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81 crack
1) трещина; расселина; щель2) трескаться; раскалываться•- branched crack - butt crack - capillary crack - central crack - contraction crack - cooling crack - corrosion crack - creep crack - cross crack - crow-foot crack - developing crack - expansion crack - failure crack - fatigue crack - fire crack - frost crack - hair crack - hair-fine crack - heat crack - horizontal crack - incipient crack - inclined crack - longitudinal crack - masked crack - root crack - service crack - sharp crack - shatter crack - shrinkage crack - star crack - surface crack - tiny crack - veed crack - wavy crack - wind crack* * *трещина- diagonal crack
- fatigue crack
- fire cracks
- frost crack
- hairline crack
- hair crack
- random cracks
- reflection cracks
- shearing cracks
- shear cracks
- shrinkage crack
- stress crack
- thermal crack
- tiny crack
- transverse crack -
82 limit
1) предел; граница; допуск2) ограничитель3) калибр4) ограничивать•- limit of adhesion - limit of application - limit of backwater - limit of elasticity - limit of proportionality - limit of sensibility - limit of stability - apparent elastic limit - bending limit - burning limit - compression limit - consistency limit - corrosion fatigue limit - creep limit - damming limit - design limits - dimension limit - elastic limit - endurance limit - extension limit - failure limit - fatigue limit - fire limit - grade limit - lean limit - liquid limit - load limit - lower limit of ultimate strength - lower limit of yield - lower flammable limit - permissible limit - plastic limit - proportional elastic limit - service limit - shrinkage limit - speed limit - stability limit - static limit of yield point - strength limit - stress limit - stressed beyond the elastic limit - superior limit of stress - ultimate limit* * *предел, граница || ограничивать- limits of acceptabilitysetting design limits — установление [принятие] расчётных ограничений
- limits of accuracy in building work
- limit of backwater
- limit of proportionality
- limit of structural usefulness
- limit of the ultimate strength
- acceptable tolerance limits
- Atterberg limit
- consistency limits
- contract limit
- creep limit
- deflection limits
- design limits
- elastic limit
- endurance limit
- explosive limits
- failure limit
- fatigue limit
- flammable limits
- harshness limit
- harshness limit of sand content
- Johnson's proportional limit
- liquid limit
- lower limit for load-carrying capacity
- lower explosive limit
- lower flammable limit
- permissible contaminant limit
- plastic limit
- proportional limit
- proportional elastic limit
- shrinkage limit
- strength limit
- stress limit
- tolerance limits
- upper limit for load-carrying capacity
- upper flammable limit
- vibration limit
- working load limit -
83 pit
яма; смотровая яма (для автомобилей); углубление; выемка; гнездо; впадина; котлован; раковина; язвина (вследствие коррозии); шахта; рудник; шурф; карьер; разрез; II делать углубление; разъедать; корродировать; покрывать коррозией- pit crane - pit depth - pit edge - pit formation - pit gravel - pit incinerator - pit nucleus - pit planer - pit rain gage - pit road - pit-run - pit scales - pit stop - pit-type planing machine - pit volume - bore pit - catch pit - dump pit - flywheel pit - sand pit - service pit - stone pit - test pit - turn-table pit - washing pit - wheel pit -
84 cap
1. n шапка, головной уборa cap set at a rakish angle — шапка, лихо сдвинутая на ухо
2. n кепка, кепи; фуражка3. n форменный головной убор; шапка4. n разг. спортсмен, представляющий страну на международном состязании5. n берет6. n колпак7. n чепец; чепчик8. n наколка9. n скуфья, камилавка10. n ермолка; тюбетейка; скуфейка11. n шапочка12. n капюшон13. n ист. шлем; кивер; каска14. n верхушка, шапка15. n крышка, колпачок; корончатая металлическая крышка16. n чехол; футляр17. n тех. колпачок; наконечник; насадка; грибок18. n мед. противозачаточный колпачокпереклад; капитель
19. n эл. цоколь20. n эл. чехлик21. n эл. шляпка гриба22. n эл. воен. наконечник снаряда23. n эл. капсюль; пистонblasting cap — подрывной капсюль, капсюль-детонатор
percussion cap — ударный капсюль, пистон
24. n эл. мор. эзельгофт25. n эл. амер. эк. верхний уровень, предел, лимит26. n эл. писчая бумага большого форматаcap-and-gown affair — мероприятие, на которое нужно являться в форме
