technical+workshop

scuola

f school

scuola di lingue language school

scuola elementare primary school

scuola media secondary school

scuola parificata private school officially recognized by the state

scuola serale evening classes pl

scuola superiore high school

scuola guida driving school

andare a scuola go to school

* * *

scuola s.f.

1 school; ( istruzione) education: scuola materna, nursery school; scuola elementare, primary (o elementary) school; scuola media inferiore, secondary school (o amer. junior high school); scuola media superiore, secondary school (o amer. high school); scuola mista, mixed school; scuola parificata, state-recognised private school; scuola parrocchiale, parish school; scuola privata, private school; scuola pubblica, state school; scuola dell'obbligo, compulsory education; scuola rurale, rural (o village) school; scuola a tempo pieno, full-time school; scuola diurna, day-classes; scuola serale, evening classes (o evening school); scuola all'aperto, open-air school; scuola magistrale, (teachers) training college; scuola tecnica, technical school; scuola commerciale, commercial school (o school of commerce); scuola aziendale, business school; scuola professionale, vocational (o trade) school; scuola di economia, school of economics; scuola di ballo, dancing school; scuola di disegno, drawing (o art) school; scuola di equitazione, riding school; scuola di scherma, fencing school; scuola di taglio, school of dress-making; compagno di scuola, school-friend (o schoolfellow o schoolmate); maestra di scuola, schoolmistress (o schoolteacher); maestro di scuola, schoolmaster (o schoolteacher); andare a scuola, to go to school; quando riapre la scuola?, when will school start again?; lasciare la scuola, to leave school; la scuola non gli piace, he does not like school // marinare la scuola, to play truant // cantiere scuola, workshop // nave scuola, training ship // alta scuola, haute école

2 ( lezione) school, lesson (anche fig.); ( esempio) example: ieri non avemmo scuola, yesterday we had no lessons (o school); faccio scuola dalle 17 alle 21, I teach from 5 o'clock to 9 o'clock; questo periodo all'estero sarà un'ottima scuola per lui, this period abroad will be a very good experience for him; la scuola dell'esperienza, the school of experience; ciò ti serva di scuola, let this be a lesson (o an example) to you // seguire la scuola di qlcu., to follow s.o.'s example

3 (arte, fil., scient.) school: (pitt.) la scuola fiamminga, fiorentina, the Dutch, Florentine school; (lett.) la scuola romantica, the Romantic school; (fil.) la scuola socratica, platonica, the Socratic, Platonic school // cresciuto alla scuola del materialismo, reared in the school of materialism // appartiene alla vecchia scuola, he belongs to the old school // fare scuola, to create a school (o to set a fashion).

* * *

['skwɔla]

1. sf

(istituzione, edificio) school

andare a scuola — to go to school

non c'è scuola domani — there's no school tomorrow

ci vediamo dopo la scuola — see you after school

- scuola guida

- scuola dell'infanzia

- scuola dell'obbligo

- scuola primaria

- scuola privata

- scuola secondaria di primo grado

- scuola pubblica

- scuola secondaria di secondo grado

- scuola serale

2. agg inv

nave scuola — training ship

See:

www.istruzione.it/

Cultural note: scuola Following the passage of the law on educational reform in 2003, Italian children go to "scuola dell'infanzia" for three years (age 3-6), after which they attend "scuola primaria" for five years (age 6-11). The first stage of education is then completed by three years of "scuola secondaria di primo grado" (age 11-14). For the second stage of their education, students can choose between various types of school and can specialize in various subjects.

* * *

['skwɔla]

sostantivo femminile

1) school

essere, andare a scuola — to be at, to go to school

la scuola è finita — school is over

fin dai tempi della scuola — since one's schooldays

avere scuola — (lezione) to have school

2) (sistema) education (system)

riformare la scuola — to reform the education system

3) (fonte di formazione) school (di of), training (di for, in)

scuola di vita — school of hard knocks, university of life, training for life

della vecchia scuola — of the old school

4) art. letter. filos. school

scuola fiamminga — Dutch School

scuola di pensiero — school of thought

•

scuola alberghiera — hotel-management school

scuola di ballo — dancing school

scuola per corrispondenza — correspondence college

scuola di danza — ballet school

scuola elementare — primary o elementary school, grade school AE

scuola guida — driving school

scuola di lingue — school of languages, language school

scuola magistrale — = formerly, high school specializing in education

scuola materna — nursery school, kindergarten, preschool AE

scuola media inferiore — = three years post elementary course, middle school BE, junior high school AE

