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1 emission cell
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2 emission cell
1) Техника: фотоэлемент (электровакуумный)2) Электроника: электровакуумный фотоэлемент3) Космонавтика: эмиссионный фотоэлемент4) Макаров: фотоэлемент с внешним фотоэффектом -
3 emission cell
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4 emission cell
The New English-Russian Dictionary of Radio-electronics > emission cell
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5 emission cell
English-Russian dictionary of mechanical engineering and automation > emission cell
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6 emission cell
эмиссионный фотоэлемент (напр. на моечных установках для выключения работы мойки) -
7 emission cell
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8 cell
1) клетка3) элемент7) эл. шайба ( выпрямителя)8) эл. изолировочная гильза9) камера для работы с радиоактивными веществами10) строит. сегмент ребристого свода11) мн. ч. строит. пустоты в кирпиче или камне12) машиностр. гибкий производственный модуль, ГП-модуль, ГПМ; гибкий автоматизированный участок, ГАУ; ставочный участок13) ячейка памяти14) грозовой очаг, грозовой район ( в зоне полёта)16) полигр. растровая ячейка ( формы глубокой печати)17) пищ. диффузор18) ячейка ( тарный вкладыш)•cell with free diffusion boundaries — ячейка со свободной диффузией на границе жидкостей;cell with liquid junction — ячейка с жидкостным соединением;cell with open liquid junction — ячейка с открытым жидкостным соединением;cell without transference — элемент без переноса;-
polka dot solar cell
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absorbing cell
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accumulator cell
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acid cell
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Acker cell
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AD cell
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aeration cell
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aftertreatment cell
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agglomerate cell
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air-depolarizing cell
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air-hydrogen fuel cell
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airlift flotation cell
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airproof cell
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alkali-chlorine cell
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alkaline cell
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Allen-Moore cell
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aluminum cell
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amalgam cell
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ammonia-air fuel cell
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amorphous solar cell
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anisotropically etched solar cell
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aqueous fuel cell
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arc-heated cell
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array cell
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asymmetrical cell
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automated cell
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back-emf cell
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back-surface-field solar cell
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bag-type cell
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balloon calibrated solar cell
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basket cathode cell
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battery cell
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bearing cell
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Becquerel cell
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bell-jar cell
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bell cell
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bending part cell
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bifacial solar cell
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Billiter cell
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bimorph cell
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binary cell
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biomass fuel cell
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bipolar cell
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bit cell
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body cell
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body-centered cubic cell
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border cell
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box cell
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Bragg cell
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brine cell
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bubble cell
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cadmium cell
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carbon cell
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cascade solar cell
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cell of table
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central cell
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chargeable cell
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chemical cell
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chlorine cell
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Clark cell
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cleaner cell
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climatic cell
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closed cell
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close-packed atomic cell
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color cell
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combustion cell
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competent cell
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complex galvanic cell
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composite cell
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conductivity cell
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consumable-electrode cell
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convection cell
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corrosion cell
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counter electromotive cell
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counter cell
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counting cell
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crown cell
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crystal cell
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data cell
