architect-engineer

♦ naval

♦ naval /ˈneɪvl/

a.

navale; della marina ( da guerra); di marina: (mil.) naval forces, forze navali; naval academy, accademia navale; a naval battle, una battaglia navale; a naval officer, un ufficiale di marina

● naval architect, ingegnere navale □ naval discharge, congedo dalla marina militare □ naval dockyard, arsenale marittimo □ naval engineer, ingegnere navale □ naval outfitter, fornitore della marina militare □ a naval power, una potenza marittima.

marine

1. [məʹri:n] n

1. морской флот

the merchant /mercantile/ marine - торговый флот

2. солдат морской пехоты

the marines - морская пехота

3. жив. морской пейзаж, марина

4. уст.

1) морской берег

2) прибрежная полоса

3) = marina1

♢ tell that to the (horse) marines - скажи(те) это кому-л. другому; ври(те) больше; ≅ расскажи(те) это своей бабушке

2. [məʹri:n] a

1. морской

marine deposits - морские отложения

marine plants - морские растения

marine animals - морские животные

marine park - морской заповедник

marine aerodrome - гидроаэродром

marine belt - пограничная (трёхмильная) зона

marine express - срочная перевозка груза морем

marine painter - художник-маринист

2. военно-морской

marine force - военно-морские силы

3. судовой

marine architect - кораблестроитель, корабельный инженер

marine engines - машины морских судов

marine engineer - судовой механик

marine glue - морской клей (замазка из резины, масла и шеллака)

marine insurance - морское страхование (судов и грузов)

marine stores - а) подержанные корабельные принадлежности; б) судовые припасы

borough

1. n городок, местечко, населённый пункт

Parliamentary borough — город, представленный в английском парламенте

close borough — город, в котором выборы находятся под контролем одного лица

municipal borough — город; имеющий самоуправление

2. n город, выбирающий одного или более представителя в парламент

parliamentary borough — город или округ, представленный в парламенте

3. n амер. один из пяти районов Нью-Йорка

borough engineer — главный инженер района

borough architect — главный архитектор района

4. n округ

pocket borough — «карманный округ»

5. n амер. город средней величины с определёнными привилегиями

borough court — муниципальный суд

Синонимический ряд:

precinct (noun) area; county; district; division; government; municipality; precinct; ward

creator

1. n творец, созидатель, создатель

supreme creator — всевышний творец

2. n создатель

Синонимический ряд:

1. Almighty (noun) Almighty; god; heavenly Father; lord; supreme Being

2. builder (noun) builder; contributor; developer; pioneer

3. originator (noun) architect; author; designer; engineer; father; founder; framer; generator; inventor; maker; mastermind; originator; parent; patriarch; planner; prime mover; sire

marine

1. n морской флот

the merchant marine — торговый флот

marine underwriter — морской страховщик

marine detachment — отряд морской пехоты

marine food chain — морская пищевая цепь

fleet marine force — морская пехота флота

marine borer — морской червь - древоточец

2. n солдат морской пехоты

the marines — морская пехота

contract of marine insurance — договор морского страхования

policy of marine insurance — полис морского страхования

marine risks insurance — страхование от морских рисков

marine pyrotechnics — морские пиротехнические средства

noise due to marine life — шумы от морских организмов

3. n жив. морской пейзаж, марина

marine tubing hanger — морская подвеска лифтовых труб

marine drilling system — система для морского бурения

marine terminal elevator — морской портовый элеватор

marine mammal carcass — туша морского млекопитающего

marine listening watch — морская слуховая радиовахта

4. n уст. морской берег

marine gradiometer — морской градиент

marine completion — морское завершение

marine ensurance — морское страхование

marine insurance — морское страхование

marine fragrance — запах морского бриза

5. n уст. прибрежная полоса

marine life — жизнь на прибрежной полосе

6. a морской

marine deposits — морские отложения

marine plants — морские растения

marine animals — морские животные

marine park — морской заповедник

marine aerodrome — гидроаэродром

marine belt — пограничная зона

marine guidance — морская навигация

marine odour — запах морского бриза

marine scent — запах морского бриза

marine paint — краска для морских судов

marine meteorology — морская метеорология

7. a военно-морской

marine force — военно-морские силы

8. a судовой

marine architect — кораблестроитель, корабельный инженер

marine engines — машины морских судов

marine engineer — судовой механик

marine freezing installation — судовая морозильная установка

marine refrigerating plant — судовая холодильная установка

marine geared-turbine unit — судовой турбозубчатый агрегат

marine cold room — провизионная судовая холодильная камера

marine refrigerating unit — судовая холодильная машина

Синонимический ряд:

nautical (adj.) maritime; nautical; navigational; oceanic; pelagic; thalassic

Антонимический ряд:

earthly; inland; tellurian; terrestrial

planner

1. n чертёжник, проектант, проектировщик

2. n плановик

central planner — главный плановик

3. n топограф

4. n землеустроитель

5. n шотл. садовник-художник

6. n планирующие органы

administrative planner — лицо, занимающееся планированием работы административно-хозяйственных органов

7. n супружеская пара, регулирующая деторождение

8. n методичный человек

Синонимический ряд:

originator (noun) architect; author; creator; designer; engineer; mastermind; originator; prime mover

prime mover

1. первичный двигатель; первичный источник энергии

source mover — устройство для передвижения источника

secondary mover — вторичный двигатель

2. генератор

3. тягач

4. первопричина

5. движущая сила

Синонимический ряд:

originator (noun) architect; author; creator; designer; engineer; mastermind; originator; planner

marine

marine [mə'ri:n]

1 noun

(a) (ships collectively) marine f

(b) (soldier) fusilier m marin; (British or American) marine m;

∎ familiar go tell it to the marines! mon œil!, à d'autres!

2 adjective

(a) (underwater) marin

(b) (naval) maritime

►► marine architect ingénieur m des constructions navales;

marine artist peintre m de marines;

marine bill of lading connaissement m maritime;

marine biologist biologiste m marin;

marine biology biologie f marine;

American Military Marine Corps Marines mpl;

marine engineer mécanicien m de bord;

marine engineering génie m maritime;

marine insurance assurance f maritime;

marine insurance policy police f d'assurance maritime;

marine life vie f marine;

marine risk risque m maritime;

marine surveyor visiteur m ou inspecteur m de navires

Bell, Henry

SUBJECT AREA: Ports and shipping

[br]

b. 1767 Torphichen Mill, near Linlithgow, Scotland

d. 1830 Helensburgh, Scotland

[br]

Scottish projector of the first steamboat service in Europe.

[br]

The son of Patrick Bell, a millwright, Henry had two sisters and an elder brother and was educated at the village school. When he was 9 years old Henry was sent to lodge in Falkirk with an uncle and aunt of his mother's so that he could attend the school there. At the age of 12 he left school and agreed to become a mason with a relative. In 1783, after only three years, he was bound apprentice to his Uncle Henry, a millwright at Jay Mill. He stayed there for a further three years and then, in 1786, joined the firm of Shaw \& Hart, shipbuilders of Borrowstoneness. These were to be the builders of William Symington's hull for the Charlotte Dundas. He also spent twelve months with Mr James Inglis, an engineer of Bellshill, Lanarkshire, and then went to London to gain experience, working for the famous John Rennie for some eighteen months. By 1790 he was back in Glasgow, and a year later he took a partner, James Paterson, into his new business of builder and contractor, based in the Trongate. He later referred to himself as "architect", and his partnership with Paterson lasted seven years. He is said to have invented a discharging machine for calico printing, as well as a steam dredger for clearing the River Clyde.

The Baths Hotel was opened in Helensburgh in 1808, with the hotel-keeper, who was also the first provost of the town, being none other than Henry Bell. It has been suggested that Bell was also the builder of the hotel and this seems very likely. Bell installed a steam engine for pumping sea water out of the Clyde and into the baths, and at first ran a coach service to bring customers from Glasgow three days a week. The driver was his brother Tom. The coach was replaced by the Comet steamboat in 1812.