scuola media superiore — = course of studies following middle school/junior high school and preceding university

scuola dell'obbligo — compulsory education

scuola privata — private school

scuola professionale — vocational school

scuola pubblica — state school, public school AE

scuola secondaria — scuola superiore

scuola serale — evening school, night school

scuola di stato o statale state school; scuola superiore — secondary school

••

fare scuola — (insegnare) to teach (school); (avere seguaci) to gain a following

* * *

scuola

/'skwɔla/

sostantivo f.

 1 school; essere, andare a scuola to be at, to go to school; la scuola è finita school is over; fin dai tempi della scuola since one's schooldays; avere scuola (lezione) to have school

 2 (sistema) education (system); riformare la scuola to reform the education system

 3 (fonte di formazione) school (di of), training (di for, in); scuola di vita school of hard knocks, university of life, training for life; della vecchia scuola of the old school

 4 art. letter. filos. school; scuola fiamminga Dutch School; scuola di pensiero school of thought

IDIOMS

fare scuola (insegnare) to teach (school); (avere seguaci) to gain a following

\

COMPOUNDS

scuola alberghiera hotel-management school; scuola di ballo dancing school; scuola per corrispondenza correspondence college; scuola di danza ballet school; scuola elementare primary o elementary school, grade school AE; scuola guida driving school; scuola di lingue school of languages, language school; scuola magistrale = formerly, high school specializing in education; scuola materna nursery school, kindergarten, preschool AE; scuola media inferiore = three years post elementary course, middle school BE, junior high school AE; scuola media superiore = course of studies following middle school/junior high school and preceding university; scuola dell'obbligo compulsory education; scuola privata private school; scuola professionale vocational school; scuola pubblica state school, public school AE; scuola secondaria →  scuola superiore; scuola serale evening school, night school; scuola di stato o statale state school; scuola superiore secondary school.

rzemieślnicz|y

adj. 1. [produkty] craft attr.

- warsztat rzemieślniczy a craftsman’s workshop

2. (warsztatowy) technical

- rzemieślnicza strona utworu the technique of a work of art

Bessemer, Sir Henry

SUBJECT AREA: Metallurgy

[br]

b. 19 January 1813 Charlton (near Hitchin), Hertfordshire, England

d. 15 January 1898 Denmark Hill, London, England

[br]

English inventor of the Bessemer steelmaking process.

[br]

The most valuable part of Bessemer's education took place in the workshop of his inventor father. At the age of only 17 he went to London to seek his fortune and set himself up in the trade of casting art works in white metal. He went on to the embossing of metals and other materials and this led to his first major invention, whereby a date was incorporated in the die for embossing seals, thus preventing the wholesale forgeries that had previously been committed. For this, a grateful Government promised Bessemer a paid position, a promise that was never kept; recognition came only in 1879 with a belated knighthood. Bessemer turned to other inventions, mainly in metalworking, including a process for making bronze powder and gold paint. After he had overcome technical problems, the process became highly profitable, earning him a considerable income during the forty years it was in use.

The Crimean War presented inventors such as Bessemer with a challenge when weaknesses in the iron used to make the cannon became apparent. In 1856, at his Baxter House premises in St Paneras, London, he tried fusing cast iron with steel. Noticing the effect of an air current on the molten mixture, he constructed a reaction vessel or converter in which air was blown through molten cast iron. There was a vigorous reaction which nearly burned the house down, and Bessemer found the iron to be almost completely decarburized, without the slag threads always present in wrought iron. Bessemer had in fact invented not only a new process but a new material, mild steel. His paper "On the manufacture of malleable iron and steel without fuel" at the British Association meeting in Cheltenham later that year created a stir. Bessemer was courted by ironmasters to license the process. However, success was short-lived, for they found that phosphorus in the original iron ore passed into the metal and rendered it useless. By chance, Bessemer had used in his trials pig-iron, derived from haematite, a phosphorus-free ore. Bessemer tried hard to overcome the problem, but lacking chemical knowledge he resigned himself to limiting his process to this kind of pig-iron. This limitation was removed in 1879 by Sidney Gilchrist Thomas, who substituted a chemically basic lining in the converter in place of the acid lining used by Bessemer. This reacted with the phosphorus to form a substance that could be tapped off with the slag, leaving the steel free from this harmful element. Even so, the new material had begun to be applied in engineering, especially for railways. The open-hearth process developed by Siemens and the Martin brothers complemented rather than competed with Bessemer steel. The widespread use of the two processes had a revolutionary effect on mechanical and structural engineering and earned Bessemer around £1 million in royalties before the patents expired.