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delay cell
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desalting cell
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detector cell
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diamond cubic unit cell
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diaphragm cell
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diffraction cell
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diffused-junction solar cell
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diffusion cell
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disk stack cell
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Doppler-resolution cell
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drift field solar cell
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driver cell
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dry cell
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dummy cell
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dye cell
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ECM cell
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edge-illuminated solar cell
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Edison storage cell
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electrical electrochemical cell
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electric electrochemical cell
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electrical cell
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electric cell
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electrochemical machining cell
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electroluminescent cell
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electrolytic cell
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electrowinning cell
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emergency cell
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emission cell
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end cell
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epitaxial solar cell
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exposure cell
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fabric cell
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face-centered cubic cell
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faceted solar cell
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Faraday cell
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filter cell
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flat cell
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flotation cell
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flow-through cell
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fluid cooled solar cell
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fluorine cell
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front-surface-field solar cell
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front-wall solar cell
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froth flotation cell
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fuel cell
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fuel debottling cell
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fuel handling cell
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fuel-reprocessing cell
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fused cell
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galvanic cell
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gamma-measuring cell
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gas cell
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graded bandgap solar cell
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grating-type solar cell
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group-technology cell
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Hall cell
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heteroface solar cell
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heterojunction solar cell
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high-bandgap solar cell
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high-intensity solar cell
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high-level cell
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high-temperature fuel cell
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hole matrix vertical junction solar cell
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hole matrix vertical solar cell
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homojunction solar cell
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hot cell
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humidity cell
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hydraulic load cell
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hydrogen cell
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hydrogenerated amorphous silicon solar cell
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indicator cell
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induced-junction solar cell
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integral diode solar cell
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intermediate-level cell
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inversion layer solar cell
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junction solar cell
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Kerr cell
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lattice cell
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lead-acid cell
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lead cell
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lead-zinc cell
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Leclanche cell
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library cell
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light cell
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light-sensitive cell
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light-switching cell
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liquid crystal cell
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liquid junction solar cell
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lithium counterdoped silicon solar cell
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lithium-chlorine cell
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lithium-sulfur cell
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load cell
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low-bandgap solar cell
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low-level cell
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machining cell
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magnesium cell
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manufacturing cell
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master cell
