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61 time
1) время; период времени2) момент времени || отмечать время3) хронометрировать; рассчитывать по времени4) синхронизировать; согласовывать во времени•- access time
- accumulated operating time
- action time
- activity slack time
- actual activity completion time
- actual time
- actuation time
- addition time
- add time
- add-subtract time
- arrival time
- assembly time
- attended time
- available machine time
- average operation time
- awaiting-repair time
- binding time
- bit time
- build-up time
- calculating time
- carry-over time
- carry time
- chip-access delay time
- circuit time
- clear-write time
- coding time
- compile time
- computation time
- computer dead time
- computer time
- computer useful time
- computing time
- connect time
- control time
- crash time
- crisis time
- cycle time
- data time
- data-retention time
- dead time
- debatable time
- debugging time
- debug time
- decay time
- deceleration time
- delay time
- design time
- destination time
- development time
- digit time
- discrete time
- divide time
- down time
- earliest expected time
- effective time
- engineering time
- entry time
- error-free running time
- estimated time
- event scheduled completion time
- event slack time
- event time
- execution cycle time
- execution time
- expected activity time
- fall time
- fault correction time
- fault location time
- fault time
- fetch time
- float time
- form movement time
- forward-current rise time
- gate time
- good time
- guard time
- handshaking time
- holding time
- hold time
- idle time
- improvement time
- incidental time
- ineffective time
- inoperable time
- installation time
- instruction time
- integrator time
- interaction time
- interarrival time
- interrogation time
- latency time
- latest allowable event time
- load time
- lock-grant time
- lock-holding time
- logarithmic time
- machine available time
- machine spoiled work time
- machine spoiled time
- machine time
- maintenance time
- makeup time
- manual time
- mean error-free time
- mean repair time
- mean time between errors
- mean time between failures
- mean time to repair
- memory cycle time
- miscellaneous time
- mission time
- most likely time
- multiply time
- no-charge machine fault time
- no-charge non-machine-fault time
- no-charge time
- nonfailure operating time
- nonreal time
- nonscheduled down time
- nonscheduled maintenance time
- object time
- occurrence time
- off time
- on time
- one-pulse time
- operating time
- operation time
- operation-use time
- optimistic time
- out-of-service time
- peaking time
- peak time
- pessimistic time
- polynomial time
- pool time
- positioning time
- power up time
- pre-assembly time
- precedence waiting time
- preset time
- preventive maintenance time
- print interlock time
- problem time
- processing time
- process time
- processor cycle time
- production time
- productive time
- program execution time
- program fetch time
- program testing time
- progration time
- propagation delay time
- proving time
- pulse time
- punch start time
- read time
- reading access time
- readout time
- read-restore time
- real time
- record check time
- recovery time
- reference time
- refresh time
- reimbursed time
- repair delay time
- repair time
- representative computing time
- request-response time
- resetting time
- resolution time
- resolving time
- response time
- restoration time
- restoring time
- retrieval time
- reversal time
- reverse-current fall time
- rewind time
- rise time
- round-trip time
- routine maintenance time- run time- sampling time
- scaled real time
- scheduled time
- schedule time
- scheduled down time
- scheduled operating time
- scramble time
- screen storage time
- search time
- seek time
- send-receive-forward time
- sensitive time
- service time
- serviceable time
- setting time
- settling time
- setup time
- simulated time
- s-n transition time
- standby time
- starting time
- start time
- start-up time
- stop time
- storage cycle time
- storage time
- subtraction time
- subtract time
- superconducting-normal transition time
- supplementary maintenance time
- swap time
- switch delay time
- switch time
- switching time
- system time
- takedown time
- task time
- testing time
- throughput time
- time between failures
- time for motion to start
- time now
- total time
- track-to-track move time
- transfer time
- transit time
- transition time
- translating time
- true time
- turnaround time
- turnoff time
- turnon time
- turnover time
- unacked time
- unattended standby time
- unattended time
- unavailable time
- unit time
- unused time
- up time
- useful time
- user time
- variable dead time
- waiting time
- word time
- word-addressing time
- write timeEnglish-Russian dictionary of computer science and programming > time
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62 cost
1. n1) цена; стоимость; себестоимость2) обыкн. pl расходы, издержки, затраты3) pl судебные издержки, судебные расходы
- absorbed costs
- accident costs
- acquisition cost
- actual cost
- actual costs
- actual manufacturing cost
- added cost
- additional cost
- adjusted historical cost
- administration costs
- administrative costs
- administrative and management costs
- administrative and operational services costs
- advertising costs
- after costs
- after-shipment costs
- aggregate costs
- agreed cost
- airfreight cost
- allocable costs
- allowable costs
- alternative costs
- amortization costs
- amortized cost
- ancillary costs
- annual costs
- anticipated costs
- applied cost
- arbitration costs
- assembly costs
- assessed cost
- average cost
- average costs
- average cost per unit
- average variable costs
- avoidable costs
- back-order costs
- basic cost
- billed cost
- book cost
- borrowing cost
- breakage cost
- break-even costs
- budget costs
- budgeted cost
- budgeted costs
- budgeted operating costs
- building costs
- burden costs
- calculated costs
- capacity costs
- capital costs
- capital floatation costs
- carriage costs
- carrying cost
- carrying costs
- centrally-managed costs
- changeover costs
- cleaning costs
- clerical costs
- closing costs
- collection costs
- combined cost
- commercial cost
- commercial costs
- committed costs
- common staff costs
- comparative costs
- competitive costs
- competitive marginal costs
- complaint costs
- conditional cost
- consequential costs
- considerable costs
- constant cost
- constant costs
- construction costs
- contract cost
- contractual costs
- controllable costs
- court costs
- crane costs
- credit costs
- cumulative costs
- current cost
- current costs
- current outlay costs
- current standard cost
- cycle inventory costs
- debt-servicing costs
- declining costs
- decorating costs
- decreasing costs
- defect costs
- defence costs
- deferred costs
- deficiency costs
- degressive costs
- delivery costs
- departmental costs
- depleted cost
- depreciable cost
- depreciated cost
- depreciated replacement cost
- depreciation costs
- designing costs
- deterioration costs
- development costs
- differential costs
- direct costs
- direct labour costs
- direct operating costs
- direct payroll costs
- discretionary fixed costs
- dismantling costs
- distribution costs
- distribution marketing cost
- domestic resource costs
- double-weighted borrowing cost
- downtime costs
- economic costs
- eligible costs
- engineering costs
- entry cost
- environmental costs
- equipment capital costs
- erection costs
- escalating costs
- escapable costs
- estimated cost
- estimated costs
- evaluation cost
- excess cost
- excess costs
- excessive costs
- exhibition costs
- exploration costs
- extra costs
- extra and extraordinary costs
- extraordinary costs
- fabrication cost
- factor cost
- factor costs
