textile+manufacture

манифактура

1. manufacture, manufactury

2. (текстил) drapery, textiles, textile goods, ам. dry goods

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манифакту̀ра,

ж., -и 1. manufacture, manufactory;

2. ( текстил) drapery, textiles, textile goods, амер. dry goods.

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drapery; manufacture

* * *

1. (текстил) drapery, textiles, textile goods, ам. dry goods 2. manufacture, manufactury

манифактурен

1. manufacture (attr.)

манифактурен период a period of manufacture

2. (за тъкани) draper's

манифактурен магазин a draper's (shop), ам. a dry goods store

манифактурни стоки drapery, textiles, ам. dry goods

манифактурна промишленост a textile industry

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манифакту̀рен,

прил., -на, -но, -ни 1. manufacture (attr.); \манифактуренен период period of manufacture;

2. (за тъкани) draper’s; \манифактуренен магазин draper’s (shop), амер. dry goods store; \манифактуренни стоки drapery, textiles, амер. dry goods.

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1. (за тъкани) draper's 2. manufacture (attr.) 3. МАНИФАКТУРЕН магазин а draper's (shop), ам. a dry goods store 4. МАНИФАКТУРЕН период a period of manufacture 5. манифактурна промишленост a textile industry 6. манифактурни стоки drapery, textiles, ам. dry goods

textil

adj.

textile.

* * *

textil

► adjetivo

1 textile

► nombre masculino

1 textile

\

FRASEOLOGÍA

industria textil textile industry

obrero textil textile worker

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noun m. adj.

textile

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1. ADJ

1) [industria] textile

2) [playa] non-nudist

2.

pl textiles

SMPL (=tejidos) textiles

3.

SF textile company

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I

adjetivo textile (before n)

II

masculino textile

* * *

= textile.

Ex. The inclusion of much of West Yorkshire in the non-quota textile programme is claimed to be at least partly attributable to this persistence.

----

* propietario de una fábrica textil = wool-factor.

* * *

I

adjetivo textile (before n)

II

masculino textile

* * *

= textile.

Ex: The inclusion of much of West Yorkshire in the non-quota textile programme is claimed to be at least partly attributable to this persistence.

* propietario de una fábrica textil = wool-factor.

* * *

textil¹

adjective

textile ( before n)

textil²

masculine

textile

textil³

feminine

(CS)

textile mill

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textil adjetivo
textile ( before n)
textil adjetivo & sustantivo masculino textile
' textil' also found in these entries:
Spanish:
borla
- fábrica
English:
textile

* * *

textil

♦ adj

textile

♦ nm

textile

♦ nf

RP textile mill

TEXTILES INDÍGENAS

In Latin America, many indigenous people still manufacture their traditional textiles by hand, as they did in pre-Columbian times. Made almost exclusively by women, these textiles include “molas” (embroidery from Guatemala and Panama), “huipiles” (shawls from southern Mexico and Guatemala) and “aguayos” (alpaca wool shawls from Bolivia and Peru). “Molas” are cloth panels made of brightly coloured pieces of fabric sewn together to depict animals or a landscape. They can then be used to decorate colourful traditional blouses. “Huipiles” and “aguayos” are woven on looms with a narrow geometrical border and sometimes show ritual animals and objects, or even entire stories. In pre-Columbian times such textiles were worn as ceremonial costumes, given as gifts, offered up to the gods and buried with the dead. Today they are used in everyday accessories, such as blankets, trimmings, handbags and shoes, and “huipiles” and “aguayos” are used for carrying loads (and babies).

* * *

textil

I adj textile atr

II mpl

:

textiles textiles

* * *

textil adj & nm

: textile

* * *

textil adj textile

Whinfield, John Rex

SUBJECT AREA: Chemical technology, Synthetic materials

[br]

b. 16 February 1901 Sutton, Surrey, England

d. 6 July 1955 Dorking, Surrey, England

[br]

English inventor ofTerylene.

[br]

Whinfield was educated at Merchant Taylors' School and Caius College, Cambridge, where he studied chemistry. Before embarking on his career as a research chemist, he worked as an un-paid assistant to the chemist C.F. Cross, who had taken part in the discovery of rayon. Whinfield then joined the Calico Printers' Association. There his interest was aroused by the discovery of nylon by W.H. Carothers to seek other polymers which could be produced in fibre form, usable by the textile industries. With his colleague J.T. Dickson, he discovered in 1941 that a polymerized condensate of terephthalic acid and ethylene glycol, polyethylene terephthgal-late, could be drawn into strong fibres. Whinfield and Dickson filed a patent application in the same year, but due to war conditions it was not published until 1946. The Ministry of Supply considered that the new material might have military applications and undertook further research and development. Its industrial and textile possibilities were evaluated by Imperial Chemical Industries (ICI) in 1943 and "Terylene", as it came to be called, was soon recognized as being as important as nylon.

In 1946, Dupont acquired rights to work the Calico Printers' Association patent in the USA and began large-scale manufacture in 1954, marketing the product under the name "Dacron". Meanwhile ICI purchased world rights except for the USA and reached the large-scale manufacture stage in 1955. A new branch of the textile industry has grown up from Whinfield's discovery: he lived to see most people in the western world wearing something made of Terylene. It was one of the major inventions of the twentieth century, yet Whinfield, perhaps because he published little, received scant recognition, apart from the CBE in 1954.

[br]

Principal Honours and Distinctions

CBE 1954.

Further Reading

Obituary, 1966, The Times (7 July).

Obituary, 1967, Chemistry in Britain 3:26.

J.Jewkes, D.Sawers and R.Stillerman, 1969, The Sources of Invention, 2nd edn, London: Macmillan.

LRD

Fairbairn, Sir Peter

SUBJECT AREA: Textiles

[br]

b. September 1799 Kelso, Roxburghshire, Scotland

d. 4 January 1861 Leeds, Yorkshire, England

[br]

British inventor of the revolving tube between drafting rollers to give false twist.

