original invention

original invention

Патенты: оригинальное изобретение

original invention

оригинальное изобретение

original invention

очевидное изобретение

(an) original invention

оригинальное/незаурядное изобретение

invention

изобретение

- invention covered by a patent

- invention in contemplation
- invention made in common
- invention reduced to practice
- hide the invention
- invention of application
- invention of no avail
- abandoned invention
- accidental invention
- actual invention
- additional invention
- AEC contract invention
- aggregative invention
- alleged invention
- atomic energy invention
- basic invention
- biotechnological invention
- broad invention
- chemical invention
- claimed invention
- cognate inventions
- combination invention
- communicated inventions
- company's invention
- competing invention
- complete invention
- contemplated invention
- dead wood invention
- declassified invention
- defense invention
- defensive invention
- dependent invention
- derived invention
- design invention
- developing invention
- disclosed invention
- distinct invention
- domestic invention
- economic invention
- efficiency promoting invention
- employee's invention
- epoch-making invention
- finished invention
- foreign invention
- fraudulent invention
- free invention
- frivolous invention
- fully disclosed invention
- fundamental invention
- gene-based invention
- generic invention
- home invention
- immature invention
- imperfect invention
- incidental invention
- incomplete invention
- independent invention
- individual invention
- ineffective invention
- injurious invention
- interfering invention
- joint invention
- labor saving invention
- later invention
- main invention under the PCT
- method invention
- military invention
- narrow invention
- new invention
- novel invention
- obvious invention
- ordinary invention
- original invention
- outsider's invention
- paper invention
- patentable invention
- patented invention
- pioneer invention
- pioneering invention
- practical invention
- practically operative invention
- prior invention
- process invention
- proposed invention
- protected invention
- purported invention
- recognized invention
- recommended invention
- registered invention
- revolutionizing invention
- scandalous invention
- secret invention
- service invention
- simple invention
- specific invention
- subordinate invention
- supplementary invention
- supposed invention
- trivial invention
- unfinished invention
- unobvious invention
- unpatentable invention
- unpatented invention
- unrealizable invention
- useful invention
- utility invention
- vicious invention
- works invention
- worthless invention

* * *

изобретение (решение технической задачи, обладающее новизной и дающее положительный эффект)

original

I [ə'rɪdʒɪn(ə)l] n

оригинал, подлинник

- original of the painting

- in the original
- read books in the original
- make several copies of the original II [ə'rɪdʒɪn(ə)l] adj

1) подлинный

- original document

- original text
- original signiture
- original picture

2) первоначальный

Tobacco is a plant original with the American Indians. — Американские индейцы первыми стали выращивать табак.

- original plan

- original meaning
- original variant
- original copy
- original edition
- original inhabitants
- original laws of the country

3) самобытный, оригинальный, необычный, незаурядный

He isn't very original in his music. — В его музыке нет ничего оригинального.

Can't you be more original in your remarks (in your suggestions). — Неужели ты не можешь дать творческих (менее заурядных) замечаний (предложений).

- original writer

- original composer
- original idea
- original mind
- original invention
- original thought

original

1. n

по́длинник м

2. a

1) первонача́льный

2) по́длинный

original picture — по́длинная карти́на

3) оригина́льный

original invention — оригина́льное изобрете́ние

- original sin

original

1. [əʹrıdʒın(ə)l] n

1. оригинал, подлинник; подлинное произведение

to take a copy from the original - снять копию с подлинника /с оригинала/

2. язык оригинала; язык, на котором создано произведение

to read Homer in the original - читать Гомера в подлиннике

to study Don Quixote in the original - изучать «Дон Кихота» на испанском языке

3. первоисточник

4. прототип, оригинал ( художественного произведения)

