to+manufacture+an+invention

disclosure

n

1) раскрытие; разглашение

2) предоставление компанией сведений о своей деятельности

- fair disclosure
- disclosure of information
- disclosure of an invention
- disclosure of know-how
- disclosure of the process of manufacture
- disclosure of shareholding
- disclosure of specifications
- disclosure of the takeover bid
- disclosure of trade secrets
- prevent disclosure

Cuff

CUFF

Cuffs were originally formed by the turning back of the termination of the sleeves at the wrist, and are first visible in ladies' dresses in the 15th century. In the reign of Henry VIII " three yards of crimson cloth of gold damask" are allowed for " the edging, facing, and cuffs " of a gown for the queen. Ben Johnson in 1629 mentions " the cuffs of Flanders." It is not definite whether of Flemish fashion, or of Flemish material. The Low Countries were celebrated for the manufacture of linen, and Flanders disputes with Venice the invention of lace.

Flemish Lace

FLEMISH LACE

A point lace of fine quality formed by what is known as the Flemish stitch. Flanders and Italy dispute the invention of this pillow lace. Lace of home manufacture was worn in the Low Countries in the 15th century. Similar lace to the Flemish is made in England and called Trolly.

Ladder Tapes

LADDER TAPES

These are tapes used for Venetian window blinds, and up to about 1878 they were made by hand from two broad tapes with the narrow ones stitched on at the required distances. On January 25, 1869, a British patent was granted to the late James Carr, of Manchester, for an invention for manufacturing the complete ladder tape. Owing to the large demand, a licence was issued to a firm in the Midlands in 1874 to manufacture under Mr. Carr's patent. In 1878 Carl Vorwerk made a slight improvement to a part of the loom in which these ladder webs were then being made. The two broad outer tapes with the required number of narrow cross tapes, are woven together. The narrow tapes are placed alternately near to the left- and the right-hand edges of the broad tapes in order to leave a space for the cord which draws up the blind.

fabrication

fabrication [‚fæbrɪ'keɪʃən]

noun

(a) (manufacture) fabrication f; (production) production f

(b) (falsehood) fabrication f;

∎ it's pure fabrication c'est de la pure invention;

∎ a pure fabrication (lie) une histoire inventée de toutes pièces

Armstrong, Sir William George, Baron Armstrong of Cragside

SUBJECT AREA: Ports and shipping, Public utilities, Weapons and armour

[br]

b. 26 November 1810 Shieldfield, Newcastle upon Tyne, England

d. 27 December 1900 Cragside, Northumbria, England

[br]

English inventor, engineer and entrepreneur in hydraulic engineering, shipbuilding and the production of artillery.

[br]

The only son of a corn merchant, Alderman William Armstrong, he was educated at private schools in Newcastle and at Bishop Auckland Grammar School. He then became an articled clerk in the office of Armorer Donkin, a solicitor and a friend of his father. During a fishing trip he saw a water-wheel driven by an open stream to work a marble-cutting machine. He felt that its efficiency would be improved by introducing the water to the wheel in a pipe. He developed an interest in hydraulics and in electricity, and became a popular lecturer on these subjects. From 1838 he became friendly with Henry Watson of the High Bridge Works, Newcastle, and for six years he visited the Works almost daily, studying turret clocks, telescopes, papermaking machinery, surveying instruments and other equipment being produced. There he had built his first hydraulic machine, which generated 5 hp when run off the Newcastle town water-mains. He then designed and made a working model of a hydraulic crane, but it created little interest. In 1845, after he had served this rather unconventional apprenticeship at High Bridge Works, he was appointed Secretary of the newly formed Whittle Dene Water Company. The same year he proposed to the town council of Newcastle the conversion of one of the quayside cranes to his hydraulic operation which, if successful, should also be applied to a further four cranes. This was done by the Newcastle Cranage Company at High Bridge Works. In 1847 he gave up law and formed W.G.Armstrong \& Co. to manufacture hydraulic machinery in a works at Elswick. Orders for cranes, hoists, dock gates and bridges were obtained from mines; docks and railways.

Early in the Crimean War, the War Office asked him to design and make submarine mines to blow up ships that were sunk by the Russians to block the entrance to Sevastopol harbour. The mines were never used, but this set him thinking about military affairs and brought him many useful contacts at the War Office. Learning that two eighteen-pounder British guns had silenced a whole Russian battery but were too heavy to move over rough ground, he carried out a thorough investigation and proposed light field guns with rifled barrels to fire elongated lead projectiles rather than cast-iron balls. He delivered his first gun in 1855; it was built of a steel core and wound-iron wire jacket. The barrel was multi-grooved and the gun weighed a quarter of a ton and could fire a 3 lb (1.4 kg) projectile. This was considered too light and was sent back to the factory to be rebored to take a 5 lb (2.3 kg) shot. The gun was a complete success and Armstrong was then asked to design and produce an equally successful eighteen-pounder. In 1859 he was appointed Engineer of Rifled Ordnance and was knighted. However, there was considerable opposition from the notably conservative officers of the Army who resented the intrusion of this civilian engineer in their affairs. In 1862, contracts with the Elswick Ordnance Company were terminated, and the Government rejected breech-loading and went back to muzzle-loading. Armstrong resigned and concentrated on foreign sales, which were successful worldwide.