[br]

Principal Honours and Distinctions

Knighted 1879. FRS 1879. Royal Society of Arts Albert Gold Medal 1872.

Bibliography

1905, Sir Henry Bessemer FRS: An Autobiography, London.

LRD

Breguet, Abraham-Louis

SUBJECT AREA: Horology

[br]

baptized 10 January 1747 Neuchâtel, Switzerland

d. 17 September 1823 Paris, France

[br]

Swiss clock-and watchmaker who made many important contributions to horology.

[br]

When Breguet was 11 years old his father died and his mother married a Swiss watchmaker who had Paris connections. His stepfather introduced him to horology and this led to an apprenticeship in Paris, during which he also attended evening classes in mathematics at the Collège Mazarin. In 1775 he married and set up a workshop in Paris, initially in collaboration with Xavier Gide. There he established a reputation among the aristocracy for elegant and innovative timepieces which included a perpétuelle, or self-winding watch, which he developed from the ideas of Perrelet. He also enjoyed the patronage of Marie Antoinette and Louis XVI. During the French Revolution his life was in danger and in 1793 he fled to Neuchâtel. The two years he spent there comprised what was intellectually one of his most productive periods and provided many of the ideas that he was able to exploit after he had returned to Paris in 1795. By the time of his death he had become the most prestigious watchmaker in Europe: he supplied timepieces to Napoleon and, after the fall of the Empire, to Louis XVIII, as well as to most of the crowned heads of Europe.

Breguet divided his contributions to horology into three categories: improvements in appearance and functionality; improvements in durability; and improvements in timekeeping. His pendule sympathique was in the first category and consisted of a clock which during the night set a watch to time, regulated it and wound it. His parachute, a spring-loaded bearing, made a significant contribution to the durability of a watch by preventing damage to its movement if it was dropped. Among the many improvements that Breguet made to timekeeping, two important ones were the introduction of the overcoil balance spring and the tourbillon. By bending the outside end of the balance spring over the top of the coils Breguet was able to make the oscillations of the balance isochronous, thus achieving for the flat spring what Arnold had already accomplished for the cylindrical balance spring. The timekeeping of a balance is also dependent on its position, and the tourbillon was an attempt to average-out positional errors by placing the balance wheel and the escapement in a cage that rotated once every minute. This principle was revived in a simplified form in the karussel at the end of the nineteenth century.

[br]

Principal Honours and Distinctions

Horloger de la marine 1815. Chevalier de la Légion d'honneur 1815.

Bibliography

Breguet gathered information for a treatise on horology that was never published but which was later plagiarized by Louis Moinet in his Traité d'horlogerie, 1848.

Further Reading

G.Daniels, 1974, The An of Breguet, London (an account of his life with a good technical assessment of his work).

DV

Chippendale, Thomas

SUBJECT AREA: Domestic appliances and interiors

[br]

baptized 5 June 1718 Otley, Yorkshire, England

d. 13 November 1779 London, England

[br]

English cabinet-maker who published the first comprehensive book of furniture.

[br]

Thomas Chippendale was the son of a carpenter. The business that he set up in London was so well established by 1753 that he was able to move to larger premises—a workshop, timberyard and shop—in the furniture-making centre of London, at 60–62 St Martin's Lane. In 1754 he published his folio work The Gentleman and Cabinet-Maker's Director, which contained illustrations of every conceivable type of furniture. No previously published book was as comprehensive. The Director, as it came to be called, made Chippendale famous and he became the best known of all such English craftsmen and designers. Further editions of the book followed in 1755 and 1762.

