battleships

battleships

Battleships

battleships

battleships ⇒ Games and sports npl Games touché-coulé m.

battleships

n pl AmE infml

Whose battleships are these under the table — Чьи это "гавнодавы" под столом?

battleships

Сленг: башмаки большого размера, большие ноги

battleships

sõjalaevad

battleships

n

სახაზო გემები

Yourkevitch, Vladimir Ivanovitch

SUBJECT AREA: Ports and shipping

[br]

b. 17 June 1885 Moscow, Russia

d. 14 December 1964 USA

[br]

Russian (naturalized American) naval architect who worked in Russia, Western Europe and the United States and who profoundly influenced the hull design of large ships.

[br]

Yourkevitch came from an academic family, but one without any experience or tradition of sea service. Despite this he decided to become a naval architect, and after secondary education at Moscow and engineering training at the St Petersburg Polytechnic, he graduated in 1909. For the following ten years he worked designing battleships and later submarines, mostly at the Baltic Shipyard in St Petersburg. Around 1910 he became a full member of the Russian Naval Constructors Corps, and in 1915 he was a founder member and first Scientific Secretary of the Society of Naval Engineers.

Using the published data of the American Admiral D.W. Taylor and taking advantage of access to the Norddeutscher Lloyd Testing Tank at Bremerhaven, Yourkevitch proposed a new hull form with bulbous bow and long entrances and runs. This was the basis for the revolutionary battleships then laid down at St Petersburg, the "Borodino" class. Owing to the war these ships were launched but never completed. At the conclusion of the war Yourkevitch found himself in Constantinople, where he experienced the life of a refugee, and then he moved to Paris where he accepted almost any work on offer. Fortunately in 1928, through an introduction, he was appointed a draughtsman at the St Nazaire shipyard. Despite his relatively lowly position, he used all his personality to persuade the French company to alter the hull form of the future record breaker Normandie. The gamble paid off and Yourkevitch was able to set up his own naval architecture company, BECNY, which designed many well-known liners, including the French Pasteur.

In 1939 he settled in North America, becoming a US citizen in 1945. On the night of the fire on the Normandie, he was in New York but was prevented from going close to the ship by the police, and the possibility of saving the ship was thrown away. He was involved in many projects as well as lecturing at Ann Arbor, Michigan, and at the Massachusetts Institute of Technology. He maintained connections with his technical colleagues in St Petersburg in the later years of his life. His unfulfilled dream was the creation of a superliner to carry 5,000 passengers and thus able to make dramatic cuts in the cost of transatlantic travel. Yourkevitch was a fine example of a man whose vision enabled him to serve science and engineering without consideration of inter-national boundaries.

[br]

Principal Honours and Distinctions

Order of St Stanislav and Order of St Anna c. 1910.

AK/FMW

stand off

1) держаться на расстоянии от;
отодвинуться от We stood off 500 of the enemy forces for nine days. ≈ В течение девяти дней мы держались на расстоянии 500 от сил врага.
2) отстранить, уволить (на время) 300 workers at the car factory were stood off when there was a lack of steel. ≈ В период нехватки стали, 300 рабочих были уволены с автомобильного завода.
3) мор. удаляться от берега Three battleships were kept standing off as a silent threat to the island people. ≈ Три линкора маячили в дали от берега, оставаясь немой угрозой для жителей острова. держаться на расстоянии;
оставаться в стороне держать( кого-л.) на почтительном расстоянии, не подпускать - to * a creditor отделаться от кредитора - they managed to stand the enemy off им удалось не подпустить врага быть неприветливым, неприступным - to * from one's friends не иметь близких друзей;
быть необщительным отстранить с работы, уволить - if the slump continues more men will be stood off если спад затянется, и другие рабочие потеряют работу (морское) удаляться от берега - to * and on ходить переменными курсами от берега и к берегу

stand off

stand off а) держаться на расстоянии от; отодвинуться от; We stood off 500of the enemy forces for nine days; б) отстранить, уволить (на время); 300workers at the car factory were stood off when there was a lack of steel; в)naut. удаляться от берега; Three battleships were kept standing off as asilent threat to the island people.

battleship

noun (a heavily armed and armoured warship.) acorazado

battleship

tr['bætəlʃɪp]

noun

1 acorazado

battleship ['bæt̬əl.ʃɪp] n

: acorazado m

battleship

n.

