principal+contract

Holland, John Philip

SUBJECT AREA: Ports and shipping

[br]

b. 29 February 1840 Liscanor, Co. Clare, Ireland

d. 12 August 1915 Newark, New Jersey, USA

[br]

Irish/American inventor of the successful modern submarine

[br]

Holland was educated first in his native town and later in Limerick, a seaport bustling with coastal trade ships. His first job was that of schoolteacher, and as such he worked in various parts of Ireland until he was about 32 years old. A combination of his burning patriotic zeal for Ireland and his interest in undersea technology (then in its infancy) made him consider designs for underwater warships for use against the British Royal Navy in the fight for Irish independence. He studied all known works on the subject and commenced drawing plans, but he was unable to make real headway owing to a lack of finance.

In 1873 he travelled to the United States, ultimately settling in New Jersey and continuing in the profession of teaching. His work on submarine design continued, but in 1875 he suffered a grave setback when the United States Navy turned down his designs. Help came from an unexpected source, the Irish Republican Brotherhood, or Fenian Society, which had been founded in Dublin and New York in 1858. Financial help enabled Holland to build a 4 m (13 ft) one-person craft, which was tested in 1878, and then a larger boat of 19 tonnes' displacement that was tested with a crew of three to depths of 20 m (65 ft) in New York's harbour in 1883. Known as the Fenian Ram, it embodied most of the principles of modern submarines, including weight compensation. The Fenians commandeered this boat, but they were unable to operate it satisfactorily and it was relegated to history.

Holland continued work, at times independently and sometimes with others, and continuously advocated submarines to the United States Navy. In 1895 he was successful in winning a contract for US$150,000 to build the US Submarine Plunger at Baltimore. With too much outside interference, this proved an unsatisfactory venture. However, with only US$5,000 of his capital left, Holland started again and in 1898 he launched the Holland at Elizabeth, New Jersey. This 16 m (52 ft) vessel was successful, and in 1900 it was purchased by the United States Government.

Six more boats were ordered by the Americans, and then some by the Russians and the Japanese. The British Royal Navy ordered five, which were built by Vickers Son and Maxim (now VSEL) at Barrow-in-Furness in the years up to 1903, commencing their long run of submarine building. They were licensed by another well-known name, the Electric Boat Company, which had formerly been the J.P.Holland Torpedo Boat Company.

Holland now had some wealth and was well known. He continued to work, trying his hand at aeronautical research, and in 1904 he invented a respirator for use in submarine rescue work. It is pleasing to record that one of his ships can be seen to this day at the Royal Navy Submarine Museum, Gosport: HM Submarine Holland No. 1, which was lost under tow in 1913 but salvaged and restored in the 1980s.

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Principal Honours and Distinctions

Order of the Rising Sun, Japan, 1910.

Bibliography

1900, "The submarine boat and its future", North American Review (December). Holland wrote several other articles of a similar nature.

Further Reading

R.K.Morris, 1966 John P.Holland 1841–1914, Inventor of the Modern Submarine, Annapolis, MD: US Naval Institute.

F.W.Lipscomb, 1975, The British Submarine, London: Conway Maritime Press. A.N.Harrison, 1979, The Development of HM Submarines from Holland No. 1 (1901) to

Porpoise (1930), Bath: MoD Ships Department (internal publication).

FMW

Howden, James

SUBJECT AREA: Steam and internal combustion engines

[br]

b. 29 February 1832 Prestonpans, East Lothian, Scotland

d. 21 November 1913 Glasgow, Scotland

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Scottish engineer and boilermaker, inventor of the forced-draught system for the boiler combustion chamber.

