mining ship

судно для добычи полезных ископаемых

mining vessel

судно для подводной добычи полезных ископаемых — undersea mining ship

судно для добычи полезных ископаемых в глубоководных районах

Naval: deep-ocean mining ship, deep-sea mining ship

судно для добычи полезных ископаемых в глубоководных районах

deep-ocean mining ship

район плавания судна — ship's working area

район рассредоточения кораблей — ship dispersal area

корабль охраны водного района базы — harbor defense ship

судно для подводной добычи полезных ископаемых

undersea mining ship

судно для добычи полезных ископаемых — mining vessel

добывающее судно

1) Naval: catching vessel

2) Engineering: catching vessel (для водного промысла)

3) Fishery: mining ship

4) Oilfield: production ship

добычное судно

Fishery: mining ship

судно для подводной добычи полезных ископаемых

Naval: undersea mining ship

судно для добычи полезных ископаемых в глубоководных районах

deep-ocean mining ship

судно для подводной добычи полезных ископаемых

undersea mining ship

крепежный лес

mining timber

подстропильный лес — roofing timber

прямоствольный лес — straight timber

корабельный, мачтовый лес — ship timber

граница распространения леса — timber line

заповедный лес, лесной заказ — timber reserve

танкер

1) General subject: cargo tank, filler, oil tanker, oil-carrier, oil-ship, oil-tanker, oiler, tank trailer, tanker

2) Naval: fueler, oil-carrying ship, petrol carrier, petroleum ship

3) Military: tanker ship

4) Engineering: AO, AOG, liquid cargo carrier, liquid carrier, tank ship

5) Economy: crude carrier (для перевозки сырой нефти), tank vessel

6) Mining: K (американское условное обозначение)

7) Oil: liquefied cargo carrier, oil ship

8) Ecology: liquid cargo vessel, oil-carrying vessel

9) Drilling: oil carrier

10) Sakhalin energy glossary: Tanker Of Opportunity

11) Oil&Gas technology carrier

12) oil&gas: export tanker

13) Logistics: petrol ship

14) Combustion gas turbines: tanker (судно)

World War II

(1939-1945)

   In the European phase of the war, neutral Portugal contributed more to the Allied victory than historians have acknowledged. Portugal experienced severe pressures to compromise her neutrality from both the Axis and Allied powers and, on several occasions, there were efforts to force Portugal to enter the war as a belligerent. Several factors lent Portugal importance as a neutral. This was especially the case during the period from the fall of France in June 1940 to the Allied invasion and reconquest of France from June to August 1944.

   In four respects, Portugal became briefly a modest strategic asset for the Allies and a war materiel supplier for both sides: the country's location in the southwesternmost corner of the largely German-occupied European continent; being a transport and communication terminus, observation post for spies, and crossroads between Europe, the Atlantic, the Americas, and Africa; Portugal's strategically located Atlantic islands, the Azores, Madeira, and Cape Verde archipelagos; and having important mines of wolfram or tungsten ore, crucial for the war industry for hardening steel.

   To maintain strict neutrality, the Estado Novo regime dominated by Antônio de Oliveira Salazar performed a delicate balancing act. Lisbon attempted to please and cater to the interests of both sets of belligerents, but only to the extent that the concessions granted would not threaten Portugal's security or its status as a neutral. On at least two occasions, Portugal's neutrality status was threatened. First, Germany briefly considered invading Portugal and Spain during 1940-41. A second occasion came in 1943 and 1944 as Great Britain, backed by the United States, pressured Portugal to grant war-related concessions that threatened Portugal's status of strict neutrality and would possibly bring Portugal into the war on the Allied side. Nazi Germany's plan ("Operation Felix") to invade the Iberian Peninsula from late 1940 into 1941 was never executed, but the Allies occupied and used several air and naval bases in Portugal's Azores Islands.

   The second major crisis for Portugal's neutrality came with increasing Allied pressures for concessions from the summer of 1943 to the summer of 1944. Led by Britain, Portugal's oldest ally, Portugal was pressured to grant access to air and naval bases in the Azores Islands. Such bases were necessary to assist the Allies in winning the Battle of the Atlantic, the naval war in which German U-boats continued to destroy Allied shipping. In October 1943, following tedious negotiations, British forces began to operate such bases and, in November 1944, American forces were allowed to enter the islands. Germany protested and made threats, but there was no German attack.

   Tensions rose again in the spring of 1944, when the Allies demanded that Lisbon cease exporting wolfram to Germany. Salazar grew agitated, considered resigning, and argued that Portugal had made a solemn promise to Germany that wolfram exports would be continued and that Portugal could not break its pledge. The Portuguese ambassador in London concluded that the shipping of wolfram to Germany was "the price of neutrality." Fearing that a still-dangerous Germany could still attack Portugal, Salazar ordered the banning of the mining, sale, and exports of wolfram not only to Germany but to the Allies as of 6 June 1944.

   Portugal did not enter the war as a belligerent, and its forces did not engage in combat, but some Portuguese experienced directly or indirectly the impact of fighting. Off Portugal or near her Atlantic islands, Portuguese naval personnel or commercial fishermen rescued at sea hundreds of victims of U-boat sinkings of Allied shipping in the Atlantic. German U-boats sank four or five Portuguese merchant vessels as well and, in 1944, a U-boat stopped, boarded, searched, and forced the evacuation of a Portuguese ocean liner, the Serpa Pinto, in mid-Atlantic. Filled with refugees, the liner was not sunk but several passengers lost their lives and the U-boat kidnapped two of the ship's passengers, Portuguese Americans of military age, and interned them in a prison camp. As for involvement in a theater of war, hundreds of inhabitants were killed and wounded in remote East Timor, a Portuguese colony near Indonesia, which was invaded, annexed, and ruled by Japanese forces between February 1942 and August 1945. In other incidents, scores of Allied military planes, out of fuel or damaged in air combat, crashed or were forced to land in neutral Portugal. Air personnel who did not survive such crashes were buried in Portuguese cemeteries or in the English Cemetery, Lisbon.

   Portugal's peripheral involvement in largely nonbelligerent aspects of the war accelerated social, economic, and political change in Portugal's urban society. It strengthened political opposition to the dictatorship among intellectual and working classes, and it obliged the regime to bolster political repression. The general economic and financial status of Portugal, too, underwent improvements since creditor Britain, in order to purchase wolfram, foods, and other materials needed during the war, became indebted to Portugal. When Britain repaid this debt after the war, Portugal was able to restore and expand its merchant fleet. Unlike most of Europe, ravaged by the worst war in human history, Portugal did not suffer heavy losses of human life, infrastructure, and property. Unlike even her neighbor Spain, badly shaken by its terrible Civil War (1936-39), Portugal's immediate postwar condition was more favorable, especially in urban areas, although deep-seated poverty remained.

