distillation industry

distillation industry

Макаров: спиртовая промышленность

distillation industry

спиртовая промышленность

industry

1. n промышленность, индустрия

a branch of industry — отрасль промышленности

perfumery industry — парфюмерная промышленность

depression in industry — застой в промышленности

depression of industry — застой в промышленности

distillation industry — спиртовая промышленность

fishing industry — рыбодобывающая промышленность

2. n отрасль промышленности; отрасль экономики

national industries — основные отрасли отечественной промышленности

advertising industry — индустрия рекламы

aerospace industry — авиационно-космическая промышленность

agricultural industry — сельскохозяйственное производство

cottage industry — надомное производство

soft drink industry — промышленность безалкогольных напитков

robotized industry — роботизированная отрасль промышленности

pulp and paper industry — целлюлозно-бумажная промышленность

oil refining industry — нефтеперерабатывающая промышленность

microbiological industry — микробиологическая промышленность

3. n трудолюбие, усердие, прилежание

indefatigable industry — неутомимое трудолюбие

in a few years he had bettered himself considerably by his talents and industry — за несколько лет он значительно продвинулся по службе благодаря своим способностям и трудолюбию

Синонимический ряд:

1. activity (noun) activity; application; assiduity; assiduousness; diligence; energy; hard work; industriousness; perseverance; sedulousness; work; zeal

2. sector of commerce (noun) branch; building trades; business; business activity; commerce; enterprise; manufacturing; sector; sector of commerce; trade; traffic

Антонимический ряд:

sloth

robotized industry

роботизированная отрасль промышленности

distillation industry — спиртовая промышленность

fishing industry — рыбодобывающая промышленность

flavoring industry — пищевкусовая промышленность

hydrolysis industry — гидролизная промышленность

metal industry — металлургическая промышленность

manufacturing industry

обрабатывающая отрасль промышленности

depression of industry — застой в промышленности

distillation industry — спиртовая промышленность

fishing industry — рыбодобывающая промышленность

flavoring industry — пищевкусовая промышленность

hydrolysis industry — гидролизная промышленность

minister of state for trade and industry

государственный министр по делам торговли и промышленности

distillation industry — спиртовая промышленность

fishing industry — рыбодобывающая промышленность

flavoring industry — пищевкусовая промышленность

hydrolysis industry — гидролизная промышленность

metal industry — металлургическая промышленность

sheltered industry

поощряемая отрасль промышленности

distillation industry — спиртовая промышленность

fishing industry — рыбодобывающая промышленность

flavoring industry — пищевкусовая промышленность

hydrolysis industry — гидролизная промышленность

metal industry — металлургическая промышленность

distilling industry

1. ликеро-водочная промышленность

 

ликеро-водочная промышленность
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[ http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]

EN

distilling industry
A sector of the economy in which an aggregate of commercial enterprises is engaged in the manufacture and marketing of alcoholic beverages made by a distillation process of vaporization and condensation, such as vodka, rum, whiskey and other related beverages. (Source: RHW / SIC)
[http://www.eionet.europa.eu/gemet/alphabetic?langcode=en]

Тематики

• охрана окружающей среды

EN

• distilling industry

DE

• Destillationsindustrie

FR

• industrie de distillation

Hofmann, August Wilhelm von

SUBJECT AREA: Chemical technology

[br]

b. 8 April 1818 Giessen, Germany

d. 2 May 1892 Berlin, Germany

[br]

German organic chemist.

[br]

The son of an architect, Hofmann began studying law and languages but was increasingly drawn to chemistry, attracted by Liebig's teaching at Giessen. In 1841 Hofmann took his doctorate with a study of coal tar. He became Privatdozent at Bonn University in 1845, but later that year he was persuaded to take up the post of first Director of the Royal College of Chemistry in London, after tenure was guaranteed as a result of Prince Albert's influence. He remained there for twenty years until he was offered professorships in chemistry at Bonn and Berlin. He accepted the latter. Hofmann continued the method of teaching chemistry, based on laboratory instruction, developed by Liebig at Giessen, and extended it to England and Berlin. A steady stream of well-trained chemists issued forth from Hofmann's tuition, concerning themselves especially with experimental organic chemistry and the industrial applications of chemistry. In 1848 one of his students, C.B. Mansfield, devised the method of fractional distillation of coal tar, to separate pure benzene, xylene and toluene, thus laying the foundations of the coal-tar industry. In 1856 another student, W.H. Perkin, prepared the first synthetic dyestuff, aniline purple, heralding the great dyestuffs industry, in which several other of his students distinguished themselves. Although keenly interested in the chemistry of dyestuffs, Hofmann did not pursue their large-scale preparation, but he stressed the importance of scientific research for success on a commercial scale. Hofmann's stimulus in this direction flagged after his return to Germany, and this was a factor in the failure of British industry to follow up their initial advantage and allow it to pass to Germany. In 1862 Hofmann prepared a dye from a derivative of triphenylmethane, which he called rosaniline. From this he derived a series of beautiful colours, ranging from blue to violet, which he patented as "Hofmann's violets" the following year.