[br]

Born of Scottish parents, Fairbairn was apprenticed at the age of 14 to John Casson, a mill-wright and engineer at the Percy Main Colliery, Newcastle upon Tyne, and remained there until 1821 when he went to work for his brother William in Manchester. After going to various other places, including Messrs Rennie in London and on the European continent, he eventually moved in 1829 to Leeds where Marshall helped him set up the Wellington Foundry and so laid the foundations for the colossal establishment which was to employ over one thousand workers. To begin with he devoted his attention to improving wool-weaving machinery, substituting iron for wood in the construction of the textile machines. He also worked on machinery for flax, incorporating many of Philippe de Girard's ideas. He assisted Henry Houldsworth in the application of the differential to roving frames, and it was to these machines that he added his own inventions. The longer fibres of wool and flax need to have some form of support and control between the rollers when they are being drawn out, and inserting a little twist helps. However, if the roving is too tightly twisted before passing through the first pair of rollers, it cannot be drawn out, while if there is insufficient twist, the fibres do not receive enough support in the drafting zone. One solution is to twist the fibres together while they are actually in the drafting zone between the rollers. In 1834, Fairbairn patented an arrangement consisting of a revolving tube placed between the drawing rollers. The tube inserted a "middle" or "false" twist in the material. As stated in the specification, it was "a well-known contrivance… for twisting and untwisting any roving passing through it". It had been used earlier in 1822 by J. Goulding of the USA and a similar idea had been developed by C.Danforth in America and patented in Britain in 1825 by J.C. Dyer. Fairbairn's machine, however, was said to make a very superior article. He was also involved with waste-silk spinning and rope-yarn machinery.

Fairbairn later began constructing machine tools, and at the beginning of the Crimean War was asked by the Government to make special tools for the manufacture of armaments. He supplied some of these, such as cannon rifling machines, to the arsenals at Woolwich and Enfield. He then made a considerable number of tools for the manufacture of the Armstrong gun. He was involved in the life of his adopted city and was elected to Leeds town council in 1832 for ten years. He was elected an alderman in 1854 and was Mayor of Leeds from 1857 to 1859, when he was knighted by Queen Victoria at the opening of the new town hall. He was twice married, first to Margaret Kennedy and then to Rachel Anne Brindling.

[br]

Principal Honours and Distinctions

Knighted 1858.

Bibliography

1834, British patent no. 6,741 (revolving tube between drafting rollers to give false twist).

Further Reading

Dictionary of National Biography.

Obituary, 1861, Engineer 11.

W.English, 1969, The Textile Industry, London (provides a brief account of Fairbairn's revolving tube).

C.Singer (ed.), 1958, A History of Technology, Vols IV and V, Oxford: Clarendon Press (provides details of Fairbairn's silk-dressing machine and a picture of a large planing machine built by him).

RLH

Leblanc, Nicolas

SUBJECT AREA: Chemical technology

[br]

b. 6 December 1742 Ivey-le-Pré, France

d. 16 January 1806 Paris, France

[br]

French chemist, inventor of the Leblanc process for the manufacture of soda.

[br]

Orphaned at an early age, Leblanc was sent by his guardian, a doctor, to study medicine at the Ecole de Chirurgie in Paris. Around 1780 he entered the service of the Duke of Orléans as Surgeon. There he was able to pursue his interest in chemistry by carrying out research, particularly into crystallization; this bore fruit in a paper to the Royal Academy of Sciences in 1786, published in 1812 as a separate work entitled Crystallotechnie. At that time there was much concern that supplies of natural soda were becoming insufficient to meet the increasing demands of various industries, textile above all. In 1775 the Academy offered a prize of 2,400 livres for a means of manufacturing soda from sea salt. Several chemists studied the problem, but the prize was never awarded. However, in 1789 Leblanc reported in the Journal de physique for 1789 that he had devised a process, and he applied to his patron for support. The Duke had the process subjected to tests, and when these proved favourable he, with Leblanc and the referee, formed a company in February 1790 to exploit it. A patent was granted in 1791 and, with the manufacture of a vital substance at low cost based on a raw material, salt in unlimited supply, a bright prospect seemed to open out for Leblanc. The salt was treated with sulphuric acid to form salt-cake (sodium sulphate), which was then rotated with coal and limestone to form a substance from which the soda was extracted with water followed by evaporation. Hydrochloric acid was a valuable by-product, from which could be made calcium chloride, widely used in the textile and paper industries. The factory worked until 1793, but did not achieve regular production, and then disaster struck: Leblanc's principal patron, the Duke of Orléans, perished under the guillotine in the reign of terror; the factory was sequestered by the Revolutionary government and the agreement was revoked. Leblanc laboured in vain to secure adequate compensation. Eventually a grant was made towards the cost of restoring the factory, but it was quite inadequate, and in despair, Leblanc shot himself. However, his process proved to be one of the greatest inventions in the chemical industry, and was taken up in other countries and remained the leading process for the production of soda for a century. In 1855 his family tried again to vindicate his name and achieve compensation, this time with success.

[br]

Further Reading

A.A.Leblanc, 1884, Nicolas Leblanc, sa vie, ses travaux et l'histoire de la soude artificielle, Paris (the standard biography, by his grandson).

For more critical studies, see: C.C.Gillispie, 1957, "The discovery of the Leblanc process", Isis 48:152–70; J.G.Smith, 1970, "Studies in certain chemical industries in revolutionary and Napoleonic France", unpublished PhD thesis, Leeds University.

LRD

Tennant, Charles

SUBJECT AREA: Chemical technology, Textiles

[br]

b. 3 May 1768 Ochiltree, Ayrshire, Scotland

d. 1 October 1838 Glasgow, Scotland

[br]

Scottish inventor of bleaching powder.