While Henry was busy with his provost's duties and making arrangements for the building of his steamboat, his wife Margaret, née Young, whom he married in March 1794, occupied herself with the management of the Baths Hotel. Bell did not himself manufacture, but supervised the work of experts: John and Charles Wood of Port Glasgow, builders of the 43ft 6 in. (13.25 m)-long hull of the Comet; David Napier of Howard Street Foundry for the boiler and other castings; and John Robertson of Dempster Street, who had previously supplied a small engine for pumping water to the baths at the hotel in Helensburgh, for the 3 hp engine. The first trials of the finished ship were held on 24 July 1812, when she was launched from Wood's yard. A regular service was advertised in the Glasgow Chronicle on 5 August and was the first in Europe, preceded only by that of Robert Fulton in the USA. The Comet continued to run until 1820, when it was wrecked.

Bell received little reward for his promotion of steam navigation, merely small pensions from the Clyde trustees and others. He was buried at the parish church of Rhu.

[br]

Further Reading

Edward Morris, 1844, Life of Henry Bell.

Henry Bell, 1813, Applying Steam Engines to Vessels.

IMcN

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.

[br]

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

Bogardus, James

SUBJECT AREA: Architecture and building

[br]

b. 14 March 1800 Catskill, New York, USA

d. 13 April 1874 New York, New York, USA

[br]

American constructor of the first buildings composed entirely of cast iron, and inventor of engraving and die-sinking machinery.

[br]

James Bogardus was neither architect nor engineer but he manufactured iron grinding machinery and was known especially for inventing his engraving and die-sinking machinery. He completed his first iron-fronted building in 1848, the five-storeyed chemist shop of John Milhau at 183 Broadway in New York City, but the building for which he is best known was the slightly later example (begun in 1848) that was created as a factory for his own use. This four-storeyed structure was in Center Street, New York City, and its exterior consisted entirely of cast-iron piers and lintels. He went on to build other iron structures around the middle of the century, and these early examples were both functional and attractive, with their simple classical columns and plain architraves contrasting with the heavier and richer ornamentation of such buildings in the second half of the century.

[br]

Further Reading

H.Russell-Hitchcock, 1958, Architecture: Nineteenth and Twentieth Centuries, Penguin, Pelican History of Art series (section on "Building with Iron and Glass").

D.Yarwood, 1985, Encyclopaedia of Architecture, Batsford (section on "Ironwork").

DY

Ctesibius (Ktesibios) of Alexandria

SUBJECT AREA: Horology, Weapons and armour

[br]

fl. c.270 BC Alexandria

[br]

Alexandrian mechanician and inventor.

[br]

Ctesibius made a number of inventions of great importance, which he described in his book Pneumatics, now lost. The Roman engineer and architect Vitruvius quoted extracts from Ctesibius' work in his De Architectura and tells us that Ctesibius was the son of a barber and that he arranged an adjustable mirror controlled by a lead counterweight descending in a cylinder. He noticed that the weight compressed the air, which could be released with a loud noise. That led him to realize that the air was a body or substance: by means of a cylinder and plunger, he went on to invent an air pump with valves. This he connected to the keyboard and rows of pipes of an organ. He also invented a force pump for water.

Ctesibius also improved the clepsydra or water clock, which measured time by the fall of water level in a vessel as the water escaped through a hole in the bottom. The rate of flow varied as the level dropped, so Ctesibius interposed a cistern with an overflow pipe, enabling the water level to be maintained; there was thus a constant flow into a cylinder and the passage of time was indicated by a float with a pointer. He fitted a rack to the float which turned a toothed wheel, to activate bells, singing birds or other "toys". This is probably the first known use of toothed gearing.

Ctesibius is credited with some other inventions of a military nature, such as a catapult, but it was his pumps that established a tradition in antiquity for mechanical invention using the pressure of the air and other fluids, stretching through Philo of Byzantium (c.150 BC) and Hero of Alexandria (c.62 AD) and on through Islam into medieval Western Europe.

[br]

Further Reading

A.G.Drachmann, 1948, Ktesibios, Philon and Heron: A Study in Ancient Pneumatics, Copenhagen: Munksgaard (Acta Hist. Sci. Nat. Med. 4).

LRD

Froude, William

SUBJECT AREA: Ports and shipping

[br]

b. 1810 Dartington, Devon, England

d. 4 May 1879 Simonstown, South Africa

[br]

English naval architect; pioneer of experimental ship-model research.