to wear cap and bells — разыгрывать шута; паясничать
cap in hand — в роли просителя; униженно, подобострастно
to send the cap round — пускать шапку по кругу, собирать деньги
small double cap — формат бумаги,6Х66 см
sheet-and-half cap — формат бумаги,3Х62 см
27. n часто pl полигр. проф. прописная буква28. n шотл. чаша; чара, чарка29. n сл. капсула наркотикаСинонимический ряд:1. hat (noun) baseball cap; beanie; beret; bonnet; calotte; hat; pillbox; skullcap; visor2. top (noun) capsule; fez; lid; plug; seal; stopper; top3. cover (verb) blanket; cover; overcast; overlay; overspread; spread over4. culminate (verb) climax; consummate; crest; crown; culminate; finish off; peak; perfect; round off; surmount; top; top off5. surpass (verb) beat; best; better; cob; ding; exceed; excel; outdo; outgo; outmatch; outshine; outstrip; pass; surpass; transcend; trump -
85 problem
1. проблема; задача2. проблема; трудностьproblem of three bodiesaerodynamic problemaeroelastic problemaeroservoelastic problembending problembest-range problembirdstrike problemBlasius boundary layer stability problemBolza problemboundary value problemBoussinesq problembuckling problemcalculus of variations problemChebyshev problemcompressible problemconstrained problemcontact problemcontinuum problemcontrol problemcorrosion problemcoupling control problemcrack problemcross-coupling problemcross-coupling robust design problemdesign problemdeterministic problemdirect problemdiscrete variable problemdivergence problemeigenvalue problemelastic contact problemelastic torsion problemelastoplastic problemelastostatic problemengine problemengine-out problemestimation problemfatigue problemfeedback problemfixed endpoint problemFlamant problemflap-lag problemflap-lag-torsion problemflight dynamics problemflutter problemg-LOC-in-flight problemg-tolerance problemguidance problemhandling problemhardware problemhigh-order problemhigh-g problemicing problemimpact problemin-service problemincompressible problemLamb's problemlanding problemlifting surface problemlinear regulator problemlinear quadratic Gaussian problemLQG problemmaneuver problemmechanics problemminimax problemminimum time problemminimum time-to-climb problemminimum fuel problemminimum time to turn problemmulti-input multi-output problemnonself-adjoint problemnonlinear inequality-constrained problemnumerical problemoptimal control problemoptimal guidance problemoptimization problemPIO problemplane stress problempost-buckling problempursuit-evasion problemrobustness problemrotor-fuselage problemrotorcraft problemsaddle point problemsafety-of-flight problemscattering problemstability problemstall problemstatically determinate problemstepped-altitude problemstress problemSturm-Liouville problemsupersonic aircraft problemsynthesis problemtail-rotor problemtakeoff problemtargeting problemthermoelasticity problemthree-state problemtime-delay-related problemtraveling salesman problemtwist problemtwo-dimensional airfoil problemtwo-point boundary value problemunconstrained problemvariational problemvibration problemviscoelastic problemvisibility problemvisual problem -
86 characteristic
характеристика; характеристическая кривая; характерный параметр; характеристический; характерныйcollapsing characteristics of the gear — поведение [характеристики] шасси при поломке (в результате аварии, удара о землю)
explosive characteristics of fuel — взрывоопаспость топлива [горючего]
handling characteristics with autostabilization — характеристики управляемости (ЛА) с системой автостабилизации
handling characteristics without autostabilization — характеристики управляемости (ЛА) без системы автостабилизации
height control response characteristics — верт. характеристики управляемости по высоте
lift and drag characteristics — величины подъёмной силы и лобового сопротивления; зависимости подъёмной силы и лобового сопротивления
rough field handling characteristics — характеристики управляемости при движении по аэродрому с неровной поверхностью
s.f.c. characteristics — характеристики удельного расхода топлива [горючего]
Englsh-Russian aviation and space dictionary > characteristic
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87 test
испытание, проба, исследование, см. тж. testing, trials; испытывать, пробовать; исследоватьacceptable environmental range test — испытание для определения диапазона допустимых изменений условий окружающей среды