   Portugal experienced other effects, especially during 1939-42, as there was an influx of about a million war refugees, an infestation of foreign spies and other secret agents from 60 secret intelligence services, and the residence of scores of international journalists who came to report the war from Lisbon. There was also the growth of war-related mining (especially wolfram and tin). Portugal's media eagerly reported the war and, by and large, despite government censorship, the Portuguese print media favored the Allied cause. Portugal's standard of living underwent some improvement, although price increases were unpopular.

   The silent invasion of several thousand foreign spies, in addition to the hiring of many Portuguese as informants and spies, had fascinating outcomes. "Spyland" Portugal, especially when Portugal was a key point for communicating with occupied Europe (1940-44), witnessed some unusual events, and spying for foreigners at least briefly became a national industry. Until mid-1944, when Allied forces invaded France, Portugal was the only secure entry point from across the Atlantic to Europe or to the British Isles, as well as the escape hatch for refugees, spies, defectors, and others fleeing occupied Europe or Vichy-controlled Morocco, Tunisia, and Algeria. Through Portugal by car, ship, train, or scheduled civil airliner one could travel to and from Spain or to Britain, or one could leave through Portugal, the westernmost continental country of Europe, to seek refuge across the Atlantic in the Americas.

   The wartime Portuguese scene was a colorful melange of illegal activities, including espionage, the black market, war propaganda, gambling, speculation, currency counterfeiting, diamond and wolfram smuggling, prostitution, and the drug and arms trade, and they were conducted by an unusual cast of characters. These included refugees, some of whom were spies, smugglers, diplomats, and business people, many from foreign countries seeking things they could find only in Portugal: information, affordable food, shelter, and security. German agents who contacted Allied sailors in the port of Lisbon sought to corrupt and neutralize these men and, if possible, recruit them as spies, and British intelligence countered this effort. Britain's MI-6 established a new kind of "safe house" to protect such Allied crews from German espionage and venereal disease infection, an approved and controlled house of prostitution in Lisbon's bairro alto district.

   Foreign observers and writers were impressed with the exotic, spy-ridden scene in Lisbon, as well as in Estoril on the Sun Coast (Costa do Sol), west of Lisbon harbor. What they observed appeared in noted autobiographical works and novels, some written during and some after the war. Among notable writers and journalists who visited or resided in wartime Portugal were Hungarian writer and former communist Arthur Koestler, on the run from the Nazi's Gestapo; American radio broadcaster-journalist Eric Sevareid; novelist and Hollywood script-writer Frederick Prokosch; American diplomat George Kennan; Rumanian cultural attache and later scholar of mythology Mircea Eliade; and British naval intelligence officer and novelist-to-be Ian Fleming. Other notable visiting British intelligence officers included novelist Graham Greene; secret Soviet agent in MI-6 and future defector to the Soviet Union Harold "Kim" Philby; and writer Malcolm Muggeridge. French letters were represented by French writer and airman, Antoine Saint-Exupery and French playwright, Jean Giroudoux. Finally, Aquilino Ribeiro, one of Portugal's premier contemporary novelists, wrote about wartime Portugal, including one sensational novel, Volframio, which portrayed the profound impact of the exploitation of the mineral wolfram on Portugal's poor, still backward society.

   In Estoril, Portugal, the idea for the world's most celebrated fictitious spy, James Bond, was probably first conceived by Ian Fleming. Fleming visited Portugal several times after 1939 on Naval Intelligence missions, and later he dreamed up the James Bond character and stories. Background for the early novels in the James Bond series was based in part on people and places Fleming observed in Portugal. A key location in Fleming's first James Bond novel, Casino Royale (1953) is the gambling Casino of Estoril. In addition, one aspect of the main plot, the notion that a spy could invent "secret" intelligence for personal profit, was observed as well by the British novelist and former MI-6 officer, while engaged in operations in wartime Portugal. Greene later used this information in his 1958 spy novel, Our Man in Havana, as he observed enemy agents who fabricated "secrets" for money.

   Thus, Portugal's World War II experiences introduced the country and her people to a host of new peoples, ideas, products, and influences that altered attitudes and quickened the pace of change in this quiet, largely tradition-bound, isolated country. The 1943-45 connections established during the Allied use of air and naval bases in Portugal's Azores Islands were a prelude to Portugal's postwar membership in the North Atlantic Treaty Organization (NATO).

Kohlenabbau

Kohlenabbau
coal mining;
• Kohlenabbaugerechtigkeit royalty;
• Kohlenabgabe coal levy;
• nicht mit größeren Kohlenanforderungen von den Versorgungsbetrieben rechnen not to expect coal demand from the utilities;
• Kohlenausfuhr coal export;
• Kohlenbergarbeiterstreik coal strike;
• Kohlenbergbau coal[-mining] industry;
• Kohlenbergwerk coal mine, pit, colliery;
• Kohlenbewirtschaftung coal control;
• Kohlenbunker coal bunker;
• Kohlendeputat allowance of free coal;
• Kohlendioxid auf dem Stand von 2002 halten to freeze emissions of carbon dioxide at 2002 level;
• Kohlendistrikt coal field;
• Kohlenfeld ausbeuten to work a coal field;
• Kohlenförderung coal output;
• tägliche Kohlenförderung pro Kopf coal output per man per day;
• Kohlenförderung steigern to increase the output of coal;
• Kohlengebiet coal-mining district, coal area;
• Kohlengrube coalpit;
• Kohlengrube ausbeuten to mine coal;
• Kohlenhafen coaling port (station);
• Kohlenhalde coal bank (stockpile), pithead stocks;
• Kohlenhändler dealer in coal, coal merchant (factor, Br.);
• Kohlenindustrie coal industry;
• Kohlenknappheit coal shortage;
• Kohlenladung load of coal;
• Kohlenlager coal field (depot, yard, bank, US);
• Kohlenlieferant coal contractor (supplier);
• Kohlenlieferungen coal supply;
• Kohlenlieferungsvertrag abschließen to make a contract for supply of coal;
• Kohlenmangel coal famine;
• Kohlennebenprodukte gewinnen to recover byproducts from coal;
• abbauwürdige Kohlenreserven workable reserves of coal;
• Kohlenrevier coal area (field), coal-mining district;
• Kohlenschätze eines Gebiets erschließen to develop a coal area;
• Kohlenschiff coal ship, collier;
• Kohlensorte grade of coal;
• Kohlenstofffaser carbon fibre (Br.) (fiber, US);
• Kohlentransport coal transport;
• Kohlenüberhang coal glut;
• Kohlenübernahme coaling;
• Kohlenverbrauch coal consumption;
• Kohlenverkaufsbüro coal sales office;
• Kohlenversorgung coal supplies;
• Kohlenvorkommen coal deposit[s];
• Kohlenvorrat ergänzen to recoal;
• Kohlenwaggon coal wag(g)on (truck, car, US);
• Kohlenwirtschaftsjahr coal production year;
• Kohlenzeche coal mine, colliery;
• Kohlenzug coal train, coaler, black snake (sl.).