5. 1) незаурядный, необыкновенный человек

2) чудак, оригинал

the man is a real original - этот человек - настоящий оригинал

he was looked upon as an original - его считали чудаком

6. почтовая марка из первого издания

7. редк. происхождение; начало

8. редк. автор, создатель

9. pl редк. первые жители или поселенцы

2. [əʹrıdʒın(ə)l] a

1. первый, первоначальный; исконный

the original edition - первое издание

original home - родина

original sin /fault/ - рел. первородный грех

the original laws of a country - первые законы страны

the original inhabitants of a country - исконные жители страны

the original price - исходная цена

original rock - горн. коренная порода

original scheme - первоначальный вариант

2. оригинальный, подлинный

the original picture - подлинник /оригинал/ картины

the original document [text] - подлинный документ [текст]

3. 1) оригинальный, незаимствованный

original plan [invention, idea] - оригинальный план [-ое изобретение, -ая мысль]

2) новый, свежий

original thought - свежая мысль

original remark - оригинальное замечание

an original point of view - иная точка зрения

4. творческий, незаурядный, самобытный

original writer [composer] - незаурядный писатель [композитор]

original mind - самобытный ум

an original thinker - оригинальный мыслитель

5. редк. врождённый; наследственный

original disposition - наследственная склонность (к чему-л.)

6. странный, своеобразный; чудаковатый

an original man - странный человек; чудак, оригинал

original behaviour - необычное поведение

(a) great invention

a (an) great (important, most original, epoch-making, new) invention крупное (важное, весьма оригинальное, эпохальное, новое) изобретение

Strutt, Jedediah

SUBJECT AREA: Textiles

[br]

b. 26 July 1726 South Normanton, near Alfreton, Derbyshire, England

d. 7 May 1797 Derby, England

[br]

English inventor of a machine for making ribbed knitting.

[br]

Jedediah Strutt was the second of three sons of William, a small farmer and maltster at South Normanton, near Alfreton, Derbyshire, where the only industry was a little framework knitting. At the age of 14 Jedediah was apprenticed to Ralph Massey, a wheelwright near Derby, and lodged with the Woollats, whose daughter Elizabeth he later married in 1755. He moved to Leicester and in 1754 started farming at Blackwell, where an uncle had died and left him the stock on his farm. It was here that he made his knitting invention.

William Lee's knitting machine remained in virtually the same form as he left it until the middle of the eighteenth century. The knitting industry moved away from London into the Midlands and in 1730 a Nottingham workman, using Indian spun yarn, produced the first pair of cotton hose ever made by mechanical means. This industry developed quickly and by 1750 was providing employment for 1,200 frameworkers using both wool and cotton in the Nottingham and Derby areas. It was against this background that Jedediah Strutt obtained patents for his Derby rib machine in 1758 and 1759.

The machine was a highly ingenious mechanism, which when placed in front of an ordinary stocking frame enabled the fashionable ribbed stockings to be made by machine instead of by hand. To develop this invention, he formed a partnership first with his brother-in-law, William Woollat, and two leading Derby hosiers, John Bloodworth and Thomas Stamford. This partnership was dissolved in 1762 and another was formed with Woollat and the Nottingham hosier Samuel Need. Strutt's invention was followed by a succession of innovations which enabled framework knitters to produce almost every kind of mesh on their machines. In 1764 the stocking frame was adapted to the making of eyelet holes, and this later lead to the production of lace. In 1767 velvet was made on these frames, and two years later brocade. In this way Strutt's original invention opened up a new era for knitting. Although all these later improvements were not his, he was able to make a fortune from his invention. In 1762 he was made a freeman of Nottingham, but by then he was living in Derby. His business at Derby was concerned mainly with silk hose and he had a silk mill there.

It was partly his need for cotton yarn and partly his wealth which led him into partnership with Richard Arkwright, John Smalley and David Thornley to exploit Arkwright's patent for spinning cotton by rollers. Together with Samuel Need, they financed the Arkwright partnership in 1770 to develop the horse-powered mill in Nottingham and then the water-powered mill at Cromford. Strutt gave advice to Arkwright about improving the machinery and helped to hold the partnership together when Arkwright fell out with his first partners. Strutt was also involved, in London, where he had a house, with the parliamentary proceedings over the passing of the Calico Act in 1774, which opened up the trade in British-manufactured all-cotton cloth.