[br]

After education at the local school, Tennant went to Kilbachan to learn the manufacture of silk. He then went on to Wellmeadow, where he acquired a knowledge of the old bleaching process, which enabled him to establish his own bleachfield at Darnly. The process consisted of boiling the fabric in weak alkali and then laying it flat on the ground to expose it to sun and air for several months. This process, expensive in time and space, would have formed an intolerable bottleneck in the rapidly expanding textile industry, but a new method was on the way. The French chemist Berthollet demonstrated in 1786 the use of chlorine as a bleaching agent and James Watt learned of this while on a visit to Paris. On his return to Glasgow, Watt passed details of the new process on to Tennant, who set about devising his own version of it. First he obtained a bleaching liquor by passing chlorine through a stirred mixture of lime and water. He was granted a patent for this process in 1798, but it was promptly infringed by bleachers in Lancashire. Tennant's efforts to enforce the patent were unsuccessful as it was alleged that others had employed a similar process some years previously. Nevertheless, the Lancashire bleachers had the good grace to present Tennant with a service of plate in recognition of the benefits he had brought to the industry.

In 1799 Tennant improved on his process by substituting dry slaked lime for the liquid, to form bleaching powder. This was patented the same year and proved to be a vital element in the advance of the textile industry. The following year, Tennant established his chemical plant at St Roll ox, outside Glasgow, to manufacture bleaching powder and alkali substances. The plant prospered and became for a time the largest chemical works in Europe.

[br]

Further Reading

L.F.Haber, 1958, The Chemical Industry During the Nineteenth Century, London: Oxford University Press.

F.S.Taylor, 1957, A History of Industrial Chemistry, London: Heinemann.

Walker, 1862, Memoirs of Distinguished Men of Science of Great Britain Living in 1807– 1808, London, p. 186.

LRD

Spencer, Christopher Miner

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Textiles, Weapons and armour

[br]

b. 10 June 1833 Manchester, Connecticut, USA

d. 14 January 1922 Hartford, Connecticut, USA

[br]

American mechanical engineer and inventor.

[br]

Christopher M.Spencer served an apprenticeship from 1847 to 1849 in the machine shop at the silk mills of Cheney Brothers in his native town and remained there for a few years as a journeyman machinist. In 1853 he went to Rochester, New York, to obtain experience with machinery other than that used in the textile industry. He then spent some years with the Colt Armory at Hartford, Connecticut, before returning to Cheney Brothers, where he obtained his first patent, which was for a silk-winding machine.

Spencer had long been interested in firearms and in 1860 he obtained a patent for a repeating rifle. The Spencer Repeating Rifle Company was organized for its manufacture, and before the end of the American Civil War about 200,000 rifles had been produced. He patented a number of other improvements in firearms and in 1868 was associated with Charles E.Billings (1835–1920) in the Roper Arms Company, set up at Amherst, Massachusetts, to manufacture Spencer's magazine gun. This was not a success, however, and in 1869 they moved to Hartford, Connecticut, and formed the Billings \& Spencer Company. There they developed the technology of the drop hammer and Spencer continued his inventive work, which included an automatic turret lathe for producing metal screws. The patent that he obtained for this in 1873 inexplicably failed to protect the essential feature of the machine which provided the automatic action, with the result that Spencer received no patent right on the most valuable feature of the machine.

In 1874 Spencer withdrew from active connection with Billings \& Spencer, although he remained a director, and in 1876 he formed with others the Hartford Machine Screw Company. However, he withdrew in 1882 to form the Spencer Arms Company at Windsor, Connecticut, for the manufacture of another of his inventions, a repeating shotgun. But this company failed and Spencer returned to the field of automatic lathes, and in 1893 he organized the Spencer Automatic Machine Screw Company at Windsor, where he remained until his retirement.

[br]

Further Reading

J.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (briefly describes his career and his automatic lathes).

L.T.C.Rolt, 1965, Tools for the Job, London; repub. 1986 (gives a brief description of Spencer's automatic lathes).

RTS

industria

f industry

( operosità) industriousness

industria automobilistica car industry

industria dei servizi service industry, services

industria pesante heavy industry

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industria s.f.

1 industry; (fabbricazione) manufacture; (attività industriale) trade; (impresa industriale) industrial concern, industry: piccola, media, grande industria, small, medium-size, big industry; industria agricola, agricultural industry; industria alimentare, food industry; industria a sovvenzione statale, subsidized industry; industria a tecnologia avanzata, high-technology industry; industria casearia, dairy industry; industria chiave, key industry; industria conserviera, canning (o tinning) industry; industria dell'abbigliamento, clothing industry; l'industria dell'automobile, the car industry; industria dei servizi, terziaria, service (o tertiary) industry; industria dei trasporti, carrying trade; industria del freddo, frozen foods industry; industria dello spettacolo, entertainment industry (o show business); industria di base, basic industry; l'industria delle costruzioni, the building industry; industria dolciaria, confectionery (industry); industria farmaceutica, pharmaceuticals (o pharmaceutical company); industria leggera, pesante, light, heavy industry; industria manifatturiera, manufacturing industry; industria metalmeccanica, engineering industry; industria mineraria, mining industry; industria navale, shipping industry; industria nazionale, domestic industry; industria nazionalizzata, nationalized industry; industria petrolchimica, petrochemical industry; industria primaria, secondaria, primary, secondary industry; industria siderurgica, iron and steel industry; industria tessile, textile industry; industria turistica, tourist industry; industrie del tempo libero, leisure industries; industrie di trasformazione, manufacturing industries; industrie estrattive, extractive industries; industrie grafiche ed editoriali, printing and publishing

2 (assiduità, zelo) industry, diligence

3 (letter.) (abilità) skill, cleverness; (ingegnosità) astuteness, cunning // vivere d'industria, to live by one's wits.

* * *

[in'dustrja]

sostantivo femminile

1) (attività, settore) industry

piccola, media industria — small, medium-sized industry

grande industria — big industries o business

2) (azienda) factory, works pl.