[br]

Froude was educated at a preparatory school at Buckfastleigh, and then at Westminster School, London, before entering Oriel College, Oxford, to read mathematics and classics. Between 1836 and 1838 he served as a pupil civil engineer, and then he joined the staff of Isambard Kingdom Brunel on various railway engineering projects in southern England, including the South Devon Atmospheric Railway. He retired from professional work in 1846 and lived with his invalid father at Dartington Parsonage. The next twenty years, while apparently unproductive, were important to Froude as he concentrated his mind on difficult mathematical and scientific problems. Froude married in 1839 and had five children, one of whom, Robert Edmund Froude (1846–1924), was to succeed him in later years in his research work for the Admiralty. Following the death of his father, Froude moved to Paignton, and there commenced his studies on the resistance of solid bodies moving through fluids. Initially these were with hulls towed through a house roof storage tank by wires taken over a pulley and attached to falling weights, but the work became more sophisticated and was conducted on ponds and the open water of a creek near Dartmouth. Froude published work on the rolling of ships in the second volume of the Transactions of the then new Institution of Naval Architects and through this became acquainted with Sir Edward Reed. This led in 1870 to the Admiralty's offer of £2,000 towards the cost of an experimental tank for ship models at Torquay. The tank was completed in 1872 and tests were carried out on the model of HMS Greyhound following full-scale towing trials which had commenced on the actual ship the previous year. From this Froude enunciated his Law of Comparisons, which defines the rules concerning the relationship of the power required to move geometrically similar floating bodies across fluids. It enabled naval architects to predict, from a study of a much less expensive and smaller model, the resistance to motion and the power required to move a full-size ship. The work in the tank led Froude to design a model-cutting machine, dynamometers and machinery for the accurate ruling of graph paper. Froude's work, and later that of his son, was prodigious and covered many fields of ship design, including powering, propulsion, rolling, steering and stability. In only six years he had stamped his academic authority on the new science of hydrodynamics, served on many national committees and corresponded with fellow researchers throughout the world. His health suffered and he sailed for South Africa to recuperate, but he contracted dysentery and died at Simonstown. He will be remembered for all time as one of the greatest "fathers" of naval architecture.

[br]

Principal Honours and Distinctions

FRS. Honorary LLD Glasgow University.

Bibliography

1955, The Papers of William Froude, London: Institution of Naval Architects (the Institution also published a memoir by Sir Westcott Abell and an evaluation of his work by Dr R.W.L. Gawn of the Royal Corps of Naval Constructors; this volume reprints all Froude's papers from the Institution of Naval Architects and other sources as diverse as the British Association, the Royal Society of Edinburgh and the Institution of Civil Engineers.

Further Reading

A.T.Crichton, 1990, "William and Robert Edmund Froude and the evolution of the ship model experimental tank", Transactions of the Newcomen Society 61:33–49.

FMW

Fuller, Richard Buckminster

SUBJECT AREA: Architecture and building

[br]

b. 12 July 1895 Milton, Massachusetts, USA

d. 1 July 1983 Los Angeles, California, USA

[br]

American engineer, designer and inventor noted particularly for his creation of the geodesic dome.

[br]

After naval service during the First World War, Fuller worked for some time in the building industry with his father, who was an architect. In 1927 he became interested in trying to solve social problems by providing good, low-cost housing for an expanding population. Utilizing modern techniques applicable in other industries, such as the design of aircraft and ships, he produced his "Dymaxion House", which was transportable and cheap. This was followed in 1946 by his aluminium, stressed-skin, prefabricated house. The geodesic dome is the structural concept for which Fuller is particularly known. It was patented in 1954 and 300,000 were built over a thirty-year period. He had envisaged the dome being utilized on smaller or larger, simple or complex patterns for a wide variety of needs such as enclosing a covered area for a house, a botanical garden, an exhibition pavilion, a factory, a weather station or, indeed, an entire city. A famous example that he designed was that for the US pavilion at Expo '67 in Montreal. A geodesic dome is generally spherical in form, the chief structural elements of which are interconnected in a geodesic pattern, i.e. one in which the lines connecting two points are the shortest possible. The structure is composed of slender, lightweight struts (usually of aluminium) arranged in geometrical patterns, with the metal skeleton covered by a light, plastic material. Inside the dome, all the space is usable and the climate is controllable. Fuller wrote and lectured widely on his patented invention, explaining the importance of structural research particularly in relation to world needs.

