brought up the subject

brought up the subject

העלה את הנושא

* * *

◙ אשונה תא הלעה◄

brought up the subject

bracht het onderwerp op

brought up the subject

framförde [ämnet], bringade [ämnet] på tal

the subject was brought up

the subject was brought up

o assunto foi trazido à baila.

(the) importance of the matter cannot be overestimated

the importance of the matter (of the subject, of this idea, of good cooking, of good health, of a good digestion, of the study, of a foreign language) cannot be overestimated (has been brought home to me) важность вопроса (предмета, идеи, приготовления пищи, крепкого здоровья, хорошего пищеварения, учебы, иностранного языка) нельзя переоценить (дошла до моего сознания)

Subject

Подлежащее

↑ Clause elements

1) Подлежащее обычно обозначает то лицо или предмет, который производит действие или является носителем состояния (см. State verbs). В пассивной конструкции подлежащим является то лицо или предмет, который подвергается действию (см. Passive).

2) В обычном утвердительном предложении подлежащее находится в начальной позиции (подробнее о порядке слов см. Sentence: word order). Позиция подлежащего меняется:

а) при образовании вопросов (см. Question)

б) при образовании отрицаний (см. Negative sentence)

в) в некоторых случаях при инвертированном порядке слов (см. Inversion)

•

The shops close at 7 tonight. — Магазины закрываются сегодня в 7.

When do the shops close tonight? — Когда сегодня закрываются магазины?

3)

а) Подлежащее обычно выражается существительным ( Noun), местоимением (Pronoun) или именной группой (например, существительным и определяющим его прилагательным).

He has brought nothing but trouble here! — Он ничего не принес, кроме неприятностей!

In a remote corner, a small spectacled person was busy writing at a table. —В дальнем углу за столом сидел маленький человек в очках и что-то писал.

б) бывают случаи, когда подлежащее выражено целым придаточным предложением (такое придаточное называется именным, см. Nominal clause):

All you need to do is give him a call. — Единственное, что тебе нужно сделать - это ему позвонить. (Тебе нужно только ему позвонить)

4) Подлежащее согласуется в числе со сказуемым ( Predicate).

Troubles were many. — Проблем было много.

5) Иногда предложение содержит несовпадающее с логическим подлежащим формальное ("пустое") подлежащее (см. Empty subject: "it" and "there").

It's a pity my plan is spoilt. — Жаль, что мой план не удался.

6) О конструкции со сложным подлежащим см. Complex subject.

•

— Дополнение см. Object

— Сказуемое см. Predicate

Peter the Great (Pyotr Alekseyevich Romanov)

SUBJECT AREA: Ports and shipping

[br]

b. 10 June 1672 (30 May 1672 Old Style) Moscow, Russia

d. 8 February 1725 (28 January 1725 Old Style) St Petersburg, Russia

[br]

Russian Tsar (1682–1725), Emperor of all the Russias (1722–5), founder of the Russian Navy, shipbuilder and scientist; as a shipbuilder he was known by the pseudonym Petr Mikhailov.

[br]

Peter the Great was a man with a single-minded approach to problems and with passionate and lifelong interests in matters scientific, military and above all maritime. The unusual and dominating rule of his vast lands brought about the age of Russian enlightenment, and ensured that his country became one of the most powerful states in Europe.

Peter's interest in ships and shipbuilding started in his childhood; c. 1687 he had an old English-built day sailing boat repaired and launched, and on it he learned the rudiments of sailing and navigation. This craft (still preserved in St Petersburg) became known as the "Grandfather of the Russian Navy". In the years 1688 to 1693 he established a shipyard on Lake Plestsheev and then began his lifelong study of shipbuilding by visiting and giving encouragement to the industry at Archangelsk on the White Sea and Voronezh in the Sea of Azov. In October 1696, Peter took Azov from the Turks, and the Russian Fleet ever since has regarded that date as their birthday. Setting an example to the young aristocracy, Peter travelled to Western Europe to widen his experience and contacts and also to learn the trade of shipbuilding. He worked in the shipyards of Amsterdam and then at the Naval Base of Deptford on the Thames.