In 1776 Strutt financed the construction of his own mill at Helper, about seven miles (11 km) further down the Derwent valley below Cromford. This was followed by another at Milford, a little lower on the river. Strutt was also a partner with Arkwright and others in the mill at Birkacre, near Chorley in Lancashire. The Strutt mills were developed into large complexes for cotton spinning and many experiments were later carried out in them, both in textile machinery and in fireproof construction for the mills themselves. They were also important training schools for engineers.

Elizabeth Strutt died in 1774 and Jedediah never married again. The family seem to have lived frugally in spite of their wealth, probably influenced by their Nonconformist background. He had built a house near the mills at Milford, but it was in his Derby house that Jedediah died in 1797. By the time of his death, his son William had long been involved with the business and became a more important cotton spinner than Jedediah.

[br]

Bibliography

1758. British patent no. 722 (Derby rib machine). 1759. British patent no. 734 (Derby rib machine).

Further Reading

For the involvement of Strutt in Arkwright's spinning ventures, there are two books, the earlier of which is R.S.Fitton and A.P.Wadsworth, 1958, The Strutts and the Arkwrights, 1758–1830, Manchester, which has most of the details about Strutt's life. This has been followed by R.S.Fitton, 1989, The Arkwrights, Spinners of Fortune, Manchester.

R.L.Hills, 1970, Power in the Industrial Revolution, Manchester (for a general background to the textile industry of the period).

W.Felkin, 1967, History of the Machine-wrought Hosiery and Lace Manufactures, reprint, Newton Abbot (orig. pub. 1867) (covers Strutt's knitting inventions).

RLH

on all accounts

(on all accounts (тж. on every account))

принимая всё во внимание, со всех точек зрения, при всех обстоятельствах, во всех отношениях

While Margorie Daw, of all these tales, was the most original invention, The Story of a Bad Boy, the most sincere and natural, was destined, on all accounts, for the longest life. (V. W. Brooks, ‘New England: Indian Summer 1865-1915’, ch. XIV) — Хотя из всех этих рассказов "Марджори До" является самым оригинальным, все же "Рассказ о плохом мальчике" написан так искренно и правдиво, что ему с полным основанием обеспечена долгая литературная жизнь.

Bauer, H.

SUBJECT AREA: Textiles

[br]

fl. c.1885

[br]

German (?) inventor of a press-stud fastener.

[br]

Fastenings are an essential component of the majority of garments. Great advances were made in Germany with press studs in the late nineteenth century after the original invention by Louis Hannart in 1863. In 1885, Bauer patented a spring and stud fastener.

[br]

Further Reading

I.McNeil (ed.), 1990, An Encyclopaedia of the History of Technology, London: Routledge, pp. 852–3 (provides an account of the development of fastenings).

RLH

Crompton, Samuel

SUBJECT AREA: Textiles

[br]

b. 3 December 1753 Firwood, near Bolton, Lancashire, England

d. 26 June 1827 Bolton, Lancashire, England

[br]

English inventor of the spinning mule.

[br]

Samuel Crompton was the son of a tenant farmer, George, who became the caretaker of the old house Hall-i-th-Wood, near Bolton, where he died in 1759. As a boy, Samuel helped his widowed mother in various tasks at home, including weaving. He liked music and made his own violin, with which he later was to earn some money to pay for tools for building his spinning mule. He was set to work at spinning and so in 1769 became familiar with the spinning jenny designed by James Hargreaves; he soon noticed the poor quality of the yarn produced and its tendency to break. Crompton became so exasperated with the jenny that in 1772 he decided to improve it. After seven years' work, in 1779 he produced his famous spinning "mule". He built the first one entirely by himself, principally from wood. He adapted rollers similar to those already patented by Arkwright for drawing out the cotton rovings, but it seems that he did not know of Arkwright's invention. The rollers were placed at the back of the mule and paid out the fibres to the spindles, which were mounted on a moving carriage that was drawn away from the rollers as the yarn was paid out. The spindles were rotated to put in twist. At the end of the draw, or shortly before, the rollers were stopped but the spindles continued to rotate. This not only twisted the yarn further, but slightly stretched it and so helped to even out any irregularities; it was this feature that gave the mule yarn extra quality. Then, after the spindles had been turned backwards to unwind the yarn from their tips, they were rotated in the spinning direction again and the yarn was wound on as the carriage was pushed up to the rollers.