[br]

Bibliography

1975, Synergetics: Exploration on the Geometry of Thinking, Macmillan.

1973, with R.W.Marks, The Dymaxion World of Buckminster Fuller, New York: Reprint Anchor.

Further Reading

M.Pawley, 1990, Buckminster Fuller, Trefoil Books.

DY

Herreshoff, Nathaniel Greene

SUBJECT AREA: Ports and shipping

[br]

b. 18 March 1848 Bristol, Rhode Island, USA

d. 2 June 1938 Bristol, Rhode Island, USA

[br]

American naval architect and designer of six successful America's Cup defenders.

[br]

Herreshoff, or, as he was known, Captain Nat, was seventh in a family of nine, four of whom became blind in childhood. Association with such problems may have sharpened his appreciation of shape and form; indeed, he made a lengthy European small-boat trip with a blind brother. While working on yacht designs, he used three-dimensional models in conjunction with the sheer draught on the drawing-board. With many of the family being boatbuilders, he started designing at the age of 16 and then decided to make this his career. As naval architecture was not then a graduating subject, he studied mechanical engineering at Massachusetts Institute of Technology. While still studying, c.1867, he broke new ground by preparing direct reading time handicapping tables for yachts up to 110 ft (33.5 m) long. After working with the Corliss Company, he set up the Herreshoff Manufacturing Company, in partnership with J.B.Herreshoff, as shipbuilders and engineers. Over the years their output included steam machinery, fishing vessels, pleasure craft and racing yachts. They built the first torpedo boat for the US Navy and another for the Royal Navy, the only such acquisition in the late nineteenth century. Herreshoff designed six of the world's greatest yachts, of the America's Cup, between 1890 and 1920. His accomplishments included new types of lightweight wood fasteners, new systems of framing, hollow spars and better methods of cutting sails. He continued to work full-time until 1935 and his work was internationally acclaimed. He maintained cordial relations with his British rivals Fife, Nicholson and G.L. Watson, and enjoyed friendship with his compatriot Edward Burgess. Few will ever match Herreshoff as an all-round engineer and designer.

[br]

Principal Honours and Distinctions

Herreshoff was one of the very few, other than heads of state, to become an Honorary Member of the New York Yacht Club.

Further Reading

L.F.Herreshoff, 1953, Capt. Nat Herreshoff. The Wizard of Bristol, White Plains, NY: Sheridan House; 2nd edn 1981.

FMW

Jenney, William Le Baron

SUBJECT AREA: Architecture and building, Civil engineering

[br]

b. 25 September 1832 Fairhaven, Massachusetts, USA

d. 15 June 1907 Los Angeles, California, USA

[br]

American architect and engineer who pioneered a method of steel-framed construction that made the skyscraper possible.

[br]

Jenney's Home Insurance Building in Chicago was completed in 1885 but demolished in 1931. It was the first building to rise above ten to twelve storeys and was possible because it did not require immensely thick walls on the lower storeys to carry the weight above. Using square-sectioned cast-iron wall piers, hollow cylindrical cast-iron columns on the interior and, across these, steel and cast-iron beams and girders, Jenney produced a load-bearing metal framework independent of the curtain walling. Beams and girders were united by ties as well as being bolted to the vertical members, so providing a strong framework to take the building load. Jenney went on to build in Chicago the Second Leiter Building (1889–91) and, in 1891, the Manhattan Building. He played a considerable part in the planning of the 1893 Chicago World's Fair. Jenney is accepted as having been the founder of the Chicago school of architecture, and he trained many of the later noted architects and builders of the city, such as William Holabird, Martin Roche and Louis Sullivan.

[br]

Further Reading

A.Woltersdorf, 1924, "The father of the skeleton frame building", Western Architecture 33.

F.A.Randall, 1949, History of the Development of Building Construction in Chicago, Urbana: University of Illinois Press.

C.Condit, 1964, The Chicago School of Architecture: A History of Commercial and Public Building in the Chicago Area 1875–1925, Chicago: University of Chicago Press.