The war with Sweden concentrated his attention on the Baltic and, to establish a base for trading and for the Navy, the City of St Petersburg was constructed on marshland. The Admiralty was built in the city and many new shipyards in the surrounding countryside, one being the Olonez yard which in 1703 built the frigate Standart, the first for the Baltic Fleet, which Peter himself commanded on its first voyage. The military defence of St Petersburg was effected by the construction of Kronstadt, seawards of the city.

Throughout his life Peter was involved in ship design and it is estimated that one thousand ships were built during his reign. He introduced the building of standard ship types and also, centuries ahead of its time, the concept of prefabrication, unit assembly and the building of part hulls in different places. Officially he was the designer of the ninety-gun ship Lesnoe of 1718, and this may have influenced him in instituting Rules for Shipbuilders and for Seamen. In 1716 he commanded the joint fleets of the four naval powers: Denmark, Britain, Holland and Russia.

He established the Marine Academy, organized and encouraged exploration and scientific research, and on his edict the St Petersburg Academy of Science was opened. He was not averse to the recruitment of foreigners to key posts in the nation's service. Peter the Great was a remarkable man, with the unusual quality of being a theorist and an innovator, in addition to the endowments of practicality and common sense.

[br]

Further Reading

Robert K.Massie, 1981, Peter the Great: His Life and Work, London: Gollancz.

Henri Troyat, 1979, Pierre le Grand; pub. in English 1988 as Peter the Great, London: Hamish Hamilton (a good all-round biography).

AK / FMW

bring smth. into the open

(bring smth. (out) into the open)

открыто обсуждать, предавать гласности, обнародовать что-л.

Arthur disliked having the subject brought into the open. (A. Sillitoe, ‘Saturday Night and Sunday Morning’, part I, ch. VII) — Артуру было неприятно, что Фред во всеуслышание говорил о его поведении.

I told him that Herbert Getliffe seemed not to be in any way responsible this time. If even one of these rumours was brought into the open, it looked entirely safe to sue straight away. (C. P. Snow, ‘The Conscience of the Rich’, ch. XXXI) — Я сказал мистеру Марчу, что на этот раз Герберт Гетлиф не несет ответственности и что если люди будут муссировать слухи, то можно сейчас же обратиться в суд.

bring into the forefront

(bring into (или to) the forefront (тж. place или put in the forefront))

выдвигать на передний план; см. тж. bring smth. into the foreground

But, naturally enough, the episode brought the whole subject into the forefront of my mind, and I could think of nothing else. (J. Wain, ‘Strike the Father Dead’, part I, ‘Alfred’) — Естественно, что благодаря этому эпизоду вся история всплыла в моей памяти и я не мог думать ни о чем другом.

...the discrepance between his evidence and that of the... doctor puts him definitely in the forefront of the suspects. (A. Christie, ‘Appointment with Death’, part II, ch. III) —...показания Раймонда Бойнтона разошлись с показаниями... врача, и он теперь один из главных подозреваемых.

Torricelli, Evangelista

SUBJECT AREA: Photography, film and optics

[br]

b. 15 October 1608 Faenza, Italy

d. 25 October 1647 Florence, Italy

[br]

Italian physicist, inventor of the mercury barometer and discoverer of atmospheric pressure.

[br]

Torricelli was the eldest child of a textile artisan. Between 1625 and 1626 he attended the Jesuit school at Faenza, where he showed such outstanding aptitude in mathematics and philosophy that his uncle was persuaded to send him to Rome to a school run by Benedetto Castelli, a mathematician and engineer and a former pupil of Galileo Galilei. Between 1630 and 1641, Torricelli was possibly Secretary to Giovanni Ciampoli, Galileo's friend and protector. In 1641 Torricelli wrote a treatise, De motugravium, amplifying Galileo's doctrine on the motion of projectiles, and Galileo accepted him as a pupil. On Galileo's death in 1642, he was appointed as mathematician and philosopher to the court of Grand Duke Ferdinando II of Tuscany. He remained in Florence until his early death in 1647, possibly from typhoid fever. He wrote a great number of mathematical papers on conic sections, the cycloid, the logarithmic curve and other subjects, which made him well known.