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matrix solar cell
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mat-type cell
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measuring cell
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memory cell
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mercury cell
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minimum manned machining cell
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monofacial solar cell
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monolithic solar cell
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multibandgap solar cell
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multicolor solar cell
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multielectrode cell
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multijunction solar cell
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multilayer solar cell
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multilevel cell
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multipass absorption cell
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NC cell
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neoprene fuel cell
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new fuel storage cell
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nickel-cadmium cell
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nickel-iron cell
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nickel-zinc cell
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noise cell
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nonideal solar cell
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normal cell
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one-device cell
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optimum work cell
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optoelectronic cell
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oxidation-reduction cell
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oxygen cell
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oxygen-hydrogen cell
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oxyhydrogen cell
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painting cell
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part washing cell
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partially manned machining cell
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parting cell
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permeabilized cell
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petite cell
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photochemical cell
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photoconducting cell
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photoelectric cell
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photoelectrochemical cell
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photoelectrolytical cell
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photoelectrolytic cell
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photoemissive cell
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photogalvanic cell
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photomultiplier cell
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photoresistance cell
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photosensitive cell
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photovoltaic cell
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pickling cell
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piezoelectric cell
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pilot cell
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p-i-n solar cell
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planar solar cell
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plunge cell
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pneumatic cell
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point contact solar cell
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polycrystalline solar cell
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pressure cell
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primary cell
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processing cell
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pump cell
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purification cell
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radar-resolution cell
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radar cell
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radiation hardened solar cell
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range-resolution cell
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rechargeable cell
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rectifying cell
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reference solar cell
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refining cell
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refresh cell
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regenerative fuel cell
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regulator cell
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resolution cell
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resting cell
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retreatment cell
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ribbon solar cell
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robotic work cell
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robot work cell
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robotic cell
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robotic welding cell
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rocking cell
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roll cell
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rotating anode cell
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rotating cathode cell
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Schottky-barrier solar cell
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Schottky solar cell
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sealed cell
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sealed-in cell
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seawater conductivity cell
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secondary cell
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selenium cell
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self-adapting production cell
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self-contained machining cell
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self-refreshing cell
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self-sufficient cell
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semiconductor-electrolyte junction solar cell