Sperry, Elmer Ambrose

SUBJECT AREA: Aerospace, Electricity, Land transport, Ports and shipping

[br]

b. 21 October 1860 Cincinnatus, Cortland County, New York, USA

d. 16 June 1930 Brooklyn, New York, USA

[br]

American entrepreneur who invented the gyrocompass.

[br]

Sperry was born into a farming community in Cortland County. He received a rudimentary education at the local school, but an interest in mechanical devices was aroused by the agricultural machinery he saw around him. His attendance at the Normal School in Cortland provided a useful theoretical background to his practical knowledge. He emerged in 1880 with an urge to pursue invention in electrical engineering, then a new and growing branch of technology. Within two years he was able to patent and demonstrate his arc lighting system, complete with its own generator, incorporating new methods of regulating its output. The Sperry Electric Light, Motor and Car Brake Company was set up to make and market the system, but it was difficult to keep pace with electric-lighting developments such as the incandescent lamp and alternating current, and the company ceased in 1887 and was replaced by the Sperry Electric Company, which itself was taken over by the General Electric Company.

In the 1890s Sperry made useful inventions in electric mining machinery and then in electric street-or tramcars, with his patent electric brake and control system. The patents for the brake were important enough to be bought by General Electric. From 1894 to 1900 he was manufacturing electric motor cars of his own design, and in 1900 he set up a laboratory in Washington, where he pursued various electrochemical processes.

In 1896 he began to work on the practical application of the principle of the gyroscope, where Sperry achieved his most notable inventions, the first of which was the gyrostabilizer for ships. The relatively narrow-hulled steamship rolled badly in heavy seas and in 1904 Ernst Otto Schuck, a German naval engineer, and Louis Brennan in England began experiments to correct this; their work stimulated Sperry to develop his own device. In 1908 he patented the active gyrostabilizer, which acted to correct a ship's roll as soon as it started. Three years later the US Navy agreed to try it on a destroyer, the USS Worden. The successful trials of the following year led to widespread adoption. Meanwhile, in 1910, Sperry set up the Sperry Gyroscope Company to extend the application to commercial shipping.

At the same time, Sperry was working to apply the gyroscope principle to the ship's compass. The magnetic compass had worked well in wooden ships, but iron hulls and electrical machinery confused it. The great powers' race to build up their navies instigated an urgent search for a solution. In Germany, Anschütz-Kämpfe (1872–1931) in 1903 tested a form of gyrocompass and was encouraged by the authorities to demonstrate the device on the German flagship, the Deutschland. Its success led Sperry to develop his own version: fortunately for him, the US Navy preferred a home-grown product to a German one and gave Sperry all the backing he needed. A successful trial on a destroyer led to widespread acceptance in the US Navy, and Sperry was soon receiving orders from the British Admiralty and the Russian Navy.

In the rapidly developing field of aeronautics, automatic stabilization was becoming an urgent need. In 1912 Sperry began work on a gyrostabilizer for aircraft. Two years later he was able to stage a spectacular demonstration of such a device at an air show near Paris.

Sperry continued research, development and promotion in military and aviation technology almost to the last. In 1926 he sold the Sperry Gyroscope Company to enable him to devote more time to invention.

[br]

Principal Honours and Distinctions

John Fritz Medal 1927. President, American Society of Mechanical Engineers 1928.

Bibliography

Sperry filed over 400 patents, of which two can be singled out: 1908. US patent no. 434,048 (ship gyroscope); 1909. US patent no. 519,533 (ship gyrocompass set).

Further Reading

T.P.Hughes, 1971, Elmer Sperry, Inventor and Engineer, Baltimore: Johns Hopkins University Press (a full and well-documented biography, with lists of his patents and published writings).

LRD

Nobel, Immanuel

SUBJECT AREA: Chemical technology, Mining and extraction technology, Weapons and armour

[br]

b. 1801 Gävle, Sweden

d. 3 September 1872 Stockholm, Sweden

[br]

Swedish inventor and industrialist, particularly noted for his work on mines and explosives.

[br]

The son of a barber-surgeon who deserted his family to serve in the Swedish army, Nobel showed little interest in academic pursuits as a child and was sent to sea at the age of 16, but jumped ship in Egypt and was eventually employed as an architect by the pasha. Returning to Sweden, he won a scholarship to the Stockholm School of Architecture, where he studied from 1821 to 1825 and was awarded a number of prizes. His interest then leaned towards mechanical matters and he transferred to the Stockholm School of Engineering. Designs for linen-finishing machines won him a prize there, and he also patented a means of transforming rotary into reciprocating movement. He then entered the real-estate business and was successful until a fire in 1833 destroyed his house and everything he owned. By this time he had married and had two sons, with a third, Alfred (of Nobel Prize fame; see Alfred Nobel), on the way. Moving to more modest quarters on the outskirts of Stockholm, Immanuel resumed his inventions, concentrating largely on India rubber, which he applied to surgical instruments and military equipment, including a rubber knapsack.

It was talk of plans to construct a canal at Suez that first excited his interest in explosives. He saw them as a means of making mining more efficient and began to experiment in his backyard. However, this made him unpopular with his neighbours, and the city authorities ordered him to cease his investigations. By this time he was deeply in debt and in 1837 moved to Finland, leaving his family in Stockholm. He hoped to interest the Russians in land and sea mines and, after some four years, succeeded in obtaining financial backing from the Ministry of War, enabling him to set up a foundry and arms factory in St Petersburg and to bring his family over. By 1850 he was clear of debt in Sweden and had begun to acquire a high reputation as an inventor and industrialist. His invention of the horned contact mine was to be the basic pattern of the sea mine for almost the next 100 years, but he also created and manufactured a central-heating system based on hot-water pipes. His three sons, Ludwig, Robert and Alfred, had now joined him in his business, but even so the outbreak of war with Britain and France in the Crimea placed severe pressures on him. The Russians looked to him to convert their navy from sail to steam, even though he had no experience in naval propulsion, but the aftermath of the Crimean War brought financial ruin once more to Immanuel. Amongst the reforms brought in by Tsar Alexander II was a reliance on imports to equip the armed forces, so all domestic arms contracts were abruptly cancelled, including those being undertaken by Nobel. Unable to raise money from the banks, Immanuel was forced to declare himself bankrupt and leave Russia for his native Sweden. Nobel then reverted to his study of explosives, particularly of how to adapt the then highly unstable nitroglycerine, which had first been developed by Ascanio Sobrero in 1847, for blasting and mining. Nobel believed that this could be done by mixing it with gunpowder, but could not establish the right proportions. His son Alfred pursued the matter semi-independently and eventually evolved the principle of the primary charge (and through it created the blasting cap), having taken out a patent for a nitroglycerine product in his own name; the eventual result of this was called dynamite. Father and son eventually fell out over Alfred's independent line, but worse was to follow. In September 1864 Immanuel's youngest son, Oscar, then studying chemistry at Uppsala University, was killed in an explosion in Alfred's laboratory: Immanuel suffered a stroke, but this only temporarily incapacitated him, and he continued to put forward new ideas. These included making timber a more flexible material through gluing crossed veneers under pressure and bending waste timber under steam, a concept which eventually came to fruition in the form of plywood.

