful jobbing platen press.

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Ruggles, a Bostonian, made a cylinder press in 1827 and also a card press, but neither was manufactured. In 1839 he completed his "Engine" press, the first self-inking, treadle-driven jobbing platen press. The machine presses that had been developed from Koenig and Bauer c. 1810 were suitable for large-scale printing but less so for the small miscellaneous work of the jobbing printer. For these needs, the bed and platen press was developed. The bed (carrying the type) and the platen (which pressed the paper onto the inked type) were pivoted and brought together like the jaws of a nutcracker instead of moving on a separate carriage. With automatic inking and treadle operation, the press offered a rapid and simple action for the small printer. In Ruggles's first press of this kind, the bed and platen were still horizontal, the bed being uppermost. If the type became loose, however, it fell onto the platen, so in 1851 Ruggles constructed a new version in which bed and platen were vertical. Later designers modified the form of the press, but it was the Ruggles that opened up a new era for the jobbing printer.

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Further Reading

J.Moran, 1973, Printing Presses, London: Faber \& Faber (provides details of Ruggles's machines).

LRD

Santos-Dumont, Alberto

SUBJECT AREA: Aerospace

[br]

b. 20 July 1873 Cabangu, Rocha Dias, Brazil

d. 23 July 1932 d. Santos, Sâo Paulo, Brazil

[br]

Brazilian pioneer in airship and aeroplane flights.

[br]

Alberto Santos-Dumont, the son of a wealthy Brazilian coffee planter, was sent to Paris to study engineering but developed a passion for flying. After several balloon flights he turned his attention to powered airships. His first small airship, powered by a motorcycle engine, flew in 1898. A series of airships followed and his flights over Paris—and his narrow escapes—generated much public interest. A large cash prize had been offered for the first person to fly from Saint-Cloud around the Eiffel Tower and back inside thirty minutes. Santos-Dumont made two attempts in his airship No. 5, but engine failures caused him to crash, once in a tree and once on a hotel roof. Undismayed, he prepared airship No. 6 and on 19 October 1901 he set out and rounded the Tower, only to suffer yet another engine failure. This time he managed to restart the engine and claim the prize. This flight created a sensation in Paris and beyond. Santos-Dumont continued to create news with a series of airship exploits, and by 1906 he had built a total of fourteen airships. In 1904 Santos-Dumont visited the United States and met Octave Chanute, who described to him the achievements of the Wright brothers. On his return to Paris he set about designing an aeroplane which was unlike any other aeroplane of the period. It had box-kite-like wings and tail, and flew tail-first (a canard) powered by an Antoinette engine at the rear. It was built for him by Gabriel Voisin and was known as the "14 bis" because it was air-tested suspended beneath airship No. 14. It made its first free take-off on 13 September 1906, and then a series of short hops, including one of 220 m (720 ft) which won Santos-Dumont an Aero-Club prize and recognition for the first aeroplane flight in Europe; indeed, it was the first officially witnessed aeroplane flight in the world. Santos-Dumont's most successful aeroplane was his No. 20 of 1909, known as the Demoiselle: a tiny machine popular with sporting pilots. About this time, however, Santos-Dumont became ill and had to abandon his aeronautical activities. Although he had not made any great technical breakthroughs, Santos-Dumont had played a major role in arousing public interest in flying.

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Principal Honours and Distinctions

Aéro Club de France Grand Prix de l'Aéronautique 1901. Chevalier de la Légion d'honneur 1904.

Bibliography

1904, Dans l'air, Paris; 1904, pub. as My Airships (repub. 1973, New York: Dover).

Further Reading

Peter Wykeham, 1962, Santos-Dumont, A Study in Obsession, London.

F.H.da Costa, c. 1971, Alberto Santos-Dumont, O Pai da Aviaçāo; pub. in English as

Alberto Santos Dumont, Father of Aviation, Rio de Janeiro.