The search for a suitable proving ground for a 12-ton gun led to an interest in shipbuilding at Elswick from 1868. This necessitated the replacement of an earlier stone bridge with the hydraulically operated Tyne Swing Bridge, which weighed some 1450 tons and allowed a clear passage for shipping. Hydraulic equipment on warships became more complex and increasing quantities of it were made at the Elswick works, which also flourished with the reintroduction of the breech-loader in 1878. In 1884 an open-hearth acid steelworks was added to the Elswick facilities. In 1897 the firm merged with Sir Joseph Whitworth \& Co. to become Sir W.G.Armstrong Whitworth \& Co. After Armstrong's death a further merger with Vickers Ltd formed Vickers Armstrong Ltd.

In 1879 Armstrong took a great interest in Joseph Swan's invention of the incandescent electric light-bulb. He was one of those who formed the Swan Electric Light Company, opening a factory at South Benwell to make the bulbs. At Cragside, his mansion at Roth bury, he installed a water turbine and generator, making it one of the first houses in England to be lit by electricity.

Armstrong was a noted philanthropist, building houses for his workforce, and endowing schools, hospitals and parks. His last act of charity was to purchase Bamburgh Castle, Northumbria, in 1894, intending to turn it into a hospital or a convalescent home, but he did not live long enough to complete the work.

[br]

Principal Honours and Distinctions

Knighted 1859. FRS 1846. President, Institution of Mechanical Engineers; Institution of Civil Engineers; British Association for the Advancement of Science 1863. Baron Armstrong of Cragside 1887.

Further Reading

E.R.Jones, 1886, Heroes of Industry', London: Low.

D.J.Scott, 1962, A History of Vickers, London: Weidenfeld \& Nicolson.

IMcN

Benton, Linn Boyd

SUBJECT AREA: Paper and printing

[br]

b. 13 May 1844 Little Falls, New York, USA

d. 15 July 1932 Plainfield, New Jersey, USA

[br]

American typefounder, cutter and designer, inventor of the automatic punch-cutting machine.

[br]

Benton spent his childhood in Milwaukee and La Crosse, where he early showed a talent for mechanical invention. His father was a lawyer with an interest in newspapers and who acquired the Milwaukee Daily News. Benton became familiar with typesetting equipment in his father's newspaper office. He learned the printer's trade at another newspaper office, at La Crosse, and later worked as bookkeeper at a type foundry in Milwaukee. When that failed in 1873, Benton acquired the plant, and when he was joined by R.V.Waldo the firm became Benton, Waldo \& Co. Benton began learning and improving type-cutting practice. He first devised unit-width or "self-spacing" type which became popular with compositors, saving, it was reckoned, 20 per cent of their time. Meanwhile, Benton worked on a punch-cutting machine to speed up the process of cutting letters in the steel punches from which matrices or moulds were formed to enable type to be cast from molten metal. His first mechanical punch-cutter worked successfully in 1884. The third machine, patented in 1885, was the model that revolutionized the typefounding operation. So far, punch-cutting had been done by hand, a rare and expensive skill that was insufficient to meet the demands of the new typesetting machines, the monotype of Lanston and the linotype of Merganthaler. These were threatened with failure until Benton saved the day with his automatic punch-cutter. Mechanizing punch-cutting and the forming of matrices made possible the typesetting revolution brought about by mono-and linotype.

In 1892 Benton's firm merged with others to form the American Type Founders Company. Benton's equipment was moved to New York and he with it, to become a board member and Chief Technical Advisor. In 1894 he became Manager of the company's new plant for type manufacture in Jersey City. Benton steadily improved both machinery and processes, for which he was granted twenty patents. With his son Morris Fuller, he was also notable and prolific in the field of type design. Benton remained in active association with his company until just two weeks before his death.

[br]

Further Reading

Obituary, 1932, Inland Printer (August): 53–4.

P.Cost, 1985, "The contributions of Lyn [sic] Boyd Benton and Morris Fuller Benton to the technology of typesetting and the art of typeface design", unpublished MSc thesis, Rochester Institute of Technology (the most thorough treatment).

H.L.Bullen, 1922, Inland Printer (October) (describes Benton's life and work).

LRD

Benz, Karl

SUBJECT AREA: Automotive engineering, Land transport

[br]

b. 25 November 1844 Pfaffenrot, Black Forest, Germany

d. 4 April 1929 Ladenburg, near Mannheim, Germany

[br]

German inventor of one of the first motor cars.