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semimanned machining cell
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shadowed solar cell
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sheet solar cell
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sheet-pile cell
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silicon solar cell
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silo cell
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silver-zinc cell
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single manufacturing cell
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single cell
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single junction solar cell
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single-crystalline solar cell
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slot-type cell
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solar cell
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solid-electrolyte cell
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solid-state cell
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space solar cell
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spherical solar cell
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spinning cell
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spray-deposited solar cell
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stacked solar cell
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standard cell
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storage cell
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surface-passivated solar cell
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swarf removing cell
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switching cell
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tandem solar cell
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thermal cell
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thermal conductivity cell
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thermoelectric solar cell
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thermogalvanic cell
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thin-film solar cell
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transfer cell
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tube cell
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twisted nematic type cell
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two-mirror absorption cell
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ultrathin solar cell
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unit cell
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unmanned production cell
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vertical junction solar cell
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vertical solar cell
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V-groove sofar cell
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voltaic cell
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water cell
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wedged channel solar cell
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weighing cell
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welding cell
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Weston standard cell
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Weston cell
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wet cell
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work cell
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wraparound solar cell -
9 cell
1) элемент2) ячейка3) гальванический элемент (первичный элемент, аккумулятор или топливный элемент)5) вчт ячейка (данных), пакет фиксированной длины ( в режиме асинхронной передачи данных)6) тлф сота7) клетка•- absorbing cell
- acid cell
- acid fuel cell
- acoustooptic deflection cell
- active cell
- air cell
- alkaline cell
- alcaline dry cell
- alcaline-manganese cell
- alkaline storage cell
- anchor cell
- application-specific integrated circuit cell
- aqueous-electrolyte fuel cell
- array cell
- ASIC cell
- asymmetrical cell
- azimuth cell
- back-wall photovoltaic cell
- bag-type cell
- barrier-layer photoelectric cell
- barrier photovoltaic cell
- base-centered cell
- base-centered Bravais cell
- basic cell
- Becquerel cell
- Becquerel photovoltaic cell
- Bernard cell
- bias cell
- bichromate cell
- bimorph cell
- binary cell
- biochemical fuel cell
- bipolar cell
- bit cell
- bistable cell
- blank cell
- blocking-layer cell
- body-centered cell
- body-centered Bravais cell
- boundary scan cell
- Bragg cell
- Bravais cell
- Bravais unit cell
- Brillouin cell
- B/S cell
- bubble cell
- bubble-lattice cell
- Bunsen cell
- cadmium normal cell
- cadmium selenide photoconductive cell
- cadmium-silver oxide cell
- cadmium telluride solar cell
- cad-telluride solar cell
- calomel half-cell
- canal fuel cell
- carbon cell
- carbon-zinc cell
- cartridge cell
- cationic membrane cell
- cesium plasma cell
- character cell
- chargeable cell
- charge-storage cell
- charge-transfer cell
- chromic acid cell
- Clark cell
- closed-circuit cell
- color cell
- color Bravais cell
- color unit cell
- concentration cell
- concentric fuel cell
- conductivity cell
- copper-oxide photovoltaic cell
- copper-zinc cell
- counter cell
- counter electromotive cell
- counting cell
- Crowe cell
- current cell
- cryogenic memory cell
- crystal cell
- crystallographic cell
- Daniell cell
- DDC cell
- decomposition cell
- delay cell
- dichromate cell
- diffraction cell
- direct fuel cell
- direct-oxidation fuel cell
- displacement cell
- divalent silver oxide cell
- Doppler-resolution cell
- double-fluid cell
- dry cell
- dry-charged cell
- dry-tape cell
- dual-dielectric charge-storage cell
- dye cell
- E-cell
- edge-centered cell
- edge-centered Bravais cell
- Edison cell
- EL cell
- electric cell
- electrode concentration cell
- electroluminescence cell
- electrolytic cell
- electrooptic liquid-crystal cell
- element cell
- emergency cells
- emission cell
- end cells
- end-centered cell
- end-centered Bravais cell
- face-centered cell
- face-centered Bravais cell
- Faraday cell
- ferrimagnetic cell
- ferrite cell
- ferroelectric cell
- ferromagnetic cell
- force cell
- front-wall photovoltaic cell
- fuel cell
- fuel-gas cell
- function cell
- functional logic cell
- fused-electrolyte cell
- galvanic cell
- ganglion cell
- gas cell
- gas-filled cell
- glass half-cell
- Golay cell
- Golay pneumatic cell
- gravity cell
- Grenet cell
- grid-bias cell - hexagonal cell
- high-temperature fuel cell
- hot cell
- hydroelectric cell
- hydrogen-air cell
- hydrogen-oxygen cell
- hypercube cell
- hysteretic memory cell
- indirect-oxidation cell
- ion-exchange cell
- ion-exchange membrane cell
- iterative master cells
- jumbo cell
- Kerr cell
- L-cell
- Lalande cell
- lattice cell
- lead cell
- lead-acid cell
- lead-calcium cell
- lead-dioxide primary cell