Stylistically most of the furniture designs in the Director followed the contemporary rococo fashion, but a number followed other popular themes such as the so-called "literary Gothic" and chinoiserie. Indeed, the Chinese versions became so well known that such furniture became known as "Chinese Chippendale". Chippendale's later work was more neo-classical, much of it produced at the request of Robert Adam for the many great houses whose interiors he was re-designing in the 1760s and 1770s.

From a technical viewpoint, Chippendale's furniture was made from a variety of woods and incorporated diverse decoration. Mahogany was the fashionable wood of the age, particularly during the middle years of the eighteenth century, and lent itself especially to the fine and elaborate carving that characterized Chippendale's intricate chair and settee backs. By the later 1760s other woods were also often in use, sometimes gilded and turned, sometimes inlaid with materials such as ivory or ceramic plaques and fine ormolu mounts. Later still, painted designs were applied to panel surfaces. Alternatively, a delicate form of marquetry had been fashionably revived.

[br]

Further Reading

C.Gilbert, 1972, The Life and Work of Thomas Chippendale: Studio Vista.

1986, Dictionary of English Furniture-Makers, The Furniture History Society and W.F. Maney.

DY

Gutenberg, Johann Gensfleisch zum

SUBJECT AREA: Paper and printing

[br]

b. c. 1394–9 Mainz, Germany

d. 3 February 1468 Mainz, Germany

[br]

German inventor of printing with movable type.

[br]

Few biographical details are known of Johann Gensfleisch zum Gutenberg, yet it has been said that he was responsible for Germany's most notable contribution to civilization. He was a goldsmith by trade, of a patrician family of the city of Mainz. He seems to have begun experiments on printing while a political exile in Strasbourg c. 1440. He returned to Mainz between 1444 and 1448 and continued his experiments, until by 1450 he had perfected his invention sufficiently to justify raising capital for its commercial exploitation.

Circumstances were propitious for the invention of printing at that time. Rises in literacy and prosperity had led to the formation of a social class with the time and resources to develop a taste for reading, and the demand for reading matter had outstripped the ability of the scribes to satisfy it. The various technologies required were well established, and finally the flourishing textile industry was producing enough waste material, rag, to make paper, the only satisfactory and cheap medium for printing. There were others working along similar lines, but it was Gutenberg who achieved the successful adaptation and combination of technologies to arrive at a process by which many identical copies of a text could be produced in a wide variety of forms, of which the book was the most important. Gutenberg did make several technical innovations, however. The two-piece adjustable mould for casting types of varying width, from T to "M", was ingenious. Then he had to devise an oil-based ink suitable for inking metal type, derived from the painting materials developed by contemporary Flemish artists. Finally, probably after many experiments, he arrived at a metal alloy of distinctive composition suitable for casting type.

In 1450 Gutenberg borrowed 800 guldens from Johannes Fust, a lawyer of Mainz, and two years later Fust advanced a further 800 guldens, securing for himself a partnership in Gutenberg's business. But in 1455 Fust foreclosed and the bulk of Gutenberg's equipment passed to Peter Schöffer, who was in the service of Fust and later married his daughter. Like most early printers, Gutenberg seems not to have appreciated, or at any rate to have been able to provide for, the great dilemma of the publishing trade, namely the outlay of considerable capital in advance of each publication and the slowness of the return. Gutenberg probably retained only the type for the 42- and 36-line bibles and possibly the Catholicon of 1460, an encyclopedic work compiled in the thirteenth century and whose production pointed the way to printing's role as a means of spreading knowledge. The work concluded with a short descriptive piece, or colophon, which is probably by Gutenberg himself and is the only output of his mind that we have; it manages to omit the names of both author and printer.

Gutenberg seems to have abandoned printing after 1460, perhaps due to failing eyesight as well as for financial reasons, and he suffered further loss in the sack of Mainz in 1462. He received a kind of pension from the Archbishop in 1465, and on his death was buried in the Franciscan church in Mainz. The only major work to have issued for certain from Gutenberg's workshop is the great 42-line bible, begun in 1452 and completed by August 1456. The quality of this Graaf piece of printing is a tribute to Gutenberg's ability as a printer, and the soundness of his invention is borne out by the survival of the process as he left it to the world, unchanged for over three hundred years save in minor details.

