1869-1926

Carmona, António Óscar de Fragoso

(1869-1951)

   Career army officer, one of the founders of the Estado Novo (1926-74), and the longest-serving president of the republic of that regime (1926-51). Born in Lisbon in 1869, the son of a career cavalry officer, Oscar Carmona entered the army in 1888 and became a lieutenant in 1894, in the same cavalry regiment in which his father had served. He rose rapidly, and became a general during the turbulent First Republic, briefly served as minister of war in 1923, and achieved public notoriety as prosecutor for the military in one of the famous trials of military personnel in an abortive 1925 coup. General Carmona was one of the key supporters of the 28 May 1926 military coup that overthrew the unstable republic and established the initially unstable military dictatorship (1926-33), which was the political system that founded the Estado Novo (1933-74).

   Carmona took power as president upon the ousting of the Twenty-eighth of May coup leader, General Gomes da Costa, and guided the military dictatorship through political and economic uncertainty until the regime settled upon empowering Antônio de Oliveira Salazar with extraordinary fiscal authority as minister of finance (April 1928). Elected in a managed election based on limited male suffrage in 1928, President Carmona served as the Dictatorship's president of the republic until his death in office in 1951 at age 81. In political creed a moderate republican not a monarchist, General (and later Marshal) Carmona played an essential role in the Dictatorship, which involved a division of labor between Dr. Salazar, who, as prime minister since July 1932 was responsible for the daily management of the government, and Carmona, who was responsible for managing civil-military relations in the system, maintaining smooth relations with Dr. Salazar, and keeping the armed forces officer corps in line and out of political intervention.

   Carmona's amiable personality and reputation for personal honesty, correctness, and hard work combined well with a friendly relationship with the civilian dictator Salazar. Especially in the period 1928-44, in his more vigorous years in the position, Carmona's role was vital in both the political and ceremonial aspects of his job. Car-mona's ability to balance the relationship with Salazar and the pressures and demands from a sometimes unhappy army officer corps that, following the civilianization of the regime in the early 1930s, could threaten military intervention in politics and government, was central to the operation of the regime.

   After 1944, however, Carmona was less effective in this role. His tiring ceremonial visits around Portugal, to the Atlantic Islands, and to the overseas empire became less frequent; younger generations of officers grew alienated from the regime; and Carmona suffered from the mental and physical ailments of old age. In the meantime, Salazar assumed the lion's share of political power and authority, all the while placing his own appointees in office. This, along with the regime's political police (PVDE or PIDE), Republican National Guard, and civil service, as well as a circle of political institutions that monopolized public office, privilege, and decision making, made Carmona's role as mediator-intermediary between the career military and the largely civilian-managed system significantly less important. Increasingly feeble and less aware of events around him, Carmona died in office in April 1951 and was replaced by Salazar's chosen appointee, General (and later Marshal) Francisco Craveiro Lopes, who was elected president of the republic in a regime-managed election.

Herbert, Edward Geisler

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering, Metallurgy

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b. 23 March 1869 Dedham, near Colchester, Essex, England

d. 9 February 1938 West Didsbury, Manchester, England

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English engineer, inventor of the Rapidor saw and the Pendulum Hardness Tester, and pioneer of cutting tool research.

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Edward Geisler Herbert was educated at Nottingham High School in 1876–87, and at University College, London, in 1887–90, graduating with a BSc in Physics in 1889 and remaining for a further year to take an engineering course. He began his career as a premium apprentice at the Nottingham works of Messrs James Hill \& Co, manufacturers of lace machinery. In 1892 he became a partner with Charles Richardson in the firm of Richardson \& Herbert, electrical engineers in Manchester, and when this partnership was dissolved in 1895 he carried on the business in his own name and began to produce machine tools. He remained as Managing Director of this firm, reconstituted in 1902 as a limited liability company styled Edward G.Herbert Ltd, until his retirement in 1928. He was joined by Charles Fletcher (1868–1930), who as joint Managing Director contributed greatly to the commercial success of the firm, which specialized in the manufacture of small machine tools and testing machinery.