• acorazado s.m.

'bætḷʃɪp

noun acorazado m

['bætlʃɪp]

N

1) (Mil) acorazado m

2)

battleships — (=game) los barquitos (juego)

* * *

['bætḷʃɪp]

noun acorazado m

mould

[məuld] 1. (US mold) n

( cast) forma f; ( mildew) pleśń f

2. vt

plastic, clay etc modelować; ( fig) public opinion, character kształtować, urabiać

clay moulded into battleships — okręty wojenne wymodelowane z gliny

* * *

I [mould] noun

1) ((soil which is full of) rotted leaves etc.) czarnoziem

2) (a growth on stale food etc: This bread is covered with mould.) pleśń

•

- mouldy

- mouldiness II 1. [məuld] noun

1) (a shape into which a substance in liquid form is poured so that it may take on that shape when it cools and hardens: a jelly mould.) forma

2) (something, especially a food, formed in a mould.) odlew

2. verb

1) (to form in a mould: The metal is moulded into long bars.) odlewać

2) (to work into a shape: He moulded the clay into a ball.) ukształtować, wymodelować

3) (to make the shape of (something): She moulded the figure out of/in clay.) kształtować, wymodelować

BB

(скор. від battleships) ліні́йні кораблі́

stand off

фраз. гл.

1) держаться на расстоянии

2) (временно) отстранить от дел; уволить

300 workers at the car factory were stood off when there was a lack of steel. — В период нехватки стали 300 рабочих были уволены с автомобильного завода.

3) мор. удаляться от берега

Three battleships were kept standing off as a silent threat to the island people. — Три линкора маячили вдали от берега как немая угроза для островитян.

4) воен. удерживать ( противника)

Booth, Hubert Cecil

SUBJECT AREA: Civil engineering, Domestic appliances and interiors, Mechanical, pneumatic and hydraulic engineering, Ports and shipping

[br]

b. 1871 Gloucester, England d. 1955

[br]

English mechanical, civil and construction engineer best remembered as the inventor of the vacuum cleaner.

[br]

As an engineer Booth contributed to the design of engines for Royal Navy battleships, designed and supervised the erection of a number of great wheels (in Blackpool, Vienna and Paris) and later designed factories and bridges.

In 1900 he attended a demonstration, at St Paneras Station in London, of a new form of railway carriage cleaner that was supposed to blow the dirt into a container. It was not a very successful experiment and Booth, having considered the problem carefully, decided that sucking might be better than blowing. He tried out his idea by placing a piece of damp cloth over an upholstered armchair. When he sucked air by mouth through his cloth the dirt upon it was tangible proof of his theory.

Various attempts were being made at this time, especially in America, to find a successful cleaner of carpets and upholstery. Booth produced the first truly satisfactory machine, which he patented in 1901, and coined the term "vacuum cleaner". He formed the Vacuum Cleaner Co. (later to become Goblin BVC Ltd) and began to manufacture his machines. For some years the company provided a cleaning service to town houses, using a large and costly vacuum cleaner (the first model cost £350). Painted scarlet, it measured 54×10×42 in. (137×25×110 cm) and was powered by a petrol-driven 5 hp piston engine. It was transported through the streets on a horse-driven van and was handled by a team of operators who parked outside the house to be cleaned. With the aid of several hundred feet of flexible hose extending from the cleaner through the windows into all the rooms, the machine sucked the dirt of decades from the carpets; at the first cleaning the weight of many such carpets was reduced by 50 per cent as the dirt was sucked away.

Many attempts were made in Europe and America to produce a smaller and less expensive machine. Booth himself designed the chief British model in 1906, the Trolley- Vac, which was wheeled around the house on a trolley. Still elaborate, expensive and heavy, this machine could, however, be operated inside a room and was powered from an electric light fitting. It consisted of a sophisticated electric motor and a belt-driven rotary vacuum pump. Various hoses and fitments made possible the cleaning of many different surfaces and the dust was trapped in a cloth filter within a small metal canister. It was a superb vacuum cleaner but cost 35 guineas and weighed a hundredweight (50 kg), so it was difficult to take upstairs.