- factory cost
- factory costs
- factory overhead costs
- failure costs
- farm production costs
- farmer's cost
- farming costs
- feed costs
- fertilizing costs
- final cost
- financial costs
- financing costs
- first cost
- fixed costs
- fixed capital replacement costs
- flat cost
- floatation costs
- food costs
- foreign housing costs
- formation costs
- freight costs
- fuel costs
- full cost
- full costs
- funding cost
- general costs
- general running costs
- government-controlled production costs
- guarantee costs
- harvesting costs
- haul costs
- haulage costs
- heavy costs
- hedging cost
- hidden costs
- high cost
- hiring costs
- historical cost
- hospitality costs
- hotel costs
- hourly costs
- idle capacity costs
- idle time costs
- implicit costs
- implied interest costs
- imputed costs
- incidental costs
- increasing costs
- incremental costs
- incremental cost of capital
- incremental costs of circulation
- incremental costs of service
- incurred costs
- indirect costs
- indirect labour costs
- indirect manufacturing costs
- indirect payroll costs
- indirect production costs
- individual costs
- industrial costs
- industry-average costs
- initial cost
- inland freight cost
- inspection costs
- installation costs
- insurance costs
- insured cost
- intangible costs
- integrated cost
- interest costs
- inventoriable costs
- inventory cost
- inventory costs
- inventory acquisition costs
- inventory possession costs
- investigation costs
- investment costs
- invoiced cost
- issuing cost
- joint cost
- labour costs
- landed cost
- launching cost
- launching costs
- layoff costs
- legal costs
- legitimate costs
- life cycle costs
- life repair cost
- liquidation cost
- litigation costs
- living costs
- loading costs
- loan cost
- long-run average costs
- long-run marginal costs
- low costs
- low operating costs
- lump-sum costs
- machining cost
- maintenance costs
- maintenance-and-repair costs
- management costs
- man-power cost
- man-power costs
- manufacturing cost
- manufacturing costs
- manufacturing overhead costs
- marginal costs
- marginal-factor costs
- maritime costs
- marketing costs
- material costs
- material handling costs
- merchandising costs
- miscellaneous costs
- mixed cost
- mounting costs
- net cost
- nominal cost
- nonmanufacturing costs
- obsolescence costs
- offering cost
- one-off costs
- one-off costs of acquiring land, buildings and equipment
- one-shot costs
- operating costs
- operation costs
- operational costs
- opportunity costs
- order cost
- ordering cost
- order initiation cost
- ordinary costs
- organization costs
- organizational costs
- original cost
- original cost of the assets
- original cost of capital
- out-of-pocket costs
- overall cost
- overall costs
- overhead costs
- overtime costs
- own costs
- owning costs
- packaging cost
- packing cost
- past costs
- past sunk costs
- payroll cost
- payroll costs
- penalty cost
- penalty costs
- period costs
- permissible costs
- personnel costs
- piece costs
- planned costs
- postponable costs
- predetermined costs
- prepaid costs
- preproduction costs
- prime cost
- processing costs
- procurement costs
- product cost
- production cost
- production costs
- product unit cost
- progress-generating costs
- progressive costs
- prohibitive costs
- project costs
- project development cost
- projected costs
- promotional costs
- protected costs
- publicity costs
- purchase costs
- purchasing costs
- pure costs of circulation
- quality costs
- quality-inspection costs
- real cost
- real costs
- recall costs
- reconstruction cost
- recoverable cost
- recurring costs
- reduction costs
- reimbursable cost
- relative cost
- relevant costs
- removal costs
- renewal cost
- reoperating costs
- reoperation costs
- reorder cost
- repair cost
- repair costs
- replacement cost
- replacement costs
- replacement cost at market rates
- replacement cost of borrowing
- replacement cost of capital assets
- replacement cost of equipment
- replacement depreciation cost
- replenishment cost
- reproduction cost
- reproduction costs
- research costs
- research and development costs
- reservation costs
- rework costs
- rising costs
- road maintenance costs
- running costs
- run-on costs
- salvage cost
- salvage costs
- scheduled costs
- scrap cost
- selling costs
- semi-variable costs
- service costs
- servicing costs
- setting-up costs
- set-up costs
- shadow costs
- shelter costs
- shipping costs
- shortage costs
- single cost
- social costs
- social marginal costs
- social overhead costs
- sorting costs
- special costs
- specification costs
- spoilage costs
- staff costs
- stand costs
- standard cost
- standard costs
- standard direct labour costs
- standard direct materials cost
- standard factory overhead cost
- standing costs
- start-up costs
- stepped costs
- stocking cost
- stockout costs
- storage costs
- sunk costs
- supervision costs
- supplementary costs
- supplementary costs of circulation
- tangible costs
- target cost
- target costs
- taxable cost of shares
- tentative cost
- time-related cost
- total cost
- training cost
- training costs
- transaction costs
- transfer costs
- transhipment costs
- transport costs
- transportation costs
- travel costs
- travelling costs
- trim costs
- true cost
- true costs
- trust cost
- unamortized cost
- unavoidable costs
- underwriting cost
- unexpired costs
- unit cost
- unit costs
- unloading costs
- unrecovered cost
- unscheduled costs
- upkeep costs
- upward costs
- utility's costs
- variable costs
- variable capital costs
- wage costs
- war costs
- warehouse costs
- warehousing costs
- weighted average cost
- welfare costs
- wintering costs
- working cost
- working costs
- costs for bunker
- costs for storing
- costs of administration
- cost of appraisal
- cost of arbitration
- cost of borrowing
- cost of boxing
- cost of bunker
- cost of capital
- cost of capital deeping
- cost of carriage
- cost of carry
- cost of carrying inventory
- costs of circulation
- cost of civil engineering work
- cost of construction
- cost of a contract
- cost of credit
- cost of delivery
- cost of demonstration
- cost of discounting
- cost of disposal
- cost of education
- cost of equipment
- cost of equity capital
- cost of filing
- cost of financing
- cost of fixed capital
- cost of funds
- cost of goods
- cost of haulage
- cost of hotel accommodation
- costs of housing
- costs of idleness
- cost of installation
- cost of insurance
- costs of inventory
- cost of issue
- cost of labour
- cost of a licence
- cost of living
- cost of manpower
- cost of manufacture
- cost of manufactured goods
- cost of manufacturing
- costs of material
- costs of material inputs
- cost of money
- cost of obtaining funds
- costs of operations
- cost of an order
- cost of packaging
- cost of packing
- cost of postage
- costs of production
- cost of product sold
- cost of a project
- cost of publication
- cost of putting goods into a saleable condition
- cost of reclamation
- cost of reinsurance
- costs of reliability
- cost of renting
- cost of renting a trading post
- cost of repairs
- costs of routine maintenance
- cost of sales
- costs of sales
- cost of scrap
- cost of service
- cost of servicing
- costs of shipping
- cost of storage
- cost of a suit
- costs of supervision
- cost of tare
- costs of trackage
- costs of transportation
- cost of work
- cost per inquiry
- costs per unit
- above cost
- at cost
- at the cost of
- at extra cost
- below cost
- less costs
- minus costs
- next to cost
- under cost
- with costs
- without regard to cost
- exclusive of costs
- free of cost
- cost of market, whichever is lower
- cost plus percentage of cost
- absorb costs
- allocate costs
- assess the cost
- assess costs
- assume costs
- award costs against smb.