By 1642 Torricelli was producing good lenses for telescopes; he subsequently improved them, and attained near optical perfection. He also constructed a simple microscope with a small glass sphere as a lens. Galileo had looked at problems of raising water with suction pumps, and also with a siphon in 1630. Torricelli brought up the subject again in 1640 and later produced his most important invention, the barometer. He used mercury to fill a glass tube that was sealed at one end and inverted it. He found that the height of mercury in the tube adjusted itself to a well-defined level of about 76 cm (30 in.), higher than the free surface outside. He realized that this must be due to the pressure of the air on the outside surface and predicted that it would fall with increasing altitude. He thus demonstrated the pressure of the atmosphere and the existence of a vacuum on top of the mercury, publishing his findings in 1644. He later noticed that changes in the height of the mercury were related to changes in the weather.

[br]

Bibliography

1641, De motu gravium.

Further Reading

T.I.Williams (ed.), 1969, A Biographical Dictionary of Scientists, London: A. \& C.Black.

Chambers Concise Dictionary of Scientists, 1989, Cambridge.

A Dictionary of Scientific Biography, 1976, Vol. XIII, New York: C.Scribner's Sons.

A.Stowers, 1961–2, "Thomas Newcomen's first steam engine 250 years ago and the initial development of steam power", Transactions of the Newcomen Society 34 (provides an account of his mercury barometer).

W.E.Knowles Middleton, 1964, The History of the Barometer, Baltimore.

RLH

mention

I ['menʃ(ə)n] n

упоминание

The mere mention of his name gave me shudders. — При одном лишь упоминании его имени у меня мурашки побежали по телу

- at the mention of smb, smth

- make no mention of smb, smth II ['menʃ(ə)n]

упоминать

- mention smb, smth

- don't mention my name
- do not mention it

USAGE:

(1.) See please, v; USAGE (3. б, г). (2.) See explain, v; USAGE (2.).

WAYS OF DOING THINGS:

Значение глагола to mention в значении "упомянуть" может быть конкретизировано не указывая какие-либо подробности характера упоминаемого или характера самого действия. Такая конкретизация, при общем значении to mention, передается такими глаголами, как to bring up, to touch on, to raise, to broach.

To refer to smth - "отослать к чему-либо", особенно без специального уточнения на что или кого дана отсылка: though she did not mention any names, everyone knew them хотя она не упомянула никаких имён, не знали кого она имела в виду; I apologized for my bad behaviour and the matter was never referred to again я извинился за своё плохое поведение, и это никогда больше не упоминалось; I think what Mary was referring to was clear я думал было ясно на что Мэри ссылалась.

To allude to - "упомянуть что-либо или кого-либо косвенным образом, намекнуть": when he spoke of the major problem I assumed that he was alluding to out scheme когда он говорил об основных проблемах, я предположил, что он намекал/имел в виду наш проект; no one ever mentioned the raid, and Pam only alluded to it in time of crisis никто никогда прямо не упоминал этого налёта, и Пэм в критические минуты только намекал на него.

To touch on - "затронуть или коснуться чего-либо, не останавливаясь на этом вопросе подробно": in my last lecture I touched on a number of important social problems which I am now going to examine in some detail в своей прошлой лекции, я коснулся ряда важных проблем, которые собираюсь подробно осветить сегодня.

To bring up - "поднять какой-либо вопрос для дальнейшего обсуждения": she wished she had never brought up the subject of money она сожалела, что подняла вопрос о деньгах; is there anything else you want to bring up before we end the meeting? Вы хотите поднять ещё какой-либо вопрос до конца собрания?

To raise - "поднять вопрос, начать разговор о чем-либо, о чем не было речи и никто об этом не думал": a number of new and important issues were raised at the conference на конференции были подняты новые важные проблемы; the matter of whether or not the royal family should pay taxes first raised in the article in the Times вопрос о том, должна ли королевская семья облагаться налогами/платить налоги был впервые поднят в статье в газете Таймс.