Various alternative machines that were cheaper and lighter were devised, but none was truly efficient until a prototype that married a small electric motor to the machine was produced in 1907 in America.

[br]

Further Reading

The Story of the World's First Vacuum Cleaner, Leatherhead: BSR (Housewares) Ltd. See also Hoover, William Henry.

DY

Fessenden, Reginald Aubrey

SUBJECT AREA: Broadcasting, Electronics and information technology, Telecommunications

[br]

b. 6 October 1866 East Bolton, Quebec, Canada

d. 22 July 1932 Bermuda

[br]

Canadian radio pioneer who made the first known broadcast of speech and music.

[br]

After initial education at Trinity College School, Port Hope, Ontario, Fessenden studied at Bishops University, Lennoxville, Quebec. When he graduated in 1885, he became Principal of the Whitney Institute in Bermuda, but he left the following year to go to New York in pursuit of his scientific interests. There he met Edison and eventually became Chief Chemist at the latter's Laboratory in Orange, New Jersey. In 1890 he moved to the Westinghouse Electric and Manufacturing Company, and two years later he returned to an academic career as Professor of Electrical Engineering, initially at Purdue University, Lafayette, Indiana, and then at the Western University of Pennsylvania, where he worked on wireless communication. From 1900 to 1902 he carried out experiments in wireless telegraphy at the US Weather Bureau, filing several patents relating to wire and liquid thermal detectors, or barretters. Following this he set up the National Electric Signalling Company; under his direction, Alexanderson and other engineers at the General Electric Company developed a high-frequency alternator that enabled him to build the first radiotelephony transmitter at Brant Rock, Massachusetts. This made its initial broadcast of speech and music on 24 December 1906, received by ship's wireless operators several hundred miles away. Soon after this the transmitter was successfully used for two-way wireless telegraphy communication with Scotland. Following this landmark event, Fessenden produced numerous inventions, including a radio compass, an acoustic depth-finder and several submarine signalling devices, a turboelectric drive for battleships and, notably, in 1912 the heterodyne principle used in radio receivers to convert signals to a lower (intermediate) frequency.

[br]

Principal Honours and Distinctions

Institute of Electrical and Electronics Engineers Medal of Honour 1921.

Bibliography

US patents relating to barretters include nos. 706,740, 706,742 and 706,744 (wire, 1902) and 731,029 (liquid, 1903). His invention of the heterodyne was filed as US patent no. 1,050,441 (1913).

Further Reading

Helen M.Fessenden, 1940, Fessenden. Builder of Tomorrow. E.Hawkes, 1927, Pioneers of Wireless, London: Methuen. O.E.Dunlop, 1944, Radio's 100 Men of Science.

KF

Izod, Edwin Gilbert

SUBJECT AREA: Metallurgy

[br]

b. 17 July 1876 Portsmouth, England

d. 2 October 1946 England

[br]

English engineer who devised the notched-bar impact test named after him.

[br]

After a general education at Vickery's School at Southsea, Izod (who pronounced his name Izzod, not Izod) started his career as a premium apprentice at the works of Maudslay, Sons and Field at Lambeth in January 1893. When in 1995 he was engaged in the installation of machinery in HMS Renown at Pembroke, he gained some notoriety for his temerity in ordering Rear Admiral J.A.Fisher, who had no pass, out of the main engine room. He subsequently worked at Portsmouth Dockyard where the battleships Caesar and Gladiator were being engined by Maudslay's. From 1898 to 1900 Izod worked as a Demonstrator in the laboratories of University College London, and he was then engaged by Captain H. Riall Sankey as his Personal Assistant at the Rugby works of Willans and Robinson. Soon after going to Rugby, Izod was asked by Sankey to examine a failed gun barrel and try to ascertain why it burst in testing. Conventional mechanical testing did not reveal any significant differences in the properties of good and bad material. Izod found, however, that, when specimens from the burst barrel were notched, gripped in a vice, and then struck with a hammer they broke in a brittle manner, whereas sounder material merely bent plastically. From these findings his well-known notched-bar impact test emerged. His address to the British Association in September 1903 described the test and his testing machine, and was subsequently published in Engineering. Izod never claimed any priority for this method of test, and generously acknowledged his predecessors in this field, Swedenborg, Fremont, Arnold and Bent Russell. The Izod Test was rapidly adopted by the English-speaking world, although Izod himself, being a busy man, did little to publicize his work, which was introduced to the engineering world largely through the efforts of Captain Sankey. Izod became Assistant Managing Director at Willans, and in 1910 was appointed Chief Consulting Mechanical and Electrical Engineer to the Central Mining Corporation at Johannesburg. He became Managing Director of the Rand Mines in 1918, and returned to the UK in 1927 to become the Managing Director of Weymann Motor Bodies Ltd of Addlestone. As Chairman of this company he extended its activitiesconsiderably.