Around 1900 Herbert had discovered that hacksaw machines cut very much quicker when only a few teeth are in operation, and in 1902 he patented a machine which utilized this concept by automatically changing the angle of incidence of the blade as cutting proceeded. These saws were commercially successful, but by 1912, when his original patents were approaching expiry, Herbert and Fletcher began to develop improved methods of applying the rapid-saw concept. From this work the well-known Rapidor and Manchester saws emerged soon after the First World War. A file-testing machine invented by Herbert before the war made an autographic record of the life and performance of the file and brought him into close contact with the file and tool steel manufacturers of Sheffield. A tool-steel testing machine, working like a lathe, was introduced when high-speed steel had just come into general use, and Herbert became a prominent member of the Cutting Tools Research Committee of the Institution of Mechanical Engineers in 1919, carrying out many investigations for that body and compiling four of its Reports published between 1927 and 1933. He was the first to conceive the idea of the "tool-work" thermocouple which allowed cutting tool temperatures to be accurately measured. For this advance he was awarded the Thomas Hawksley Gold Medal of the Institution in 1926.

His best-known invention was the Pendulum Hardness Tester, introduced in 1923. This used a spherical indentor, which was rolled over, rather than being pushed into, the surface being examined, by a small, heavy, inverted pendulum. The period of oscillation of this pendulum provided a sensitive measurement of the specimen's hardness. Following this work Herbert introduced his "Cloudburst" surface hardening process, in which hardened steel engineering components were bombarded by steel balls moving at random in all directions at very high velocities like gaseous molecules. This treatment superhardened the surface of the components, improved their resistance to abrasion, and revealed any surface defects. After bombardment the hardness of the superficially hardened layers increased slowly and spontaneously by a room-temperature ageing process. After his retirement in 1928 Herbert devoted himself to a detailed study of the influence of intense magnetic fields on the hardening of steels.

Herbert was a member of several learned societies, including the Manchester Association of Engineers, the Institute of Metals, the American Society of Mechanical Engineers and the Institution of Mechanical Engineers. He retained a seat on the Board of his company from his retirement until the end of his life.

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Principal Honours and Distinctions

Manchester Association of Engineers Butterworth Gold Medal 1923. Institution of Mechanical Engineers Thomas Hawksley Gold Medal 1926.

Bibliography

E.G.Herbert obtained several British and American patents and was the author of many papers, which are listed in T.M.Herbert (ed.), 1939, "The inventions of Edward Geisler Herbert: an autobiographical note", Proceedings of the Institution of Mechanical Engineers 141: 59–67.

ASD / RTS

Le Chatelier, Henri Louis

SUBJECT AREA: Metallurgy

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b. 8 November 1850 Paris, France

d. 17 September 1926 Miribel-les-Echelle, France

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French inventor of the rhodium—platinum thermocouple and the first practical optical pyrometer, and pioneer of physical metallurgy.