[br]

Further Reading

A.Ruppel, 1967, Johannes Gutenberg: sein Leben und sein Werk, 3rd edn, Nieuwkoop: B.de Graaf (the standard biography), A.M.L.de Lamartine, 1960, Gutenberg, inventeur de l'imprimerie, Tallone.

Scholderer, 1963, Gutenberg, Inventor of Printing, London: British Museum.

S.H.Steinberg, 1974, Five Hundred Years of Printing 3rd edn, London: Penguin (provides briefer details).

LRD

Jablochkoff, Paul

SUBJECT AREA: Electricity, Public utilities

[br]

b. 14 September 1847 Serdobsk, Russia

d. April 1894 St Petersburg, Russia

[br]

Russian military engineer and inventor of an electric "candle", the invention of which gave an immense impetus to electric lighting in the 1870s.

[br]

Jablochkoff studied at the Military Engineering College in St Petersburg. Having a scientific bent, he was sent to the Military Galvano Technical School. At the end of his military service in 1871 he was appointed Director General of the Moscow-Kursk telegraph lines for the Midi Railway Company. At this time he began to develop an interest in electric lighting, and in 1875 he left the Imperial Telegraph Service to devote his time exclusively to scientific pursuits. He found employment at the workshop of M Bréguet in Paris, where Gramme dynamos and Serrin arc lamps were being constructed. After some experimentation he found a means of producing a carbon arc that regulated itself without any mechanism. This lamp, the Jablochkoff candle, with two carbon rods placed parallel to each other and so close that an arc formed at the ends, could continue to burn until the rods were consumed. Plaster of Paris was used to separate the two electrodes and crumbled away as the carbon burned, thus exposing fresh carbon. These lamps were used in May 1878 in Paris to illuminate the avenue de l'Opéra, and later in Rome and London, and in essence were the first practical electric street lighting. Since there was no regulating mechanism, several candles could be placed in a single circuit. Despite inherent defects, such as the inability to restart the lamps after they were extinguished by wind or interruption of supply, they remained in use for some purposes for several years on account of their simplicity and cheapness. In 1877 Jablochkoff obtained the earliest patent to employ transformers to distribute current in an alternating-current circuit.

[br]

Bibliography

11 September 1876, British patent no. 3,552 (Jablochkoff's candle).

22 May 1877, British patent no. 1,996 (transformer or induction coil distribution).

Further Reading

W.J.King, 1962, The Development of Electrical Technology in the 19th Century, Washington, DC: Smithsonian Institution, Paper 30, pp. 393–407 (a detailed account). W.E.Langdon, 1877, "On a new form of electric light", Journal of the Society of

Telegraph Engineers 6:303–19 (an early report on Jablochkoffs system).

Engineering (1878) 26:125–7.

GW

Johansson, Carl Edvard

SUBJECT AREA: Automotive engineering, Mechanical, pneumatic and hydraulic engineering

[br]

b. 15 March 1864 Orebro, Sweden

d. 30 September 1943 Eskilstuna, Sweden

[br]

Swedish metrologist and inventor of measuring-gauge blocks.

[br]

Carl Edvard Johansson was first apprenticed to a shoemaker, but he soon abandoned that career. In 1882 he went to America to join his brother Arvid working at a sawmill in the summer; in winter the brothers obtained further general education at the Gustavus Adolphus College at St Peter, Minnesota. They returned to Sweden in November 1884 and in the following year Carl obtained employment with a small engineering firm which rented a workshop in the government small-arms factory at Eskilstuna. In his spare time he attended the Eskilstuna Technical College and in 1888 he was accepted as an apprentice armourer inspector. After completion of his apprenticeship he was appointed an armourer inspector, and it was in his work of inspection that he realized that the large number of gauges then required could be reduced if several accurate gauges could be used in combination. This was in 1896, and the first set of gauges was made for use in the rifle factory. With these, any dimension between 1 mm and 201 mm could be made up to the nearest 0.01 mm, the gauges having flat polished surfaces that would adhere together by "wringing". Johansson obtained patents for the system from 1901, but it was not until c.1907 that the sets of gauges were marketed generally. Gauges were made in inch units for Britain and America—slightly different as the standards were not then identical. Johansson formed his own company to manufacture the gauges in 1910, but he did not give up his post in the rifle factory until 1914. By the 1920s Johansson gauges were established as the engineering dimensional standards for the whole world; the company also made other precision measuring instruments such as micrometers and extensometers. A new company, C.E.Johansson Inc., was set up in America for manufacture and sales, and the gauges were extensively used in the American automobile industry. Henry Ford took a special interest and Johansson spent several years in a post with the Ford Motor Company in Detroit, Michigan, until he returned to Sweden in 1936.