The mule was a very versatile machine, making it possible to spin almost every type of yarn. In fact, Samuel Crompton was soon producing yarn of a much finer quality than had ever been spun in Bolton, and people attempted to break into Hall-i-th-Wood to see how he produced it. Crompton did not patent his invention, perhaps because it consisted basically of the essential features of the earlier machines of Hargreaves and Arkwright, or perhaps through lack of funds. Under promise of a generous subscription, he disclosed his invention to the spinning industry, but was shabbily treated because most of the promised money was never paid. Crompton's first mule had forty-eight spindles, but it did not long remain in its original form for many people started to make improvements to it. The mule soon became more popular than Arkwright's waterframe because it could spin such fine yarn, which enabled weavers to produce the best muslin cloth, rivalling that woven in India and leading to an enormous expansion in the British cotton-textile industry. Crompton eventually saved enough capital to set up as a manufacturer himself and around 1784 he experimented with an improved carding engine, although he was not successful. In 1800, local manufacturers raised a sum of £500 for him, and eventually in 1812 he received a government grant of £5,000, but this was trifling in relation to the immense financial benefits his invention had conferred on the industry, to say nothing of his expenses. When Crompton was seeking evidence in 1811 to support his claim for financial assistance, he found that there were 4,209,570 mule spindles compared with 155,880 jenny and 310,516 waterframe spindles. He later set up as a bleacher and again as a cotton manufacturer, but only the gift of a small annuity by his friends saved him from dying in total poverty.

[br]

Further Reading

H.C.Cameron, 1951, Samuel Crompton, Inventor of the Spinning Mule, London (a rather discursive biography).

Dobson \& Barlow Ltd, 1927, Samuel Crompton, the Inventor of the Spinning Mule, Bolton.

G.J.French, 1859, The Life and Times of Samuel Crompton, Inventor of the Spinning Machine Called the Mule, London.

The invention of the mule is fully described in H. Gatling, 1970, The Spinning Mule, Newton Abbot; W.English, 1969, The Textile Industry, London; R.L.Hills, 1970, Power in the Industrial Revolution, Manchester.

C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press (provides a brief account).

RLH

Monro, Philip Peter

SUBJECT AREA: Chemical technology

[br]

b. 27 May 1946 London, England

[br]

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

[br]

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

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

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

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

[br]

Bibliography

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

LRD

Swan, Sir Joseph Wilson

SUBJECT AREA: Electricity, Photography, film and optics

[br]

b. 31 October 1828 Sunderland, England

d. 27 May 1914 Warlingham, Surrey, England

[br]

English chemist, inventor in Britain of the incandescent electric lamp and of photographic processes.

[br]

At the age of 14 Swan was apprenticed to a Sunderland firm of druggists, later joining John Mawson who had opened a pharmacy in Newcastle. While in Sunderland Swan attended lectures at the Athenaeum, at one of which W.E. Staite exhibited electric-arc and incandescent lighting. The impression made on Swan prompted him to conduct experiments that led to his demonstration of a practical working lamp in 1879. As early as 1848 he was experimenting with carbon as a lamp filament, and by 1869 he had mounted a strip of carbon in a vessel exhausted of air as completely as was then possible; however, because of residual air, the filament quickly failed.

Discouraged by the cost of current from primary batteries and the difficulty of achieving a good vacuum, Swan began to devote much of his attention to photography. With Mawson's support the pharmacy was expanded to include a photographic business. Swan's interest in making permanent photographic records led him to patent the carbon process in 1864 and he discovered how to make a sensitive dry plate in place of the inconvenient wet collodian process hitherto in use. He followed this success with the invention of bromide paper, the subject of a British patent in 1879.