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The son of a distinguished engineer, Le Chatelier entered the Ecole Polytechnique in 1869: after graduating in the Faculty of Mines, he was appointed Professor at the Ecole Supérieure des Mines in 1877. After assisting Deville with the purification of bauxite in unsuccessful attempts to obtain aluminium in useful quantities, Le Chatelier's work covered a wide range of topics and he gave much attention to the driving forces of chemical reactions. Between 1879 and 1882 he studied the mechanisms of explosions in mines, and his doctorate in 1882 was concerned with the chemistry and properties of hydraulic cements. The dehydration of such materials was studied by thermal analysis and dilatometry. Accurate temperature measurement was crucial and his work on the stability of thermocouples, begun in 1886, soon established the superiority of rhodium-platinum alloys for high-temperature measurement. The most stable combination, pure platinum coupled with a 10 per cent rhodium platinum positive limb, became known as Le Chatelier couple and was in general use throughout the industrial world until c. 1922. For applications where thermocouples could not be used, Le Chatelier also developed the first practical optical pyrometer. From hydraulic cements he moved on to refractory and other ceramic materials which were also studied by thermal analysis and dilatometry. By 1888 he was systematically applying such techniques to metals and alloys. Le Chatelier, together with Osmond, Worth, Genet and Charpy, was a leading member of that group of French investigators who established the new science of physical metallurgy between 1888 and 1900. Le Chatelier was determining the recalescence points in steels in 1888 and was among the first to study intermetallic compounds in a systematic manner. To facilitate such work he introduced the inverted microscope, upon which metallographers still depend for the routine examination of polished and etched metallurgical specimens under incident light. The principle of mobile equilibrium, developed independently by Le Chatelier in 1885 and F.Braun in 1886, stated that if one parameter in an equilibrium situation changed, the equilibrium point of the system would move in a direction which tended to reduce the effect of this change. This provided a useful qualitative working tool for the experimentalists, and was soon used with great effect by Haber in his work on the synthesis of ammonia.

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Principal Honours and Distinctions

Grand Officier de la Légion d'honneur. Honorary Member of the Institute of Metals 1912. Iron and Steel Institute Bessemer Medal.

Further Reading

F.Le Chatelier, 1969, Henri Le Chatelier.

C.K.Burgess and H.L.Le Chatelier, The Measurement of High Temperature.

ASD

Pratt, Francis Ashbury

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

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b. 15 February 1827 Woodstock, Vermont, USA

d. 10 February 1902 Hartford, Connecticut, USA

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American mechanical engineer and machine-tool manufacturer.

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Francis A.Pratt served an apprenticeship as a machinist with Warren Aldrich, and on completing it in 1848 he entered the Gloucester Machine Works as a journeyman machinist. From 1852 to 1854 he worked at the Colt Armory in Hartford, Connecticut, where he met his future partner, Amos Whitney. He then became Superintendent of the Phoenix Iron Works, also at Hartford and run by George S.Lincoln \& Company. While there he designed the well-known "Lincoln" miller, which was first produced in 1855. This was a development of the milling machine built by Robbins \& Lawrence and designed by F.W. Howe, and incorporated a screw drive for the table instead of the rack and pinion used in the earlier machine.

Whitney also moved to the Phoenix Iron Works, and in 1860 the two men started in a small way doing machine work on their own account. In 1862 they took a third partner, Monroe Stannard, and enlarged their workshop. The business continued to expand, but Pratt and Whitney remained at the Phoenix Iron Works until 1864 and in the following year they built their first new factory. The Pratt \& Whitney Company was incorporated in 1869 with a capital of $350,000, F.A.Pratt being elected President. The firm specialized in making machine tools and tools particularly for the armament industry. In the 1870s Pratt made no less than ten trips to Europe gaining orders for equipping armouries in many different countries. Pratt \& Whitney was one of the leading firms developing the system of interchangeable manufacture which led to the need to establish national standards of measurement. The Rogers-Bond Comparator, developed with the backing of Pratt \& Whitney, played an important part in the establishment of these standards, which formed the basis of the gauges of many various types made by the firm. Pratt remained President of the company until 1898, after which he served as their Consulting Engineer for a short time before retiring from professional life. He was granted a number of patents relating to machine tools. He was a founder member of the American Society of Mechanical Engineers in 1880 and was elected a vice-president in 1881. He was an alderman of the city of Hartford.

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Principal Honours and Distinctions

Vice-President, American Society of Mechanical Engineers 1881.

Further Reading

J.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, 111. (describes the origin and development of the Pratt \& Whitney Company).

RTS

Roebling, Washington Augustus

SUBJECT AREA: Civil engineering

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b. 26 May 1837 Saxonburg, Pennsylvania, USA

d. 21 July 1926 Trenton, New Jersey, USA.

