conceived the idea of

concebir una idea

(v.) = conceive + idea

Ex. In 1894 two Belgians, Paul Otlet and Henri LaFontaine, conceived the idea of a 'universal index to recorded knowledge', to which people all over the world would contribute, and which would in its turn be available to all.

* * *

(v.) = conceive + idea

Ex: In 1894 two Belgians, Paul Otlet and Henri LaFontaine, conceived the idea of a 'universal index to recorded knowledge', to which people all over the world would contribute, and which would in its turn be available to all.

задумывать

•

The designer conceived the idea of a submarine with three pressure hulls.

* * *

Задумывать -- to conceive (об идее, конструкции); to design (планировать)

 A modification to enlarge the annulus for improved oil cooling has been conceived but not tested.

 These tests were designed to investigate the effect of applied force when the initial counterface roughness was relatively high.

задумывать

•

The designer conceived the idea of a submarine with three pressure hulls.

зараждам се

зародя се

be born, originate, come into existence/being

прен. arise

животът на земята се е зародил много отдавна life on the earth began a very long time ago

у него се зароди мисълта he conceived the idea

зараждащ се nascent, incipient, inceptive; in the making; growing

* * *

зара̀ждам се,

възвр. гл. be born, originate, engender; come into existence/being; прен. arise; emerge; животът на Земята се е зародил много отдавна life on the earth began a very long time ago; growing; у него се зароди мисълта he conceived the idea.

* * *

rise

Albert, Wilhelm August Julius

SUBJECT AREA: Mining and extraction technology

[br]

b. 24 January 1787 Hannover, Germany

d. 4 July 1846 Clausthal, Harz, Germany

[br]

German mining official, successful applier of wire cable.

[br]

After studying law at the University of Göttingen, Albert turned to the mining industry and in 1806 started his career in mining administration in the Harz district, where he became Chief Inspector of mines thirty years later. His influence on the organization of the mining industry was considerable and he contributed valuable ideas for the development of mining technology. For example, he initiated experiments with Reichenbach's water-column pump in Harz when it had been working successfully in the transportation of brine in Bavaria, and he encouraged Dörell to work on his miner's elevator.

The increasing depths of shafts in the Harz district brought problems with hoisting as the ropes became too heavy and tended to break. At the beginning of the nineteenth century, iron link chains replaced the hempen ropes which were expensive and wore out too quickly, especially in the wet conditions in the shafts. After he had experimented for six years using counterbalancing iron link chains, which broke too easily, in 1834 he conceived the idea of producing stranded cables from iron wires. Their breaking strength and flexibility depended greatly on the softness of the iron and the way of laying the strands. Albert produced the cable by attaching the wires to strings which he turned evenly; this method became known as "Albert lay". He was not the first to conceive the idea of metal cables: there exists evidence for such cables as far back as Pompeii; Leonardo da Vinci made sketches of cables made from brass wires; and in 1780 the French engineer Reignier applied iron cables for lightning conductors. The idea also developed in various other mining areas, but Albert cables were the first to gain rapidly direct common usage worldwide.

[br]

Bibliography

1835, "Die Anfertigung von Treibseilen aus geflochtenem Eisendraht", Karstens Archiv 8: 418–28.

Further Reading

K.Karmarsch, "W.A.J.Albert", Allgemeine deutsche Biographie 1:212–3.

W.Bornhardt, 1934, W.A.J.Albert und die Erfindung der Eisendrahtseile, Berlin (a detailed description of his inventions, based on source material).

C.Bartels, 1992, Vom frühneuzeitlichen Montangewerbe zur Bergbauindustrie, Bochum: Deut sches Bergbau-Museum (evaluates his achievements within the framework of technological development in the Harz mining industry).

WK

Argand, François-Pierre Amis

SUBJECT AREA: Chemical technology, Domestic appliances and interiors, Public utilities

[br]

b. 5 July 1750 Geneva, Switzerland

d. October 1803 London, England

[br]

Swiss inventor of the Argand lamp.