[br]

The son of a railway mechanic, it is said that as a child one of his hobbies was the repair of Black Forest clocks. He trained as a mechanical engineer at the Karlsruhe Lyzeum and Polytechnikum under Ferdinand Redtenbacher (d. 1863), who pointed out to him the need for a more portable power source than the steam engine. He went to Maschinenbau Gesellschaft Karlsruhe for workshop experience and then joined Schweizer \& Cie, Mannheim, for two years. In 1868 he went to the Benkiser Brothers at Pforzheim. In 1871 he set up a small machine-tool works at Mannheim, but in 1877, in financial difficulties, he turned to the idea of an entirely new product based on the internal-combustion engine. At this time, N.A. Otto held the patent for the four-stroke internal-combustion engine, so Benz had to put his hopes on a two-stroke design. He avoided the trouble with Dugald Clerk's engine and designed one in which the fuel would not ignite in the pump and in which the cylinder was swept with fresh air between each two firing strokes. His first car had a sparking plug and coil ignition. By 1879 he had developed the engine to a stage where it would run satisfactorily with little attention. On 31 December 1879, with his wife Bertha working the treadle of her sewing machine to charge the batteries, he demonstrated his engine in street trials in Mannheim. In the summer of 1888, unknown to her husband, Bertha drove one of his cars the 80 km (50 miles) to Pforzheim and back with her two sons, aged 13 and 15. She and the elder boy pushed the car up hills while the younger one steered. They bought petrol from an apothecary in Wiesloch and had a brake block repaired in Bauschlott by the village cobbler. Karl Benz's comments on her return from this venture are not recorded! Financial problems prevented immediate commercial production of the automobile, but in 1882 Benz set up the Gasmotorenfabrik Mannheim. After trouble with some of his partners, he left in 1883 and formed a new company, Benz \& Cie, Rheinische Gasmotorenfabrik. Otto's patent was revoked in 1886 and in that year Benz patented a motor car with a gas engine drive. He manufactured a 0.8hp car, the engine running at 250 rpm with a horizontal flywheel, exhibited at the Paris Fair in 1889. He was not successful in finding anyone in France who would undertake manufacture. This first car was a three-wheeler, and soon after he produced a four-wheeled car, but he quarrelled with his co-directors, and although he left the board in 1902 he rejoined it soon after.

[br]

Further Reading

St J.Nixon, 1936, The Invention of the Automobile. E.Diesel et al., 1960, From Engines to Autos. E.Johnson, 1986, The Dawn of Motoring.

IMcN

Bessemer, Sir Henry

SUBJECT AREA: Metallurgy

[br]

b. 19 January 1813 Charlton (near Hitchin), Hertfordshire, England

d. 15 January 1898 Denmark Hill, London, England

[br]

English inventor of the Bessemer steelmaking process.

[br]

The most valuable part of Bessemer's education took place in the workshop of his inventor father. At the age of only 17 he went to London to seek his fortune and set himself up in the trade of casting art works in white metal. He went on to the embossing of metals and other materials and this led to his first major invention, whereby a date was incorporated in the die for embossing seals, thus preventing the wholesale forgeries that had previously been committed. For this, a grateful Government promised Bessemer a paid position, a promise that was never kept; recognition came only in 1879 with a belated knighthood. Bessemer turned to other inventions, mainly in metalworking, including a process for making bronze powder and gold paint. After he had overcome technical problems, the process became highly profitable, earning him a considerable income during the forty years it was in use.

The Crimean War presented inventors such as Bessemer with a challenge when weaknesses in the iron used to make the cannon became apparent. In 1856, at his Baxter House premises in St Paneras, London, he tried fusing cast iron with steel. Noticing the effect of an air current on the molten mixture, he constructed a reaction vessel or converter in which air was blown through molten cast iron. There was a vigorous reaction which nearly burned the house down, and Bessemer found the iron to be almost completely decarburized, without the slag threads always present in wrought iron. Bessemer had in fact invented not only a new process but a new material, mild steel. His paper "On the manufacture of malleable iron and steel without fuel" at the British Association meeting in Cheltenham later that year created a stir. Bessemer was courted by ironmasters to license the process. However, success was short-lived, for they found that phosphorus in the original iron ore passed into the metal and rendered it useless. By chance, Bessemer had used in his trials pig-iron, derived from haematite, a phosphorus-free ore. Bessemer tried hard to overcome the problem, but lacking chemical knowledge he resigned himself to limiting his process to this kind of pig-iron. This limitation was removed in 1879 by Sidney Gilchrist Thomas, who substituted a chemically basic lining in the converter in place of the acid lining used by Bessemer. This reacted with the phosphorus to form a substance that could be tapped off with the slag, leaving the steel free from this harmful element. Even so, the new material had begun to be applied in engineering, especially for railways. The open-hearth process developed by Siemens and the Martin brothers complemented rather than competed with Bessemer steel. The widespread use of the two processes had a revolutionary effect on mechanical and structural engineering and earned Bessemer around £1 million in royalties before the patents expired.

[br]

Principal Honours and Distinctions

Knighted 1879. FRS 1879. Royal Society of Arts Albert Gold Medal 1872.

Bibliography

1905, Sir Henry Bessemer FRS: An Autobiography, London.

LRD

Chubb, Charles

SUBJECT AREA: Domestic appliances and interiors

[br]

b. 1779 Fordingbridge, Hampshire, England

d. 16 May 1845 Islington, London, England.

[br]

English locksmith.