- lead sulfide cell
- leaf cell
- Leclanche cell
- light-sensitive cell
- Li-ion cell
- Li-pol cell
- liquid-crystal cell
- liquid-crystal display cell
- liquid diffraction cell
- liquid-gas cell
- liquid-liquid cell
- liquid-metal fuel cell
- lithium cell
- lithium-ion cell
- lithium-iron sulfide secondary cell
- lithium-pol cell
- lithium-polymer cell
- lithium-silver chromate cell
- lithium-water cell
- load cell
- logic cell
- low-temperature fuel cell
- macro cell
- magnesium cell
- magnesium-cuprous chloride cell
- magnesium-silver chloride cell
- magnesium-water cell
- magnetic cell
- magnetic tunnel junction memory cell
- magnetic unit cell
- manganese-magnesium cell
- master cell
- memory cell
- mercury cell
- metal-air storage cell
- metal fuel cell
- metal-based fuel cell
- metallic rectifier cell
- metal-oxide-semiconductor cell
- metal-semiconductor barrier cell
- microphoto cell
- molten-carbonate fuel cell
- molten-electrolyte fuel cell
- MOS cell
- multijunction solar cell
- Na/S cell
- nerve cell
- nickel-cadmium cell
- nickel-iron cell
- nickel metal-hydride cell
- NiMH cell
- n-on-p solar cell
- nonprimitive Bravais cell
- nonprimitive unit cell
- nonregenerative fuel cell
- nuclear cell
- organic-semiconductor solar cell
- oxygen concentration cell
- oxygen-hydrogen cell
- Penning cell
- photochemical cell
- photoconducting cell
- photoconductive cell
- photoelectric cell
- photoelectrolytic cell
- photoemissive cell
- photogalvanic cell
- photovoltaic cell
- photronic cell
- piezoelectric cell
- pilot cell
- planar solar cell
- Plante cell
- plasma cell
- Pockels cell
- polycrystalline-film photoconducting cell
- p-on-n solar cell
- postsynaptic cell
- pressure cell
- presynaptic cell
- primary cell
- primary fuel cell
- primitive cell
- primitive unit cell
- processing cell
- promethium cell
- protected cell
- Purkinje cell
- quinhydrone electrode half-cell
- radar cell
- Raman cell
- range-resolution cell
- rapid single flux quantum cell
- rectifier photoelectric cell
- rectifying cell
- regenerative fuel cell
- reserve cell
- resolution cell
- resolving cell
- resonance cell
- rhombohedral cell
- robotic work cell
- RSFQ cell
- Ruben cell
- rubidium gas cell
- sal-ammonia cell
- SAM cell
- saturated standard cell
- Schottky-barrier solar cell
- sealed cell
- secondary cell
- selenium cell
- silicon rectifying cell
- silicon solar cell
- silver-hydrogen cell
- silver-oxide cell
- silver-zinc primary cell
- single-bit storage cell
- slot cell
- solar cell
- solid-electrolyte fuel cell
- standard cell
- standard Daniell cell
- Stark cell
- storage cell
- synchronous active-memory machine cell
- thallofide cell
- thermal cell
- thermoelectric solar cell
- thin-film solar cell
- TR cell
- transition cell
- transmit-receive cell
- tube fuel cell
- ultrasonic modulation cell
- ultrasonic refraction cell
- ultrasonic storage cell
- unit cell
- unsaturated standard cell
- vertical junction solar cell
- vertical memory cell
- voltaic cell
- Weston cell
- Weston standard cell
- wet cell
- Wigner-Seitz cell
- zinc-air fuel cell
- zinc-chlorine cell
- zinc-copper oxide cell
- zinc-iron cell
- zinc-mercury oxide cell
- zinc-silver chloride primary cell
- zinc-silver oxide cell -
10 cell
1) элемент2) ячейка3) гальванический элемент (первичный элемент, аккумулятор или топливный элемент)5) вчт. ячейка (данных), пакет фиксированной длины ( в режиме асинхронной передачи данных)6) тлф. сот7) клетка•- absorbing cell
- acid cell
- acid fuel cell
- acoustooptic deflection cell
- active cell
- air cell
- alcaline dry cell
- alcaline-manganese cell
- alkaline cell
- alkaline storage cell
- anchor cell
- application-specific integrated circuit cell
- aqueous-electrolyte fuel cell
- array cell
- ASIC cell
- asymmetrical cell
- azimuth cell
- B/S cell
- back-wall photovoltaic cell
- bag-type cell
- barrier photovoltaic cell
- barrier-layer photoelectric cell
- base-centered Bravais cell
- base-centered cell
- basic cell
- Becquerel cell
- Becquerel photovoltaic cell
- Bernard cell
- bias cell
- bichromate cell
- bimorph cell
- binary cell
- biochemical fuel cell
- bipolar cell
- bistable cell
- bit cell
- blank cell
- blocking-layer cell
- body-centered Bravais cell
- body-centered cell
- boundary scan cell
- Bragg cell
- Bravais cell
- Bravais unit cell
- Brillouin cell
- bubble cell
- bubble-lattice cell
- Bunsen cell
- cadmium normal cell
- cadmium selenide photoconductive cell
- cadmium telluride solar cell
- cadmium-silver oxide cell
- cad-telluride solar cell - carbon cell
- carbon-zinc cell
- cartridge cell
- cationic membrane cell
- cesium plasma cell
- character cell
- chargeable cell
- charge-storage cell
- charge-transfer cell
- chromic acid cell
- Clark cell
- closed-circuit cell
- color Bravais cell
- color cell
- color unit cell
- concentration cell
- concentric fuel cell
- conductivity cell
- copper-oxide photovoltaic cell
- copper-zinc cell
- counter cell
- counterelectromotive cell
- counting cell
- Crowe cell
- cryogenic memory cell
- crystal cell
- crystallographic cell
- current cell
- Daniell cell
- DDC cell
- decomposition cell
- delay cell
- dichromate cell
- diffraction cell
- direct fuel cell
- direct-oxidation fuel cell
- displacement cell
- divalent silver oxide cell
- Doppler-resolution cell
- double-fluid cell
- dry cell
- dry-charged cell
- dry-tape cell
- dual-dielectric charge-storage cell
- dye cell
- E cell
- edge-centered Bravais cell
- edge-centered cell
- Edison cell
- EL cell
- electric cell
- electrode concentration cell
- electroluminescence cell
- electrolytic cell
- electrooptic liquid-crystal cell
- element cell
- emergency cells
- emission cell
- end cells
- end-centered Bravais cell
- end-centered cell
- face-centered Bravais cell
- face-centered cell
- Faraday cell
- ferrimagnetic cell
- ferrite cell
- ferroelectric cell
- ferromagnetic cell
- force cell
- front-wall photovoltaic cell
- fuel cell
- fuel-gas cell
- function cell
- functional logic cell
- fused-electrolyte cell
- galvanic cell
- ganglion cell
- gas cell
- gas-filled cell - Golay pneumatic cell
- gravity cell
- Grenet cell
- grid-bias cell - hexagonal cell
- high-temperature fuel cell
- hot cell
- hydroelectric cell
- hydrogen-air cell
- hydrogen-oxygen cell
- hypercube cell
- hysteretic memory cell
- indirect-oxidation cell
- ion-exchange cell
- ion-exchange membrane cell
- iterative master cells
- jumbo cell
- Kerr cell
- Lalande cell
- lattice cell
- L-cell
- lead cell
- lead sulfide cell
- lead-acid cell
- lead-calcium cell
- lead-dioxide primary cell
- leaf cell
- Leclanche cell
- light-sensitive cell
- Li-ion cell
- Li-pol cell
- liquid diffraction cell
- liquid-crystal cell
- liquid-crystal display cell
- liquid-gas cell
- liquid-liquid cell
- liquid-metal fuel cell
- lithium cell
- lithium-ion cell
- lithium-iron sulfide secondary cell
- lithium-pol cell
- lithium-polymer cell
- lithium-silver chromate cell
- lithium-water cell
- load cell
- logic cell
- low-temperature fuel cell
- macro cell