[br]

Howden was educated in Prestonpans. While aged only 14 or 15, he travelled across Scotland by canal to Glasgow, where he served an engineering apprenticeship with James Gray \& Co. In 1853 he completed his time and for some months served with the civil engineers Bell and Miller, and then with Robert Griffiths, a designer of screw propellers for ships. In 1854, at the age of 22, Howden set up as a consulting engineer and designer. He designed a rivet-making machine from which he realized a fair sum by the sale of patent rights, this assisting him in converting the design business into a manufacturing one. His first contract for a marine engine came in 1859 for the compound steam engine and the watertube boilers of the Anchor Liner Ailsa Craig. This ship operated at 100 psi (approximately 7 kg/cm²), well above the norm for those days. James Howden \& Co. was formed in 1862. Despite operating in the world's most competitive market, the new company remained prosperous through the flow of inventions in marine propulsion. Shipbuilding was added to the company's list of services, but such work was subcontracted. Work was obtained from all the great shipping companies building in the Glasgow region, and with such throughput Howden's could afford research and experimentation. This led to the Howden hot-air forced-draught system, whereby furnace waste gases were used to heat the air being drawn into the combustion chambers. The first installation was on the New York City, built in 1885 for West Indian service. Howden's fertile mind brought about a fully enclosed high-speed marine steam engine in the 1900s and, shortly after, the Howden-Zoelly impulse steam turbine for land operation. Until his death, Howden worked on many technical and business problems: he was involved in the St Helena Whaling Company, marble quarrying in Greece and in the design of a recoilless gun for the Admiralty.

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Principal Honours and Distinctions

Howden was the last surviving member of the group who founded the Institution of Engineers and Shipbuilders in Scotland in 1857.

Bibliography

Howden contributed several papers to the Institution of Engineers and Shipbuilders in Scotland.

Further Reading

C.W.Munn, 1986, "James Howden", Dictionary of Scottish Business Biography, Vol. I, Aberdeen.

FMW

Napier, Robert

SUBJECT AREA: Ports and shipping

[br]

b. 18 June 1791 Dumbarton, Scotland

d. 23 June 1876 Shandon, Dunbartonshire, Scotland

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Scottish shipbuilder one of the greatest shipbuilders of all time, known as the "father" of Clyde shipbuilding.

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Educated at Dumbarton Grammar School, Robert Napier had been destined for the Church but persuaded his father to let him serve an apprenticeship as a blacksmith under him. For a while he worked in Edinburgh, but then in 1815 he commenced business in Glasgow, the city that he served for the rest of his life. Initially his workshop was in Camlachie, but it was moved in 1836 to a riverside factory site at Lancefield in the heart of the City and again in 1841 to the Old Shipyard in the Burgh of Govan (then independent of the City of Glasgow). The business expanded through his preparedness to build steam machinery, beginning in 1823 with the engines for the paddle steamer Leven, still to be seen a few hundred metres from Napier's grave in Dumbarton. His name assured owners of quality, and business expanded after two key orders: one in 1836 for the Honourable East India Company; and the second two years later for the Royal Navy, hitherto the preserve of the Royal Dockyards and of the shipbuilders of south-east England. Napier's shipyard and engine shops, then known as Robert Napier and Sons, were to be awarded sixty Admiralty contracts in his lifetime, with a profound influence on ship and engine procurement for the Navy and on foreign governments, which for the first time placed substantial work in the United Kingdom.

Having had problems with hull subcontractors and also with the installation of machinery in wooden hulls, in 1843 Napier ventured into shipbuilding with the paddle steamer Vanguard, which was built of iron. The following year the Royal Navy took delivery of the iron-hulled Jackall, enabling Napier to secure the contract for the Black Prince, Britain's second ironclad and sister ship to HMS Warrior now preserved at Portsmouth. With so much work in iron Napier instigated studies into metallurgy, and the published work of David Kirkaldy bears witness to his open-handedness in assisting the industry. This service to industry was even more apparent in 1866 when the company laid out the Skelmorlie Measured Mile on the Firth of Clyde for ship testing, a mile still in use by ships of all nations.