[br]

Son of a clockmaker, he studied physics and chemistry under H.-D. de Saussure (1740– 99). In 1775 he moved to Paris, where he taught chemistry and presented a paper on electrical phenomena to the Académie Royale des Sciences. He assisted the Montgolfier brothers in their Paris balloon ascents.

From 1780 Argand spent some time in Montpellier, where he conceived the idea of the lamp that was to make him famous. It was an oil lamp with gravity oil feed, in which the flame was enlarged by burning it in a current of air induced by two concentric iron tubes. It produced ten times the illumination of the simple oil lamp. From the autumn of 1783 to summer 1785, Argand travelled to London and Birmingham to promote the manufacture and sale of his lamp. Upon his return to Paris, he found that his design had been plagiarized; with others, Argand sought to establish his priority, and Paul Abeille published a tract, Déscouverte des lampes à courant d'air et à cylindre (1785). As a result, the Académie granted Argand a licence to manufacture the lamp. However, during the Revolution, Argand's factories were destroyed and his licence annulled. He withdrew to Versoix, near Geneva. In 1793, the English persuaded him to take refuge in England and tried, apparently without success, to obtain recompense for his losses.

Argand is also remembered for his work on distillation and on the water distributor or hydraulic ram, which was conceived with Joseph Montgolfier in 1797 and recognized by the grant of a patent in the same year.

[br]

Further Reading

M.Schroder, 1969, The Armand Burner: Its Origin and Development in France and England, 1781–1800, Odense University Press.

LRD

Babbage, Charles

SUBJECT AREA: Electronics and information technology

[br]

b. 26 December 1791 Walworth, Surrey, England

d. 18 October 1871 London, England

[br]

English mathematician who invented the forerunner of the modern computer.

[br]

Charles Babbage was the son of a banker, Benjamin Babbage, and was a sickly child who had a rather haphazard education at private schools near Exeter and later at Enfield. Even as a child, he was inordinately fond of algebra, which he taught himself. He was conversant with several advanced mathematical texts, so by the time he entered Trinity College, Cambridge, in 1811, he was ahead of his tutors. In his third year he moved to Peterhouse, whence he graduated in 1814, taking his MA in 1817. He first contributed to the Philosophical Transactions of the Royal Society in 1815, and was elected a fellow of that body in 1816. He was one of the founders of the Astronomical Society in 1820 and served in high office in it.

While he was still at Cambridge, in 1812, he had the first idea of calculating numerical tables by machinery. This was his first difference engine, which worked on the principle of repeatedly adding a common difference. He built a small model of an engine working on this principle between 1820 and 1822, and in July of the latter year he read an enthusiastically received note about it to the Astronomical Society. The following year he was awarded the Society's first gold medal. He submitted details of his invention to Sir Humphry Davy, President of the Royal Society; the Society reported favourably and the Government became interested, and following a meeting with the Chancellor of the Exchequer Babbage was awarded a grant of £1,500. Work proceeded and was carried on for four years under the direction of Joseph Clement.

In 1827 Babbage went abroad for a year on medical advice. There he studied foreign workshops and factories, and in 1832 he published his observations in On the Economy of Machinery and Manufactures. While abroad, he received the news that he had been appointed Lucasian Professor of Mathematics at Cambridge University. He held the Chair until 1839, although he neither resided in College nor gave any lectures. For this he was paid between £80 and £90 a year! Differences arose between Babbage and Clement. Manufacture was moved from Clement's works in Lambeth, London, to new, fireproof buildings specially erected by the Government near Babbage's house in Dorset Square, London. Clement made a large claim for compensation and, when it was refused, withdrew his workers as well as all the special tools he had made up for the job. No work was possible for the next fifteen months, during which Babbage conceived the idea of his "analytical engine". He approached the Government with this, but it was not until eight years later, in 1842, that he received the reply that the expense was considered too great for further backing and that the Government was abandoning the project. This was in spite of the demonstration and perfectly satisfactory operation of a small section of the analytical engine at the International Exhibition of 1862. It is said that the demands made on manufacture in the production of his engines had an appreciable influence in improving the standard of machine tools, whilst similar benefits accrued from his development of a system of notation for the movements of machine elements. His opposition to street organ-grinders was a notable eccentricity; he estimated that a quarter of his mental effort was wasted by the effect of noise on his concentration.