•

industria alimentare — food industry

industria automobilistica — car o motor industry

industria bellica — armament industry

industria chimica — chemical industry

industria farmaceutica — drug o pharmaceutical industry

industria leggera — light industry

industria meccanica — engineering industry

industria mineraria — mining industry

industria pesante — heavy industry

industria petrolifera — oil industry

industria siderurgica — steel industry

industria dello spettacolo — show business

industria tessile — textile industry

* * *

industria

/in'dustrja/

sostantivo f.

 1 (attività, settore) industry; piccola, media industria small, medium-sized industry; grande industria big industries o business

 2 (azienda) factory, works pl.

COMPOUNDS

industria alimentare food industry; industria automobilistica car o motor industry; industria bellica armament industry; industria chimica chemical industry; industria farmaceutica drug o pharmaceutical industry; industria leggera light industry; industria meccanica engineering industry; industria mineraria mining industry; industria pesante heavy industry; industria petrolifera oil industry; industria siderurgica steel industry; industria dello spettacolo show business; industria tessile textile industry.

Arnold, Aza

SUBJECT AREA: Textiles

[br]

b. 4 October 1788 Smithfield, Pawtucket, Rhode Island, USA

d. 1865 Washington, DC, USA

[br]

American textile machinist who applied the differential motion to roving frames, solving the problem of winding on the delicate cotton rovings.

[br]

He was the son of Benjamin and Isabel Arnold, but his mother died when he was 2 years old and after his father's second marriage he was largely left to look after himself. After attending the village school he learnt the trade of a carpenter, and following this he became a machinist. He entered the employment of Samuel Slater, but left after a few years to engage in the unsuccessful manufacture of woollen blankets. He became involved in an engineering shop, where he devised a machine for taking wool off a carding machine and making it into endless slivers or rovings for spinning. He then became associated with a cotton-spinning mill, which led to his most important invention. The carded cotton sliver had to be reduced in thickness before it could be spun on the final machines such as the mule or the waterframe. The roving, as the mass of cotton fibres was called at this stage, was thin and very delicate because it could not be twisted to give strength, as this would not allow it to be drawn out again during the next stage. In order to wind the roving on to bobbins, the speed of the bobbin had to be just right but the diameter of the bobbin increased as it was filled. Obtaining the correct reduction in speed as the circumference increased was partially solved by the use of double-coned pulleys, but the driving belt was liable to slip owing to the power that had to be transmitted.

The final solution to the problem came with the introduction of the differential drive with bevel gears or a sun-and-planet motion. Arnold had invented this compound motion in 1818 but did not think of applying it to the roving frame until 1820. It combined the direct-gearing drive from the main shaft of the machine with that from the cone-drum drive so that the latter only provided the difference between flyer and bobbin speeds, which meant that most of the transmission power was taken away from the belt. The patent for this invention was issued to Arnold on 23 January 1823 and was soon copied in Britain by Henry Houldsworth, although J.Green of Mansfield may have originated it independendy in the same year. Arnold's patent was widely infringed in America and he sued the Proprietors of the Locks and Canals, machine makers for the Lowell manufacturers, for $30,000, eventually receiving $3,500 compensation. Arnold had his own machine shop but he gave it up in 1838 and moved the Philadelphia, where he operated the Mulhausen Print Works. Around 1850 he went to Washington, DC, and became a patent attorney, remaining as such until his death. On 24 June 1856 he was granted patent for a self-setting and self-raking saw for sawing machines.

[br]

Bibliography

28 June 1856, US patent no. 15,163 (self-setting and self-raking saw for sawing machines).

Further Reading

Dictionary of American Biography, Vol. 1.

W.English, 1969, The Textile Industry, London (a description of the principles of the differential gear applied to the roving frame).

D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830, Oxford (a discussion of the introduction and spread of Arnold's gear).

RLH

Radcliffe, William

SUBJECT AREA: Textiles

[br]

b. 1761 Mellor, Cheshire, England

d. 1842 Mellor, Cheshire, England

[br]

English inventor of the sizing machine.

[br]

Radcliffe was brought up in the textile industry and learned carding and spinning as a child. When he was old enough, he became a weaver. It was a time when there were not enough weavers to work up all the yarn being spun on the recently invented spinning machines, so some yarn was exported. Radcliffe regarded this as a sin; meetings were held to prohibit the export, and Radcliffe promised to use his best endeavours to discover means to work up the yarn in England. He owned a mill at Mellor and by 1801 was employing over 1,000 hand-loom weavers. He wanted to improve their efficiency so they could compete against power looms, which were beginning to be introduced at that time.

His first step was to divide up as much as possible the different weaving processes, not unlike the plan adopted by Arkwright in spinning. In order to strengthen the warp yarns made of cotton and to reduce their tendency to fray during weaving, it was customary to apply an adhesive substance such as starch paste. This was brushed on as the warp was unwound from the back beam during weaving, so only short lengths could be treated before being dried. Instead of dressing the warp in the loom as was hitherto done, Radcliffe had it dressed in a separate machine, relieving the weaver of the trouble and saving the time wasted by the method previously used. Radcliffe employed a young man names Thomas Johnson, who proved to be a clever mechanic. Radcliffe patented his inventions in Johnson's name to avoid other people, especially foreigners, finding out his ideas. He took out his first patent, for a dressing machine, in March 1803 and a second the following year. The combined result of the two patents was the introduction of a beaming machine and a dressing machine which, in addition to applying the paste to the yarns and then drying them, wound them onto a beam ready for the loom. These machines enabled the weaver to work a loom with fewer stoppages; however, Radcliffe did not anticipate that his method of sizing would soon be applied to power looms as well and lead to the commercial success of powered weaving. Other manufacturers quickly adopted Radcliffe's system, and Radcliffe himself soon had to introduce power looms in his own business.