The greatest legacy of Robert Napier was his training of young engineers, shipbuilders and naval architects. Almost every major Scottish shipyard, and some English too, was influenced by him and many of his early foremen left to set up rival establishments along the banks of the River Clyde. His close association with Samuel Cunard led to the setting up of the company now known as the Cunard Line. Napier designed and engined the first four ships, subcontracting the hulls of this historic quartet to other shipbuilders on the river. While he contributed only 2 per cent to the equity of the shipping line, they came back to him for many more vessels, including the magnificent paddle ship Persia, of 1855.

It is an old tradition on the Clyde that the smokestacks of ships are made by the enginebuilders. The Cunard Line still uses red funnels with black bands, Napier's trademark, in honour of the engineer who set them going.

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Principal Honours and Distinctions

Knight Commander of the Dannebrog (Denmark). President, Institution of Mechanical Engineers 1864. Honorary Member of the Glasgow Society of Engineers 1869.

Further Reading

James Napier, 1904, The Life of Robert Napier, Edinburgh, Blackwood.

J.M.Halliday, 1980–1, "Robert Napier. The father of Clyde shipbuilding", Transactions of the Institution of Engineers and Shipbuilders in Scotland 124.

Fred M.Walker, 1984, Song of the Clyde. A History of Clyde Shipbuilding, Cambridge: PSL.

See also: Fairbairn, William; Thomson, Sir William

FMW

Porsche, Ferdinand

SUBJECT AREA: Automotive engineering, Land transport

[br]

b. 3 September 1875 Maffersdorf, Austria

d. 30 January 1952 Stuttgart, Baden-Württemberg, Germany

[br]

Austrian automobile engineer, designer of the Volkswagen car.

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At the age of fifteen, Porsche built a complete electrical installation for his home. In 1894 he went to technical school in Vienna. Four years later he became Manager of the test department of the Bela Egger concern, which later became part of the Brown Boveri organization where he became the first Assistant in the calculating section. In 1899 he joined the long-established coachbuilders Jacob Lohner, and in 1902 a car of his design with mixed drive won the 1,000 kg (2,200 lb) class in the Exelberg races. In 1905 he joined the Austro-Daimler Company as Technical Director; his subsequent designs included an 85 hp mixed-drive racing car in 1907 and in 1912 an air-cooled aircraft engine which came to be known in later years as the "great-grandfather" of the Volkswagen engine. In 1916, he became Managing Director of Austro-Daimler.

In 1921 he designed his first small car, which, appearing under the name of Sasch, won its class in the 1922 Targa Florio, a gruelling road-race in Italy. In 1923 Porsche left Austro-Daimler and joined the Daimler Company in Untertürk-heim, near Stuttgart, Germany. In 1929 he joined the firm of Steyr in Austria as a director and chief engineer, and in 1930 he set up his own independent design office in Stuttgart. In 1932 he visited Russia, and in the same year completed the design calculations for the Auto-Union racing car.

In 1934, with his son Ferry (b. 1909), he prepared a plan for the construction of the German "people's car", a project initiated by Adolf Hitler and his Nazi regime; in June of that year he signed a contract for the design work on the Volkswagen. Racing cars of his design were also successful in 1934: the rear-engined Auto-Union won the German Grand Prix, and another Au to-Union car took the Flying Kilometre speed record at 327 km/h (203.2 mph). In 1935 Daimler-Benz started preproduction on the Volkswagen. The first trials of the cars took place in the autumn of 1936, and the following year thirty experimental cars were built by Daimler-Benz. In that year, Porsche visited the United States, where he met Henry Ford; in October an Auto-Union took the Flying Five Kilometre record at 404.3 km/h (251.2 mph). On 26 May 1938, the foundation stone of the Volkswagen factory was laid in Wolfsburg, near Braunschweig, Germany.

In October 1945 Ferdinand Porsche was arrested by a unit of the United States Army and taken to Hessen; the French army removed him to Baden-Baden, then to Paris and later to Dijon. During this time he was consulted by Renault engineers regarding the design of their 4CV and designed a diesel-engined tractor. He was finally released on 5 August 1947. His last major work before his death was the approval of the design for the Cisitalia Grand Prix car.