To broach (the matter, the question) - "упомянуть о чем-либо, что может вызвать смущение или может быть неприятным или вызвать спор": he decided not to broach the subject of divorce until his wife had recovered from her illness он решил не поднимать вопроса о разводе до выздоровления жены; Ella is missing school, but every time I tried to broach the matter with her, she talks back Элла пропускает занятия в школе, но каждый раз, когда я пытаюсь с ней об этом поговорить, она огрызается

up

adj. ayakta, dik, çıkmış, yükselmiş, üstün, önde, ayaklanmış, olmuş, olmakta, keyifli, ümitli, yukarı giden, şehre giden

————————

adv. yukarı, yukarıya, kuzeye, hepsini (fiillerle)

————————

interj. kalk, yaşasın, yukarı

————————

n. çıkış, artış, uyarıcı, mutluluk veren şey

————————

prep. yukarı, yukarıya, tepesinde, içeride (ülke)

————————

v. yükseltmek, artırmak, uyuşturucu almak

* * *

yukarı

* * *

1. adverb, adjective

1) (to, or at, a higher or better position: Is the elevator going up?; The office is up on the top floor; She looked up at him; The price of coffee is up again.) yukarı, yukarıda, yukarıya

2) (erect: Sit/Stand up; He got up from his chair.) yukarı

3) (out of bed: What time do you get up?; I'll be up all night finishing this work.) (yataktan) kalkmış

4) (to the place or person mentioned or understood: A taxi drove up and she got in; He came up (to me) and shook hands.) yanına, yakınına

5) (into the presence, or consideration, of a person, group of people etc: He brought up the subject during the conversation.) ortaya

6) (to an increased degree eg of loudness, speed etc: Please turn the radio up a little!; Speak up! I can't hear you) daha yüksek sesle/hızla v.b.

7) (used to indicate completeness; throughly or finally: You'll end up in hospital if you don't drive more carefully; Help me wash up the dishes!; I've used up the whole supply of paper; He tore up the letter.) tamamen

2. preposition

1) (to or at a higher level on: He climbed up the tree.) yukarı

2) ((at a place) along: They walked up the street; Their house is up the road.) boyunca

3) (towards the source of (a river): When do the salmon start swimming up the river?) kaynağa/ters yöne doğru

3. verb

(to increase (a price etc): They upped the price that they wanted for their house.) arttırmak

- upward

- upwards
- upward
- up-and-coming
- uphill 4. adjective

1) (sloping upwards; ascending: an uphill road.) yokuş yukarı

2) (difficult: This will be an uphill struggle.) güç, zahmetli

•

- upstairs

5. noun

(the upper floor(s): The ground floor needs painting, but the upstairs is nice; ( also adjective) an upstairs sitting room.) üst/yukarı kat

- upstream

- be up and about
- be up to
- up to
- up to date

Sutton, Thomas

SUBJECT AREA: Photography, film and optics

[br]

b. 1819 England

d. 1875 Jersey, Channel Islands

[br]

English photographer and writer on photography.

[br]

In 1841, while studying at Cambridge, Sutton became interested in photography and tried out the current processes, daguerreotype, calotype and cyanotype among them. He subsequently settled in Jersey, where he continued his photographic studies. In 1855 he opened a photographic printing works in Jersey, in partnership with L.-D. Blanquart- Evrard, exploiting the latter's process for producing developed positive prints. He started and edited one of the first photographic periodicals, Photographic Notes, in 1856; until its cessation in 1867, his journal presented a fresher view of the world of photography than that given by its London-based rivals. He also drew up the first dictionary of photography in 1858.

In 1859 Sutton designed and patented a wideangle lens in which the space between two meniscus lenses, forming parts of a sphere and sealed in a metal rim, was filled with water; the lens so formed could cover an angle of up to 120 degrees at an aperture of f12. Sutton's design was inspired by observing the images produced by the water-filled sphere of a "snowstorm" souvenir brought home from Paris! Sutton commissioned the London camera-maker Frederick Cox to make the Panoramic camera, demonstrating the first model in January 1860; it took panoramic pictures on curved glass plates 152×381 mm in size. Cox later advertised other models in a total of four sizes. In January 1861 Sutton handed over manufacture to Andrew Ross's son Thomas Ross, who produced much-improved lenses and also cameras in three sizes. Sutton then developed the first single-lens reflex camera design, patenting it on 20 August 1961: a pivoted mirror, placed at 45 degrees inside the camera, reflected the image from the lens onto a ground glass-screen set in the top of the camera for framing and focusing. When ready, the mirror was swung up out of the way to allow light to reach the plate at the back of the camera. The design was manufactured for a few years by Thomas Ross and J.H. Dallmeyer.