Radcliffe improved the hand looms themselves when, with the help of Johnson, he devised a cloth taking-up motion that wound the woven cloth onto a roller automatically as the weaver operated the loom. Radcliffe and Johnson also developed the "dandy loom", which was a more compact form of hand loom and was also later adapted for weaving by power. Radcliffe was among the witnesses before the Parliamentary Committee which in 1808 awarded Edmund Cartwright a grant for his invention of the power loom. Later Radcliffe was unsuccessfully to petition Parliament for a similar reward for his contributions to the introduction of power weaving. His business affairs ultimately failed partly through his own obstinacy and his continued opposition to the export of cotton yarn. He lived to be 81 years old and was buried in Mellor churchyard.

[br]

Bibliography

1811, Exportation of Cotton Yarn and Real Cause of the Distress that has Fallen upon the Cotton Trade for a Series of Years Past, Stockport.

1828, Origin of the New System of Manufacture, Commonly Called "Power-Loom Weaving", Stockport (this should be read, even though it is mostly covers Radcliffe's political aims).

Further Reading

A.Barlow, 1870, The History and Principles of Weaving by Hand and by Power, London (provides an outline of Radcliffe's life and work).

W.English, 1969, The Textile Industry, London (a general background of his inventions). R.L.Hills, 1970, Power in the Industrial Revolution, Manchester (a general background).

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

RLH

перерабатывать

1) General subject: convert, manufacture, manufacture (сырье), overdrive, overtire, overwork, process, recast, remake, remanufacture, revise, rewrite, work, work over, overtire oneself, reingeneer, work long hours

2) Geology: retreat (подвергать повторной обработке)

3) Engineering: clear (почтовые отправления), digest, process (подвергать обработке), recover, redesign (проект или конструкцию), reprocess (подвергать повторной обработке), retreat, revise (напр. статью), treat (подвергать обработке), work over (подвергать обработке), work overtime (работать сверх нормы), overhaul

4) Agriculture: slaughter (скот)

5) Mathematics: alter, change, transform

6) Accounting: recycle (отходы), reprocess

7) Mining: refine (нефть)

8) Metallurgy: handle (грузы)

9) Polygraphy: rewrite (текст)

10) TV: produce (сценарий, программу ( в том числе адаптировать))

11) Textile: convert (сырьё), run

12) Jargon: rip off (недобросовестно; произведение), (недобросовестно) rip off (произведение)

13) Information technology: crunch

14) Oil: refine (нефть), rework

15) Business: adapt, handle, improve

16) Polymers: work

17) Automation: redevelop (конструкцию)

18) leg.N.P. redraft, revise (a draft, such as draft resolution, draft convention, or draft statute)

19) Makarov: clear (груз, почтовые отправления), process (подвергать обработке, напр. сырье в полуфабрикат или готовую продукцию), refine (напр. нефть), revise (переделывать, напр. книгу статью), rewrite (о тексте), work (подвергать обработке, напр. сырье в полуфабрикат или готовую продукцию), work overtune (работать сверх нормы), convert into

суконное производство

1) General subject: cloth manufacture

2) Textile: cloth industry, woolen manufacture

Viscose

VISCOSE

Viscose was discovered by two English chemists, Charles F. Cross and E. J. Be van, working in collaboration at Kew, near London, who found that when cellulose was treated with disulphide of carbon in the presence of caustic soda, it was converted into a golden yellow plastic compound which dissolved readily in water. A solution of the plastic was of such viscosity that it was named " viscose," a name that was destined to become world famous, seeing that round about 88 per cent of the world production of rayon is now made by the viscose process. In 1892 Cross and Bevan were granted a patent on the viscose process and it was applied to many purposes before the production of a textile thread was successfully accomplished. Fundamentally, the manufacture of viscose rayon is fairly simple. The raw material may be wood pulp, pulp from cotton linters, or a mixture of the two. The greater part of the world's viscose is made from wood pulp. Viscose rayon manufacture comprises seven distinct treatments as follows: - 1. Making and purifying the cotton or wood pulp which forms the cellulose base. 2. Caustic soda treatment of the cellulose base thereby forming alkali cellulose. 3. Treatment of alkali cellulose with carbon disulphide, forming cellulose xanthate. 4. Dissolving the cellulose xanthate in weak caustic soda to form cellulose solution or viscose. 5. Spinning viscose into yarn. 6. Bleaching, purification and finishing of the yarn. 7. Preparing the yarn for weaving and knitting.

Daimler, Gottlieb

SUBJECT AREA: Automotive engineering, Land transport

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b. 17 March 1834 Schorndorff, near Stuttgart, Germany

d. 6 March 1900 Cannstatt, near Stuttgart, Germany

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German engineer, pioneer automobile maker.

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The son of a baker, his youthful interest in technical affairs led to his being apprenticed to a gunsmith with whom he produced his apprenticeship piece: a double-barrelled pistol with a rifled barrel and "nicely chased scrollwork", for which he received high praise. He remained there until 1852 before going to technical school in Stuttgart from 1853 to 1857. He then went to a steam-engineering company in Strasbourg to gain practical experience. He completed his formal education at Stuttgart Polytechnik, and in 1861 he left to tour France and England. There he worked in the engine-shop of Smith, Peacock \& Tanner and then with Roberts \& Co., textile machinery manufacturers of Manchester. He later moved to Coventry to work at Whitworths, and it was in that city that he was later involved with the Daimler Motor Company, who had been granted a licence by his company in Germany. In 1867 he was working at Bruderhaus Engineering Works at Reutlingen and in 1869 went to Maschinenbau Gesellschaft Karlsruhe where he became Manager and later a director. Early in the 1870s, N.A. Otto had reorganized his company into Gasmotorenfabrik Deutz and he appointed Gottlieb Daimler as Factory Manager and Wilhelm Maybach as Chief Designer. Together they developed the Otto engine to its limit, with Otto's co-operation. Daimler and Maybach had met previously when both were working at Bruderhaus. In 1875 Daimler left Deutz, taking Maybach with him to set up a factory in Stuttgart to manufacture light, high-speed internal-combustion engines. Their first patent was granted in 1883. This was for an engine fuelled by petrol and with hot tube ignition which continued to be used until Robert Bosch's low-voltage ignition became available in 1897. Two years later he produced his first vehicle, a motor cycle with outriggers. They showed a motor car at the Paris exhibition in 1889, but French manufacturers were slow to come forward and no French company could be found to undertake manufacture. Eventually Panhard and Levassor established the Daimler engine in France. Daimler Motoren GmbH was started in 1895, but soon after Daimler and Maybach parted, having provided an engine for a boat on the River Neckar in 1887 and that for the Wolfert airship in 1888. Daimler was in sole charge of the company from 1895, but his health began to decline in 1899 and he died in 1900.