[br]

Principal Honours and Distinctions

FRS 1816. Astronomical Society Gold Medal 1823.

Bibliography

Babbage wrote eighty works, including: 1864, Passages from the Life of a Philosopher.

1832, On the Economy of Manufacture and Machinery.

July 1822, Letter to Sir Humphry Davy, PRS, on the Application of Machinery to the purpose of calculating and printing Mathematical Tables.

Further Reading

1961, Charles Babbage and His Calculating Engines: Selected Writings by Charles Babbage and Others, eds Philip and Emily Morrison, New York: Dover Publications.

IMcN

Kilby, Jack St Clair

SUBJECT AREA: Electronics and information technology

[br]

b. 8 November 1923 Jefferson City, Missouri, USA

[br]

American engineer who filed the first patents for micro-electronic (integrated) circuits.

[br]

Kilby spent most of his childhood in Great Bend, Kansas, where he often accompanied his father, an electrical power engineer, on his maintenance rounds. Working in the blizzard of 1937, his father borrowed a "ham" radio, and this fired Jack to study for his amateur licence (W9GTY) and to construct his own equipment while still a student at Great Bend High School. In 1941 he entered the University of Illinois, but four months later, after the attack on Pearl Harbor, he was enlisted in the US Army and found himself working in a radio repair workshop in India. When the war ended he returned to his studies, obtaining his BSEE from Illinois in 1947 and his MSEE from the University of Wisconsin. He then joined Centralab, a small electronics firm in Milwaukee owned by Globe-Union. There he filed twelve patents, including some for reduced titanate capacitors and for Steatite-packing of transistors, and developed a transistorized hearing-aid. During this period he also attended a course on transistors at Bell Laboratories. In May 1958, concerned to gain experience in the field of number processing, he joined Texas Instruments in Dallas. Shortly afterwards, while working alone during the factory vacation, he conceived the idea of making monolithic, or integrated, circuits by diffusing impurities into a silicon substrate to create P-N junctions. Within less than a month he had produced a complete oscillator on a chip to prove that the technology was feasible, and the following year at the 1ERE Show he demonstrated a germanium integrated-circuit flip-flop. Initially he was granted a patent for the idea, but eventually, after protracted litigation, priority was awarded to Robert Noyce of Fairchild. In 1965 he was commissioned by Patrick Haggerty, the Chief Executive of Texas Instruments, to make a pocket calculator based on integrated circuits, and on 14 April 1971 the world's first such device, the Pocketronic, was launched onto the market. Costing $150 (and weighing some 2½ lb or 1.1 kg), it was an instant success and in 1972 some 5 million calculators were sold worldwide. He left Texas Instruments in November 1970 to become an independent consultant and inventor, working on, amongst other things, methods of deriving electricity from sunlight.

[br]

Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1966. Institute of Electrical and Electronics Engineers David Sarnoff Award 1966; Cledo Brunetti Award (jointly with Noyce) 1978; Medal of Honour 1986. National Academy of Engineering 1967. National Science Medal 1969. National Inventors Hall of Fame 1982. Honorary DEng Miami 1982, Rochester 1986. Honorary DSc Wisconsin 1988. Distinguished Professor, Texas A \& M University.

Bibliography

6 February 1959, US patent no. 3,138,743 (the first integrated circuit (IC); initially granted June 1964).

US patent no. 3,819,921 (the Pocketronic calculator).

Further Reading

T.R.Reid, 1984, Microchip. The Story of a Revolution and the Men Who Made It, London: Pan Books (for the background to the development of the integrated circuit). H.Queisser, 1988, Conquest of the Microchip, Cambridge, Mass.: Harvard University Press.