[br]

Both Charles Chubb and his younger brother Jeremiah served as apprentices to a blacksmith. The brothers were in business together in Daniel Street, Portsea, Hampshire, from 1804 until 1820, when Charles moved to London to establish the firm of Chubb \& Son. In 1818, Jeremiah Chubb had patented a detector lock; this invention proved to be the foundation of the later success of the firm of Chubb \& Son. Charles Chubb made improvements on this lock, for which he took out patents in 1824, 1828 and 1833. He also took out several patents for fireproof and burglarproof safes.

In the Portsea factory, at first there were only two or three employees engaged in lockmaking, but when Charles Chubb moved to London another twelve were taken on and thus things remained until 1830, when a factory was opened in Wolverhampton with up to two hundred employees. The manufacture of fireproof and burglarproof safes was carried out at a separate factory in London, which had up to one hundred and fifty employees. The two factories supplied nearly 1,500,000 patent locks and about 30,000 safes and strongrooms, costing between £8 and £5,000, the latter being the largest-ever safe supplied to a bank at that time.

See also: Chubb, John

IMcN

Davis, Robert Henry

SUBJECT AREA: Ports and shipping

[br]

b. 6 June 1870 London, England

d. 29 March 1965 Epsom, Surrey, England

[br]

English inventor of breathing, diving and escape apparatus.

[br]

Davis was the son of a detective with the City of London police. At the age of 11 he entered the employment of Siebe, Gorman \& Co., manufacturers of diving and other safety equipment since 1819, at their Lambeth works. By good fortune, his neat handwriting attracted the notice of Mr Gorman and he was transferred to work in the office. He studied hard after working hours and rose steadily in the firm. In his twenties he was promoted to Assistant Manager, then General Manager, Managing Director and finally Governing Director. He retired in 1960, having been made Life President the previous year, and continued to attend the office regularly until May 1964.

Davis's entire career was devoted to research and development in the firm's special field. In 1906 he perfected the first practicable oxygen-breathing apparatus for use in mine rescue; it was widely adopted and with modifications was still in use in the 1990s. With Professor Leonard Hill he designed a deep-sea diving-bell incorporating a decompression chamber. He also invented an oxygen-breathing apparatus and heated apparel for airmen flying at high altitudes.

Immediately after the first German gas attacks on the Western Front in April 1915, Davis devised a respirator, known as the stocking skene or veil mask. He quickly organized the mass manufacture of this device, roping in members of his family and placing the work in the homes of Lambeth: within 48 hours the first consignment was being sent off to France.

He was a member of the Admiralty Deep Sea Diving Committee, which in 1933 completed tables for the safe ascent of divers with oxygen from a depth of 300 ft (91 m). They were compiled by Davis in conjunction with Professors J.B.S.Haldane and Leonard Hill and Captain G.C.Damant, the Royal Navy's leading diving expert. With revisions these tables have been used by the Navy ever since. Davis's best-known invention was first used in 1929: the Davis Submarine Escape Apparatus. It became standard equipment on submarines until it was replaced by the Built-in Breathing System, which the firm began manufacturing in 1951.

The firm's works were bombed during the Second World War and were re-established at Chessington, Surrey. The extensive research facilities there were placed at the disposal of the Royal Navy and the Admiralty Experimental Diving Unit. Davis worked with Haldane and Hill on problems of the underwater physiology of working divers. A number of inventions issued from Chessington, such as the human torpedo, midget submarine and human minesweeper. In the early 1950s the firm helped to pioneer the use of underwater television to investigate the sinking of the submarine Affray and the crashed Comet jet airliners.

[br]

Principal Honours and Distinctions

Knighted 1932.

Bibliography

Davis was the author of several manuals on diving including Deep Sea Diving and Submarine Operations and Breathing in Irrespirable Atmospheres. He also wrote Resuscitation: A Brief Personal History of Siebe, Gorman \& Co. 1819–1957.

Further Reading

Obituary, 1965, The Times, 31 March, p. 16.

LRD

Donkin, Bryan I

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Paper and printing

[br]

b. 22 March 1768 Sandoe, Northumberland, England

d. 27 February 1855 London, England

[br]

English mechanical engineer and inventor.

[br]

It was intended that Bryan Donkin should follow his father's profession of surveyor and land agent, so he spent a year or so in that occupation before he was apprenticed to John Hall, millwright of Dartford, Kent. Donkin remained with the firm after completing his apprenticeship, and when the Fourdrinier brothers in 1802 introduced from France an invention for making paper in continuous lengths they turned to John Hall for help in developing the machine: Donkin was chosen to undertake the work. In 1803 the Fourdriniers established their own works in Bermondsey, with Bryan Donkin in charge. By 1808 Donkin had acquired the works, but he continued to manufacture paper-making machines, paying a royalty to the patentees. He also undertook other engineering work including water-wheels for driving paper and other mills. He was also involved in the development of printing machinery and the preservation of food in airtight containers. Some of these improvements were patented, and he also obtained patents relating to gearing, steel pens, paper-making and railway wheels. Other inventions of Bryan Donkin that were not patented concerned revolution counters and improvements in accurate screw threads for use in graduating mathematical scales. Donkin was elected a member of the Society of Arts in 1803 and was later Chairman of the Society's Committee of Mechanics and a Vice-President of the society. He was also a member of the Royal Astronomical Society. In 1818 a group of eight young men founded the Institution of Civil Engineers; two of them were apprentices of Bryan Donkin and he encouraged their enterprise. After a change in the rules permitted the election of members over the age of 35, he himself became a member in 1821. He served on the Council and became a Vice- President, but he resigned from the Institution in 1848.