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Further Reading

E.Johnson, 1986, The Dawn of Motoring. P.Siebetz, 1942, Gottlieb Daimler.

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Dyer, Joseph Chessborough

SUBJECT AREA: Textiles

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b. 15 November 1780 Stonnington Point, Connecticut, USA

d. 2 May 1871 Manchester, England

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American inventor of a popular type of roving frame for cotton manufacture.

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As a youth, Dyer constructed an unsinkable life-boat but did not immediately pursue his mechanical bent, for at 16 he entered the counting-house of a French refugee named Nancrède and succeeded to part of the business. He first went to England in 1801 and finally settled in 1811 when he married Ellen Jones (d. 1842) of Gower Street, London. Dyer was already linked with American inventors and brought to England Perkins's plan for steel engraving in 1809, shearing and nail-making machines in 1811, and also received plans and specifications for Fulton's steamboats. He seems to have acted as a sort of British patent agent for American inventors, and in 1811 took out a patent for carding engines and a card clothing machine. In 1813 there was a patent for spinning long-fibred substances such as hemp, flax or grasses, and in 1825 there was a further patent for card making machinery. Joshua Field, on his tour through Britain in 1821, saw a wire drawing machine and a leather splitting machine at Dyer's works as well as the card-making machines. At first Dyer lived in Camden Town, London, but he had a card clothing business in Birmingham. He moved to Manchester c.1816, where he developed an extensive engineering works under the name "Joseph C.Dyer, patent card manufacturers, 8 Stanley Street, Dale Street". In 1832 he founded another works at Gamaches, Somme, France, but this enterprise was closed in 1848 with heavy losses through the mismanagement of an agent. In 1825 Dyer improved on Danforth's roving frame and started to manufacture it. While it was still a comparatively crude machine when com-pared with later versions, it had the merit of turning out a large quantity of work and was very popular, realizing a large sum of money. He patented the machine that year and must have continued his interest in these machines as further patents followed in 1830 and 1835. In 1821 Dyer had been involved in the foundation of the Manchester Guardian (now The Guardian) and he was linked with the construction of the Liverpool \& Manchester Railway. He was not so successful with the ill-fated Bank of Manchester, of which he was a director and in which he lost £98,000. Dyer played an active role in the community and presented many papers to the Manchester Literary and Philosophical Society. He helped to establish the Royal Institution in London and the Mechanics Institution in Manchester. In 1830 he was a member of the delegation to Paris to take contributions from the town of Manchester for the relief of those wounded in the July revolution and to congratulate Louis-Philippe on his accession. He called for the reform of Parliament and helped to form the Anti-Corn Law League. He hated slavery and wrote several articles on the subject, both prior to and during the American Civil War.

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Bibliography

1811, British patent no. 3,498 (carding engines and card clothing machine). 1813, British patent no. 3,743 (spinning long-fibred substances).

1825, British patent no. 5,309 (card making machinery).

1825, British patent no. 5,217 (roving frame). 1830, British patent no. 5,909 (roving frame).

1835, British patent no. 6,863 (roving frame).

Further Reading

Dictionary of National Biography.

J.W.Hall, 1932–3, "Joshua Field's diary of a tour in 1821 through the Midlands", Transactions of the Newcomen Society 6.

Evan Leigh, 1875, The Science of Modern Cotton Spinning, Vol. II, Manchester (provides an account of Dyer's roving frame).

D.J.Jeremy, 1981, Transatlantic Industrial Revolution: The Diffusion of Textile

Technologies Between Britain and America, 1790–1830s, Oxford (describes Dyer's links with America).

See also: Arnold, Aza

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Ferranti, Sebastian Ziani de

SUBJECT AREA: Electricity, Public utilities

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b. 9 April 1864 Liverpool, England

d. 13 January 1930 Zurich, Switzerland

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English manufacturing engineer and inventor, a pioneer and early advocate of high-voltage alternating-current electric-power systems.

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Ferranti, who had taken an interest in electrical and mechanical devices from an early age, was educated at St Augustine's College in Ramsgate and for a short time attended evening classes at University College, London. Rather than pursue an academic career, Ferranti, who had intense practical interests, found employment in 1881 with the Siemens Company (see Werner von Siemens) in their experimental department. There he had the opportunity to superintend the installation of electric-lighting plants in various parts of the country. Becoming acquainted with Alfred Thomson, an engineer, Ferranti entered into a short-lived partnership with him to manufacture the Ferranti alternator. This generator, with a unique zig-zag armature, had an efficiency exceeding that of all its rivals. Finding that Sir William Thomson had invented a similar machine, Ferranti formed a company with him to combine the inventions and produce the Ferranti- Thomson machine. For this the Hammond Electric Light and Power Company obtained the sole selling rights.