KF

Murdock (Murdoch), William

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

[br]

b. 21 August 1754 Cumnock, Ayrshire, Scotland

d. 15 November 1839 Handsworth, Birmingham, England

[br]

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

[br]

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

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

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

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

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

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

[br]

Principal Honours and Distinctions

Royal Society Rumford Gold Medal 1808.

Further Reading

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

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

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

IMcN

Pierce, George Washington

SUBJECT AREA: Electronics and information technology

[br]

b. 11 January 1872 Austin, Texas, USA

d. 25 August 1956 Franklin, New Hampshire, USA

[br]

American physicist who made various contributions to electronics, particularly crystal oscillators.

[br]

Pierce entered the University of Texas in 1890, gaining his BSc in physics in 1893 and his MSc in 1894. After teaching and doing various odd jobs, in 1897 he obtained a scholarship to Harvard, obtaining his PhD three years later. Following a period at the University of Leipzig, he returned to the USA in 1903 to join the teaching staff at Harvard, where he soon established new courses and began to gain a reputation as a pioneer in electronics, including the study of crystal rectifiers and publication of a textbook on wireless telegraphy. In 1912, with Kennelly, he conceived the idea of motional impedance. The same year he was made first Director of Harvard's Cruft High- Tension Electrical Laboratory, a post he held until his retirement. In 1917 he was appointed Professor of Physics, and for the remainder of the First World War he was also involved in work on submarine detection at the US Naval Base in New London. In 1921 he was appointed Rumford Professor of Physics and became interested in the work of Walter Cady on crystal-controlled circuits. As a result of this he patented the Pierce crystal oscillator in 1924. Having discovered the magnetostriction property of nickel and nichrome, in 1928 he also invented the magnetostriction oscillator. The mercury-vapour discharge lamp is also said to have been his idea. He became Gordon McKay Professor of Physics and Communications in 1935 and retired from Harvard in 1940, but he remained active for the rest of his life with the study of sound generation by birds and insects.

[br]

Principal Honours and Distinctions

President, Institute of Radio Engineers 1918–19. Institute of Electrical and Electronics Engineers Medal of Honour 1929.

Bibliography

1910, Principles of Wireless Telegraphy.

1914, US patent no. 1,450,749 (a mercury vapour tube control circuit). 1919, Electrical Oscillations and Electric Waves.

1922, "The piezo-electric Resonator", Proceedings of the Institute of Radio Engineers 10:83.

Further Reading

F.E.Terman, 1943, Radio Engineers'Handbook, New York: McGraw-Hill (for details of piezo-electric crystal oscillator circuits).

KF

приходить в голову

•

This is the first possibility that comes to mind.

•

It was then that they conceived the idea of forming...

•

This idea occurred to several investigators.

вознамериваться

несов. - вознаме́риваться, сов. - вознаме́риться; уст. и ирон. (+ инф.)

intend (+ to inf), make up one's mind (+ to inf), conceive the idea (of ger)

он вознаме́рился уе́хать — he took it into his head to leave

они́ вознаме́рились всех осчастли́вить — they conceived the idea of making everyone happy

Bell, Alexander Graham

SUBJECT AREA: Telecommunications

[br]

b. 3 March 1847 Edinburgh, Scotland

d. 3 August 1922 Beinn Bhreagh, Baddeck, Cape Breton Island, Nova Scotia, Canada

[br]

Scottish/American inventor of the telephone.

[br]

Bell's grandfather was a professor of elocution in London and his father an authority on the physiology of the voice and on elocution; Bell was to follow in their footsteps. He was educated in Edinburgh, leaving school at 13. In 1863 he went to Elgin, Morayshire, as a pupil teacher in elocution, with a year's break to study at Edinburgh University; it was in 1865, while still in Elgin, that he first conceived the idea of the electrical transmission of speech. He went as a master to Somersetshire College, Bath (now in Avon), and in 1867 he moved to London to assist his father, who had taken up the grandfather's work in elocution. In the same year, he matriculated at London University, studying anatomy and physiology, and also began teaching the deaf. He continued to pursue the studies that were to lead to the invention of the telephone. At this time he read Helmholtz's The Sensations of Tone, an important work on the theory of sound that was to exert a considerable influence on him.