[br]

Principal Honours and Distinctions

FRS 1838. Vice-President, Institution of Civil Engineers 1826–32, 1835–45. Member, Smeatonian Society of Civil Engineers 1835; President 1843. Society of Arts Gold Medal 1810, 1819.

Further Reading

S.B.Donkin, 1949–51, "Bryan Donkin, FRS, MICE 1768–1855", Transactions of the Newcomen Society 27:85–95.

RTS

Flügge-Lotz, Irmgard

SUBJECT AREA: Aerospace

[br]

b. 1903 Germany

d. 1974 USA

[br]

German/American aeronautical engineer, specializing inflight control.

[br]

Both her father, a mathematician, and her mother encouraged Flügge-Lotz in her desire, unusual for a woman at that time, for a technical education. Her interest in aeronautics was awakened when she was a child, by seeing zeppelins (see Zeppelin, Ferdinand, Count von) being tested. In 1923 she entered the Technische Hochschule in Hannover to study engineering, specializing in aeronautics; she was often the only woman in the class. She obtained her doctorate in 1929 and began working in aeronautics. Two years later she derived the Lotz Method for calculating the distribution in aircraft wings of different shapes, which became widely used. Later, Flügge-Lotz took up an interest in automatic flight control of aircraft, notably of the discontinuous or "on-off" type. These were simple in design, inexpensive to manufacture and reliable in operation. By 1928 she had risen to the position of head of the Department of Theoretical Aerodynamics at Göttingen University, but she and her husband, Wilhelm Flügge, an engineering academic known for his anti-Nazi views, felt themselves increasingly discriminated against by the Hitler regime. In 1948 they emigrated to the USA, where Flügge was soon offered a professorship in engineering, while his wife had at first to make do with a lectureship. But her distinguished work eventually earned her appointment as the first woman full professor in the Engineering Department at Stanford University.

She later extended her work on automatic flight control to the guidance of rockets and missiles, earning herself the description "a female Werner von Braun ".

[br]

Principal Honours and Distinctions

Society of Women Engineers Achievement Award 1970. Fellow, Institution of Aeronautics and Astronautics.

Bibliography

Flügge-Lotz was the author of two books on automatic control and over fifty scientific papers.

Further Reading

A.Stanley, 1993, Mothers and Daughters of Invention, Meruchen, NJ: Scarecrow Press, pp. 899–901.

LRD

Fox, James

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. c.1760

d. 1835 Derby, England

[br]

English machine-tool builder.

[br]

Very little is known about the life of James Fox, but according to Samuel Smiles (1863) he was as a young man a butler in the service of the Reverend Thomas Gisborne of Foxhall Lodge, Staffordshire. His mechanical abilities were evident from his spare-time activities in the handling of tools and so impressed his employer that he supplied the capital to enable Fox to set up a business in Derby for the manufacture of machinery for the textile and lacemaking industries. To construct this machinery, Fox had to build his own machine tools and later, in the early nineteenth century, made them for sale, some being exported to France, Germany and Poland. He was renowned for his lathes, some of which were quite large; one built in 1830 has been preserved and is 22 ft (6.7 m) long with a swing of 27 in. (69 cm). He was responsible for many improve-ments in the design of the lathe and he also built some of the earliest planing machines (the first, it has been claimed, as early as 1814) and a gear-cutting machine, although this was apparently for cutting wooden patterns for cast gears. The business was continued by his sons Joseph and James (who died in 1859 aged 69) and into the 1860s by the sons of Joseph.

[br]

Further Reading

S.Smiles, 1863, Industrial Biography, London, reprinted 1967, Newton Abbot (makes brief mention of Fox).

Letters relating to the invention of the planing machine can be found in Engineer 14 (1862): 189, 204, 219, 246 and 247.

His lathes are described in: R.S.Woodbury, 1961, History of the Lathe to 1850, Cleveland, Ohio; L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986; W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford.

RTS

Gillott, Joseph

SUBJECT AREA: Paper and printing

[br]

b. 1799 Sheffield, Yorkshire d. 1877

[br]

English maker of steel pens.

[br]

The name Joseph Gillott became synonymous with pen making at a time when the basic equipment for writing was undergoing a change. The quill pen had served writers for centuries, but attempts had been made since the seventeenth century to improve on it. The first major technical development was the steel nib, which began to be made c.1829. The steel nib was still little known in Birmingham in 1839, but ten years later it was in common use. Its stiffness was at first a drawback, but Gillott was among the first to improve its flexibility by introducing three slots, which later became standard practice. Mechanical methods of manufacture made the pen cheaper and improved its quality. In 1840 Gillott issued a "precept" informing the public that he was pen maker to the Queen and that he had been manufacturing pens for twenty years at his Victoria Works in Birmingham. He announced the successful reception by the public of his new patent pen. There were also special "warranted school" pens designed for the various grades of writing taught in schools. Finally, he warned against inferior imitations and recommended the public to buy only those pens stamped with his name.