In 1861 James Clerk Maxwell asked Sutton to prepare a series of photographs for use in his lecture "On the theory of three primary colours", to be presented at the Royal Institution in London on 17 May 1861. Maxwell required three photographs to be taken through red, green and blue filters, which were to be printed as lantern slides and projected in superimposition through three projectors. If his theory was correct, a colour reproduction of the original subject would be produced. Sutton used liquid filters: ammoniacal copper sulphate for blue, copper chloride for the green and iron sulphocyanide for the red. A fourth exposure was made through lemon-yellow glass, but was not used in the final demonstration. A tartan ribbon in a bow was used as the subject; the wet-collodion process in current use required six seconds for the blue exposure, about twice what would have been needed without the filter. After twelve minutes no trace of image was produced through the green filter, which had to be diluted to a pale green: a twelve-minute exposure then produced a serviceable negative. Eight minutes was enough to record an image through the red filter, although since the process was sensitive only to blue light, nothing at all should have been recorded. In 1961, R.M.Evans of the Kodak Research Laboratory showed that the red liquid transmitted ultraviolet radiation, and by an extraordinary coincidence many natural red dye-stuffs reflect ultraviolet. Thus the red separation was made on the basis of non-visible radiation rather than red, but the net result was correct and the projected images did give an identifiable reproduction of the original. Sutton's photographs enabled Maxwell to establish the validity of his theory and to provide the basis upon which all subsequent methods of colour photography have been founded.

JW / BC

Dyer, Joseph Chessborough

SUBJECT AREA: Textiles

[br]

b. 15 November 1780 Stonnington Point, Connecticut, USA

d. 2 May 1871 Manchester, England

[br]

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

[br]

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.

[br]

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

RLH

Lebon, Philippe

SUBJECT AREA: Public utilities

[br]

b. 29 May 1767 Bruchey, near Joinville, France

d. 2 December 1804 Paris, France

[br]

French pioneer of gas lighting.

[br]

Lebon was the son of a court official under Louis XV. He entered the Ecole des Ponts et Chaussées and graduated in 1792, by which time he had acquired a considerable reputation as a scientific engineer. He is credited with the invention of the firetube steam boiler and of the superheater, and he also devised an engine to work by gas, but from 1792 until his untimely death he worked mainly on his experiments to produce an inflammable gas for lighting purposes. He submitted a paper on the subject in 1799 to the Institut National and received a patent in the same year. The patent covers the detailed making and application of gas for light, heat and power, and the recovery of by-products. It describes the production of the gas by the carbonization of coal, although Lebon in feet used only wood gas for his experiments and demonstrations. He began demonstrations in a private house in Paris, but these attracted little attention. He achieved wider public interest when he moved to the Hôtel Seignelay, where he started a series of public demonstrations in 1801, but he attracted little profit, and in fact lost his money in his experiments. He then set up a plant near Rouen to manufacture wood tar, but his career was brought to an end by his brutal murder in the Champs Elysées in Paris. William Murdock was working along similar lines in England, although Lebon knew nothing of his experiments. The German entrepreneur F.A. Winsor visited Lebon and managed to discover the essentials of his processes, which he turned to good account in England with the founding of the Gas, Light \& Coke Company.

[br]

Further Reading

S.T.McCloy, 1952, French Inventors of the Eighteenth Century.

A.Fayol, 1943, Philippe Lebon et le gaz d'éclair-age.

LRD

Bentham, Sir Samuel

SUBJECT AREA: Ports and shipping

[br]

b. 11 January 1757 England

d. 31 May 1831 London, England

[br]

English naval architect and engineer.

[br]

He was the son of Jeremiah Bentham, a lawyer. His mother died when he was an infant and his early education was at Westminster. At the age of 14 he was apprenticed to a master shipwright at Woolwich and later at Chatham Dockyard, where he made some small improvements in the fittings of ships. In 1778 he completed his apprenticeship and sailed on the Bienfaisant on a summer cruise of the Channel Fleet where he suggested and supervised several improvements to the steering gear and gun fittings.