In 1868 Immanuel and Alfred were jointly awarded the prestigious Letterstedt Prize for their work on explosives, but Alfred never for-gave his father for retaining the medal without offering it to him.

[br]

Principal Honours and Distinctions

Imperial Gold Medal (Russia) 1853. Swedish Academy of Science Letterstedt Prize (jointly with son Alfred) 1868.

Bibliography

Immanuel Nobel produced a short handwritten account of his early life 1813–37, which is now in the possession of one of his descendants. He also had published three short books during the last decade of his life— Cheap Defence of the Country's Roads (on land mines), Cheap Defence of the Archipelagos (on sea mines), and Proposal for the Country's Defence (1871)—as well as his pamphlet (1870) on making wood a more physically flexible product.

Further Reading

No biographies of Immanuel Nobel exist, but his life is detailed in a number of books on his son Alfred.

CM

mine

اِسْتَخْرَجَ من منجم \ mine: to dig (a mineral) from a mine: They were mining for gold, but they found silver. They mined the silver. \ خَاصَّتي \ mine: belonging to me: He’s a friend of mine. Is that pen yours or mine?. \ عَدَّنَ \ mine: to dig a mine; dig (a mineral) from a mine: They were mining for gold, but they found silver. They mined the silver. \ لَغَم \ mine: explosive material that is placed in the sea or under the ground, so as to destroy an enemy or anything (a bridge, etc.) that would be useful to him. \ لَغَمَ \ mine: to place a mine in or under (sth.); damage (sth.) with a mine: They mined the sea around the port. The ship was mined and quickly sank. \ See Also نسف (نَسَفَ)‏ \ لِي \ mine: belonging to me: He’s a friend of mine. Is that pen yours or mine?. \ مِلْكِي \ mine: belonging to me: Is that pen yours or mine?. \ نَقَّبَ عن المعادن \ mine: to dig a mine; dig (a mineral) from a mine: They were mining for gold, but they found silver.

система

complex, chain, installation, method, repertoire вчт., repertory, structure, system

* * *

систе́ма ж.
system

дубли́ровать систе́му — duplicate a system

отла́живать систе́му — tune up a system

систе́ма функциони́рует норма́льно киб. — the system is well-behaved

авари́йная систе́ма ав. — emergency system

систе́ма авари́йного покида́ния ( самолёта) — escape system

автомати́ческая систе́ма — automatic system

систе́ма автомати́ческого регули́рования [САР] — automatic-control system of the regulator(y) type

систе́ма автомати́ческого регули́рования, де́йствующая по отклоне́нию — error-actuated control system

систе́ма автомати́ческого регули́рования, за́мкнутая — closed-loop control system

систе́ма автомати́ческого регули́рования, и́мпульсная — sampling control system

систе́ма автомати́ческого регули́рования, многоё́мкостная — multicapacity control system

систе́ма автомати́ческого регули́рования, многоко́нтурная — multiloop control system

систе́ма автомати́ческого регули́рования, многоме́рная — multivariable control system

систе́ма автомати́ческого регули́рования, програ́ммная — time-pattern control system

систе́ма автомати́ческого регули́рования, разо́мкнутая — open-loop control system

систе́ма автомати́ческого регули́рования следя́щего ти́па — servo-operation control system

систе́ма автомати́ческого регули́рования со случа́йными возде́йствиями, и́мпульсная — random-input sampled-data system

систе́ма автомати́ческого регули́рования со стабилиза́цией (проце́сса) — regulator-operation control system

систе́ма автомати́ческого управле́ния [САУ] — automatic-control system

систе́ма автомати́ческого управле́ния, цифрова́я — digital control system

систе́ма автоподстро́йки частоты́ [АПЧ] — AFC system

систе́ма АПЧ захва́тывает частоту́ — the AFC system locks on to the (desired) frequency

систе́ма АПЧ осуществля́ет по́иск частоты́ — the AFC system searches for the (desired) frequency

систе́ма автоподстро́йки частоты́, фа́зовая [ФАПЧ] — phase-lock loop, PLL

агрега́тная, унифици́рованная систе́ма ( советская система пневматических средств автоматики) — standard-module pneumatic instrumentation system

адапти́вная систе́ма — adaptive system

апериоди́ческая систе́ма — critically damped system

асинхро́нная систе́ма — asynchronous system

астати́ческая систе́ма — zero-constant-error system

астати́ческая систе́ма второ́го поря́дка — Type 2 [zero-velocity-error] system

астати́ческая систе́ма пе́рвого поря́дка — Type 1 [zero-position-error] system

систе́ма без резерви́рования — non-redundant system

систе́ма блокиро́вки ( радиационной установки) — interlock system

систе́ма ва́ла ( в допусках и посадках) — the basic shaft system

вентиляцио́нная систе́ма — ventilation system

вентиляцио́нная, вытяжна́я систе́ма — exhaust ventilation system

взаи́мные систе́мы — mutual systems

систе́ма водоснабже́ния — water(-supply) system

систе́ма водоснабже́ния, оборо́тная — circulating [closed-circuit] water system

систе́ма водоснабже́ния, прямото́чная — once-through [run-of-river cooling] system

систе́ма возду́шного отопле́ния — warm-air heating system

систе́ма воспроизведе́ния ( записи) — reproduction system

систе́ма впры́ска двс. — injection system

систе́ма впры́ска, предка́мерная двс. — antechamber system of injection

систе́ма впу́ска двс. — induction [intake] system

систе́ма вы́борки вчт. — selection system

вытяжна́я систе́ма — exhaust system

вычисли́тельная систе́ма — computer [computing] system

вычисли́тельная, многома́шинная систе́ма — multicomputer system

систе́ма генера́тор — дви́гатель — Ward-Leonard speed-control system

гибри́дная систе́ма — hybrid system

систе́ма громкоговоря́щей свя́зи — public-address [personnel-address, PA] system

грузова́я систе́ма мор. — cargo (handling) system

двухкомпоне́нтная систе́ма хим. — two-component [binary] system

двухни́точная систе́ма тепл. — two-flow system

двухпроводна́я систе́ма эл. — two-wire system

двухэлектро́дная систе́ма ( электроннооптического преобразователя) — self-focusing (diod) system

