a new process of dyeing

process

I

1. n

1) процес; хід розвитку

the evolutionary process — еволюційний процес

the process of development (of decay) — процес розвитку (розпаду)

2) хід, перебіг, рух, плин (часу)

in process of time — з перебігом часу

changes are in process — відбуваються зміни

3) юр. виклик до суду

4) судочинство, судовий процес

5) тех. технологічний процес; прийом, спосіб; режим

a new process of dyeing — новий спосіб фарбування

6) друк. фотомеханічний спосіб

7) анат. відросток; виступ (кістки)

8) бот. паросток

process block — кліше, одержане фотомеханічним способом; відбиток кліше

process chart — схема технологічного процесу

process cheese — плавлений сир

process shooting — комбінована кінозйомка

process tankage — корм (добриво) з відходів

2. v

1) юр. порушувати справу; починати процес

2) піддавати обробці, обробляти

3) друк. відтворювати фотомеханічним способом

II

v розм.

брати участь у процесії

* * *

I n

1) процес; хід розвитку

2) перебіг, рух, хід

3) юp. виклик до суду; судовий припис; судочинство; судовий процес

4) тex. технологічний процес, прийом, спосіб; режим

process shooting — кiнo комбінована кінозйомка

5) пoлiгp. фотомеханічний спосіб

6) aнaт. відросток, придаток, виріст, лопата; виступ (кістки, нервової клітини); бoт. відросток

7) "процес" ( вид зачіски)

II a

оброблений, перероблений

III v

1) юp. порушувати справу, починати процес; надсилати кому-небудь повістку до суду

2) піддавати обробці, обробляти; обробляти (документацію, книги, що надходять до бібліотеки)

3) пoлiгp. відтворювати фотомеханічним способом

4) cл. оформляти (візу, документи); розглядати (заяву, проект, кандидатуру)

IV v,

брати участь у процесії

Macintosh, Charles

SUBJECT AREA: Chemical technology, Textiles

[br]

b. 29 December 1766 Glasgow, Scotland

d. 25 July 1843 Dunchattan, near Glasgow, Scotland

[br]

Scottish inventor of rubberized waterproof clothing.

[br]

As the son of the well-known and inventive dyer George Macintosh, Charles had an early interest in chemistry. At the age of 19 he gave up his work as a clerk with a Glasgow merchant to manufacture sal ammoniac (ammonium chloride) and developed new processes in dyeing. In 1797 he started the first Scottish alum works, finding the alum in waste shale from coal mines. His first works was at Hurlet, Renfrewshire, and was followed later by others. He then formed a partnership with Charles Tennant, the proprietor of a chemical works at St Rollox, near Glasgow, and sold "lime bleaching liquor" made with chlorine and milk of lime from their bleach works at Darnley. A year later the use of dry lime to make bleaching powder, a process worked out by Macintosh, was patented. Macintosh remained associated with Tennant's St Rollox chemical works until 1814. During this time, in 1809, he had set up a yeast factory, but it failed because of opposition from the London brewers.

There was a steady demand for the ammonia that gas works produced, but the tar was often looked upon as an inconvenient waste product. Macintosh bought all the ammonia and tar that the Glasgow works produced, using the ammonia in his establishment to produce cudbear, a dyestuff extracted from various lichens. Cudbear could be used with appropriate mordants to make shades from pink to blue. The tar could be distilled to produce naphtha, which was used as a flare. Macintosh also became interested in ironmaking. In 1825 he took out a patent for converting malleable iron into steel by taking it to white heat in a current of gas with a carbon content, such as coal gas. However, the process was not commercially successful because of the difficulty keeping the furnace gas-tight. In 1828 he assisted J.B. Neilson in bringing hot blast into use in blast furnaces; Neilson assigned Macintosh a share in the patent, which was of dubious benefit as it involved him in the tortuous litigation that surrounded the patent until 1843.

In June 1823, as a result of experiments into the possible uses of naphtha obtained as a by-product of the distillation of coal tar, Macintosh patented his process for waterproofing fabric. This comprised dissolving rubber in naphtha and applying the solution to two pieces of cloth which were afterwards pressed together to form an impermeable compound fabric. After an experimental period in Glasgow, Macintosh commenced manufacture in Manchester, where he formed a partnership with H.H.Birley, B.Kirk and R.W.Barton. Birley was a cotton spinner and weaver and was looking for ways to extend the output of his cloth. He was amongst the first to light his mills with gas, so he shared a common interest with Macintosh.

New buildings were erected for the production of waterproof cloth in 1824–5, but there were considerable teething troubles with the process, particularly in the spreading of the rubber solution onto the cloth. Peter Ewart helped to install the machinery, including a steam engine supplied by Boulton \& Watt, and the naphtha was supplied from Macintosh's works in Glasgow. It seems that the process was still giving difficulties when Thomas Hancock, the foremost rubber technologist of that time, became involved in 1830 and was made a partner in 1834. By 1836 the waterproof coat was being called a "mackintosh" [sic] and was gaining such popularity that the Manchester business was expanded with additional premises. Macintosh's business was gradually enlarged to include many other kinds of indiarubber products, such as rubber shoes and cushions.

[br]

Principal Honours and Distinctions

FRS 1823.

Further Reading

G.Macintosh, 1847, Memoir of Charles Macintosh, London (the fullest account of Charles Macintosh's life).

T.Hancock, 1957, Narrative of the Indiarubber Manufacture, London.