Unable to find suitable employment at home, he sailed for Russia to study naval architecture and shipbuilding, arriving at St Petersburg in 1780, whence he travelled throughout Russia as far as the frontier of China, examining mines and methods of working metals. He settled in Kritchev in 1782 and there established a small shipyard with a motley work-force. In 1784 he was appointed to command a battalion. He set up a yard on the "Panopticon" principle, with all workshops radiating from his own central office. He increased the armament of his ships greatly by strengthening the hulls and fitting guns without recoil, which resulted in a great victory over the Turks at Liman in 1788. For this he was awarded the Cross of St George and promoted to Brigadier- General. Soon after, he was appointed to a command in Siberia, where he was responsible for opening up the resources of the country greatly by developing river navigation.

In 1791 he returned to England, where he was at first involved in the development of the Panopticon for his brother as well as with several other patents. In 1795 he was asked to look into the mechanization of the naval dockyards, and for the next eighteen years he was involved in improving methods of naval construction and machinery. He was responsible for the invention of the steam dredger, the caisson method of enclosing the entrances to docks, and the development of non-recoil cannonades of large calibre.

His intervention in the maladministration of the naval dockyards resulted in an enquiry that brought about the clearing-away of much corruption, making him very unpopular. As a result he was sent to St Petersburg to arrange for the building of a number of ships for the British navy, in which the Russians had no intention of co-operating. On his return to England after two years he was told that his office of Inspector-General of Navy Works had been abolished and he was appointed to the Navy Board; he had several disagreements with John Rennie and in 1812 was told that this office, too, had been abolished. He went to live in France, where he stayed for thirteen years, returning in 1827 to arrange for the publication of some of his papers.

There is some doubt about his use of his title: there is no record of his having received a knighthood in England, but it was assumed that he was authorized to use the title, granted to him in Russia, after his presentation to the Tsar in 1809.

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Further Reading

Mary Sophia Bentham, Life of Brigadier-General Sir Samuel Bentham, K.S.G., Formerly Inspector of Naval Works (written by his wife, who died before completing it; completed by their daughter).

IMcN

Biringuccio, Vanoccio Vincenzio Agustino Luca

SUBJECT AREA: Metallurgy, Mining and extraction technology

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b. 1480 Siena, Italy

d. 1537 Rome, Italy

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Italian author of the celebrated "Pirotechnia" on mining and metallurgy.

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Biringuccio spent much of his life in the service of, or under the patronage of, the Petruccis, one of the leading families of Siena. In his youth, he was able to travel widely in Italy and Germany, observing mining and metallurgical processes at first hand. For example, his visit to the brass-works in Milan was to be the source of the detailed description in Pirotechnia, published alter his death. He held various appointments in charge of mines or other concerns, such as the Siena mint, under the patronage of the Petruccis. During two periods of exile, while the Petrucci fortunes were in eclipse, he engaged in military activities such as the casting of cannon. That included the great culverin of Florence cast in 1529, also described in the Pirotechnia. In December 1534 Pope Paul III offered him the post of Director of the papal foundry and munitions. He did not take up the post until 1536, but he died the following year.

P irotechnia, which made Biringuccio famous, was published in Venice in 1540, three years after his death. The word "pirotechnia" had a wider meaning than that of fireworks, extending to the action of fire on various substances and including distillation and the preparation of acids. While owing something to earlier written sources, the book is substantially based on a lifetime of practical experience of mining and metalworking, including smelting, casting and alloying, and evidence in the book suggests that it was written between 1530 and 1535. Curzio Navo brought out the second and third editions in 1550 and 1559, as well as a Latin edition. A fourth edition was also printed in 1559. The appearance of four editions in such a short time testifies to the popularity and usefulness of the work.

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Bibliography

1942, Pirotechnia, Translated from the Italian with an Introduction and Notes, ed. Cyril S. Smith and Martha T.Gnudi, New York: American Institute of Mining and Metallurgi cal Engineers (the best account of Biringuccio's life, with bibliographical details of the various editions of the Pirotechnia, is in the preface).