In 1870 he accompanied his parents when they emigrated to Canada. His work for the deaf gained fame in both Canada and the USA, and in 1873 he was apponted professor of vocal physiology and the mechanics of speech at Boston University, Massachusetts. There, he continued to work on his theory that sound wave vibrations could be converted into a fluctuating electric current, be sent along a wire and then be converted back into sound waves by means of a receiver. He approached the problem from the background of the theory of sound and voice production rather than from that of electrical science, and by 1875 he had succeeded in constructing a rough model. On 7 March 1876 Bell spoke the famous command to his assistant, "Mr Watson, come here, I want you": this was the first time a human voice had been transmitted along a wire. Only three days earlier, Bell's first patent for the telephone had been granted. Almost simultaneously, but quite independently, Elisha Gray had achieved a similar result. After a period of litigation, the US Supreme Court awarded Bell priority, although Gray's device was technically superior.

In 1877, three years after becoming a naturalized US citizen, Bell married the deaf daughter of his first backer. In August of that year, they travelled to Europe to combine a honeymoon with promotion of the telephone. Bell's patent was possibly the most valuable ever issued, for it gave birth to what later became the world's largest private service organization, the Bell Telephone Company.

Bell had other scientific and technological interests: he made improvements in telegraphy and in Edison's gramophone, and he also developed a keen interest in aeronautics, working on Curtiss's flying machine. Bell founded the celebrated periodical Science.

[br]

Principal Honours and Distinctions

Legion of Honour; Hughes Medal, Royal Society, 1913.

Further Reading

Obituary, 7 August 1922, The Times. Dictionary of American Biography.

R.Burlingame, 1964, Out of Silence into Sound, London: Macmillan.

LRD

Cotton, William

SUBJECT AREA: Textiles

[br]

b. 1819 Seagrave, Leicestershire, England

d. after 1878

[br]

English inventor of a power-driven flat-bed knitting machine.

[br]

Cotton was originally employed in Loughborough and became one of the first specialized hosiery-machine builders. After the introduction of the latch needle by Matthew Townsend in 1856, knitting frames developed rapidly. The circular frame was easier to work automatically, but attempts to apply power to the flat frame, which could produce fully fashioned work, culminated in 1863 with William Cotton's machine. In that year he invented a machine that could make a dozen or more stockings or hose simultaneously and knit fashioned garments of all kinds. The difficulty was to reduce automatically the number of stitches in the courses where the hose or garment narrowed to give it shape. Cotton had early opportunities to apply himself to the improvement of hosiery machines while employed in the patent shop of Cartwright \& Warner of Loughborough, where some of the first rotaries were made. He remained with the firm for twenty years, during which time sixty or seventy of these machines were turned out. Cotton then established a factory for the manufacture of warp fabrics, and it was here that he began to work on his ideas. He had no knowledge of the principles of engineering or drawing, so his method of making sketches and then getting his ideas roughed out involved much useless labour. After twelve years, in 1863, a patent was issued for the machine that became the basis of the Cotton's Patent type. This was a flat frame driven by rotary mechanism and remarkable for its adaptability. At first he built his machine upright, like a cottage piano, but after much thought and experimentation he conceived the idea of turning the upper part down flat so that the needles were in a vertical position instead of being horizontal, and the work was carried off horizontally instead of vertically. His first machine produced four identical pieces simultaneously, but this number was soon increased. Cotton was induced by the success of his invention to begin machine building as a separate business and thus established one of the first of a class of engineering firms that sprung up as an adjunct to the new hosiery manufacture. He employed only a dozen men and turned out six machines in the first year, entering into an agreement with Hine \& Mundella for their exclusive use. This was later extended to the firm of I. \& R.Morley. In 1878, Cotton began to build on his own account, and the business steadily increased until it employed some 200 workers and had an output of 100 machines a year.

[br]

Bibliography

1863, British patent no. 1,901 (flat-frame knitting machine).