[br]

Further Reading

J.T.Bunce and S.Timmins, c.1880 Joseph Gillott 1799–1877: A Sketch of His Life.

H.Bore, 1890, The Story of the Invention of the Steel Pen, London.

J.Whalley, 1975, Writing Implements and Accessories, Newton Abbot: David \& Charles.

LRD

Gramme, Zénobe Théophile

SUBJECT AREA: Electricity, Public utilities

[br]

b. 4 April 1826 Jehay-Bodignée, Belgium

d. 20 January 1901 Bois de Colombes, Paris, France

[br]

Belgian engineer whose improvements to the dynamo produced a machine ready for successful commercial exploitation.

[br]

Gramme trained as a carpenter and showed an early talent for working with machinery. Moving to Paris he found employment in the Alliance factory as a model maker. With a growing interest in electricity he left to become an instrument maker with Heinrich Daniel Rühmkorff. In 1870 he patented the uniformly wound ring-armature dynamo with which his name is associated. Together with Hippolyte Fontaine, in 1871 Gramme opened a factory to manufacture his dynamos. They rapidly became a commercial success for both arc lighting and electrochemical purposes, international publicity being achieved at exhibitions in Vienna, Paris and Philadelphia. It was the realization that a Gramme machine was capable of running as a motor, i.e. the reversibility of function, that illustrated the entire concept of power transmission by electricity. This was first publicly demonstrated in 1873. In 1874 Gramme reduced the size and increased the efficiency of his generators by relying completely on the principle of self-excitation. It was the first practical machine in which were combined the features of continuity of commutation, self-excitation, good lamination of the armature core and a reasonably good magnetic circuit. This dynamo, together with the self-regulating arc lamps then available, made possible the innumerable electric-lighting schemes that followed. These were of the greatest importance in demonstrating that electric lighting was a practical and economic means of illumination. Gramme also designed an alternator to operate Jablochkoff candles. For some years he took an active part in the operations of the Société Gramme and also experimented in his own workshop without collaboration, but made no further contribution to electrical technology.

[br]

Principal Honours and Distinctions

Knight Commander, Order of Leopold of Belgium 1897. Chevalier de la Légion d'honneur. Chevalier, Order of the Iron Crown, Austria.

Bibliography

9 June 1870, British patent no. 1,668 (the ring armature machine).

1871, Comptes rendus 73:175–8 (Gramme's first description of his invention).

Further Reading

W.J.King, 1962, The Development of Electrical Technology in the 19th Century, Washington, DC: Smithsonian Institution, Paper 30, pp. 377–90 (an extensive account of Gramme's machines).

S.P.Thompson, 1901, obituary, Electrician 66: 509–10.

C.C.Gillispie (ed.), 1972, Dictionary of Scientific Biography, Vol. V, New York, p. 496.

GW

Herbert, Edward Geisler

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy

[br]

b. 23 March 1869 Dedham, near Colchester, Essex, England

d. 9 February 1938 West Didsbury, Manchester, England

[br]

English engineer, inventor of the Rapidor saw and the Pendulum Hardness Tester, and pioneer of cutting tool research.

[br]

Edward Geisler Herbert was educated at Nottingham High School in 1876–87, and at University College, London, in 1887–90, graduating with a BSc in Physics in 1889 and remaining for a further year to take an engineering course. He began his career as a premium apprentice at the Nottingham works of Messrs James Hill \& Co, manufacturers of lace machinery. In 1892 he became a partner with Charles Richardson in the firm of Richardson \& Herbert, electrical engineers in Manchester, and when this partnership was dissolved in 1895 he carried on the business in his own name and began to produce machine tools. He remained as Managing Director of this firm, reconstituted in 1902 as a limited liability company styled Edward G.Herbert Ltd, until his retirement in 1928. He was joined by Charles Fletcher (1868–1930), who as joint Managing Director contributed greatly to the commercial success of the firm, which specialized in the manufacture of small machine tools and testing machinery.

Around 1900 Herbert had discovered that hacksaw machines cut very much quicker when only a few teeth are in operation, and in 1902 he patented a machine which utilized this concept by automatically changing the angle of incidence of the blade as cutting proceeded. These saws were commercially successful, but by 1912, when his original patents were approaching expiry, Herbert and Fletcher began to develop improved methods of applying the rapid-saw concept. From this work the well-known Rapidor and Manchester saws emerged soon after the First World War. A file-testing machine invented by Herbert before the war made an autographic record of the life and performance of the file and brought him into close contact with the file and tool steel manufacturers of Sheffield. A tool-steel testing machine, working like a lathe, was introduced when high-speed steel had just come into general use, and Herbert became a prominent member of the Cutting Tools Research Committee of the Institution of Mechanical Engineers in 1919, carrying out many investigations for that body and compiling four of its Reports published between 1927 and 1933. He was the first to conceive the idea of the "tool-work" thermocouple which allowed cutting tool temperatures to be accurately measured. For this advance he was awarded the Thomas Hawksley Gold Medal of the Institution in 1926.