JDS

Smith, Oberlin

SUBJECT AREA: Electronics and information technology, Recording

[br]

b. 22 March 1840 Cincinnati, Ohio, USA

d. 18 July 1926

[br]

American mechanical engineer, pioneer in experiments with magnetic recording.

[br]

Of English descent, Smith embarked on an education in mechanical engineering, graduating from West Jersey Academy, Bridgeton, New Jersey, in 1859. In 1863 he established a machine shop in Bridgeton, New Jersey, that became the Ferracute Machine Company in 1877, eventually specializing in the manufacture of presses for metalworking. He seems to have subscribed to design principles considered modern even in the 1990s, "always giving attention to the development of artistic form in combination with simplicity, and with massive strength where required" (bibliographic reference below). He was successful in his business, and developed and patented a large number of mechanical constructions.

Inspired by the advent of the phonograph of Edison, in 1878 Smith obtained the tin-foil mechanical phonograph, analysed its shortcomings and performed some experiments in magnetic recording. He filed a caveat in the US Patent Office in order to be protected while he "reduced the invention to practice". However, he did not follow this trail. When there was renewed interest in practical sound recording and reproduction in 1888 (the constructions of Berliner and Bell \& Tainter), Smith published an account of his experiments in the journal Electrical World. In a corrective letter three weeks later it is clear that he was aware of the physical requirements for the interaction between magnetic coil and magnetic medium, but his publications also indicate that he did not as such obtain reproduction of recorded sound.

Smith did not try to develop magnetic recording, but he felt it imperative that he be given credit for conceiving the idea of it. When accounts of Valdemar Poulsen's work were published in 1900, Smith attempted to prove some rights in the invention in the US Patent Office, but to no avail.

He was a highly respected member of both his community and engineering societies, and in later life became interested in the anti-slavery cause that had also been close to the heart of his parents, as well as in the YMCA movement and in women's suffrage.

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Bibliography

Apart from numerous technical papers, he wrote the book Press Working of Metals, 1896. His accounts on the magnetic recording experiments were "Some possible forms of phonograph", Electrical World (8 September 1888): 161 ff, and "Letter to the Editor", Electrical World (29 September 1888): 179.

Further Reading

F.K.Engel, 1990, Documents on the Invention of Magnetic Recording in 1878, New York: Audio Engineering Society, Reprint no. 2,914 (G2) (a good overview of the material collected by the Oberlin Smith Society, Bridgeton, New Jersey, in particular as regards the recording experiments; it is here that it is doubted that Valdemar Poulsen developed his ideas independently).

GB-N

Smith, Sir Francis Pettit

SUBJECT AREA: Ports and shipping

[br]

b. 9 February 1808 Copperhurst Farm, near Hythe, Kent, England

d. 12 February 1874 South Kensington, London, England

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English inventor of the screw propeller.

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Smith was the only son of Charles Smith, Postmaster at Hythe, and his wife Sarah (née Pettit). After education at a private school in Ashford, Kent, he took to farming, first on Romney Marsh, then at Hendon, Middlesex. As a boy, he showed much skill in the construction of model boats, especially in devising their means of propulsion. He maintained this interest into adult life and in 1835 he made a model propelled by a screw driven by a spring. This worked so well that he became convinced that the screw propeller offered a better method of propulsion than the paddle wheels that were then in general use. This notion so fired his enthusiasm that he virtually gave up farming to devote himself to perfecting his invention. The following year he produced a better model, which he successfully demonstrated to friends on his farm at Hendon and afterwards to the public at the Adelaide Gallery in London. On 31 May 1836 Smith was granted a patent for the propulsion of vessels by means of a screw.

The idea of screw propulsion was not new, however, for it had been mooted as early as the seventeenth century and since then several proposals had been advanced, but without successful practical application. Indeed, simultaneously but quite independently of Smith, the Swedish engineer John Ericsson had invented the ship's propeller and obtained a patent on 13 July 1836, just weeks after Smith. But Smith was completely unaware of this and pursued his own device in the belief that he was the sole inventor.