DY

Lanchester, Frederick William

SUBJECT AREA: Automotive engineering, Land transport

[br]

b. 28 October 1868 Lewisham, London, England

d. 8 March 1946 Birmingham, England

[br]

English designer and builder of the first all-British motor car.

[br]

The fourth of eight children of an architect, he spent his childhood in Hove and attended a private preparatory school, from where, aged 14, he went to the Hartley Institution (the forerunner of Southampton University). He was then granted a scholarship to the Royal College of Science, South Kensington, and also studied practical engineering at Finsbury Technical College, London. He worked first for a draughtsman and pseudo-patent agent, and was then appointed Assistant Works Manager of the Forward Gas Engine Company of Birmingham, with sixty men and a salary of £1 per week. He was then aged 21. His younger brother, George, was apprenticed to the same company. In 1889 and 1890 he invented a pendulum governor and an engine starter which earned him royalties. He built a flat-bottomed river craft with a stern paddle-wheel and a vertical single-cylinder engine with a wick carburettor of his own design. From 1892 he performed a number of garden experiments on model gliders relating to problems of lift and drag, which led him to postulate vortices from the wingtips trailing behind, much of his work lying behind the theory of modern aerodynamics. The need to develop a light engine for aircraft led him to car design.

In February 1896 his first experimental car took the road. It had a torsionally rigid chassis, a perfectly balanced and almost noiseless engine, dynamically stable steering, epicyclic gear for low speed and reverse with direct drive for high speed. It turned out to be underpowered and was therefore redesigned. Two years later an 8 hp, two-cylinder flat twin appeared which retained the principle of balancing by reverse rotation, had new Lanchester valve-gear and a new method of ignition based on a magneto generator. For the first time a worm and wheel replaced chain-drive or bevel-gear transmission. Lanchester also designed the machinery to make it. The car was capable of about 18 mph (29 km/h): future cars of his travelled at twice that speed. From 1899 to 1904 cars were produced for sale by the Lanchester Engine Company, which was formed in 1898. The company had to make every component except the tyres. Lanchester gave up the managership but remained as Chief Designer, and he remained in this post until 1914.

In 1907–8 his two-volume treatise Aerial Flight was published; it included consideration of skin friction, boundary-layer theory and the theory of stability. In 1909 he was appointed to the Government's Committee for Aeronautics and also became a consultant to the Daimler Company. At the age of 51 he married Dorothea Cooper. He remained a consultant to Daimler and worked also for Wolseley and Beardmore until 1929 when he started Lanchester Laboratories, working on sound reproduction. He also wrote books on relativity and on the theory of dimensions.

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Principal Honours and Distinctions

FRS.

Bibliography

bht=1907–8, Aerial Flight, 2 vols.

Further Reading

P.W.Kingsford, 1966, F.W.Lanchester, Automobile Engineer.

E.G.Semler (ed.), 1966, The Great Masters. Engineering Heritage, Vol. II, London: Institution of Mechanical Engineers/Heinemann.

IMcN

Lilienthal, Otto

SUBJECT AREA: Aerospace

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b. 23 May 1848 Anklam, Prussia (now Germany)

d. 10 August 1896 Berlin, Germany

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German glider pioneer, the first to make a controlled flight using wings.

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Otto Lilienthal and his brother Gustav developed an interest in flying as boys, when they studied birds in flight, built models and even tried to fit wings to their arms. Gustav went on to become a successful architect while Otto, after a brilliant scholastic career, became a mechanical engineer. Otto was able to devote his spare time to the problems of flight, and Gustav helped when his work allowed. They considered manpowered and mechanically powered projects, but neither looked hopeful so they turned to gliding. Otto published his research work in a book, Bird Flight as a Basis for Aviation. By 1889 Otto Lilienthal was ready to test his first full-size gliders. No. 1 and No. 2 were not successful, but No. 3, built in 1891, showed promise. He gradually improved his designs and his launching sites as he gained experience. To take off he ran downhill carrying his hang-glider until it became airborne, then he controlled it by swinging his body weight in the appropriate direction. He even built an artificial mound near Berlin so that he could take off into the wind whichever way it was blowing.