jolt and jumble test — разг. испытание на удар и вибрацию
partial climb flight tests — лётные испытания «на зубцы»
single engine stall tests — испытания на срыв [сваливание] с одним работающим двигателем
supercharged CFR engine test — оценка детонационной стойкости (авиационных бензинов) на одноцилиндровой установке CFR
water(-flow, -impingement) test — холодная проливка (ракетного двигателя)
— air test— bed test— hot test— jet test -
88 Davy, Sir Humphry
[br]b. 17 December 1778 Penzance, Cornwall, Englandd. 29 May 1829 Geneva, Switzerland[br]English chemist, discoverer of the alkali and alkaline earth metals and the halogens, inventor of the miner's safety lamp.[br]Educated at the Latin School at Penzance and from 1792 at Truro Grammar School, Davy was apprenticed to a surgeon in Penzance. In 1797 he began to teach himself chemistry by reading, among other works, Lavoisier's elementary treatise on chemistry. In 1798 Dr Thomas Beddoes of Bristol engaged him as assistant in setting up his Pneumatic Institution to pioneer the medical application of the newly discovered gases, especially oxygen.In 1799 he discovered the anaesthetic properties of nitrous oxide, discovered not long before by the chemist Joseph Priestley. He also noted its intoxicating qualities, on account of which it was dubbed "laughing-gas". Two years later Count Rumford, founder of the Royal Institution in 1800, appointed Davy Assistant Lecturer, and the following year Professor. His lecturing ability soon began to attract large audiences, making science both popular and fashionable.Davy was stimulated by Volta's invention of the voltaic pile, or electric battery, to construct one for himself in 1800. That enabled him to embark on the researches into electrochemistry by which is chiefly known. In 1807 he tried decomposing caustic soda and caustic potash, hitherto regarded as elements, by electrolysis and obtained the metals sodium and potassium. He went on to discover the metals barium, strontium, calcium and magnesium by the same means. Next, he turned his attention to chlorine, which was then regarded as an oxide in accordance with Lavoisier's theory that oxygen was the essential component of acids; Davy failed to decompose it, however, even with the aid of electricity and concluded that it was an element, thus disproving Lavoisier's view of the nature of acids. In 1812 Davy published his Elements of Chemical Philosophy, in which he presented his chemical ideas without, however, committing himself to the atomic theory, recently advanced by John Dalton.In 1813 Davy engaged Faraday as Assistant, perhaps his greatest service to science. In April 1815 Davy was asked to assist in the development of a miner's lamp which could be safely used in a firedamp (methane) laden atmosphere. The "Davy lamp", which emerged in January 1816, had its flame completely surrounded by a fine wire mesh; George Stephenson's lamp, based on a similar principle, had been introduced into the Northumberland pits several months earlier, and a bitter controversy as to priority of invention ensued, but it was Davy who was awarded the prize for inventing a successful safety lamp.In 1824 Davy was the first to suggest the possibility of conferring cathodic protection to the copper bottoms of naval vessels by the use of sacrificial electrodes. Zinc and iron were found to be equally effective in inhibiting corrosion, although the scheme was later abandoned when it was found that ships protected in this way were rapidly fouled by weeds and barnacles.[br]Principal Honours and DistinctionsKnighted 1812. FRS 1803; President, Royal Society 1820. Royal Society Copley Medal 1805.Bibliography1812, Elements of Chemical Philosophy.1839–40, The Collected Works of Sir Humphry Davy, 9 vols, ed. John Davy, London.Further ReadingJ.Davy, 1836, Memoirs of the Life of Sir Humphry Davy, London (a classic biography). J.A.Paris, 1831, The Life of Sir Humphry Davy, London (a classic biography). H.Hartley, 1967, Humphry Davy, London (a more recent biography).J.Z.Fullmer, 1969, Cambridge, Mass, (a bibliography of Davy's works).ASD -
89 Monell, Ambrose