диспе́рсная систе́ма — disperse system

диссипати́вная систе́ма — dissipative system

систе́ма дистанцио́нного управле́ния — remote control system

диффере́нтная систе́ма мор. — trim system

дифференциа́льная систе́ма тлф. — hybrid set

систе́ма дождева́ния — sprinkling system

систе́ма до́пусков — tolerance system

систе́ма до́пусков, двусторо́нняя [симметри́чная], преде́льная — bilateral system of tolerances

систе́ма до́пусков и поса́док — system [classification] of fits and tolerances

систе́ма до́пусков, односторо́нняя [асимметри́чная], преде́льная — unilateral system of tolerances

систе́ма дрена́жа ( топливных баков) ав. — vent system

систе́ма едини́ц — system of units

систе́ма едини́ц, междунаро́дная [СИ] — international system of units, SI

систе́ма едини́ц МКГСС уст. — MKGSS [metre-kilogram(me)-force-second ] system (of units)

систе́ма едини́ц МКС — MKS [metre-kilogram(me)-second ] system (of units)

систе́ма едини́ц МКСА — MKSA [metre-kilogram(me)-mass-second-ampere ] system (of units), absolute practical system of units

систе́ма едини́ц МКСГ — MKSG [metre-kilogram(me)-force-second-kelvin ] system (of units)

систе́ма едини́ц МСС — MSC [metre-second-candela] system (of units)

систе́ма едини́ц МТС — MTS [metre-ton-second] system (of units)

систе́мы едини́ц СГС — CGS [centimetre-gram(me)-second ] systems (of units)

систе́ма едини́ц, техни́ческая — engineer's system of units

же́зловая систе́ма ж.-д. — staff system

систе́ма жизнеобеспе́чения косм. — life-support (and survival) system

систе́ма жизнеобеспе́чения, автоно́мная — back-pack life-support system

систе́ма зажига́ния — ignition system

систе́ма зажига́ния, полупроводнико́вая — transistor(ized) ignition system

систе́ма зажига́ния, электро́нная — electronic ignition system

систе́ма заземле́ния — earth [ground] network

замедля́ющая систе́ма — ( в электровакуумных устройствах СВЧ) slow-wave structure; ( волноводная) slow-wave guide; ( коаксиальная) wave delay line

замедля́ющая, встре́чно-стержнева́я систе́ма — interdigital [interdigitated] slow-wave structure

замедля́ющая, гребе́нчатая систе́ма — vane-line slow-wave structure, finned slow-wave guide

замедля́ющая, спира́льная систе́ма — helical slow-wave structure

за́мкнутая систе́ма — closed system

систе́ма за́писи вчт. — writing system

запомина́ющая систе́ма вчт. — storage system

систе́ма затопле́ния мор. — flood(ing) system

систе́ма захо́да на поса́дку по кома́ндам с земли́ ав. — ground-controlled-approach [GCA] system

зачи́стная систе́ма ( танкера) — stripping system

систе́ма зерка́л Фабри́—Перо́ — Fabry-Perot [FP] mirror system

зерка́льно-ли́нзовая систе́ма ( в микроскопе) — catadioptric system

систе́ма золоудале́ния — ash-handling system

систе́ма зо́льников кож. — lime yard, lime round

изоли́рованная систе́ма — isolated system

систе́ма индивидуа́льного вы́зова свз. — paging system

инерциа́льная систе́ма — inertial system

информацио́нная систе́ма — information system

информацио́нно-поиско́вая систе́ма — information retrieval system

исхо́дная систе́ма — prototype [original] system

канализацио́нная систе́ма — sewer(age) system

канализацио́нная, общесплавна́я систе́ма — combined sewer(age) system

канализацио́нная, разде́льная систе́ма — separate sewer(age) system

систе́ма коди́рования — coding system

колеба́тельная систе́ма — (преим. механическая) vibratory [vibrating] system; ( немеханическая) oscillatory [resonant] system

колеба́тельная, многорезона́торная систе́ма ( магнетрона) — multiple-cavity resonator

колориметри́ческая трёхцве́тная систе́ма — three-colour photometric system

систе́ма кома́нд ЭВМ — instruction set of a computer, computer instruction set

систе́ма координа́т — coordinate system

свя́зывать систе́му координа́т с … — tie in a coordinate system with …, tie coordinate system to …

систе́ма координа́т, инерциа́льная — inertial frame

систе́ма координа́т, лаборато́рная — laboratory coordinate system, laboratory frame of reference

систе́ма координа́т, ле́вая — left-handed coordinate system

систе́ма координа́т, ме́стная — local (coordinate) system

систе́ма координа́т, поко́ящаяся — rest (coordinate) system

систе́ма координа́т, пото́чная аргд. — (relative) wind coordinate system

систе́ма координа́т, пра́вая — right-handed coordinate system

систе́ма координа́т, свя́занная с дви́жущимся те́лом — body axes (coordinate) system

систе́ма координа́т, свя́занная с Землё́й — fixed-in-the-earth (coordinate) system

систе́ма корре́кции гироско́па — gyro monitor, (long-term) reference

систе́ма корре́кции гироско́па, магни́тная — magnetic gyro monitor, magnetic reference

систе́ма корре́кции гироско́па, ма́ятниковая — gravity gyro monitor, gravity reference

систе́ма криволине́йных координа́т — curvilinear coordinate system

курсова́я систе́ма ав. — directional heading [waiting] system

ли́тниковая систе́ма — gating [pouring gate] system

магни́тная систе́ма — magnetic system

систе́ма ма́ссового обслу́живания — queueing [waiting] system

систе́ма ма́ссового обслу́живания, сме́шанная — combined loss-delay queueing [waiting] system

систе́ма ма́ссового обслу́живания с ожида́нием — delay queueing [waiting] system

систе́ма ма́ссового обслу́живания с отка́зами — congestion queueing [waiting] system

систе́ма ма́ссового обслу́живания с поте́рями — loss-type queueing [waiting] system

мени́сковая систе́ма — meniscus [Maksutov] system

систе́ма мер, метри́ческая — metric system

систе́ма мер, типогра́фская — point system

механи́ческая систе́ма — mechanical system

механи́ческая, несвобо́дная систе́ма — constrained material system

систе́ма мно́гих тел — many-body system

многокана́льная систе́ма свз. — multichannel system

многокомпоне́нтная систе́ма — multicomponent system

многоме́рная систе́ма — multivariable system

модели́руемая систе́ма — prototype system

мо́дульная систе́ма — modular system

мультипле́ксная систе́ма — multiplex system

систе́ма набо́ра ( корпуса судна) — framing system

систе́ма набо́ра, кле́тчатая — cellular framing system

систе́ма набо́ра, попере́чная — transverse framing system

систе́ма набо́ра, продо́льная — longitudinal framing system

систе́ма набо́ра, сме́шанная — mixed framing system

систе́ма навига́ции — navigation system

систе́ма навига́ции, автоно́мная — self-contained navigation system

систе́ма навига́ции, гиперболи́ческая — hyperbolic navigation system

систе́ма навига́ции, дальноме́рная — rho-rho [ - ] navigation system

систе́ма навига́ции, дальноме́рно-угломе́рная — rho-theta [ - ] navigation system