In all, Lilienthal built some eighteen gliders with various wing shapes, including biplanes. By 1895 he was planning movable control surfaces (operated by head movement) and a powered version using a carbonic acid gas motor. Unfortunately, Lilienthal crashed and died of his injuries before these ideas could be tested. In all, he made over two thousand flights covering distances up to 300 m (300 yds. Many of these flights were recorded on photographs and so generated an interest in flying. Lilienthal's achievements also encouraged other pioneers, such as Percy Pilcher in Britain, and Octave Chanute and the Wright brothers in the United States.

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Bibliography

1899, Der Vogelflug als Grundlage der Fliegekunst, Berlin, reprinted c. 1977; repub. in English, 1911, as Bird Flight as a Basis for Aviation.

Further Reading

Charles H.Gibbs-Smith, 1985, Aviation, London (provides a detailed account of Lilienthal's gliders).

P.H.Lilienthal, 1978, "Die Lilienthal Gebrüder", Aerospace (Royal Aeronautical Society) (January) (for more personal information).

"The Lilienthal and Pilcher gliders compared", Flight (1 January 1910 and 8 January 1910) (for details about and plans of a typical Lilienthal glider).

JDS

Nervi, Pier Luigi

SUBJECT AREA: Architecture and building, Civil engineering

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b. 21 June 1891 Sondrio, Italy

d. 9 January 1979 (?), Italy

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Italian engineer who played a vital role in the use and adaptation of reinforced concrete as a structural material from the 1930s to the 1970s.

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Nervi early established a reputation in the use of reinforced concrete with his stadium in Florence (1930–2). This elegant concrete structure combines graceful curves with functional solidity and is capable of seating some 35,000 spectators. The stadium was followed by the aircraft hangars built for the Italian Air Force at Orvieto and Ortebello, in which he spanned the vast roofs of the hangars with thin-shelled vaults supported by precast concrete beams and steel-reinforced ribs. The structural strength and subtle curves of these ribbed roofs set the pattern for Nervi's techniques, which he subsequently varied and elaborated on to solve problems that arose in further commissions.

Immediately after the Second World War Italy was short of supplies of steel for structural purposes so, in contrast to the USA, Britain and Germany, did not for some years construct any quantity of steel-framed rectangular buildinngs used for offices, housing or industrial use. It was Nervi who led the way to a ferroconcrete approach, using a new type of structure based on these materials in the form of a fine steel mesh sprayed with cement mortar and used to roof all kinds of structures. It was a method that resulted in expressionist curves instead of rectangular blocks, and the first of his great exhibition halls at Turin (1949), with a vault span of 240 ft (73 m), was an early example of this technique. Nervi continued to create original and beautiful ferroconcrete structures of infinite variety: for example, the hall at the Lido di Roma, Ostia; the terme at Chianciano; and the three buildings that he designed for the Rome Olympics in 1960. The Palazzetto dello Sport is probably the most famous of these, for which he co-operated with the architect Annibale Vitellozzi to construct a small sports palace seating 5,000 spectators under a concrete "big top" of 194 ft (59 m) diameter, its enclosing walls supported by thirtysix guy ropes of concrete; inside, the elegant roof displays a floral quality. In 1960 Nervi returned to Turin to build his imaginative Palace of Labour for the centenary celebrations of Garibaldi and Victor Emmanuel in the city. This vast hall, like the Crystal Palace in England a century earlier (see Paxton), had to be built quickly and be suitable for later adaptation. It was therefore constructed partly in steel, and the metal supporting columns rose to palm-leaf capitals reminiscent of those in ancient Nile palaces.

Nervi's aim was always to create functional buildings that simultaneously act by their aesthetic qualities as an effective educational influence. Functionalism for Nervi never became "brutalism". In consequence, his work is admired by the lay public as well as by architects. He collaborated with many of the outstanding architects of the day: with Gio Ponti on the Pirelli Building in Milan (1955–9); with Zehrfuss and Breuer on the Y-plan UNESCO Building in Paris (1953–7); and with Marcello Piacentini on the 16,000-seat Palazzo dello Sport in Rome. Nervi found time to write a number of books on building construction and design, lectured in the Universities of Rio de Janiero and Buenos Aires, and was for many years Professor of Technology and Technique of Construction in the Faculty of Architecture at the University of Rome. He continued to design new structures until well into the 1970s.