Swan resumed his interest in electric lighting. Sprengel's invention of the mercury pump in 1865 provided Swan with the means of obtaining the high vacuum he needed to produce a satisfactory lamp. Swan adopted a technique which was to become an essential feature in vacuum physics: continuing to heat the filament during the exhaustion process allowed the removal of absorbed gases. The inventions of Gramme, Siemens and Brush provided the source of electrical power at reasonable cost needed to make the incandescent lamp of practical service. Swan exhibited his lamp at a meeting in December 1878 of the Newcastle Chemical Society and again the following year before an audience of 700 at the Newcastle Literary and Philosophical Society. Swan's failure to patent his invention immediately was a tactical error as in November 1879 Edison was granted a British patent for his original lamp, which, however, did not go into production. Parchmentized thread was used in Swan's first commercial lamps, a material soon superseded by the regenerated cellulose filament that he developed. The cellulose filament was made by extruding a solution of nitro-cellulose in acetic acid through a die under pressure into a coagulating fluid, and was used until the ultimate obsolescence of the carbon-filament lamp. Regenerated cellulose became the first synthetic fibre, the further development and exploitation of which he left to others, the patent rights for the process being sold to Courtaulds.

Swan also devised a modification of Planté's secondary battery in which the active material was compressed into a cellular lead plate. This has remained the central principle of all improvements in secondary cells, greatly increasing the storage capacity for a given weight.

[br]

Principal Honours and Distinctions

Knighted 1904. FRS 1894. President, Institution of Electrical Engineers 1898. First President, Faraday Society 1904. Royal Society Hughes Medal 1904. Chevalier de la Légion d'Honneur 1881.

Bibliography

2 January 1880, British patent no. 18 (incandescent electric lamp).

24 May 1881, British patent no. 2,272 (improved plates for the Planté cell).

1898, "The rise and progress of the electrochemical industries", Journal of the Institution of Electrical Engineers 27:8–33 (Swan's Presidential Address to the Institution of Electrical Engineers).

Further Reading

M.E.Swan and K.R.Swan, 1968, Sir Joseph Wilson Swan F.R.S., Newcastle upon Tyne (a detailed account).

R.C.Chirnside, 1979, "Sir Joseph Swan and the invention of the electric lamp", IEE

Electronics and Power 25:96–100 (a short, authoritative biography).

GW

Lister, Samuel Cunliffe, 1st Baron Masham

SUBJECT AREA: Textiles

[br]

b. 1 January 1815 Calverly Hall, Bradford, England

d. 2 February 1906 Swinton Park, near Bradford, England

[br]

English inventor of successful wool-combing and waste-silk spinning machines.

[br]

Lister was descended from one of the old Yorkshire families, the Cunliffe Listers of Manningham, and was the fourth son of his father Ellis. After attending a school on Clapham Common, Lister would not go to university; his family hoped he would enter the Church, but instead he started work with the Liverpool merchants Sands, Turner \& Co., who frequently sent him to America. In 1837 his father built for him and his brother a worsted mill at Manningham, where Samuel invented a swivel shuttle and a machine for making fringes on shawls. It was here that he first became aware of the unhealthy occupation of combing wool by hand. Four years later, after seeing the machine that G.E. Donisthorpe was trying to work out, he turned his attention to mechanizing wool-combing. Lister took Donisthorpe into partnership after paying him £12,000 for his patent, and developed the Lister-Cartwright "square nip" comber. Until this time, combing machines were little different from Cartwright's original, but Lister was able to improve on this with continuous operation and by 1843 was combing the first fine botany wool that had ever been combed by machinery. In the following year he received an order for fifty machines to comb all qualities of wool. Further combing patents were taken out with Donisthorpe in 1849, 1850, 1851 and 1852, the last two being in Lister's name only. One of the important features of these patents was the provision of a gripping device or "nip" which held the wool fibres at one end while the rest of the tuft was being combed. Lister was soon running nine combing mills. In the 1850s Lister had become involved in disputes with others who held combing patents, such as his associate Isaac Holden and the Frenchman Josué Heilmann. Lister bought up the Heilmann machine patents and afterwards other types until he obtained a complete monopoly of combing machines before the patents expired. His invention stimulated demand for wool by cheapening the product and gave a vital boost to the Australian wool trade. By 1856 he was at the head of a wool-combing business such as had never been seen before, with mills at Manningham, Bradford, Halifax, Keighley and other places in the West Riding, as well as abroad.