- bear costs
- calculate costs
- charge cost
- compute the cost
- cover the cost
- cover costs
- curb costs
- curtail costs
- cut down on costs
- cut production costs
- decrease the cost
- defray the costs
- determine the cost
- disregard costs
- distort the cost
- distribute costs
- entail costs
- estimate costs
- exceed the cost
- impose costs
- increase cost
- incur costs
- inflict economic and social costs
- involve costs
- itemize costs
- keep down costs
- meet the cost
- meet costs
- offset the cost
- offset the costs
- offset high interest costs
- overestimate production costs
- pay costs
- prune away costs
- push up costs
- recompense the cost
- recoup the cost
- recover costs
- reduce costs
- refund the cost
- revise the cost
- save costs
- sell at a cost
- share the cost
- slash costs
- split up the cost
- trim costs
- write off costs
- write off costs against revenues
- write off capital costs2. v1) стоить -
63 Nobel, Immanuel
[br]b. 1801 Gävle, Swedend. 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 DistinctionsImperial Gold Medal (Russia) 1853. Swedish Academy of Science Letterstedt Prize (jointly with son Alfred) 1868.BibliographyImmanuel 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 ReadingNo biographies of Immanuel Nobel exist, but his life is detailed in a number of books on his son Alfred.CM -
64 Wilkinson, John
SUBJECT AREA: Weapons and armour[br]b. 1728 Clifton, Cumberland, Englandd. 14 July 1808 Bradley, Staffordshire, England[br]English ironmaster, inventor of a cannon-boring machine.[br]Wilkinson's father Isaac was a farmer turned ironmaster. Soon after 1750, the family acquired Bersham furnace, near Wrexham. This was later in the hands of John and his brother William. By 1763, John had risen to take sole charge of Broseley furnace near Coalbrookdale, Shropshire, and in 1770 he set up a third furnace at Bradley, Staffordshire. By this time he had become one of the country's leading ironmasters, known for the wide range of ware made of cast iron, doubtless the reason for his nickname "Ironmad Wilkinson". He made a cast-iron boat which, to the surprise of many, floated. For his own eventual use, he also made a cast-iron coffin, but did not make sufficient allowance for increasing girth with age! Wilkinson's most notable invention was his cannon-boring machine, patented in 1774. The gun barrel was held rigidly while the cutter head moved forward on a rod inside a hollow boring bar. The machine was easily adapted to bore the cylinders for Boulton \& Watt's steam engines and he became a regular supplier, as only he could bore them with the required accuracy. On the other hand, their second engine was supplied to Wilkinson to power a blowing engine to provide air blast for his Broseley furnace: this was the first use of a Boulton \& Watt engine for a purpose other than pumping. By 1780 he had three further steam engines at work. Wilkinson installed the first Boulton \& Watt engine in France at the Paris waterworks, for which he supplied the iron pipes. Another patent was obtained in 1794 for the invention of the cupola or furnace for melting metal for small castings, although it is now thought that the real inventor was his brother William. Apart from domestic and engineering ironware, Wilkinson was supplier of arms to the American and, illicitly, to the French.[br]Further ReadingH.W.Dickinson, 1914, John Wilkinson, Iron-master.LRD -
65 CASE
case [keɪs]1. nouna. ( = fact, example) cas m• is it the case that...? est-il vrai que... ?• I'm in charge here, in case you've forgotten! (inf) c'est moi qui commande ici, au cas où vous l'auriez oublié !• there is a strong case for compulsory vaccination les partisans de la vaccination obligatoire ont de solides arguments• to have a good/strong case avoir de bons/solides argumentsd. (British = suitcase) valise f ; ( = box) (for bottles) caisse f ; (for goods on display) vitrine f ; (for jewels) coffret m ; (for camera, binoculars) étui m• violin/umbrella case étui m à violon/parapluie2. compounds* * *[keɪs]noun (abrév = computer-aided software engineering) CPAO f -
66 Parkes, Alexander
[br]b. 29 December 1813 Birmingham, Englandd. 29 June 1890 West Dulwich, England[br]English chemist and inventor who made the first plastic material.[br]After serving apprentice to brassfounders in Birmingham, Parkes entered Elkington's, the celebrated metalworking firm, and took charge of their casting department. They were active in introducing electroplating and Parkes's first patent, of 1841, was for the electroplating of works of art. The electrodeposition of metals became a lifelong interest.Notably, he achieved the electroplating of fragile objects, such as flowers, which he patented in 1843. When Prince Albert visited Elkington's, he was presented with a spider's web coated with silver. Altogether, Parkes was granted sixty-six patents over a period of forty-six years, mainly relating to metallurgy.In 1841 he patented a process for waterproofing textiles by immersing them in a solution of indiarubber in carbon disulphide. Elkingtons manufactured such fabrics until they sold the process to Mackintosh Company, which continued making them for many years. While working for Elkingtons in south Wales, Parkes developed the use of zinc for desilvering lead. He obtained a patent in 1850 for this process, which was one of his most important inventions and became widely used.The year 1856 saw Parkes's first patent on pyroxylin, later called Xylonite or celluloid, the first plastic material. Articles made of Parkesine, as it came to be called, were shown at the International Exhibition in London in 1862, and he was awarded a medal for his work. Five years later, Parkesine featured at the Paris Exhibition. Even so, Parkes's efforts to promote the material commercially, particularly as a substitute for ivory, remained stubbornly unsuccessful.[br]Bibliography1850, British patent no. 13118 (the desilvering of lead). 1856, British patent no. 235 (the first on Parkesine).1865, Parkes gave an account of his invention of Parkesine in J.Roy.Arts, (1865), 14, 81–.Further ReadingObituary, 1890, Engineering, (25 July): 111.Obituary, 1890, Mining Journal (26 July): 855.LRD -
67 Rawcliffe, Gordon Hindle
SUBJECT AREA: Electricity[br]b. 2 June 1910 Sheffield, Englandd. 3 September 1979 Bristol, England[br]English scientist and inventor of the multi-speed induction motor using the pole amplitude modulation principle.[br]After graduating from Keble College, Oxford, Rawcliffe joined the Metropolitan Vickers Electrical Company in 1932 as a college apprentice, and later became a design engineer. This was followed by a period as a lecturer at Liverpool University, where he was able to extend his knowledge of the principles underlying the design and operation of electrical machines. In 1941 he became Head of the Electrical Engineering Department at the Robert Gordon Technical College, Aberdeen, and Lecturer in charge of Electrical Engineering at Aberdeen University. In 1944 Rawcliffe was appointed to the Chair of Electrical Engineering at the University of Bristol, where he remained until his retirement in 1975. The reputation of his department was enhanced by the colleagues he recruited.After 1954 he began research into polyphase windings, the basis of alternating-current machinery, and published papers concerned with the dual problems of frequency changing and pole changing. The result of this research was the discovery in 1957 of a technique for making squirrel-cage induction motors run at more than one speed. By reversing current in one part of the winding, the pole distribution and number were changed, and with it the speed of rotation.Rawcliffe's name became synonymous with pole amplitude modulation, or PAM, the name given to this technique. Described by Rawcliffe as a new philosophy of windings, the technique led to a series of research papers, patents and licensing agreements in addition to consultancies to advise on application problems. Commercial exploitation of the new idea throughout Western Europe, the United Kingdom and the United States followed. In total he contributed twentyfive papers to the Proceedings of the Institution of Electrical Engineers and some sixty British patent applications were filed.[br]Principal Honours and DistinctionsFRS 1972. Royal Society S.G.Brown Medal 1978.Bibliography21 August 1958, British patent no. 900,600 (pole amplitude modulation).1958, with R.F.Burbridge and W.Fong, "Induction motor speed changing by pole amplitude modulation", Proceedings of the Institution of Electrical Engineers 105 (Part A): 411–19 (the first description of pole amplitude modulation).Further ReadingBiographical Memoirs of Fellows of the Royal Society, 1981, Vol. XXVII, London, pp. 479–503 (includes lists of Rawcliffe's patents and principal papers published).GWBiographical history of technology > Rawcliffe, Gordon Hindle