[br]

Principal Honours and Distinctions

Honorary Doctorates, Gustavus Adolphus College, St Peter and Wayne University, Detroit. Swedish Engineering Society John Ericsson Gold Medal. American Society of Mechanical Engineers Gold Medal.

Further Reading

K.J.Hume, 1980, A History of Engineering Metrology, London, pp. 54–66 (a short biography).

RTS

Whitworth, Sir Joseph

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

[br]

b. 21 December 1803 Stockport, Cheshire, England

d. 22 January 1887 Monte Carlo, Monaco

[br]

English mechanical engineer and pioneer of precision measurement.

[br]

Joseph Whitworth received his early education in a school kept by his father, but from the age of 12 he attended a school near Leeds. At 14 he joined his uncle's mill near Ambergate, Derbyshire, to learn the business of cotton spinning. In the four years he spent there he realized that he was more interested in the machinery than in managing a cotton mill. In 1821 he obtained employment as a mechanic with Crighton \& Co., Manchester. In 1825 he moved to London and worked for Henry Maudslay and later for the Holtzapffels and Joseph Clement. After these years spent gaining experience, he returned to Manchester in 1833 and set up in a small workshop under a sign "Joseph Whitworth, Tool Maker, from London".

The business expanded steadily and the firm made machine tools of all types and other engineering products including steam engines. From 1834 Whitworth obtained many patents in the fields of machine tools, textile and knitting machinery and road-sweeping machines. By 1851 the company was generally regarded as the leading manufacturer of machine tools in the country. Whitworth was a pioneer of precise measurement and demonstrated the fundamental mode of producing a true plane by making surface plates in sets of three. He advocated the use of the decimal system and made use of limit gauges, and he established a standard screw thread which was adopted as the national standard. In 1853 Whitworth visited America as a member of a Royal Commission and reported on American industry. At the time of the Crimean War in 1854 he was asked to provide machinery for manufacturing rifles and this led him to design an improved rifle of his own. Although tests in 1857 showed this to be much superior to all others, it was not adopted by the War Office. Whitworth's experiments with small arms led on to the construction of big guns and projectiles. To improve the quality of the steel used for these guns, he subjected the molten metal to pressure during its solidification, this fluid-compressed steel being then known as "Whitworth steel".

In 1868 Whitworth established thirty annual scholarships for engineering students. After his death his executors permanently endowed the Whitworth Scholarships and distributed his estate of nearly half a million pounds to various educational and charitable institutions. Whitworth was elected an Associate of the Institution of Civil Engineers in 1841 and a Member in 1848 and served on its Council for many years. He was elected a Member of the Institution of Mechanical Engineers in 1847, the year of its foundation.

[br]

Principal Honours and Distinctions

Baronet 1869. FRS 1857. President, Institution of Mechanical Engineers 1856, 1857 and 1866. Hon. LLD Trinity College, Dublin, 1863. Hon. DCL Oxford University 1868. Member of the Smeatonian Society of Civil Engineers 1864. Légion d'honneur 1868. Society of Arts Albert Medal 1868.

Bibliography

1858, Miscellaneous Papers on Mechanical Subjects, London; 1873, Miscellaneous Papers on Practical Subjects: Guns and Steel, London (both are collections of his papers to technical societies).

1854, with G.Wallis, The Industry of the United States in Machinery, Manufactures, and

Useful and Ornamental Arts, London.

Further Reading

F.C.Lea, 1946, A Pioneer of Mechanical Engineering: Sir Joseph Whitworth, London (a short biographical account).

A.E.Musson, 1963, "Joseph Whitworth: toolmaker and manufacturer", Engineering Heritage, Vol. 1, London, 124–9 (a short biography).

D.J.Jeremy (ed.), 1984–6, Dictionary of Business Biography, Vol. 5, London, 797–802 (a short biography).

W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (describes Whitworth's machine tools).

RTS