With some financial and technical backing, Smith was able to construct a 10 ton boat driven by a screw and powered by a steam engine of about 6 hp (4.5 kW). After showing it off to the public, Smith tried it out at sea, from Ramsgate round to Dover and Hythe, returning in stormy weather. The screw performed well in both calm and rough water. The engineering world seemed opposed to the new method of propulsion, but the Admiralty gave cautious encouragement in 1839 by ordering that the 237 ton Archimedes be equipped with a screw. It showed itself superior to the Vulcan, one of the fastest paddle-driven ships in the Navy. The ship was put through its paces in several ports, including Bristol, where Isambard Kingdom Brunel was constructing his Great Britain, the first large iron ocean-going vessel. Brunel was so impressed that he adapted his ship for screw propulsion.

Meanwhile, in spite of favourable reports, the Admiralty were dragging their feet and ordered further trials, fitting Smith's four-bladed propeller to the Rattler, then under construction and completed in 1844. The trials were a complete success and propelled their lordships of the Admiralty to a decision to equip twenty ships with screw propulsion, under Smith's supervision.

At last the superiority of screw propulsion was generally accepted and virtually universally adopted. Yet Smith gained little financial reward for his invention and in 1850 he retired to Guernsey to resume his farming life. In 1860 financial pressures compelled him to accept the position of Curator of Patent Models at the Patent Museum in South Kensington, London, a post he held until his death. Belated recognition by the Government, then headed by Lord Palmerston, came in 1855 with the grant of an annual pension of £200. Two years later Smith received unofficial recognition when he was presented with a national testimonial, consisting of a service of plate and nearly £3,000 in cash subscribed largely by the shipbuilding and engineering community. Finally, in 1871 Smith was honoured with a knighthood.

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Principal Honours and Distinctions

Knighted 1871.

Further Reading

Obituary, 1874, Illustrated London News (7 February).

1856, On the Invention and Progress of the Screw Propeller, London (provides biographical details).

Smith and his invention are referred to in papers in Transactions of the Newcomen Society, 14 (1934): 9; 19 (1939): 145–8, 155–7, 161–4, 237–9.

LRD

Stanier, Sir William Arthur

SUBJECT AREA: Land transport, Railways and locomotives

[br]

b. 27 May 1876 Swindon, England

d. 27 September 1965 London, England

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

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

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

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Principal Honours and Distinctions

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

Bibliography

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

Further Reading

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

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

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

PJGR

Taylor, Frederick Winslow

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 20 March 1856 Germantown, Pennsylvania, USA

d. 21 March 1915 Philadelphia, Pennsylvania, USA

[br]

American mechanical engineer and pioneer of scientific management.

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Frederick W.Taylor received his early education from his mother, followed by some years of schooling in France and Germany. Then in 1872 he entered Phillips Exeter Academy, New Hampshire, to prepare for Harvard Law School, as it was intended that he should follow his father's profession. However, in 1874 he had to abandon his studies because of poor eyesight, and he began an apprenticeship at a pump-manufacturing works in Philadelphia learning the trades of pattern-maker and machinist. On its completion in 1878 he joined the Midvale Steel Company, at first as a labourer but then as Shop Clerk and Foreman, finally becoming Chief Engineer in 1884. At the same time he was able to resume study in the evenings at the Stevens Institute of Technology, and in 1883 he obtained the degree of Mechanical Engineer (ME). He also found time to take part in amateur sport and in 1881 he won the tennis doubles championship of the United States.