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American civil engineer.

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The son of John Augustus Roebling, he graduated in 1857 from the Rensselaer Polytechnic Institute as a civil engineer, and joined his father in his suspension bridge construction work. He served in the Civil War as a colonel of engineers in the Union Army, and in 1867, two years after the end of the war, he went to Europe to study new methods of sinking underwater foundations by means of compressed air. These new methods were employed in the construction of the Brooklyn Bridge, of which he took charge on his father's death in 1869. Timber pneumatic caissons were used, with a maximum pressure of 34 psi (2.4 kg/cm²) above atmospheric pressure. Two years after work on the piers had started in the caissons, Roebling, who had been working constantly with the men on the foundations of the piers, was carried unconscious out of the caisson, a victim of decompression sickness, then known as “caisson disease”. He was paralysed and lost the use of his voice. From then on he directed the rest of the work from the sickroom of his nearby house, his wife, Emily Warren Roebling, helping with his instructions and notes and carrying them out to the workforce; she even read a statement from him to the American Society of Civil Engineers. The erection of the cables, which were of steel, began in August 1876 and took twenty-six months to complete. In 1881 eleven trustees and Emily Warren Roebling walked across temporary planking, but the decking of the total span was not completed until 1885, fourteen years after construction of the bridge had started. The Brooklyn Bridge was Roebling's last major work, although following the death of his nephew in 1921 he was forced to head again the management of Roebling \& Company, though aged 84 and an invalid.

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Further Reading

D.B.Steinman and S.R.Watson, 1941, Bridges and their Builders, New York: Dover Books.

D.McCullough, 1982, The Great Bridge: The Epic Story of the Building of the Brooklyn

Bridge, New York: Simon \& Schuster.

IMcN

Spencer, Christopher Miner

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

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b. 10 June 1833 Manchester, Connecticut, USA

d. 14 January 1922 Hartford, Connecticut, USA

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American mechanical engineer and inventor.

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

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

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

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Further Reading

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

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

RTS

Whitney, Amos

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

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b. 8 October 1832 Biddeford, Maine, USA

d. 5 August 1920 Poland Springs, Maine, USA

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American mechanical engineer and machine-tool manufacturer.

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Amos Whitney was a member of the same distinguished family as Eli Whitney. His father was a locksmith and machinist and he was apprenticed at the age of 14 to the Essex Machine Company of Lawrence, Massachusetts. In 1850 both he and his father were working at the Colt Armory in Hartford, Connecticut, where he first met his future partner, F.A. Pratt. They both subsequently moved to the Phoenix Iron Works, also at Hartford, and in 1860 they started in a small way doing machine work on their own account. In 1862 they took a third partner, Monroe Stannard, and enlarged their workshop. The business continued to expand, but Pratt and Whitney remained at the Phoenix Iron Works until 1864 and in the following year they built their first new factory. The Pratt \& Whitney Company was incorporated in 1869 with a capital of $350,000, Amos Whitney being appointed General Superintendent. The firm specialized in making machine tools and tools particularly for the armament industry. Pratt \& Whitney was one of the leading firms developing the system of interchangeable manufacture which led to the need to establish national standards of measurement. The Rogers-Bond Comparator, developed with the backing of Pratt \& Whitney, played an important part in the establishment of these standards, which formed the basis of the gauges of many various types made by the firm.

Amos Whitney was made Vice-President of Pratt \& Whitney Company in 1893 and was President from 1898 until 1901, when the company was acquired by the Niles- Bement-Pond Company: he then remained as one of the directors. He was elected a Member of the American Society of Mechanical Engineers in 1913.

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Further Reading

J.W.Roe, 1916, English and American Tool Builders, New Haven; reprinted 1926, New York, and 1987, Bradley, Ill. (describes the origin and development of the Pratt \& Whitney Company).

RTS