His inventive genius also extended to other fields. In 1848 he patented automatic compressed air brakes for railways, and in 1853 alone he took out twelve patents for various textile machines. He then tried to spin waste silk and made a second commercial career, turning what was called "chassum" and hitherto regarded as refuse into beautiful velvets, silks, plush and other fine materials. Waste silk consisted of cocoon remnants from the reeling process, damaged cocoons and fibres rejected from other processes. There was also wild silk obtained from uncultivated worms. This is what Lister saw in a London warehouse as a mass of knotty, dirty, impure stuff, full of bits of stick and dead mulberry leaves, which he bought for a halfpenny a pound. He spent ten years trying to solve the problems, but after a loss of £250,000 and desertion by his partner his machine caught on in 1865 and brought Lister another fortune. Having failed to comb this waste silk, Lister turned his attention to the idea of "dressing" it and separating the qualities automatically. He patented a machine in 1877 that gave a graduated combing. To weave his new silk, he imported from Spain to Bradford, together with its inventor Jose Reixach, a velvet loom that was still giving trouble. It wove two fabrics face to face, but the problem lay in separating the layers so that the pile remained regular in length. Eventually Lister was inspired by watching a scissors grinder in the street to use small emery wheels to sharpen the cutters that divided the layers of fabric. Lister took out several patents for this loom in his own name in 1868 and 1869, while in 1871 he took out one jointly with Reixach. It is said that he spent £29,000 over an eleven-year period on this loom, but this was more than recouped from the sale of reasonably priced high-quality velvets and plushes once success was achieved. Manningham mills were greatly enlarged to accommodate this new manufacture.

In later years Lister had an annual profit from his mills of £250,000, much of which was presented to Bradford city in gifts such as Lister Park, the original home of the Listers. He was connected with the Bradford Chamber of Commerce for many years and held the position of President of the Fair Trade League for some time. In 1887 he became High Sheriff of Yorkshire, and in 1891 he was made 1st Baron Masham. He was also Deputy Lieutenant in North and West Riding.

[br]

Principal Honours and Distinctions

Created 1st Baron Masham 1891.

Bibliography

1849, with G.E.Donisthorpe, British patent no. 12,712. 1850, with G.E. Donisthorpe, British patent no. 13,009. 1851, British patent no. 13,532.

1852, British patent no. 14,135.

1877, British patent no. 3,600 (combing machine). 1868, British patent no. 470.

1868, British patent no. 2,386.

1868, British patent no. 2,429.

1868, British patent no. 3,669.

1868, British patent no. 1,549.

1871, with J.Reixach, British patent no. 1,117. 1905, Lord Masham's Inventions (autobiography).

Further Reading

J.Hogg (ed.), c. 1888, Fortunes Made in Business, London (biography).

W.English, 1969, The Textile Industry, London; and C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press (both cover the technical details of Lister's invention).

RLH

Biro, Laszlo Joszef (Ladislao José)

SUBJECT AREA: Paper and printing

[br]

b. 29 September 1899 Budapest, Hungary

d. 24 October 1985 Buenos Aires, Argentina

[br]

Hungarian inventor of the ballpoint pen.

[br]

Details of Biro's early life are obscure, but by 1939 he had been active as a painter, a member of the Hungarian Academy of Sciences and an inventor, patenting over thirty minor inventions. During the 1930s he edited a cultural magazine and noticed in the printing shop the advantages of quick-drying ink. He began experimenting with crude ballpoint pens. The idea was not new, for an American, John Loud, had patented a cumbersome form of pen for marking rough surfaces in 1888; it had failed commercially. Biro and his brother Georg patented a ballpoint pen in 1938, although they had not yet perfected a suitable ink or a reservoir to hold it.