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Principal Honours and Distinctions

Poetting Medal 1905. Officer's Cross of Franz Josef 1916. Honorary PhD, Vienna Technical University 1916. Honorary PhD, University of Stuttgart 1924.

Further Reading

K.Ludvigsen, 1983, Porsche: Excellence Was Expected: The Complete History of the Sports and Racing Cars, London: Frederick Muller.

T.Shuler and G.Borgeson, 1985, "Origin and Evolution of the VW Beetle", Automobile

Quarterly (May).

M.Toogood, 1991, Porsche—Germany's Legend, London: Apple Press.

IMcN

Sarnoff, David

SUBJECT AREA: Broadcasting, Electronics and information technology, Telecommunications

[br]

b. 27 February 1891 Uzlian, Minsk (now in Belarus)

d. 12 December 1971 New York City, New York, USA

[br]

Russian/American engineer who made a major contribution to the commercial development of radio and television.

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As a Jewish boy in Russia, Sarnoff spent several years preparing to be a Talmudic Scholar, but in 1900 the family emigrated to the USA and settled in Albany, New York. While at public school and at the Pratt Institute in Brooklyn, New York, he helped the family finances by running errands, selling newspapers and singing the liturgy in the synagogue. After a short period as a messenger boy with the Commercial Cable Company, in 1906 he became an office boy with the Marconi Wireless Telegraph Company of America (see G. Marconi). Having bought a telegraph instrument with his first earnings, he taught himself Morse code and was made a junior telegraph operator in 1907. The following year he became a wireless operator at Nantucket Island, then in 1909 he became Manager of the Marconi station at Sea Gate, New York. After two years at sea he returned to a shore job as wireless operator at the world's most powerful station at Wanamaker's store in Manhattan. There, on 14 April 1912, he picked up the distress signals from the sinking iner Titanic, remaining at his post for three days.

Rewarded by rapid promotion (Chief Radio Inspector 1913, Contract Manager 1914, Assistant Traffic Manager 1915, Commercial Manager 1917) he proposed the introduction of commercial radio broadcasting, but this received little response. Consequently, in 1919 he took the job of Commercial Manager of the newly formed Radio Corporation of America (RCA), becoming General Manager in 1921, Vice- President in 1922, Executive Vice-President in 1929 and President in 1930. In 1921 he was responsible for the broadcasting of the Dempsey-Carpentier title-fight, as a result of which RCA sold $80 million worth of radio receivers in the following three years. In 1926 he formed the National Broadcasting Company (NBC). Rightly anticipating the development of television, in 1928 he inaugurated an experimental NBC television station and in 1939 demonstrated television at the New York World Fair. Because of his involvement with the provision of radio equipment for the armed services, he was made a lieutenant-colonel in the US Signal Corps Reserves in 1924, a full colonel in 1931 and, while serving as a communications consultant to General Eisenhower during the Second World War, Brigadier General in 1944.

With the end of the war, RCA became a major manufacturer of television receivers and then invested greatly in the ultimately successful development of shadowmask tubes and receivers for colour television. Chairman and Chief Executive from 1934, Sarnoff held the former post until his retirement in 1970.

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Principal Honours and Distinctions

French Croix de Chevalier d'honneur 1935, Croix d'Officier 1940, Croix de Commandant 1947. Luxembourg Order of the Oaken Crown 1960. Japanese Order of the Rising Sun 1960. US Legion of Merit 1946. UN Citation 1949. French Union of Inventors Gold Medal 1954.

KF

See also: Zworykin, Vladimir Kosma

Tesla, Nikola

SUBJECT AREA: Electricity

[br]

b. 9 July 1856 Smiljan, Croatia

d. 7 January 1943 New York, USA

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Serbian (naturalized American) engineer and inventor of polyphase electrical power systems.