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68 Royce, Sir Frederick Henry
[br]b. 27 March 1863 Alwalton, Huntingdonshire, Englandd. 22 April 1933 West Wittering, Sussex, England.[br]English engineer and industrialist.[br]Royce was the younger son of a flour miller. His father's death forced him to earn his own living from the age of 10 selling newspapers, as a post office messenger boy, and in other jobs. At the age of 14, he became an apprentice at the Great Northern Railway's locomotive works, but was unable to complete his apprenticeship due to a shortage of money. He moved to a tool company in Leeds, then in 1882 he became a tester for the London Electric Light \& Power Company and attended classes at the City \& Guilds Technical College. In the same year, the company made him Chief Electrical Engineer for the lighting of the streets of Liverpool.In 1884, at the age of 21, he founded F.H. Royce \& Co (later called Royce Ltd, from 1894 to 1933) with a capital of £70, manufacturing arc lamps, dynamos and electric cranes. In 1903, he bought a 10 hp Deauville car which proved noisy and unreliable; he therefore designed his own car. By the end of 1903 he had produced a twocylinder engine which ran for many hundreds of hours driving dynamos; on 31 March 1904, a 10 hp Royce car was driven smoothly and silently from the works in Cooke Street, Manchester. This car so impressed Charles S. Rolls, whose London firm were agents for high-class continental cars, that he agreed to take the entire output from the Manchester works. In 1906 they jointly formed Rolls-Royce Ltd and at the end of that year Royce produced the first 40/50 hp Silver Ghost, which remained in production until 1925 when it was replaced by the Phantom and Wraith. The demand for the cars grew so great that in 1908 manufacture was transferred to a new factory in Derby.In 1911 Royce had a breakdown due to overwork and his lack of attention to taking regular meals. From that time he never returned to the works but continued in charge of design from a drawing office in his home in the south of France and later at West Wittering, Sussex, England. During the First World War he designed the Falcon, Hawk and Condor engines as well as the VI2 Eagle, all of which were liquid-cooled. Later he designed the 36.7-litre Rolls-Royce R engines for the Vickers Supermarine S.6 and S.6B seaplanes which were entered for the Schneider Trophy (which they won in 1929 and 1931, the 5.5 having won in 1927 with a Napier Lion engine) and set a world speed record of 408 mph (657 km/h) in 1931; the 1941 Griffon engine was derived from the R.Royce was an improver rather than an innovator, though he did invent a silent form of valve gear, a friction-damped slipper flywheel, the Royce carburettor and a spring drive for timing gears. He was a modest man with a remarkable memory who concentrated on perfecting the detail of every component. He married Minnie Punt, but they had no children. A bust of him at the Derby factory is captioned simply "Henry Royce, Mechanic".[br]Further ReadingR.Bird, 1995, Rolls Royce Heritage, London: Osprey.IMcNBiographical history of technology > Royce, Sir Frederick Henry
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69 Fischer, E.
[br]fl. 1930s Switzerland[br]Swiss engineer who invented the Eidophor large-screen television projector.[br]Fischer was a professor of engineering at the Swiss Federal Institute of Technology in the late 1930s. Interested in the emerging technology for television, he was of the opinion that the growth of television would take place through the development and use of large-screen cinema-type displays serving large audiences. He therefore carried out research into suitable techniques. Realizing the brightness limitations of projection systems based on the optical magnification of the image produced by a conventional cathode ray tube, he used the deflected electron-beam, not to excite a phosphor screen, but to deposit a variable charge on the surface of a film or oil. By means of a Schlieren slit system, the consequent deformations of the surface were used to spatially modulate the light from an electric arc or a discharge tube, giving a large, high-brightness image. Although the idea, first put forward in 1939, was not taken up for cinema television, the subsequent requirement of the US National Aeronautics and Space Administration in the 1960s for large colour displays in its Command and Control Centres led to the successful development of the idea by Gretag AG, a subsidiary of Ciba-Geigy: separate units were used for the red, green and blue images. In the 1990s, colour Eidophor projectors were used for large conference meetings and pop concerts.[br]Bibliography1946, "Views on the suitability of a cathode ray tube with a fluorescent screen for projection in cinemas", Bulletin of the Association of Swiss Electricians 39:468 (describes the concept of the Eidophor).Further ReadingE.H.Baumann, 1953, "The Fischer large screen projection system", Journal of Society of Motion Picture and Television Engineers 60:344.A.Robertson, 1976, "Projection television. A review of current practice in large-screen projectors", Wireless World 47.KF -
70 power supply
- энергоснабжение
- электроснабжение
- электропитание
- сетевое питание
- источник электропитания радиоэлектронной аппаратуры
- источник питания (в электроснабжении)
- источник питания
- импульсный источник (электро)питания
импульсный источник (электро)питания
—
[Я.Н.Лугинский, М.С.Фези-Жилинская, Ю.С.Кабиров. Англо-русский словарь по электротехнике и электроэнергетике, Москва, 1999 г.]Тематики
- электротехника, основные понятия
EN
источник питания
Характеристики внешних источников питания следует принимать по техническим условиям на присоединение, выдаваемым энегоснабжающей организацией в соответствии с Правилами пользования электрической энергией...
источник питания электроэнергией
-
[Интент]
источник электропитания
—
[Я.Н.Лугинский, М.С.Фези-Жилинская, Ю.С.Кабиров. Англо-русский словарь по электротехнике и электроэнергетике, Москва, 1999 г.]
Основными источниками питания должны служить электростанции и сети районных энергосистем. Исключение представляют большие предприятия с большим теплопотреблением, где основным источником питания может быть собственная электростанция (ТЭЦ). Но и в этом случае обязательно должна предусматриваться связь системы электроснабжения предприятия с сетью энергосистемы.
[СН 174-75 Инструкция по проектированию электроснабжения промышленных предприятий]
1.1.2 Зануление следует выполнять электрическим соединением металлических частей электроустановок с заземленной точкой источника питания электроэнергией при помощи нулевого защитного проводника.
[ ГОСТ 12.1.030-81]
Параллельные тексты EN-RUIt is recommended that, where practicable, the electrical equipment of a machine is connected to a single incoming supply. Where another supply is necessary for certain parts of the equipment (for example, electronic equipment that operates at a different voltage), that supply should be derived, as far as is practicable, from devices (for example, transformers, converters) forming part of the electrical equipment of the machine.