[br]

Principal Honours and Distinctions

Ennobled 1888.

Further Reading

J.Volhard and E.Fischer, 1902, August Wilhelm von Hofmann, ein Lebensbild, Berlin (the basic biography).

K.M.Hammond, 1967, bibliography, unpublished, (Diploma in Librarianship, London University (lists 373 items; deposited in University College, London)).

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Young, James

SUBJECT AREA: Chemical technology

[br]

b. 13 July 1811 Glasgow, Scotland

d. 13 May 1883 Wemyss Bay, Scotland

[br]

Scottish chemist and pioneer petroleum technologist.

[br]

Young's early education took place in the evenings, after the day's work in his father's joinery. From 1830 he studied chemistry at the evening classes in Glasgow given by the distinguished Scottish chemist Thomas Graham (1805–69) and soon afterwards became Graham's assistant. When Graham moved to University College London in 1837, Young accompanied him.

From 1839 he was employed in the chemical industry, first with James Muspratt at St Helens, Lancashire, and from 1843 with Tennant \& Company in Manchester. In 1848 his attention was drawn to an oil seepage in a mine at Alfreton, Derbyshire, of some 300 gallons per day; he set up his own works there to extract an oil that could be used for lighting and lubrication. When this source of oil was exhausted, three years later, Young moved to Lothian in Scotland. By distillation, he extracted oil from the oil-shale deposits there and thus founded the Scottish oil-shale industry: he obtained a high yield of paraffin oil for lighting and heating, and was a pioneer in the use of chemical methods in extracting and treating oil. In 1866 he disposed of his company for no less than £400,000. Young's other activities included measuring the speed of light by Fizeau's method and giving financial support to the expeditions of David Livingstone, who had been a fellow student in Glasgow.

[br]

Principal Honours and Distinctions

FRS 1873.

Further Reading

Obituary, 1884, Journal of the Chemical Society 45:630.

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extractive

extractive [-tıv]

A adj

1. (her)ausziehend:

extractive industry Industrie f zur Gewinnung von Naturprodukten

2. CHEM extraktiv, Extraktiv…:

extractive distillation

B s CHEM Extrakt m

extractive

1. n извлечение, экстракт

2. n спец. экстрактивное вещество

extractive distillation — экстрактивная дистилляция

extractive alkylation — экстрактивное алкилирование

3. a извлекаемый; добываемый

4. a добывающий, экстрагирующий

extractive industry — добывающая промышленность

extractive industries — отрасли добывающей промышленности

5. a спец. экстрактивный

extractive material — экстрактивное вещество

Clerk, Sir Dugald

SUBJECT AREA: Automotive engineering, Steam and internal combustion engines

[br]

b. 31 March 1854 Glasgow, Scotland

d. 12 November 1932 Ewhurst, Surrey, England

[br]

Scottish mechanical engineer, inventor of the two-stroke internal combustion engine.

[br]

Clerk began his engineering training at about the age of 15 in the drawing office of H.O.Robinson \& Company, Glasgow, and in his father's works. Meanwhile, he studied at the West of Scotland Technical College and then, from 1871 to 1876, at Anderson's College, Glasgow, and at the Yorkshire College of Science, Leeds. Here he worked under and then became assistant to the distinguished chemist T.E.Thorpe, who set him to work on the fractional distillation of petroleum, which was to be useful to him in his later work. At that time he had intended to become a chemical engineer, but seeing a Lenoir gas engine at work, after his return to Glasgow, turned his main interest to gas and other internal combustion engines. He pursued his investigations first at Thomson, Sterne \& Company (1877–85) and then at Tangyes of Birmingham (1886–88. In 1888 he began a lifelong partnership in Marks and Clerk, consulting engineers and patent agents, in London.

Beginning his work on gas engines in 1876, he achieved two patents in the two following years. In 1878 he made his principal invention, patented in 1881, of an engine working on the two-stroke cycle, in which the piston is powered during each revolution of the crankshaft, instead of alternate revolutions as in the Otto four-stroke cycle. In this engine, Clerk introduced supercharging, or increasing the pressure of the air intake. Many engines of the Clerk type were made but their popularity waned after the patent for the Otto engine expired in 1890. Interest was later revived, particularly for application to large gas engines, but Clerk's engine eventually came into its own where simple, low-power motors are needed, such as in motor cycles or motor mowers.