In 1885 the Grosvenor Gallery Electricity Supply Corporation was having serious problems with its Gaulard and Gibbs series distribution system. Ferranti, when consulted, reviewed the design and recommended transformers connected across constant-potential mains. In the following year, at the age of 22, he was appointed Engineer to the company and introduced the pattern of electricity supply that was eventually adopted universally. Ambitious plans by Ferranti for London envisaged the location of a generating station of unprecedented size at Deptford, about eight miles (13 km) from the city, a departure from the previous practice of placing stations within the area to be supplied. For this venture the London Electricity Supply Corporation was formed. Ferranti's bold decision to bring the supply from Deptford at the hitherto unheard-of pressure of 10,000 volts required him to design suitable cables, transformers and generators. Ferranti planned generators with 10,000 hp (7,460 kW)engines, but these were abandoned at an advanced stage of construction. Financial difficulties were caused in part when a Board of Trade enquiry in 1889 reduced the area that the company was able to supply. In spite of this adverse situation the enterprise continued on a reduced scale. Leaving the London Electricity Supply Corporation in 1892, Ferranti again started his own business, manufacturing electrical plant. He conceived the use of wax-impregnated paper-insulated cables for high voltages, which formed a landmark in the history of cable development. This method of flexible-cable manufacture was used almost exclusively until synthetic materials became available. In 1892 Ferranti obtained a patent which set out the advantages to be gained by adopting sector-shaped conductors in multi-core cables. This was to be fundamental to the future design and development of such cables.

A total of 176 patents were taken out by S.Z. de Ferranti. His varied and numerous inventions included a successful mercury-motor energy meter and improvements to textile-yarn produc-tion. A transmission-line phenomenon where the open-circuit voltage at the receiving end of a long line is greater than the sending voltage was named the Ferranti Effect after him.

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Principal Honours and Distinctions

FRS 1927. President, Institution of Electrical Engineers 1910 and 1911. Institution of Electrical Engineers Faraday Medal 1924.

Bibliography

18 July 1882, British patent no. 3,419 (Ferranti's first alternator).

13 December 1892, British patent no. 22,923 (shaped conductors of multi-core cables). 1929, "Electricity in the service of man", Journal of the Institution of Electrical Engineers 67: 125–30.

Further Reading

G.Z.de Ferranti and R. Ince, 1934, The Life and Letters of Sebastian Ziani de Ferranti, London.

A.Ridding, 1964, S.Z.de Ferranti. Pioneer of Electric Power, London: Science Museum and HMSO (a concise biography).

R.H.Parsons, 1939, Early Days of the Power Station Industry, Cambridge, pp. 21–41.

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Heathcote, John

SUBJECT AREA: Textiles

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b. 7 August 1783 Duffield, Derbyshire, England

d. 18 January 1861 Tiverton, Devonshire, England

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English inventor of the bobbin-net lace machine.

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Heathcote was the son of a small farmer who became blind, obliging the family to move to Long Whatton, near Loughborough, c.1790. He was apprenticed to W.Shepherd, a hosiery-machine maker, and became a frame-smith in the hosiery industry. He moved to Nottingham where he entered the employment of an excellent machine maker named Elliott. He later joined William Caldwell of Hathern, whose daughter he had married. The lace-making apparatus they patented jointly in 1804 had already been anticipated, so Heathcote turned to the problem of making pillow lace, a cottage industry in which women made lace by arranging pins stuck in a pillow in the correct pattern and winding around them thread contained on thin bobbins. He began by analysing the complicated hand-woven lace into simple warp and weft threads and found he could dispense with half the bobbins. The first machine he developed and patented, in 1808, made narrow lace an inch or so wide, but the following year he made much broader lace on an improved version. In his second patent, in 1809, he could make a type of net curtain, Brussels lace, without patterns. His machine made bobbin-net by the use of thin brass discs, between which the thread was wound. As they passed through the warp threads, which were arranged vertically, the warp threads were moved to each side in turn, so as to twist the bobbin threads round the warp threads. The bobbins were in two rows to save space, and jogged on carriages in grooves along a bar running the length of the machine. As the strength of this fabric depended upon bringing the bobbin threads diagonally across, in addition to the forward movement, the machine had to provide for a sideways movement of each bobbin every time the lengthwise course was completed. A high standard of accuracy in manufacture was essential for success. Called the "Old Loughborough", it was acknowledged to be the most complicated machine so far produced. In partnership with a man named Charles Lacy, who supplied the necessary capital, a factory was established at Loughborough that proved highly successful; however, their fifty-five frames were destroyed by Luddites in 1816. Heathcote was awarded damages of £10,000 by the county of Nottingham on the condition it was spent locally, but to avoid further interference he decided to transfer not only his machines but his entire workforce elsewhere and refused the money. In a disused woollen factory at Tiverton in Devonshire, powered by the waters of the river Exe, he built 300 frames of greater width and speed. By continually making inventions and improvements until he retired in 1843, his business flourished and he amassed a large fortune. He patented one machine for silk cocoon-reeling and another for plaiting or braiding. In 1825 he brought out two patents for the mechanical ornamentation or figuring of lace. He acquired a sound knowledge of French prior to opening a steam-powered lace factory in France. The factory proved to be a successful venture that lasted many years. In 1832 he patented a monstrous steam plough that is reputed to have cost him over £12,000 and was claimed to be the best in its day. One of its stated aims was "improved methods of draining land", which he hoped would develop agriculture in Ireland. A cable was used to haul the implement across the land. From 1832 to 1859, Heathcote represented Tiverton in Parliament and, among other benefactions, he built a school for his adopted town.

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Bibliography

1804, with William Caldwell, British patent no. 2,788 (lace-making machine). 1808. British patent no. 3,151 (machine for making narrow lace).

1809. British patent no. 3,216 (machine for making Brussels lace). 1813, British patent no. 3,673.

1825, British patent no. 5,103 (mechanical ornamentation of lace). 1825, British patent no. 5,144 (mechanical ornamentation of lace).

Further Reading

V.Felkin, 1867, History of the Machine-wrought Hosiery and Lace Manufacture, Nottingham (provides a full account of Heathcote's early life and his inventions).

A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London (provides more details of his later years).

W.G.Allen, 1958 John Heathcote and His Heritage (biography).

M.R.Lane, 1980, The Story of the Steam Plough Works, Fowlers of Leeds, London (for comments about Heathcote's steam plough).