[br]

Principal Honours and Distinctions

MBE. Member of the Iron and Steel Institute.

Further Reading

1903, "Testing brittleness of steel", Engineering (25 September): 431–2.

ASD

Krylov, Alexei Nicolaevitch

SUBJECT AREA: Ports and shipping

[br]

b. 15 August 1863 Visyoger, Siberia

d. 26 October 1945 Leningrad (now St Petersburg), Russia

[br]

Russian academician and naval architect) exponent of a rigorous mathematical approach to the study of ship motions.

[br]

After schooling in France and Germany, Krylov returned to St Petersburg (as it then was) and in 1878 entered the Naval College. Upon graduating, he started work with the Naval Hydrographic Department; the combination of his genius and breadth of interest became apparent, and from 1888 until 1890 he undertook simultaneously a two-year university course in mathematics and a naval architecture course at his old college. On completion of his formal studies, Krylov commenced fifty years of service to the academic bodies of St Petersburg, including eight years as Superintendent of the Russian Admiralty Ship Model Experiment Tank. For many years he was Professor of Naval Architecture in the city, reorganizing the methods of teaching of his profession in Russia. It was during this period that he laid the foundations of his remarkable research and published the first of his many books destined to become internationally accepted in the fields of waves, rolling, ship motion and vibration. Practical work was not overlooked: he was responsible for the design of many vessels for the Imperial Russian Navy, including the battleships Sevastopol and Petropavlovsk, and went on, as Director of Naval Construction, to test anti-rolling tanks aboard military vessels in the North Atlantic in 1913. Following the Revolution, Krylov was employed by the Soviet Union to re-establish scientific links with other European countries, and on several occasions he acted as Superintendent in the procurement of important technical material from overseas. In 1919 he was appointed Head of the Marine Academy, and from then on participated in many scientific conferences and commissions, mainly in the shipbuilding field, and served on the Editorial Board of the well-respected Russian periodical Sudostroenie (Shipbuilding). The breadth of his personal research was demonstrated by the notable contributions he made to the Russian development of the gyro compass.

[br]

Principal Honours and Distinctions

Member, Russian Academy of Science 1814. Royal Institution of Naval Architects Gold Medal 1898. State Prize of the Soviet Union (first degree). Stalin Premium for work on compass deviation.

Bibliography

Krylov published more than 500 books, papers and articles; these have been collected and published in twelve volumes by the Academy of Sciences of the USSR. 1942, My Memories (autobiography).

AK / FMW

White, Sir William Henry

SUBJECT AREA: Ports and shipping

[br]

b. 2 February 1845 Devonport, England

d. 27 February 1913 London, England

[br]

English naval architect distinguished as the foremost nineteenth-century Director of Naval Construction, and latterly as a consultant and author.

[br]

Following early education at Devonport, White passed the Royal Dockyard entry examination in 1859 to commence a seven-year shipwright apprenticeship. However, he was destined for greater achievements and in 1863 passed the Admiralty Scholarship examinations, which enabled him to study at the Royal School of Naval Architecture at South Kensington, London. He graduated in 1867 with high honours and was posted to the Admiralty Constructive Department. Promotion came swiftly, with appointment to Assistant Constructor in 1875 and Chief Constructor in 1881.