Further Reading

F.A.Wells, 1935, The British Hosiery and Knitwear Industry: Its History and Organisation, London (based on an article in the Knitters' Circular (Feb. 1898).

A brief account of the background to Cotton's invention can be found in T.K.Derry and T.I. Williams, 1960, A Short History of Technology from the Earliest Times to AD 1900, Oxford; C. Singer (ed.), 1958, A History of Technology, Vol. V, Oxford: Clarendon Press.

F.Moy Thomas, 1900, I. \& R.Morley. A Record of a Hundred Years, London (mentions cotton's first machines).

RLH

Koenig, Friedrich

SUBJECT AREA: Paper and printing

[br]

b. 17 April 1774 Eisleben, Thuringia, Germany

d. 17 January 1833 Oberzell, near Würzburg, Germany

[br]

German inventor of the machine printing press.

[br]

Koenig became a printer and bookseller. Around 1800 he was among those who conceived the idea of mechanizing the hand printing press, which apart from minor details had survived virtually unchanged through the first three and a half centuries of printing. In 1803, in Sühl, Saxony, he designed a press in which the flat forme, carrying the type, was mechanically inked and passed to and from the platen. Whether this ma-chine was ever constructed is not known, but Koenig found little support for his ideas because of lack of technical and financial resources. So, in 1806, he went to England and was introduced to Thomas Bensley, a book printer off Fleet Street in London. Bensley agreed to support Koenig and brought in two other printers to help finance Koenig's experiments. Another German, Andreas Bauer, an engineer, assisted Koenig and became largely responsible for the practical execution of Koenig's plans.

In 1810 they patented a press which was steam-driven but still used a platen. It was set to work in Bensley's office the following year but did not prove to be satisfactory. Koenig redesigned it, and in October 1811 he obtained a patent for a steam-driven press on an entirely new principle. In place of the platen, the paper was fixed around a hollow rotating cylinder, which impressed the paper on to the inked forme. In Bensley's office it was used for book printing, but its increased speed over the hand press appealed to newspaper proprietors and John Walter II of The Times asked Koenig to make a double-cylinder machine, so that the return stroke of the forme would be productive. A further patent was taken out in 1813 and the new machine was made ready to print the 29 November 1814 issue—in secrecy, behind closed doors, to forestall opposition from the pressmen working the hand presses. An important feature of the machine was that the inking rollers were not of the traditional leather or skin but a composite material made from glue, molasses and some soda. The inking could not have been achieved satisfactorily with the old materials. The editorial of that historic issue proclaimed, 'Our Journal of this day presents to the public the practical result of the greatest improvement connected with printing, since the discovery of the art itself Koenig's machine press could make 1,200 impressions an hour compared to 200 with the hand press; further improvements raised this figure to 1,500–2,000. Koenig's last English patent was in 1814 for an improved cylinder machine and a perfecting machine, which printed both sides of the paper. The steam-driven perfecting press was printing books in Bensley's office in February 1816. Koenig and Bauer wanted by that time to manufacture machine presses for other customers, but Bensley, now the principal shareholder, insisted that they should make machines for his benefit only. Finding this restriction intolerable, Koenig and Bauer returned to Germany: they became partners in a factory at Oberzell, near Würzburg, in 1817 and the firm of Koenig and Bauer flourishes there to this day.

[br]

Further Reading

J.Moran, 1973, Printing Presses, London: Faber \& Faber.

T.Goebel, 1956, Friedrich Koenig und die Erfindung der Schnellpresse, Würzburg.

LRD

Koepe, Friedrich

SUBJECT AREA: Mining and extraction technology

[br]

b. 1 July 1835 Bergkamen, Westphalia, Germany

d. 12 September 1922 Bochum, Germany

[br]

German mining engineer, inventor of the friction winder for shaft hoisting.