H.Schurer, 1953, "The macintosh: the paternity of an invention", Transactions of the Newcomen Society 28:77–87 (an account of the invention of the mackintosh).

RLH / LRD

Berthollet, Claude-Louis

SUBJECT AREA: Textiles

[br]

b. 9 November 1748 Talloise, near Lake Annecy, France

d. 6 November 1822 Arceuil, France

[br]

French chemist who made important innovations in textile chemistry.

[br]

Berthollet qualified as a medical doctor and pursued chemical researches, notably into "muriatic acid" (chlorine), then recently discovered by Scheele. He was one of the first chemists to embrace the new system of chemistry advanced by Lavoisier. Berthollet held several official appointments, among them inspector of dye works (from 1784) and Director of the Manufacture Nationale des Gobelins. These appointments enabled him to continue his researches and embark on a series of publications on the practical applications of chlorine, prussic acid (hydrocyanic acid) and ammonia. He clearly demonstrated the benefits of the French practice of appointing scientists to the state manufactories.

There were two practical results of Berthollet's studies of chlorine. First, he produced a powerful explosive by substituting potassium chlorate, formed by the action of chlorine on potash, in place of nitre (potassium nitrate) in gunpowder. Then, mainly from humanitarian motives, he followed up Scheele's observation of the bleaching properties of chlorine water, in order to release for cultivation the considerable areas of land that had hitherto been required by the old bleaching process. The chlorine method greatly speeded up bleaching; this was a vital factor in the revolution in the textile industries.

After a visit to Egypt in 1799, Berthollet carried out many experiments on dyeing, seeking to place this ancient craft onto a scientific basis. His work is summed up in his Eléments de l'art de la teinture, Paris, 1791.

[br]

Bibliography

1791, Eléments de Van de la teinture, Paris (covers his work on dyeing).

Berthollet published two books of importance in the early history of physical chemistry: 1801, Recherches sur les lois de l'affinité, Paris.

1803, Essai de statique chimique, Paris.

His scientific papers appeared mainly in Mémores de l'Académie Royal des Sciences and

Annales de Chimie.

Further Reading

E.F.Jomard, 1844, Notice sur la vie et les ouvrages de Claude-Louis Berthollet, Annecy.

E.Farber, 1961, Great Chemists, New York: Interscience, pp. 32–4 (includes a short biographical account).

LRD

Perkin, Sir William Henry

SUBJECT AREA: Chemical technology, Synthetic materials, Textiles

[br]

b. 12 March 1838 London, England

d. 14 July 1907 Sudbury, England

[br]

English chemist, discoverer of aniline dyes, the first synthetic dyestuffs.

[br]

He early showed an aptitude for chemistry and in 1853 entered the Royal College of Chemistry as a student under A.W.von Hofmann, the first Professor at the College. By the end of his first year, he had carried out his first piece of chemical research, on the action of cyanogen chloride on phenylamine, which he published in the Journal of the Chemical Society (1857). He became honorary assistant to von Hofmann in 1857; three years previously he had set up his own chemical laboratory at home, where he had discovered the first of the azo dyes, aminoazonapththalene. In 1856 Perkin began work on the synthesis of quinine by oxidizing a salt of allyl toluidine with potassium dichromate. Substituting aniline, he obtained a dark-coloured precipitate which proved to possess dyeing properties: Perkin had discovered the first aniline dye. Upon receiving favourable reports on the new material from manufacturers of dyestuffs, especially Pullars of Perth, Perkin resigned from the College and turned to the commercial exploitation of his discovery. This proved highly successful. From 1858, the dye was manufactured at his Greenford Green works as "Aniline Purple" or "Tyrian Purple". It was later to be referred to by the French as mauve. Perkin's discovery led to the development of the modern dyestuffs industry, supplanting dyes from the traditional vegetable sources. In 1869, he introduced two new methods for making the red dye alizarin, in place of the process that involved the use of the madder plant (Rubia tinctorum). In spite of German competition, he dominated the British market until the end of 1873. After eighteen years in chemical industry, Perkin retired and devoted himself entirely to the pure chemical research which he had been pursuing since the 1850s. He eventually contributed ninety papers to the Chemical Society and further papers to other bodies, including the Royal Society. For example, in 1867 he published his synthesis of unsaturated organic acids, known as "Perkin's synthesis". Other papers followed, on the structure of "Aniline Purple". In 1881 Perkin drew attention to the magnetic-rotatory power of some of the substances he had been dealing with. From then on, he devoted particular attention to the application of this phenomenon to the determination of chemical structure.

Perkin won wide recognition for his discoveries and other contributions to chemistry.

The half-centenary of his great discovery was celebrated in July 1906 and later that year he received a knighthood.

[br]

Principal Honours and Distinctions

Knighted 1906. FRS 1866. President, Chemical Society 1883–5. President, Society of Chemical Industry 1884–5. Royal Society Royal Medal 1879; Davy Medal 1889.

Bibliography

26 August 1856, British patent no. 1984 (Aniline Purple).

1867, "The action of acetic anhydride upon the hydrides of salicyl, etc.", Journal of the Chemical Society 20:586 (the first description of Perkin's synthesis).

Further Reading

S.M.Edelstein, 1961, biography in Great Chemists, ed. E.Farber, New York: Interscience, pp. 757–72 (a reliable, short account).

R.Meldola, 1908, Journal of the Chemical Society 93:2,214–57 (the most detailed account).

LRD