In 1883 he left the Admiralty and joined the Tyneside shipyard of Sir W.G. Armstrong, Mitchell \& Co. at a salary of about treble that of a Chief Constructor, with, in addition, a production bonus based on tonnage produced! At the Elswick Shipyard he became responsible for the organization and direction of shipbuilding activities, and during his relatively short period there enhanced the name of the shipyard in the warship export market. It is assumed that White did not settle easily in the North East of England, and in 1885, following negotiations with the Admiralty, he was released from his five-year exclusive contract and returned to public service as Director of Naval Construction and Assistant Controller of the Royal Navy. (As part of the settlement the Admiralty released Philip Watts to replace White, and in later years Watts was also to move from that same shipyard and become White's successor as Director of Naval Construction.) For seventeen momentous years White had technical control of ship production for the Royal Navy. The rapid building of warships commenced after the passing of the Naval Defence Act of 1889, which authorized directly and indirectly the construction of around seventy vessels. The total number of ships built during the White era amounted to 43 battleships, 128 cruisers of varying size and type, and 74 smaller vessels. While White did not have the stimulation of building a revolutionary capital ship as did his successor, he did have the satisfaction of ensuring that the Royal Navy was equipped with a fleet of all-round capability, and he saw the size, displacement and speed of the ships increase dramatically.

In 1902 he resigned from the Navy because of ill health and assumed several less onerous tasks. During the construction of the Cunard Liner Mauretania on the Tyne, he held directorships with the shipbuilders Swan, Hunter and Wigham Richardson, and also the Parsons Marine Turbine Company. He acted as a consultant to many organizations and had an office in Westminster. It was there that he died in February 1913.

White left a great literary legacy in the form of his esteemed Manual of Naval Architecture, first published in 1877 and reprinted several times since in English, German and other languages. This volume is important not only as a text dealing with first principles but also as an illustration of the problems facing warship designers of the late nineteenth century.

[br]

Principal Honours and Distinctions

KCB 1895. Knight Commander of the Order of the Danneborg (Denmark). FRS. FRSE. President, Institution of Civil Engineers; Mechanical Engineers; Marine Engineers. Vice- President, Institution of Naval Architects.

Bibliography

1877, A Manual of Naval Architecture, London.

Further Reading

D.K.Brown, 1983, A Century of Naval Construction, London.

FMW

Wilde, Henry

SUBJECT AREA: Electricity

[br]

b. 1833 Manchester, England

d. 28 March 1919 Alderley Edge, Cheshire, England

[br]

English inventor and pioneer manufacturer of electrical generators.

[br]

After completing a mechanical engineering apprenticeship Wilde commenced in business as a telegraph and lightning conductor specialist in Lancashire. Several years spent on the design of an alphabetic telegraph resulted in a number of patents. In 1864 he secured a patent for an electromagnetic generator which gave alternating current from a shuttle-wound armature, the field being excited by a small direct-current magneto. Wilde's invention was described to the Royal Society by Faraday in March 1866. When demonstrated at the Paris Exhibition of 1867, Wilde's machine produced sufficient power to maintain an arc light. The small size of the generator provided a contrast to the large and heavy magnetoelectric machines also exhibited. He discovered, by experiment, that alternators in synchronism could be connected in parallel. At about the same time John Hopkinson arrived at the same conclusions on theoretical grounds.

Between 1866 and 1877 he sold ninety-four machines with commutators for electroplating purposes, a number being purchased by Elkingtons of Birmingham. He also supplied generators for the first use of electric searchlights on battleships. In his early experiments Wilde was extremely close to the discovery of true self-excitation from remnant magnetism, a principle which he was to discover in 1867 on machines intended for electroplating. His patents proved to be financially successful and he retired from business in 1884. During the remaining thirty-five years of his life he published many scientific papers, turning from experimental work to philosophical and, finally, theological matters. His record as an inventor established him as a pioneer of electrical engineering, but his lack of scientific training was to restrict his later contributions.

[br]

Principal Honours and Distinctions

FRS 1886.

Bibliography

1 December 1863, British patent no. 3,006 (alternator with a magneto-exciter).

1866, Proceedings of the Royal Society 14:107–11 (first report on Wilde's experiments). 1900, autobiographical note, Journal of the Institution of Electrical Engineers 29:3–17.

Further Reading

W.W.Haldane Gee. 1920, biography, Memoirs, Manchester Literary and Philosophical Society 63:1–16 (a comprehensive account).

P.Dunsheath, 1962, A History of Electrical Engineering, London: Faber \& Faber, pp. 110–12 (a short account).

GW