[br]

After attending the School of Mines at Bochum, from 1862 he worked as an overseer in the coal-mining district of Ibbenbüren until he joined a mining company in the Ruhr area. There, as head of the machine shop, he was mainly concerned with sinking new shafts. In 1873 he became the Technical Director of the Hannover mine, near Bochum, which belonged to Krupp. When the shaft hoisting was to be extended to a lower level Koepe conceived the idea of applying a friction winder to the hoist instead of a drum, in order to save weight and costs. His method involved the use of an endless rope to which the cages were fixed without a safety catch. The rope passed over pulleys instead of coiling and uncoiling on a drum, and he consequently proposed to have the motor erected on top of the shaft rather than beside it, as had been the practice until then.

Koepe's innovation turned out to be highly effective for hoisting heavy loads from deep shafts and was still popular in many countries in the 1990s, although the Krupp company did not accept it for a long time. He had severe personal problems with the company, and as Krupp refused to have his system patented he had to take it out in his own name in 1877. However, Krupp did not pay for the extension of the patent, nor did they pass the dossiers over to him, so the patent expired two years later. It was not until 1888 that a hoisting engine equipped with a friction winder was erected for the first time in a head gear, above the new Hannover II shaft. The following year Koepe left the Krupp company and settled as a freelance consulting engineer in Bochum; he was successful in having his system introduced by other mining companies. Ironi-cally, in 1948 the world's first four-rope winding, based on his system, was installed at the Hannover mine.

[br]

Further Reading

For detailed biographical information and an assessment of his technological achievements see: H.Arnold and W.Kroker, 1977, "100 Jahre Schachtförderung nach dem System Koepe", Der Anschnitt 29:235–42.

F.Lange, 1952, Die Vierseilförderung, Essen.

WK

Lippman, Gabriel

SUBJECT AREA: Photography, film and optics

[br]

b. 16 August 1845 Hallerick, Luxembourg

d. 14 July 1921 at sea, in the North Atlantic

[br]

French physicist who developed interference colour photography.

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Born of French parents, Lippman's work began with a distinguished career in classics, philosophy, mathematics and physics at the Ecole Normale in Luxembourg. After further studies in physics at Heidelberg University, he returned to France and the Sorbonne, where he was in 1886 appointed Director of Physics. He was a leading pioneer in France of research into electricity, optics, heat and other branches of physics.

In 1886 he conceived the idea of recording the existence of standing waves in light when it is reflected back on itself, by photographing the colours so produced. This required the production of a photographic emulsion that was effectively grainless: the individual silver halide crystals had to be smaller than the shortest wavelength of light to be recorded. Lippman succeeded in this and in 1891 demonstrated his process. A glass plate was coated with a grainless emulsion and held in a special plate-holder, glass towards the lens. The back of the holder was filled with mercury, which provided a perfect reflector when in contact with the emulsion. The standing waves produced during the exposure formed laminae in the emulsion, with the number of laminae being determined by the wavelength of the incoming light at each point on the image. When the processed plate was viewed under the correct lighting conditions, a theoretically exact reproduction of the colours of the original subject could be seen. However, the Lippman process remained a beautiful scientific demonstration only, since the ultra-fine-grain emulsion was very slow, requiring exposure times of over 10,000 times that of conventional negative material. Any method of increasing the speed of the emulsion also increased the grain size and destroyed the conditions required for the process to work.

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Principal Honours and Distinctions

Royal Photographic Society Progress Medal 1897. Nobel Prize (for his work in interference colour photography) 1908.

Further Reading

J.S.Friedman, 1944, History of Colour Photography, Boston.

Brian Coe, 1978, Colour Photography: The First Hundred Years, London. Gert Koshofer, 1981, Farbfotografie, Vol. I, Munich.

BC

Mole, Lancelot de

SUBJECT AREA: Weapons and armour

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b. 13 March 1880 Adelaide, Australia

d. 6 May 1950 Sydney, Australia

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Australian engineer and early tank designer.