систе́ма навига́ции, кругова́я — rho-rho [ - ] navigation system

систе́ма навига́ции, ра́зностно-дальноме́рная [РДНС] — hyperbolic navigation system

систе́ма навига́ции, угломе́рная — theta-theta [ - ] navigation system

систе́ма на стру́йных элеме́нтах, логи́ческая — fluid logic system

систе́ма нумера́ции тлф. — numbering scheme

систе́ма обду́ва стё́кол авто, автмт. — demister

систе́ма обнаруже́ния оши́бок ( в передаче данных) свз. — error detection system

систе́ма обогре́ва стё́кол авто, ав. — defroster

систе́ма обозначе́ний — notation, symbolism

систе́ма обозначе́ний Междунаро́дного нау́чного радиообъедине́ния — URSI symbol system

систе́ма обозначе́ния про́бы, кара́тная — carat test sign system

систе́ма обозначе́ния про́бы, метри́ческая — metric test sign system

обора́чивающая систе́ма опт. — erecting [inversion (optical)] system

обора́чивающая, при́зменная систе́ма опт. — prism-erecting (optical) system

систе́ма обрабо́тки да́нных — data processing [dp] system

систе́ма обрабо́тки да́нных в реа́льном масшта́бе вре́мени — real time data processing system

систе́ма обрабо́тки да́нных, операти́вная — on-line data processing system

систе́ма обрабо́тки отхо́дов — waste treatment system

систе́ма объё́много пожаротуше́ния мор. — fire-smothering system

одноотка́зная систе́ма — fall-safe system

опти́ческая систе́ма — optical system, optical train

опти́ческая, зерка́льно-ли́нзовая систе́ма — catadioptric system

систе́ма ориента́ции ав. — attitude control system

ороси́тельная систе́ма — irrigation system, irrigation project

систе́ма ороше́ния мор. — sprinkling system

систе́ма освеще́ния — lighting (system)

осуши́тельная систе́ма мор. — drain(age) system

систе́ма отбо́ра во́здуха от компре́ссора — compressor air-bleed system

систе́ма отве́рстия ( в допусках и посадках) — the basic hole system

отклоня́ющая систе́ма ( в ЭЛТ) — deflecting system, deflection yoke

отклоня́ющая, ка́дровая систе́ма — vertical (deflection) yoke

отклоня́ющая, магни́тная систе́ма — magnetic (deflection) yoke

отклоня́ющая, стро́чная систе́ма — horizontal [line] (deflection) yoke

систе́ма относи́тельных едини́ц — per-unit system

отопи́тельная систе́ма — heating system

отопи́тельная систе́ма с разво́дкой све́рху — down-feed heating system

отопи́тельная систе́ма с разво́дкой сни́зу — up-feed heating system

систе́ма отсчё́та — frame of reference, (reference) frame, reference system

систе́ма отсчё́та, инерциа́льная — inertial frame of reference

систе́ма охлажде́ния — cooling system

систе́ма охлажде́ния, возду́шная — air-cooling system

систе́ма охлажде́ния, жи́дкостная — liquid-cooling system

систе́ма охлажде́ния, испари́тельная — evaporative cooling system

систе́ма охлажде́ния, каска́дная — cascade refrigeration system

систе́ма охлажде́ния непосре́дственным испаре́нием холоди́льного аге́нта — direct expansion system

систе́ма охлажде́ния, пане́льная — panel cooling system

систе́ма охлажде́ния, рассо́льная, двухтемперату́рная — dual-temperature brine refrigeration system

систе́ма охлажде́ния, рассо́льная, закры́тая — closed brine cooling system

систе́ма охлажде́ния, рассо́льная, с испаре́нием — brine spray cooling system

систе́ма охлажде́ния с теплозащи́тной руба́шкой — jacketed cooling system

систе́ма очи́стки воды́ — water purification system

систе́ма па́мяти — memory [storage] system

систе́ма парашю́та, подвесна́я — parachute harness

систе́ма переда́чи да́нных — data transmission system

систе́ма переда́чи да́нных с обра́тной свя́зью — information feedback data transmission system

систе́ма переда́чи да́нных с коммута́цией сообще́ний и промежу́точным хране́нием — store-and-forward data network

систе́ма переда́чи да́нных с реша́ющей обра́тной свя́зью — decision feedback data transmission system

систе́ма переда́чи и́мпульсов набо́ра, шле́йфная тлф. — loop dialling system

систе́ма переда́чи на одно́й боково́й полосе́ и пода́вленной несу́щей — single-sideband suppressed-carrier [SSB-SC] system

систе́ма переда́чи на одно́й боково́й полосе́ с осла́бленной несу́щей — single-sideband reduced carrier [SSB-RC] system

систе́ма пита́ния двс. — fuel system

систе́ма пита́ния котла́ — boiler-feed piping system

систе́ма питьево́й воды́ мор. — drinking-water [portable-water] system

систе́ма пода́чи то́плива, вытесни́тельная — pressure feeding system

систе́ма пода́чи то́плива самотё́ком — gravity feeding system

систе́ма пода́чи то́плива, турбонасо́сная — turbopump feeding system

подви́жная систе́ма ( измерительного прибора) — moving element (movement не рекомендован соответствующими стандартами)

систе́ма пожа́рной сигнализа́ции — fire-alarm system

систе́ма пожаротуше́нения — fire-extinguishing system

систе́ма поса́дки — landing system

систе́ма поса́дки по прибо́рам — instrument landing system (сокращение ILS относится к международной системе, советская система обозначается СП — instrument landing system)

систе́ма проду́вки авто — scavenging system

противообледени́тельная систе́ма ав. — ( для предотвращения образования льда) anti-icing [ice protection] system; ( для удаления образовавшегося льда) de-icing system

противопожа́рная систе́ма — fire-extinguishing system

противото́чная систе́ма — counter-current flow system

систе́ма прямо́го перено́са ( электроннооптического преобразователя) — proximity focused system

прямото́чная систе́ма — direct-flow system

систе́ма прямоуго́льных координа́т — Cartesian [rectangular] coordinate system

систе́ма, рабо́тающая в и́стинном масшта́бе вре́мени — real-time system

радиолокацио́нная, втори́чная систе́ма УВД — ( для работы внутри СССР) SSR system; ( отвечающая нормам ИКАО) ICAO SSR system