- magnesium cell
- magnesium-cuprous chloride cell
- magnesium-silver chloride cell
- magnesium-water cell
- magnetic cell
- magnetic tunnel junction memory cell
- magnetic unit cell
- manganese-magnesium cell
- master cell
- memory cell
- mercury cell
- metal fuel cell
- metal-air storage cell
- metal-based fuel cell
- metallic rectifier cell
- metal-oxide-semiconductor cell
- metal-semiconductor barrier cell
- microphoto cell
- molten-carbonate fuel cell
- molten-electrolyte fuel cell
- MOS cell
- multijunction solar cell
- Na/S cell
- nerve cell
- nickel metal-hydride cell
- nickel-cadmium cell
- nickel-iron cell
- NiMH cell
- n-on-p solar cell
- nonprimitive Bravais cell
- nonprimitive unit cell
- nonregenerative fuel cell
- nuclear cell
- organic-semiconductor solar cell
- oxygen concentration cell
- oxygen-hydrogen cell
- Penning cell
- photochemical cell
- photoconducting cell
- photoconductive cell
- photoelectric cell
- photoelectrolytic cell
- photoemissive cell
- photogalvanic cell
- photovoltaic cell
- photronic cell
- piezoelectric cell
- pilot cell
- planar solar cell
- Plante cell
- plasma cell
- Pockels cell
- polycrystalline-film photoconducting cell
- p-on-n solar cell
- postsynaptic cell
- pressure cell
- presynaptic cell
- primary cell
- primary fuel cell
- primitive cell
- primitive unit cell
- processing cell
- promethium cell
- protected cell
- Purkinje cell - Raman cell
- range-resolution cell
- rapid single flux quantum cell
- rectifier photoelectric cell
- rectifying cell
- regenerative fuel cell
- reserve cell
- resolution cell
- resolving cell
- resonance cell
- rhombohedral cell
- robotic work cell
- RSFQ cell
- Ruben cell
- rubidium gas cell
- sal-ammonia cell
- SAM cell
- saturated standard cell
- Schottky-barrier solar cell
- sealed cell
- secondary cell
- selenium cell
- silicon rectifying cell
- silicon solar cell
- silver-hydrogen cell
- silver-oxide cell
- silver-zinc primary cell
- single-bit storage cell
- slot cell
- solar cell
- solid-electrolyte fuel cell
- standard cell
- standard Daniell cell
- Stark cell
- storage cell
- synchronous active-memory machine cell
- thallofide cell
- thermal cell
- thermoelectric solar cell
- thin-film solar cell
- TR cell
- transition cell
- transmit-receive cell
- tube fuel cell
- ultrasonic modulation cell
- ultrasonic refraction cell
- ultrasonic storage cell
- unit cell
- unsaturated standard cell
- vertical junction solar cell
- vertical memory cell
- voltaic cell
- Weston cell
- Weston standard cell
- wet cell
- Wigner-Seitz cell
- zinc-air fuel cell
- zinc-chlorine cell
- zinc-copper oxide cell
- zinc-iron cell
- zinc-mercury oxide cell
- zinc-silver chloride primary cell
- zinc-silver oxide cellThe New English-Russian Dictionary of Radio-electronics > cell
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11 cell
1) гибкий производственный модуль, ГПМ2) гибкая производственная ячейка, ГПЯ4) камера; секция; ячейка5) элемент, гальванический элемент•- automated manufacturing cell
- automated turning cell
- automated work cell
- circular sawing cell
- CNC machining center cell
- combined cell
- complex part cell
- component cells
- computer-controlled cell
- computer-driven cell
- counter cell
- crankshaft cell
- creep feed cell
- damped cell
- design-to-manufacturing cell
- desired-value cell
- dew cell
- discrete cell
- DNC flexible machining cell
- drilling cell
- dry cell
- dual-robot cell
- duplex machining cell
- EDM FMS cell
- electrical discharge machining cell
- electrochemical cell
- electrochemical machining cell
- emission cell
- extrusion trim cell
- family-of-parts manufacturing cell
- FFS cell
- final machining cell
- fir-tree grinding cell
- fir-tree milling cell
- flexible assembly cell
- flexible bending cell
- flexible drilling-and-milling manufacturing cell
- flexible fabricating cell
- flexible machining cell
- flexible manufacturing cell
- flexible production cell
- flexible turning cell
- FMS sheet metal cell
- FMT cell
- focused-layout cell
- force load cell
- forming cell
- gear hobbing cell
- gear manufacturing cell
- gear shaping cell
- grinding cell
- group technology cell
- group technology-based cell
- GT cell
- heat-treatment cell
- HMC cell
- honing cell
- horizontal machining cell
- inspection cell
- integrated cell
- integrated turning cells
- lathe cell
- lathe machining cell
- light-sensitive cell
- limited-manned cell
- load cell
- machine tool cell
- machining cell
- machining-center cell
- magnetic cell
- manned cell
- manufacturing cell
- measuring cell
- memory cell
- metalforming production cell
- milling and boring cell
- milling cell
- minimum manned cell
- mixed GT cell
- modular FMS cell
- multiaxis cell
- multirobot cell
- NC cell
- NC machine tool cell
- near-term cell
- noise testing cell
- one-machine cell
- on-line inspection cell
- operating cell
- opposed-spindle turning cell
- optimum work cell
- palletizing cell
- partially-manned flexible machining cell
- part-processing cell
- part-washing cell
- photoconductive cell
- photovoltaic cell
- piezoelectric crystal-type load cell
- pilot cell
- pneumatic cell
- position-sensitive photoelectric cell
- pressure cell
- processing cell
- production cell
- rechargeable cell
- reverse-engineering cell
- RGV-served cell
- robot-controlled machining cell
- robotic assembly cell
- robotic cell
- robotic machining cell
- robotic work cell
- robot-integrated cell
- robotized measuring cell
- robot-loaded cell
- robot-welding cell
- sandwiched liquid crystal cell
- sawing cell
- sealant cell
- secondary cell
- self-contained machining cell
- self-sufficient cell
- semimanned cell
- shallow-junction solar cells
- sheet-metal cell
- single-machine cell
- single-manufacturing cell
- spur helical bevel gear cell
- stand-alone cell
- standard cell
- storage cell
- store cell
- strain-gage load cell
- superconductor memory cell
- target cell
- test cell
- testing cell
- thermoelectric cell
- three-core cell
- three-unit flexible manufacturing cell
- time cell
- total parts-processing cell
- turned parts cell
- turning cell
- turning/milling cell
- two-machining-center cell
- two-unit flexible manufacturing cell
- unattended machining cell
- unattended production cell
- unmanned machining cell
- unmanned production cell
- versatile machining cell
- versatile manufacturing cell
- vertical internal milling machine cell
- VMC cell
- work cellEnglish-Russian dictionary of mechanical engineering and automation > cell
-
12 emission
выделение; распространение (напр. тепла, света); эмиссия; излучение; эманация- emission cell - emission control - emission index - emission inventory - emission limit - emission map - emission monitoring - emission of heat - emission point - emission regulation - emission test - heat emission -
13 emission test cell concentration
3.7 концентрация ЛОС в эмиссионной испытательной ячейке (emission test cell concentration): Массовая концентрация индивидуального ЛОС (или группы ЛОС), измеренная на выходе испытательной ячейки.