LRD

Brown, Joseph Rogers

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

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b. 26 January 1810 Warren, Rhode Island, USA

d. 23 July 1876 Isles of Shoals, New Hampshire, USA

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American machine-tool builder and co-founder of Brown \& Sharpe.

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Joseph Rogers Brown was the eldest son of David Brown, who was modestly established as a maker of and dealer in clocks and watches. Joseph assisted his father during school vacations and at the age of 17 left to obtain training as a machinist. In 1829 he joined his father in the manufacture of tower clocks at Pawtucket, Rhode Island, and two years later went into business for himself in Pawtucket making lathes and small tools. In 1833 he rejoined his father in Providence, Rhode Island, as a partner in the manufacture of docks, watches and surveying and mathematical instruments. David Brown retired in 1841.

J.R.Brown invented and built in 1850 a linear dividing engine which was the first automatic machine for graduating rules in the United States. In 1851 he brought out the vernier calliper, the first application of a vernier scale in a workshop measuring tool. Lucian Sharpe was taken into partnership in 1853 and the firm became J.R.Brown \& Sharpe; in 1868 the firm was incorporated as the Brown \& Sharpe Manufacturing Company.

In 1855 Brown invented a precision gear-cutting machine to make clock gears. The firm obtained in 1861 a contract to make Wilcox \& Gibbs sewing machines and gave up the manufacture of clocks. At about this time F.W. Howe of the Providence Tool Company arranged for Brown \& Sharpe to make a turret lathe required for the manufacture of muskets. This was basically Howe's design, but Brown added a few features, and it was the first machine tool built for sale by the Brown \& Sharpe Company. It was followed in 1862 by the universal milling machine invented by Brown initially for making twist drills. Particularly for cutting gear teeth, Brown invented in 1864 a formed milling cutter which could be sharpened without changing its profile. In 1867 the need for an instrument for checking the thickness of sheet material became apparent, and in August of that year J.R.Brown and L.Sharpe visited the Paris Exhibition and saw a micrometer calliper invented by Jean Laurent Palmer in 1848. They recognized its possibilities and with a few developments marketed it as a convenient, hand-held measuring instrument. Grinding lathes were made by Brown \& Sharpe in the early 1860s, and from 1868 a universal grinding machine was developed, with the first one being completed in 1876. The patent for this machine was granted after Brown's sudden death while on holiday.

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Further Reading

J.W.Roe, 1916, English and American Tool Builders, New Haven: Yale University Press; repub. 1926, New York and 1987, Bradley, Ill.: Lindsay Publications Inc. (further details of Brown \& Sharpe Company and their products).

R.S.Woodbury, 1958, History of the Gear-Cutting Machine, Cambridge, Mass.: MIT Press ——, 1959, History of the Grinding Machine, Cambridge, Mass.: MIT Press.

——, 1960, History of the Milling Machine, Cambridge, Mass.: MIT Press.

RTS

Clegg, Samuel

SUBJECT AREA: Public utilities, Railways and locomotives

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b. 2 March 1781 Manchester, England

d. 8 January 1861 Haverstock Hill, Hampstead, London, England

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English inventor and gas engineer.

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Clegg received scientific instruction from John Dalton, the founder of the atomic theory, and was apprenticed to Boulton \& Watt. While at their Soho factory in Birmingham, he assisted William Murdock with his experiments on coal gas. He left the firm in 1804 and set up as a gas engineer on his own account. He designed and installed gas plant and lighting in a number of factories, including Henry Lodge's cotton mill at Sowerby Bridge and in 1811 the Jesuit College at Stoneyhurst in Lancashire, the first non-industrial establishment to be equipped with gas lighting.