His best-known invention was the Pendulum Hardness Tester, introduced in 1923. This used a spherical indentor, which was rolled over, rather than being pushed into, the surface being examined, by a small, heavy, inverted pendulum. The period of oscillation of this pendulum provided a sensitive measurement of the specimen's hardness. Following this work Herbert introduced his "Cloudburst" surface hardening process, in which hardened steel engineering components were bombarded by steel balls moving at random in all directions at very high velocities like gaseous molecules. This treatment superhardened the surface of the components, improved their resistance to abrasion, and revealed any surface defects. After bombardment the hardness of the superficially hardened layers increased slowly and spontaneously by a room-temperature ageing process. After his retirement in 1928 Herbert devoted himself to a detailed study of the influence of intense magnetic fields on the hardening of steels.

Herbert was a member of several learned societies, including the Manchester Association of Engineers, the Institute of Metals, the American Society of Mechanical Engineers and the Institution of Mechanical Engineers. He retained a seat on the Board of his company from his retirement until the end of his life.

[br]

Principal Honours and Distinctions

Manchester Association of Engineers Butterworth Gold Medal 1923. Institution of Mechanical Engineers Thomas Hawksley Gold Medal 1926.

Bibliography

E.G.Herbert obtained several British and American patents and was the author of many papers, which are listed in T.M.Herbert (ed.), 1939, "The inventions of Edward Geisler Herbert: an autobiographical note", Proceedings of the Institution of Mechanical Engineers 141: 59–67.

ASD / RTS

Hyatt, John Wesley

SUBJECT AREA: Chemical technology, Synthetic materials

[br]

b. 28 November 1837 Starkey, New York, USA

d. 10 May 1920 Short Hills, New Jersey, USA

[br]

American inventor and the first successful manufacturer of celluloid.

[br]

Leaving school at the age of 16, Hyatt spent ten years in the printing trade, demonstrating meanwhile a talent for invention. The offer of a prize of $10,000 for finding a substitute for ivory billiard balls stimulated Hyatt to experiment with various materials. After many failures, he arrived at a composition of paper flock, shellac and collodion, which was widely adopted. Noting the "skin" left after evaporating collodion, he continued his experiments, using nitrocellulose as a base for plastic materials, yet he remained largely ignorant of both chemistry and the dangers of this explosive substance. Independently of Parkes in England, he found that a mixture of nitrocellulose, camphor and a little alcohol could, by heating, be made soft enough to mould but became hard at room temperature. Hyatt's first patent for the material, celluloid, was dated 12 July 1870 (US pat. 105338) and was followed by many others for making domestic and decorative articles of celluloid, replacing more expensive natural materials. Manufacture began at Albany in the winter of 1872–3. In 1881 Hyatt and his brother Isiah Smith floated the Hyatt Pure Water Company. By introducing purifying coagulants into flowing water, they avoided the expense and delay of allowing the water to settle in large tanks before filtration. Many towns and paper and woollen mills adopted the new process, and in 1891 it was introduced into Europe. During 1891–2, Hyatt devised a widely used type of roller bearing. Later inventions included a sugar-cane mill, a multistitch sewing machine and a mill for the cold rolling and straightening of steel shafts. It was characteristic of Hyatt's varied inventions that they achieved improved results at less expense.

[br]

Principal Honours and Distinctions

Society of Chemical Industry Perkin Medal 1914.

Bibliography

12 July 1870, US patent no. 105,338 (celluloid).

Further Reading

Obituary, 1920, Chem. Metal. Eng. (19 May).

J. Soc. Chem. Ind. for 16 March 1914 and J. Ind. Eng. Chem. for March 1914 carried accounts of Hyatt's achievements, on the occasion of his award of the Perkin Medal of the Society of Chemical Industry in that year.

LRD

Johnson, Thomas

SUBJECT AREA: Textiles

[br]

fl. 1800s England

d. after 1846

[br]

English developer of the sizing and beaming machine, and improver of the hand loom.

[br]

Thomas Johnson was an assistant to William Radcliffe c.1802 in his developments of the sizing machine and hand looms. Johnson is described by Edward Baines (1835) as "an ingenious but dissipated young man to whom he [Radcliffe] explained what he wanted, and whose fertile invention suggested a great variety of expedients, so that he obtained the name of the “conjuror” among his fellow-workmen". Johnson's genius, and Radcliffe's judgement and perseverance, at length produced the dressing-machine that was soon applied to power looms and made their use economic. Cotton warps had to be dressed with a starch paste to prevent them from fraying as they were being woven. Up to this time, the paste had had to be applied as the warp was unwound from the back of the loom, which meant that only short lengths could be treated and then left to dry, holding up the weaver. Radcliffe carried out the dressing and beaming in a separate machine so that weaving could proceed without interruption. Work on the dressing-machine was carried out in 1802 and patents were taken out in 1803 and 1804. These were made out in Johnson's name because Radcliffe was afraid that if his own name were used other people, particularly foreigners, would discover his secrets. Two more patents were taken out for improvements to hand looms. The first of these was a take-up motion for the woven cloth that automatically wound the cloth onto a roller as the weaver operated the loom. This was later incorporated by H.Horrocks into his own power loom design.