Источник: ГОСТ Р ИСО 16000-10-2009: Воздух замкнутых помещений. Часть 10. Определение выделения летучих органических соединений строительными и отделочными материалами. Метод с использованием испытательной ячейки оригинал документа
Англо-русский словарь нормативно-технической терминологии > emission test cell concentration
-
14 field-emission cathode
The English-Russian dictionary general scientific > field-emission cathode
-
15 электровакуумный фотоэлемент
emission cell, photoemissive cell, vacuum phototube, phototube, photoelectric tube, photosensitive tubeБольшой англо-русский и русско-английский словарь > электровакуумный фотоэлемент
-
16 respiration
1. n дыхание2. n вдохСинонимический ряд:emission of vapor (noun) breathing; emission; emission of vapor; exhalation; exhaling; exhausting; exhaustion; expiration; removal of air -
17 arc-proof low voltage switchgear and controlgear assembly
НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]EN
arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.
There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.
Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.
arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]Параллельные тексты EN-RU
If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.
Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.
The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.
Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.
This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.
Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.
These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.
As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.
This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.
[ABB]Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.
Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.
Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.
Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.
Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.
При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.
Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.
Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.
Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.
[Перевод Интент]Тематики
- НКУ (шкафы, пульты,...)
Синонимы
- комплектное устройство с защитой от электрической дуги
- низковольтное комплектное устройство с защитой от электрической дуги
- НКУ распределения и управления с защитой от электрической дуги
EN
Англо-русский словарь нормативно-технической терминологии > arc-proof low voltage switchgear and controlgear assembly
-
18 arc-proof switchboard
НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]EN
arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.
There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.
Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.
arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]Параллельные тексты EN-RU
If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.
Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.
The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.
Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.
This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.
Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.
These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.
As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.
This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.
[ABB]Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.
Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.
Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.
Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.
Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.
При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.
Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.
Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.
Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.
[Перевод Интент]Тематики
- НКУ (шкафы, пульты,...)
Синонимы
- комплектное устройство с защитой от электрической дуги
- низковольтное комплектное устройство с защитой от электрической дуги
- НКУ распределения и управления с защитой от электрической дуги
EN
Англо-русский словарь нормативно-технической терминологии > arc-proof switchboard
-
19 arc-proof switchgear
НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]EN
arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.
There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.
Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.
arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]Параллельные тексты EN-RU
If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.
Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.
The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.
Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.
This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.
Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.
These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.
As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.
This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.
[ABB]Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.
Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.
Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.
Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.
Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.
При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.
Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.
Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.
Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.
[Перевод Интент]Тематики
- НКУ (шкафы, пульты,...)
Синонимы
- комплектное устройство с защитой от электрической дуги
- низковольтное комплектное устройство с защитой от электрической дуги
- НКУ распределения и управления с защитой от электрической дуги
EN
Англо-русский словарь нормативно-технической терминологии > arc-proof switchgear
-
20 arc-resistant switchgear
НКУ с защитой от воздействия электрической дуги
комплектное устройство с защитой от электрической дуги
низковольтное комплектное устройство с защитой от электрической дуги
НКУ распределения и управления с защитой от электрической дуги
-
[Интент]EN
arc-resistant switchgear
A type of switchgear design which is designed to withstand the effects of an internal arcing fault, without causing harm to personnel who are located in defined areas. It is not intended to withstand these internal arcing fault without possibly causing physical damage to the structure and/or components, but often the physical damage is less with an arc-resistant design.