Clerk's work on the theory and design of gas engines bore fruit in the book The Gas Engine (1886), republished with an extended text in 1909 as The Gas, Petrol and Oil Engine; these and a number of papers in scientific journals won him international renown. During and after the First World War, Clerk widened the scope of his interests and served, often as chairman, on many bodies in the field of science and industry.

[br]

Principal Honours and Distinctions

Knighted 1917; FRS 1908; Royal Society Royal Medal 1924; Royal Society of Arts Alber Medal 1922.

Further Reading

Obituary Notices of Fellows of the Royal Society, no. 2, 1933.

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Coffey, Aeneas

SUBJECT AREA: Chemical technology

[br]

b. 1779/80 England

d. 26 November 1852 Bromley, England

[br]

English inventor of the Coffey still for fractional distillation.

[br]

As Surveyor and Inspector General of Excise in Ireland, Coffey was responsible for the suppression of the illicit distilling of alcohol. In 1818 he published a pamphlet refuting charges of oppression and brutality brought against him by Irish revenue officers. He seems to have hunted with the hounds, for as a distiller himself in Dublin, he patented in 1831 the improved form of still that bears his name. The still was quickly adopted by the whisky industry as it accomplished in a single operation what had previously required several stages using the old pot stills. It is still used in the making of potable spirits, and consists of two adjacent columns, an analyser and a rectifier. Steam is passed through the liquor in the analyser, which removes the volatile fraction, and is then fractionally condensed in the rectifier column; almost pure alcohol could be produced by this means.

[br]

Further Reading

E.J.Rothery, 1968, Annals of Science 24:53.

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Lavoisier, Antoine Laurent

SUBJECT AREA: Chemical technology

[br]

b. 26 August 1743 Paris, France

d. 8 May 1794 Paris, France

[br]

French founder of the modern science of chemistry.

[br]

As well as receiving a formal education in law and literature, Lavoisier studied science under some of the leading figures of the day. This proved to be an ideal formation of the man in whom "man of science" and "public servant" were so intimately combined. His early work towards the first geological map of France and on the water supply of Paris helped to win him election to the Royal Academy of Sciences in 1768 at the youthful age of 25. In the same year he used some of his private income to buy a part-share in the "tax farm", a private company which leased from the Government the right to collect certain indirect taxes.

In 1772 Lavoisier began his researches into the related phenomena of combustion, respiration and the calcination or oxidation of metals. This culminated in the early 1780s in the overthrow of the prevailing theory, based on an imponderable combustion principle called "phlogiston", and the substitution of the modern explanation of these processes. At the same time, understanding of the nature of acids, bases and salts was placed on a sounder footing. More important, Lavoisier defined a chemical element in its modern sense and showed how it should be applied by drawing up the first modern list of the chemical elements. With the revolution in chemistry initiated by Lavoisier, chemists could begin to understand correctly the fundamental processes of their science. This understanding was the foundationo of the astonishing advance in scientific and industrial chemistry that has taken place since then. As an academician, Lavoisier was paid by the Government to carry out investigations into a wide variety of practical questions with a chemical bias, such as the manufacture of starch and the distillation of phosphorus. In 1775 Louis XVI ordered the setting up of the Gunpowder Commission to improve the supply and quality of gunpowder, deficiencies in which had hampered France's war efforts. Lavoisier was a member of the Commission and, as usual, took the leading part, drawing up its report and supervising its implementation. As a result, the industry became profitable, output increased so that France could even export powder, and the range of the powder increased by two-thirds. This was a material factor in France's war effort in the Revolution and the Napoleonic wars.

As if his chemical researches and official duties were not enough, Lavoisier began to apply his scientific principles to agriculture when he purchased an estate at Frechines, near Blois. After ten years' work on his experimental farm there, Lavoisier was able to describe his results in the memoir "Results of some agricultural experiments and reflections on their relation to political economy" (Paris, 1788), which holds historic importance in agriculture and economics. In spite of his services to the nation and to humanity, his association with the tax farm was to have tragic consequences: during the reign of terror in 1794 the Revolutionaries consigned to the guillotine all the tax farmers, including Lavoisier.

[br]

Bibliography

1862–93, Oeuvres de Lavoisier, Vols I–IV, ed. J.B.A.Dumas; Vols V–VI, ed. E.Grimaux, Paris (Lavoisier's collected works).

Further Reading

D.I.Duveen and H.S.Klickstein, 1954, A Bibliography of the Works of Antoine Laurent Lavoisier 1743–1794, London: William Dawson (contains valuable biographical material).

D.McKie, 1952, Antoine Lavoisier, Scientist, Economist, Social Reformer, London: Constable (the best modern, general biography).

H.Guerlac, 1975, Antoine Laurent Lavoisier, Chemist and Revolutionary, New York: Charles Scribner's Sons (a more recent work).

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