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De Mole's father was an architect and surveyor and he himself followed a similar avenue as a draughtsman working on mining, surveying and engineering projects in Australia. It was in 1911, while surveying in particularly rough terrain in Western Australia, that he first conceived the idea of the tank as a tracked, armoured vehicle capable of traversing the most difficult ground. He drew up detailed plans and submitted them to the War Office in London the following year, but although they were rejected, not all the plans were returned to him. When war broke out in 1914 he tried without success to interest the Australian authorities, even after he had constructed a model at their request. A further blow came in 1916, when the first tanks, built by the British, appeared on the battlefields of France and looked remarkably similar in design to his own. Believing that he could play a significant role in further tank development, but lacking the funds to travel to Britain, de Mole eventually succeeded, after an initial rejection by a medical board, in enlisting in the Australian Army, which got him to England at the beginning of 1918. He immediately took his model to the British Inventions Committee, who were sufficiently impressed to pass it to the Tank Board, who promptly mislaid it for six weeks. Meanwhile, in March 1918, Private de Mole was ordered to France and was unable to take matters further. On his return to England in early 1919 he made a formal claim for a reward for his invention, but this was turned down on the grounds that no direct link could be established between his design and the first tanks that were built. Even so, the Inventions Committee did authorize a sum of money to cover his expenses, and in 1920 de Mole was a made a Commander of the Order of the British Empire.

Returning to Australia, de Mole worked as an engineer in the design branch of the Sydney Water Board. He continued to invent, but none of his designs, which covered a wide range of items, were ever taken up.

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Principal Honours and Distinctions

CBE 1920.

Further Reading

Australian Dictionary of Biography, 1918, Vol. 8.

A.J.Smithers, 1986, A New Excalibur: The Development of the Tank 1909–1939, London: Leo Cooper (for illustrations of the model of his tank).

Mention of his invention is made in a number of books on the history of the tank.

CM

Robert, Nicolas Louis

SUBJECT AREA: Paper and printing

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b. 2 December 1761 Paris, France

d. 8 August 1828 Dreux, France

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French inventor of the papermaking machine.

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Robert was born into a prosperous family and received a fair education, after which he became a lawyer's clerk. In 1780, however, he enlisted in the Army and joined the artillery, serving with distinction in the West Indies, where he fought against the English. When dissatisfied with his prospects, Robert returned to Paris and obtained a post as proof-reader to the firm of printers and publishers owned by the Didot family. They were so impressed with his abilities that they promoted him, c. 1790, to "clerk inspector of workmen" at their paper mill at Essonnes, south of Paris, under the control of Didot St Leger.

It was there that Robert conceived the idea of a continuous papermaking machine. In 1797 he made a model of it and, after further models, he obtained a patent in 1798. The paper was formed on a continuously revolving wire gauze, from which the sheets were lifted off and hung up to dry. Didot was at first scathing, but he came round to encouraging Robert to make a success of the machine. However, they quarrelled over the financial arrangements and Robert left to try setting up his own mill near Rouen. He failed for lack of capital, and in 1800 he returned to Essonnes and sold his patent to Didot for part cash, part proceeds from the operation of the mill. Didot left for England to enlist capital and technical skills to exploit the invention, while Robert was left in charge at Essonnes. It was the Fourdrinier brothers and Bryan Donkin who developed the papermaking machine into a form in which it could succeed. Meanwhile the mill at Essonnes under Robert's direction had begun to falter and declined to the point where it had to be sold. He had never received the full return from the sale of his patent, but he managed to recover his rights in it. This profited him little, for Didot obtained a patent in France for the Fourdrinier machine and had two examples erected in 1814 and the following year, respectively, neatly side-tracking Robert, who was now without funds or position. To support himself and his family, Robert set up a primary school in Dreux and there passed his remaining years. Although it was the Fourdrinier papermaking machine that was generally adopted, it is Robert who deserves credit for the original initiative.

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Further Reading

R.H.Clapperton, 1967, The Papermaking Machine, Oxford: Pergamon Press, pp. 279–83 (provides a full description of Robert's invention and patent, together with a biography).

LRD

Seguin, Marc

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

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b. 20 April 1786 Annonay, Ardèche, France

d. 24 February 1875 Annonay, Ardèche, France

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French engineer, inventor of multi-tubular firetube boiler.

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

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

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Bibliography

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

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

Further Reading

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

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

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

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

PJGR