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While at the technical institute in Graz, Austria, Tesla's attention was drawn to the desirability of constructing a motor without a commutator. He considered the sparking between the commutator and brushes of the Gramme machine when run as a motor a serious defect. In 1881 he went to Budapest to work on the telegraph system and while there conceived the principle of the rotating magnetic field, upon which all polyphase induction motors are based. In 1882 Tesla moved to Paris and joined the Continental Edison Company. After building a prototype of his motor he emigrated to the United States in 1884, becoming an American citizen in 1889. He left Edison and founded an independent concern, the Tesla Electric Company, to develop his inventions.

The importance of Tesla's first patents, granted in 1888 for alternating-current machines, cannot be over-emphasized. They covered a complete polyphase system including an alternator and induction motor. Other patents included the polyphase transformer, synchronous motor and the star connection of three-phase machines. These were to become the basis of the whole of the modern electric power industry. The Westinghouse company purchased the patents and marketed Tesla motors, obtaining in 1893 the contract for the Niagara Falls two-phase alternators driven by 5,000 hp (3,700 kW) water turbines.

After a short period with Westinghouse, Tesla resigned to continue his research into high-frequency and high-voltage phenomena using the Tesla coil, an air-cored transformer. He lectured in America and Europe on his high-frequency devices, enjoying a considerable international reputation. The name "tesla" has been given to the SI unit of magnetic-flux density. The induction motor became one of the greatest advances in the industrial application of electricity. A claim for priority of invention of the induction motor was made by protagonists of Galileo Ferraris (1847–1897), whose discovery of rotating magnetic fields produced by alternating currents was made independently of Tesla's. Ferraris demonstrated the phenomenon but neglected its exploitation to produce a practical motor. Tesla himself failed to reap more than a small return on his work and later became more interested in scientific achievement than commercial success, with his patents being infringed on a wide scale.

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Principal Honours and Distinctions

American Institute of Electrical Engineers Edison Medal 1917. Tesla received doctorates from fourteen universities.

Bibliography

1 May 1888, American patent no. 381,968 (initial patent for the three-phase induction motor).

1956, Nikola Tesla, 1856–1943, Lectures, Patents, Articles, ed. L.I.Anderson, Belgrade (selected works, in English).

1977, My Inventions, repub. Zagreb (autobiography).

Further Reading

M.Cheney, 1981, Tesla: Man Out of Time, New Jersey (a full biography). C.Mackechnie Jarvis, 1969, in IEE Electronics and Power 15:436–40 (a brief treatment).

T.C.Martin, 1894, The Inventions, Researches and Writings of Nikola Tesla, New York (covers his early work on polyphase systems).

GW

White, Sir William Henry

SUBJECT AREA: Ports and shipping

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b. 2 February 1845 Devonport, England

d. 27 February 1913 London, England

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

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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.

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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

APC

APC, abbreviated performance characteristics

краткие эксплуатационные [рабочие] характеристики

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APC, advanced procurement change

изменения предварительных закупок

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APC, advanced procurement check

проверка предварительных закупок

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APC, aeronautical planning chart

карта аэронавигационного планирования

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APC, aimpoint correlator

прицельный коррелятор

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APC, Air Priority Committee

комитет по определению очередности воздушных перевозок

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APC, airframe production contract

контракт на производство планеров самолетов

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APC, all-purpose capsule

универсальная капсула

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APC, ammonium perchlorate

перхлорат амония (ВВ)

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APC, area of positive control

зона подтверждающего контроля

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APC, armor-piercing capped (projectile)

бронебойный снаряд с бронебойным наконечником

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APC, armored personnel carrier

бронетранспортер, БТР

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APC, Army Pay Corps

финансовая служба СВ

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APC, Army Petroleum Center

центр снабжения ГСМ СВ

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APC, Army Pictorial Center

центр кинематографической службы СВ

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APC, Army Policy Council

совет по вопросам строительства СВ

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APC, Army postal clerk

писарь почтовой службы СВ

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APC, aspirin, phenacetin, and caffeine

аспирин, фенацетин и кофеин (лекарственные препараты индивидуальной аптечки военнослужащего)

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APC, Бр Assistant Principal Chaplain

помощник старшего военного священника