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Principal Honours and Distinctions

RIBA Royal Gold Medal 1960. Royal Institute of Structural Engineers Gold Medal 1968. Honorary Degree Edinburgh University, Warsaw University, Munich University, London University, Harvard University. Member International Institute of Arts and Letters, Zurich; American Academy of Arts and Sciences; Royal Academy of Fine Arts, Stockholm.

Bibliography

1956, Structures, New York: Dodge.

1945, Scienza o Arte del Costruire?, Rome: Bussola.

Further Reading

P.Desideri et al., 1979, Pier Luigi Nervi, Bologna: Zanichelli.

A.L.Huxtable, 1960, Masters of World Architecture; Pier Luigi Nervi, New York: Braziller.

DY

Ricardo, Sir Harry Ralph

SUBJECT AREA: Aerospace, Steam and internal combustion engines

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b. 26 January 1885 London, England

d. 18 May 1974 Graffham, Sussex, England

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English mechanical engineer; researcher, designer and developer of internal combustion engines.

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Harry Ricardo was the eldest child and only son of Halsey Ricardo (architect) and Catherine Rendel (daughter of Alexander Rendel, senior partner in the firm of consulting civil engineers that later became Rendel, Palmer and Tritton). He was educated at Rugby School and at Cambridge. While still at school, he designed and made a steam engine to drive his bicycle, and by the time he went up to Cambridge in 1903 he was a skilled craftsman. At Cambridge, he made a motor cycle powered by a petrol engine of his own design, and with this he won a fuel-consumption competition by covering almost 40 miles (64 km) on a quart (1.14 1) of petrol. This brought him to the attention of Professor Bertram Hopkinson, who invited him to help with research on turbulence and pre-ignition in internal combustion engines. After leaving Cambridge in 1907, he joined his grandfather's firm and became head of the design department for mechanical equipment used in civil engineering. In 1916 he was asked to help with the problem of loading tanks on to railway trucks. He was then given the task of designing and organizing the manufacture of engines for tanks, and the success of this enterprise encouraged him to set up his own establishment at Shoreham, devoted to research on, and design and development of, internal combustion engines.

Leading on from the work with Hopkinson were his discoveries on the suppression of detonation in spark-ignition engines. He noted that the current paraffinic fuels were more prone to detonation than the aromatics, which were being discarded as they did not comply with the existing specifications because of their high specific gravity. He introduced the concepts of "highest useful compression ratio" (HUCR) and "toluene number" for fuel samples burned in a special variable compression-ratio engine. The toluene number was the proportion of toluene in heptane that gave the same HUCR as the fuel sample. Later, toluene was superseded by iso-octane to give the now familiar octane rating. He went on to improve the combustion in side-valve engines by increasing turbulence, shortening the flame path and minimizing the clearance between piston and head by concentrating the combustion space over the valves. By these means, the compression ratio could be increased to that used by overhead-valve engines before detonation intervened. The very hot poppet valve restricted the advancement of all internal combustion engines, so he turned his attention to eliminating it by use of the single sleeve-valve, this being developed with support from the Air Ministry. By the end of the Second World War some 130,000 such aero-engines had been built by Bristol, Napier and Rolls-Royce before the piston aero-engine was superseded by the gas turbine of Whittle. He even contributed to the success of the latter by developing a fuel control system for it.

Concurrent with this was work on the diesel engine. He designed and developed the engine that halved the fuel consumption of London buses. He invented and perfected the "Comet" series of combustion chambers for diesel engines, and the Company was consulted by the vast majority of international internal combustion engine manufacturers. He published and lectured widely and fully deserved his many honours; he was elected FRS in 1929, was President of the Institution of Mechanical Engineers in 1944–5 and was knighted in 1948. This shy and modest, though very determined man was highly regarded by all who came into contact with him. It was said that research into internal combustion engines, his family and boats constituted all that he would wish from life.

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Principal Honours and Distinctions

Knighted 1948. FRS 1929. President, Institution of Mechanical Engineers 1944–5.

Bibliography

1968, Memo \& Machines. The Pattern of My Life, London: Constable.

Further Reading

Sir William Hawthorne, 1976, "Harry Ralph Ricardo", Biographical Memoirs of Fellows of the Royal Society 22.

JB