[IEC 60204-1-2006]Рекомендуется, там где это возможно, чтобы электрооборудование машины получало электропитание от одного источника. Если для каких-либо частей электрооборудования машины (например для электронного оборудования, работающего на другом напряжении) необходим отдельный источник питания, то, насколько это возможно, он должен являться частью (такой, например, как трансформатор, конвертор) электрооборудования этой же машины.
[Перевод Интент]
Power supplies
The required power supplies can be determined based on the criteria for definition of the installation (receivers, power, location, etc.) and the operating conditions (safety, evacuation of the public, continuity, etc.).
They are as follows:
- Main power supply
- Replacement power supply
- Power supply for safety services
- Auxiliary power supply
[Legrand]Источники электропитания
Источники электропитания определяют по различным критериям, в соответствии с характеристиками конкретной электроустановки. Определяют типы электроприемников, их мощность, территориальное расположение и др. При этом учитывают условия эксплуатации (безопасность, требования к аварийной эвакуации людей, непрерывность технологического процесса и т. д.).
Применяют следующие источники:
- основной источник питания;
- резервный источник питания;
- аварийный источник питания систем безопасности;
- дополнительный источник питания.
[Перевод Интент]
Рис. Legrand
Типовая схема электроснабжения: 1 - Main power supply - Основной источник питания
2 - Replacement power supply (2nd source) - Резервный источник питания (2-й источник)
3 - Replacement power supply (backup) - Резервный источник питания (независимый)
4 - Auxiliary power supply - Дополнительный источник питания
5 - Power supply for safety services - Аварийный источник питания для систем безопасности
6 - Management of sources - Управление источниками питания
7 - Control - Цепь управления
8 - Main LV distrib. board - Главный распределительный щит (ГРЩ)
9 - Safety panel - Панель безопасности
10 - Uninterruptible power supply - Источник бесперебойного питания
11 - Load shedding - Отключение нагрузки
12 - Non-priority circuits - Цепи неприоритетной нагрузки
14 - Uninterruptible circuits - Цепи бесперебойного питания
15 - Shed circuits - Цепи отключаемой нагрузки
16 - Safety circuits - Цепи систем безопасностиТематики
Близкие понятия
Действия
Синонимы
Сопутствующие термины
- аварийный источник питания
- взаимно резервируемые источники питания
- внешний источник питания
- дополнительный источник питания
- источник бесперебойного питания
- источник питания с ограничением тока
- независимый источник питания
- основной источник питания
- резервный источник питания
EN
источник электропитания радиоэлектронной аппаратуры
источник электропитания РЭА
Нерекомендуемый термин - источник питания
Устройство силовой электроники, входящее в состав радиоэлектронной аппаратуры и преобразующее входную электроэнергию для согласования ее параметров с входными параметрами составных частей радиоэлектронной аппаратуры.
[< size="2"> ГОСТ Р 52907-2008]
источник питания
Часть устройства, обеспечивающая электропитание остальных модулей устройства.
[ http://www.lexikon.ru/dict/net/index.html]EN
power supply
An electronic module that converts power from some power source to a form which is needed by the equipment to which power is being supplied.
[Comprehensive dictionary of electrical engineering / editor-in-chief Phillip A. Laplante.-- 2nd ed.]
Рис. ABB
Структурная схема источника электропитанияThe input side and the output side are electrically isolated against each other
Вход и выход гальванически развязаны
Терминология относящая к входу
Primary side
Первичная сторона
Input voltage
Входное напряжение
Primary grounding
Current consumption
Потребляемый ток
Inrush current
Пусковой ток
Input fuse
Предохранитель входной цепи
Frequency
Частота
Power failure buffering
Power factor correction (PFC)
Коррекция коэффициента мощности
Терминология относящая к выходу
Secondary side
Вторичная сторона
Output voltage
Выходное напряжение
Secondary grounding
Short-circuit current
То короткого замыкания
Residual ripple
Output characteristics
Выходные характеристики
Output current
Выходной ток
Различают первичные и вторичные источники питания.
К первичным относят преобразователи различных видов энергии в электрическую, например:
- аккумулятор (преобразует химическую энергию.
Вторичные источники не генерируют электроэнергию, а служат лишь для её преобразования с целью обеспечения требуемых параметров (напряжения, тока, пульсаций напряжения и т. п.)Задачи вторичного источника питания
- Обеспечение передачи мощности — источник питания должен обеспечивать передачу заданной мощности с наименьшими потерями и соблюдением заданных характеристик на выходе без вреда для себя. Обычно мощность источника питания берут с некоторым запасом.
- Преобразование формы напряжения — преобразование переменного напряжения в постоянное, и наоборот, а также преобразование частоты, формирование импульсов напряжения и т. д. Чаще всего необходимо преобразование переменного напряжения промышленной частоты в постоянное.
- Преобразование величины напряжения — как повышение, так и понижение. Нередко необходим набор из нескольких напряжений различной величины для питания различных цепей.
- Стабилизация — напряжение, ток и другие параметры на выходе источника питания должны лежать в определённых пределах, в зависимости от его назначения при влиянии большого количества дестабилизирующих факторов: изменения напряжения на входе, тока нагрузки и т. д. Чаще всего необходима стабилизация напряжения на нагрузке, однако иногда (например для зарядки аккумуляторов) необходима стабилизация тока.
- Защита — напряжение или ток нагрузки в случае неисправности (например, короткого замыкания) каких-либо цепей может превысить допустимые пределы и вывести электроприбор или сам источник питания из строя. Также во многих случаях требуется защита от прохождения тока по неправильному пути: например прохождения тока через землю при прикосновении человека или постороннего предмета к токоведущим частям.
- Гальваническая развязка цепей — одна из мер защиты от протекания тока по неверному пути.
- Регулировка — в процессе эксплуатации может потребоваться изменение каких-либо параметров для обеспечения правильной работы электроприбора.
- Управление — может включать регулировку, включение/отключение каких-либо цепей или источника питания в целом. Может быть как непосредственным (с помощью органов управления на корпусе устройства), так и дистанционным, а также программным (обеспечение включения/выключения, регулировка в заданное время или с наступлением каких-либо событий).
- Контроль — отображение параметров на входе и на выходе источника питания, включения/выключения цепей, срабатывания защит. Также может быть непосредственным или дистанционным.
Трансформаторный (сетевой) источник питания
Чаще всего состоит из следующих частей:- Сетевого трансформатора, преобразующего величину напряжения, а также осуществляющего гальваническую развязку;
- Выпрямителя, преобразующего переменное напряжение в пульсирующее;
- Фильтра для снижения уровня пульсаций;
- Стабилизатора напряжения для приведения выходного напряжения в соответствие с номиналом, также выполняющего функцию сглаживания пульсаций за счёт их «срезания».
В сетевых источниках питания применяются чаще всего линейные стабилизаторы напряжения, а в некоторых случаях и вовсе отказываются от стабилизации.
Достоинства такой схемы:- Простота построения и обслуживания
- Надёжность
- Низкий уровень радиопомех.
Недостатки:
- Большой вес и габариты, особенно при большой мощности: по большей части за счёт габаритов трансформатора и сглаживающего фильтра
- Металлоёмкость
- Применение линейных стабилизаторов напряжения вводит компромисс между стабильностью выходного напряжения и КПД: чем больше диапазон изменения напряжения, тем больше потери мощности.