In 1940 Biro fled the Nazi occupation of Hungary and settled in Argentina. Two years later, he had developed his pen to the point where he could seek backers for a company to exploit it commercially. His principal backer appears to have been an English accountant, Henry George Martin. In 1944 Martin offered the invention to the US Army Air Force and the British Royal Air Force to overcome the problems aircrews were experiencing at high altitudes with leaking fountain pens. Some 10,000 ballpoints were made for the RAF. Licences were granted in the USA for the manufacture of the "biro", and in 1944 the Miles-Martin Pen Company was formed in Britain and began making them on a large scale at a factory near Reading, Berkshire; by 1951 its workforce had grown to over 1,000. Other companies followed suit; by varying details of the pen, they avoided infringing the original patents. One such entrepreneur, Miles Reynolds, was the first to put the pen on sale to the public in New York; it is reputed that 10,000 were sold on the first day.

Biro had little taste for commercial exploitation, and by 1947 he had withdrawn from the Argentine company, mainly to resume his painting, in the surrealist style. Examples of his work are exhibited in the Fine Arts Museum in Budapest. He created an instrument that had a greater impact on written communication than any other single invention.

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Further Reading

"Nachruf: Ladislao José Biro (1899–1985)", HistorischeBurowelt (1988) 21:5–8 (with English summary).

J.Jewkes, The Sources of Invention, pp. 234–5.

LRD

Judson, Whitcomb L.

SUBJECT AREA: Textiles

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fl. 1891–1905 USA

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American inventor of the zip fastener.

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Whitcomb Judson was a mechanical engineer by profession. He filed his first patent application for a zip fastener in 1891 and took out a fifth in 1905. His invention was originally designed for shoes and consisted of separate fasteners with two interlocking parts which could be fastened either by hand or by a movable guide. In his last patent, he clamped the fastening elements to the edge of a fabric tape and patented a machine for manufacturing this. Through an earlier exploit, the Judson Pneumatic Street Railway Company, Judson knew Colonel Lewis Walker, who helped him to organize the Universal Fastener Company of Chicago to manufacture these fasteners, which at first were made by hand. One machine invented by Judson proved to be too complicated, but Judson's later fasteners were easier to adapt to machine production. The original company was reorganized as the Automatic Hook and Eye Company of Hoboken, New Jersey, and the new fasteners were sold under the name "C-curity". However, the garment manufacturers would not use them at first because the fasteners had defects, such as springing open at unexpected moments. The Automatic Hook and Eye Company brought in Gideon Sundback, who improved Judson's work and made the zip fastener successful.

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Further Reading

J.Jewkes, D.Sawyers and R.Stillerman, 1969, The Sources of Invention, 2nd edn, London (for an account of the invention).

I.McNeil (ed.), 1990, An Encyclopaedia of the History of Technology, London: Routledge, pp. 852–3 (provides a brief account of fastenings).

RLH

Holmes, Frederic Hale

SUBJECT AREA: Electricity, Public utilities

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fl. 1850s–60s

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British engineer who pioneered the electrical illumination of lighthouses in Great Britain.

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An important application of the magneto generator was demonstrated by Holmes in 1853 when he showed that it might be used to supply an arc lamp. This had many implications for the future because it presented the possibility of making electric lighting economically successful. In 1856 he patented a machine with six disc armatures on a common axis rotating between seven banks of permanent magnets. The following year Holmes suggested the possible application of his invention to lighthouse illumination and a trial was arranged and observed by Faraday, who was at that time scientific adviser to Trinity House, the corporation entrusted with the care of light-houses in England and Wales. Although the trial was successful and gained the approval of Faraday, the Elder Brethren of Trinity House imposed strict conditions on Holmes's design for machines to be used for a more extensive trial. These included connecting the machine directly to a slow-speed steam engine, but this resulted in a reduced performance. The experiments of Holmes and Faraday were brought to the attention of the French lighthouse authorities and magneto generators manufactured by Société Alliance began to be installed in some lighthouses along the coast of France. After noticing the French commutatorless machines, Holmes produced an alternator of similar type in 1867. Two of these were constructed for a new lighthouse at Souter Point near Newcastle and two were installed in each of the two lighthouses at South Foreland. One of the machines from South Foreland that was in service from 1872 to 1922 is preserved in the Royal Museum of Scotland, Edinburgh. A Holmes generator is also preserved in the Science Museum, London. Holmes obtained a series of patents for generators between 1856 and 1869, with all but the last being of the magneto-electric type.