Radcliffe and Johnson also developed the "dandy-loom", which was a more compact form of hand loom and later became adapted for weaving by power. Johnson was the inventor of the first circular or revolving temples, which kept the woven cloth at the right width. In the patent specifications there is a patent in 1805 by Thomas Johnson and James Kay for an improved power loom and another in 1807 for a vertical type of power loom. Johnson could have been involved with further patents in the 1830s and 1840s for vertical power looms and dressing-machines, which would put his death after 1846.

[br]

Bibliography

1802, British patent no. 2,684 (dressing-machine).

1803, British patent no. 2,771 (dressing-machine).

1805, with James Kay, British patent no. 2,876 (power-loom). 1807, British patent no. 6,570 (vertical powerloom).

Further Reading

There is no general account of Johnson's life, but references to his work with Radcliffe may be found in A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; and in E.Baines, 1835, History of the Cotton Manufacture in Great Britain, London.

D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830s, Oxford (for the impact of the dressing-machine in America).

RLH

Kay (of Bury), John

SUBJECT AREA: Textiles

[br]

b. 16 July 1704 Walmersley, near Bury, Lancashire, England

d. 1779 France

[br]

English inventor of the flying shuttle.

[br]

John Kay was the youngest of five sons of a yeoman farmer of Walmersley, near Bury, Lancashire, who died before his birth. John was apprenticed to a reedmaker, and just before he was 21 he married a daughter of John Hall of Bury and carried on his trade in that town until 1733. It is possible that his first patent, taken out in 1730, was connected with this business because it was for an engine that made mohair thread for tailors and twisted and dressed thread; such thread could have been used to bind up the reeds used in looms. He also improved the reeds by making them from metal instead of cane strips so they lasted much longer and could be made to be much finer. His next patent in 1733, was a double one. One part of it was for a batting machine to remove dust from wool by beating it with sticks, but the patent is better known for its description of the flying shuttle. Kay placed boxes to receive the shuttle at either end of the reed or sley. Across the open top of these boxes was a metal rod along which a picking peg could slide and drive the shuttle out across the loom. The pegs at each end were connected by strings to a stick that was held in the right hand of the weaver and which jerked the shuttle out of the box. The shuttle had wheels to make it "fly" across the warp more easily, and ran on a shuttle race to support and guide it. Not only was weaving speeded up, but the weaver could produce broader cloth without any aid from a second person. This invention was later adapted for the power loom. Kay moved to Colchester and entered into partnership with a baymaker named Solomon Smith and a year later was joined by William Carter of Ballingdon, Essex. His shuttle was received with considerable hostility in both Lancashire and Essex, but it was probably more his charge of 15 shillings a year for its use that roused the antagonism. From 1737 he was much involved with lawsuits to try and protect his patent, particularly the part that specified the method of winding the thread onto a fixed bobbin in the shuttle. In 1738 Kay patented a windmill for working pumps and an improved chain pump, but neither of these seems to have been successful. In 1745, with Joseph Stell of Keighley, he patented a narrow fabric loom that could be worked by power; this type may have been employed by Gartside in Manchester soon afterwards. It was probably through failure to protect his patent rights that Kay moved to France, where he arrived penniless in 1747. He went to the Dutch firm of Daniel Scalongne, woollen manufacturers, in Abbeville. The company helped him to apply for a French patent for his shuttle, but Kay wanted the exorbitant sum of £10,000. There was much discussion and eventually Kay set up a workshop in Paris, where he received a pension of 2,500 livres. However, he was to face the same problems as in England with weavers copying his shuttle without permission. In 1754 he produced two machines for making card clothing: one pierced holes in the leather, while the other cut and sharpened the wires. These were later improved by his son, Robert Kay. Kay returned to England briefly, but was back in France in 1758. He was involved with machines to card both cotton and wool and tried again to obtain support from the French Government. He was still involved with developing textile machines in 1779, when he was 75, but he must have died soon afterwards. As an inventor Kay was a genius of the first rank, but he was vain, obstinate and suspicious and was destitute of business qualities.

[br]

Bibliography

1730, British patent no. 515 (machine for making mohair thread). 1733, British patent no. 542 (batting machine and flying shuttle). 1738, British patent no. 561 (pump windmill and chain pump). 1745, with Joseph Stell, British patent no. 612 (power loom).

Further Reading

B.Woodcroft, 1863, Brief Biographies of Inventors or Machines for the Manufacture of Textile Fabrics, London.

J.Lord, 1903, Memoir of John Kay, (a more accurate account).

Descriptions of his inventions may be found in A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; R.L. Hills, 1970, Power in the

Industrial Revolution, Manchester; and C.Singer (ed.), 1957, A History of

Technology, Vol. III, Oxford: Clarendon Press. The most important record, however, is in A.P.Wadsworth and J. de L. Mann, 1931, The Cotton Trade and Industrial

Lancashire, Manchester.

RLH