- При отсутствии стабилизатора на выход источника питания проникают пульсации с частотой 100Гц.
В целом ничто не мешает применить в трансформаторном источнике питания импульсный стабилизатор напряжения, однако большее распространение получила схема с полностью импульсным преобразованием напряжения.
Импульсный источник питания
Широко распространённая схема импульсного источника питания состоит из следующих частей:- Входного фильтра, призванного предотвращать распространение импульсных помех в питающей сети
- Входного выпрямителя, преобразующего переменное напряжение в пульсирующее
- Фильтра, сглаживающего пульсации выпрямленного напряжения
- Прерывателя (обычно мощного транзистора, работающего в ключевом режиме)
- Цепей управления прерывателем (генератора импульсов, широтно-импульсного модулятора)
- Импульсного трансформатора, который служит накопителем энергии импульсного преобразователя, формирования нескольких номиналов напряжения, а также для гальванической развязки цепей (входных от выходных, а также, при необходимости, выходных друг от друга)
- Выходного выпрямителя
- Выходных фильтров, сглаживающих высокочастотные пульсации и импульсные помехи.
Достоинства такого блока питания:
- Можно достичь высокого коэффициента стабилизации
- Высокий КПД. Основные потери приходятся на переходные процессы, которые длятся значительно меньшее время, чем устойчивое состояние.
- Малые габариты и масса, обусловленные как меньшим выделением тепла на регулирующем элементе, так и меньшими габаритами трансформатора, благодаря тому, что последний работает на более высокой частоте.
- Меньшая металлоёмкость, благодаря чему мощные импульсные источники питания стоят дешевле трансформаторных, несмотря на бо́льшую сложность
- Возможность включения в сети широкого диапазона напряжений и частот, или даже постоянного тока. Благодаря этому возможна унификация техники, производимой для различных стран мира, а значит и её удешевление при массовом производстве.
Однако имеют такие источники питания и недостатки, ограничивающие их применение:
- Импульсные помехи. В связи с этим часто недопустимо применение импульсных источников питания для некоторых видов аппаратуры.
- Невысокий cosφ, что требует включения компенсаторов коэффициента мощности.
- Работа большей части схемы без гальванической развязки, что затрудняет обслуживание и ремонт.
- Во многих импульсных источниках питания входной фильтр помех часто соединён с корпусом, а значит такие устройства требуют заземления.
[Википедия]
Недопустимые, нерекомендуемые
Тематики
Обобщающие термины
Синонимы
EN
Параллельные тексты EN-RU Safely OS shutdown and protection from data loss during power failure
Корректное завершение работы ОС с сохранением данных при нарушении сетевого питания
[Перевод Интент]EN
электропитание
-
[IEV number 151-13-75]EN
power supply
provision of electric energy from a source
[IEV number 151-13-75]FR
alimentation électrique, f
fourniture d'énergie électrique à partir d’une source
[IEV number 151-13-75]2
электропитание
-
[IEV number 151-13-76]EN
power supply
electric energy converter which draws electric energy from a source and supplies it in a specified form to a load
[IEV number 151-13-76]FR
alimentation électrique, f
convertisseur d’énergie électrique qui prélève de l'énergie électrique à une source et la restitue sous une forme spécifiée à une charge
[IEV number 151-13-76]Тематики
Действия
- нарушение электропитания
- обеспечивать электропитание для работы...
- отключение электропитания
- подача электропитания на...
- подвод электропитания
- поддерживать электропитание
- прерывание электропитания
Синонимы
Сопутствующие термины
- (электро)питание (электро)приемников
- (электро)питание (электро)приемников от сети переменного тока
- (электро)питание непрерывным напряжением переменного тока
- бесперебойность (электро)питания
- кабель электропитания
- категория электропитания
- линия электропитания
- надежность электропитания
- напряжение электропитания
- непрерывное (электро)питание нагрузки
- непрерывность (электро)питания
- нестабильность электропитания
- перерыв (электро)питания
- сеть электропитания
- трехфазная система электропитания
- цепи электропитания переменного (постоянного) тока
EN
DE
FR
электроснабжение
Обеспечение потребителей электрической энергией.
[ ГОСТ 19431-84]Качество электрической энергии (КЭ) тесно связано с надежностью электроснабжения, поскольку нормальным режимом электроснабжения потребителей является такой режим, при котором потребители получают электроэнергию бесперебойно, в количестве, заранее согласованном с энергоснабжающей организацией, и нормированного качества.
[В. В. Суднова. Качество электрической энергии]Тематики
Действия
Сопутствующие термины
- бесперебойность электроснабжения
- надежность электроснабжения
- нарушение электроснабжения
- нормальный режим электроснабжения
- проект электроснабжения
- электроснабжение от автономного источника питания электроэнергией
EN
3.21 источник питания (power supply): Источник электрической энергии, к которому предполагается подключать оборудование связи (в контексте требований настоящего стандарта).
Источник: ГОСТ Р 55266-2012: Совместимость технических средств электромагнитная. Оборудование сетей связи. Требования и методы испытаний оригинал документа
Англо-русский словарь нормативно-технической терминологии > power supply
71 Martin, Sir James
SUBJECT AREA: Aerospace[br]b. 1893 Co. Down, Northern Irelandd. 5 January 1981 England[br]Irish military aircraft engineer, inventor of the ejector seat.[br]Martin acquired a general knowledge of engineering as an industrial worker in Belfast. In 1929 he established the Martin Aircraft Company, which was merged five years later with another concern to form the Martin-Baker Aircraft Company at Denham, Buckinghamshire. They became known for designing and constructing efficient, lightweight military aircraft, and Martin supervised personally every aspect of the work of his factory. During the Second World War they developed a number of aircraft weapons, including an explosive device carried on a bomber's wings for cutting the cables of barrage balloons, the flat-feed system for the 20 mm Hispano cannon used on British fighter planes and the twelve-gun pack mounted in the nose of the Havoc night fighter. Martin began devising means of rapid escape from a disabled fighter plane. First came a quick-release canopy for the Spitfire, followed by an improved form sliding on guides set in the fuselage. Then came the Martin-Baker seat, which ejected the pilot from his plane by an explosive charge. Ground tests were made to determine the rates of acceleration that could be tolerated by the pilot, and the first test in the air with a pilot took place in July 1946 at a speed of 320 mph (515 km/h) and an altitude of 8,000 ft (2,400 m). Its first use in a genuine emergency was in May 1949.After the Second World War, the firm specialized in making components, particularly the ejector seat, rather than complete aircraft. The higher speeds and altitudes of supersonic jet aircraft made it necessary to modify the ejector seat: a device to hold the pilot's legs together, to prevent their being broken, was incorporated. In addition, with the Institute of Aviation Medicine, Martin developed a face blind to prevent skin damage at low temperatures. Another modification was to allow the seat to fall freely for the first 10,000 ft (3,000 m) to enable the pilot to reach breathable air more quickly; in October 1959 a successful demonstration took place at 1,250 mph (2,000 km/h) and 40,000 ft (12,000 m) altitude. During the inventor's lifetime, it is estimated that his ejector seat saved the lives of some 4,700 airmen.[br]Principal Honours and DistinctionsKnighted 1965. Barbour Air Safety Award 1958. Cumberbatch Air Safety Trophy 1959. Royal Aero Club Gold Medal 1964.Further ReadingObituary, 1981, The Times.LRD72 Shoenberg, Isaac