SUBJECT AREA: Metallurgy[br]b. 1874 New York, USAd. 2 May 1921 Beacon, New York, USA[br]American metallurgist who gave his name to a successful nickel-copper alloy.[br]After graduating from Columbia University in 1896. Monell became a metallurgical engineer to the Carnegie Steel Company, rising in six years to be Assistant to the President. In 1900, while Manager of the company's open-hearth steelworks at Pittsburg, he patented a procedure for making high-carbon steel in basic conditions on the hearth of a fixed/stationary furnace; the method was intended to refine pig-iron containing substantial proportions of phosphorus and to do so relatively quickly. The process was introduced at the Homestead Works of the Carnegie Steel Company in February 1900, where it continued in use for some years. In April 1902 Monell was among those who launched the International Nickel Company of New Jersey in order to bring together a number of existing nickel interests; he became the new company's President. In 1904–5, members of the company's metallurgical staff produced an alloy of about 70 parts nickel and 30 copper which seemed to show great commercial promise on account of its high resistance to corrosion and its good appearance. Monell agreed to the suggestion that the new alloy should be given his name; for commercial reasons it was marketed as "Monel metal". In 1917, following the entry of the USA into the First World War, Monell was commissioned Colonel in the US Army (Aviation) for overseas service, relinquishing his presidency of the International Nickel Company but remaining as a director. At the time of his death he was also a director in several other companies in the USA.[br]Bibliography1900, British patent no. 5506 (taken out by O. Imray on behalf of Monell).Monell insinuated an account of his steel-making procedure at a meeting of the Iron and Steel Institute held in London and reported in The Journal of the Iron and SteelInstitute (1900) 1:71–80; some of the comments made by other speakers, particularly B.Talbot, were adverse. The following year (1901) Monell produced a general historical review: "A summary of development in open-hearth steel", Iron TradeReview 14(14 November):39–47.Further ReadingA.J.Wadhams, 1931, "The story of the nickel industry", Metals and Alloys 2(3):166–75 (mentions Monell among many others, and includes a portrait (p. 170)).JKA -
90 environment
aerodynamic environment — аэродинамические условия
aerospace environment — окружающие условия в воздушно-космическом пространстве
artificial environment — искусственная среда, имитирующие условия
ascent environment — условия подъёма
ascent aerodynamic environment — условия аэродинамического подъёма
atmospheric environment — окружающие атмосферные условия
chemical environment — химическая среда
corrosion environment — коррозионная среда
corrosive environment — коррозионная среда
cryogenic environment — криогенные условия
elevated-temperature environment — условия при повышенной температуре, условия воздействия высоких температур
erosive environment — эрозионная среда
gaseous environment — газовая среда, условия воздействия газовой среды
heating environment — нагревающая среда, условия нагрева
high-temperature environment — условия при высоких температурах
high-temperature oxidative environment — окисляющая среда при высоких температурах
landing environment — условия приземления [посадки]
launch environment — условия пуска ( ракеты)
launch site environment — условия на пусковой установке
low-temperature environment — условия при низких температурах
manufacturing environment — производственные условия, условия производства
outer-space environment — внешние космические условия
oxidizing environment — окисляющая среда
penetrating-radiation environment — условия проникающей радиации
prelaunch environment — предпусковые условия
preorbital environment — предорбитальпые условия
radiation environment — радиационная среда
re-entry environment — условия входа в плотную атмосферу
salt environment — солевая среда
sea environment — морские условия
service environment — эксплуатационная среда
space environment — космические условия [среда]
temperature environment — температурные условия ( окружающей среды)
thermal environment — тепловые условия
transportation environment — условия транспортировки
tropical environment — тропические условия
vacuum environment — условия вакуума
vacuum radiation environment — условия излучения в вакууме
vibration environment — вибрационные условия
weather environment — погодные условия
zero-gravity environment — условия невесомости
English-Russian dictionary of aviation and space materials > environment
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