It was while with the Midvale Steel Company that Taylor began the systematic study of workshop management, and the application of his techniques produced significant increases in the company's output and productivity. In 1890 he became Manager of a company operating large paper mills in Maine and Wisconsin, until 1893 when he set up on his own account as a consulting engineer specializing in management organization. In 1898 he was retained exclusively by the Bethlehem Steel Company, and there continued his work on the metal-cutting process that he had started at Midvale. In collaboration with J.Maunsel White (1856–1912) he developed high-speed tool steels and their heat treatment which increased cutting capacity by up to 300 per cent. He resigned from the Bethlehem Steel Company in 1901 and devoted the remainder of his life to expounding the principles of scientific management which became known as "Taylorism". The Society to Promote the Science of Management was established in 1911, renamed the Taylor Society after his death. He was an active member of the American Society of Mechanical Engineers and was its President in 1906; his presidential address "On the Art of Cutting Metals" was reprinted in book form.

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Principal Honours and Distinctions

Paris Exposition Gold Medal 1900. Franklin Institute Elliott Cresson Gold Medal 1900. President, American Society of Mechanical Engineers 1906. Hon. ScD, University of Pennsylvania 1906. Hon. LLD, Hobart College 1912.

Bibliography

F.W.Taylor was the author of about 100 patents, several papers to the American Society of Mechanical Engineers, On the Art of Cutting Metals (1907, New York) and The Principles of Scientific Management (1911, New York) and, with S.E.Thompson, 1905 A Treatise on Concrete, New York, and Concrete Costs, 1912, New York.

Further Reading

The standard biography is Frank B.Copley, 1923, Frederick W.Taylor, Father of Scientific Management, New York (reprinted 1969, New York) and there have been numerous commentaries on his work: see, for example, Daniel Nelson, 1980, Frederick W.Taylor and the Rise of Scientific Management, Madison, Wis.

RTS

Treadgold, Arthur Newton Christian

SUBJECT AREA: Mining and extraction technology

[br]

b. August 1863 Woolsthorpe, Grantham, Lincolnshire, England

d. 23 March 1951 London, England

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English organizer of the Yukon gold fields in Canada, who introduced hydraulic mining.

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A direct descendant of Sir Isaac Newton, Treadgold worked as a schoolmaster, mostly at Bath College, for eleven years after completing his studies at Oxford University. He gained a reputation as an energetic teacher who devoted much of his work to sport, but he resigned his post and returned to Oxford; here, in 1897, he learned of the gold rush in the Klondike in the Canadian northwest. With a view to making his own fortune, he took a course in geology at the London Geological College and in 1898 set off for Dawson City, in the Yukon Territory. Working as a correspondent for two English newspapers, he studied thoroughly the situation there; he decided to join the stampede, but as a rather sophisticated gold hustler.

As there were limited water resources for sluicing or dredging, and underground mining methods were too expensive, Treadgold conceived the idea of hydraulic mining. He designed a ditch-and-siphon system for bringing large amounts of water down from the mountains; in 1901, after three years of negotiation with the Canadian government in Ottawa, he obtained permission to set up the Treadgold Concession to cover the water supply to the Klondike mining claims. This enabled him to supply giant water cannons which battered the hillsides, breaking up the gravel which was then sluiced. Massive protests by the individual miners in the Dawson City region, which he had overrun with his system, led to the concession being rescinded in 1904. Two years later, however, Treadgold began again, forming the Yukon Gold Company, initially in partnership with Solomon Guggenheim; he started work on a channel, completed in 1910, to carry water over a distance of 115 km (70 miles) down to Bonanza Creek. In 1919 he founded the Granville Mining Company, which was to give him control of all the gold-mining operations in the southern Klondike region. When he returned to London in the following year, the company began to fail, and in 1920 he went bankrupt with liabilities totalling more than $2 million. After the Yukon Consolidated Gold Corporation had been formed in 1923, Treadgold returned to the Klondike in 1925 in order to acquire the assets of the operating companies; he gained control and personally supervised the operations. But the company drifted towards disaster, and in 1930 he was dismissed from active management and his shares were cancelled by the courts; he fought for their reinstatement right up until his death.

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Further Reading

L.Green, 1977, The Gold Hustlers, Anchorage, Alaska (describes this outstanding character and his unusual gold-prospecting career).

WK