радиолокацио́нная систе́ма с электро́нным скани́рованием — electronic scanning radar system, ESRS

радиомая́чная систе́ма — radio range

радиомая́чная, многокана́льная систе́ма — multitrack radio range

систе́ма радионавига́ции — radio-navigation system (см. тж. система навигации)

развё́ртывающая систе́ма тлв. — scanning system

систе́ма разрабо́тки — mining system, method of mining

распредели́тельная систе́ма — distribution system

регенерати́вная систе́ма тепл. — feed heating system

резерви́рованная систе́ма — redundant system

систе́ма ремне́й, подвесна́я ( респиратора) — harness

систе́ма ру́бок лес. — cutting system

самонастра́ивающаяся систе́ма — self-adjusting system

самообуча́ющаяся систе́ма киб. — learning system

самоорганизу́ющаяся систе́ма — self-organizing system

самоприспоса́бливающаяся систе́ма киб. — adaptive system

самоуравнове́шивающаяся систе́ма — self-balancing system

самоусоверше́нствующаяся систе́ма — evolutionary system

санита́рная систе́ма мор. — sanitary system

систе́ма свя́зи — communication system

сопряга́ть систе́му свя́зи, напр. с ЭВМ — interface a communication network with, e. g., a computer

уплотня́ть систе́му свя́зи телегра́фными кана́лами — multiplex telegraph channels on a communication link

систе́ма свя́зи, асинхро́нная — asyncronous communication system

систе́ма свя́зи, двои́чная — binary communication system

систе́ма свя́зи, многокана́льная — multi-channel communication system

систе́ма свя́зи на метео́рных вспы́шках — meteor burst [meteor-scatter] communication system

систе́ма свя́зи, разветвлё́нная — deployed communication system

систе́ма свя́зи с испо́льзованием да́льнего тропосфе́рного рассе́яния — troposcatter communication system

систе́ма свя́зи с испо́льзованием ионосфе́рного рассе́яния — ionoscatter communication system

систе́ма свя́зи с переспро́сом — ARQ communication system

систе́ма свя́зи, уплотнё́нная — multiplex communication system

систе́ма свя́зи, уплотнё́нная, с временны́м разделе́нием сигна́лов — time division multiplex [TDM] communication system

систе́ма свя́зи, уплотнё́нная, с разделе́нием по ко́дам — code-division multiplex(ing) communication system

систе́ма свя́зи, уплотнё́нная, с часто́тным разделе́нием сигна́лов — frequency division multiplex [FDM] communication system

сельси́нная систе́ма — synchro system

сельси́нная систе́ма в индика́торном режи́ме — synchro-repeater [direct-transmission synchro] system

сельси́нная систе́ма в трансформа́торном режи́ме — synchro-detector [control-transformer synchro] system

сельси́нная, двухотсчё́тная систе́ма — two-speed [coarse-fine] synchro system

сельси́нная, дифференциа́льная систе́ма — differential synchro system

сельси́нная, одноотсчё́тная систе́ма — singlespeed synchro system

систе́ма сил — force system

систе́ма синхрониза́ции — timing [synchronizing] mechanism

синхро́нная систе́ма — synchronous system

следя́щая систе́ма — servo (system)

следя́щая, позицио́нная систе́ма — positional servo (system)

следя́щая систе́ма с не́сколькими входны́ми возде́йствиями — multi-input servo (system)

следя́щая систе́ма с предваре́нием — predictor servo (system)

систе́ма слеже́ния — tracking system

систе́ма слеже́ния по да́льности — range tracking system

систе́ма слеже́ния по ско́рости измене́ния да́льности — range rate tracking system

систе́ма сма́зки — lubrication (system)

систе́ма сма́зки, принуди́тельная — force(-feed) lubrication (system)

систе́ма сма́зки, разбры́згивающая — splash lubrication (system)

сма́зочная систе́ма — lubrication (system)

систе́ма с мно́гими переме́нными — multivariable system

систе́ма сниже́ния шу́ма — noise reduction system

систе́ма с обра́тной свя́зью — feedback system

Со́лнечная систе́ма — solar system

систе́ма сопровожде́ния — tracking system

систе́ма со свобо́дными пове́рхностями — unbounded system

систе́ма с пара́метрами, изменя́ющимися во вре́мени — time variable [time-variant] system

систе́ма с постоя́нным резерви́рованием — parallel-redundant system

систе́ма с разделе́нием вре́мени — time-sharing system

систе́ма с распределё́нными пара́метрами — distributed parameter system

систе́ма с самоизменя́ющейся структу́рой — self-structuring system

систе́ма с сосредото́ченными пара́метрами — lumped-parameter [lumped-constant] system

стати́ческая систе́ма — киб. constant-error system; ( в следящих системах) type O servo system

систе́ма, стати́чески неопредели́мая мех. — statically indeterminate system

систе́ма, стати́чески определи́мая мех. — statically determinate system

систе́ма стира́ния ( записи) — erasing system

стохасти́ческая систе́ма — stochastic system

сто́чная систе́ма мор. — deck drain system

судова́я систе́ма — ship system

систе́ма с фикси́рованными грани́цами — bounded system

систе́ма счисле́ния — number(ing) system, notation

систе́ма счисле́ния, восьмери́чная — octal number system, octonary notation

систе́ма счисле́ния, двенадцатери́чная — duodecimal number system, duodecimal notation

систе́ма счисле́ния, двои́чная — binary system, binary notation

систе́ма счисле́ния, двои́чно-десяти́чная — binary-coded decimal system, binary-coded decimal [BCD] notation

систе́ма счисле́ния, девятери́чная — nine number system

систе́ма счисле́ния, десяти́чная — decimal number system, decimal notation

систе́ма счисле́ния, непозицио́нная — non-positional notation

систе́ма счисле́ния, позицио́нная — positional number notation

систе́ма счисле́ния пути́, возду́шно-до́плеровская навиг. — airborne Doppler navigator

систе́ма счисле́ния, трои́чная — ternary number system, ternary notation

систе́ма счисле́ния, шестнадцатери́чная — hexadecimal number system, hexadecimal notation

телевизио́нная светокла́панная систе́ма — light-modulator [light-modulating] television system

телегра́фная многокра́тная систе́ма ( с временным распределением) — time-division multiplex (transmission), time division telegraph system

телеметри́ческая систе́ма — telemetering system

телеметри́ческая, промы́шленная систе́ма — industrial telemetering system

телеметри́ческая, то́ковая систе́ма — current-type telemeter

телеметри́ческая, часто́тная систе́ма — frequency-type telemeter

телефо́нная, автомати́ческая систе́ма — dial telephone system

телефо́нная систе́ма с ручны́м обслу́живанием — manual-switchboard telephone system