Clegg moved to London in 1813 and successfully installed gas lighting at the premises of Rudolf Ackermann in the Strand. His success in the manufacture of gas had earned him the Royal Society of Arts Silver Medal in 1808 for furthering "the art of gas production", and in 1813 it brought him the appointment of Chief Engineer to the first gas company, the Chartered Gas, Light \& Coke Company. He left in 1817, but remained in demand to set up gas works and advise on the formation of gas companies. Throughout this time there flowed from Clegg a series of inventions of fundamental importance in the gas industry. While at Lodge's mill he had begun purifying gas by adding lime to the gas holder, and at Stoneyhurst this had become a separate lime purifier. In 1815, and again in 1818, Clegg patented the wet-meter which proved to be the basis for future devices for measuring gas. He invented the gas governor and, favouring the horizontal retort, developed the form which was to become standard for the next forty years. But after all this, Clegg joined a concern in Liverpool which failed, taking all his possessions with it. He made a fresh start in Lisbon, where he undertook various engineering works for the Portuguese government. He returned to England to find railway construction gathering pace, but he again backed a loser by engaging in the ill-fated atmospheric-rail way project. He was finally discouraged from taking part in further enterprises, but he received a government appointment as Surveying Officer to conduct enquiries in connection with the various Bills on gas that were presented to Parliament. Clegg also contributed to his son's massive treatise on the manufacture of coal gas.

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Principal Honours and Distinctions

Royal Society of Arts Silver Medal 1808.

Further Reading

Minutes of Proceedings of the Institution of Civil Engineers (1862) 21:552–4.

S.Everard, 1949, The History of the Gas light and Coke Company, London: Ernest Benn.

LRD

Dale, David

SUBJECT AREA: Textiles

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b. 6 January 1739 Stewarton, Ayrshire, Scotland

d. 17 March 1806 Glasgow, Scotland

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Scottish developer of a large textile business in find around Glasgow, including the cotton-spinning mills at New Lanark.

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David Dale, the son of a grocer, began his working life by herding cattle. His connection with the textile industry started when he was apprenticed to a Paisley weaver. After this he travelled the country buying home-spun linen yarns, which he sold in Glasgow. At about the age of 24 he settled in Glasgow as Clerk to a silk merchant. He then started a business importing fine yarns from France and Holland for weaving good-quality cloths such as cambrics. Dale was to become one of the pre-eminent yarn dealers in Scotland. In 1778 he acquired the first cotton-spinning mill built in Scotland by an English company at Rothesay on the Isle of Bute. In 1784 he met Richard Arkwright, who was touring Scotland, and together they visited the Falls of the Clyde near the town of Lanark. Arkwright immediately recognized the potential of the site for driving water-powered mills. Dale acquired part of the area from Lord Braxfield and in 1785 began to build his first mill there in partnership with Arkwright. The association with Arkwright soon ceased, however, and by c.1795 Dale had erected four mills. Because the location of the mills was remote, he built houses for the workers and then employed pauper children brought from the slums of Edinburgh and Glasgow; at one time there were over 400 of them. Dale's attitude to his workers was benevolent and humane. He tried to provide reasonable working conditions and the mills were well designed with a large workshop in which machinery was constructed. Dale was also a partner in mills at Catrine, Newton Stewart, Spinningdale in Sutherlandshire and some others. In 1785 he established the first Turkey red dye works in Scotland and was in partnership with George Macintosh, the father of Charles Macintosh. Dale manufactured cloth in Glasgow and from 1783 was Agent for the Royal Bank of Scotland, a lucrative position. In 1799 he was persuaded by Robert Owen to sell the New Lanark mills for £60,000 to a Manchester partnership which made Owen the Manager. Owen had married Dale's daughter, Anne Caroline, in 1799. Possibly due in part to poor health, Dale retired in 1800 to Rosebank near Glasgow, having made a large fortune. In 1770 he had withdrawn from the established Church of Scotland and founded a new one called the "Old Independents". He visited the various branches of this Church, as well as convicts in Bridewell prison, to preach. He was also a great benefactor to the poor in Glasgow. He had a taste for music and sang old Scottish songs with great gusto.

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Further Reading

Dictionary of National Biography.

R.Owen, 1857, The Life of Robert Owen, written by himself, London (mentions Dale).

Through his association with New Lanark and Robert Owen, details about Dale may be found in J.Butt (ed.), 1971, Robert Owen, Prince of Cotton Spinners, Newton Abbot; S.Pollard and J.Salt (eds), 1971, Robert Owen, Prophet of the Poor: essays in honour of the two-hundredth anniversary of his birth, London.

RLH