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Bibliography

7 March 1856, British patent no. 573 (the original patent for Holmes's invention).

1863, "On magneto electricity and its application to lighthouse purposes", Journal of the Society of Arts 12:39–43.

Further Reading

W.J.King, 1962, in The Development of Electrical Technology in the 19th Century; Washington, DC: Smithsonian Institution, Paper 30, pp. 351–63 (provides a detailed account of Holmes's generators).

J.N.Douglas, 1879, "The electric light applied to lighthouse illumination", Proceedings of the Institution of Civil Engineers 57(3):77–110 (describes trials of Holmes's machines).

GW

Noyce, Robert

SUBJECT AREA: Electronics and information technology

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b. 12 December 1927 Burlington, Iowa, USA

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American engineer responsible for the development of integrated circuits and the microprocessor chip.

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Noyce was the son of a Congregational minister whose family, after a number of moves, finally settled in Grinnell, some 50 miles (80 km) east of Des Moines, Iowa. Encouraged to follow his interest in science, in his teens he worked as a baby-sitter and mower of lawns to earn money for his hobby. One of his clients was Professor of Physics at Grinnell College, where Noyce enrolled to study mathematics and physics and eventually gained a top-grade BA. It was while there that he learned of the invention of the transistor by the team at Bell Laboratories, which included John Bardeen, a former fellow student of his professor. After taking a PhD in physical electronics at the Massachusetts Institute of Technology in 1953, he joined the Philco Corporation in Philadelphia to work on the development of transistors. Then in January 1956 he accepted an invitation from William Shockley, another of the Bell transistor team, to join the newly formed Shockley Transistor Company, the first electronic firm to set up shop in Palo Alto, California, in what later became known as "Silicon Valley".

From the start things at the company did not go well and eventually Noyce and Gordon Moore and six colleagues decided to offer themselves as a complete development team; with the aid of the Fairchild Camera and Instrument Company, the Fairchild Semiconductor Corporation was born. It was there that in 1958, contemporaneously with Jack K. Wilby at Texas Instruments, Noyce had the idea for monolithic integration of transistor circuits. Eventually, after extended patent litigation involving study of laboratory notebooks and careful examination of the original claims, priority was assigned to Noyce. The invention was most timely. The Apollo Moon-landing programme announced by President Kennedy in May 1961 called for lightweight sophisticated navigation and control computer systems, which could only be met by the rapid development of the new technology, and Fairchild was well placed to deliver the micrologic chips required by NASA.

In 1968 the founders sold Fairchild Semicon-ductors to the parent company. Noyce and Moore promptly found new backers and set up the Intel Corporation, primarily to make high-density memory chips. The first product was a 1,024-bit random access memory (1 K RAM) and by 1973 sales had reached $60 million. However, Noyce and Moore had already realized that it was possible to make a complete microcomputer by putting all the logic needed to go with the memory chip(s) on a single integrated circuit (1C) chip in the form of a general purpose central processing unit (CPU). By 1971 they had produced the Intel 4004 microprocessor, which sold for US$200, and within a year the 8008 followed. The personal computer (PC) revolution had begun! Noyce eventually left Intel, but he remained active in microchip technology and subsequently founded Sematech Inc.

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Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1966. National Academy of Engineering 1969. National Academy of Science. Institute of Electrical and Electronics Engineers Medal of Honour 1978; Cledo Brunetti Award (jointly with Kilby) 1978. Institution of Electrical Engineers Faraday Medal 1979. National Medal of Science 1979. National Medal of Engineering 1987.

Bibliography

1955, "Base-widening punch-through", Proceedings of the American Physical Society.

30 July 1959, US patent no. 2,981,877.

Further Reading

T.R.Reid, 1985, Microchip: The Story of a Revolution and the Men Who Made It, London: Pan Books.

KF