термодинами́ческая систе́ма — thermodynamic system

техни́ческая систе́ма (в отличие от естественных, математических и т. п.) — engineering system

систе́ма тона́льного телеграфи́рования — voice-frequency multichannel system

то́пливная систе́ма — fuel system

то́пливная систе́ма с пода́чей само́тёком — gravity fuel system

тормозна́я систе́ма ( автомобиля) — brake system

трёхкомпоне́нтная систе́ма — ternary [three-component] system

трёхпроводна́я систе́ма эл. — three-wire system

трёхфа́зная систе́ма эл. — three-phase system

трёхфа́зная систе́ма с глухозаземлё́нной нейтра́лью эл. — solidly-earthed-neutral three-phase system

трёхфа́зная, симметри́чная систе́ма эл. — symmetrical three-phase system

трёхфа́зная систе́ма с незаземлё́нной нейтра́лью эл. — isolated-neutral three-phase system

трю́мная систе́ма мор. — bilge system

систе́ма тяг — linkage

тя́го-дутьева́я систе́ма — draught system

систе́ма УВД — air traffic control [ATC] system

систе́ма управле́ния — control system

систе́ма управле́ния, автомати́ческая — automatic control system

систе́ма управле́ния без па́мяти — combinational (control) system

систе́ма управле́ния возду́шным движе́нием — air traffic control [ATC] system

систе́ма управле́ния произво́дством [предприя́тием], автоматизи́рованная [АСУП] — management information system, MIS

систе́ма управле́ния с вычисли́тельной маши́ной — computer control system

систе́ма управле́ния с па́мятью — sequential (control) system

систе́ма управле́ния с предсказа́нием — predictor control system

систе́ма управле́ния технологи́ческим проце́ссом, автоматизи́рованная [АСУТП] — (automatic) process control system

систе́ма управле́ния, цифрова́я — digital control system

управля́емая систе́ма ( объект управления) — controlled system, controlled plant

управля́ющая систе́ма ( часть системы управления) — controlling (sub-)system

упру́гая систе́ма ( гравиметра) — elastic system

систе́ма уравне́ний — set [system] of equations, set of simultaneous equations

систе́ма уравне́ния объё́ма ( ядерного реактора) — pressurizing system

уравнове́шенная систе́ма — balanced system

усто́йчивая систе́ма — stable system

фа́новая систе́ма мор. — flushing [sewage-disposal] system

систе́ма физи́ческих величи́н — system of physical quantities

хи́мико-технологи́ческая систе́ма — chemical engineering system

хими́ческая систе́ма — chemical system

систе́ма ЦБ-АТС тлф. — dial system

систе́ма цветно́го телеви́дения, совмести́мая — compatible colour-television system

систе́ма це́нтра масс — centre-of-mass [centre-of-gravity, centre-of-momentum] system

систе́ма цифрово́го управле́ния ( не путать с числовы́м управле́нием) — digital control system (not to be confused with numeric control system)

систе́ма «челове́к — маши́на» — man-machine system

шарни́рная систе́ма — hinged system

шарни́рно-стержнева́я систе́ма — hinged-rod system

шпре́нгельная систе́ма — strutted [truss] system

систе́ма эксплуата́ции телефо́нной свя́зи, заказна́я — delay operation

систе́ма эксплуата́ции телефо́нной свя́зи, ско́рая — demand working, telephone traffic on the demand basis

экстрема́льная систе́ма — extremal system

систе́ма электро́дов ЭЛТ — CRT electrode structure

электроже́зловая систе́ма ж.-д. — (electric) token system

электрохими́ческая систе́ма — electrochemical system

электрохими́ческая, необрати́мая систе́ма — irreversible electrochemical system

электрохими́ческая, обрати́мая систе́ма — reversible electrochemical system

электроэнергети́ческая систе́ма — electric power system

систе́ма элеме́нтов Менделе́ева, периоди́ческая — Mendeleeff's [Mendeleev's, periodic] law, periodic system, periodic table

систе́ма элеме́нтов ЦВМ — computer building-block range

энергети́ческая систе́ма — power system

энергети́ческая, еди́ная систе́ма — power grid

энергети́ческая, объединё́нная систе́ма — interconnected power system

команда

1) General subject: aggie (студентов сельскохозяйственного колледжа), also-ran, brigade, command, company, crew, demand, detachment, detail, equipage, gang, party, signal, squad, team, the lower deck (на английских судах), band

2) Computers: jump

3) Aviation: demand (запрос)

4) Naval: equipage (судна), ship company, ship crew

5) Sports: crew (на шлюпке и т.п.), cue, side (в частности, в футболе)

6) Military: batch, cell, code (на машинном языке), complement, draft, packet, smoke to!, word of command

7) Engineering: command order, command word, control word, crew (группа людей), instruction, instruction word, manning, party (группа людей)

8) Mathematics: program order

9) Economy: production code

10) Mining: gang (группа людей)

11) Information technology: function word, instruction statement (в языке ассемблера), named command, operation, order, verb

12) Missiles: command signal (наведения)

13) Football: outfit

14) Automation: code, command instruction, command signal, demand signal, message

15) Makarov: crew (судна), crew (судна), crew (судовая), direction, directive, hands (судна), instruction (ЭВМ)

16) Navy: (в значении подразделения на корабле) workcenter

17) SAP.tech. cmd

плавучий кран

1) General subject: derrick boat, ponton crane

2) Naval: crane boat

3) Engineering: crane barge, floating crane, pontoon crane, ship crane

4) Construction: barge crane, boat derive

5) Mining: derrick barge

6) Oil: floating derrick

7) Makarov: fc ( floating crane)

8) Logistics: crane ship

транспорт

1) General subject: carriage, carrier, carry over, portage, traffic, transport, transportation

2) Computers: vehicle

3) Naval: carrying trade (как отрасль хозяйства), craft (перевозочные средства), store-ship, vessels (сухопутные перевозочные средства)

4) Military: lift

5) Engineering: haul, haulage, hauling, transport ship, vehicles (перевозочные средства), vehicular traffic

6) Construction: conveyance, handling, transport facility, transit

7) Mathematics: transportation facilities

8) Commerce: carrying trade

9) Economy: transport industry, transportation industry (как отрасль экономики)

10) Accounting: carry-over, transfer

11) Mining: casting (породы)

12) Forestry: train

13) Textile: transfer (перенос)

14) Genetics: cotranslational transfer

15) SAP. shipment

16) Drilling: conveying

17) Automation: transport (ировка)

18) Makarov: convoy, craft (морской), transference, transport (перевозочные средства), transport (перемещение, перевозка, грузов, людей), transport (перемещение, перевозка, передвижение грузов, людей), transport sector, vehicles (сухопутный), vessels (морской)

19) Logistics: delivery vessel