[br]b. 1 March 1880 Kiev, Ukrained. 25 January 1963 Willesden, London, England[br]Russian engineer and friend of Vladimir Zworykin; Director of Research at EMI, responsible for creating the team that successfully developed the world's first all-electronic television system.[br]After his initial engineering education at Kiev Polytechnic, Shoenberg went to London to undertake further studies at the Royal College of Science. In 1905 he returned to Russia and rose to become Chief Engineer of the Russian Wireless Telegraphy Company. He then returned to England, where he was a consultant in charge of the Patent Department and then joint General Manager of the Marconi Wireless Telegraphy Company (see Marconi). In 1929 he joined the Columbia Graphophone Company, but two years later this amalgamated with the Gramophone Company, by then known as His Master's voice (HMV), to form EMI (Electric and Musical Industries), a company in which the Radio Corporation of America (RCA) had a significant shareholding. Appointed Director of the new company's Research Laboratories in 1931, Shoenberg gathered together a team of highly skilled engineers, including Blumlein, Browne, Willans, McGee, Lubszynski, Broadway and White, with the objective of producing an all-electronic television system suitable for public broadcasting. A 150-line system had already been demonstrated using film as the source material; a photoemissive camera tube similar to Zworykin's iconoscope soon followed. With alternate demonstrations of the EMI system and the mechanical system of Baird arranged with the object of selecting a broadcast system for the UK, Shoenberg took the bold decision to aim for a 405-line "high-definition" standard, using interlaced scanning based on an RCA patent and further developed by Blumlein. This was so successful that it was formally adopted as the British standard in 1935 and regular broadcasts, the first in the world, began in 1937. It is a tribute to Shoenberg's vision and the skills of his team that this standard was to remain in use, apart from the war years, until finally superseded in 1985.[br]Principal Honours and DistinctionsKnighted 1954. Institution of Electrical Engineers Faraday Medal 1954.Further ReadingA.D.Blumlein et al., 1938, "The Marconi-EMI television system", Journal of the Institution of Electrical Engineers 83:729 (provides a description of the development of the 405-line system).For more background information, see Proceedings of the International Conference on the History of Television. From Early Days to the Present, November 1986, Institution of Electrical Engineers Publication No. 271.KF73 CTE
1) Компьютерная техника: channel termination equipment2) Спорт: Countdown To Extinction3) Военный термин: central timing equipment, commander, task element, commercial test equipment, components test equipment, contractor technical evaluation, contractor test and evaluation4) Техника: cable terminal equipment, charge transfer efficiency, circuit transmission efficiency, command and telemetry electronics5) Железнодорожный термин: Cen-Tex Rail Link Limited6) Оптика: charge-transfer efficiency7) Сокращение: Contractual Technical Evaluation8) Университет: Center For Teaching Excellence9) Вычислительная техника: Compliance Test and Evaluation10) Нефтегазовая техника coal tar enamel (угольная эмаль) (покрытие труб (см., напр., http://findarticles.com/p/articles/mi_m3251/is_6_228/ai_n25035018/)11) Образование: Career And Technical Education12) Полимеры: coefficient of thermal expansion13) Нефть и газ: competency technical excellence14) Электротехника: cable termination equipment15) Печатные платы: thermal coefficient of expansion, коэффициент теплового расширения74 загрузочное отверстие
1) Aviation: service door2) Engineering: charge hole, feeding hole3) Construction: fill opening, filling nozzle4) Forestry: charging door (дефибрера), opening for charge5) Metallurgy: charging opening, filling opening6) Oil: charging hole, feed port, receiving opening7) Polymers: feed opening8) Makarov: charging port, loading port9) Aluminium industry: feeding hole (in the crust) (в корке)10) Cement: feed inlet, feed-inlet end (мельницы), ingate, inlet openingУниверсальный русско-английский словарь > загрузочное отверстие
75 продуктивность
1) General subject: productiveness, productivity, efficiency2) Geology: HC charge, hydrocarbon charge3) Biology: performance, producing capacity, production performance4) Engineering: effectiveness, production5) Economy: productive efficiency6) Linguistics: creativity7) Forestry: fertility (насаждения), productive capacity, yield, yield power, yielding power8) Information technology: productivity (использования ресурсов)9) Oil: producibility (технологичность), productivity (пласта)10) Immunology: issue (процесса)11) Ecology: yielding capacity12) Sakhalin energy glossary: deliverability, productivity (пласта - по нефти, воде), productivity (по нефти, воде)13) Sakhalin R: productivity (пласта)15) Soil science: cropping power16) Karachaganak: (пласта) producing pay (Карачаганак, Rigless Operations)17) Phraseological unit: bang for the buck76 сечение перезарядки
1) Engineering: charge-exchange cross-section2) Makarov: cross-section for charge exchangeУниверсальный русско-английский словарь > сечение перезарядки
77 толчок
1) General subject: bob, boon, buffet, bunt, butt, cant, clean and jerk, concussion, dig, dig up, fillip, flick, hit, hitch, hoick, ictus, impact, impulse, impulsion, ivy, jab, jerk, job, jog, jolt, jostle, jounce, jumble, jump off, kick, lunge, momentas, poke, prod, prog, propulsion, pulse, pulsion, push, push off, shock, shove, start, stir, stirrer, take off, thrust, toss, urge, wap, yerk, burst, impetus, momentum, stimulus, motive2) Geology: forerunners, shake3) Naval: jolting, projection, pusher6) Sports: jump-off, push-off, repulsion, take-off, thrust against the horse8) Rare: illision9) General subject: toilet10) Railway term: slam12) Polygraphy: jerk (при пуске печатной машины)13) Jargon: charge, whack, flea market (Russian slang), john (US English slang for toilet), crapper (US slang for toilet), lav (short for lavatory), bog (slang for toilet)14) Oil: percussion, surge, tremor16) Graphic expression: jump start (The fact that such initiatives have been very limited suggests they need a jump-start.)17) Mechanics: impact shock18) Automation: jogging20) Makarov: beat (сердечный), bump (тока), burst (ионизации), incitement, kick (ногой, копытом), shock (при землетрясении и т.п.)78 service
1. n услужениеdomestic service — домашняя работа, обязанности слуги
to be in service — быть слугой, служить
2. n работаlength of service — стаж работы; срок службы
3. n рабочий стаж, срок службы4. n государственная служба5. n учреждение6. n службаrailway service, service of trains — железнодорожное сообщение
7. n обслуживание, сервис8. n сфера услуг; обслуживание населения; служба быта, сервисservice workers — работники, занятые в сфере обслуживания
9. n библиотечное обслуживание10. n военная службаactive service, service with the colours — действительная военная служба
11. n воен. вид вооружённых сил; род войскthe three services — the army, the navy, the aviation — три рода войск: сухопутные войска, военно-морской флот и военно-воздушные силы
12. n услуга, одолжение; помощь13. n заслугаdistinguished service order — орден "За боевые заслуги"
14. n сервиз15. n прибор16. n церк. богослужение, службаmemorial service — заупокойная служба, панихида