W.English, 1969, The Textile Industry, London, and C.Singer (ed.), 1958, A History of

Technology, Vol. V, Oxford: Clarendon Press (both describe the lace-making machine).

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Weldon, Walter

SUBJECT AREA: Chemical technology

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b. 31 October 1832 Loughborough, England

d. 20 September 1885 Burstow, Surrey, England

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English industrial chemist.

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It was intended that Weldon should enter his father's factory in Loughborough, but he decided instead to turn to journalism, which he pursued with varying success in London. His Weldon's Register of Facts and Occurrences in Literature, Science, and Art ran for only four years, from 1860 to 1864, but the fashion magazine Weldon's Journal, which he published with his wife, was more successful. Meanwhile Weldon formed an interest in chemistry, although he had no formal training in that subject. He devoted himself to solving one of the great problems of industrial chemistry at that time. The Leblanc process for the manufacture of soda produced large quantities of hydrochloric acid in gas form. By this time, this by-product was being converted, by oxidation with manganese dioxide, to chlorine, which was much used in the textile and paper industries as a bleaching agent. The manganese ended up as manganese chloride, from which it was difficult to convert back to the oxide, for reuse in treating the hydrochloric acid, and it was an expensive substance. Weldon visited the St Helens district of Lancashire, an important centre for the manufacture of soda, to work on the problem. During the three years from 1866 to 1869, he took out six patents for the regeneration of manganese dioxide by treating the manganese chloride with milk of lime and blowing air through it. The Weldon process was quickly adopted and had a notable economic effect: the price of bleaching powder came down by £6 per ton and production went up fourfold.

By the time of his death, nearly all chlorine works in the world used Weldon's process. The distinguished French chemist J.B.A.Dumas said of the process, when presenting Weldon with a gold medal, "every sheet of paper and every yard of calico has been cheapened throughout the world". Weldon played an active part in the founding of the Society of Chemical Industry.

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Principal Honours and Distinctions

FRS 1882. President, Society of Chemical Industry 1883–4.

Further Reading

T.C.Barker and J.R.Harris, 1954, A Merseyside Town in the Industrial Revolution: St Helens, 1750–1900, Liverpool: Liverpool University Press; reprinted with corrections, 1959, London: Cass.

S.Miall, 1931, A History of the British Chemical Industry.

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Wyatt, John

SUBJECT AREA: Metallurgy, Textiles

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b. April 1700 Thickbroom, Weeford, near Lichfield, England

d. 29 November 1766 Birmingham, England

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English inventor of machines for making files and rolling lead, and co-constructor of a cotton-spinning machine.

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John Wyatt was the eldest son of John and Jane Wyatt, who lived in the small village of Thickbroom in the parish of Weeford, near Lichfield. John the younger was educated at Lichfield school and then worked as a carpenter at Thickbroom till 1730. In 1732 he was in Birmingham, engaged by a man named Heely, a gunbarrel forger, who became bankrupt in 1734. Wyatt had invented a machine for making files and sought the help of Lewis Paul to manufacture this commercially.

The surviving papers of Paul and Wyatt in Birmingham are mostly undated and show a variety of machines with which they were involved. There was a machine for "making lead hard" which had rollers, and "a Gymcrak of some consequence" probably refers to a machine for boring barrels or the file-making machine. Wyatt is said to have been one of the unsuccessful competitors for the erection of London Bridge in 1736. He invented and perfected the compound-lever weighing machine. He had more success with this: after 1744, machines for weighing up to five tons were set up at Birmingham, Chester, Gloucester, Hereford, Lichfield and Liverpool. Road construction, bridge building, hydrostatics, canals, water-powered engines and many other schemes received his attention and it is said that he was employed for a time after 1744 by Matthew Boulton.

It is certain that in April 1735 Paul and Wyatt were working on their spinning machine and Wyatt was making a model of it in London in 1736, giving up his work in Birmingham. The first patent, in 1738, was taken out in the name of Lewis Paul. It is impossible to know which of these two invented what. This first patent covers a wide variety of descriptions of the vital roller drafting to draw out the fibres, and it is unknown which system was actually used. Paul's carding patent of 1748 and his second spinning patent of 1758 show that he moved away from the system and principles upon which Arkwright built his success. Wyatt and Paul's spinning machines were sufficiently promising for a mill to be set up in 1741 at the Upper Priory, Birmingham, that was powered by two asses. Wyatt was the person responsible for constructing the machinery. Edward Cave established another at Northampton powered by water while later Daniel Bourn built yet another at Leominster. Many others were interested too. The Birmingham mill did not work for long and seems to have been given up in 1743. Wyatt was imprisoned for debt in The Fleet in 1742, and when released in 1743 he tried for a time to run the Birmingham mill and possibly the Northampton one. The one at Leominster burned down in 1754, while the Northampton mill was advertised for sale in 1756. This last mill may have been used again in conjunction with the 1758 patent. It was Wyatt whom Daniel Bourn contacted about a grant for spindles for his Leominster mill in 1748, but this seems to have been Wyatt's last association with the spinning venture.

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Further Reading

G.J.French, 1859, The Life and Times of Samuel Crompton, London (French collected many of the Paul and Wyatt papers; these should be read in conjunction with Hills 1970).

R.L.Hills, 1970, Power in the Industrial Revolution, Manchester (Hills shows that the rollerdrafting system on this spinning machine worked on the wrong principles). A.P.Wadsworth and J.de L.Mann, 1931, The Cotton Trade and Industrial Lancashire, 1600–1780, Manchester (provides good coverage of the partnership of Paul and Wyatt and of the early mills).

E.Baines, 1835, History of the Cotton Manufacture in Great Britain, London (this publication must be mentioned, although it is now out of date).

W.English, 1969, The Textile Industry, London (a more recent account).

W.A.Benton, "John Wyatt and the weighing of heavy loads", Transactions of the Newcomen Society 9 (for a description of Wyatt's weighing machine).

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