There are three classes of protection:
Type A - eliminates the emission of gases and particles from the front of the switchgear during an internal arcing fault,
Type B - eliminates the emission of gases and particles from the front and sides of the switchgear during an internal arcing fault,
Type C - eliminates the emission of gases and particles from the front and sides of the switchgear, from between compartments within the same cell, and between adjacent cells during an internal arcing fault.
Arc-resistant switchgear has traditionally been metal-clad, but the basic concept could also be applied to other types of switchgear as well.
arc-proof switchgear
An incorrect term. Please refer to arc-resistant switchgear
[Schneider Electric]
[ http://electrical-engineering-portal.com/glossary-of-medium-voltage-switchgear-terms]Параллельные тексты EN-RU
If the electric arc occurs inside LV switchgear it generates internal overpressures and results in local overheatings which may cause high mechanical and thermal stresses in the equipment.
Besides, the involved materials can generate hot decomposition products, gases or fumes, which, due to the overpressure, are almost always ejected to the outside of the enclosure thus jeopardizing the operator safety.
The European Directive 2006/95/EC states the fundamental safety requirements for low voltage electric materials (from 50 V to 1000 V in alternating current, from 75 V to 1500 V in continuos current) to be put on the market within the European Community.
Among the essential safety requirements defined by this Directive particular importance is given to the need of taking technical measures to prevent “temperature rises, electric arcs or radiations which may result in hazards” from occurring.
This aspect has always been highly considered for apparatus, but it has been wrongly neglected for electrical switchgear and only in the last 10-15 years it has been catching on both at Italian as well as at international level.
Safety for the operator and for the installation in case of arcing inside LV switchgear can be obtained through three different design philosophies:
1. assemblies mechanically capable of withstanding the electric arc (passive protection)
2. assemblies equipped with devices limiting the effects of internal arcing (active protection)
3. assemblies equipped with current limiting circuitbreakers.
These three solutions (also combined together) have found a remakable development in the industrial field and have been successfully applied by the main manufacturers of LV switchgear and controlgear assemblies.
As it can be seen hereafter by examining the first two solutions, an “active” protection against arc faults is intrinsecally more complex than a “passive” one.
This because of the presence of additional electromechanical/ electronic devices5 which limit the arcing effects and which, by their nature, may be subject to faults or not-tripping.
[ABB]Дуга, возникшая внутри НКУ, создает внутреннее избыточное давление и вызывает локальный перегрев, что может привести к воздействию на оборудование значительного механического напряжения и перепада температур.
Кроме того, под воздействием дуги различные материалы разлагаются на продукты, имеющие высокую температуру, в том числе газы и дым, которые почти всегда вырываются из оболочки НКУ под высоким давлением, подвергая опасности оперативный персонал.
Европейская директива 2006/95/EC определяет основные требования безопасности для низковольтного (от 50 до 1000 В переменного тока и от 75 до 1500 В постоянного тока) оборудования поставляемого на рынок Европейского Сообщества.
Одно из основных требований безопасности, определяемое данной директивой как наиболее важное, заключается в необходимости предпринять технические меры для предотвращения "подъема температуры, возникновения электрической дуги или излучения", которые могут причинить ущерб.
Данная проблема всегда учитывалась при создании различных аппаратов, но незаслуженно игнорировалась при разработке электрических комплектных устройств, и только в последние 10-15 лет ей стали уделять должное внимание как в Италии, так и во всем мире.
При возникновении электрической дуги внутри НКУ безопасность оператора и электроустановки обеспечивается тремя способами:
1. Конструкция НКУ должна выдерживать механические воздействия, возникающие при горении электрической дуги (пассивная защита).
2. НКУ должно быть оснащено устройствами, ограничивающими воздействие электрической дуги (активная защита)
3. НКУ должны быть оснащены токоограничивающими автоматическими выключателями.
Указанные три способа (применяемые совместно) получили дальнейшее развитие в промышленности и успешно применяются основными изготовителями НКУ распределения и управления.
Как будет показано далее при рассмотрении первых двух способов, активная защита от дуговых» неисправностей является более сложной, чем пассивная защита.
Это объясняется необходимостью использования дополнительных электромеханических или электронных устройств, задачей которых является ограничение воздействий дуги и которые сами могут оказаться неисправными и не сработать.
[Перевод Интент]Тематики
- НКУ (шкафы, пульты,...)
Синонимы
- комплектное устройство с защитой от электрической дуги
- низковольтное комплектное устройство с защитой от электрической дуги
- НКУ распределения и управления с защитой от электрической дуги
EN
Англо-русский словарь нормативно-технической терминологии > arc-resistant switchgear
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