17. n юр. исполнение постановления суда; вручение; судебное извещениеservice of warrant — вручение судебного приказа, ордера
18. n с. -х. случка19. n мор. клетневание20. n тех. эксплуатация21. a военный; относящийся к вооружённым силамservice test — испытания в войсках, войсковые испытания
service troops — войска обслуживания; тыловые части и подразделения
22. a служебный23. a повседневный; прочный, ноский24. a обслуживающийservice trades — профессии, относящиеся к сфере обслуживания
25. v обслуживать26. v производить осмотр и текущий ремонт27. v заправлять28. n бот. рябина домашняяСинонимический ряд:1. action (noun) action; combat2. agency (noun) agency; bureau; commission; department3. aid (noun) aid; assistance; attendance; cooperation; help; ministration; usefulness; value4. armed forces (noun) armed forces; military5. army (noun) army; duty; stint6. benefit (noun) benefit; utility; wear7. effort (noun) effort; labor8. favor (noun) courtesy; dispensation; favor; favour; grace; indulgence; kindness9. rite (noun) ceremonial; ceremony; formality; liturgy; observance; rite; ritual; sermon; worship10. tableware (noun) china; set; setting; silver; tableware11. use (noun) account; advantage; applicability; application; appropriateness; avail; employment; fitness; relevance; serviceability; use; utilisation12. maintain (verb) maintain; preserve; repair; sustain79 Benz, Karl
[br]b. 25 November 1844 Pfaffenrot, Black Forest, Germanyd. 4 April 1929 Ladenburg, near Mannheim, Germany[br]German inventor of one of the first motor cars.[br]The son of a railway mechanic, it is said that as a child one of his hobbies was the repair of Black Forest clocks. He trained as a mechanical engineer at the Karlsruhe Lyzeum and Polytechnikum under Ferdinand Redtenbacher (d. 1863), who pointed out to him the need for a more portable power source than the steam engine. He went to Maschinenbau Gesellschaft Karlsruhe for workshop experience and then joined Schweizer \& Cie, Mannheim, for two years. In 1868 he went to the Benkiser Brothers at Pforzheim. In 1871 he set up a small machine-tool works at Mannheim, but in 1877, in financial difficulties, he turned to the idea of an entirely new product based on the internal-combustion engine. At this time, N.A. Otto held the patent for the four-stroke internal-combustion engine, so Benz had to put his hopes on a two-stroke design. He avoided the trouble with Dugald Clerk's engine and designed one in which the fuel would not ignite in the pump and in which the cylinder was swept with fresh air between each two firing strokes. His first car had a sparking plug and coil ignition. By 1879 he had developed the engine to a stage where it would run satisfactorily with little attention. On 31 December 1879, with his wife Bertha working the treadle of her sewing machine to charge the batteries, he demonstrated his engine in street trials in Mannheim. In the summer of 1888, unknown to her husband, Bertha drove one of his cars the 80 km (50 miles) to Pforzheim and back with her two sons, aged 13 and 15. She and the elder boy pushed the car up hills while the younger one steered. They bought petrol from an apothecary in Wiesloch and had a brake block repaired in Bauschlott by the village cobbler. Karl Benz's comments on her return from this venture are not recorded! Financial problems prevented immediate commercial production of the automobile, but in 1882 Benz set up the Gasmotorenfabrik Mannheim. After trouble with some of his partners, he left in 1883 and formed a new company, Benz \& Cie, Rheinische Gasmotorenfabrik. Otto's patent was revoked in 1886 and in that year Benz patented a motor car with a gas engine drive. He manufactured a 0.8hp car, the engine running at 250 rpm with a horizontal flywheel, exhibited at the Paris Fair in 1889. He was not successful in finding anyone in France who would undertake manufacture. This first car was a three-wheeler, and soon after he produced a four-wheeled car, but he quarrelled with his co-directors, and although he left the board in 1902 he rejoined it soon after.[br]Further ReadingSt J.Nixon, 1936, The Invention of the Automobile. E.Diesel et al., 1960, From Engines to Autos. E.Johnson, 1986, The Dawn of Motoring.IMcN80 By, Lieutenant-Colonel John
SUBJECT AREA: Canals[br]b. 7 (?) August 1779 Lambeth, London, Englandd. 1 February 1836 Frant, Sussex, England[br]English Engineer-in-Charge of the construction of the Rideau Canal, linking the St Lawrence and Ottawa Rivers in Canada.[br]Admitted in 1797 as a Gentleman Cadet in the Royal Military Academy at Woolwich, By was commissioned on 1 August 1799 as a second lieutenant in the Royal Artillery, but was soon transferred to the Royal Engineers. Posted to Plymouth upon the development of the fortifications, he was further posted to Canada, arriving there in August 1802.In 1803 By was engaged in canal work, assisting Captain Bruyères in the construction of a short canal (1,500 ft (460 m) long) at the Cascades on the Grand, now the Ottawa, River. In 1805 he was back at the Cascades repairing ice damage caused during the previous winter. He was promoted Captain in 1809. Meanwhile he worked on the fortifications of Quebec and in 1806–7 he built a scale model of the Citadel, which is now in the National War Museum of Canada. He returned to England in 1810 and served in Portugal in 1811. Back in England at the end of the year, he was appointed Royal Engineer Officer in charge at the Waltham Abbey Gunpowder Works on 1 January 1812 and later planned the new Small Arms Factory at Enfield; both works were on the navigable River Lee.In the post-Napoleonic period Major By, as he then was, retired on half-pay but was promoted to Lieu tenant-Colonel on 2 December 1824. Eighteen months later, in March 1826, he returned to Canada on active duty to build the Rideau Canal. This was John By's greatest work. It was conceived after the American war of 1812–14 as a connection for vessels to reach Kingston and the Great Lakes from Montreal while avoiding possible attack from the United States forces. Ships would pass up the Ottawa River using the already-constructed locks and bypass channels and then travel via a new canal cut through virgin forest southwards to the St Lawrence at Kingston. By based his operational headquarters at the Ottawa River end of the new works and in a forest clearing he established a small settlement. Because of the regard in which By was held, this settlement became known as By town. In 1855, long after By's death, the settlement was designated by Queen Victoria as capital of United Canada (which was to become a self-governing Dominion in 1867) and renamed Ottawa; as a result of the presence of the national government, the growth of the town accelerated greatly.Between 1826–7 and 1832 the Rideau Canal was constructed. It included the massive engineering works of Jones Falls Dam (62 ft 6 in. (19 m) high) and 47 locks. By exercised an almost paternal care over those employed under his direction. The canal was completed in June 1832 at a cost of £800,000. By was summoned back to London to face virulent and unjust criticism from the Treasury. He was honoured in Canada but vilified by the British Government.[br]Further ReadingR.F.Leggett, 1982, John By, Historical Society of Canada.—1976, Canals of Canada, Newton Abbot: David \& Charles.—1972, Rideau Waterway, Toronto: University of Toronto Press.Bernard Pothier, 1978, "The Quebec Model", Canadian War Museum Paper 9, Ottawa: National Museums of Canada.JHBBiographical history of technology > By, Lieutenant-Colonel John
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